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|
|
~ ANNALS

OF THE SOUTH AF RICAN
MUSEUM

ANNALS OF THE SOUTH AFRICAN MUSEUM
ANNALE VAN DIE SUID-AFRIKAANSE MUSEUM

Volume 61 ~~ Band
October 1973 Oktober

COMPARATIVE ECOLOGY AND BEHAVIOUR OF
CHAMAELEO PUMILUS PUMILUS (GMELIN)
& C. NAMAQUENSIS A. SMITH
(SAURIA: CHAMAELEONIDAE)

By
BRYAN RONALD BURRAGE

Cape Town Kaapstad

The ANNALS OF THE SOUTH AFRICAN MUSEUM

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ISBN 0 949940 30 5

Printed in South Africa by In Suid-Afrika gedruk deur
The Rustica Press, Pty., Ltd., Die Rustica-pers, Edms., Bpk.,
Court Road, Wynberg, Cape Courtweg, Wynberg, Kaap

COMPARATIVE ECOLOGY AND BEHAVIOUR OF
CHAMAELEO PUMILUS PUMILUS (GMELIN)
AND C. NAMAQUENSIS A. SMITH (SAURIA: CHAMAELEONIDAE) —

By
BRYAN RONALD BURRAGE
South African Museum, Cape Town*

(With 14 figures and 49 tables)
[MS. accepted 2 October 1972]

CONTENTS

I. Introduction . 3
A Systematics : , : : ; 4
B. Distribution and Papi : ; : ; ; 8
9

9

fe)

II. Materials and Methods

A Collecting and observational tvethods
B_ Thermal studies : ; ; ; : ee) at
C Metabolic rate studies s : i ‘ #2
D Cardiac rate studies . é , : ; ‘ 13
E_ Food studies : : ‘ : : : 13
F Water and salt balance weuclie’ : ; : eis
G Territorial and population studies : : eo UNE
H Reproduction studies . : : : : tee RG
III. Results and Discussion . ; : : 6
A Habitat of Chamaeleo putts : 216
B_ Description of study stations of Ghamiaeteo puis 5D)
C Habitat of Chamaeleo namaquensis . 5 KS)
D Description of study stations of Gherigeleo namaquensis 18
E Mortality . : : ; : : > gO
1 Parasitism and nies : : : : > BO
oe Predatvionss: : 2 : i A ; 32
g leovancall : ; : : : i AED
4 Humanagency . ‘ 5 GR
F ‘Temperatures and their genitals neta patterns) = 533
1 Regulation of temperatures . : ; 5 8G
2 Thermal preferences in the field. ; 34
3 Thermal preferences in the laboratory . go
4 ‘Thermal preferences of chamaeleons in compari-
son with other saurians . 37
5 Thermoregulation: warming cooling 4 in ie aa 42
6 Thermoregulation: warming/cooling in the

laboratory ; : : : : SA
7 Cardiac rate and temperature : 50
8 Summation of chamaeleon thermoncmalationt: in

comparison with other reptiles; role of colour 51
g Summation of chamaeleon thermoregulation in

comparison with other reptiles; role of posture 60

* Present address: College of the Desert, Palm Desert, California.

Ann. S. Afr. Mus. 61, 1973: 1-158, 14 figs, 49 tables

ANNALS OF THE SOUTH AFRICAN MUSEUM

PAGE
10 Summation of chamaeleon thermoregulation in
comparison with other reptiles; roles of the
lungs, the cardiovascular system, and
temperature control centres : . +60
11 Oxygen consumption . ; » G4
12 Activity patterns: daily and seasowal ; . . 167
G Behaviour : : : 5 : j es
I Senses : : : : : : > © Oa
2 Defence . ; ; ‘ : 5 "ae
3 Learning ability . : : i : «| FA
H_ Food habits : ? : : ; ‘ mee 7/5
ceding ‘ : : : ; a 7/5;
2 Amount ofone meal . : : : . Fg
3 Rates of passage . ; ; 2 .' 8
4 Prey items . : : : ; ; . 79
5 Skin-shedding . : : : » "68
I Water and salt balance ; ; : : . 65
1 Drinking and water sources . 5 : » 65
2 Water storage and conservation . : 7 8b
3 Water loss . ; : 89
4 Laboratory desiccation eaeies on Chamaeten
pumilus and C. namaquensis : ; » 4 390
5 Salt balance : ‘ : : ; 198
J Population structure . 6 ; ; 5)
1 Density and biomass . 5 : ; . OF
2 Social interactions : ; : : | 100
3 ‘Territorial display : ; ; ; on
4. Size and structure of territories : : a CP
K Reproduction . 109
Te sex dermaination ane desertion of adit
Chamaeleo pumilus and C. namaquensis . » 109
2 Courting . : : -) LL
3 Description of the eggs of Ghmeleo:: namaquensis . 112
4 Parturition sites of Chamaeleo pumilus and nesting
sites of C. namaquensis : 114
5 Annual number and size of litters a Ghamueen
pumilus and clutches of C. namaquensis . 116
6 Success of the litters of Chamaeleo pumilus ‘ii
the clutches of C. namaquensis : .. 119
7 Role of fat bodies : : - 120
8 Nature of gonads (adult Aentrenieeate) 7 B26
9 Nature of gonads (adult reproductive) . en
10 Gestation . F 3 ; é : . 130
11 Incubation . ; : ; : : . 136
12 Young : : : ; : 2 Ago
13 Growth and longer, : : : : ee SO)
IV. Summary ‘ : : : : ; : 5 ale
Acknowledgements : ; ‘ : ' ; BANG

References. 3 ; , : : b 2 Ay

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 3

I. INTRODUCTION

This study describes certain aspects of the life history of Chamaeleo pumilus
(Gmelin) and of C. namaquensis A. Smith. Reproductive potential, population
size, territorial structure, thermoregulation, behaviour, and other ecological
relationships of these chamaeleonids in dynamic equilibrium with their vastly
different habitats are considered. ‘The viviparous, arboreal C’. pumilus lives mostly
in mesic areas of southern Africa. The aforementioned ecological considerations
of the oviparous C. namaquensis have never been studied. This ground-dwelling
species inhabits semi-arid and arid areas of southern Africa.

There is no comprehensive picture of chamaeleon ecology. Brain (1961) has
given a preliminary picture of the life history and biology of Chamaeleo dilepis.
Rose (1950) has made general comments on chamaeleons. Ecological studies
on field populations of chamaeleons are so few and mostly of such limited scope
as to be virtually non-existent. Following his papers on yearly population
density variation of C. pardalis (Bourgat 1968a), and the spermatogenesis cycle
of this insular species (Bourgat 1968)), Bourgat (1970) has provided a detailed
study of C. pardalis. These are the only ecological studies on marked field
populations of chamaeleons. Bourgat’s papers and those of Saint Girons (1962)
on sperm storage in female C. basiliscus, C. chamaeleon, and C. lateralis, Wager
(1958), Bons & Bons (1960) on reproduction of C. dilepis and C. chamaeleon,
respectively, are the only detailed field studies on chamaeleon reproduction,
save short notes by Trench (1912) on C. calcaratus (=C. chamaeleon zeylanicus)
and Menzies (1958) on C. gracilis. Chamaeleon colour lability has been the
subject of very few serious studies. Until recently the general interpretation of
this phenomenon has not altered much from those stated by Aristotle (Cross-
well’s translation, 1883) and Pliny (Bostock & Riley’s translation, 1887). The
function of chamaeleon colour lability has been discussed and investigated by
Briicke (1852), Weber (1881), Fuchs (1914) and Kriiger & Kern (1924). The
dynamics of chamaeleon physiological thermoregulation were indicated in
studies on the lungs and air sacs by Couvreur & Gautier (1904) and Tornier
(1904), and the chamaeleonid carotid body (Adams 1957). Hogben & Mirvish
(1928a, b) and Zoond & Eyre (1934) investigated colour change in Chamaeleo
pumilus and Lophosaura pumila (both =C. pumilus) respectively, and Farghaly
(1941) in Chamaeleo vulgaris (=C. chamaeleon), but few speculated on, or
endeavoured to study its functional significance. Some of these early findings of
the mediating mechanism of chamaeleon colour lability have been subsequently
challenged and enlarged upon by Canella (1963) and Cleworth (unpublished
data). There are no field records of chamaeleon body temperatures, but Stebbins
(1961) gives body temperature records of captive C. dilepis and C. namaquensis.
Parasites and disease of Madagascan chamaeleons have been studied by Brygoo
(1963), Brygoo, Dodin & Sureau (1959) and Chabaud & Brygoo (1960). A
fungal infection disturbing the colour lability mechanism is reported by Elkan
(1965) for the East African C. bitaeniatus.

There are a number of papers based on captive chamaeleons, such as those

4 ANNALS OF THE SOUTH AFRICAN MUSEUM

by Abel (1931), Angel (1933), Atsatt (1953), Busack & Busack (1967), Bustard
(1955, 1958, 1963, 1965, 1966, 1967a), and Von Frisch (1962), which are mostly
short and often report results differing from findings on field studies of chamae-
leons; a fact which only Bustard (1963) recognized might be true. A detailed
discussion of the literature is given in the relevant sections of this paper to which
they pertain.

A. Systematics

Knowledge of the life history and habits of our commonest reptiles,
particularly lizards, is meagre. To avoid confusion as to the life history of which
species or subspecies was examined, such studies should follow taxonomic
investigations. Nevertheless, in many instances life history studies may help
clarify systematics by providing clues to relationships, differences and simi-
larities between closely related taxa. Studies in different areas of a widely
distributed species’ range help to assess its adaptations to diverse habitats and
to determine the validity of recognized subspecies and perhaps the need for
establishing others.

The Family Chamaeleonidae (or Chamaeleontidae) forms the Infraorder
Rhiptoglossa, which, with the Infraorders Gekkota and Iguania (iguanids and
agamids), comprises the Suborder Ascalabota. The Suborder Ascalabota is
distinguished from the Suborder Autarchoglossa by the simple body muscu-
lature, tongue, and hemipenal structure and generally primitive character of
the squamation (Camp 1923). Among the Ascalabota the superior temporal
arch of Iguania distinguishes them from Gekkota. The acrodont dentition of
chamaeleonids and agamids is sufficient to set them apart from iguanids which
have pleurodont teeth.

Many Rhiptoglossa characters are shared with arboreal Gekkota (as partial
zygodactyly in Phyllurus; reduction of body musculature and hoop-like para-
sterna in Uroplates) and arboreal Iguania (variously independent eye mobility,
diverticulate lungs, prehensile tail, anterior pineal foramen, casque develop-
ment and colour lability in Agama, Anolis, Calotes, Chamaeleolis, Cophotis, Poly-
churus and Xiphocercus). ‘The Cuban iguanid Chamaeleolis chamaeleontides is most
chamaeleonid-like, with which it shares partly fused eyelids, cranial casque
development, and sluggish, deliberate movements (Wilson 1957). Only the
Iguania and Rhiptoglossa have developed high laterally compressed arboreal
forms. The only really distinctive Rhiptoglossa characters are the highly
specialized feet and vermiform, highly extensile tongue, which, in Boulenger’s
(1885-87) and Gadow’s (1901) view, justify their consideration as a separate
infraorder ; a view rejected by Romer (1956), Terentiev (1961), Mertens (1966)
and others, as so many characters on which the separation is based are shared
with others of the Infraorder Iguania in which these workers place the chamae-
leonids. Cope (1864) was the first to regard the Rhiptoglossa as related to the
Agamidae.

Saurians date back to the Upper Triassic; Upper Cretaceous lizards were

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 5

essentially modern (Carroll 1969). The fossil record yields no undoubted
chamaeleons, and those so assigned are based on jaw fragments with acrodont
teeth that could equally be assigned to the agamids, from which the cham-
aeleonids could be derived (Camp 1923; Romer 1956). Leidy’s (1873) Chamaeleo
pristinus from the Eocene of Wyoming is most similar to the agamid Calotes, and
thus not a chamaeleon. Camp (1923), Brock (1940), Malan (1946) and others
consider chamaeleons as primitive survivors of some ancient pro-agamid-
iguanid stock. Hillenius (1963, 1964) feels chamaeleons are of more recent
origin, as the most primitive forms (Chamaeleo chamaeleon and allies) not only
possess the characters one would expect in the hypothetical, ancestral chamae-
leon, but also occupy the periphery of the chamaeleonid range (cf. Matthew
1915; Mayr 1954, 1963; Tihen 1949). Shute & Bellairs (1953), Hamilton (1960)
and Schmidt (1964) have examined the inner ear structure of lizards to provide
clues to their relationships. ‘The latter two consider the chamaeleonid ear
primitive —agreeing with Camp, Brock, Malan and others as to chamaeleonid
affinities—whereas Miller (1966) thinks the chamaeleonid ear regressed or
degenerate and distinct, neither supporting nor rejecting derivation of this
group from the agamids, though the chamaeleon cochlear duct could conceivably
derive from regression of the agamid type. Thus, most modern evidence
indicates the distinctiveness of chamaeleonids, with possible close relationship
to the agamids, but rejects the hypothesis that chamaeleons are survivors of an
ancient pro-agamid-iguanid stock. This unsolved problem of chamaeleonid
origin and affinities is not of further concern. Chamaeleon taxonomy is sum-
marized below. 3
Terentiev (1961) recognizes 73 species of Chamaeleon (=Chamaeleo), Mertens
(1966) 113 species of Chamaeleo, including Microsaura. Chamaeleo has the tail
at least as long as the body, and smooth-scaled soles. Chamaeleo namaquensis is
a possible exception with its lamellate soles, partly fringed toes, and tail much
shorter or equal to body length. Mertens (1966) includes the five species of
Rhampholeon with the seven species of Brookesia (=Evoluticauda and Leandria,
Schmidt & Inger 1965). Brookesia and Rhampholeon have the tail shorter than
the body, and spinose-scaled soles, but Rhampholeon differs by having bicuspid
claws. Chamaeleo embraces the entire range of the Chamaeleonidae and is
found in Africa, Madagascar, India, Ceylon, southern Spain, Asia Minor and
Arabia; most are arboreal and oviparous. The exceptions are Chamaeleo
chamaeleon and C. namaquensis which are cursorial, even fossorial in desert
regions, and the C. pumilus and C. bitaeniatus groups which are viviparous.
Brookesia, sensu stricto, is confined to Madagascar and is ground-dwelling on
fallen leaves in forests. Rhampholeon (if a valid genus) is confined to tropical
African rain forests in shrubs and undergrowth. The adaptations of chamaeleons
show rigid specializations to an arboreal habitat, though some, as Brookesva,
sensu stricto, Chamaeleo chamaeleon, and C. namaquensis have secondarily reverted
to the ground. Chamaeleonids occur from sea-level to the Ethiopian Highlands
and Ruwenzori Mountains, inhabiting the littoral to at least the mean high

6 ANNALS OF THE SOUTH AFRICAN MUSEUM

tide limit (conflicts with Neill 1958), forests, grassland, semi-arid scrub and
deserts. Most species average 180 to 350 mm when fully matured (males
usually smaller), with extremes of two Madagascan species: Chamaeleo oustaleti
of nearly a metre, and Brookesia minima at 33 mm.

Chamaeleon taxonomy is confusing and best described as in a state of
flux. Apart from whether chamaeleonids should be lumped with iguanids and
agamids in the Infraorder Iguania or recognized as the separate Infraorder
Rhiptoglossa, the family name has been changed several times, principally
from Chamaeleonidae to Chamaeleontidae and vice versa, though there has
been a myriad of other names and various taxonomic changes.

Gmelin (1789) originally described the Cape dwarf chamaeleon as
Lacerta pumila, but Daudin (1802) renamed it Chamaeleo pumilus, when referring
it to the Chamaeleonidae. Gray (1864) recognized Chamaeleonidae as the
family name. In the same paper he renamed Chamaeleo pumilus, Lophosaura
pumila. However, Lophosaura was preoccupied by a group of South American
lizards Gray himself had previously described. Thoughtfully, Gray put the
viviparous melanocephala (now considered at most a subspecies of Chamaeleo
pumilus) into the genus Microsaura. Lophosaura was recognized as valid in subse-
quent taxonomic revisions, such as those of Methuen & Hewitt (1913), Hewitt
(1935) and Power (1932), but since a preoccupied name cannot stand and
since Microsaura melanocephala was later included in the pumila group, the name
Microsaura took precedence (FitzSimons 1943). Werner (1911), while con-
sidering Chamaeleontidae the valid family name, recognized Chamaeleon
(=Chamaeleo) pumilus, but not M. pumila. Matthey (1931) and Matthey &
Brink (1956, 1960) applied cytological technique to what they regarded as
chamaeleontids. They found male chamaeleons have no ‘Y’ chromosome, and
showed that Microsaura should not be considered apart from Chamaeleo and that
only one species (pumilus) was valid. Skinner (1958) noted the shoulder girdle
of Microsaura pumila (=Chamaeleo pumilus) was more like that of Chamaeleo
than that of Brookesia.

Hillenius (1959, 1963) has reviewed the genus Chamaeleo from morphological
considerations and co-ordinated these with the cytological findings of Matthey
(1931) and Matthey & Brink (1956, 1960). As far as the pumilus group is
concerned, these workers agree that: (1) Microsaura is invalid and referrable
to Chamaeleo. (2) There seems to be one species, Chamaeleo pumilus, and the
other Muicrosaura species and/or subspecies (e.g. caffer, damaranus, gutturalis,
Karrooicus, melanocephalus, occidentalis, taeniobronchus, transvaalensis, and ventralis)
are best considered no more than subspecies of Chamaeleo pumilus until more
detailed studies indicate the contrary. Furthermore, C. p. pumilus of the southern
Cape Province has more characters in common with C. melanocephalus than
with its subspecies C. pumilus transvaalensis. C. p. transvaalensis shares more
characters with C. v. ventralis, C. ventralis occidentalis and C. damaranus than with
C. p. pumilus. The hemipenes of C. pumilus are of the ‘cogwheel’ type as in C.
dilepis (Broadley 1971). The viviparous South African C. pumilus group is

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) g|

distinct from the viviparous East African C. bitaeniatus group. Therefore,
there is no validity in the arguments of Methuen & Hewitt (1913) and Power
(1932) for re-establishment of a separate genus (Lophosaura and Mucrosaura
as per Gray, 1864).

Hillenius (1959, 1963, 1964) investigated distribution of characters, not of
species, and showed that East Africa has the greatest number of characters,
and, hence, is the origin of Chamaeleo, with secondary centres in Madagascar
and West Africa. Away from East Africa the number of shared characters
diminishes. ‘Thus, while Madagascar has the bulk of chamaeleonid species and
the greatest variety of form and size, it is not the original home of Chamaeleo,
and chamaeleonids flourish there because of the absence of higher predators as
well as competitors. Hillenius (1959, 1963) showed that earlier taxonomists
wrongly assigned characters as ‘key’ because they had not studied the whole
group and often recognized species on few specimens, or even one, and in some
cases confused sexual dimorphism with their ‘key’ characters, which they often
did not apply uniformly, assigning females to one genus or species and the
males to another. Mertens (1966) endorses Matthey’s (1931), Matthey &
Brink’s (1956, 1960) and Hillenius’s (1959, 1963, 1964) views in determining
subdivisions of the form-rich and unwieldy Chamaeleo, and hopes the procedure
will be extended to Brookesia to better understand taxonomic relationships
within the chamaeleonids (or chamaeleontids). Mertens agrees recognition of
Microsaura is unwarranted until a study of all forms is made, and currently
validity of Microsaura cannot be recognized on purely nomenclatural views
alone. Mertens feels a study of the pumilus and dilepis complexes will raise
rather than diminish the 113 species of Chamaeleo. For this investigation, the
nomenclature of Daudin as validated by Hillenius and Matthey is endorsed.

A. Smith (1831) originally described the Namaqualand chamaeleon as
Chamaeleo namaquensis. Fortunately, C. namaquensis is harder to find than other
chamaeleons, thus largely escaping the taxonomic confusion perpetrated on
C. pumilus. After several questionable changes, Gray (1864) finally placed
namaquensis in its own genus, Phumanola. Werner (1911) placed namaquensis in
Chamaeleon. FitzSimons (1943), Hillenius (1959, 1963) and Mertens (1955, 1966)
call it Chamaeleo namaquensis. Hillenius (1959) feels that Chamaeleo namaquensis,
while previously considered as very isolated and not closely related to other
species, is in fact more or less related to the Chamaeleo chamaeleon group in
homogenous squamation, sometimes with scales in rosette-shaped groups, no
temporal crest, casque as Chamaeleo basiliscus (roof-shaped parietal crest higher
than lateral crests, elevated posteriorly, lateral crests stopping just after the
temporal region, no occipital lobes). Chamaeleo namaquensis’ dorsal knobs are
very similar to those of the Camerounian Chamaeleo wiedersheimi, whose position
is unknown because of insufficient material, but is similar to Chamaeleo nama-
quensis in several characters. Since Chamaeleo dilepis is in the Chamaeleo chamaeleon
group, its link with Chamaeleo namaquensis makes sense from the point of distri-
bution.

8 ANNALS OF THE SOUTH AFRICAN MUSEUM

B. Distribution and habitat

Chamaeleo pumilus is of southern African distribution, occurring from
Liideritzbucht, South West Africa (ignoring an introduced population at
Walvis Bay), south through the Cape Province and north through Natal to
the north-east Transvaal (FitzSimons 1943, 1965; Hillenius 1959; Mertens
1955, 1966). For an arboreal chamaeleon it is of ubiquitous habits and habitat,
inhabiting the extremes of desert shrubs of Namaqualand and the Karoo and
the high rainfall areas of the south-east coast and Drakensberg plateau.

Chamaeleo namaquensis ranges from southern Angola through South West
Africa from the Atlantic shore to the east of the Great Western Escarpment and
south through karoid parts of the Cape Province (FitzSimons 1943; Hillenius
1959; Mertens 1955, 1966). It inhabits arid and semi-arid situations, some of
which seem an unlikely ‘chamaeleon’ habitat. One of the few ground-dwelling
chamaeleons— Brookesia of Madagascan tropical rain forests is another—it is
one of two chamaeleons to invade strict desert. The other deserticulous
chamaeleon is the ubiquitous Mediterranean variety (Chamaeleo chamaeleon), to
whose group C’. namaquensis is probably related. Alexander’s (1838) description
of C. namaquensis at Walvis Bay still holds true for an introduction: ‘When
[approached] these cameleons [sic] . .. opened their mouths . . . and bissed like
angry snakes, whilst a bag under their mouth swelled to a great size, which,
with their dark blotched bodies, gave them a hideous appearance. They run
fast, and are accounted to be poisonous by the natives.’ Alexander’s description
is correct, for they can run at a quick walk and their high speed evasions make
flight a satisfactory escape for this chamaeleon.

This study was largely motivated by the virtual dearth of knowledge on
chamaeleon ecology. In essence, this paper presents two autecological studies
on the mesic-adapted Chamaeleo pumilus and the xeric-adapted C. namaquensis.
The problem of the role of body compression and colour change was investigated
in the field and in the laboratory, as was the dynamics of chamaeleon physio-
logical thermoregulation in maintaining these animals in thermal equilibrium
with their respective environments. A study of chamaeleon habitats was under-
taken to see if they were of ubiquitous or restricted habitat preferences. The
reproduction of the oviparous C. namaquensis and viviparous C. pumilus was
thoroughly investigated under natural conditions and supplemented with
laboratory records. A complete idea of chamaeleon reproduction was acquired
from courting to maturity of the young. The reproductive potential was
integrated with field studies on mortality, population dynamics, spatial
organization, and behaviour. A detailed investigation was made on nutrition
needs and prey items, and water and salt metabolism. The last study was
particularly interesting, since C. namaquensis inhabits the desert littoral, ingesting
food of high salt content, the salt being excreted via a nasal salt gland. The
study of adaptation to desiccation in both chamaeleons provided valuable
information on their respective solutions to water balance and water sources.

After preliminary field studies on chamaeleon requirements, conditions

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 9

for successfully maintaining captives were improved, allowing laboratory
findings to complement field studies. Since captive chamaeleons usually do
poorly, this casts considerable doubt on the acceptance of previous findings on
captives. Thus, in this study an attempt was made to integrate laboratory and
field investigations to give as complete an understanding of the ecology and
environmental adaptations of at least two chamaeleonids.

II. MATERIALS AND METHODS

A. Collecting and observational methods

Specimens of Chamaeleo pumilus were collected and observed from 13
January 1969 to 30 November 1970, chiefly at Stellenbosch, but also at Beaufort
West, The Strand, Van der Stel, and in the Cape Peninsula in the Cape
Province. They were readily found on garden shrubs, bushes, grasses, and on
reeds along the margins of various bodies of water in developed and undeveloped
areas.

Specimens of C. namaquensis were observed and collected during 1969 in
April, June, August and November, and in February 1970 in South West
Africa. Inland populations of C. namaquensis were investigated at Gobabeb,
Tsondab, Geluk Farm, Solitaire and Rehoboth, and coastal populations from
Walvis Bay north to Cape Cross.

C. pumilus and C’. namaquensis would not enter any sort of trap, requiring
employment of random and sector search methods. In the latter method, a
given area was intensively searched in the morning, collecting, taking data
from the animals present, while noting signs and marking the site. The after-
noon search sector was reached by walking to it via the morning sector, checking
on the markers to see any fresh signs or, hopefully, the animals themselves.
This method proved quite rewarding. These patrols were more or less straight
lines and selected through varied habitats. Return was by a parallel route. ‘The
maximum daily return distance covered was 25,75 km, the minimum 12,88,
the average 19,31. Shorter trips with observation points were also employed,
especially for social interaction, activity, and territorial studies. The sites to
which animals were retreating for the night were marked on the return after-
noon sector search, for later observations during the night. Binoculars were
employed for observing both species from a distance.

Animals were marked by branding an identity number on the proximal
ventrum of the tail, or by small identity number-bearing leg bands. Chamaeleons
were first cooled to render them comatose, and restrict peripheral circulation
to minimize bleeding when the number was applied with a sterilized surgical
blade. Both methods were durable and effective. A total of 165 (87 33, 78 99)
coastal and 42 (22 gg, 20 99) inland Chamaeleo namaquensis adults were marked,
and 107 coastal juveniles. A total of 494 (159 dd, 187 99, 148 juveniles) C.
pumilus were marked at Stellenbosch. These animals were never killed or
collected, serving as subjects for field territorial, behavioural, and reproduction

IO ANNALS OF THE SOUTH AFRICAN MUSEUM

studies. Reproduction data were obtained by palpating. Prey preferential
studies were also gathered from them by observation and scat analysis.

B. Thermal studies

A Wesco rapid equilibrium cloacal thermometer was used to obtain most
lizard field temperatures, though a Yellow Springs Instrument 46TUC Tele-
thermometer (probes YSI 402 body; 405 air temperature; 409 skin surface;
524 subdermal) was employed, occasionally in the field, and exclusively in all
laboratory studies on thermoregulation, metabolic, and cardiac rates. Since
colour change of chamaeleons is rapid and alters the skin temperature, all skin
temperatures must be recorded as rapidly as possible. ‘The telethermometer is
the superior instrument, since it records temperatures almost instantly, and
several probes can make simultaneous recordings. However, by simultaneously
calibrating telethermometer readings with those made by a thermometer, a
technique was devised to reflect most accurately all chamaeleon temperatures.
All skin temperature readings (first, side to the sun; second, side in the shade)
must be made as soon as possible, and precede cloacal readings. The skin
surface temperatures must be made in such a manner that the chamaeleon is
not greatly alarmed. For example, a pale chamaeleon on a hot day is reflecting
heat, and the temperature of the skin presented to the sun is at or near that of
the air temperature. If angered, such a chamaeleon goes uniformly black in
less than 1,6 seconds, and almost instantly absorbs heat (>3,0 C rise in skin
surface temperature within 30 seconds). Chamaeleo namaquensis and C. pumilus did
not evince more than alertness if approached slowly and skin surface tempera-
tures recorded gently. Though the cloacal temperature lags in reflecting the
skin surface temperature, all cloacal readings must be made within 10 seconds
of capture, and all readings employing a cloacal thermometer must be com-
pleted within 20 seconds, cloth insulating the chamaeleon during the reading
to eliminate temperature exchange between the investigator and subject. All
chamaeleon and environmental temperatures were recorded in the shade of
the author’s body. Data were not used from injured chamaeleons, those forced
to remain in the shade or open by the author’s activity, or those that were not
readily captured or overtly disturbed.

Various substrate and air temperatures were recorded in the field to
assess their bearing, if any, on chamaeleon body temperatures. Surface substrate
temperatures were taken by resting the recording instrument on the surface.
Temperatures at subsoil depths of 0,5; 2,0; 5,0; 10,0; 15,0; 20,0; 25,0 and 30,0
cm were taken by pushing the recorder down until the desired depth was
reached. Air temperature was taken at two metres (T,2m) and fifty millimetres
(T,50 mm) from the substrate surface, or what the animals were on. Environ-
mental temperatures (T’,) were the same as the T,50 mm reading in the case of
Chamaeleo pumilus. Environmental temperatures in the case of C. namaquensis
varied according to what the animals were on (rock, gravel or sand surfaces),
the vegetation-protected temperature of the substrate surface (T,), the vege-

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) II

tation-protected T,50 mm when in or on a plant, and the T, of the lee, crest,
or windward of hummocks. Details of weather, cloud cover, wind velocity and
direction, and sunrise and sunset were also recorded. All such weather data
collected from 13 January 1969 to 30 November 1970 were divided into ‘cool’
(April to September) and ‘warm’ (October to March) months, and further
subdivided into ‘fair’ (o-29% cloud or fog), ‘overcast’ (29-100% cloud or fog),
and ‘rainy’ weather lasting throughout the day. For coastal Namib readings,
the condition of early morning and late afternoon fog with clear midday skies,
necessitated the category of ‘partly overcast’.

A laboratory experiment of thermoregulation was designed to test the role
of body compression and skin colour in light and total darkness. A light-proof
temperature room (effective ambient temperature: —5,0 to 40,0 CG) was used,
so that the animals could be tested over the same temperature range in total
darkness and in light, and in light followed by dark and so on sequentially.
Radiant heat and light from a uni-directional source, as with the sun, was
employed, except in dark conditions when just heat was used. ‘Ten animals of
each species, two at a time (one of each species), were secured by tape to a
board (160 x 70 mm) in such a manner that they could compress and position
the body freely and stand up, stiff-legged, but not walk off. The board and the
animals were supported by a ring stand 300 mm from the counter surface.
Thirty-minute intervals at each temperature (— 4,5; 2,53 5,73 15,0; 17,03; 18,0;
25,03 30,0; 35,0; 42,0 C with light) (—5,0; 5,3; 8,6; 12,0; 13,8; 14,6; 20,3;
23,0; 30,1; 40,0 C in the dark) were used to conform with previous colour
studies, though results at ten-, twenty-, and sixty-minute intervals were virtually
identical. Trial runs were conducted for a week to allow the subjects to become
accustomed to the protocol. In the dark, instrument readings were made with
a flashlight, screened from the subjects. Ambient air temperature, skin surface
and chamaeleon body temperatures were recorded at each time interval, along
with notes as to body compression, skin colour, and behavioural state of the
subjects.

A second temperature test was set up in an outside enclosure (3 x 2 m) to
examine body compression and skin colour in thermoregulation under ‘natural’
conditions. The floor was red Namib dune sand 150 mm thick in which was
embedded a pot containing a small acacia plant. Ten specimens each of
Chamaeleo namaquensis and C. pumilus were used. The plant was provided for
C. pumilus, which will not climb down from, and is at ease when a raised object
is available. Adult C. namaquensis will not climb. Substrate temperatures were
recorded as well as the readings made in the previously described experiment.
Telethermometer leads were made sufficiently long enough to allow the animals
complete freedom of movement and action. Data from two animals of each
type could be recorded simultaneously. Five days were allowed for the subjects
to become accustomed to the set-up, followed by ten days of data-taking. Suitable
precautions were taken to allow as many animals as possible to be used with-
out causing territorial stress that would affect colour and compression changes.

12 ANNALS OF THE SOUTH AFRICAN MUSEUM

Preferred temperature tests were run on both species (18 Chamaeleo nama-
quensis, 20 C. pumilus) at ambient temperatures of 5,0 to 50,0 C in long, runway-
type cages 3X2 m which were placed horizontally for C. namaquensis and
vertically for C. pumilus, in order to house a small potted plant for the con-
venience of the latter. Red Namib dune sand arranged in banks of various
depths (50-300 mm), and scattered rocks provided shelters. ‘Thus, by such
arrangements, spatial behaviour of both forms was also realized. Instrumenta-
tion and readings recorded were as in the previously described experiments.
Preferred temperature tests were run for two weeks, after allowing the subjects
a week to get used to the arrangement and select space preferenda.

The role of the skin in mediating core temperature changes in chamaeleons
was examined at various ambient temperatures from 5 to 35 C at 10 degree
intervals. Water blebs were injected subdermally in ten Chamaeleo pumilus and
eight C’. namaquensis and subdermal thermistor probes inserted on both sides of
the body of each chamaeleon and another probe inserted into the large intestine
of each subject. Skin surface, subdermal, body, substrate, and air temperatures
were then read from the telethermometer at a given temperature interval, and
the colour of both sides of the body, body compression, and other notations
recorded. The same test was run on five dead and five live individuals of each
species to assess heating and cooling rates at a given temperature in live and
dead chamaeleons.

C. Metabolic rate studies

A device as described by Bailey, Kitts & Wood (1957) was employed and
their procedure followed, except that the equilibration time was lengthened to
thirty minutes. The value of this device is the ease with which oxygen con-
sumption can be measured at various activity levels over any time interval.

Chamaeleons struggle violently if restrained in a submerged vessel, so
telethermometer leads were made sufficiently long enough to ensure maximum
freedom of movement. Readings at rest were possible, and since the subjects
periodically sought active escape, various activity states could be measured,
such as torpor, sleep, awake but alert, and active. The animal vessel was
provided with a small twig for the convenience of C. pumilus.

Oxygen consumption from 5,0 to 45,0 C was measured, and apart from
40 to 45 G, ten degree temperature intervals were employed. Recording
instrumentation for temperatures was as in the previously described thermo-
regulation experiments. Air temperatures of both the animal and blank vessels
were recorded, as well as the body temperatures of the animals. Also recorded
were the respiration rates, body compression, and skin colour of the animals,
and when they commenced panting. At temperatures other than 20 C, a nearby
oven and refrigerator were used to hold, raise, or lower subjects’ temperatures
to the test level. A period of 205 minutes was necessary to bring C. namaquensis
body temperatures down from 20 C to 5,0 C and 100 minutes for C. pumilus.
Sixty minutes were needed to raise C. namaquensis body temperatures from 20 to

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 13

4o C and 35 minutes for C. pumilus. Difficulties were encountered bringing
C. pumilus, except for two, to 45 C. Fifteen C. pumilus ranging from 5,1 to 24,7 g
(K = 11,4); and 15 C. namaquensis ranging from 49,3 to 113,4 g (X = 76,1) were
used. Rehearsal runs were conducted for a week to allow subjects and experi-
mentor familiarization with technique and equipment. Recordings were made
from 08:00 to 18:00 hours, with test temperatures temporally varied to eliminate
any circadian rhythm effects. Results were corrected to standard temperature
and barometric pressure.

D. Cardiac rate studies

The relationship of chamaeleon heart rate to temperature was also
investigated. Five C’. namaquensis (71,6-115,0 g; X = 80,0) and five C. pumilus
(6,0-26,0 g; X = 13,0) were used. Ten degree temperature intervals from 5,0
to 45,0 CG were employed, animal body temperatures being held, raised, or
lowered as previously described. During experimental runs, a pan containing
ice was placed under the subjects to keep ambient temperatures low, and a red
lamp 0,5-1,0 m away was employed for higher temperatures. A small twig was
necessary for the C’. pumilus to cling to. The animals were placed in a container
660 x 300 X 300 mm open to the experimentor on one side. Body and air
temperatures were monitored as in the previously described experiments, and
a Stanley Cox Electrocardioscope (Med 158) recorded heart beat. Familiariza-
tion runs were conducted for a week for the specimens to become used to the
procedure.

E. Food studies

In calculating the amount devoured by 25 captive Chamaeleo namaquensis,
35 captive C’.. pumilus, and chamaeleons in the field, food was measured by
volumetric water displacement and arranged by size from very small (< 0,25 ml;
2-3 mm long), small (0,25 ml; 10 mm long), medium (0,75 ml; 20 mm long),
large (2,0 ml; 30 mm long), to extra large (4,5 ml; 54 mm long), respectively
Food Indices 1-5. Marked prey was given to chamaeleons at different times to
determine rates of passage.

Prey taken by wild chamaeleons was studied by sacrificing the following:
C. pumilus (February, 6 29, 3 3; March, 6 99, 6 gg; April, 9 29, 8 dg; May,
8 99, 833; June, 10 99, 6 3d; July, 10 99, 5 dd; August, 7 99, 8 3d; September,
25 605 October,7 22, 3:\g3; November, 5 99, 5 dd; December, 6 29,
4 $3; January, 5 99, 4 dd; 1969-1970), and C’. namaquensis (April, 9 99,
5 dd; June, 14 99, 9 gd; August, 5 99, 4 3d; November, 11 99, 6 gg; February,
11 99, 6 gg; 1969-70). Animals were collected in the morning and afternoon
when they were adjudged to have eaten, but not yet digested their meal.
Chamaeleons were killed by decapitation and then preserved in 70% alcohol,
with exact date, time, and locality. Length of the stomach, small and large
intestine were measured in millimetres with Vernier callipers or measuring
dividers. Stomach contents were removed, weighed on a Mettler H1oT balance

14 ANNALS OF THE SOUTH AFRICAN MUSEUM

and placed in vials with identifying labels for future analyses. Scats provided a
valuable source of prey information for both species, particularly C. namaquensis.
C. namaquensis scats are large (up to 60 mm long) and very distinct. ‘They last
in the wind and shifting sands for about three days, though only those no more
than two days old were taken. Fresher ones formed the bulk of scats examined.
Scats were collected and processed in the manner previously described for
stomach contents. The percentage of items in stomach contents and scats was
calculated by volumetric analysis. Endoparasites were also removed from the
digestive tract, placed in 70% alcohol and sent to Dr Prudhoe of the British
Museum (Natural History) for identification.

F. Water and salt balance studies

Ten Chamaeleo namaquensis (17,8-90,1; X = 58,1 g) and ten C. pumilus
(6,4-12,4; X = 9,2 g) were fasted but hydrated for 24 hours prior to use in a
desiccation study. They were then weighed on an Ohaus animal scale and placed
one each in glass desiccation chambers (0,20 m diameter) in zero per cent
humidity created by silica blue gel crystals below and separated from the
animals. ‘The lips of the chambers were sealed with silicon grease. A small twig,
pre-dried in an oven, was provided for the C. pumilus to cling to. The test was
run for seven days at 25,0 C +1,3 in a temperature room, the chamaeleons
subjected to eight hours of light per day. Faeces and uric acid were removed
daily and weighed (Mettler H1oT balance). Wastes were removed early in the
morning at such time when fasting chamaeleons always had eliminated. Each
chamber was aerated daily. At the end of seven days, all animals were weighed
and a half of each species group were killed. Blood samples were taken from
this dehydrated group in haematocrit capillary tubes and centrifuged on a
clinical centrifuge at 2500 rpm for thirty minutes. A second blood sample,
taken in polyethylene microtest tubes, was centrifuged at 10 000 rpm for five
minutes to obtain plasma for freezing point determination of osmolality. The
remainder of each species were given as much water as desired and the following
day weighed and killed, the previously described procedure for the dehydrated
group being followed.

A separate study lasting twelve days examined survival with food but no
water. The animals were placed in a separate cage maintained at 25,0 C +3,2;
and 40-50% humidity. Eight C. pumilus (6,1-14,9; % = 9,7 g) and seven C.
namaquensis (36,0-91,4; X = 61,7 g) were weighed at the start, every third day
and at the conclusion of the study. Faeces and uric acid were collected as soon
as they were eliminated and weighed as previously described, and blood and
plasma taken as previously from two C. pumilus and two C. namaquensis on the
twelfth day. The survivors were dehydrated and body weights taken daily as
were the weights of any droppings. At day 15 the survivors were killed, being
processed as previously described.

Blood was similarly taken from seven freshly caught C. pumilus, and seven
inland and ten coastal C. namaquensis for haematocrit and osmolality plasma

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 15

determinations. For C’. pumilus analysis was immediate, but for C. namaquensis,
except for haematocrits, analysis was one to three days after capture.

The osmolality of chamaeleon plasma was determined by measuring the
comparative melting point against standard solutions (100; 325; 500 and goo
mOsm) in the manner of Gross (1954).

The exudate from the nares of Chamaeleo namaquensis suggested the presence
of a nasal salt gland, the nature of which was grossly examined but not so
histologically. An exudate sample was examined by Dr V. Wolfe, Department
of Chemical Pathology, University of Stellenbosch, using a flame photometer.

G. Territorial and population studies

The method employed for the iguanid Uta stansburiana hesperis (Burrage
1966) was adapted for chamaeleon territorial studies and was especially
valuable for Chamaeleo namaquensis. This method allows territorial investigations
and population structure to be studied together. Close daily observation
throughout the day gave an accurate picture of the spatial arrangement of
chamaeleons, not only in regard to the extent of the territory of individuals,
but also those parts most used. The open desert facilitated distant observations
by binoculars from a vantage site. Points visited by a chamaeleon were marked
at the site, the lizard’s number, sex, and date being printed on a marker in
waterproof ink. The points were simultaneously plotted on a scaled map on
graph paper of the given area. The denser the dots, the greater the activity of
the lizard within a given part of its occupied area, and the peripheral dots on
the map and site markers gave the exact area. Connecting the outlying dots
gave the periphery of the territory, the area of which was then computed with
a planimeter from the graph paper. Territorial conflicts and social interactions
were marked on the site on which they occurred and on the graph paper to
determine usage of a given territory and which part(s) were most vigorously

defended.

H. Reproduction studies

Those Chamaeleo pumilus and C. namaquensis used in food studies also served
for anatomical examinations of reproductive state. Each chamaeleon was
tagged with the date, precise locality of collection, and observational data.
Chamaeleons were weighed on a Ohaus animal scale and then killed, where-
upon various measurements were taken with measuring dividers. All C. pumilus
and most C’. namaquensis were freshly dissected and their reproductive structures
studied. Those C’. namaquensis not studied immediately after death, were stored
in 70% alcohol. The maximum delay in examination was seven days. The
chamaeleons, their reproductive structures, embryos (pumilus), eggs (namaquensis)
were measured with Vernier callipers or measuring dividers in millimetres. ‘The
reproductive structures were weighed on a Mettler HioT balance. These
excised parts were fixed in 10% and preserved in 4% formalin. Routine
histological techniques were carried out on some of these reproductive tissues

16 ANNALS OF THE SOUTH AFRICAN MUSEUM

which had been embedded in paraffin wax. Sections were cut to 5 or 8 uw and
stained with haematoxylin-eosin, or azo-carmine and azan.

In order to examine the role of the fat bodies in reproduction, a group of
six Chamaeleo pumilas and four C. namaquensis females and four males of each
species had their fat bodies excised. Four controls in each species category group
were sham-operated. The animals were cryo-anaesthetized and kept comatose
during the operation by being placed ventrum up on a plastic bag filled with
crushed ice in which was moulded a hollow to accept each subject. Sterile
instruments and technique were employed. Cautery sealed the severed areas,
and sterilized adhesive ‘butterflies’ closed the wounds.

In order to examine the role of the corpora lutea, five pregnant female
Chamaeleo pumilus had their corpora lutea excised, with another five sham-
operated as controls. Four gravid C’. namaquensis had their corpora lutea excised,
with an additional four sham-operated as controls. The operative technique
was as previously described for fat body excision.

III. REsuLTs AND DiscussION

A. Habitat of Chamaeleo pumilus

Chamaeleo pumilus inhabits any vegetation guaranteeing a plentiful and
sustained prey source, such as flowering bushes and hedges, grasses, supratidal
bushes and grasses, and especially reeds surrounding stagnant bodies of water.
C’. pumilus was observed in the Cape Province, in the southern Namib Desert at
Port Nolloth, the semi-arid Karoo at Leeu-Gamka and Beaufort West, and the
south-west Cape winter rainfall area at Stellenbosch, Van der Stel station, and
The Strand. The vegetation at Port Nolloth is West Coast Strandveld, con-
sisting of open, semi-succulent scrub of Fynbos form and intermediate between
the Coastal Fynbos and the Succulent Karoo. The Karoo vegetation is complex,
consisting of succulents, and semi-arid shrubs. The winter-rainfall area has
evergreen shrubs, with a variety of grasses and other annuals. A full discussion
of the vegetation of all these areas is given by Acocks (1953).

B. Description of study stations of Chamaeleo pumilus

Stellenbosch is situated in gently rolling lowland at the mouth of the
Jonkershoek Valley. Data were taken from Chamaeleo pumilus inhabiting the
University of Stellenbosch Botanical Gardens, suburban hedgerows and
gardens, which are planted with many exotics, and from the Marais Park with
natural shrubs. C. pumilus was also studied in vegetation surrounding freshwater
bodies, roadside and railroad right-of-way ditches (Fig. 1), where reeds,
mostly Phragmites, predominate. Van der Stel station and The Strand occupy
inland and coastal situations respectively, on the gradually seawards sloping
base of the Hottentots Holland range. C. pumuilus is abundant in the reeds along
the railroad right-of-way at Van der Stel station, and supratidally on the
backshore shrubs and grasses at The Strand.

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 17

Weather data for the principal study station of Stellenbosch are presented
in Table 1, from data provided by the Geography Department of the University
of Stellenbosch. During 1969—70 rainfall was approximately two-thirds normal,
though the preceding years had average precipitation. Stellenbosch has a
winter-rainfall climate with the bulk of the rain falling in winter, though not
entirely limited to it. North-west winds bring rain; south-westerly clearing with
showers to fine; south-easters are strong winds.

Table 1. Weather data for Stellenbosch, Cape Province, Republic of South
Africa (source, Geography Department, University of Stellenbosch).
Temperatures are in degrees Celsius; rainfall in millimetres.

‘Temperatures
Absolute Mean Monthly
Max. Min. Max. Min. Mean Rainfall

1969

january 92. = 3337 8,5 26,0 13,2 19,6 41,9

Hebruary = =. =. °36;0 0,4 28,1 14,3 21,2 23,5

Marchi =: 5 <1 41,1 955 27,6 14,4 21,0 38,5

EXOT ese te | 20,6 4,1 20,9 10,3 15,6 4559

Mayet. 2...) 2650 355 20,1 6,6 BB Teja

umes te). 26,6 reg 16,6 6,4 11,5 91,3

ulyeree . 2 . © 25,6 1,0 16,5 5,1 10,8 71,9

FAUSUSE se =. |. | | 2054 2,0 18,2 7,0 12,6 85,6

September ae OX) 1,0 18,0 5,6 11,8 88,4

October ~.)'. §. "94,4 6,5 20,5 9,9 15,2 66,1

iNevermber=- = 35 3353 6,0 24,0 10,2 1G 16,7

Wecember = 85 .. 36,7 7,0 7G 12,8 20,0 8,0
1970

Nanuary |. . = 37,8 10,1 28,5 13,9 21,3 8,9

The native vegetation is macchia shrub of Coastal Rhenosterbosveld
(Acocks 1953), of which rhenosterbos (Elytropappus) is distinctive. There is a
variety of undershrubs, grasses, and other annuals. On beaches and disturbed
areas succulents such as Mesembryanthemum predominate. Over the years much
native vegetation has been destroyed and the area planted with exotic trees.

Reptiles preying on Chamaeleo pumilus are discussed in the predation
section (see p. 32), and this discussion deals with co-inhabiting reptile com-
petitors of C. pumilus. The most important reptilian competitor of C. pumilus is
the skink Mabuya capensis, which is of ubiquitous habits and, while primarily
ground-dwelling, frequently ascends into and hunts prey in shrubs inhabited
by chamaeleons. It appears less in evidence in grassy and reedy areas, where it
does not climb into such vegetation. A large skink might prey on any newborn
C. pumilus encountered. C. pumilus was rare in exotic montane conifers, but was
common in such trees in lowland areas. Montane conifers are abundantly
inhabited by geckos (Phyllodactylus), which might prevent C. pumilus from
successfully invading this niche. However, montane areas might represent
marginal habitat to C. pumilus, since the largest concentrations of chamaeleons
in uplands were limited numbers on shrubs on sunny slopes and streamside
vegetation.

18 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 1.
Chamaeleo pumilus habitat on reeds, mostly Phragmites, growing in ditch beside railroad right-of-way
(Stellenbosch goods yards).

C. Habitat of Chamaeleo namaquensis

Mr John Visser found a large Chamaeleo namaquensis on the road near
Laingsburg, Cape Province, and it is recorded from the arid and semi-arid
(Fig. 2A) portions of the Cape Province. The author studied them in the most
arid part (that between 18° to 29° South latitude) of the central Namib Desert
(Meigs 1966) of South West Africa along the coast from Walvis Bay north to
Cape Cross, in the interior at Gobabeb and Tsondab, the edge of the Great
Western Escarpment at Geluk Farm and Solitaire, and the South African
Plateau highlands at Windhoek and Rehoboth. The geography and other vitae
of this area are given by Meigs (1966), Koch (1961), Logan (1960), Schulze
(1969) and the South West Africa handbook (1971-2); the first three containing
pertinent literature to more detailed studies. The plateau and Great Western
Escarpment are better-watered, supporting grasses and scattered thorn trees
(Fig. 28) on the uplands and steppe along the escarpment. Vegetation rapidly
becomes sparser farther west to the Atlantic, and in the true Namib is meagre
and may be absent. Around mountains, and along watercourses the ‘luxuriance’
of vegetation varies according to the water supply from riverine forest along
the Kuiseb River to a better showing of succulents along washes.

D. Description of study stations of Chamaeleo namaquensis

The principal study areas were the coastal central Namib Desert from
Walvis Bay to Cape Cross, based at Swakopmund, and the interior, based at

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 19

the research station at Gobabeb, 120 km south-east of Walvis Bay and about
58 km from the Atlantic. Sorties were made to surrounding areas from these
bases. General descriptions of these regions are given by Logan (1960), Koch
(1961) and Meigs (1966). Dunes, mountains and gravel plains are the principal
biotopes, with special biotopes of hygrophilous or halophilous strata, for
example, river beds and pans.

That part of the littoral Namib (Fig. 54) studied is primarily sandy beach
with occasional outcrops of the underlying Namib bedrock platform, and
massive deposits of fly-infested tidal wrack. The backshore is a monotonous
expanse of soft, dirty gray-white gravel, virtually devoid of plants. South of the
Swakop River are dunes lying east of the coastal rail line, over which they
occasionally drift. Proximal to the beach are small (about 10 m high), whitish
gray seif dunes devoid of vegetation. Further inland, especially near Walvis
Bay, the coastal dunes (Fig. 64) are considerably larger (about 200 m high),
yellow, and support sparse vegetation.

The north bank of the Swakop River consists of barren, flat-topped
limestone bluffs (Fig. 68). The base of this outcrop has a skirting deposit of
wind-blown dune sand. Away from the outcrop is the monotony of the feature-
less gravel plains (Fig. 58) unbroken except for slightly indented meandering
washes. Farther north the monotony of the gravel plain is broken by broad-
based, narrow-ridged outcrops of black diorite and white dolomite. South of
the Swakop River gravel plains form corridors between dune ridges.

The Swakop River bed (Stengel 1964) consists of river channel, flats
(Fig. 4B) and varied sized hummocks (Fig. 7A) of whitish sand. These river
hummocks may be single or inter-connected as a miniature mountain range.
Stengel’s Map 1 graphically shows the area of dune hummocks (Fig. 7B) in
the Swakop River bottomlands, which mostly lie south of a 1,3 m high bank and
the coastal dunes. These hummocks are composed of wind-blown dune sand and
are of varied size, but not as large as the river hummocks, nor interconnected.
Dune hummocks reach a maximum height of 2,3 m and river hummocks 3,5 m.

At the principal central Namib Desert interior site of Gobabeb are located
featureless gravel plains, with occasional granitic outcrops (Fig. 34), large reddish
dunes (Fig. 3B), with basal vegetation (mostly Aristida grasses), the riverine forest
of the Kuiseb (Fig. 4a), granitic mountains (Fig. 34), such as Zwartbank and
Rooikop, and sandy flats, with scattered grass clumps. Further descriptions of
the physiography are given by Logan (1960), Koch (1961) and Meigs (1966).

Table 2 gives air and substrate temperature data for the coastal and
interior central Namib and is derived from data collected by the author, those
collected at Swakopmund by Mr Moisel for the Namib Desert Research
Station, and by the Namib Desert Research Station at Gobabeb for the interior.
These data are in addition to those made for environmental and body tempera-
tures collected for the chamaeleons, and thus there are some differences.
According to the South West Africa handbook (1971-2), Swakopmund has an

average yearly precipitation of 16,2 mm over 40 years of records; heavy rains

20 ANNALS OF THE SOUTH AFRICAN MUSEUM

Figs 2-7.
Habitats of Chamaeleo namaquensis. Leeu-Gamka, Cape Province is also a habitat of C. pumilus.
All other photographs were taken in South West Africa.

Fig. 2A.
The Karoo in the region of Leeu-Gamka, Cape Province, Republic of South Africa.

Fig. 2B.
Scattered thorn trees on grassland of South African Plateau in vicinity of Rehoboth.

Bigs QA.
Outcropping of white weathered marble and black dolerite, Zwartbank Mountain, breaks
featureless gravel plain of Namib Outer Platform.

Fig. 3B.
Base of large, red inland dune near Gobabeb, showing heavily overgrazed Aristida sabulicola
hummock in right foreground. Hummock in left centre is a ‘narras’ (Acanthosicyos horrida).

Fig. 4A.
Kuiseb River bottoms with Eragrostis spinosa grass and Acacia giraffae and A. albida trees in the
background. Large dunes form backdrop.

Fig. 4B.
Mud-cracked channel in stream-deposited gravel flats of the Swakop River. In the right centre

is a Chamaeleo namaquensis. Nasal salt exudate appears as a small white spot on the chamaeleon’s
nose.

Fig. 5A.
Namib littoral at mouth of Swakop River, showing deposits of tidal wrack and other debris.
C. namaquensis forages seawards at least to the tidal wrack.

Fig. 5B.
Featureless gravel plain near Swakopmund forming a street between dunes. Small Zygophyllum
stapffi bush just visible at foot of dunes at right.

Fig. 6A.

Near Swakopmund, vegetationless coastal dune, on lee slope (slip-face) of which a chamaeleon
was discovered with body temperature of 34,2°C (sand surface temperature, 67,0°C).

Fig. 6B.

Limestone outcrop on north bank of Swakop River, showing its barren flat-top. Small black
dots are plants.

Fig. 7A.
River hummocks in bottomlands of Swakop River. Note inter-connected nature and larger size
of this hummock type. Eragrostis spinosa grass forms partial cover.

Fig. 7B.
Dune hummock region. Predominant hummock vegetation is Eragrostis spinosa grass, Trianthema
sp. and <ygophyllum stapffi. A single Nicotiana glauca is in right foreground; Tamarix austro-africana
in left background on foot of dune, and a ‘narras’ (Acanthosicyos horrida) on foot of dune in distant
left centre.

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 21

SRS
S Ss

EGQCEE[E[’

22 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 3B.

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 23

Fig. 4A.

24 ANNALS OF THE SOUTH AFRICAN MUSEUM

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 2255

LOA SSN
ESA

96. ANNALS OF THE SOUTH AFRICAN MUSEUM

SSESN

Ss
SS

SESS

SRS
Ss
.

SAG

AN ~
ASSES
SERS

~

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 77)

of 42,1 mm fell in 1969, with 41,3 mm falling in March alone, and as little as
0,4 mm in 1959. The Namib Desert has very little rain of erratic distribution,
the causes of which are reviewed by Logan (1960) and Meigs (1966). Inland
areas are both wetter (more rain) and drier (lower humidity) than coastal
locales. Fog is a persistent and normal feature of the Namib Desert, especially
along the coast, but its effect reaches far inland (at least 200 days per year,
58 km from the coast). The moisture realized from fog far exceeds that from
rain, as demonstrated by Walter (1937), who in one month collected more than
250 litres of water condensed from fog on the inclined roof (60 m? in area) of
a house in Swakopmund. The immense, similarly inclined plane of a dune must
collect far more water, and percolation down and outward at the base explains
the richer vegetation of inland dunes.

Table 2

Weather data for coastal and inland locales of the central Namib Desert. Temperatures are in
degrees Celsius. Means in parentheses.

Substrate temperatures

Surface At 50 mm depth
Location and month Air at2m _ Dune sand Gravel Dune sand Gravel
1969
Coastal . 14,7—27,0 19,0—55,0 18,4-47,0 18,7—56,0 19,0—48,0
April. (19,1) (30,0) (24,5) (33,4) (26,8)
Inland 7,0-38,0 8,0-48,5 8,0-46,0 9,0—50,0 8,0-47,0
April. (25,5) (31,5) (25,6) (28,5) (27,2)
Coastal . 6,0—-35,0 8,0-35,0 8,5-33,0 8,0—35,0 9,0—33,0
iene. (15,0) (27,5) (20,0) (21,8) (20,0)
Inland 4,0—35,0 6,0-38,5 55-36,5 6,6—43,0 6,3-42,0
June . (19,9) (25,5) (23,7) (27,6) (26,8)
Coastal . 16,1-25,5 17,4-48,0 16,2-43,0 17,0-42,3 17,5-42,5
November (19,9) (33,1) (30,3) (34,3) (31,3)
Inland 12,0—36,5 20,0—52,0 21,0—49,0 25,7—49,0 21,0—50,0
November (24,4) (37:3) (30,6) (36,7) (32,7)
1970
Coastal . 16,8-34,0 19,9-67,0 19,7-45,0 20,3—70,0 19,5-45,0
February (23,1) (36,6) (31,5) (39,6) (31,1)
Inland 10,3-42,5 14,0-83,0 14,0—80,0 14,0—85,0 14,0—-83,0
February (26,6) (43,7) (40,0) (45,0) (43,3)
x Coastal 19,3 31,8 26,6 3203 P75)
x Inland 24,1 34,5 30,0 34,7 32,5

Data from personal records and the official records of the Namib Desert Research Station.

The daily fog regimen is well discussed by Logan (1960). Fog may be low
or medium altitude, but drizzly ground fogs are frequent. Fog generally clears
by mid-morning between 10:00 and 12:00 hours, returning by 15:00 hours, but
varying with the time of the year, since in winter the sun is weaker and less
vigorous in dissipating or preventing the return of fog. Indeed, some days the
fog persists throughout. Another oddity is that maximum yearly temperatures
along the coast coincide with the occurrence of the east wind in midwinter

28 ANNALS OF THE SOUTH AFRICAN MUSEUM

(Logan 1960; Meigs 1966). In 1969 a June east wind gave a maximum of
33,9 C and in July 33,6 C, though winter 1969 was cooler and drier than
normal. In January 1970 a midsummer maximum of 27 C was recorded, with
no east wind condition. Logan considers east winds of rare occurrence. Winter
minimums along the coast are to 6 C in June and July, about twice that in
midsummer. Low maximum temperatures under fog were 11,4 C in July;
18,4 C in December; the corresponding lows for these days were 9,5 C and
14,5 C respectively, demonstrating the temperature insulating effect of fog.
There is less temperature range in summer than in winter, though conditions
do not vary greatly along the coast. The greatest temperature range is in winter
with an east wind condition.

In summer, coastal winds are mostly northerly or north-westerly, often
accompanied with drizzle when from the latter direction. Winter winds are
southerly or south-westerly. Humidity is closely related to temperature,
presence of fog and proximity to the Atlantic, being at or near 100% with low
temperatures and fog. Near the coast humidity rarely falls below 90% even in
the absence of fog cover. East winds drop humidity to 30%. Duration of fog
and degree of humidity is less even a short distance from the coast, such as
Swakopmund airport 1,8 km from the Atlantic, and lessens still further inland.
Walvis Bay, partly protected by Pelican Point from the effect of the ocean,
has conditions similar to Swakopmund airport and far less fog than at the
Swakopmund lighthouse.

Fog has an effect at Gobabeb, but usually burns off sooner and returns
later than along the coast. Air temperature minimums are lower and maximums
higher at Gobabeb than at Swakopmund (Table 2). Though humidities of
100 % occur, usually coinciding with fog, humidity tends to be lower at Gobabeb
and as low as 5°% with east winds. Other weather conditions are essentially
as described for coastal sites, and are fully discussed for Gobabeb by Schulze
(1969) and generally discussed by Logan (1960), Koch (1961) and Meigs (1966).

There is no great difference in dune sand and gravel substrate tempera-
tures, other than for locality of both (Table 2). On dunes proper a considerable
variation was apparent as to site and time of temperature data collected. For
example, lee faces were hottest until such situations were shaded, when the
crest was hottest. On winter afternoons dune lee faces are shaded earlier in
the day. Dune temperature data have been omitted in this study, but Louw
& Holm (1972) discuss these in detail in their study of the ecology of Aporosaura
anchietae. Chamaeleons did not purposely seek cooler or warmer substrates or
situations, as Warburg (1964) reported for vipers and Burrage (1966) for utas.
Chamaeleons sometimes sought wind-protected sites to the lee of small objects.
Burrage (1966) found a tremendous difference in thermal and textural qualities
of nearby substrates and a consequent effect on the overall ecology of utas.
Namib dune sand and gravel have an unfavourable heating gradient, barely
heating under overcast conditions, when the substrate temperature approxi-
mated that of the air at 50 mm. Under clear skies dune sand and gravel heated

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 29

rapidly to high levels, and cooled equally rapidly. Strong, sustained wind
also depressed substrate surface temperatures. Because of this it is an advantage
for Chamaeleo namaquensis that, thermally speaking, it is less dependent on the
thermal qualities of the substrate than most reptiles. Schulze (1969) discusses
the soil (gravel) thermal regimen at Gobabeb.

Logan (1960) and Koch (1961) give general consideration to Namib
Desert flora, but Giess (1962, 1968) considers this in greater detail. Giess
(1962) divided the Namib Desert flora into: (1) red dunes; (2) Kuiseb and
Swakop Rivers; (3) Namib Flats north of the Kuiseb River stretching to the
mountainous area of the Swakop Canyon and farther north from the Swakop
River; (4) the mountains, such as Zwartbank, Vogelfelderberg, and isolated
granitic koppies arising from the flats.

According to Giess (1968), coastal plants have a cushionlike shape due
to wind and sand and assist in formation of small secondary dunes of varied
height. Beach flora consists of Pszlocaulon salicornioides, < ygophyllum clavatum,
Salsola aphylla and occasional S. nollothensis. On the gravelly flats just inland of
the strand are very scanty, widely scattered <ygophyllum stapffii and Arthraeura
leubnitziae. Because of salt or gypsum, large tracts of these flats are barren.
Eleven kilometres north of Swakopmund near Wlotzka’s Baken great diorite
boulders and stones shelter a richer flora, with Drosanthemum paxianum, Ruscha,
Tetragonia arbusuloides and lichens. Sufficient rainfall permits growth of annuals.
The gypsum plains have a rich growth of colourful lichens.

In dune regions the ‘narras’ (Acanthosicyos horrida) gives a thorny refuge
to pursued reptiles. A few narras plants were found on the northern extremity
of dunes at Swakopmund, though it is commoner on Gobabeb dunes. Large
tufts of Aristida sabulicola are terribly overgrazed near the Kuiseb River in the
Gobabeb area. Aristida sabulicola normally form hummocks on dune bases,
the usually unharmed grass reaching heights of 1,5 m. Acacia giraffae trees
occur on dunes near the banks of the Kuiseb River. Tamarix austro-africana
(3-5 m high) are the commonest trees on the low dunes bordering the Swakop
River. Both trees are frequently in various stages of burial by the shifting dunes.
There are clumps of Trzanthema sp. on small dunes.

The Kuiseb River has a distinct riverine forest, with large stands of
Acacia giraffae and some Acacia albida. Tamarix austro-africana also occurs, but
is virtually the only tree in the Swakop River region investigated. Density,
variety and size of trees increase upstream. ‘The exotic Nicotiana glauca is very
common in the Kuiseb and Swakop River beds and bottomlands. Salvadora
persica thickets line the banks of the Kuiseb River. Grasses consist of Eragrostis
spinosa, singly or in thick stands, Aristida sabulicola (commoner in the Kuiseb
River), and Cynodon dactylon and Odyssea paucinervis are found in damper spots.
In the Swakop River Trianthema sp. occurs singly in clumps or forms low,
broad-based hummocks, resembling hummocks formed by Cynodon dactylon.
After floods and rains, a variety of annuals and especially pretty flowers
appears in these areas.

30 ANNALS OF THE SOUTH AFRICAN MUSEUM

The Namib Flats, or gravel plains, are practically devoid of vegetation
along the coast and for approximately 12-18 km inland. About the only vege-
tation are sparsely scattered <ygophyllum stapffit (0,25—0,5 m high), and Arthraerua
leubnitziae, occasionally forming small hummocks. < ygophyllum stapffi is the only
large plant on the barren limestone outcrop on the north bank of the Swakop
River. Aizoaceae occur in the watercourses along with <. stapffu. Lichens are
also present. Welwitschia occurs in this biotope. Farther inland appear shrubs
such as Sutera canescens, Citrullus eccirhosus, the very small Acacia reficiens, Asclepias
filtformis, and the larger Parkinsonia africana.

The mountains have a richer vegetation, especially of succulents, due to
greater moisture from fog condensing on stones. Four succulents, one her-
baceous Euphorbia, and an Aloe are recorded by Giess (1962). Lichens are
also very abundant.

Mertens (1955) gives an excellent review of the reptilian co-inhabitants
of Chamaeleo namaquensis. No information is available on the reptiles that
directly compete with C. namaquensis, but the larger species of the lacertid genus
Meroles do eat mainly tenebrionid beetles, which also form the bulk of the
chamaeleon’s diet. However, there is no information that either lizard eats
exactly the same species of tenebrionids, and selection of different tenebrionid
species by each lizard may not place them in too great a degree of competition
with each other for this food. Chamaeleo namaquensis is the more ubiquitous
saurian, while most Meroies species are restricted to sandy situations. Where
Meroles and Chamaeleo co-inhabit, the lacertid is the more numerous. But greater
population density of the lacertid does not necessarily mean it is the more
successful saurian. The lower population density of the chamaeleon may be
due to factors other than competition between these saurians. Furthermore, the
population density of C. namaquensis does not greatly vary in all the diverse
habitats in which it is found. |

It seems that smaller reptiles chanced upon by Chamaeleo namaquensis
are potential prey for it; the larger reptiles, potential predators of it. The only
lizard that could prey on C. namaquensis is Varanus, which occasionally ventures
from the Great Western Escarpment along the rivers into the barren desert.
Chamaeleo namaquensis lives in the Salvadora persica thickets, which are also
frequented by large cobras (Naja). Bitis caudalis may prey on C. namaquensis.
Smaller snakes, saurians and sometimes geckos (Rhoptropus), are eaten by C.
namaquensis. ‘The nocturnal geckos, for example, Ptenopus and Palmatogecko,
should be safe from Chamaeleo namaquensis because of their habits. Palmatogecko
tracks were observed on the dune sand skirt of the limestone outcrop on the
north bank of the Swakop River.

E. Mortality

1. Parasitism and disease

Elkan (1965) describes a fungal infection, probably by Candida albicans,
destroying one half of the liver of a Chamaeleo bitaeniatus. Another G. bitaeniatus

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 31

suffered a dermal fungal (Dematiaceae) infection. The reaction of the chamae-
leon’s skin was an increasing keratinization and thickening of the stratum
germinativum, and ulceration of the dermis which contains the melanophores.
This condition would prevent colour lability, disrupting chamaeleon thermo-
regulation and result in loss of appetite, general weakened condition and even-
tually death. An ailment affecting thermoregulation of Chamaeleo namaquensis
and C. pumilus is discussed later under thermoregulation (see p. 55). It is not
known what etiological agent was involved. ‘These afflicted chamaeleons were
unable to turn darker shades, and hence had trouble in warming at cool
experimental temperatures. ‘They had no difficulty in keeping cool at high
experimental temperatures. Disruption of physiological thermoregulatory
capacity greatly lowered the high metabolic rate of chamaeleons, resulting in
loss of appetite, increasing listlessness, daytime sleeping, and eventual death.

Culex mosquitoes were observed feeding on Chamaeleo namaquensis at
Gobabeb, South West Africa. Brygoo, Dodin & Sureau (1959) report Culex
fatigans feeding on Chamaeleo lateralis and C. verrucosus of Madagascar. No other
ectoparasites were observed on Chamaeleo namaquensis or C’. pumilus. Brygoo and
his associates have worked on the many protozoan parasites of Madagascan
chamaeleons. Microscopic parasites were not examined in either Chamaeleo
pumilus or C’. namaquensis, but macroscopic endoparasites, which were encount-
ered during autopsies of chamaeleons in association with investigations of
diet, and reproduction, were removed. Dr Prudhoe of the British Museum
(Natural History) kindly identified such parasites, and published his findings
separately (Prudhoe & Harris 1971).

In January 100% of female Chamaeleo pumilus harboured intestinal para-
sites, but in October only 14,2°% were so parasitised. In January, February,
July and October 100% of male C. pumilus had intestinal parasites, but this
incidence was only 16,7°% in June. The greatest number of parasites was 70
nematodes removed from a female C. pumilus, whereas 36 was the largest number
of nematodes removed from a male. In June a female C. pumilus weighin 15,4
g had a total parasite complement of 1,2 g consisting of 23 nematodes and
7 cysts variously on the bladder, ovaries and in the abdominal wall. It seemed
healthy and yolking of follicles appeared normal. In April and August every
C. namaquensis examined contained some parasites, but in June only 50% were
parasitised. Intestinal parasites were mostly tapeworms in this species, with
some nematodes, acanthocephalans and small cysts in the body wall.

According to Dr Prudhoe, the nematodes in Chamaeleo pumilus were all
Strongyluris, but all the cysts were undergoing calcification, making them im-
possible to identify. However, one cyst showed great superficial resemblance
to a cestode cysticerous. The cestodes of C. namaquensis were all Oochoristica
africana, the nematodes Physaloptera sp., and the acanthocephalan larvae
possibly of the genus Echinopardalis, which occurs as adults in mammalian
carnivores. Oochoristica africana also occurs in the saurians Agama and Meroles.
The cysts found in Chamaeleo namaquensis had also undergone calcification to a

32 ANNALS OF THE SOUTH AFRICAN MUSEUM

degree making accurate identification impossible. Helminths, covered by a
gelatinous covering, were frequently observed among tenebrionid beetle remains
in the stomachs of C. namaquensis. Chabaud & Brygoo (1960) and Brygoo
(1963) record nematodes and trematodes of Madagascan chamaeleons, only
the nematode Strongyluris being represented in their and this study’s samples.

2. Predation

No actual field predation on Chamaeleo pumilus or C. namaquensis was
observed. Defence is discussed later under that section in behaviour (see p. 73).
While C. pumilus females are alleged (Rose 1950) to devour their young, this
was found to be accidental, and triggered by a fruit-fly landing on or near the
baby. Captured babies were not eaten, though usually killed by such mistaken
identity on the part of the adults. A C’. dilepis in captivity did eat young C.
pumilus, and its presence caused some upset among the adults. Snakes of the
genera Dendroaspis, Dispholidus, Philothamnus and Thelotorns are recorded
(FitzSimons 1962) as predators on chamaeleons. According to Dr R. Jensen
of Gobabeb, the raptorial birds Falco rupicoloides, F. terinunculus and Melierax
musicus, and the mammal Canis mesomelas, prey on Chamaeleo namaquensis. Rose
(1950) says shrikes eat C. pumilus, and, indeed, one can see the catch stored
on barbed wire fences. Wager (1958) records cats, dogs, motor traffic, raptorial
birds and snakes as mortality factors of C. dilepis, and also a spider ensnaring a
young individual. Cats and dogs, particularly the former, preyed on C. pumilus,
and the feral dogs of the Walvis Bay vicinity may prey on C. namaquensis.
Chamaeleons sustained severe injuries, often fatal, as the result of intraspecific
action (see under population structure, social interactions, p. 101).

3. Physical

Wager (1958) considers grassfires cause ‘many thousands’ of chamaeleon
deaths. Fortunately, or unfortunately, none of the marked chamaeleon popu-
lations examined suffered any fires during the study period, so the real effect
of this mortality factor cannot be estimated. Fire-ravaged grassy areas were
combed, where previously Chamaeleo pumilus had been observed, but no remains
were uncovered. C. pumilus at such sites appeared unscathed by such fires,
provided they climbed high enough into tall reeds which were moist enough
to resist burning, or evacuated to such nearby. It is not known whether chamae-
leons found in burnt areas were simply returning refugees originally located
there, or new individuals. Fire was scarcely a problem to C. namaquensis, since
any burning of the meagre and scant vegetation of their habitat would be most
local and easy to escape.

Fire is ‘normal’ in areas of scant or seasonal rainfall. Burrage (1966) feels
that fire is beneficial to reptiles preferring open spaces, since fire clears dense
growth that crowds such reptiles out. Fire would be beneficial to Chamaeleo
pumilus in limiting tall trees from crowding out the bushes and grasses which
it prefers, and which rapidly recover in burned areas.

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 33

No instance of flooding deaths in Chamaeleo pumilus is known, but any
sudden, large increase in river volume would be suspected to have deadly
effect on chamaeleons inhabiting stream-side vegetation. Flooding may be a
mortality factor of those C. namaquensis directly inhabiting water courses in
narrow canyons and bottom lands of intermittent rivers subject to sudden and
erratic discharge. This would necessarily depend on the discharge at any given
time of a given stream and the topography in the immediate area.

Burrage (1966) reports flooding of washes caused as high as 95% mortality
of Uta stansburiana hesperis inhabiting such situations, though the effect on the
overall population was minor. Those U. s. hesperis inhabiting a burn area of
2 050 m? suffered a 33,3°% mortality.

Rand (1968) reports suffocation in nest-building Jguana of Panama, when
their excavations collapsed and they could not free themselves. In captivity a
male Chamaeleo namaquensis was rescued and survived a cave-in of its retreat
burrow, but a female of this species died when its nest burrow collapsed.

4. Human agency

Setting of fires, spraying with insecticides, alteration of habitat, capture
and killing for any of several reasons by man must rate as predation, since an
animal permanently removed from a specific locality is denied to that local
population as surely as if it had been killed and eaten. Alteration of the habitat
is probably man’s most destructive effort, because it totally eliminates a habitat
and all forms dependent upon it. It was felt at Gobabeb that Chamaeleo nama-
quensis was rare there owing to the Kuiseb flooding in 1969. This is very much
doubted. They were very much in evidence elsewhere along and in the Kuiseb
away from Gobabeb, and flooding could not be a mortality factor on the gravel
plains and dunes in the immediate Gobabeb area. Moreover, they were
common in other riverbeds that were also subject to flooding at the same time
as the Kuiseb.

Survival of Chamaeleo pumilus and C. namaquensis is discussed in the section
on population structure (see p. 95).

F. Yemperatures and their control: activity patterns
1. Regulation of temperatures

Most reptiles are considered ectotherms, though Benedict (1932), ‘Temple-
ton (1960), Dawson & Templeton (1963), Bartholomew & Tucker (1963),
Norris (1967), Dawson (1967) and Weathers (1970) have shown that a number
of forms supplement behavioural thermoregulation with purely physiological
mechanisms. Ectotherms acquire and lose body heat by: (1) radiation; (2)
conduction, primarily with the substrate; (3) air convection. Although at
extremely high temperatures some lizards pant, this may be a wasteful recourse
in the case of deserticulous species. Many diurnal forms maintain their body
temperatures within narrow limits by behavioural adjustments, as demonstrated

by Cowles & Bogert (1944).

34. ANNALS OF THE SOUTH AFRICAN MUSEUM

Diurnal deserticulous lizards apparently have the most varied means of
controlling their temperatures, employing physiological methods to increase
their activity time beyond the restrictions of behavioural thermoregulation
and in ‘hostile’ thermal conditions. This is discussed by Dawson (1967),
Tucker (1967) and Mayhew (1968), who point out the following methods:
(1) toleration of hyperthermia; (2) changes in surface-volume ratio by body
expansion and contraction; (3) changes in reflectivity; (4) changes in the
cardiovascular system affecting heat transport through the tissues. Richards
(1970) discusses the use of evaporative cooling by reptiles.

2. Thermal preferences in the field

Chamaeleo pumilus is active even on rainy winter days that would seemingly
deter any heliothermic reptile. It is able to be abroad because it is eurythermic
and partly endothermic. Of 549 active C. pumilus body temperatures recorded,
the overall yearly range was 3,5-37,0 C (x = 22,4 C; median 22,8 C). These
data are given by season and weather condition in Table 17, and summarized in
Table 3. Body temperatures differed according to season and weather conditions
(Table 17). Seasonal differences have been reported in American iguanids by
Tinkle (1967) for Uta stansburiana and McGinnis (1966) for Sceloporus occidentalis.

Fifteen records of low active body temperatures (3,5-9,9 C) for Chamaeleo
pumilus were all taken under ‘Cool Fair’ conditions. Two C. pumilus with body
temperatures of 3,5 C were catching flying prey. All these low readings,

Table 3

Environmental temperatures (°C) related to body temperatures (°C) and activity states of 603
Chamaeleo pumilus at Stellenbosch, Cape Province.

Numbers do not quite add up to 603, since some individuals were engaged in several activity
states simultaneously.

Environmental State and number of individuals
temperatures Body Basking Foraging
(Mean in parentheses) temperatures Cool/Warm Open/Shade Retreat
32,0-39,0 (34,9) 36,0-37,9 4 6
27,0-39,0 (32,7) 34,0-35,9 7 10
27,0-35,0 (31,2) 32,0-33,9 17 15
20,7-31,8 (28,3) 30,0-31,9 17
19,0-32,5 (24,7) 28,0-29,9 27 4
18,4-31,0 (21,7) 26,0-27,9 5 46 5 4
14,5-24,5 (20,0) 24,0-25,9 6 70 10 I
14,5-22,0 (18,8) 22,0—23,9 10 75 I 5
1350-2155 (17,1) 20,0—21,9 10 30 2
13,0-20,1 (17,8) 18,0-19,9 6 25 9 5
6,5-17,2 (14,5) 16,0-17,9 7 12 4 =
12,0-15,2 (13,8) 14,0-15,9 4 10 2
9;0-1352")((11,6) 12,0-13,9 F] 2 3
I1,0-11,6 (11,3) 10,0-11,9 2 I 7.
9,3-11,4 (10,6) 8,0— 9,9 2 4 6
50 7,2 (6,1) 6,0- 7,9 5 3 3
3,6— 5,0 (4,5) 4,0—- 5,9 I 5 5
2,0 2,0— 3,9 3 4
0,0— 1,7 (0,5) 0,0— 1,9 5

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 35

however, were taken very early in the day (mostly before 08:00 hours), about
15 minutes before sunrise. ‘These low body temperatures of active C. pumilus in
the field agree with the body temperatures of 40,0 C recorded by Pearson (1954)
for the Andean iguanid Liolaemus multiformis. Records for 45 Chamaeleo pumilus
asleep and mostly taken at night range from 0,5 C (‘Cool Fair’) to 26,5 C
(‘Warm Fair’), and were almost the same as that of the air temperature at
50 mm (= Environmental Temperature). Body temperatures for active C.
pumilus and for those at rest were monitored on a 24-hour basis. Table 6 gives
a summary of body temperatures of selected lizards active in nature, which are
co-inhabitants, or of similar habits as C. pumilus and C. namaquensis, the relevance
of which is discussed later. These data are taken from Brattstrom (1965),
though recent data have been included. Where the incorporation of new data
differs from those of Brattstrom, the newer source has been credited.

Chamaeleo pumilus dies if held at —5,0 C for a minimum of two hours, and
this temperature is considered the minimum lethal temperature. Though
torpor does occur at this temperature, pumilus does react to pinching and
prodding at 0,o C and even —5,o C for a time. The critical maximum tempera-
ture is 43,0 C; the maximum lethal temperature 43,0-47,0 C.

The body temperatures of active Chamaeleo namaquensis are remarkably
stable, despite the varied environmental temperatures of the Namib Desert.
On foggy mornings the substrate temperature was as low as 8,0 C; but on
clear, sunny days the substrate temperature reached 67,0 C. Of 351 active
C. namaquensis body temperatures recorded in the field, the overall range was
14,0-39,7 C; mean 28,7 C; median 28,8 C (Coastal, 14,0-36,2 C; X = 27,0 CG;
median 28,4 C: Inland, 15,0-39,7 C; ¥ = 30,3 C; median 31,5 C). These data
treated seasonally, are given in Table 17, and summarized in Tables 4 and 5.
There is slight difference in weather and season in the means and between coastal
and inland populations, but it is not significant. Though body temperatures
of inland C. namaquensis were slightly higher, the range of body temperatures is
about the same for the respective populations, regardless of weather conditions.

Most diurnal desert lizards have far higher mean body temperatures than
C. namaquensis (Table 6) and this is discussed in the section on thermoregulation
(see p. 37). C. namaquensis not only has the normal desertic problem of adapta-
tion to and survival of high environmental temperatures, but also one of
tolerating low environmental temperatures, or controlling its body temperature
by physiological means. It solves its thermal needs to both environmental
extremes by recourse to the latter solution. C. namaquensis shows discomfort at a
body temperature of 41,0 C; is ‘troubled’ (seeks shade, mouth gaping, eye
bulging) at 45,0 C; its critical thermal maximum was 47,0-48,0 C and lethal
temperature was 49,5 C +1,3. There was no difference in critical thermal
maximum between inland and coastal individuals. The critical minimum
temperature was 0,0 C for two hours; the minimum lethal temperature,
—5,0 C for a minimum of two hours. Partial torpor occurred at a body tempera-
ture of 13,5 C (coastal), 15,5 C (inland), though pinching evoked response

36 ANNALS OF THE SOUTH AFRICAN MUSEUM

Table 4

Environmental temperatures (°C) related to body temperatures (°C) and activity states of 272
coastal Chamaeleo namaquensis in South West Africa.

Environmental State and number of individuals
temperatures Body Basking Foraging
(Mean in parentheses) temperatures Cool/Warm Open/Shade Retreat
50,0-58,0 (55,0) 36,0-37,9 3 6
67,0 34,0-35,9 I
25,5-47,5 (36,0) 32,0-33,9 14 14
20,5-45,0 (31,0) 30,0-31,9 20 10 6
21,5-38,0 (25,5) 28,0-29,9 IO 22 2
18,2-47,0 (29,5) 26,0-27,9 29 33 6
14,7-30,7 (21,4) 24,0-25,9 12 15 4
20,4 22,0—23,9 10 16 8
14,7-19,5 (17,1) 20,0-21,9 4 4 4 4
16,5-19,5 (18,0) 18,0-19,9 4 2 2
14,0-17,0 (15,5) 16,0-17,9 2 2 2
8,0-16,0 (11,6) 14,0-15,9 4 4 6

Numbers do not add up to 272, since some individuals: were engaged in several activity states
simultaneously.

Table 5

Environmental temperatures (°C) related to body temperatures (°C) and activity states of 97
inland Chamaeleo namaquensis in South West Africa.

Environmental State and number of individuals
temperatures Body Basking Foraging
(Mean in parentheses) temperature Cool/Warm Open/Shade Retreat
48,5-58,0 (53,3) 38,0-39,9 5
37,0-48,5 (41,5) 36,0-37,9 10 3
34,0-40,0 (37,1) 34,0-35,9 4 8
32,6-38,5 (35,6) 32,0-33,9 6 3
30,0-43,5 (40,7) 30,0-31,9 8 29 6
32,0-34,0 (33,3) 28,0-29,9
30,0-36,0 (33,0) 26,0-27,9 4 8
23,0 24,0—25,9 2
— 22,0—23,9
= 20,0—21,9
— 18,0-19,9
12,5 16,0-17,9 2 5
= 14,0-15,9

Numbers do not quite add up to 97, since some individuals were engaged in several activity
states simultaneously.

down to a body temperature of 10,0 C. Full torpor occurred at a body tempera-
ture of 7,6 C.

Field records (N = 18) of C. namaquensis at rest ranged from (coastal
N = 11) 7,0-13,0 C (% = 10,6 C), and (inland N = 7) 9,0-16,0 C (x = 12,3 C)

and were about that of the substrate.

3. Thermal preferences in the laboratory

In a laboratory thermal gradient active Chamaeleo pumilus body tempera-
tures (N = 20) ranged from 7,0-30,0 C (% = 25,0 C), which is the ambient
preferendum Von Frisch (1962) found. Bustard (1963) kept his C. pumilus at

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 37

30,6 C during the day. Laboratory resting temperatures (15,0-25,0 GC; x =
22,0 C) are similar to ‘Warm Fair’ field records, thus C. pumilus ‘prefers’ a
higher resting (= nocturnal) environmental temperature, if it is available.

Like Von Frisch, Bustard (1965) did not take actual body temperatures,
but records 36 captive Chamaeleo hohneli active at an ambient temperature of
2,0-3,0 Cand catching food at 10,0 C. Bustard (1966) also observes C. bztaenzatus
is quite hardy, surviving ambient nocturnal temperatures of 36-39 F (2,0-4,0
C). Unlike C. pumilus, bitaeniatus and hohnelu of East Africa inhabit montane
grasslands.

Chamaeleo namaquensis (N = 18) active preferred body temperatures
ranged from 18,5-36,2 C (X = 29,3 QC), with no difference between inland or
coastal individuals. The eccritic range was somewhat wider (14,0-39,7 C) but
the mean (28,7 C) of both populations was close to laboratory findings. Stebbins
(1961) gives a preferred body temperature range of 28,5-36,5 C (% = 33,5 C)
based on 27 records of two captive C’. namaquensis. Greatest similarity in eccritic
and preferred body temperatures is that for “Warm Overcast’ (coast 17,5-
Bae = — 27,7 C: inland 20,0-390,0 C; x = 20,0 C). The eccritic body
temperatures of both populations do not differ considerably with most seasonal
and weather conditions. Resting laboratory C. namaquensis body temperatures
(25,0-29,7 C; x = 28,7 C) were not really different from active preferred body
temperatures, thus C’. namaquensis, as C’. pumilus, prefers warmer resting tempera-
tures, if available. At night they did not select lower resting temperatures
available, as Regal (1967) reported for some of his desert lizards.

As Mayhew (1968) points out, the eccritic and preferred body temperatures
may be essentially the same for some species, but it is not the rule (Licht et al.
1966a, 6). DeWitt (1963, 1967) found the deserticulous iguanid Dipsosaurus
dorsalis to have a mean preferred body temperature of 38,5 C, whereas 42,1 C
was the mean eccritic body temperature (Norris 1953). It is difficult to simulate
in the laboratory the various weather conditions, such as rain, cloud, fog, and
wind to which reptiles are subjected in the field. Thus, even if within the
environmental range it is considered that laboratory thermal gradients do not
give a clear reflection of the actual thermal factors of the environment, the
thermal preferences of reptiles, or their need, ability, or lack of it to make
thermoregulatory adjustments. This study agrees with Bustard (1967), who
thought that any difference in active preferred and eccritic body temperatures
indicates that optimum temperatures exist for different functions. Artificially
supplied temperatures also allow selection of, rather than regulation to, the
preferred body temperature, without the variabilities imposed on it by other
environmental factors.

4. Thermal preferences of chamaeleons in comparison with other saurians

The thermal preferences of co-inhabitants of, and species of similar habitat
and habits as Chamaeleo pumilus and C. namaquensis are summarized in Table 6.
Body temperatures of C’. pumilus have a range similar to those of the Andean

38 ANNALS OF THE SOUTH AFRICAN MUSEUM

Species

AGAMIDAE
A SOMONOL Gn
Amphibolurus barbatus

a caudicinctus .
eS inermis .
i reticulatus

Physignathus longirostris

Moloch horridus
CHAMAELEONIDAE

Chamaeleo dilepis . :

Ss namaquensis (coast)

‘ , (inland)

- pumilus ;

GEKKONIDAE
Rhoptropus afer (coast)
- op (Guallayavel))
HELODERMATIDAE
Heloderma suspectum
*p horridum
IGUANIDAE
Anolis allison .
,, allogus .
5, carolinensis .
», homolechis .
» limifrons
SRL UCLUS,
ES OUCL
Basiliscus vittatus .

5 plumifrons
Callisaurus draconoides
Crotaphytus collaris

5 wislizent
Dipsosaurus dorsalis
Holbrookia texana .
Iguana iguana . :
Liolaemus multiformis .
Phrynosoma coronatum .

A platyrhinos

a m calli
Sator grandaevis
Sauromalus obesus .
Sceloporus gracilis .

ba Br Aaclosus

AS jarrou .

ee magister .

a merriamt

Pe occidentalis .

59 orcuttt

ae poinsetti

squamosus

a” undulatus

Ps variablis

7 woodi

Table 6

Summary of body temperatures (°C) of selected lizards active in nature, co-inhabitants of or
of similar habits as Chamaeleo pumilus and C. namaquensis.

Range

29,0-32,0
25,2—-40,0
34,8-41,0
34,5-43,0
35,0-40,6
34,2-39,0
27,2—-40,2

21,0-36,5
14,0-36,2
15,0-39,7

325-3750

19,0—38,0
28,5-36,5

24,2-33>7
25,6-36,0

28,2-36,6
26,2-33,5
18,0-37,5
26,2—35,0
24,6-31,0
24,8-32,4
27,4—36, 1
22,5-38,5
28,0-35,5
26,4-40,2
20,7-4353
23,0-41,4
27,0-4.7,0
32,0—-40,2
26,7-42,4

4,0-37,0
20,8-39,0
26,2-39,5
29,3-41,0
32,6-38,8

23,8-42,0

30,3-39,1
20,8—38,2
32,2-37,0
31,0-37,0
29,6-37,4
26,4-38,0
26,0-38,5
30,8-38, 4
32,5-38,0
25,0-38,9
3351 —40,0
32,0—-39,2

xe

30,5
33,8
39,0
3953
37,0
37,0
3357

31,2
27,0
3953
22,4

28,0
3257

One,
28,7

33,0
20,2
27,0
31,8
27,1
29,3
3351
35,0
Bley
38,0
Bye
38,3
40,0
3751
3353
35,0
34,9
36,0
3754
3597
37,9
33,6
34,2
35,0
34,8
33,6
35,0
3594
3452
3553
34,8

3451
36,2

min.
Crit.

max.
Crit:

0,0 47,0-48,0

= 5;0 43,0
41,8
41,0-44,6
— 3,0
—2,0 46,5
0,0 4755
46,7
— 3,0 46,7
4555
45,6
— 3;0 43,0
—3,0 44,0-46,8
4357
43,0
44,2

N

Ref.

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN)

Species

Uma notata
3s scoparia . :
Urosaurus auriculatus .

Es clarionensis .

5 nigricaudus .

5 ornatus
Uta stansburiana hesperis .
= ae stejnegert.

;, thalassina
LACERTIDAE
Aporosaura anchietae (coast)

35 (inland).

33
Eremias lineo-ocellata .

33 _Namaquensis (coast) .
(inland)

Ty EOS) oy)
Meroles cunetrostris

»> namaquensis
3» reticulata (coast) .
59 »5 (inland)
,, suborbitalis
SCINCIDAE
Eumeces fasciatus .
>, obsoletus .
Lygosoma laterale .
Mabuya capensis
>> occidentalis
nsimata
5, multifasciata
= rudis i
Sphenomorphus sabanus
Tiliqua occipitalis .
3 rugosa
3, Scincoides .
‘TEMDAE
Ameiva ameiva
> festiva .
3 quadrilineata
5, pluvianota .
Cnemidophorus ceralbensis .
oe hyperythrus .
5 lemniscatus .
= sexlineatus .
re tigris
V ARANIDAE
Varanus spp.*
> gould

* acanthurus, gouldit, punctatus.

Table 6 continued

Range

18,0—46,0
26,6-39,0
32,3-39,0
29,6-39,0
33,8-39,5
26,8-39,5
17,2—40,6
25,0-37,8
32,6-38,8

26,0—42,0
26,4-38, 3
35,0-41,5
19,0—36,0
36,0—40,0
24,2-39,1
36,0-40,0
19,0—36,0
25,0—43,0
36,0-41,5

13,5-37,0
17,5-36,3
22,0-35,5
19,0—40,0
19,0-37,0
3 1,0-39,5
209,6-37,8
25,4-38,6
24,0—28,4
3955-3535
25,0—41,0
2955-3955

3551-39 3
32,0-39,8
24,0—42,0
33,8-40,0
36,7-41 56
36,8-41,6
3455-4233
27,0—45,0
29,0—44,6

20,0—40,0
34,4-36,2

se

min. max. N
Crit. Crit.

45:1 13

45,4 24

44,0 18

m5 y0) 41

39

Ref.

Where uncredited, data shown are derived from Brattstrom (1965). Data for other species
are identified by the following numbers to the references given below, as are the incorporation
of new data for species listed by Brattstrom.

(1) Ballinger, R. E., K. R. Marion & O. J. Sexton (1970). (2) Bartholomew, G. A., V. A.
Tucker & A. K. Lee (1965). (3) Bartholomew, G. A. & V. A. Tucker (1964). (4) Brain, C. K.
(1962). (5) Burrage, B. R. (unpublished data). (6) Burrage, B. R. (1966). (7) this study.
(8) Hirth, H. F. (1965). (9) Lee, A. K. & J. A. Badham (1963). (10) Licht, P., W. R. Dawson
& V. H. Shoemaker (1966a). (11) Louw, G. N. & E. Holm (1972). (12) Mayhew, W. W.
(1968). (13) Pearson, O. P. (1954). (14) Pianka, E. R. & H. D. Pianka (1970). (15) Stebbins,
R. C. (1961). (16) Warburg, M. R. (1965).

40 ANNALS OF THE SOUTH AFRICAN MUSEUM

iguanid Liolaemus multiformis and Lacerta agilis of the Russian Caucasian
Mountains. Lacerta agilis maintains body temperatures 29,9 C above that of
the environment (Strel’nikov 1944). Though their thermal problems are
equivalent, the habitats of these three lizards are quite different, as Liolaemus
multiformis and Lacerta agilis inhabit high mountains, while Chamaeleo pumuilus
does not encroach above lower mountain slopes. The montane chamaeleons,
C. bitaeniatus and hohnelii, are ‘active’ in a similar thermal range in the laboratory,
but for these species there are no field temperature data. ‘These viviparous
Chamaeleo may regulate to lower temperatures for reproductive reasons, which
is discussed later in the section on reproduction. C. pumilus occurs sparsely in
montane valleys and is subject there to lower environmental temperatures than
those inhabiting lowlands.

The chief co-inhabitant of C. pumilus is the skink Mabuya capensis. M. capensis
is active from 19,0-40,0 C (X = 27,7 C), and is not abroad with body tempera-
tures as low as C. pumilus, tolerates a body temperature slightly higher than the
chamaeleon and has a higher mean body temperature. Mabuya capensis is rarely
active in rainy weather, and usually keeps within dense vegetation avoiding
exposure to the weather as does Chamaeleo pumilus. Mabuya capensis is chiefly a
heliothermic skink, using dead vegetation as an insulator as does Liolaemus
multiforms (Pearson 1954) and Uta stansburiana (Burrage 1966) to maintain
very high body temperatures, much above that of the environment. How
chamaeleons maintain higher or lower body temperatures compared to
environmental temperatures is discussed in the thermoregulation—warming/
cooling section (see p. 42). Mabuya capensis and M. rudis differ from most
skinks in being active thermoregulators. Agama atra is another co-inhabitant of
Chamaeleo pumilus. Agama atra is far commoner than the chamaeleon on mountain
slopes; the reverse is true in lowlands. The agamids recorded (N = 20) had a
body temperature range of 29,0-32,0 C (X = 30,5 C).

The New World iguanid anoles (Anolis) are the ecological equivalents of
the Old World chamaeleonids. Chamaeleo pumilus and Anolis carolinensis seem of
quite similar habits and live under roughly comparable conditions. Most of
the other species of Anolis listed in Table 6 are Neotropical, though some are
mountain-dwelling, and others (e.g. A. limifrons and A. frenatus) inhabit closed
canopy forests and are less warm-adapted than grassland or ecotone species,
such as A. auratus and A. tropidogaster (Ballinger et al. 1970). Brattstrom’s (1965)
temperature data for A. carolinensis are for resting individuals, and those given
in ‘Table 6 are data collected by the author over several years from animals
living in outdoor enclosures in New Jersey, Kansas and California. Thus, they
are not ‘field’ body temperatures per se, but are all that are known of for this
abundant species. The minimum voluntary body temperature (18,0 C) of
active Anolis carolinensis is much higher than that of Chamaeleo pumilus, and the
mean body temperature of Anolis carolinensis is slightly higher. However, the
maximum voluntary body temperatures of both species are almost the same.
A. carolinensis was also subject to approximately the same weather conditions,

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 4I

thus environmental temperatures are about the same, and judging the range
of A. carolinensis (south-eastern United States of America) the similarity of these
species seems valid. Basiliscus and some Sceloporus are also forms of somewhat
similar habitat and habits as Chamaeleo pumilus.

Body temperature data of four Chamaeleo dilepis were recorded in the field
at Windhoek, South West Africa. Data for this species are within the range
Stebbins (1961) gives for 328 records of 30 captives. Rhoptropus afer is a co-
inhabitant of Chamaeleo namaquensis. Like the chamaeleonid, there is a difference
in the eccritic thermal preferenda of the coastal and inland populations of this
diurnal gekkonid (Table 6). Rhoptropus only emerges when it can maintain a
minimum body temperature of 19,0 C. It was never seen abroad during
completely overcast conditions, but was active on the hottest days. At both
times Chamaeleo namaquensis was active. Rhoptropus has temperature preferenda
similar to the co-inhabitant lacertids Eremias namaquensis, Meroles reticulata, and
the scincid Mabuya occidentalis. The principally dune-dwelling lacertid Aforosaura
anchetae has been studied in detail by Louw & Holm (1972). This study’s
records are for coastal individuals only and appear to be slightly different from
those of Brain (1962) and Louw & Holm (1972). Aporosaura is similar in
psammophilous adaptations and thermal requirements to the iguanid genus
Uma of the deserts of the south-western United States of America. Other
desertic saurians are: Cnemidophorus (ted), Tzliqua (scincid), Callisaurus,
Crotaphytus, Dipsosaurus, Holbrookia, Phrynosoma, Sator, Sauromalus, (most listed)
Sceloporus, Urosaurus, Uta (iguanids), Heloderma (helodermatid), Amphibolurus and
Moloch (agamids).

Chamaeleo namaquensis has a low minimum voluntary body temperature for
a diurnal desert saurian and most other species have far higher maximum
voluntary and mean body temperatures. The American deserticulous iguanid
Dipsosaurus dorsalis and Chamaeleo namaquensis are active in the extreme midday
desert heat at environmental temperatures lethal to most birds, and probably
all mammals. Dipsosaurus is active with a body temperature of 47,0 C on sub-
strates reaching 60,0 C. A Chamaeleo namaquensis active with a body temperature
of 34,2 C was recorded on vegetationless dune sand with a temperature of
67,0 C, and five records gave maximum voluntary body temperatures of 39,7 C
for C. namaquensis on substrates with temperatures of 48,5-58,0 C (X = 53,3 C).
Some of these chamaeleons were probably in transit between grass clumps, but
others were in areas apparently devoid of any sort of available shade.

Gates (1970) contends that by knowing the properties of a particular
species, one can predict the climate under which it must live. He has predicted
the climatic parameters for Dipsosaurus dorsalis.

Iguanids, agamids and teiids are the most heat resistant lizards, skinks
and xantusids are heat sensitive, while geckos vary in this regard according to
species (Mayhew 1968). Chamaeleo pumilus is active over a broad span of body
temperatures (34,5 C), but its critical minimum and critical maximum agree
closely with such thermophilic deserticulous forms as Callisaurus and Sceloporus

42 ANNALS OF THE SOUTH AFRICAN MUSEUM

(iguanids), which are not as low as the heat sensitive skink, Eumeces fasciatus.
Chamaeleo namaquensis has the same critical minimum and critical maximum as
the iguanid Dipsosaurus dorsalis. Chamaeleo namaquensis cannot be described as
thermophilic, but it is active over a narrower span of body temperatures
(25,7 C) than C. pumilus. There are no other data on chamaeleon body tempera-
tures in the field, so the thermal situation of Chamaeleo pumilus and namaquensis
with other chamaeleonids cannot be discussed reasonably.

5. Lhermoregulation: warming|cooling in the field

Chamaeleo pumilus and C’. namaquensis thermoregulation is a complexly
integrated process, involving dermal colour lability with attendant vasomotor
and other cardiovascular adjustments, body posturing, thermo-pneumatic
changes in lung and air sac volume, and panting.

Table 7 gives the skin colour and body compression indices referred to in
this study. Body compression ‘I’ was the initial warming posture used by C.
namaquensis and C. pumilus earliest and latest in the day, and occasionally
during cool or unfavourable days to maintain body temperatures close to
preferendum. It is also the resting position, being modified to initial warming
by the chamaeleon assuming colour index ‘5’ and positioning so that both sides
of the body were usually in the sun, allowing the slanted rays of the rising or
setting sun to strike the chamaeleon’s body as directly as possible. Such a
position gives the body a spherical shape and aids the warming of the upper
part of the body, the lungs, air sacs, and probably the dorsal aorta. At this
time the air sacs in C. namaquensis are inflated (Fig. 128). In C. namaquensis this
posture was coupled with thigmothermic behaviour. On chilly, foggy winter
mornings coastal C’. namaquensis experienced environmental temperatures of
8 C. The chamaeleons assumed body compression ‘I’ and colour index ‘5’ and
were Closely adpressed to, but not ploughed into the substrate. The tail and
legs were held close to the body. Such behaviour minimizes convective heat
loss and thermoregulatory ploughing has no value, since temperatures warmer
than that at the surface do not occur until a depth of 150 mm and greater.
Under these weather conditions, the body temperatures and skin surface
temperatures of the chamaeleons were no lower than 14,0 C. The substrate
surface temperature directly beneath the animal is warmer by one or two
degrees to that of exposed substrates. The animals remain still, moving out
only for passing prey, territorial challenges, and courtship.

Under fair skies C. namaquensis ploughed thermoregulatory warming
grooves in the substrate. In the mornings, such grooves were dug no deeper
than 5 mm, but in late afternoons and evenings such grooves were ploughed
to a depth of 15 mm. Digging deeper grooves later in the day allowed C.
namaquensis to experience substrate temperatures a few degrees higher than that
at the surface, whereas early in the day temperatures higher than that at the
surface are only realized at depths of 150 mm and greater. However, a shallow
groove early in the day minimizes convective heat loss, especially in the strong

43

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN)

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44 ANNALS OF THE SOUTH AFRICAN MUSEUM

winds occurring under fair skies, and the slightly deeper grooves later in the
day have the same value with the added benefit of a heat source. C. namaquensis
periodically ploughed along uncovering more warmth as that at one site
dissipated. C’. namaquensis occasionally selected sheltered sites to the lee of dead
vegetation, rocks, and other objects. The efficiency of initial heating within
one hour is given in Table 8. C. namaquensis body temperatures increased by
9,5 C in the first 20 minutes after which heat uptake slows. Heating during the
warmer season was somewhat faster, but the environmental temperatures were

also higher.

Table 8

Efficiency of initial warming over the sixty minute period after sunrise (cool season only),
in Chamaeleo pumilus (Cp) and C. namaquensis (Cn). Body compression (“CmI’) and colour index
(‘Cll’) are given in Table 7.

Temperatures (°C)

increase N
Environmental Body Species Cll CmI Weather
8,0-10,0 14,0—-25,0 6 Cn 5/5 I fog, no wind
13,0-13,8 18,0—29,0 8 Cn 5/5 I clear, strong wind
5,0-10,8 6,0-25,0 14 Cp 5/5 I clear, light to moderate wind
13,0-14,5 12,0-20,0 10 Cp 5/5 I rain, strong wind

Chamaeleo pumilus followed much the same mode as to body compression
and colour indices as described above for C’. namaquensis, except for use of
substrates. Occasionally, C. pumilus would use metal objects (e.g. iron railings)
acquiring some thigmothermic value as those selecting somewhat wind-
protected sites. C. pumilus lacks air sacs, but the lungs are long, the distal parts
of which might serve the same function as the air sacs in C’. namaquensis. During
warming and cooling thermoregulation, the lungs of C. pumilus and air sacs
of C.. namaquensis were brought to maximum volume, as can be deduced by the
inflated appearance of the body in the field, palping, and verified surgically.
The efficiency of C. pumilus when warming is given in Table 8. As in C. nama-
quensis, the fastest heat increase was in the earlier basking period, when C.
pumilus body temperatures increased by 14 C in the first 15 minutes, the
environmental temperature increasing only by one degree in the same period.
Warmer season body temperature heating rates were as in C. namaquensis.

When initial warming has taken place, both chamaeleons switched to body
compression ‘IV’. In body compression ‘ITV’ the body is greatly laterally
compressed, reducing body width to 30% of normal, and the skin between the
scales is greatly stretched. Usually only one side at colour index ‘4-5’ was
presented to the sun, the side in the shade being considerably lighter, usually
at colour index ‘2’. Warming C. namaquensis at colour index ‘5’ and body
compression ‘I'V’ with the skin thus stretched, have some of the scales edged
in, and small flecks of the skin yellow and red. The whole body was positioned
to receive the rays of the sun as directly as possible. The temperature of the
side in the sun was read with a shielded probe and was at or slightly above that

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 45

of the body; the side in the shade at, or a few degrees below. The chamaeleons
periodically changed position, so that the side presented to the sun became the
side in the shade and vice versa. The hue of each side changing during the turn
around, so that the side facing the sun was always a darker colour, such as ‘4’
or ‘5’, and the side in the shade always lighter. They performed thus, even if
the weather was overcast, presenting to the obscured sun.

Postural changes and assumption of different hues during the day varies
somewhat with the environmental conditions, such as temperature, wind, cloud
cover and rain. It must be noted here that chamaeleons in apparently identical
situations were not necessarily the same colour, though body temperatures
were about the same. Close observation revealed that the light phase ones
assumed darker hues as their body temperatures dropped below the thermal
preferential, and as their body temperatures rose their hues again lightened. In
short, dark chamaeleons are raising their body temperatures to preferential.
Chamaeleons at a colour index of ‘2-3’ are at preferential. Fine adjustments
included varying the side exposed to the sun. Efficiency of temperature main-
tenance is given in Table 9.

Table 17, showing thermoregulation through the seasons, veils important
aspects by giving these data inclusively. For example, it amply shows the range
of environmental and body temperatures per season for different weather
conditions, but also implies that the higher body temperatures occurred with
the higher environmental temperatures. This is not so, as most high body
temperatures were recorded with lower environmental temperatures. This is
brought out in Table 9, but C. pumilus, for example, ‘Cool Fair’, June 5, 11:00
hours, moderate south-west wind, environmental temperature (50 mm) 14,5 C;
body temperatures (N = 5) 20,9-23,6 C (x = 22,5 QC). This is also true of
C. namaquensis; ‘Cool Fair’, April 14, 12N, calm, substrate temperature 55,5 C;
body temperatures (N = 5) 30,0-36,2 C (X = 33,1 C).

Thermoneutrality occurs when the chamaeleon does not have to regulate
to maintain thermal preferenda. This condition is realized with environmental
temperatures of 23,0-26,0 C for Chamaeleo pumilus and 26,0-32,0 C for C.
namaquensis under calm conditions. At such time they assumed a body com-
pression of ‘II’, sometimes ‘III’, and skin colour of ‘3’, and in some instances
‘9’, which are the upper levels of the thermoneutrality zone. Dermal tempera-
tures of both sides were about the same and close to the body temperatures.
In C. namaquensis the air sacs were not in use, and in C. pumilus the lungs not
filled to full volume. Also, the tail and legs were not held closely to the body.

As environmental temperatures soared, chamaeleons responded by
reversion to body compression ‘IV’, rarely ‘III’, but never ‘IT’ or ‘II’. Colour
was always ‘2’ or lower, and the side to the sun lighter than the side in the shade.
Complete pallor was assumed with a body temperature of 39,0 C for C. pumilus,
and 30,0 C for C. namaquensis at abnormally high environmental temperatures.
The lungs and air sacs filled and expelled air rapidly, and panting ensued.
C. namaquensis was interesting in that occasional irregular panting with the

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ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 47

mouth barely open starts at a body temperature of 27,0-32,0 C, becomes
periodic and regular at a body temperature of 36,0-37,0 C and continuous at
a body temperature of 39,0 C, when the mouth is more widely open and the
tongue gorged with blood and raised from the floor of the mouth. ‘There was
no preliminary panting in C. pumilus; juveniles began continuous panting with
a body temperature of 33,1 C and adults at 37,0 C, with the mouth widely
agape, the labial scales bulged outward, and the tongue much engorged with
blood above the floor of the mouth.

Towards the end of the day, as solar insolation wanes and environmental
temperatures drop, chamaeleons resort to darker hues (‘4-5’) and body
compression ‘I’ and thigmothermic behaviour—including ploughing in C.
namaquensis, and body compression ‘IV’ in C. pumilus. In short, the whole
thermoregulatory process towards the end of the day is essentially a repeat of
early morning warming. ‘The loss of body temperatures over a period of one
hour is given in Table 1o.

Table 10

Fall of environmental and body temperatures of Chamaeleo pumilus (Cp) and C. namaquensis
(Cn) over the one hour prior to sunset during the cool season.

Temperatures (°C)

N loss
species Environmental Body Weather
15 Cn 20,0-18,0 29,5-29,0 fog, light/variable wind to calm
19 Cn 35,0—24,0 29,0-27,0 clear, strong wind
17 Cp 16,0-13,0 23,0-21,0 rain, moderate wind
40 Cp 21,5-13,0 28,0—25,0 clear, light/variable wind

N.B.—Compression and colour indices for this time span are essentially as in Table 8.

6. Thermoregulation

Warming|cooling in the laboratory: Under artificial and natural conditions
live chamaeleons heated faster than they cooled, while dead ones heated and
cooled at the same rate. Table 11 shows Chamaeleo namaquensis and C. pumilus
over a period of 300 minutes in total darkness and ‘Table 12 in light. Equivalent
results were obtained for a similar test with light and darkness alternated. It
is apparent that skin colour liability does enable chamaeleons to raise and
lower their body temperatures (Table 11). In the dark, no skin hue above
colour index ‘2’ was recorded. The rise of body temperatures was slow and it
should be noted that both animals, though previously held at —5,o C before
the run, maintained body temperatures above —5,0 C. C. namaquensis body
temperatures ranged from —2,0 to 1,9 C (kX = 0,7 CQ); C. pumilus body tempera-
tures ranged from —3,0 to —1,0 C (X = —2,5 C). Skin surface temperatures
were equivalent in both animals throughout the experimental range. Body
temperatures, especially those of C. pumilus, are considerably below the higher
experimental temperatures.

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ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 49

Table 12 shows the results with these animals exposed to light. Active
thermoregulation in C. namaquensis did not occur until the experimental
temperature reached 5,0 C and was markedly so at 15,0 C; two degrees above
voluntary torpor for this species. However, C. pumilus actively thermoregulated
at the lowest experimental temperature. Dark phase (colour index ‘4—5’) was
evident on the light facing side of the animals at experimental temperatures,
—4,5 to 25,0 C (C. pumilus) and 5,9 to 25,0 C (C. namaquensis). Thermoneutrality
occurred in both species at experimental temperature 30,0 C, and cooling with
light hues and less of body side presented to the light at experimental tempera-
tures of 35,0 CG and above. Body compression and panting were as in field
observations.

Table 12

Body compression (‘Cml’ in roman numerals), colour changes (‘CII’ in arabic numerals),

and body temperatures of 10 Chamaeleo pumilus and 10 C. namaquensis in the light at various

experimental temperatures. See Table 7 for compression and colour indices. Below, “I” denotes
time from 0 in minutes.

Chamaeleo namaquensis

(°C) Skin temperatures (°C) Body temperatures
Exptl Side to the light Side to the dark (°C)
ieeetemp. Cm Cll Range Mean Cll Range Mean Range Mean
3.1- 353 393 I 1,2- 1,3 1,3 1,0- 1,9 1,7
4,8- 5,5 Bol 3,0 3,0 3,0- 4,4 359
7,8-10,0 Q,1 2 6,9- 8,4 7,0 6,8— 8,5 8,1
1453-2535 18,2 I I 1,3-16,2 1353 12,4-22,9 16,3
16,4—26,0 BIg 7) I 15,2-17,9 16,6 16,5-25,0 DIRT
21,1-27,6 26,2 I 19,0—20,5 20,2 20,3-26,9 24,9
2755-335 31,6 2 24,0—25,0 24,6 2755-3250 30,8
28,4-33,3 31,3 1 26,5-31,0 27,7 26,2-32,6 29,4
3953-3750 32,0 2 29,7-35,8 3957 30,8-37,6 32,6
35,0-36,0 35,6 2 33,0-34,9 34,3 34:7-3557 352

Lael
on
°
_
S.
)
—_
—
Lo
On NP OOO OO 09

Chamaeleo pumilus

Ge) Skin temperatures (°C) Body temperatures
Exptl Side to the light Side to the dark (°C)
ie temp. Cm Cil Range Mean Cll Range Mean Range Mean

Moi My 1,2
Se BED 4,9
8,0— 9,0 8,5
13,5-22,7 1735

5 —0,5- 0,0 —0,5 0,4- 0,6 0,6
5
5
5)
150 17,0 IN A 15,1-23,5 22,0
4
+
3
I
(e)

2,5-— 4,0 393 325- 5,9 453
OG= 75 752 7;0— 9,0 8,5
12,3-17,0 13,3 13,8-20,0 17,2
14,5-17,0 16,0 17,0-22,0 20,5
17,0-19,3 18,3 19,9-25,0 23,5
23,0—24,0 27,0 27,0-28,0 27,4
25,9-30,9 32,3 25,9-32,8 27,8
31,0-33,2 31,7 31,0-35,0 3253
3257-3459 3325 34,2-35,0 3453

19,0-27,0 2555
27,6-29,5 28,2
27,1-33,5 28,8
31,2-34,8 32,3
3257-3459 33:5

270 35,0 IAW)
300 42,0 IV

NrReNNNNO ND ND N

Table 13 shows thermoregulation of chamaeleons in an outdoor enclosure.
These results were similar to those of field temperatures and need no further
discussion.

50 ANNALS OF THE SOUTH AFRICAN MUSEUM

Table 13

Effect of rising experimental temperatures in an outdoor enclosure on the thermoregulation
of 10 Chamaeleo namaquensis and 10 C. pumilus, showing body compression (“CmlI’ in roman
numerals), colour changes (‘ClI’ in arabic numerals), skin, and body temperatures. Air
temperature at five centimetres (Tag 50 mm) is the experimental temperature for C. pumilus;
and temperature of red Namib dune sand (T>) is the experimental temperature for C. namaquensis.
Below, “T’ denotes time in minutes. See Table 7 for compression and colour indices.

Chamaeleo namaquensis

(°C)
Exptl Skin temperatures (°C) Body temperatures
temp. Side to the light Side to the dark (¢@)

T We Oral (CI Range Mean CII Range Mean Range Mean

8,0- 9,5 8,8 9,3-11,0 10,0 8,5-10,5 9,6
19,0—21,0 20,3 14,5-16,3 15,3 17,0-10,5 18,5
33,5-30,4 35.5 31,7-33,0 32,7 32,0-34,0 33,3
32,5-36,0 3455 3330-3555 34,0 36,0-39,5 38,6
30,7-33,1 31,7 30,5-32,5 31,8 35,0-38,6 36,7
24,5-28,0 25,7 23,5-27,0 25,3 33,5-38,0 35,7

(ep)

je)

1S)

ee

fe)

—|

—
Or we NOON
= NO NOW Se

Chamaeleo pumilus

(°C)

Exptl

temp. Skin temperatures (°C) Body temperatures
Ta Side to the light Side to the dark (°C)

WG) eons (Croll (Cit Range Mean CII Range Mean Range Mean
7,7- 91 8,5 2 3, O= 955 8,5 8,5-10,3 953
8,9-11,0 10,0 I 8,8-10,5 9,5 10,8-12,7 12,0
18,5-20,5 19,7 2 18,0—-19,5 19,0 23,5-26,0 2553
23;5-26,5 24,55 1 23,0-25,0 24,1 35,0-3853° 3755
22,0-24,9 22,7 2 21,5-23,5 22,5 32,0-36,0 3453
23,3-26,0 24,3 I 22,0-25,5 23,8 (gi}@—35,Guumusa.5

DD
(o)
iS)
2
(o)
=
=
Se Se ae OO OO

Comparing thermoregulation data collected in the field and laboratory
it appears that the results are similar. But the slight discrepancy that occurs
between field and laboratory are assignable to the fact that the animals in the
laboratory tests were strapped so that they could not readily alternate body
sides in presentation to the heat source, as demonstrated by the results of those
in the outdoor enclosure which could alternate body sides and agree with the
field data. This ‘minor’ variance seems important to the chamaeleons for fine
thermoregulation. It must be noted that some chamaeleons never accepted
being strapped down or in other ways adapting peaceably to the experimental
process, regardless of the acclimation period.

7. Cardiac rate and temperature

The heart rate of Chamaeleo pumilus and C. namaquensis during heating and
cooling was greater during rising body temperatures and lower during falling
body temperatures at the same experimental temperature (Table 14). The
values are similar to that Bartholomew et al. (1965) give for the scincid Tiliqua
scincoides, and Bartholomew & Lasiewski (1965) give for the iguanid Ambly-
rhynchus cristatus. The elevation in chamaeleon heart rates at higher temperatures

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 51

is assignable to the panic and frantic activity shown by both species at these
levels. C. pumilus and C’. namaquensis during cooling slightly elevated heart rates
when their respective thermal preferenda were reacquired during cooling, as
apparently does Amblyrhynchus. Again it must be noted that the cardiac rate of
chamaeleons must be high, since no specimen adjusted to the test, nor was
quiet during readings, their violent struggles being reflected. They seemed
particularly irritated by the probe, which they made frantic efforts to dislodge.
Therefore, except for the lower temperatures from 5 to 10 C, when C. nama-
quensis is torpid, the readings given are for very active animals.

Table 14

Heart rates of 5 Chamaeleo pumilus and 5 C. namaquensis
in relation to heating and cooling at various temperatures.

C. namaquensis C. pumilus
Temp. Heart Beats per Minute
5G Cooling Heating Cooling Heating
5 2,0 0,9 5;0 20,0
10 3,0 6,0 18,0 45,0
15 10,0 44,0 3155 85,0
20 30,0 110,0 85,0 190,0
25 38,5 150,0 100,0 215,0
30 40,0 160,0 Q5,0 205,0
35 50,0 151,3 100,0 185,0
40 65,0 100,0 125,0 200,0
45 77,0 105,0 no record

8. Summation of chamaeleon thermoregulation in comparison with other reptiles ;
role of colour

In summarizing and comparing chamaeleon thermoregulation with other
reptiles, it should be noted that the known saurian usage of physiological
temperature control methods are: (1) toleration of hyperthermia, which is non-
existent in Chamaeleo namaquensis (maximum voluntary body temperature,
39,7 C), or C. pumilus (maximum voluntary body temperature, 37,0 C);
(2) changes in surface-volume ratio by body contraction and expansion;
(3) changes in reflectivity; (4) changes in the cardio-vascular system affecting
heat transport through the tissues.

The ability of chamaeleons to change colour is the most noticeable integral
part of chamaeleon thermoregulation. Aristotle (Crosswell’s translation 1883)
and Pliny (Bostock & Riley’s translation 1887) first recorded that chamaeleons
change colour, the former suspecting this to be a response to light and tempera-
ture. But it is an old fallacy that they do so to match their background, and
such background-matching as does occur is the exception, not the rule, and
quite incidental to the thermoregulatory function. It seems absurd that back-
ground-matching is so widely held —yet so easily disproved by direct observation.
No studies have measured actual body and dermal temperatures at the varied
hues, and their relationships to environmental temperatures or conditions.

This study has reported environmental temperatures and conditions, body

52 ANNALS OF THE SOUTH AFRICAN MUSEUM

temperatures and dermal temperatures at different hues in an integrated
manner in the field and laboratory and in concert with other chamaeleonid
thermoregulatory processes. From this it is concluded that colour change in
Chamaeleo pumilus and C. namaquensis is primarily thermoregulatory, secondarily
camouflage, and least important is background-matching.

Colour lability is a widely recorded phenomenon in invertebrates. The
teleost fishes are the most proficient of colour labile vertebrates. For example,
plaice can even match checkerboards and mosaics. Many reptiles, mostly the
small desert saurians, have a wide range of colour change, and the agamid
genus Calotes has probably the most versatile colour repertory. The young of
some larger forms are colour labile, such as Sauromalus obesus, Alligator mississip1-
ensis, and Crocodylus niloticus. There are pattern component changes in /guana
iguana. ‘The tortoise Chelodina longicollis (Woolley 1956) is colour labile. The
largest living lizards (Varanidae) are not colour labile, perhaps because they
enjoy true endothermy by virtue of their size and proven physiological ability
(Bartholomew & Tucker 1964). Rahn (1940, 1941) and Norris (1967) also
discuss colour change in snakes of the genus Crotalus (Crotalidae), the deserti-
culous Crotalus cerastes being the most versatile at colour change.

The mechanics of chamaeleon colour change are mediated by expansion
and contraction of melanophores in the first, innermost layer of the thick dermis.
In expansion, the melanin extends into tentacle-like arms towards the surface
through the other three dermal layers, which are: a uniform layer of white-
reflecting cells; an irregularly distributed layer of blue-reflecting cells; an
outer dermal layer composed mostly of xanthophores and a few erythrophores.
The thin, transparent epidermis covers these dermal layers. The white-reflecting
and blue-reflecting cells contain no pigment but intracellular-layered crystalline
structures of guanine.

The blue- and white-reflecting cells do not function in colour change, but
the xanthophores and erythrophores contract and expand, acting as a screen
to give weaker or stronger effects. The blue-reflecting cells under the xantho-
phores give the typical green hue in a chamaeleon. The main effectors of
chamaeleon colour change, the melanophores, disperse melanin into the cell
arms which penetrate the other layers to mask one or more of them. Light green
or yellow is mediated by melanin contracted below the white-reflecting layer,
and the dispersal of melanin masking white reflection results in dark green. If
melanin is dispersed over the xanthophores, the chamaeleon appears black.

Reptiles with the ability to change colour have the same complement of
chromatophores as that described for chamaeleons, or some items missing, but
all have melanophores, the chromatophores necessary for colour change.

Questions about colour change revolve largely around control of the
colour mediating structures and secondarily the value to the animal of such
change. It is not the purpose of this study to undertake detailed examination
of the former, but an understanding of the latter is important as to how
chamacleons use colour change to maintain themselves in dynamic equilibrium

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 53

with their environment.

Detailed studies on reptilian colour response, with valuable literature
reviews in some, should be consulted in Atsatt (1939), Briicke (1852), Fuchs
(1914), Hogben (1924), Hogben & Mirvish (1928a, 6), Kleinholz (1938a, },
1941), Kriiger & Kern (1924), Longstaff & Poulton (1907), May (1924),
Parker (1932, 1938, 1948), Rahn (1940, 1941), Redfield (1918), Sand (1935),
Walls (1942), Weber (1881), Zoond & Bokenham (1935), Zoond & Eyre (1934),
for early work, and Canella (1963), Coleman & Livezey (1968), Fingerman
(1965), Hoesch (1961), Norris (1967), Talbot & Livezey (1964) and Waring
(1963) for recent studies. Cleworth (unpublished data) is examining the
electrophysiology of chamaeleon colour change by studies involving electron
microscopy, skin reflectivity at dark and light adapted states, and light magni-
tude necessary to evoke change. Fingerman’s (1965) and Waring’s (1963)
reviews provide excellent treatment of colour changes in all animals; the latter
dealing only with vertebrates.

Colour change in reptiles is under nervous control in the chamaeleonids
(Briicke 1852; Hogben & Mirvish 19284, 5; Zoond & Eyre 1934; Zoond &
Bokenham 1935; Farghaly 1941), endocrine only in the iguanid Anolis (Klein-
holz 1938a, 6; May 1924), and dual in the iguanid Phrynosoma (Redfield 1918;
Parker 1928). Part of the confusion of what mediates control is simply answered
by different animals using different methods, as such would be expected in a
polyphyletic group.

Canella (1963) questioned Hogben & Mirvish’s (1928a, 5) findings on
chamaeleonids that epinephrine is not involved in excitement pallor, an error
suggested by Parker (1938). Canella also found MSH, intermedin, ACTH,
acetylcholine, pilocarpine, and atropine cause darkening. However, the
presence of pigment concentrating nerves of the autonomic system in chamaeleons
is still widely accepted. Perhaps complicating the picture still further is that all
workers on chamaeleonids used species from different species groups (Farghaly:
Chamaeleo vulgaris = C. chamaeleon; Canella: C. jacksoni; Zoond and co-workers:
Lophosaura pumila; Hogben and Mirvish: C. pumulus, the latter two now synony-
mous with C. pumilus). ‘The confusion of the identity of the last workers’ subjects
is reflected in Waring’s (1963) review.

Cleworth (unpubl. data) has kindly summarized for me the results of his
study on Chamaeleo dilepis, C. zeylanica (=C. chamaeleon), C. pumilus and C.
jackson. Work on the last two species was discontinued, because the rough
texture of their skin made reflection analyses difficult. Cleworth standardized
ambient temperatures (22,0-25,0 C) to investigate effect of light on light- and
dark-adapted animals. He found the skin of chamaeleons shows marked
spectral sensitivity. Cleworth found that dark-adapted chamaeleons absorb
heat, which is of considerable value at low temperatures. C. pumilus darkens to
a greater degree than other chamaeleons. Heating effect of light-adapted
chamaeleons is negligible, and is of reflective value at high temperatures.
Regional differences in skin texture are not demonstrable, that is, the sides, the

54 ANNALS OF THE SOUTH AFRICAN MUSEUM

back and the belly are equally reflective. C. pumilus is not quite as reflective as
C. dilepis (C. namaquensis would be more similar to C. dilepis), though this may
not be owing to texture. Chamaeleons absorb a large percentage of incident
light, especially at the near infra-red, with two main absorption peaks cor-
responding to those for water. More light passes through individuals with
stretched skin, and all ‘extra’ transmission is through the inter-scale skin.
Melanin acts as a ‘flat black’ substance over the whole spectral range (300-
2700 my). Cleworth observed migration of the allophore granules. Sub-
cutaneous injection of MSH caused the injected area to go very black, giving
an idea of maximal response. An area of illuminated skin can act independently,
and response of the system to light is rapid, especially darkening.

Complicating studies of colour lability in Chamaeleo namaquensis are geo-
graphic variance of ground and colour pattern, which are discussed in the
reproduction section. Hoesch (1961) gives an interesting account of the colours
and patterns of this species. He found C. namaquensis is whitish gray at environ-
mental temperatures up to 37,0 C, and that it becomes pallid at an environ-
mental temperature of 40,0 C. Hoesch feels this is an adaptation to the desert
in which it lives. He mentions the variation of black coloration covered with
equidistant small white spots, and the variety of colour with pattern, which
make assignment of colour indices a problem in this species. Hoesch also
records a ‘Schreckmuster’ (fright muster) C’. namaquensis assumes when con-
fronted by a predator, for example a snake, Bitis caudalis. It is doubted that it is
a fright muster, since C’. namaquensis assumes it when suddenly sighting a
food item (Fig. 8), or a mate (usually only females). Furthermore, an angry
chamaeleon (see defence in section on behaviour, p. 73) assumes uniform
black (colour index ‘5’). Thus, it is felt that colour index ‘5’ is the fright or
intimidation hue of angry C. namaquensis, as with C. pumilus, and this seems
true of most chamaeleonids. Until further data are forthcoming, Hoesch’s
‘fright muster’ is best considered an ‘excitement pattern’. The speed of change
(<1,6 secs) from uniform pallor completely to this excitement pattern and/or
colour index ‘5’ seems to indicate neutral control.

That chamaeleonid melanophores are served by pigment concentrating
nerves of the autonomic system is generally accepted. The problem is do the
nerves themselves mediate dispersal and contraction, is it humoral, or neuro-
humoral? Zoond & Eyre (1934) found nerve transection caused darkening
of that part of the skin served by the severed nerve. Parker (1938) suggested
that darkening of the skin area after nerve transection is due to excessive stimu-
lation by ‘injury currents’, whereas Sand (1935) thought it due to lack of
stimulation. That is, no nerve to carry the message equals no response, or
darkening. It was frequently observed in wild and captive Chamaeleo pumilus
and C. namaquensis that injuries inflicted in territorial conflicts were a perfect
pallid outline of the attacker’s teeth when the injured chamaeleon was dark
(colour indices ‘4~5’), but the injuries were colour indices ‘4-5’ when these
same chamaeleons were lighter (colour indices ‘<2’). A large C. namaquensis

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 55

attempting to eat a Bitis peringueyi was observed in the field. The viper bit the
chamaeleon on the dorsum in the pelvic region. The fang punctures went
black, surrounded by a small, pallid area. Within a week, these injury reactions
normalized. Of further interest, an ailing C. namaquensis was injected intra-
muscularly in the tail, with 125 000 units of procaine penicillin and 0,12 g
dihydrostreptomycin (‘Strypen’, May & Baker Co.). Ten minutes after the
injection the left side of the head was black and the right side of the head was
pallid, but the rest of the body was all black. Fifty minutes after the injection
this chamaeleon was uniformly black. This might indicate that the antibiotic
interfered with colour lability on an intracellular or enzymatic level.

Somewhat more drastic to the chamaeleons was the observation that before
decapitation, all chamaeleons were uniformly black with rage, but upon
beheading the body became instantly pallid while the severed head remained
black. This reaction did not occur unless the spinal cord was cut, and would
indicate CNS colour control of a high order of integration.

Ailing chamaeleons cannot readily change colour. ‘The symptoms and some
etiological agents are given in the section on parasitism and disease in mortality
(see p. 31). Such affected chamaeleons were always pallid, and unable to
effectively thermoregulate (Table 15). They were unable to warm as fast as
normal chamaeleons who could assume colour index ‘5’. Diseased chamaeleons
also cooled at a faster rate. At higher ambient temperatures the thermal
relationships of sick and normal C’. namaquensis seemed to be the same. Although
some thermoregulatory aids still functioned, it was apparent that even they
were less effective with an upset in thermo-colour-lability, and its attendant
postural changes. Diseased chamaeleons were rarely other than body com-
pression index ‘I’. The skin temperature of such afflicted chamaeleons was
that of the ambient air temperature. Also C’. namaquensis with pneumonia seemed
quite unable to warm or maintain heat. Unfortunately, all these data are
for captives, though individuals in the wild would be more vulnerable to
weather conditions and certainly to predation. Diseased chamaeleons eat
sparingly, if at all, and their high metabolic rate dwindles. ‘This indicates that
colour lability is important in thermo-homeostasis of C. namaquensis and com-
parable data for C. pumilus are available.

Table 15

Thermoregulatory efficiency of diseased and healthy Chamaeleo namaquensts.
Temperatures are in degrees Celsius. Means are shown in parentheses.

Time

from Healthy (N = 7) Diseased (N = 6)
oin Exptl temps Body temperatures Body temperatures

mins 106 1 GO saaban Range Range
30 10,0 10,0 9,5—12,0 (10,5) 7;5-— 955 (8,5)
60 17,0 15,0 18,5-21,0 (20,0) 13,0-14,5 (13,7)
go 33,0 30,0 3395-3525 (3453) 27,0-29,0 (28,0)
120 50,0 35,0 36,5-39,0 (3755) 34,0-37,5 (36,0)
150 55,0 3535 36,5-39,0 (3755) 36,5-39,0 (37,5)
180 45,0 25,0 36,5-39,0 (3755) 26,5-28,5 (27,5)

56 ANNALS OF THE SOUTH AFRICAN MUSEUM

Longstaff & Poulton (1907) discuss the only protective value that colour
may have for C. fumilus. Warming in the morning, a chamaeleon laterally
compressed at body compression index ‘IV’ is black at colour index ‘5’ on the
side to the sun and light at colour index ‘2’ on the opposite side, with the venter
rather static at colour index ‘2’. This counterbalances the diminution of
natural illumination from the open sky as the eye scans from the back to the
sides to the venter on the animal, thus neutralizing shadow and conspicuous-
ness. The light hue of the shade side neutralizes shadow, and the highly illumi-
nated side presented to the light source is toned down by being dark, so the
overall effect is to dissipate solidity. The ornamental knobs and crests disrupt
the body outline melting the chamaeleon into its background. Such protective
coloration may be most valuable to a chamaeleon warming during the cooler
times of day, when assumption of dark (colour index ‘5’) to the sun also has
thermoregulatory value in absorbing warmth. Weber (1881) first proposed
that dark coloration serves chamaeleons for warmth absorption and light for
cooling. At hotter times of the day, assumption of a lighter hue facing the sun
for cooling had less camouflage value depending where the C. pumilus was and
it frequently selected sites which it did not match. The best overall matching
were for chamaeleons on reeds surrounding vleis. The nocturnal resting hue
(pallor) of C. pumilus made it quite conspicuous, and may be due to the old
response of melanophores to contract in the dark.

It is generally regarded that chamaeleons cannot turn or acquire reddish
hues, though erythrophores are in the dermis. On the reddish, interior Namib
Desert dunes, most inhabitant Chamaeleo namaquensis have a pinkish or reddish
ground colour with a pattern of brick-red blotches. On the grayish-white
coastal dunes, most inhabitant C. namaquensis have a basic ground colour of
sulphur yellow with a pattern of brownish or reddish blotches. But when
warming, both inland and coastal phases of C. namaquensis assumed black
(colour index ‘5’) and on their respective substrates alone they were most
conspicuous, especially on foggy mornings. However, where there were scattered
debris on their highly contrasting substrates, the chamaeleons at colour index
‘5 appeared as artifacts and not readily noticeable. The colour variants of
C. namaquensis are most difficult to see at colour indices of ‘<2’ on their respective
substrates.

Thus, reds, especially dark reds, may have the same thermoregulatory
benefits of other dark colours, but a dark red chamaeleon in a green bush on
a cold day would be noticeable and more vulnerable to predation. But a dark
green chamaeleon on red or whitish-gray desert sand would also be conspicuous.
Thus it is felt that red is beneficial for the Namib Desert dune-dwelling Chamaeleo
namaquensis, just as a sulphur yellow or yellowish ground colour is concealing
and valuable in thermoregulation for coastal Namib dune dwellers. Towards
the better-watered and vegetated Great Western Escarpment at the eastern
edge of the Namib, very dark greens appear in the inhabiting C. namaquensis.
hus, colour lability precludes habitat background-matching, since it is pro-

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) i,

tective only at colour indices of ‘2-3’ at thermoneutrality. The complexity of
colours in C’. namaquensis is furthered by the individual variety in base ground
colour and patterns, which is discussed in reproduction under sex determina-
tion and description of adult Chamaeleo pumilus and C. namaquensis (see p. 109).
However, an individual chamaeleon can only change from light to dark, as
Farghaly (1941) and others have noted.

The importance of radiant energy to ecological studies was emphasized
by Gates (1962). All radiant heat energy reaching the earth is divisible into
visible spectrum 40%, infra-red 40% and ultra-violet and radio regions 20%.
As Norris (1967) emphasizes, complicating the assessment of radiation im-
pinging on reptiles are such environmental factors as cloud cover, fog, surround-
ing vegetation, substrates and local topography. Since the skin of a reptile is
its ‘first line’ of defence or adaption to usage and/or protection from such
extraterrestrial emanations, it seems logical that colour lability serves as this
shielding regulator. Radiant energy penetrating an organism may be important
to lizards with a pigmented peritoneum, which may be significant in infra-red
absorption. Thus, as Bartholomew & Tucker (1963) observed, changes in
dermal radiative properties may help in thermoregulation.

Detailed studies of dermal colour lability as it relates to saurian ecology
have been made to date only on American desert lizards, principally iguanids.
Atsatt (1939) pioneered this investigation and others have expanded it. These
are given in the reviews of Norris (1967) and Mayhew (1968).

Atsatt (1939) observed blanching in Uta at 22,0-25,0 C, but the upper
level temperature (30,0 C) used did not produce blanching in the thermophilic
Dipsosaurus because it only emerges (dark hued) at a minimum body tempera-
ture of 33,0 C, but becomes pale after warming to a foraging minimum of 38,0
C. Atsatt found that except for some Callisaurus, which are first pale then dark,
all iguanids at low body temperatures have dispersed melanin, whereas at high
temperatures relative to normal activity levels they assume the light condition.
Between the extremes, temperature is not an overriding influence, and illumi-
nation tends to regulate melanin dispersal. In this middle thermal range
lizards tend to become dark when placed in light and vice versa.

The grasshopper Kosciuscola tristis is black at 15 C; at temperatures greater
than 25,0 C it is a bright greenish-blue, and intermediate shades between 15
and 25 C. Paling occurs two to three hours after sunrise, darkening again in
late afternoon. Colour lability of this orthopteran seems thermoregulatory to
lessen the heating effect of the midday sun (Fingerman 1965). Thermal colour
lability in other invertebrates, especially intertidal crustaceans, is also dis-
cussed by Fingerman, harmonizing with that given for vertebrates.

Virtually all amphibians and reptiles disperse melanin at low temperatures
and concentrate it at high temperatures, agreeing with a thermoregulatory
role. Rivalling any colour labile reptile, the anuran Hyla versicolor is dark at
3,0-5,0 C, and lightens with increased temperature. Deanin & Steggerda
(1948) have shown that a pale Ayla reflects more light, principally the heat-

53 ANNALS OF THE SOUTH AFRICAN MUSEUM

producing longer wavelengths, than dark individuals. Cole (1943) demonstrated
that dark-coloured reptiles more rapidly overheated than light-coloured ones.

Working with several reptiles, Kriger & Kern (1924) showed black in
Lacerta serves for heat absorption and light filtering. Thus, quanta of light
penetrating to the body cavity might harm tissues (this would be ultra-violet
absorbed by DNA), but the skin effectively blocks this when melanin is dis-
persed. Hutchinson & Larimer (1960) confirmed Kriiger & Kern’s finding
that melanin dispersed in the dermis blocks 80% of the radiation from pene-
trating the interior. Therefore, a warming lizard exposing itself to the sun can
achieve warmth without harm. Mayhew (1968) reviews this problem of light
penetrating the body cavity with pertinent references.

The role of the black abdominal peritoneum is often cited as the barrier
to harmful light, but Hunsaker & Johnson (1959) found the outer skin the
chief reflector of ultra-violet, mainly wavelengths of 187-310 my. Porter (1966)
noted most earlier investigators used wavelengths atmospherically absorbed
and not reaching the earth’s surface. Therefore, he used wavelengths (290-
2 600 mp), comprising 97% of the solar energy reaching the earth. His results
showed that the skin is the prime absorber of energy, followed by the muscles,
and then by the black abdominal peritoneum. However, more ultra-violet
than previously thought penetrates to the body cavity.

In Chamaeleo namaquensis there is a transparent abdominal peritoneum
(Fig. 12), with black visceral peritoneum occurring on the digestive tract,
save the stomach, and variously wholly, partly, or absent on the testes. Only
the American deserticulous te1id Cnemidophorus tigris has a transparent ab-
dominal peritoneum among other diurnal series, but this teiid is protected
by a large, immobile deposit of melanin in the dermis. Warming Chamaeleo
namaquensis would be protected from harm by a colour index of ‘5’, but it is
impossible to deduce how it protects itself when at the pale hues in the midday
Namib Desert heat and high illumination, unless; 1) the transparent abdominal
peritoneum has strong reflective capabilities (?); 2) the light phases of Chamaeleo
namaquensis are more efficient in dermal reflectivity than has been previously
recorded (Waring 1963; Norris 1967; Mayhew 1968). Chamaeleo pumilus has
black abdominal and visceral peritoneum, which may wholly or partly cover
the testes, rarely absent, and always shields the uterus. Mayhew (1968) notes
that no lizard capable of marked colour change lacks a black abdominal
peritoneum.

The previous discussion shows that warming reptiles expose themselves
to light (=heat), and how they might protect themselves from the harmful
effects of exposure to the sun; it reports dark phase (colour index ‘5’) for
warming Chamaeleo pumilus and namaquensis, light phase (colour indices ‘<”)
for cooling individuals, and colour indices ‘2-3’ for those at thermoneutrality.
The same findings have been recorded for several American deserticulous
iguanids, such as Dipsosaurus, Holbrookia, Phrynosoma, some Sauromalus, Sceloporus,
Uma, and Uta, tropical Anolis (Ballinger et al. 1970), some gekkonids, several

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 59

agamids, for example, Amp/ibolurus (Bartholomew & ‘Tucker 1963), and
Moloch (Pianka & Pianka 1970), and even snakes, for example, the deserticulous
Crotalus cerastes (Norris 1967).

Norris (1967) computes the net energy gain at lightest phase (71,2 cal/min)
and darkest phase (92,4 cal/min) for Dipsosaurus, a deserticulous iguanid roughly
the same size as Chamaeleo namaquensis. Norris concludes that colour change has
value as a heat flux control for warming Dzpsosaurus. The same seems true for
C. namaquensis and C’. pumilus as well as Dipsosaurus. As Norris points out, the desert
environmental temperature, coupled with local topographic conditions can put
desert species in the centre of a reflector oven, where, he feels, colour lability
would be of minimal value. Here other adaptations might be of importance.

It is doubtful that forced convection from wind is of importance to cooling
in Chamaeleo namaquensis, since this species was often observed active without
discomfort in wind-protected areas between dunes in sizeable pockets of still
air (i.e. a reflector oven). Also, light is very bright in the Namib Desert, particu-
larly in the coastal dunes, with high reflection from the substrate. ‘The air
temperature at two metres and the heat load in a reflector oven are stultifying
and the light dazzling, yet C. namaquensis seems quite at ease, pallid to the sun,
patterned to the reverse, and always at a body compression index of ‘IV’.
C. namaquensis has a white venter, which undoubtedly reflects light and heat
rebounding from the substrate. The venter pattern of C’. namaquensis and C.
pumilus is similar, differing only in colour, and consists of a broad mid-ventral
white or dusky-white band edged by a narrow, conspicuous band of light gray
in C’. namaquensis, greenish in C. pumilus, dorsal to which white resumes up to the
main laterum colour. Reflection from the venter can be cancelled by
adpression (compression index ‘I’) to the substrate. Although most reflectivity
data answer problems of colour lability and thermoregulation for C. pumilus and
C. namaquensis, the problems of a transparent abdominal peritoneum, and the
reflective efficiency of the light phases of the latter yet remain. C. namaquensis
inhabits areas devoid of vegetation, and rarely seeks relief in shade where
shelter is present.

Some workers (Mayhew 1968) see colour as wholly, or chiefly for protective
concealment (Schmidt-Nielsen & Dawson 1964). As Norris (1967) points out,
best matching (see previous discussion p. 56) occurs at thermoneutrality. This
is what Klauber (1939) was considering, actually predicting many findings
made later, and he is not a proponent of colour being primarily for concealment.
Norris (1967) and the author feel that if a dark-hued animal is not concealed
while warming (cf. Chamaeleo pumilus and C. namaquensis), the rate of warming
must be rapid (Table 8), so that thermoneutrality brings concealment coloration.
C. namaquensis follows this, so it can be said that diurnal deserticulous species are
generally conspicuous on pale habitats (cf. the permanently black Pisgah U/a
reported by Norris 1967) when black during warming, but quickly gain conceal-
ment with paler hues at thermoneutrality and cooling. Thus, pale for thermo-
regulation and concealment are synergistic at high environmental temperatures.

60 ANNALS OF THE SOUTH AFRICAN MUSEUM

Unfortunately, no data are available to compare Chamaeleo pumilus with
non-desertic or ‘temperate’ colour labile forms, but it can be said that C.
pumilus, subjected to prolonged cool environmental temperatures, 1s concealed
best while warming at a colour index of ‘5’ (reverse of desertic lizards) and at
thermoneutrality, and quite conspicuous at the palest hues.

g. Summation of chamaeleon thermoregulation in comparison with other repizles ;
role of posture

Body compression and associated colour lability in thermoregulating
Chamaeleo pumilus and C. namaquensis are discussed in detail on pages 42-7.
Body compression ‘I’ gives chamaeleons an ellipsoid shape in cross-section,
increasing surface area by 30% and body width by 33,3%. The surface area
of the back is especially increased, acquiring the outline of a large sphere. (See
Norris (1967) for the value of this.) This posture, in adpression to the substrate
minimizes convective heat loss, and concentrates initial warming on the mid-
dorsum. Heating is exaggerated on the lungs of both chamaeleons and the air
sacs of C. namaquensis, which lie close to the dorsum when inflated, and also
on the dorsal aorta. The essentially body compression ‘II’ is considered the
‘normal’ body form and is a posture at thermoneutrality. ‘The slightly laterally
compressed body compression ‘III’ which only reduces body width by 10% is
the other posture at thermoneutrality. Body compression ‘IV’ reduces body
width by 30%, and increases the total surface area by at least 110%. Fine
orientation increases or decreases the intensity of impinging insolation, such
as the longitudinal axis presented with the head to the sun with the light
striking on both sides of the chamaeleon’s body; lateral body compression with
the centre of one side directly facing the sun, or slanted so the sun obliquely hits
that side. Frequently the chamaeleons tilted, so both sides received the sun,
concentrated on the dorsum.

Body compression, mostly dorso-lateral flattening, has been recorded for
various forms, for example, Anolis (Ballinger et al. 1970), Amphibolurus, Sauromalus
and Crotalus (Norris 1967), and Uta (Burrage 1966). Heath (1962a) found that
Phrynosoma facing into the sun achieves a more reduced heat load than when
in the opposite position. Greatest heat load is when the lizard presents itself
broadside to the sun.

Lillywhite (1970) demonstrated behavioural thermoregulation in the
anuran Rana catesbeiana. By postural adjustments, this frog maintains active
body temperatures of 26,0 to 33,0 C (x=30,0 C), using pond water as a heat
source or sink. Body temperatures of these frogs closely followed that of the
dry bulb air temperature.

10. Summation of chamaeleon thermoregulation in comparison with other reptiles ;
roles of the lungs, the cardiovascular system and temperature control centres

D) . : ; ;
Previously, lungs do not seem to have been considered as thermoregulatory
aids in reptiles and information on this is circumstantial, since no probes were

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 61

inserted into the lungs or air sacs of the chamaeleons. As stated, the air sacs of
Chamaeleo namaquensis were pumped and held full during warming, and alternately
filled and flushed in cooling. ‘The distal parts of the lungs in C. pumilus acted as
air sacs. Tornier (1904) made an exhaustive study on chamaeleon air sacs,
including those located in the gular and occipital regions, which possibly aid
in maintaining cranial thermo-homeostasis. ‘Tornier showed that the air sacs
are valved to regulate the passage of air, which is shunted in and held. He
showed their value in puffing-up in defence, which this study endorses. How-
ever, the distal parts of the lungs of C. pumilus and C. namaquensis and the air
sacs of the latter serve as dead air spaces, which when full and closely adpressed
to the body wall could act as temperature stabilizers or reservoirs, maintaining
even temperatures or insulation from high temperatures for the reproductive
organs and other vitals to which they are closely adpressed (Fig. 12). Body
compression increases the surface area of the lungs and air sacs. Couvreur &
Gautier (1904) found a distinctly thermally correlated respiratory pattern in
C’. chamaeleon. involving flushing of the air sacs at 42,0 C.

Bakker (1971), in his paper on the probable physiology of dinosaurs and
other archosaurians, postulates that chamaeleonids may use their lungs and air
sacs in thermoregulation and/or for protecting their gonads. It seems that this
suggestion is valid.

It could be assumed that chamaeleonids are not alone in using their lungs
for thermoregulation, and that Varanus similarly uses its lungs. The lungs in
Varanus are large, as in the chamaeleonids, and occupy a large part of the
thoracic cavity, closely applied to the dorsal surface of the body cavity. When
warming, Varanus flattens in the sun and laterally expands, increasing the
surface area of the lungs. Since many reptiles do likewise, the role of the lungs
in thermoregulation may be widespread.

The peculiar anatomy of the squamate heart (White 1959) and great
vessels consists of a ventricle imperfectly divided into dorsal and ventral
chambers. The ventricular base communicates with the atria, the right and
left systemic arches and the pulmonary artery. The systemic arches join sym-
metrically, forming the dorsal aorta just posterior to the heart. The right
systemic arch is the only supply to the head and anterior parts, other than a
small connection from the left arch. This arrangement could favour a device
for increased cardiac output for heat transport by allowing large volumes of
venous blood to bypass pulmonary resistance. Concurrently, well-oxygenated
blood could be supplied to the brain via the right systemic arch. Cardiac output
could increase beyond the need for respiratory exchange without the energy
expense to pass the whole cardiac output through the pulmonary circuit and
without cutting the oxygen supply to the brain. The incomplete ventricular
septum hypothetically could allow venous blood to exit directly via the left
systemic arch and continue to the posterior parts of the body. Experimental
data (White 1959; Tucker 1966; Baker & White 1970) have shown that the

blood in the left systemic arch has an oxygen content equal to or somewhat less

62 ANNALS OF THE SOUTH AFRICAN MUSEUM

than that of the blood in the right systemic arch, but not vice versa, agreeing
with the hypothesis that this arrangement could be of thermoregulatory value.

Thus, in warming, an open pulmonary circuit, with high systemic
resistance, favours a cardiac left-right shunt, increasing the pulmonary blood
supply for warming, with a well-oxygenated blood supply to the brain and
major sense organs via the right systemic arch. When warming is completed
the increase of pulmonary resistance would invoke a proper double circulation.
Increase of this resistance would result in a systemic arch circulation, thus
enabling the reptile to conserve heat through toleration of high anoxia in the
posterior trunk. (See Gordon, Bartholomew, Grinnell, Jorgensen & White
(1968) and Tucker (1967) for a discussion of reptile circulation, respiration and
temperature control centres.)

An efficient peripheral vascular circulatory arrangement, involving shunts,
is necessary for dermal heat absorption or reflection to have any importance
in body temperatures. Cowles (1958) pointed to the importance of dermal
temperature regulation in the development of endothermy. His elaborate
experiments showed that lizards in fur coats benefited from insulation only
when warmed. According to Cowles, in amphibians the vascularized dermis
serves chiefly in respiration, but possibly the dermis also had a thermoregulatory
function in extinct terrestrial labyrinthodonts. In reptiles the dermis serves in
thermoregulation. In the truly endothermic birds and mammals the dermis
functions in thermoregulation with fur or feathers for insulation.

Experimentally, Cowles (1958) demonstrated in Dzpsosaurus dorsalis a
temperature gradient is greatest during heat absorption; not so in cool air.
Subdermally injected water blebs heated on one side only, showing that the
heat is more rapidly dispersed on the radiated side, heat being transferred to
the body interior in warming lizards. The dermal vascular supply was greater
at higher warming temperatures. Trying Cowles’s method with Chamaeleo
pumilus and C’. namaquensis yielded equivalent results, and at high temperatures
the blebs were cooler on the radiated surface, indicating cooling. In cooling
(pallid) chamaeleons, there was no gain in bleb temperature, indicating peri-
pheral dermal vasomotor control, which may be mediated by the change of
pigment dispersal itself. A lizard being cooled constricts peripheral circulation
to preserve body core heat—as does one resting at night, and dilation of peri-
pheral circulation upon basking allows a warmth exchange with the interior.

Bartholomew (1966), Bartholomew & Tucker (1963, 1964), Bartholomew,
et al. (1965) and Weathers (1970) report representatives of the Agamidae,
Iguanidae, Scincidae, Gekkonidae, and Varanidae heat faster than they cool.
Some of these differences are attributable to endogenous heat production and
circulatory adjustments. The degree of circulatory control of heat transport
varies. In the agamid Amphibolurus barbatus 75° of the difference in heating
and cooling is assignable to circulatory changes, but in the skink Tiliqua
scincoides this difference is due to endogenous heat production. Waranids are
intermediate. Much the same situation is seen in the marine iguanid Ambly-

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 63

rhynchus cristatus (Bartholomew & Lasiewski 1965). In the sea the cardiac rate
drops and the peripheral vessels are constricted, with tolerance of anoxia in the
body tissues, especially when diving. Basking on land, the peripheral vessels
dilate as the cardiac rate increases. Thus, it should be emphasized that an
increased cardiac rate and/or vascular bed adjustments are important in this
process.

Heath (1962a, 1964a, 5b, 1965, 1966) has demonstrated differential head-
body temperatures of as much as 3 C to 5 Cin partly buried Phrynosoma, and
De Witt (1963, 1967a) found this to be true also for Dipsosaurus dorsalis. Bruner
(1907) describes sphincter muscles around the internal jugular veins. Con-
traction of these muscles reduces the flow of blood from the head. Closure of
the internal jugular veins accompanies an increased heat flux from the head to
the body in Phrynosoma, which Heath (1963) feels may be important in the
thermoregulation of these lizards. Dissection revealed sinuses in the head of both
Chamaeleo pumilus and C. namaquensis, but their functional significance was not
investigated; they may possibly serve as in Phrynosoma and Dipsosaurus. Such
a cranial circulation, as with peripheral circulation, would involve shunts.

Sensitivity of some centre is required to mediate reptile body temperatures
to stability through use of the physiological methods discussed. Adams (1957)
showed that chamaeleons possess a carotid body, very similar to that of mam-
mals, which mediates blood pressure by increasing and decreasing stroke
volume. ‘The nature of the chamaeleon carotid body, the peculiarity of the
chamaeleon lungs and air sacs, the nature of the squamate heart and great
vessels, and the peripheral and cranial vascular supply would suggest a role of
the cardiovascular system in thermoregulation.

Hammel, Caldwell & Abrams (1967) and Cabanac, Hammel & Hardy
(1967) showed for the skink Tzlzqua scincoides a thermally responsive (3 cold
neurons, 5 warm—heat sensitive) region in the preoptic part of the brain.
Heating or cooling the brain stem resulted in the appropriate behavioural
thermoregulation for stabilization, but prematurely at higher or lower tem-
peratures than normal. However, dermal and body temperatures also impinge
on thermoregulation in this species. Saalfeld (1936) found similar thermal
receptors in the medulla of lizards. Rodbard (1948), Rodbard, Sampson &
Ferguson (1950) and Heath, Gasdor & Northcutt (1968) made similar findings
for turtles.

This study records panting in Chamaeleo pumilus and C. namaquensis. Temple-
ton (1960) showed for Dipsosaurus dorsalis and Dawson & Templeton (1963)
for Crotaphytus collaris that panting dissipates 1,3 times the metabolic heat
production at 44,0 C and felt the water loss negligible. Chamaeleo pumilus and
C. namaquensis can easily maintain their water requirements, so this method
of cooling could be most effective for them. Panting is recorded in several
lizards (Dawson 1967; Mayhew 1968), except those that are not heat-resistant
(e.g. Eumeces obsoletus), who pant weakly, or not at all, even under thermal stress.
Varanids have a strong gular pumping action at high temperatures. Panting

64 ANNALS OF THE SOUTH AFRICAN MUSEUM

ensues close to the maximum voluntary body temperature, except in Chamaeleo
namaquensis in which it begins early (see p. 47). Richards (1970), in a detailed
review of panting, concludes that it is an ancient method, and true endothermy
may have originated as a response to dissipating endogenous heat in hot
environments.

11. Oxygen consumption

Table 16 shows oxygen consumption, breathing rate, and Q)) for Chamaeleo
pumilus and C. namaquensis at rest and activity. Peak oxygen consumption was
at 25 C for C. pumilus and at 35 C for C. namaquensis. ‘The large increase in oxygen
consumption for C’. pumilus at 40 C was a reflection of the frenzied escape activi-
ties of the subjects at this temperature, and is so out of pattern and based on
such few frantically active individuals that it might be advisable to ignore it.
This seems odd, since C’. pumilus was encountered in the field at environmental
temperatures of nearly 40 C, but had a lower body temperature, perhaps
assignable to the ease of thermoregulating in nature which they could not
properly undertake in the oxygen consumption chamber. Except for those
C. pumilus at 40 CG, both species showed a reduction in oxygen consumption
past their thermal preferendum. There was an apparent temperature difference
in oxygen consumption between coastal and inland C. namaquensis, though
they are reported here as a unit.

Literature reviews of the oxygen consumption of lizards are given by
Dawson (1967), Tucker (1967) and Mayhew (1968). In the thermophilic
Cnemidophorus tigris (ted), and the less heat-resistant Gerrhonotus multicarinatus
(anguid) and Coleonyx variegatus (eublepharid) the Q,, remains constant over
at least 20 C, including low temperatures (Dawson 1967), but in the thermo-
philic iguanids Crotaphytus collaris, Dipsosaurus dorsalis and Uma notata, and the
less heat-resistant xantusiid Xantusia vigilis, the Qj) varies with temperature,
usually decreasing as the animals become warmer (Cook 1949; Dawson &
Bartholomew 1958; Dawson & ‘Templeton 1963). The equivalent-sized
Dipsosaurus dorsalis and Crotaphytus collaris have lower resting metabolic rates
between 35-40 C than the less heat-resistant skink Eumeces obsoletus (Dawson
1960) and Gerrhonotus multicarinatus (Dawson & Templeton, unpublished data,
see Dawson 1967), possibly because the first pair have lower oxygen require-
ments at high body temperatures. Below 15 C the heat-resistant forms show
somewhat higher values than those that are less heat-resistant, indicating some
cold sensitivity of the former.

Mayhew (1965) found in Phrynosoma m’calli (iguanid) oxygen consumption
increased until 35 C, with a metabolic plateau at 35-40 C and a marked
increase resumed at 45 C. He sometimes found quite a difference in oxygen
consumption of laboratory and field measurements, though recorded under
apparently indentical conditions. Bullock (1955) noted that such metabolic
plateaus are not unusual. Schmidt-Nielsen, Crawford & Bentley (1966) record
the iguanid Sauromalus obesus to have continuous oxygen consumption curves,

65

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN)

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66 ANNALS OF THE SOUTH AFRICAN MUSEUM

but some had periodic peaks interrupted by periods of no detectable oxygen
consumption, with a highly variable oxygen concentration of the air in the
lungs.

Resting Chamaeleo pumilus showed a gradual increase in the Q)4, of oxygen
consumption values up to their thermal preferendum, but between 25-35 C
the Q,, dropped to the same level (1,20) as that from 5-15 C. Resting C.
namaquensis oxygen consumption Q,,) values were variable, though generally
increasing with temperature. The Q,) values of both these species of chamae-
leons suggest they are in the less heat-resistant category of lizards.

In maximally active lizards Bartholomew & Tucker (1963) showed the
QO. of oxygen consumption in the agamid Amphibolurus barbatus to increase
rapidly between 15-20 C, but to decrease thereafter. In Varanus spp. (Bartholo-
mew & Tucker 1964) and the skink Tzliqua scincoides (Bartholomew et al. 1965)
the maximal rates of oxygen consumption at various temperatures have a
constant Q,, between 20-40 C, which are lower than the corresponding ones
for resting animals. Iguana iguana between 15-30 C. shows an active Qj,
exceeding that for resting individuals. Active Chamaeleo pumilus had the greatest
Q.4) value (1,29) for oxygen consumption over 5-15 C, dropping slightly
(1,26) over 15-25 C within the thermal preferendum of this species, thereafter
dropping sharply. Oxygen consumption of active C. namaquensis had a Qj) of
1,47 between 15-25 C, with the greatest Q,) value (2,91) between 25-35 C
within the thermal preferendum of this species, dropping very sharply (0,64)
thereafter. C’. pumilus and C’. namaquensis active Q,, values were greater than
those for resting individuals, except for the respective values at 25-35 C
(C. pumilus) and 35-45 C (C. namaquensis) when the reverse was true.

Measurements of metabolic rates of maximally active and resting lizards
may indicate the available energy to them for activity at various temperatures
(‘scope for activity’ of Fry 1947). Moberly (1964) notes that this is complicated
by indications that these animals rely extensively on anaerobic metabolism
during activity, so oxygen consumption measurements may not give the full
extent of energy utilization. Schmidt-Nielsen, Crawford & Bentley (1966)
report continuous oxygen curves for Sauromalus obesus (iguanid), but other
curves had periodic peaks interspersed with periods when no oxygen con-
sumption was detectable. The same phenomenon was observed in C. pumilus
and C. namaquensis. Aerobic scope for activity is maximal at 20 C for Amphi-
bolurus barbatus, approximately 15 C below the activity temperature and
thermal preferendum of this species. Jguana iguana has its maximum aerobic
scope for activity at about 31 C; five degrees below its activity temperature.
But in Varanus spp. with activity temperatures between 35,5-37,1 C and Tiliqua
scincoides with an activity temperature of 32,6 C, the aerobic scope for activity
increases with temperature between 20-40 C.

Without comparative data for other chamaeleonids, generalizations of data
for Chamaeleo pumilus and C. namaquensis to that for other lizards have little
meaning. All lizards discussed in the above paragraph were stimulated to

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 67

maximal activity by electric shocks. Since chamaeleons struggled ceaselessly,
electric shocks seemed unnecessary. C. pumilus appeared, however, to follow the
pattern of Amphibolurus barbatus, whereas the greatest aerobic scope for activity
of Chamaeleo namaquensis was at its thermal preferendum, which may corroborate
its ability to stabilize its body temperature by the physiological methods
discussed elsewhere. The slightly higher Q,, of C. pumilus between 5-15 C
indicates its ability to be active at low temperatures.

Water loss in respiration is discussed in the section on ‘Water and salt
balance’, and further remarks on metabolism are given in the section on ‘Food

habits’.

12. Activity patterns: daily and seasonal

Chamaeleo pumilus and C. namaquensis emerged from overnight spots inde-
pendent of weather in all seasons. To be sure, prolonged days of rain discouraged
C. pumilus activity in the open, but it was active within dense vegetation, which
afforded shelter from heavy, driving rain, and probably more importantly from
strong accompanying winds. Soft rain and occasional intermittent showers had
no marked effect on discouraging activity in the open. In fair, or cloudy
weather C’. pumilus spent the night in exposed conditions, so that the first rays
of the rising sun struck them early. Thus, C. pumilus was active as early as one
hour before sunrise. ‘This was particularly true of ‘Fair Warm’ days, though it
must be remembered that the environmental temperature (T,50 mm) was
often quite warm. A daily minimum in summer of 11,5 C (T,2 m) was recorded,
and a summer minimum as low as 6,0 C has been officially recorded.

The daily temperature regimens of C’. pumilus are given in Table 17.
Cloud cover of 30°% or more was considered overcast, since at that minimum
coverage alteration of environmental temperatures was noted. Inspection of
the data for “Cool Cloud’ and ‘Cool Rain’ show chamaeleon body temperatures
to be higher than environmental temperatures. And as previously emphasized,
high chamaeleon body temperatures were not necessarily recorded with high
environmental temperatures. Details of heat maintenance are given in the
thermoregulation: warming/cooling section (pp. 42-7). Excessive heat was
not a problem for C. pumilus, since it mitigated this by resorting to shade.

C’. pumilus retired for the night at paler hues and with body temperatures
higher than those at emergence. This was about the same time as sunset.
Retiring with paler hues may be an effect of insufficient light intensity to
excite melanin dispersal, as Cleworth’s (unpublished data) experiments
indicate. Dermal heat exchange is reduced by a lower heart beat and peripheral
vasoconstriction would conserve body core heat by reducing the blood flow to
the periphery.

Chamaeleo namaquensis spent the night in various shelters, such as burrows,
rock crevices, in thick vegetation, and sometimes in the open. Those not in
burrows always ended their daily activity in the shade away from the setting
sun to the lee of some object. This strange behaviour proved as ‘correct’ as

68 ANNALS OF THE SOUTH AFRICAN MUSEUM

C. pumilus settling down in exposed sites, since both methods afforded access to
the first rays of the rising sun on the following morning. The previous remarks
for C. pumilus upon retiring are also applicable to C. namaquensis, except of a
night when the latter goes into a full torpor from which it was very difficult to
arouse.

Body temperature data for Chamaeleo namaquensis are in ‘Table 17. Overcast
criteria are as for C’. pumilus. But it should be noted that fog was the usual
overcast type for C’. namaquensis, especially coastal populations, for which no
distinction is made for drizzle, the rare event of rain, or whether the fog was
down to the ground or at what altitude.

Of note was the stability and often narrow range of C’. namaquensis body
temperatures after initial warming, as compared to that of the environmental
temperatures, regardless of the population considered. Highest and lowest
environmental temperatures were recorded at the coast.

There is no inland record for ‘Cool Overcast’. The substrate in ‘Cool’
months heats almost to as great (48,5 C) a maximum as it does in ‘Warm’
months (58,0 C), though the corresponding maximum body temperature
records at these readings were 39,7 GC (‘Cool’), and 37,0 CG (‘Warm’). ‘Warm
Overcast’ has maximum environmental temperatures eight degrees cooler than
‘Warm Fair’.

Coastal populations were subjected to more varied environmental tempera-
tures than those recorded at inland locales. Coastal ‘Cool Overcast’ environ-
mental temperatures were as low as 8,0 C, and the coastal “Warm Fair’ maxi-
mum environmental temperature was 67,0 C. The body temperatures of active
C’. namaquensis, subject to these environmental temperatures, were 14,0 C and
34,2 C, respectively. For ‘Partly Cloudy’ conditions, the clearing of the fog
was reflected in a sudden increase of the environmental temperatures, whereas
the environmental temperatures drop upon the return of the fog. Of especial
note with both C. namaquensis populations was the rapid increase in warming
body temperatures in the early part of the day and the stability and narrow
body temperature range independent of the environmental temperature
throughout the bulk of the day. So, too, towards the end of the day body
temperatures stabilized, even slightly rose, or declined very little in comparison
with the rapidly dropping environmental temperature. Wind intensity has no
effect on the activity of C. namaquensis. The thermal qualities of the surface of
the substrate are discussed in the relevant section on habitats (pp. 28-9),
and at depths in Table 45 in the discussion of incubation in the section on
reproduction (see p. 115).

First daily order of business of Chamaeleo pumilus and C. namaquensis was
basking (= warming), which upon their body temperatures reaching minimum
operating levels (3,5 CC. pumilus; 14,0 C C. namaquensis), defecation, drinking,
feeding and courting (see Behaviour, p. 72) usually followed. The previous
arrangement is not meant to imply that this was the order followed, since
neither chamaeleon was averse to forgoing drinking for a delectable prey item,

69

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN)

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70 ANNALS OF THE SOUTH AFRICAN MUSEUM

an attractive mate, or repelling an invader. Also, some items are performed
concurrently. C. pumilus frequently resorted to ‘emergence’ warming basking on
cold or inclement days, though C’. namaquensis rarely did so, even in drizzle and
strong wind, though it did turn black (colour index °5’) and assumed body
compression index ‘IV’. So, too, C. namaquensis (pallid to the sun, patterned on
the side in the shade) was abroad during midday heat on the hottest days,
though it would be hard put to find shade in such localities as the featureless
gravel plains.

Chamaeleons appear to be wholly diurnal, as Uible (1968), Rosen (1950)
and Spence (1966) report for those in the field, and Bustard (1965, 1966) and
Von Frisch (1962) record for captives. In captivity chamaeleons kept pretty
much to their wild regimen, but some captive C. pumilus and C. namaquensis
were not averse to eating at night if illumination was provided. ‘The exception
was for captive females excavating nests, which is discussed further in the section
on reproduction (p. 114).

Details of daily and seasonal activity for other diurnal saurians can be
consulted in Mayhew (1968) for comparison with Chamaeleo pumilus and C.
namaquensis. Excluding brumating species, as a rule seasonal changes include
later daily emergence and earlier retreat in the cooler months, taking into
account the effect of sunrise and sunset. Heath (1962a, b) records temperature-
independent emergence in the iguanid Phrynosoma. Burrage (1966) found that
different substrates have different thermal gradients and that this controls
emergence in the iguanid Uta stansburiana hesperis, regardless of the weather.
‘Normal’ emergence, though, is about sunrise, or its equivalent. Ground fog
has a delaying effect on uta emergence, but high thin fogs and no wind favour
a ‘greenhouse effect’, aiding substrate heating. These emergent control factors
are also noted in another iguanid, Sceloporus orcutti (Mayhew 1962), and the
te1ids Cnemidophorus sexlineatus (Fitch 1958; Hardy 1962), C. sacki, C. perplexus,
C. tessellatus and C. tigris (Milstead 1957). The daily order of business and
retreat time for most other saurians is as described for chamaeleons, but Uta
stansburiana is active up to an hour after sunset (Irwin 1965; Burrage 1966) as
is Urosaurus (Shaw 1950).

Midday increase in substrate temperatures and wind intensity are generally
regarded as forcing saurians into retreats (Tinkle 1967, and Irwin 1965, for
Uta stansburiana stejnegert; Milstead 1957, for Cnemidophorus perplexus, C. sackt,
C. tessellatus and C’. tigris; and Bostic 1964, for Cnemidophorus hyperythrus). These
factors do indeed have some correlation, especially for winds greater than
9,3 kph. But, as Burrage (1966) reports for Uta stansburiana hesperis, this may
not be true on closer inspection, as utas are quite abundantly active under open
vegetation, where the effect of wind is lessened and cooler substrates are found.
Also, wind effect may be indirect, since utas restrict their activity to wind-
protected sites because their prey are limited to such situations. Thus, the
lizards go under open vegetation to find their prey in a concentrated and
perhaps more vulnerable situation. Chamaeleo pumilus in intensifying wind some-

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 771

times restricted its activity to plant cover, because the flying insects which form
its main prey were restricted to protecting vegetation by strong winds. Chamaeleo
namaquensis was active in the strongest winds with blowing sand in the air and
small gravel blown along the ground. Under such conditions, its prey was also
abroad, even in winds strong enough to upset beetles and small lizards, such as
Eremias.

G. Behaviour

1. Senses

Most studies of the senses of chamaeleons focus on their highly developed
visual acuity, and it seems strange that the auditory organ should either not
have developed (Hamilton 1960; Schmidt 1964) or degenerated (Miller 1966).
While the auditory apparatus of chamaeleons is unique, the chamaeleonid
cochlear duct could result from regression of the agamid type (Miller 1966).
Only six of the 100-odd chamaeleon species have been studied: Chamaeleo
vulgaris (= CC’. chamaeleon) by Versluys (1898) and Parker (1880); Mucrosaura
pumila (= C. pumilus) by Parker (1880), Engelbrecht (1951) and Toerien (1963) ;
Lophosaura ventralis (= C. pumilus) by Brock (1940); Chamaeleo senegalensis and
C. quilensis by Wever (1968); Brookesia marshallu by Toerien (1963); B. super-
ciliaris by Siebenrock (1893) ; Rhampholeon platyceps by Frank (1951) and Toerien
(1963). The two common features of the auditory apparatus of those chamaeleons
examined (see also detailed summary of Baird 1970) consists of: no tympanic
membrane; fenestra ovalis very small, or absent. Other variations and details
in the previously mentioned species can be had by consulting the preceding
sources.

Anatomically, it appears that Chamaeleo pumilus would be deaf to air-borne
sounds. Blindfolded individuals did not respond to the shaking of a pebble-
filled can nearby, nor to a rock impacting on the ground. They did respond
to something hitting a branch, but this could also be tactile. Wever (1968)
showed that C. senegalensis and C. quilensis have a poor auditory sensitivity in
comparison to other lizards, yet not far below that in many species with a
conventional auditory apparatus. Wever (1968) found C. senegalensis and C.
quilensis to have a frequency range extending from 100 to 10 000 cycles per
second, with best sensitivity in the region of 200 to 600 cps. Blindfolded C.
namaquensis were very alert to ground-borne sounds, as a rock dropped on sand,
and particularly on a rocky or gravel surface. Shaking a pebble-filled can
nearby caused them to turn and hiss in its direction.

The sight of chamaeleons is almost a legend in zoology. Excellent dis-
cussions of the chamaeleon eye and the host of pertinent literature are given
by Johnson (1927), Walls (1942), Polyak (1957) and Underwood (1970).
Polyak’s account of vision in vertebrates is most valuable, noting the same
chamaeleonid-type eye mobility and perhaps visual acuity in the American
iguanid Anolis carolinensis, with binocular stereoscopy in this and several other
forms. ‘The more chamaeleonid-like Chamaeleolis chamaeleontides is an even more

72 ANNALS OF THE SOUTH AFRICAN MUSEUM

perfect duplicate (Wilson 1957). In Anolis, Polyak (1957) describes a ‘sighting
groove’, a black area of decreasing width anteriorad, running from the anterior
margin of the eye to the tip of the nose, which also occurs in esocid fish, among
others. In the chamaeleonids this sighting groove is structural, rather than
pigmented. It is widely stated in the literature that the chamaeleon eye is of
‘unerring accuracy’, and completely dependent on the functioning of both
eyes. This study showed that nothing was further from the truth; especially in
the latter instance.

Normal Chamaeleo namaquensis had an accuracy of 80 to 90% (X = 85,0%),
but was usually a painstaking aimer, sighting at an object, positioning back and
forth, and even taking sightings from different angles. C. pumilus and C. nama-
quensis often shot at moving prey, which conflicts with what Von Frisch (1962)
notes for the former. Normal C. pumilus also tended to shoot with far less
preliminaries and was accurate 75 to 92% (x = 86,0%) of the time. Dis-
counting those temporarily blinded by the stings and bites of captured prey,
several C. pumilus were found with only one functional eye. While the extent of
this partial vision disability varied between individuals, some had one eye
completely ripped out. These chamaeleons with only one functional eye had an
accuracy of 57-63% (kX = 60,0%). They aimed by fixing their sole eye on the
target and slowly turned the head to face the target before shooting out their
tongue. Adhesive tape on one eye was used to experimentally blind twelve each
of C. pumilus and C. namaquensis; they were then allowed 24 hours’ acclimatiza-
tion. The chamaeleons were then given five daily trials at prey, all scoring zero
on the first test day. By the close of the second day, the accuracy of both species
Was 15 to 30% (k = 22,7%), by the end of the third day, 45) ton5q gu
50,1%), and by the end of the fourth day, 57 to 62°, (x = j0,0 7) aluney,
aimed in the previously described manner of naturally partly blind C. pumilus.
If initially the left eye had been experimentally covered, there was no change
in fourth day individual accuracy if the right eye was subsequently covered on
the fifth day.

Of all squamates, Jacobson’s organ is least developed in the chamaeleonids,
and it may be reduced to a small pit without a mushroom body, as in Microsaura
pumila (= Chamaeleo pumilus) (Malan 1946; Engelbrecht 1951), or absent in
Rhampholeon (Frank 1951). Haas (1947) feels it is debatable as to whether

Jacobson’s organ has any sensory function in the chamaeleonids (Parsons 1970).

2. Defence

Chamaeleons habitually select a site as a retreat for the night, as is
recorded for Chamaeleo dilepis (Wager 1958; Brain 1961), Microsaurus pumilus
(= C. pumilus) of Von Frisch (1962), and Microsaura damarana (= C. pumilus) of
Spence (1966), Chamaeleo pardalis (Bourgat 1968)), C’. jackson: (Bustard 1958),
C. hohneli: (Bustard 1965) and C. bitaeniatus (Bustard 1966). In the case of
arboreal forms, this is a favoured perch on a twig. While this was true of
C’. pumilus, in heavy rains it would climb to the underside of a large leaf and

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 73

in its manner of gripping it, create a satisfactory umbrella.

Both sexes of C. namaquensis, in the field and in captivity, occasionally
constructed burrows for retreats. While some were undoubtedly abandoned
small rodent burrows, others were purposely dug by the chamaeleons. They
were less elaborate than a nest burrow (see reproduction, p. 114). A retreat
burrow constructed by a male 90 mm snout-vent, consisted of a terminal
chamber 95 mm long, 63 mm wide, and 38 mm from the floor to the ceiling.
The roof of the terminal chamber was 75 mm from the surface of the ground,
and a narrow, gently sloping passage led 200 mm to the surface. Retreat
burrows of C’. namaquensis were usually located in some sort of a redoubt, as
clumped vegetation, where the binding roots gave the soil greater cohesiveness,
eliminating the danger of cave-ins. Those inhabiting rocky areas either used
crevices and fissures in the rocks, or dug burrows in the gravel between rocks.
Terentiev (1961) records fossorial habits of Saharan Chamaeleon vulgaris
(= Chamaeleo chamaeleon). Similar burrows are dug by the European lacertid
Lacerta vivipara (Burrage 1961), and by the American iguanid Uta stansburiana
hesperis (Burrage 1966).

Camouflage value through colour lability in chamaeleons is synergistic
with thermoregulation only at certain temperatures (see pp. 56-7, 59-60).
Colour change in chamaeleons is primarily not for concealment, since when
annoyed they become black, irrespective of background, and quite conspicuous.
Thus, some colour lability in chamaeleons is emotional as the ‘excitement
pattern’ of Chamaeleo namaquensis (p. 54). Schmidt & Inger (1965) note a
normal C’. zturiensis is forest green with large, irregular black spots, becoming
dark if annoyed, but light green if victorious in combat (Bustard 1965, 1966,
1967c).

Upon the approach of a potential source of harm, Chamaeleo pumilus on a
twig nearly always turned in an attempt to put the twig between itself and the
object of its fear. The value of this is questionable, as in turning it flashes the
longitudinally striped ventrum, which directs attention to its movement. Those
that remained still were more difficult to detect. If annoyed, or faced with the
further threat of harm, they frequently dropped and fell, as is described for
C. dilepis (Brain 1961), or attempted escape in flight, without the wavering
gait. C. pumilus did not feign death, as recorded for C. dilepis by Brain (1961).

_C. namaquensis attempted escape in evasive flight, and could run very fast.
However, if chanced upon when at rest, it kept perfectly still, except for the
eyes, which rivet on its tormentor. There was no colour change, nor any
reaction to having hands passed over them, or fingers straddling them. How-
ever, even if lightly touched, especially in the inguinal region, C. namaquensis
exploded into challenge and fury. Leaping to a high, stiff-legged stance, it
quickly became black, and inflated and laterally compressed the body. The
throat was gorged, showing the yellow, reddish-orange interstitial skin, and the
mouth held widely agape, accompanied to hissing (sounds like ‘bissss’), and it
often emitted a guttural growl (sounds like ‘rrrr’). The mouth of adults has a

74 ANNALS OF THE SOUTH AFRICAN MUSEUM

yellow-orange interior, while that of the young is black. In this display, C.
namaquensis turned and faced and frequently rushed its tormentor if further
annoyed. Such action was usually quite startling and, in a moment of hesitation
on the part of its antagonist, the chamaeleon changed to a lighter pattern and
attempted to escape. It was most vicious when trapped, making repeated
charges, and snapping its powerful jaws. While C. pumilus would bite if held,
it was not painful, but a large C. namaquensis could inflict a powerful bite.
C. namaquensis did not release its hold, but biting down hard, twisted and turned,
and pushed and pulled in a most vicious manner.

3. Learning ability

Detailed studies of learning in reptiles are lacking, but some observations
are warranted of evidence of learned behaviour, and modification of instinctive
behavioural patterns in the light of past experience of the subject. Lacerta agilis
(Rollinat 1934), L. muralis (Cooper 1958) and the iguanid Uta stansburiana
hesperis (Burrage 1966) have been shown to demonstrate a Pavlovian response.
Furthermore, when prey is in hiding, they attempt to flush it from cover by
appropriate means.

Chamaeleo namaquensis and C’. pumilus did not respond to Pavlovian sound
stimuli, but would associate objects with food, as do the previously mentioned
lizards. C’. namaquensis would drink from the nozzle of a plastic squeeze bottle.
During a food shortage several small males would accept dead food items such
as large grasshoppers trimmed to size, and even devoured pieces of liver or
meat. C. pumilus learnt to accept food from fingers, and both species quickly
came regularly to food dishes, whether they contained a meal or not. Several
C. pumilus often walked over to the enclosure containing the C. namaquensis to
take the food of the larger species, successfully bluffing any which challenged
them.

In hunting prey older chamaeleons demonstrated techniques which would
be modified through experience and continually reinforced. Such instances
were: (1) the safe overpowering of prey items capable of harming the chamae-
leon; (2) the capture of prey which secretes itself during pursuit. The latter
behavioural pattern was evidenced only by Chamaeleo namaquensis (see also
food habits, p. 75). Uhe chamaeleon would stop at the end of the prey’s
tracks and begin a careful search of the cover, beating small plants with its
feet, or overturning small pebbles and other objects to flush the prey. If prey
sought shelter in vegetation too large for the chamaeleon to trample, they lay
in ambush until the potential meal emerged of its own accord within a reason-
able period. Hatchlings would not do this, and by successive trials (15-25,
Xx = 17) of securing hidden prey, whether chased or not, the young C. nama-
quensis gradually seems to learn that out of sight prey was under cover.

Chamaeleo namaquensis and C. pumilus adults quickly recognized the potential
harm that might be inflicted on them by such prey as large spiders, scorpions,
hymenopterans, vipers and large lizards. Experienced saurian hunters disabled

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 75

the capacity of such prey to inflict harm and seemed to know and recognized
which part of the prey inflicted injury. In attacking such prey they adopted
totally different tactics. First, they carefully viewed the prey, and then secured
it so as to bring the teeth into play at once on that structure capable of causing
harm, rather than a general, indiscriminate crushing. They then spat out the
prey, viewed it again carefully and repeated the process until they were
apparently ‘satisfied’ that no further danger existed. The prey was then taken
in the normal manner. In the case of a large spider they aimed for the chelicerae;
a scorpion, its terminal, poisonous sting; a wasp or bee, the most posterior part
of its abdomen; a venomous snake or large lizard, its head. In the case of a
very large scorpion, they disabled the large, clawed pedipalps after removing
the sting. New-born young and hatchlings would not do this, and carelessly
grabbed such items, often receiving a painful injury. They then wiped their
head on the substrate and tried again. Within three days, all young handled
such dangerous prey items as the adults.

The green anole (Anolis carolinensis) and another iguanid, Uta stansburiana
hesperis also behaved similarly (Burrage 1966); seasoned hunters of both species
being most cautious in attacking and disabling black widow spiders (Latrodectes),
as though they fully realize the danger of this arachnid.

H. Food habits
1. Feeding

Chamaeleo pumilus stations itself on shrubs, grasses, reeds and wire fences in
situations apt to be frequented by its prey, which it captures mostly by ambush.
C. namaquensis regularly hunts, patrolling its territories, and securing any
suitable prey chanced upon. The tongue only is used by C. pumilus and most
often by C. namaquensis in catching prey. However, C. namaquensis often chased
smail lizards, beetles, and others attempting to escape it. C. namaquensis pursued
those prey attempting escape, and when overtaking such prey on a parallel
course, the chamaeleons simply snapped up the victim in their jaws in the
normal saurian manner. They also lay in wait under plant cover and caught
any suitable animal walking by, or beat and harried cover into which prey had
sought refuge. Both species, but particularly C. namaquensis, meticulously
masticate their prey before swallowing it, the tongue assisting. One forefoot
was sometimes used to manipulate especially large prey.

Burrage (1966) reports that captive Uta stansburiana hesperis developed a
taste for an egg mixture that was fed to alleviate insect shortages and served
as a vehicle for medicine and nutriment for sickly specimens. Sick chamaeleons
did not take to such fare and had to be force-fed.

Hotton (1955) gives an interesting and detailed account of the dentition
of certain American iguanids, noting that lizard dentition is a reflection of the
character of the integument and activity of the prey. In Chamaeleo pumilus there
are usually 14 teeth in each half of the lower jaw, of which the first two teeth
are the smallest, and teeth 6, 7, 11 and 12 are the largest. The teeth are all

76 ANNALS OF THE SOUTH AFRICAN MUSEUM

even and not tilted. The posterior teeth are broad-based, whereas the anterior
teeth are conical. These teeth have faint anterior and posterior crenulations
and the last teeth in the row have the central cusp pointing slightly backwards.
Teeth 9-14 are set at an angle so that their bases are straight, but oblique to
the jaw. There are usually 15 teeth in each half of the upper jaw, of which
teeth 12-14 are the largest and tricuspid. The first three teeth are the smallest
and conical. The posterior teeth have the main cusp tilted backwards very
slightly. Only teeth 12-15 have slight anterior and posterior crenulations.
Teeth 4-10 are very broad-based. In occlusion lower and upper jaw intermesh
with each other.

In C’. namaquensis there are usually 15 teeth in each half of the lower jaw,
of which the first and fifth teeth are the smallest; teeth 6-10 and 15 are equi-
sized; and teeth 11-14 are the largest. A line drawn through the crown apices
is even in the anterior half of the jaw only, since the teeth of the posterior half
tilt labially. Viewed from the side, the upper jaw is curved down at mid-point,
so that the first and last teeth are at the same level, whereas those in between
describe a gentle arc of 80°; the base of the tooth at mid-arc being equal in
lateral line to the crowns of the first and last teeth in the jaw. In each half of
the upper jaw, there are usually 16 teeth, of which teeth 12-15 are the largest,
and from that point forwards they become progressively smaller. The first
five teeth of the lower jaw are somewhat conical, especially those most anterior,
but all the remaining teeth of both jaws are noticeably laterally compressed
and crenulated on their anterior and posterior cutting edges. These crenulations
do not show in labial view, because the teeth are slightly convex. The posterior
margin of each tooth is somewhat steeper than the anterior margin, and the
large central cusp is usually slightly recurved. There are no tricuspid teeth.
The upper jaw occludes outside of the lower jaw.

The conical fore teeth in the jaws of both species of chamaeleons hold
and prevent escape of the prey. The prey of Chamaeleo pumilus falls into all of
Hotton’s (1955) prey categories of ‘low, intermediate, and high activity, and
those of light, intermediate, and heavy integument—based on effect of teeth
on the integument’. Probably because of its catholic diet, the dentition of
Chamaeleo pumilus is too complex to fit Hotton’s system. In C. namaquensis the
meticulous chewing shears prey items into neat particles. C. namaquensis prey
fall into Hotton’s (1955) ‘heavy integument . . . intermediate activity’ prey
category. C’. namaquensis dentition seems most similar to Hotton’s Group ‘A’
dentition, but this is the dentition type of such herbivorous iguanids as Ctenosaura,
Dipsosaurus, and Sauromalus. The Chamaeleo namaquensis prey would seem to
require Hotton’s Groups ‘D’ and ‘E’ dentitions, but ‘D’ has little or no lateral
compression of the crowns, and neither does ‘E’ fit, since such teeth are slender
and cylindrical. Hotton’s other dentition groups do not readily accommodate
the teeth of C. namaquensis.

Chamaeleon teeth occupy a shallow dental groove in the jaw. Edmund’s
(1969) description of the number of teeth in Chamaeleo pumilus agrees with this

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 7]

study. Chamaeleons have only acrodont dentition, with teeth added only at
the most posterior end of the jaw. Chamaeleons lack any anterior pleurodont
teeth as in contrast to the agamids, which also have acrodont teeth. Chamaeleon-
ids and agamids do not show the polyphyodonty of other lizards. The teeth of
chamaeleonids and agamids apparently wear down with age, until the jaw
margin itself is utilized as a cutting edge, but this was never observed.

Sight is the principal sense of chamaeleons, which aim their eyes (see
pp. 71-2) on their prey before securing it. Projection of the chamaeleon
tongue is a source of dispute between Gnanamuthu (1930) and Zoond (1933).
The former thinks projection of the tongue is due mostly to relaxation of the
highly contracted hyoglossi. However, by physiological experiments and
anatomical investigation of the muscles and vascular supply of the tongue,
Zoond (1933) showed that protrusion of the tongue is effected by the contraction
of the geniohyoids, the tongue is held protruded by extreme contraction of the
hyoglossi, and that several other muscles and tendinous tubes are important
in the final thrust and holding of the target. Retraction is by the interplay of
the hyoglossi and the sternohyoids. Zoond showed that several points of
Gnanamuthu’s surmised chamaeleon tongue action are not supported by
physiological or anatomical data.

In some Chamaeleo pumilus the tongue pulling power approximated two-
thirds of the animal’s body weight, but most had a tongue pulling power
about 50% of their body weight. C. pumilus shot its tongue to a maximum
range, roughly equivalent to two-thirds of its total length, exceeding the
maximal range observed by Von Frisch (1962). In C. namaquensis the tongue
has a pulling power equivalent to the body weight of the chamaeleon, and was
maximally projected to a distance approximating its snout-vent length. Data
are limited on the range and pulling power of the tongue of chamaeleons.
Dischner (1958) says a Camerounian C. montium weighing 100 g has a tongue
pulling power of 43 g. As Dischner (1958) observes, there is no evidence of
any adhesive substance on the tip of the tongue, other than the ‘normal’
adhering quality of a moist object. Pulling the tongue from the mouth of an
anaesthetized chamaeleon and placing it on a beetle showed no stickiness,
neither was it sticky to the touch. The tongue only held an object to which it
was forcibly applied, as would be the case in normal projection. ‘The prey is
grabbed and held by a mechanical overlapping of the bi-lobed tongue knob
(Fig. 8). What is brought in by the tongue was considered food and eaten,
even if the missed edible prey was still in view to a chamaeleon chewing a
physical surrogate.

2. Amount of one meal

Chamaeleo pumilus and C. namaquensis in the field were voracious feeders,
often eating to stomach capacity, and as soon as the preceding meal passed to
the small intestine, a new meal was ingested. Size and specifity in prey selection
were important in actual meal volume. Table 18 shows the normal volumetric

78 ANNALS OF THE SOUTH AFRICAN MUSEUM

daily food intake of C. pumilus (+70 mm, s-v) and C. namaquensis (+-105 mm,
s-v). By selecting tenebrionids and the smaller orthopterans, C. namaquensis
realized a greater real intake of food than by taking individually larger prey.
While the same was true for C. pumilus, the wider tastes of this species made it
more difficult for this type of analysis. The largest prey taken by C. pumilus
adults were tettigoniid orthopterans and large vespids, of which two were
capacity. Both of these prey items were Food Index ‘3’ at 2 ml volume each.
The smallest prey taken by adult C. pumilus were fruit flies (Drosophilidae).

Table 18

Volumetric daily food intake of Chamaeleo namaquensis! and C. pumilus?.

Prey Vol. Number Daily volume (in ml) per number
Food (ml) per (in parentheses) of daily meals
Example Index each meal min. x max.
1L_arge locustid 5,0 455 4 (9) 7G.) (6) 108,0 (8) 144,0
1Small Jocustid 4,0 2,0 30 (3) 18050 (6) 360,0 (8) 480,0
1|_arge tenebrionid 3,8 1,25 19 (5) 118,75 (12) 285,0 (15) 356,25
25 55 3,8 1,25 23 (5) 143,75 (12) 345,07 b)eAgie2s
1Small tenebrionid 355 0,85 19 (5) 80,75 (12) 193,8 (15) 242,25
>» >» Be OS 23 (5) 97.75 (12) 234,6 (15) 293,25
*Muscid BO 4°25 15 (3) 11,25 (5) | 18575" (G)inego;0
* Tenebrio molitor 4,0 2,0 5 (3) $0.0 (5) 50,0 (8) 80,0
>» 2» 4,0 2,0 7 (3) 42,0 (5) 70,0 (8) 112,0
is a 4,0 2,0 10 (3) 60,0 (5) 100,0 (8) 160,0

C. namaquensis and C’. pumilus began eating soon after emergence—after
early morning defecation of the previous late day meal—the former eating
prodigiously while drenched in dripping ground fogs, and the latter on frosty
winter mornings. Early morning at emergence and late afternoon chamaeleons
ate to their stomach capacities. The number of daily meals is given in Table 18.
Of 80 C. namaquensis stomachs examined, only 2 were empty, and of 150 C.
pumilus stomachs examined, only 20 were empty.

Wood (1933) and Burrage (1966) studied food amounts ingested by the
American iguanid Uta stansburiana, noting variation in consumption with the
weather, it being greatest at the hottest times of the year. Seasonal variation in
food consumption was not particularly noticeable in C. pumilus or C. namaquensis.

3. Rates of passage

Feeding marked insects to chamaeleons showed that the last meal of the
preceding day was passed on emergence the following day, which was the
longest time for digestion (12 hours). Digestion of the other daily meals was
completed in two to five hours, depending on the integument of the prey.
Undoubtedly, the short passage rates reflected the high degree of mastication
to which the food was subjected, increasing the area for enzymatic action and
absorption.

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 79

4. Prey items

In Chamaeleo pumilus (Table 19) differences in food ingested were seasonal,
but appeared to vary with sex. While dipterous families were usually a pre-
dominant prey item in both sexes, quite a considerable part of their prey was
taken from other insect orders. For example, females ate mostly dipterans
(97,2%, mainly muscids) in June, and the least (2°%) in October, whereas
males ate only dipterans in February, and the least (50%, almost equivalent
amounts of syrphids and muscids) in August, with the remaining prey in August
almost evenly taken from immature insects (24,5°%) and orthopterans (25%).
Orthopterous families were predominant in the winter diet of males, whereas
the highest intake (23,4°%) of orthopterans was in the February diet of females.
Essentially as can be seen in Table 19, what was most taken in the diet of one
sex for any given month was taken in different amounts by the opposite sex,
and the total consumption of each contained different prey elements. Of note
was the amount of ground-living carabids taken, which in May accounted
for almost a third of the diet of male C. pumilus. Greatest ingestion of carabids
(22%) by females was in August. C. pumilus were found supratidally at Port
Nolloth, and The Strand, feeding on small tenebrionids and flies at the former
locale, and exclusively on flies at the latter. Injurious insects formed the major
portion of the diet of C. pumilus, and the large numbers taken rate this little
lizard significant in their control.

Table 20 gives the prey taken by coastal Chamaeleo namaquensis, and ‘lable
21 that of inland populations. In the former the predominant item was tene-
brionid beetles. The lowest amount of tenebrionids in any monthly sample was
60%, and the monthly mean was never below 93,3%. The inland populations
of C’. namaquensis ate larger amounts of other prey items, especially Orthoptera
and Lepidoptera. Some prey, such as buprestids and curculionids were
seasonally taken, when these were commonest. However, inland C. namaquensis
also ate predominantly tenebrionids, and the lowest percentage in any monthly
sample was 2,5°%4, and the monthly mean was never below 67%. Plants were
ingested regularly, but more so by coastal C. namaquensis. In coastal C. nama-
quensis the largest amount of plants in any sample was 29,1°%, and the largest
mean 2,8%. In inland C. namaquensis the largest amount of plants in any sample
was 20%, and the largest mean was 1,5°%. Certainly some plant ingestion might
be incidental with the prey, but this seems scarcely credible in view of the
amounts recorded, nor that <ygophyllum stapffi was the predominant plant
ingested. Only the fleshy parts of these plants were taken in by the chamaeleons.
Inorganic matter composed of small stones, gravel, and sand was more frequently
ingested by coastal Chamaeleo namaquensis, of which the greatest amount in a
sample was 30%, and the largest mean was 6,2°%. The greatest amount of
inorganic matter in an inland sample was 1,1°%, and the largest mean was
0,5%. Inorganic matter might be ingested for assisting in internal, physical
degradation of food, and/or parasite removal.

The fact that some C. namaquensis had eaten larval beetles was interesting,

80

Table 19

Monthly prey percentage of male and female Chamaeleo pumilus at Stellenbosch, Cape Province.

ANNALS OF THE SOUTH AFRICAN MUSEUM

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ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 83

since these are mainly fossorial and indicated that C. namaquensis occasionally
dug up food purposely or ate those unearthed by chance in excavation. It is
not known whether the bird feathers and mammal hairs in some inland C.
namaquensis (Table 21) were the remains of meals or accidental ingestion of
feathers and hairs taken in with other prey. Since they were small feathers and
hairs, it strongly infers purposeful ingestion of small birds and mammals. A
chamaeleon captured at Ganab, near the Great Western Escarpment, had
eaten only wasps, but this information is not reflected in Table 21. Some
coastal dune-dwelling C’. namaquensis ate significant numbers of other reptiles
(Table 20). In January 1970, at Cape Cross, South West Africa, Dr J. Jurgens
collected a chamaeleon that had eaten only reptiles, but this information is
not reflected in Table 20. Figure 8 shows a C’. namaquensis catching a gecko.
In the field a male C. namaquensis 95 mm long snout-vent was seen to capture
and kill a Bitis peringueyi 200 mm in total length. At low tide and within the
spray of heavy surf, strand-dwelling C. namaquensis frequently penetrated
seawards of the mean high tide limit on to damp sand. These chamaeleons
walked amongst the tidal wrack and fed chiefly on flies, intertidal arthropods,
tenebrionids, and reptiles. The ingestion of intertidal arthropods would
certainly necessitate a salt gland. Unfortunately, the larger numbers of coastal
C’. namaquensis sampled further inland obscures the actual diet of these strand-
dwelling chamaeleons as presented in Table 20.

Burrage (1966) notes that the American iguanid Uta stansburiana hesperis
takes more flying insects later in the day, when the activity of such forms was
restricted to plant cover by increasing wind intensity. Chamaeleo pumilus was
restricted to plant cover only by the most intense winds, and, at such times,
took slightly more flying insects; however, most of its prey was of the winged
insect orders. Prey selection by C. namaquensis was not affected by wind intensity.

There are no detailed accounts of annual prey ingestion for chamaeleons.
Most chamaeleons are insectivorous, though C. oustaleti of Madagascar eats
mice and birds, and C. dilepis and C. melleri of Africa take birds (Schmidt &
Inger 1965).

5. Skin-shedding

Adult Chamaeleo pumilus and C. namaquensis in the field shed their skins
every six weeks, and juveniles every four weeks. Unhealthy chamaeleons took
as much as eight weeks between shedding periods, and had difficulty completely
sloughing off the old skin. Time interval between sloughing in C. pumilus and
C. namaquensis agrees with Bustard (1963) for C. chamaeleon. Shedding was as in
C. dilepis, as given by Brain (1961). The old skin whitens over the body and
limbs prior to shedding. In C. pumilus and C. namaquensis the old skin splits
along the body in a mid-dorsal line and in the neck region and head. By
laboured compression, arching of the body, and rubbing against any rough
object the skin is loosened and removed. C. namaquensis used its hind feet to
remove large patches of skin on the back of the body. Both species used their

84 ANNALS OF THE SOUTH AFRICAN MUSEUM

Y

YY

Fig. 8.

Chamaeleo namaquensis in the act of catching a gecko (Rhoptropus afer).

Note bi-lobed nature of tip of chamaeleon’s tongue, which totally

obscures head of victim. Also of interest, this chamaeleon shows

Hoesch’s ‘Schreckmuster’ (see text). Photo through courtesy of
Mr H. Maedler, Swakopmund.

jaws to remove the old skin from their limbs. Isolated pieces of skin often
persisted along the cranial ornamentations for some time. C. namaquensis shed
its skin almost in one piece, which it then devoured. C. pumilus did a more
patchy job of sloughing and was less likely to eat the cast skin.

Further aspects of skin-shedding in reptiles are discussed in the following
section.

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 85

I. Water and salt balance
1. Drinking and water sources

Chamaeleo pumilus uses its tongue to lap up water drops on plants, but in
rains, condensing fog, or drizzle, water drops beading-up on the snout tip
were simply run on to the slightly protruded tongue. Occasionally, captives on
one twig used the tongue to shoot off water droplets on adjacent leaves. Except
during summer, water was readily available to C. pumilus in varied forms. In
summer, precipitation is less frequent, and at this time dew is the principal
source of water. C. pumilus always drank early in the day. On rainy days
drinking was ad lib. through the day, but in clear weather, the early morning
drink of dew had to suffice (see water storage and conservation, p. 86).

The water sources available to C. namaquensis are the same as that of C.
pumilus, but the former species rarely encounters rain. Coastal C. namaquensis
relies mainly on the frequent fogs. On wholly foggy days C. namaquensis drinks
ad lib., but on clear days fog and dew frequently recurred in the late afternoon
and evening when the chamaeleons were still abroad. Thus, on clear days the
desert chamaeleon can drink at times early in the day at emergence and late
the same day prior to retirement.

C. namaquensis uses its tongue to lap up dew, as well as fog water condensed
on vegetation, sand and rocks. It also used the tongue to shoot water drops off
adjacent plants. Early in the morning in sparsely vegetated areas, C’. namaquensis
drank from the water-saturated sand arising from condensate run-off from its
body. C. namaquensis has a fine-grained squamation which serves as fine, very
distinct capillary channels leading to the mouth. These channels are especially
distinct on the throat and fore-part of the body. If dyed water was placed on
the mid-laterum of the body, water moved by capillarity up to the vertebral
region, and towards the head and tail. The chamaeleon turned its head to
drink the water accumulated on its flanks and vertebral knobs, and in captivity
would do so off each other’s bodies. Thus, the animal is designed as a ‘water
collection’ surface itself.

Tenebrionid beetles are the principal prey of C. namaquensis, and they
undoubtedly contribute to the water economy of the chamaeleon. Early in the
morning various tenebrionid beetles could be seen upended, with the head
buried in the sand and fog water condensing on their thorax and abdomen.
The water trickled down to the sand which became thoroughly saturated.
Careful removal of the sand around the head showed it to be buried in this
water-saturated sand and the jaws working in drinking.

Lizards in areas of moderately high, or regular rainfall, have little difficulty
in meeting their water requirements. Most lizards drink essentially as do
chamaeleons, but varanids, large iguanids, the larger anguids, teiids and
scincids immerse the snout in water to drink. Chamaeleo pumilus and C. nama-
quensis, co-inhabitant populations in the Namib Desert at Liideritz and Port
Nolloth, utilize the same water sources. An introduced population of C. pumilus
at a residence in Walvis Bay had no apparent water-source problem. C.

86 ANNALS OF THE SOUTH AFRICAN MUSEUM

chamaeleon of the Sahara and Levant is the only other chamaeleon of deserticulous
habits, but no references to its ecological adaptations have been found. Mayhew
(1968) has adequately reviewed water problems of desert lizards. Desert lizards
acquire water from: (1) drinking; (2) free water in the food; (3) oxidation
water (Schmidt-Nielsen 1964). The helodermatid Heloderma suspectum (Bogert
& Martin del Campo 1956) needs surface water, and the iguanid Dzpsosaurus
dorsalis and the agamid Amphibolurus pictus (Mayhew 1963) copiously drink
water if available. Chamaeleo namaquensis and C’. pumilus were both active at
times of dew, thus this was a realized water source for them. Since dew occurs
on cold nights, most reptiles are considered unable to use this source because
they would be inactive (Schmidt-Nielsen & Dawson 1964). However, many
desert lizards merely emerge the head, on which the dew may condense and be
licked off. The agamid Moloch horridus (Davey 1923; Hosking 1923), and
iguanids Phrynosoma modestum, P. cornutum, and Holbrookia maculata (Meyer 1966)
lick water from plants. Louw & Holm (1972) show the coastal Namib Desert
lacertid Aporosaura anchetae uses not only condensed fog water directly, but
also that condensed on kelp flies.

The hygroscopic skin of the agamids Cordylus giganteus (Mertens 1960),
Uromastix hardwicki (Seshardi 1957) and Moloch horridus (Davey 1923) is
considered to absorb water by capillary action. Bentley & Blumer (1962)
demonstrated that M. horridus does not absorb water through the skin, but that
the water penetrates fine capillary channels, in which it moves to the mouth
and is taken in. Certainly impervious skin would be an advantage to desert
forms, and Tercafs (1963) showed variability in dermal permeability of the
agamid Uromastix acanthinurus, it being permeable when saturated with water,
but not in dry air. Warburg (1966) and Maderson (19652) found that the
epidermis of some lizards is water permeable. The iguanids Phrynosoma modestum
(Weese 1917) and P. m’calli (Mayhew 1965) have never been observed to
drink in the field or in captivity.

2. Water storage and conservation

The large urinary bladder was flaccid and empty in all Chamaeleo pumilus
caught in the late afternoon during dry, summer weather. But C. pumilus taken
earlier the same day after drinking dew had their urinary bladders distended
with fluid (Fig. 9). This observation was also true for those taken on rainy
days. These field observations were duplicated in the laboratory and are
reported later. It seems that since C. pumilus always had access to dew, daily
water storage was sufficient to get them through the day during dry, summer
weather.

C’. namaquensis stores a little water in its digestive tract, though the gut is
not visibly distended. The gut was also usually crammed with food, so available
space for water storage was limited. The urinary bladder of C. namaquensis is
surprisingly small (Fig. 10a, B), thick-walled with little expansive qualities, and
of negligible use for water storage. Unless C. namaquensis uses the vascular space

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 87

Fig. 9.

Distended urinary bladder of Chamaeleo pumilus early on a summer day after drinking dew.
Bladder lies approximately between ‘4’ and ‘5’ on mm rule.

for water storage, there seems to be no other visibly apparent water depots.
Thus we have the phenomenon of the desert chamaeleon with far less ability
to store water than the mesic C. pumilus. Coastal C. namaquensis apparently
obtains sufficient water from the frequent fogs and its food to meet its water
requirements. Outside of the fog belt, cloacal reabsorption in conjunction with
the salt gland, also allows water economy, and the prey serves as a water source.

Chamaeleo pumilus and C’. namaquensis excrete a closely packed faeces, which
when crushed appeared pasty with hard fragments. The uric acid pellet is
excreted first, but attached to the faeces. In these chamaeleons, a water and
uric acid mixture can be seen in the ureters. Therefore, it would seem that
cloacal reabsorption of water is efficient in both species.

Mayhew (1968) discusses water storage in tissues of desert lizards. Norris &
Dawson (1964) found the iguanids Sauromalus hispidus, S. obesus, and S. varius
have lateral accessory lymph spaces which are distended with fluid in rainy
times and that these storage depots are larger in those forms from more arid
regions. The Namib Desert lacertid Aporosaura anchietae drinks water copiously
and stores it in the digestive tract and vascular space (Louw & Holm 1972).
Khalil & Abdel-Messieh (1954) consider the tissues of desert reptiles to have a
higher water content than those of mammals, which is disputed by Sokolov
(1966).

The gekkonid Hemidactylus flaviviridis (Seshardi 1956), agamid Uromastix

88 ANNALS OF THE SOUTH AFRICAN MUSEUM

Big. 10;

A. Flaccid urinary bladder of Chamaeleo namaquensis.

B. Distended urinary bladder. In both cases bladder lies directly on top of piece of black paper.
Scale in mm.

&

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 89g

hardwicku (Seshardi 1957), varanids Veranus monitor (Seshardi 1959), V. gouldii
(Braysher & Green 1970), and scincids Scincus scincus and Chalcides ocellatus
(Khalil 1951) reabsorb water from the urine in the cloaca, excreting the waste
as a solid pellet.

3. Water loss

Chamaeleo namaquensis was abroad throughout the day, retiring to its
retreat only at night. C. pumilus is problematical since it occurs in mesic areas,
where desiccation is less extreme, but also in arid areas. C. pumilus and C.
namaquensis pant, which is discussed in the section on thermoregulation (see
p. 45). Water loss of chamaeleons in laboratory desiccation studies is dealt
with in the next section.

Desert reptiles reduce evaporative water loss by avoiding excessively high
temperatures, thus diminishing the use of water in temperature regulation
(Schmidt-Nielsen 1963). However, Schmidt-Nielsen (1964) noted little evidence
that panting involves a great use of water in thermoregulation even at near
lethal body temperatures. The rate of water loss in reptiles is slow (Bentley
1959; Warburg 1965a, 5b) and is exceeded ten times by that of deserticulous
rodents (Chew & Dammann 10961). Some desert lizards utilize the higher
humidity and lower temperatures in their burrows during extreme midday
conditions (Schmidt-Nielsen & Dawson 1964) as do small desert mammals
(Schmidt-Nielsen & Schmidt-Nielsen 1950). Evaporative cooling through the
respiratory tract enables reptiles a degree of remaining cooler than their
surroundings on hot days (Dawson 1967; Dawson, Shoemaker & Licht 1966)
and to dissipate 1,3 times the metabolic heat produced at 44 C in the iguanids
Dipsosaurus dorsalis (Templeton 1960) and Crotaphytus collans (Dawson &
Templeton 1963). At elevated body temperatures oxygen consumption rises
and respiration rate increases. As panting ensues, breathing is rapid and
monophasic, though oxygen consumption decreases at higher temperatures
(Dawson & Templeton 1963; Templeton & Dawson 1963; Dill, Edwards,
Bock & Talbott 1935). Consulting Table 16 indicates these relationships to be
true for Chamaeleo namaquensis and C’. pumilus, particularly the former.

Benedict (1932), Templeton (1960), and Dawson & Templeton (1963)
found evaporative water loss is in excess of water produced, so lizards are
dependent on preformed water from their food for maintaining water balance.
Since lizards are uricotelic, they gain more oxidation water from protein
degradation than ureotelic forms (Schmidt-Nielsen 1964; Schmidt-Nielsen &
Dawson 1964). Thus, carnivorous saurians gain considerable water from their
prey. Reptiles cannot form hypertonic urine. Roberts & Schmidt-Nielsen (1966)
found the kidneys of the iguanids Phrynosoma cornutum and Tropidurus produce
isoosmotic urine, reabsorbing 55% of the glomerular filtrate. Chew (1961) and
Bradshaw & Shoemaker (1967) found dehydrated lizards may excrete little
urine, but their blood tolerates a greater sodium increase, resulting from
electrolyte retention. Shoemaker, Licht & Dawson (1966, 1967) and Dawson

gO ANNALS OF THE SOUTH AFRICAN MUSEUM

(1967) found the scincid Tiliqua rugosa, the gekkonid Phyllurus mili, and the
agamid Amphibolurus barbatus excrete water loads with the least loss of sodium
near their particular thermal preferenda. Maderson (19656) hypothesized that
skin-sloughing may enable lizards to excrete wastes without losing water.

Chew (1961) and Chew & Damman (1961) considered the skin of some
reptiles to be nearly waterproof. However, cutaneous water loss recently has
been shown to be a significant avenue of loss, often exceeding that lost via
respiration and excretion. Of several reptiles from habitats of varying degrees
of aridity, Sauromalus (most arid) lost the least (5% of Caiman). Cutaneous
evaporation in Sauromalus, however, was the chief avenue of loss, accounting
for 66% of the total water loss at 23 C. Other examples of cutaneous evaporative
loss as a percentage of the total water loss are: the arid-dwelling iguanid Uta
stansburiana 39°%, and the more humid iguanid Anolis 42°%—at 30 C (Claussen
1967), at 30 C, 57% in the gekkonid Gehyra variegata, and 59% in the agamid
Amphibolurus ornatus, and at 20 C, 70% in both of the preceding forms (Dawson
et al. 1966). Maderson (1964) feels the main site of cutaneous water loss in
reptiles is the hinge area around the scales. Temperature controlled water loss
is that via respiration, and the humidity affects the rate of cutaneous water loss
(Warburg 1966).

4. Laboratory desiccation studies on Chamaeleo pumilus and C.. namaquensis

Table 22 shows the body weight losses of the chamaeleons without food
or water for seven days and Table 23 gives the haematocrits and plasma
osmolality values (with the significance at ‘P’ level) of the de- and rehydrated
groups of this experimental set of Chamaeleo pumilus and C. namaquensis. Signifi-
cant differences in the haematocrit are shown between dehydrated C. pumilus
and dehydrated C. namaquensis; between dehydrated C. pumilus and C. nama-
quensis and those rehydrated. There is no significant difference between

Table 22

Weight changes (in grams) of ten Chamaeleo pumilus and ten C. namaquensis desiccated for seven
days, giving body weights at the start and the conclusion of dehydration, body weight losses
during dehydration, and body weight changes after rehydration. Means are shown in parentheses.

Dehydrated Rehydrated
body weights body weights
In Out % loss at death
Dehydrated
Cums ee Syo—Te 6,2-10,8 16,8—29,0
(10,3) (8,5) (21,7)
C. namaquensis . . . . 17,8-82,3 15,8-77,0 4,6-12,4
(5555) (52,0) (7,1)
Rehydrated
Cypunitlise oy, 1) ae GA Gas 553- 759 1322.6 6,2-10,2
(8,4) (7,0) (16,7) (8,7)
C. mamaquensis . . . . 49,7-90,1 45,9-84,9 2,3-12,3 47,2-88,0

(60,7) (56,2) (7,6) (57:8)

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) QI

rehydrated C. pumilus and C’. namaquensis. In plasma osmolality values there is a
significant difference between dehydrated C. pumilus and dehydrated C. nama-
quensis, and between dehydrated and rehydrated C. pumilus, but no significant
difference between rehydrated C. pumilus and C. namaqiensis, nor between
dehydrated and rehydrated C. namaquensis. These data suggest a degree of
water storage in the vascular space of both chamaeleons.

Table 23

Haematocrits, and plasma osmolalities, with relevant statistics for ten Chamaeleo pumilus (Cp)

and ten C. namaquensis (Cn) subjected to seven days’ desiccation at 0% humidity. At day seven,

the rehydrated half of each group were killed and the remainder then rehydrated and killed
the following day.

Haematocrits Dehydrated Rehydrated
Dehydrated
Came 8. | 26,0-39,7 (« — 31,3; S.D., 254) Cn <05001
Cumeee- - 4.6-19,8 («= 17,6; S.D., 2,3)
Rehydrated
Come). 14,5-29,0 (k — 21,4; S.D., 6,0) (Cys PIP == SO.2 nse — 0:2
mer 155-9255 (x — 24.6; S.D., 754) (Ciro DIP == SS O47
Dehydrated
Spy) =) 395-440 (K = 421,93; S.D., 19,0) (Cis DIP == 0,2
Samer = 230-255 (x = 246,3; S.D., 11,1)
Rehydrated
Cpe = = 200-210 (k = 203,8; S.D., 4,8) Cp?) SE <o705) 0 Cn > 2 — 052
Gass = «219-202 (k = 261,3; S.D., 35,4) (Ciao DIP == SO,

The results of the experiment on the survival of C. pumilus and C. nama-
quensis with food but no water for twelve days and food and water for an
additional three days are given in Tables 24 and 25. Due to the difficulty in
acquiring sufficient numbers of C. namaquensis in respect of all the studies
conducted, the numbers here are too small for statistical analysis. The striking
feature is the mortality of half of the C. pumilus by the sixth day and the badly
dehydrated state of the survivors at the end of the dehydration period. The
two taken for an additional three days with water quickly recovered some of
their weight loss. Even the deserticulous C. namaquensis showed some dehydra-
tion and had one mortality, from unknown causes, during the experiment.
All of the rehydrated C. namaquensis showed an increase in body weight on the
first day of rehydration, but at sacrifice had lost more than they had gained,
despite having food and water. Both species ate less without water, and easy
faecal elimination seemed hindered. The haematocrit and plasma osmolality
values of the dehydrated and rehydrated chamaeleons in this experiment
approximated those given for the chamaeleons in the preceding experiment.

Upon rehydration in both experiments C. pumilus strained and ran to the
water, drinking so fast that it choked, and regurgitated, but kept drinking until
satiated. C. namaquensis acted likewise, but it also chewed water-saturated
vegetation, which it spat out, and rolled, ploughed, and rubbed its body in
wet sand. Upon sacrifice, both sets of rehydrated chamaeleons contained

92 ANNALS OF THE SOUTH AFRICAN MUSEUM

considerable ingested water, especially evident in the urinary bladder of C.
pumilus, and the digestive tract and urinary bladder of C. namaquensis.

Freshly caught C. pumilus (elev. 105 m) had a haematocrit of 29,0-30,5
(N=7; x = 29,9; S.D.; 0,63), and plasma osmolality values of 200-210
(N = 8; x = 203,8; S.D.; 5,23). Freshly caught C. namaquensis had haemato-
erits of (coastal; elev. 12 m)) 42,0-49,0 (N = 10;) x)— 4405 oer)
(inland; elev. 407 m) 46,0-50,0 (N = 7; x = 48,7; S.D.; 1,38), and plasma
osmolality values of 220-290 (N = 8; x = 259,8; S.D.; 28,64). The wide
range of the S.D. of the plasma osmolality values of C. namaquensis may reflect
individual differences, the fact that the sample did not separate inland and
coastal specimens, or the delay in sacrificing the animals.

Table 24

Body weight losses (in grams) for 3 day periods for 8 Chamaeleo pumilus (Cp) and 8 C. namaquensis
(Cn) for 12 days with food but no water. At the end of 12 days, 2 C. pumilus and 6 C. namaquensis
were given water and food for an additional 3 days (see Table 25). Means are shown in

parentheses.
Days
1-3 4-6 7-9 10-12
Body weights

Body weight losses In Out % loss
Cp. . . . 0,8-1,5 0,6-1,3 0,4-0,8 0,3-0,5 6,1-11,3 3,4- 8,6 23,9-44,3
(1,1) (0,9) (0,5) (0,4) (8,7) (6,2) (29,9)
Cn. . . . 0,5-4,9 0,4-4,3 0,3-3,2 | 0,4-1,6 36,0-91,4 31,0-77,4 353=15,3
(2,1) (1,5) (1,6) (0,9) (60,8) (54,9) (9,6)

Table 25

Weight changes (in grams) of Chamaeleo pumilus (1-2) and C. namaquensts
(3-7) which were given water and food for 3 additional days after receiving
only food for 12 preceding days (see Table 24).

Days 13 to 15

Rehydration
Maximum 3 days
body weight Total losses
Id. Body weight (day in Uric
No. In Out parentheses) acid Faeces Remarks
I 12,5 14,0 14,0 (15) 0,12 0,67
2 8,5 9,2 9,2 (15) 0,06 0,22
3 50,5 503 53,3. (13) 0,16 1,32
4 48,5 48,8 49,2 (13) 0,28 2,91
5 49,0 4755 50,0 (13) 0,31 0,80 shed skin day 13
6 60,3 60,1 62,0 (13) 0,17 1,98
i 77:54 73:7 7933 (13) 0,67 3,40 shed skin day 13

Water is obviously crucial to chamaeleons, as was first observed by
Brehm (1893), latterly by Bustard (1963), Von Frisch (1962), and experi-
mentally shown in this study. Starving and dehydrated chamaeleons, as those
shipped a distance, will drink before they feed, even if food is abundant. They
cannot survive on food alone, as the laboratory tests demonstrate. Even
humidities of 40-50% experienced by the animals given food and no water

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 93

did not assuage them, yet this humidity was experienced by them in the field,
and actually a trifle low for coastal C. namaquensis.

Minnich (1970) estimates that Dipsosaurus dorsalis loses via defecation 61 %
of its total water intake, and water loss studies under simulated natural con-
ditions apparently show that this iguanid cannot balance evaporative water
loss through oxidative water production at the low humidities it encounters
when active. A loss via defecation of 61% of the total water intake seems a
bit high in the light of studies on cutaneous water loss in reptiles. Perhaps D.
dorsalis has less cutaneous water loss than another desertic iguanid, Sauromalus,
though it seems doubtful. Comparison of chamaeleons with other reptile
desiccatory studies is difficult, since the dehydration period varies. Claussen
(1967), for example, kept his animals in the drying chamber for only 24 hours.
Furthermore, he was able to collect faecal and uric acid eliminations in a
manner not possible in this study. Faeces and uric acid were weighed as
promptly as possible, while they were still moist and freshly eliminated. How-
ever, such data seem too open to variables and, thus, are not given here.

Louw & Holm (1972) found Aporosaura anchietae haematocrits (dehydrated)
of 43-48 (K = 45); (rehydrated) 41-46 (X = 44), and osmolality values
(dehydrated) of 410-435 (X = 420); (rehydrated) 390-415 (X = 406), and
‘normal’ of 275-320 (X = 312). Freshly caught and rehydrated Chamaeleo
pumilus haematocrit values agree with those (26,0-35,0; X = 29,7) given by
Thorson (1968) for terrestrial sauria, but those for rehydrated Aporosaura
anchetae (Louw & Holm 1972) and for this study for normal and rehydrated
C. namaquensis do not. This may be due to Thorson’s use of the tropical, non-arid
saurian, the green iguana (Iguana); however his values (25,0-34,0; X = 29,6)
for the deserticulous tortoise (Gopherus) are still much lower than those for the
desert-dwelling Aporosaura anchietae and Chamaeleo namaquensis. ‘Thorson notes
the similarity in haematocrit values of those reptiles inhabiting the two desic-
catory environments of sea and land, and deserts are the most drying.

5. Salt balance

Figure 11A, B shows a close-up of the salt exudate around the nares of a
captive juvenile Chamaeleo namaquensis. In C. namaquensis the salt gradually
exudes in the manner of a brine, forming a considerable deposit as it dries,
through which runs a small air passage. When the encrustation gets too large,
it is rubbed off with the feet or by scraping the nose against some object.
Though C. pumilus inhabits supratidal bushes and may ingest animals with a
high salt content, no evidence of salt excretion was observed for this species.
Collected from C. namaquensis, the dry salt exudate was dissolved in 0,1 ml of
distilled water. The exudate contained 7 mEq/L of potassium; 45 mEq/L of
sodium; and 49 mEq/L of chloride. While captive C. namaquensis occasionally
ingested water-drenched plants, especially succulents, for water, those in the
field not infrequently had plant matter (see food habits, p. 79) in their
digestive tracts. The finding of potassium in the nasal salt exudate may indicate

ANNALS OF THE SOUTH AFRICAN MUSEUM

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ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 95

an ability to utilize desert plants for food as well as water. Either way it is
most interesting, since we may have an omnivorous chamaeleon, excreting
salts extrarenally as an adaptation to diet and utilization (plant-chewing) for
maintaining water balance. Several lizards (Neill 1958; Burrage 1966) prey
intertidally on marine arthropods along desert shores, and undoubtedly take
in with such prey some quantity of salt which must be eliminated. C. nama-
quensis, inhabiting the Namib Desert littoral, is the only chamaeleon known to
exploit this niche.

Schmidt-Nielsen (1963) feels extrarenal salt excretion is related to cloacal
water reabsorption. This may be necessary for production of a low water
content urine and efficient cloacal water conservation. The cations of sodium
and potassium are actively reabsorbed, with water following passively, which
method requires far less work than active water transport. The salt gland serves,
then, to eliminate excess cations, which would be primarily potassium in
herbivorous and scdium in carnivorous forms.

Schmidt-Nielsen (1965) gives a good general physiological and anatomical
account of salt glands; Roberts & Schmidt-Nielsen (1966) also describe the
structure of the gland. The reptile salt gland is structured as that of other
vertebrates, with branching secretory tubules arranged radially around a
central duct. Most studies on salt-excreting saurians have been done on herbi-
vorous forms, which excrete primarily potassium. Templeton (1963, 1964)
showed the iguanids Ctenosaura pectinata and Sauromalus obesus excrete 950 mEq/L
of potassium at 190 times plasma concentration, being similar to renal tubule
secretion in mammals. Potassium predominates even when the animals were
injected with sodium chloride. Other salt-excreting saurians are S. hispidus,
S. varius (Norris & Dawson 1964), Dipsosaurus dorsalis (Schmidt-Nielsen, Borut,
Lee & Crawford 1963; Templeton 1966), agamids Uromastix aegyptus (Schmidt-
Nielsen et al. 1963), U. acanthinurus (Grenot 1967), and the non-arid-dwelling
tropical iguanid Jguana iguana (Schmidt-Nielsen et al. 1963) which secretes
potassium as a bicarbonate. These lizards are all primarily herbivorous and
the salt-excreting gland serves to remove the salt loads, of which potassium is
the major cation, derived from the halophytes on which they feed, which
cannot be excreted by their kidneys. Norris & Dawson (1964) consider excretion
of potassium by the salt gland of Sauromalus varius a physiological adaptation of
deserticulous herbivorous lizards to utilization of halophytic plants.

J. Population structure

1. Density and biomass

The high survival of adult Chamaeleo pumilus (Table 26) and C. namaquensis
(Table 27) suggests the very young either bore the brunt of predation or were
harder to locate. Adult C. pumilus were recovered at a higher rate than juveniles,
though after two to three months the juvenile recovery rate stabilized, thus
indicating a high mortality of the very young. Of 40 juvenile and adult C.
pumilus marked in February 1969, 40,0°% were recovered in February 1971.

ANNALS OF THE SOUTH AFRICAN MUSEUM

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gz 21421,

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 97

Of 11 coastal juvenile C. namaquensis marked in June, overall recovery in
November was only 27,2°%, of which all were males, for a male recovery of
45,4.%- Of the 41 coastal juveniles marked in November, 48,7°% were recaptured
in February. Of 21 males marked in November, 52,3° were recovered in
February. In February, 45,0% of the females were recovered, of the 20 marked
in November. Only in February did marked juveniles (53,4%) exceed adults,
though since these juveniles were all coastal, they were actually a larger
component of this population (58,5 °%).

Of 207 marked C. namaquensis adults, only 17 were not definitely main-
taining territories. As the number removed for research purposes is not included,
the biomass (mean weight of chamaeleons per hectare) of C. namaquensis
(Table 27) and C. pumilus (Table 28) could be considered somewhat above
what is given.

Table 27

Mean density per hectare, body weight, and biomass (in grams) of juvenile and adult Chamaeleo
namaquensis based upon a composite of two study stations.

Monthly total marked

(recovered and new) Percentage of adult
Mean Mean Per hectare recovery marked in
Adults weight Juveniles weight Density Biomass April June Nov.*
Apr. 45,0 3725 oa ia 055 18,8 Hip ee a
June 56,0 53,8 11,0 7,0 6,1 70,8 4352 re a
Nov. 57,0 56,1 41,0 355 21,2 I1I,O 24,3 40,0 —
Feb. 49,0 65,3 5530 8,0 23,4. 238,8 40,5 36,0 20,8
Mean 51,8 53,1 35,6 6,1 12,8 109,9

* Months at far left should be read for recovery month of adults. Juvenile recovery is dis-
cussed in the text.

Table 28

Mean density per hectare, body weight, and biomass (in grams) of adult and

juvenile Chamaeleo pumilus based upon a composite of all study stations. (See

Table 26 for percentage recovery per month.) N.B. As juveniles of a given
month mature they are included with the adults of that month.

Mean Mean Total

Adults weight Juveniles weight Density Biomass
1213] 3S a er 20 13,5 20 1,0 40 290,0
Maates) 3) 3 ahs 35 8,5 42 1,5 77 361,0
pH =) = 4S 7.4 34 1,7 107 363.7
UES i ae 38 8,8 20 1,5 58 364,4
kanes ea 51 11,0 16 1,6 67 586,6
ifeeryewe eee 48 11,5 18 7 66 582,6
Aug. <) “Ree £: 70 6,5 29 1,8 99 507,2
epics” is) AEE 4. 66 10,5 35 0,6 IOI 714,0
Oct a s BBO 9,3 35 1,0 155 I 151,0
Nov. eRe e 89 933 22 0,6 III 846,3
Dees © a Gee QR 12,5 39 0,5 234 2 456,0
fates Ys) he ce ARTS 935 56 0,8 174. 1 165,8

INICAE SE cas oe 75,2 9,9 29,6 1,3 107,4 802,0

98 ANNALS OF THE SOUTH AFRICAN MUSEUM

Biomass of Chamaeleo pumilus was highest in December, no doubt reflecting
the increasing proportion of young and older juveniles. It is not certain whether
the slow climb from February to May is best assigned to an increase in marked
individuals, a reflection of actual conditions, or both factors. Biomass of C.
namaquensis was highest in February. But that of adults was relatively consistent ;
monthly variations merely reflecting increased weights of reproductively active
adults, and addition of juveniles. Since juveniles were not territorial and were
tolerated in the territories of the adults, biomass of juveniles in a given area
often exceeded that of adults.

The density of C. pumilus varied with habitat, being densest on reeds
surrounding still bodies of water, as vleis, and least in brushy areas. Density
in brushy areas never exceeded 12 (x = 8) per hectare, of which males com-
posed approximately 45°% of the population. In reedy areas densities ranged
from 75 to 200 (x = go) per hectare, of which males were 40-51% (X = 47%)
of the population. These data are not reflected in the tables. Differences in
habitat density for C. namaquensis are apparent in ‘Tables 32 and 33, but these
data are somewhat misleading, since more time was spent at coastal locales.
Also, there is a big difference between ‘inland’ and ‘coastal’ dunes. Inland
dunes have vegetation-covered hummocks at their bases, which are lacking in
coastal dunes which only have very meagre and scattered single grasses,
predominantly Eragrostis spinosa. Because these inland vegetated hummocks
were on true dunes, they were considered to be part of the dunes, whereas
coastal vegetation-covered dune hummocks were accumulations of dune sand
on flat areas, apart from dunes. Though found throughout the desert, C.
namaquensis was most numerous in topographically varied areas.

In February juvenile Chamaeleo pumilus (Table 29) were at parity with the
adults and in March 56% of the population, and least evident (16,8%) in

Table 29

Population structure (in per cent) of 346 adults and 148 young in the
marked population of Chamaeleo pumilus. Large follicles are those having a
diameter of 5 mm or greater.

Females
Yolked follicles Males
Month Juveniles Pregnant Large Small Active Inactive
HeDsae =. 1. 2) As) 5OLO 12,5 0,0 20,0 1755 oe
Mate 3 et. 54 15,6 52 Q,1 15,6 OS
OTE ae GE (MOONE By] 27,2 557 12,9 BOO
LS sr Pe eR: YT 13,8 8,6 8,6 20,7 13,8
MNEs, 2s Gs... BBhG 17,9 11,9 11,9 455 29,9
ei cat is Ne BRD 333 10,6 0,0 0,0 28,8
AGEs i. ayey. BOO 34,0 5,0 4,0 27,0 Oo
SePE eo eh. ISAO 23,0 8,0 10,0 22,0 3,0
Oct. STU ye oem os 28,4 6,5 8,3 30,3 329
INOW. 3) ae 1) TOG 25,2 1355 6,3 35,1 Oe
Dec. ‘ , ; ‘ 16,8 16,8 12,8 13,7 39,0 0,9

Jats Sh eee. 3308 2307 355 4,2 36,3 EO)

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 99

December. C. pumilus males were usually slightly in the minority (see also
Hogben & Mirvish 1928a, 6; Zoond & Eyre 1934), and in some months males
were outnumbered by a considerable margin. Only in November were female
C. pumilus greatly outnumbered by males. Juvenile C. namaquensis (Table 30)
were predominant in February (58,5 % coastal; 53,4°% overall) and a significant
component in November. Tables 27 and 30 reflect overall, rather than one
population data. Male C. namaquensis were somewhat more predominant in
June and November, almost at parity with the females in August (inland data
only), and the minority sex in February and April.

Table 30

Population structure (in per cent) of 207 adults and 107 juveniles in the
marked population of Chamaeleo namaquensis. Large follicles are those having
a diameter of 5 mm or greater.

Females
Yolked follicles Males
Month Juveniles Gravid Large Small Active Inactive
Repwp i = . <« 59,4 2,8 18,2 a7 21,1 0,8
Ais Sai aie 0,0 40,0 0,0 17,8 42,2 0,0
uneia. VSS.) or4y2 12,9 6,5 24,6 41,5 0,0
INGNe ee ce ss ATG Q,2 14,3 Q,2 19,4 6,1

Over 27 months Bourgat (1968a) marked 140 Chamaeleo pardalis on
Réunion Island, of which 80 were lost, 54 recovered over several subsequent
weeks, and six recovered several months later. Unlike C. pumilus and C. nama-
quensis, C’.. pardalis males outnumbered females 6:1, males being most abundant
in December to April, but tend to hibernate in cooler times, whereas females
are in evidence throughout the year. Bourgat observed 632 males, 382 females,
and 31 young. No young were uncovered in January, April to June, and August.
There are no other ecological field studies on chamaeleons, and in this respect,
statements of chamaeleon population structure are rather premature.

The spatial relationships of American saurians, especially iguanids, have
been the most studied, and good reviews are those of Rand (1967), and Mayhew
(1968). However, almost all of these are of no comparative value for Chamaeleo
pumilus, since the iguanids studied are not arboreal, and of doubtful value for
C. namaquensis. Most studied saurians have an almost 50:50 sex ratio. Population
density has been thoroughly investigated in Uta stansburiana and related insular
forms of Uta (Soulé 1964); U. s. hesperis, U. stejnegeri, and U. elegans (Burrage
1966) ; U.s. stansburiana, and U. stejnegert (Tinkle 1961, 1967; Tinkle, McGregor
& Dana 1962; Tinkle & Woodard 1967). The average inland density is approxi-
mately 25,5 territory-holding adult utas per acre (about 63,6 per hectare),
while that of littoral and insular populations is two to three times as dense.
Very few tropical species have been studied, but Harris (1964) reports of 36
Agama agama per acre (about 90,0 per hectare) with a biomass of about 2 000
grams (about 5 000 g per hectare). According to Cagle (1946), Hemidactylus

100 ANNALS OF THE SOUTH AFRICAN MUSEUM

on Tinian have a density of 500 adults in a 2 400 square feet area (about
223,0 m?), so assuming even distribution this gives 10 000 per acre (about
25 000 per hectare). Larger species have lower densities and all sizes of tropical
species the highest. Shore-dwelling and insular populations have higher
densities than those inland, even those adjacent to the coast.

Data are meagre on survival of lizard populations and those available
indicate widely different demographies in different species populations. Almost
all are concerned with temperate iguanids, save the tropical Basiliscus and
Anolis; Cnemidophorus (temperate) and Ameiva (tropical) are te1ds, and Amphi-
bolurus is an Australian agamid. Blair (1960), calculating on theoretical natality
rather than juveniles actually marked, estimated that 6-20°% of hatchling
Sceloporus olivaceus reached maturity and 20% of the adults survived to a second
breeding season. Fitch (1956) reports almost 40°% of young Crotaphytus collaris
reach sexual maturity, about 20% of these surviving a second season. Crenshaw
(1955) reports Sceloporus undulatus hatchlings suffered a 50% loss during their
first six weeks, and 68% in their first two months; a mortality schedule similar
to that reported for Uta stansburiana by Tinkle (1967). Burrage (1966) observes
that the brunt of predation is borne by the very young and adult females in
U.s. hesperis. Less than 10% of Baszliscus vittatus and Ameiva quadrilineata live for
one year and only 2% of Basiliscus survive two years (Hirth 1963). Essentially,
annual turnover is suggested in Anolis limifrons (Sexton, Heatwole & Meseth
1963) and Amphibolurus isolepis (Storr 1965), but these are based on size groupings
present at different times of the year, rather than recovery of marked animals.
Fitch (1958) records a 50% yearly reduction of adult Cnemidophorus sexlineatus.

2. Social interactions

Chamaeleo pumilus defended only its perches and such territorial conflicts
were noted in all months at homo- and heterosexual levels. There were more
such disputes between females in winter, more between males in summer,
though overall territorial disputes were seasonally constant. Table 31 documents

Table 31

Number of social interactions observed in the field in coastal and inland populations of adult
Chamaeleo namaquensis. (Table is set up to show the defender on the left versus the transgressor
on the right, hence the two sets of heterosexual combat.)

Social Interactions

Territorial conflicts Copulation

Month 22 us. 99 29 us. 83 3S us. 33 5S vs. 99 33 and 99
Feb. Coast 17 O 12 fo) o
Inland 6 fe) 2 O I
Apr. Coast 51 14 43 10 104
Inland e) O fe) O oO
June Coast 15 I 10 O 5
Inland 5 I fo) 2 dl
Nov. Coast O O 3 3 oO
Inland 9) O O O oO

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) IOI

C. namaquensis social interactions in the field at various contact levels. The
territorial structure of C. namaquensis was such that interactions were between
neighbouring individuals mainly on the finely delimited borders of their
respective territories. They often inflicted considerable damage on each other
in such defence. As defenders, females were involved in more homo- and
heterosexual territorial defence than males, but were not observed in any in
November, and no heterosexual combat in February. Males defended their
territories throughout the year, but were not observed to engage in heterosexual
disputes in February. Courtship and coition in both species is discussed under
courting in the reproduction section (see p. I11).

3. Territorial display

Territorial displaying Chamaeleo pumilus gorged the throat, which had
orange interstitial skin in Stellenbosch specimens, but purple in those from
Port Nolloth. C. pumilus laterally compressed the body which assumed Colour
Index ‘5’ and facing-off delivered a series of five side-to-side head bobs in a
right and left horizontal ‘T’, starting and finishing on the right. Head bobs 1
and 5 were at the top arm of the right ‘T’, and head bob 2 at the top of the
left “I”. These bobs were more like flicks, so quickly and precisely were they
executed. An entire set was delivered in 1,2 to 1,4 (X = 1,35 sec) seconds. Four
sets constituted a threat series, with 1,5 to 1,7 seconds intervals between each,
and 1,9 to 2,2 seconds intervals between each series. Refusal of the transgressor
to leave resulted in fight in C. pumilus in the field and in several observations
vicious attacks resulted when the transgressor refused to acknowledge the
defender’s display. Frequently, they fell from trees with interlocked jaws. No
deaths resulted, as in C. namaquensis, but severe injuries were incurred. As with
C. namaquensis, females were more aggressive than males.

C. namaquensis territorial display consisted of lateral body compression, a
stiff-legged erect stance, gorged throat (displaying purple interstitial skin) and
partly gaping mouth, either Colour Index ‘5’, excitement pattern (Hoesch’s
‘schreckmuster’), or in combination. In delivery, the combatants ‘faced-off’,
with much hissing, head-bobbing, and weaving of the whole fore part of the
body side-to-side, up and down; the rear was virtually stable, except in especially
heated displays. Looking head on, the head-bobbing was laterally in the hori-
zontal plane, describing an ‘S’ lying on its side, with the first and last bobs being
delivered on the right. Five such bobs constituted a set (delivered in 2,8 sec),
two to three sets per display with a one second interval between each. Refusal
of the transgressor to leave the defender’s presence resulted in combat, in which
severe, often fatal, injuries were incurred. There was no ‘submissive posture’ ;
only flight of the transgressor averted a fight. Two patrolling C. namaquensis
often displayed from their respective sides of a common border along its entire
length.

A discussion of the literature in respect and synthesis of social interactions
and display is included with that on territories.

102 ANNALS OF THE SOUTH AFRICAN MUSEUM

4. Size and structure of territories

Chamaeleo pumilus had an undefended, shifting, vertical home range, with a
vigorously defended night-time rest area. Shifting occurred only if the home
range did not provide adequate food throughout the year. C. pumilus frequently
walked considerable distances to locate new food sources. In plan view the
home range area was about 10 m? in both sexes, but since it was at several
different horizontal levels, or ‘multi-storied’, the actual area was much more.
For example, C. pumilus occupying a bush 3 m high and of 10 m? in plan view
with 20 such multi-storied plan areas, the actual home range area was about
600 m2. It is, therefore, a more effective use of space. Juvenile C. pumilus had
no sleeping area that they regularly used for a long time, and a continuously
shifting home range.

For simplicity territories occurring in various biotopes and habitats have
been placed under the type in which a given territory has most of its area.
Such territories embracing different biotopes or habitats were considerably
larger than most of those that were limited to one. Territory data are summarized
in Table 32 and given in detail of biotope and/or habitat in Table 33. Maximum
individual territories occurred in November for coastal males (8 000 mj’),
females (1 632 m?), inland males (1 752 m?), and females (998 m?), but mean
territory sizes were largest in April (male; 2 429,0 m?; female; 885,7 m?—
coastal only). One would suspect this to be true for inland populations, but
insufficient data are available, thus, the maximum mean (1 435,7 m?) of inland
male territories was in June, and females (881,8 m?) in November. Territories
appeared to vary in size according to reproductive demands, that is, male
territories generally increased in area during courting and those of females
were enlarged during egg-laying.

Table 32

Summary of seasonal variation in territory sizes (in square metres)

in coastal and inland populations of Chamaeleo namaquensis in South

West Africa. Means are in parentheses. (For a detailed consideration
by biotope and habitat, see Table 33.)

N Coastal N Inland

Feb.

dd 16 771-6 800 (1 294,8) 4 I 109Q-I 300 (I 225,2)
OO" ie 17 7— (G00) (25256) 6 790— 899 (858,0)
Apr

dd 21 800-7 200 (2 429,0) 0) =

OP 24 120-1100 (885,7) 0) =

June

dd 23 I 030-2 666 (1 192,1) B 1 256-1 751 (1 435,7)
QP 15 IOI— 250 (176,5) 3 800— 920 (864,0)
Nov.

3d 21 927-8 000 (1 954,1) 11 I 211-1 752 (1 089,6)

Of 17 102-1 632 = (21,0) 8 joo— 998 (881,8)

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104 ANNALS OF THE SOUTH AFRICAN MUSEUM

The territorial structure of C. namaquensis consisted of a more or less
centrally located resting area, usually in a redoubt, but there were no sur-
rounding areas of lesser or greater usage. On waking, chamaeleons patrolled
to the border limits and encompassed their entire domain; as the day pro-
gressed they proceeded inwards in decreasing patrol courses towards the rest
area and night-time retirement. In areas of micro-relief, such as hummocks,
the border configuration closely followed the higher ground to an extent that
a finger-like projection on such high ground of one chamaeleon’s territory
intruded into lowlands dominated by another. This system prevailed even on
monotonously flat areas, and especially on dunes, where one would suspect
territories to be circular, or squarish, since there was no local micro-relief to
affect border configuration. There was no overlap of any territories with
members of the same or the opposite sex. All ownership disputes, and most
courting, were border incidents, and upon completion of courting the contact
became a territorial challenge, the ‘invading’ sex partner being evicted. Usually
the larger male territories were surrounded by female territories more than
they bordered on those of other males. Female territories were smaller than
those of males.

Juveniles had no territories of any discernible sort. They always slept on
an object, not necessarily the same, and companionably together when the
occasion warranted. Juvenile C. namaquensis occupied a shifting home range
(10-53 m?; X = 27,5) that occurred wholly or partly in the strongly defended
territories of the adults, from whom they were free of challenge. Recently
hatched C. namaquensis initially had their home ranges within the territory of
one of their parents, or within the territories of both parents. As they matured,
the juveniles apparently began defending their home ranges as they stabilized
their locations. By shifting an undefended space when juvenile and free of
challenges, the young might find an unoccupied area that they can defend on
adulthood.

Establishment of territories was impossible in captivity and this mediated
an entirely different type of spatial occupancy in C. pumilus and C. namaquensis.
Both defended favoured rest sites and C. pumilus giving birth and ovipositing
C. namaquensis defended the parturition and nest site, respectively, from all
intruders. Thus, in captivity both chamaeleons worked on a ‘free run’ basis,
which, in the case of C. pumilus explains why previous authors considered it not
to engage in fights, since they had not observed it in the field.

Literature accounts of lizard social organization are virtually limited to
American forms, especially the iguanid Uta stansburiana. Harris (1964) studied
social interactions in an agamid, and noted that female Agama in estrous are
more submissive to males than non-estrous females. The same was noted in
Chamaeleo pumilus and C. namaquensis, and by Fitch (1940) for Sceloporus occi-
dentalis, Irwin (1965) for Uta stansburiana, U. stejnegeri and U. hesperis (Burrage
1966) and demonstrated (Ferguson 1966) as controlled in Uta by FSH.

Brain (1961) describes the display of Chamaeleo dilepis as similar to that of

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 105

C. namaquensis, but C. dilepis threatens broadside on, rather than in face-off
position as in C. namaquensis. Bustard (1958: C. jackson’ ; 1965: C. hohnelu ; 1966:
C. bitaeniatus; 1967: C. gracilis) describes the behaviour of several captive
specimens, and in his discussion of C. gracilis also mentions observations on
Maicrosaura pumila (= Chamaeleo pumilus) and Chameleo chamaeleon (= Chamaeleo
chamaeleon). C.. jackson exhibits ritualized fighting, using its horns to ward off
attackers of its own and other species, and in intraspecific conflicts in attempts
to dislodge each other. C. hohnelit possesses the most highly ritualized fight
behaviour, with the use of more extreme colour changes of any other chamaeleon,
the combatants circling each other with mock-biting, which settles encounters
without injury. Schmidt & Inger (1965) describe display in C’. ituriensis ; sub-
mission is by assuming a drab colour, with which the wearer is safe from
further attack. The male C. hohneli is the more aggressive sex, with the reverse
being true of C. bitaeniatus. C’. chamaeleon and C. gracilis have threat display
followed by actual fighting, inflicting severe, sometimes fatal, injuries, as is
true of C. namaquensis and C. pumilus in the field. C. gracilis has a submissive
posture, which secures the chamaeleon assuming it from attack from even an
irate individual. In this posture the body is longitudinally extended making
the minimal distance between dorsal and ventral areas. Both sexes of C. pumilus
were observed to threaten other lizards, as Bustard (1965) notes for female C.
hohnelu. Lateral compression, throat gorging, open-mouthed hissing and
aposematic colour and patterns are the norm of chamaeleon display. In
especially intense displays, they rock vigorously from side to side. C. bitaeniatus
(Bustard 1966) and C. pumilus (Bustard 1967a) males do not fight and are less
aggressive than the females. Bustard’s observations as to display and behaviour
patterns of C’. pumilus are essentially as in this study and in most respects as
found by Spence (1966) for Micresaura damarana (= Chamaeleo pumilus) and Von
Frisch (1962) for Microsaurus pumilus (= Chamaeleo pumilus), except Von Frisch
considers females less hostile than the males. Unfortunately, all these workers
examined C’. pumilus in captivity, whereas individuals of this species did give
combat in the field.

Fighting in wild populations of lizards is rare, but has been recorded for
the iguanids Sceloporus grammicus (Evans 1946) and Uta stansburiana (Burrage
1966; Tinkle 1967). There is no study, other than the results reported here, for
Chamaeleo namaquensis and C’. pumilus, on the significance of head-bobbing in
chamaeleons at the level of Carpenter’s (1962) and Hunsaker’s (1962) investi-
gation of the function of this in iguanids. Bustard (1966) found courting male
C. bitaentatus jerk the head. The head-bobbing display of C. namaquensis bears a
close similarity to that which the author observed in the iguanid Cyclura cornuta.

Discussions of spatial occupancy in lizards are disconcerting, because of
the varied techniques employed, consideration of widely separate populations
in different habitats, physical factors, such as varied geologic substrates, local
topography, and other biotic dynamics, for example, the population density of
the studied species, plant density, and competitors. Also, despite the call for

106 ANNALS OF THE SOUTH AFRICAN MUSEUM

metrication, a not inconsiderable number of recent papers persist in utilizing
outdated units, requiring tedious conversion and a double set of figures in any
presentation reviewing data. With few exceptions, no attempt has been made
to study adjacent populations in the same general area under slightly different
conditions of local topography, geologic substrates, plant, and population
density. For example, for five years in Southern California Burrage (1966)
observed proximal coastal bluffs, sandy and rocky beaches, coastal and inland
canyons, areas of rugged and flat topography and varied geologic substrates,
plant density, and population density in an investigation of spatial occupancy
of Uta stansburiana hesperis and found widely different territory sizes and social
organizations obtaining at each study station. Jorgensen & Tanner (1963)
used the density probability function obtaining larger territory sizes for this
species in Nevada, than did Tinkle, McGregor & Dana (1962) using the
minimum polygon method for this species in Texas. Furthermore, in Texas,
Uta concentrates its activity around wood rat (Neotoma) nests in mesquite
(Prosopis) —a rich source of arthropod prey—and, has less need to wander for
food than those in Nevada. Thus, environmental factors in widely separated
areas or adjacent areas of varied topography could account for an actual
difference in territory size, rather than computation error.

Furthermore, as Tinkle (1967) observes, there are few studies based on
large numbers of captures. Indeed, a lack of sufficient minimum recaptures is
why no territorial data in April for inland Chamaeleo namaquensis are presented
here. Most studies demonstrating territorial behaviour in lizards are based on
temperate iguanids, with little speculation as to its adaptive significance in
reptiles, as has been done by Nice (1941), Hinde (1956) and Carpenter (1958)
for other animals, mostly birds. Rand (1967) has made a step in this direction,
based largely on his observations of the iguanid Anolis lineatopus in Jamaica.
Hypothetical values of territory can be: (1) securing a requisite share of
environmental resources, and/or (2) mating, and/or (3) survival of the offspring.
Rand reports that critical environmental resources for A. lineatopus need be
defended intra- and interspecifically. In Chamaeleo pumilus and C. namaquensis
food was certainly not critical, especially for the latter. C. pumilus defended only
its favourite perch for sunning and rest, thus, a secure night-time shelter was
critical to this species. The fact that C. pumilus was frequently found on top of
grass stems in grassy areas away from shrubs cannot be assigned to a surplus,
displaced population away from supposed ‘choice’ shrubs, because wild C.
pumillus preferred reeds. The high metabolic rate of C. namaquensis may require
spacing—as their rigid territorialism invokes—for more efficient exploitation
of prey. Since C. namaquensis has ubiquitous habitat preferences, site selection
cannot be important. Vigorous territorial defence for food by male and female
CG. namaquensis seems interesting, particularly when pugnacious defence of
territories by both sexes in some lizards (e.g. Sceloporus merriami) occurs if food
is the limiting resource (Milstead 1961). The structure of territories is possibly
most valuable to C. namaquensis, for even if transgression was allowed in courting,

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 107

it assured that any given male would meet more females than other males
during the normal diel patrol of both sexes. Only captives defended the
immediate nest site, and such defence must be considered an artifact of captivity.
Since suitable nest sites were available in each female’s territory, territorial
defence in the field would limit or eliminate intrusion of the nest site fer se.
Defence of the nest sites and their location within the female territory prevented
exhumation of buried eggs by other females digging a nest.

Bourgat (1968a) notes that each individual C’. pardalis patrolled an area of
several 10 square metres. There are no other comments of territory size in
chamaeleons, but defence of a favoured perch is noted for C. dilepis (Brain 1961),
C. jacksont (Bustard 1958), C. hohneli (Bustard 1965), C. ditaeniatus (Bustard
1966), C. gracilis (Bustard 1967a), and synonomies of C. pumilus, Microsaurus
pumilus (Von Frisch 1962), Microsaura pumila (Bustard 1967a) and Muicrosaura
damarana (Spence 1966). All these observations are based on captives, except
those of Brain and Spence. Table 34 gives the mean territory and home range
sizes of some lizards that are available in the literature. These data used the
minimum polygon technique, or planimetry. It is important to an interpretation
of chamaeleon home ranges to realize that most chamaeleons are aboreal,
whereas the majority of the lizards investigated are terrestrial. Burrage (1966)
notes that only the resting site is defended by Uta stansburiana hesperis in popula-
tions so large (>250 per acre; about >625,0 per hectare) that individual
territorial establishment is impossible or unnecessary. In a consideration of
territories of Uta, Burrage (1966) discusses at length the influence of intricately
eroded and/or steep slopes in allowing the establishment of rather large
territories in high population densities, which perhaps approaches the spatial
relationships of Chamaeleo pumilus. ‘This paper also considers local topography,
relief, and slope angle, differences in geologic substrates, plant density, and
lizard population density at coastal and inland sites in a small geographic area
to assess factors regulating the establishment of territories and social organiza-
tions in Uta stansburiana hesperis.

Knowledge of social behaviour in reptiles is poor; what is known is
somewhat confusing, since display patterns appear in newly hatched or new-
born young, as observed in Chamaeleo pumilus. Carpenter (1967) gives an
interesting review of social behaviour of iguanids, with pertinent references,
and a detailed study (Carpenter 1961) of social behaviour of the desert iguana
Dipsosaurus dorsalis. Hunsaker & Burrage (1969) studied a multi-species
assemblage of captive iguanids and demonstrated a shift from territories to a
social hierarchy as a result of population pressure and reduction of available
area. ‘his hierarchical system is established by increasingly vicious fighting,
rather than the normal displays, as population pressure increases, and/or the
available area is reduced. Similar social hierarchies in wild populations of
normally territorial iguanids are noted for Ctenosaura pectinata (Evans 1951).
Burrage (1966) studied the various social relationships of Uta stansburiana
hesperis of California in relation to habitat and physical factors, population

108

ANNALS OF THE SOUTH AFRICAN MUSEUM

Table 34

Review of mean territory and home range sizes of some of the lizards reported in the literature.

Species

Amblyrhynchus

cristatus

Ameiva
quadrilineata

Anolis sagret

Basiliscus
vittatus

Chamaeleo
namaquensis

Chamaeleo
pardalis

Chamaeleo
pumilus

Cnemidophorus
hyperythrus

Cnemidophorus
tigris

Ctenosaura

pectinata

Sceloporus
olivaceus

Uta stansburiana
hesperis

Uta stansburiana
hesperis

Uta stansburiana
stansburiana

Uta stansburiana
stejnegert

Sex/Age

ad’t.

Area occupied

Acres Metres?

_ 1,0

= 16,4
— 15,1
— 21,1
aa 13,7
— > 36,0

a 14,9
= 12,4
= 12,0
— 12,2

a 2755
== I 71755
— I 250,2
_ 382,0
= 867,9

‘several 10 m2’

_ 600,0
0,07 283,3
0,10 404,7
0,09 364,2
0,50 2 023,55
0,24 971,3

— 2a
0,027 109,3
0,017 68,8
0,17 687,9
0,07 283,3
0,005 20,2
0,004 16,2
0,05 202,4
0,034 137,6
0,075 303,4
0,056 226,6
0,021 85,0
0,016 64,8
0,04 161,9
0,10 404,7
0,03 121,4
0,11 445,2
0,03 121,4

Remarks
only in breed-

ing season
only displays

coastal
inland
coastal
inland

California

99
Calif. coastal
99

Calif. inland

by)
intertidal home
range of
strand-dwellers

Nevada

be)

Source

Carpenter (1967)

3)

Hirth (1963)

Evans (1938)
Hirth (1963)

Bourgat (19682)
this study

Bostic (1964)
33

Jorgensen &
Tanner (1963)

29

Evans (1951)

Blair (1960)

Jorgensen &
Tanner (1963)

Tinkle (1967)

99

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 109

pressure and food supply. The social organization of other races of U. stansburiana
have been studied by Tinkle (1967). Clarke (1965) studied several iguanids in
captivity, showing formation of dominants—sub-dominants hierarchies. Harris
(1964) gives a detailed account of social behaviour in the agamid, Agama agama,
noting formation of social hierarchies in high population densities. Harris
further notes the establishment of territorial borders in A. agama, where two
males fought several times over a path between their boundaries. Fighting
decreased and eventually display along the path replaced combat as the border
became established, with rare attempts at violation. Establishment of social
hierarchies in high population densities limits the frequency of antagonistic
behaviour that would result in attempts at territory formation. This has been
demonstrated by Soulé (1964) and Burrage (1966) in the case of littoral and
insular high density populations of Uta, where only the retreat burrow of each
lizard is defended and only a ‘free run’ home range exists. This has also been
noted by the latter author for some inland populations and is always associated
with abundant food supplies.

K. Reproduction

1. Sex determination and description of adult Chamaeleo pumilus and C’. namaquensis

Males are the smaller sex in C. namaquensis and C. pumilus. Male C. pumilus
have a slightly longer tail length (49-56%; X = 53% of total length) than
females (39-56%; ¥ = 47%). In C. namaquensis the tail length never exceeds
the snout-vent measurement and tail length as a percentage of total length is
nearly equivalent in the sexes (males; 30-44%; * = 38%: females; 23-50%;
x = 38%). In both species the limb proportions are more robust in males,
especially the hind, and the head proportionately larger, more rugose and
ornamented as compared with females. The tail base of males, housing the
paired copulatory organs, is larger and has a distinctly swollen appearance
when the animal is reproductively active. The hemipenes can be everted by
gentle pressure on the tail base to determine sex at any age.

Zoond & Eyre (1934) describe the general pattern of C. pumilus to consist
of stripes, patches and individually coloured skin tubercles, arranged as ‘bands’
(mid-laterum), ‘islands’ (large tubercles within the bands), ‘margins’ (dorsal
and ventral to the islands), and ‘back’ (area dorsad of the margins). Bands
are always present, though varying in width and distinctness between indi-
viduals, and at thermal neutrality (Colour Index ‘2—3”) are orange or brown.
The ground colour of the back in adults is usually green, though some have it
brown, russet, or yellowish at thermal neutrality, which is essentially a con-
tinuation of a juvenile colour type (Table 48). In these individuals, always
females, brown predominates and there is really no distinct pattern. The usually
blue or gray islands and margins vary and may be totally absent in some,
especially females. The margins are quite wide and often intensely bright blue
in some males. Some C. pumilus have large orange tubercles in the back, or
green region. Further discussion of the pattern of C. pumilus is given by Zoond &

110 ANNALS OF THE SOUTH AFRICAN MUSEUM

Eyre (1934) and as they note, it 1s extremely variable with individuals, and
changes somewhat in each through the Colour Index, since each colour, and
thus the pattern lay out, is masked, or enhanced through the values of the
Colour Index. However, a brown one, for example, cannot go green, or vice
versa, but only ‘light’ or ‘dark’ phases of these colours; a feat also noted by
Farghaly (1941) for C. vulgaris (= C. chamaeleon) and a host of others back to
Aristotle.

The 65 male C. pumilus examined varied in snout-vent from 53,0-93,0 mm
(K = 73,5 mm), with the tail 55,5-107,0 mm (X = 82,3 mm). The 86 female
C. pumilus examined had a snout-vent length of 51,0-102,0 mm (x = 78,8 mm),
with the tail 52,0-103,0 mm (xX = 78,0 mm). Spence (1966) collected 4 males
and 7 females of Microsaura damarana (= C. pumilus) at the Storms River bridge
in the Tsitsikama National Park, Cape Province. He found the snout-vent
length to be 54,6—78,0 mm (x = 62,9 mm) in the males; and that of the females
to be 51,6-78,3 mm (x = 65,8 mm). Tail length for the Tsitsikama males
ranged from 125,2-192,5 mm (X = 147,7 mm), with the tail 55,4-59,5%
(X = 57,2%) of the total length, and for the females tail length ranged from
58,9-97,5 mm (X = 77,0 mm), with the tail 50,9-55,5% (X = 53,6%) of the
total length. Since (see pp. 6—7) this study follows Hillenius (1959), it is not
known whether the differences in sizes and the tail as a percentage of the total
length between Spence’s Tsiksikama M. damarana (= C. pumilus) and C. pumilus
in the southern Cape Province are ascribable to his smaller sample (i.e. random
error), genuine specific, or subspecific differences, or simply a geographic
cline within a species. Bustard (1966) noted that the sexes of the viviparous
chamaeleons rest differently; the males longitudinally stretched, with the tail
straight out; the females hunched, with the tail in an ungripping coiled watch
spring.

There are no sexual, or age pattern differences in Chamaeleo namaquensis,
but there are differences in pattern (Table 35) and proportions between coastal
and inland individuals. For example, the depth and breadth of the head of
most coastal specimens are almost equal and the body stockier and more
porcine, while most inland individuals have a conspicuously long, deep,

Table 35

The percentage of ground colour types in the inland and coastal populations of
Chamaeleo namaquensis (coastal N = 100; inland N = 40).

Populations
Inland Coastal
Ground Dunes
colour River Gravel +8km River’ Gravel
type Dunes bottom plain Shore in bottom plain
Sulphur yellow ~ = — 80 35 10 2
Gray 13 85 100 19 20 50 97

Green — — — I 30 40 I

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) III

narrow skull, and the body form and proportions are more attenuated and
slender. The tail length as a percentage of the total length also differs.

2. Courting

Courtship was observed in the field and captivity during all months
except June and July in Chamaeleo pumilus and from April to July in C. nama-
quensis. It is similar in pattern to that described for the African C. dilepis (Cott
1934), Trench (1912) for the Indian C. calcaratus (= C. chamaeleon zeylanicus)
and C. vulgaris ( = C’. chamaeleon) as described by Schrieber (1912).

C’. pumilus courted only in bushes. Courting C’. pumilus males are a bright
green, the females usually dark. In most respects as to head and body motions
the courtship of C. pumilus closely resembles that given below for C. namaquensis,
except the former head bobs more jerkily in a flat, horizontal plane. In C.
pumilus the tail is kept on the branch and there is no circling dance. Pre-
sumably this is because courtship occurs in different situations in the two species.
Coitus is as described below for C. namaquensis and in C’. pumilus lasts from seven
to fourteen minutes. Bustard (1963) observed courting in Mucrosaura ventralis
(= C. pumilus), with coition lasting up to two hours. Von Frisch (1962) found
Microsaurus pumilus (= C. pumilus) copulated for eleven minutes. During
coition the female is passive, but becomes aggressive after coitus, which
temperament lasts until termination of her pregnancy. As also observed in
the literature cited here on chamaeleon breeding, these animals are solitary,
tolerating close proximity only during mating. C. pumilus and C’. namaquensis
were seen to copulate two to three times per day, several times per week,
and both sexes are even more aggressive to members of their own sex (see
population structure p. 105) at such times.

Courting C. namaquensis of both sexes are mottled and spotty. The male
C. namaquensis approaches the female with his tail held up and commences
‘dancing’ around her with a slow, pronounced weaving side to side of the body;
not fast as with the territorial challenge. This is similar to head-bobbing in
other lizards, but in C. namaquensis the body and head bob in unison, as it
were. However, the head concurrently describes a horizontal ‘S’-shaped
bobbing in challenge, which may evidence itself in initiation of courtship
(see p. 101). The large female, if receptive, remains passive, or ‘face-offs’
the male. Then he intensifies his display with sideways jerks of the head and
exaggerates his highly erect ‘dancing’ stance, lateral body compression, and
tail held high. Continuing, both open their mouths and ‘bisss’ at each other,
lunging, weaving back and forth, and flicking their tails at each other. If the
male touches the female, she may feign biting, but usually prods him with
her jaws closed. At the onset of copulation the female bolts a short distance,
pursued by the male. The female halts in a highly erect and exaggerated
stance, and the male climbs on to her back just anterior to her hind legs, his
hind limbs gripping hers on their dorsal surfaces. The plantar surface of the
male’s fore paws are placed on the front of the female’s axilla. The male swings

II2 ANNALS OF THE SOUTH AFRICAN MUSEUM

down his tail under the female’s tail base, bringing their vents in apposition.
One of the hemipenes is everted and enters the female’s cloaca. Copulation
lasts for five to fifteen minutes in ‘adpressed’ Body Compression ‘I’ and is
of the normal saurian pattern.

Sex recognition is by sight in the related iguanids and agamids, and in
these, differences in colour, shape and behaviour are used in sex determination.
Since size is the only unvarying difference in the chamaeleons studied, it is
difficult to know whether this would have any value in sex determination for a
large male and a small, recently matured female, or one medium-sized. Mating
in chamaeleons may start off as a challenge and the answering behaviour of the
female to this determines the outcome. Brain (1961) considered there were
frequent rebuffs to homosexual mating attempts due to ‘mistakes’, with the
enraged and unwilling male partner pulling off his attacker. This may be so
for the C’. dilepis Brain observed, but in C’. pumilus and C’. namaquensis such
injuries were due more to territorial fighting and in these species both sexes
had such back scars. Non-receptive females aggressively asserted themselves by
biting the inguinal region and flanks of a potential suitor, and since the females
are larger than the males, this frequently ended in damaging injuries and death.
This occurrence is particularly true in C. namaquensis.

Trench (1912) observed copulating C. chamaeleon zeylanicus in October,
noting mated females were a jet black and aggressive to males. Bons & Bons
(1960) say courting occurs in August and September in the North African
deserticulous C’. chamaeleon. Brain (1961) gives a four month gestation period
for the East African C’. dilepis, putting courtship back to about May, agreeing
with Milner (1947). Cott (1934) observed C. dilepis courting in February in
Mozambique.

Only recently ovulated females of C. pumilus and C. namaquensis were
receptive to males, a condition noted in iguanids by Burrage (1966) for Uta
stansburiana hesperis and Sceloporus occidentalis (Fitch 1940).

3. Description of the eggs of Chamaeleo namaquensis

Fresh-laid eggs were beige, becoming immaculate white with thin,
parchment-like shells, though the sand usually adhering to them gave them a
reddish appearance. Of 250 C. namaquensis eggs examined (Table 36) in the
field and captivity, the largest was 26,0 X 14,5 mm, 2,8 g; the smallest 17,5 x
10,0 mm, 1,2 g (X = 20,5 11,6 mm; 1,5 g). FitzSimons (1943) states that
C. namaquensis eggs average 20 X 13 mmat laying. C. dilepis eggs may be spherical
(diameter 8,0-10,0 mm (FitzSimons 1943), 12,5 mm (Wager 1958)) or oval
(12,0-16,0 x 7,0-8,0 mm (FitzSimons 1943), 10,8-15,4 X 7,2-10,6 mm (Brain
1961)). C. gracilis eggs when laid average 10,0 X 14,0 mm (Menzies 1958), and
Shaw (1960) gives C. basiliscus eggs as being 10,0-14,8 X9,5-13,5 mm, 0,7 g
(X = 13,3 X9,9 mm; 0,67 g). All in all, there is a dearth of information on
chamaeleon eggs as compared with other saurians.

113

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN)

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II4 ANNALS OF THE SOUTH AFRICAN MUSEUM

4. Parturition sites of Chameleo pumilus and nesting sites of Chameleo namaquensis

Chamaeleo pumilus females giving birth select small-leaved shrubs or grass
stems. Parturition of 56 litters for a total of 614 young was observed. In any
given litter, time between births of young took less than a second to as much as
13 minutes (X = 8 min, 10 sec). The time between parturition and the young
being active and free of their membranes was usually immediate. About 10%
were born internally, appearing free of their egg membranes and exhausted
yolk sacs, which came out first. The entire birth process may take nearly two
hours for a litter complement of 10 or more young, or as little as twenty minutes
for a litter complement of 5 or less. Abel (1931) found C’. pumilus and C. melano-
cephala (= C. pumilus) to give birth to nine young in one and a quarter hours.
Bustard (1955, 1965, 1966) records and compares birth in several viviparous
chamaeleons, including C. bitaeniatus, C. hohnelu, Miucrosaura pumila and M.
ventralis (= Chamaeleo pumilus). Nine Chamaeleo pumilus young freed themselves
and were active in a minute, six C. bitaeniatus were free in 1,3 minutes, but
C’. hohnelut took 5,3 minutes. Bustard (1955) gives the entire birth process of
seven C. pumilus as lasting 24 minutes, with the average time of the birth
process of individual young as I minute, 42 seconds (range: 0,15 sec to 4 min)
and the average time between births of individual young as 2 minutes, 50
seconds (range: 0,04 sec to 7 minutes, 15 seconds).

Chamaeleo namaquensis nests were constructed in the typical oviparous
chamaeleon manner, consisting essentially of a hole large enough for the
female with a terminal enlargement for her to turn around in at the end of
excavation and commencement of egg-laying. In the field favoured nest sites
were loose gravel, and especially the foot of and the windward slopes of large
dunes, and below the crest of small (6 m high) ones. Such sites were abundant
in the field, and each female had its own nesting site located within its tightly
defended territory. In crowded, captive conditions an area 350 mm in diameter
was viciously defended against intrusion by other females, gravid or not, and
even males. For up to a week prior to laying, most females dug exploratory
holes to a depth of 130 mm; which, presumably, was in search of the layer of
moist sand under which the eggs were laid. In captivity, the eggs were laid at
100 mm total depth, provided an artificial layer of saturated sand was available.

The construction of six nests in captivity for a total of 83 eggs was observed,
and two nests in the field for a total of 25 eggs. Only data in Table 36 refer to
the 225 eggs laid in captivity. Nest-building in captivity was as in the field, and
the process was observed by inserting a horizontal glass viewing plate, under
which the animals dug. Some completed nests were excavated to examine their
form. After preliminary holes had been dug, the preferred site was selected,
usually on a slight rise, since a steep slope would invite tunnel collapse in
digging, especially through the initially dry, non-cohesive upper substrate
layers. Nevertheless, the top portion of the nest was about 300 mm in diameter,
plus a spoil heap of 1,20 m. The nest was constructed as a pit down to the
loose, moist sand layer, which was 10 mm subsurface in gravel, deeper for dune

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 115

sand, and extended for a depth of approximately 150 mm, becoming dry
deeper than this. It was to this dry layer below the loose, moist layer that
C. namaquensis dug. Excavation through the moist area was narrow (approxi-
mately 150 mm wide) and the terminal enlargement in the dry area beneath
this was 77 mm or more, so that the nest had an appearance of a wide-mouthed,
beakered flask, with a narrow neck and wide base. Dug at an angle of 60-80",
the nests were almost consistently of an overall depth of 200-250 mm, rarely
more, never less. The female excavated this with her eyes closed by using her
head as a battering ram, pushing vigorously forwards and laterally, and
somewhat up and down. The right fore and left hind feet acted as braces, while
the left fore foot dug, pushing the excavated spoil back to the right hind foot
for evacuation. This arrangement was alternated back and forth in the course
of excavation. As the spoil accumulated behind, the female cleared this by
backing up and using the hind feet as ploughs until at least 350 mm clear of
the excavation area, where the spoil was dumped on the heap. At the top of
this heap, the female shook off the spoil that had accumulated on the top of
her head, then opened her eyes and walked back to more excavating. Nest
excavation occurred at any time of the day or night. The time from the start
of excavation to completion of oviposition took as little as eight or as long as
ten hours, with no rest between excavation and oviposition.

The first eggs were laid with the female facing tail outward, positioning
the dropped eggs with her fore feet as they rolled from her cloaca under her
body and down to the terminal enlargement. In ovipositing the tail was held
up as space permitted, the pelvis resting on the floor, and the legs held high
and far apart, especially the hind ones. Passage of eggs resembled defecation.
Six to eight eggs were well-spaced in the loosened floor of the terminal enlarge-
ment and constituted the first layer of eggs, which was then covered by spoil
and then another layer of eggs and so on. As the terminal enlargement filled,
the female reversed her position and with the head then pointing outward
completed egg-laying, each egg layer being separated from that above and
below it by a layer of spoil. The final layers were positioned with the hind legs,
and the upper spoil layer tamped down. The first eggs were laid at average
intervals of 20 minutes, which became progressively shorter as laying proceeded.
At mid-laying the interval between eggs averaged 10 minutes, 7 minutes
towards the end, and to as little as 30 seconds or almost instantly for the last
dropped. Depending on the clutch complement, one or two hours comprised
the ovipositing period. Upon emerging at the conclusion of egg-laying, the
female used her hind legs to push spoil back into the hole to fill it. This final
operation proved interesting in captivity, since other C. namaquensis of both
sexes sometimes assisted. Spent females ate to capacity and captives must be
given as much food as desired.

Chamaeleo basiliscus (Shaw 1960), C. chamaeleon zeylanicus (Trench 1912),
C. dilepis (FitzSimons 1943; Milner 1949; Wager 1958; Brain 1961) and C.

gracilis (Menzies 1958) all construct nests as does C. namaquensis, except that

116 ANNALS OF THE SOUTH AFRICAN MUSEUM

those of C. dilepis are at a less steep angle (45°) and may be considerably
deeper (250-700 mm), as those of C. chamaeleon zeylanicus (to 350 mm), or
considerably shallower (85 mm) as those of C’. gracilis. Digging time may be as
much as 60 hours (C. chamaeleon zeylanicus), 44 hours (C. gracilis), or 24-30 hours
(C. dilepis). Rain-moistened soil is selected for ease of digging in these species,
and in the case of tropic forms construction of nests coincides with the end of
the rainy season.

5. Annual number and size of litters of Chamaeleo pumilus and clutches of C.
namaquensis

Sexually mature C. pumilus females had four litters per year; the size of the
female bears some relation to litter size, and the larger females had the largest
litters (Tables 29, 37, 38). The first litter (7-9; x = 8) of newly matured
females (snout-vent 51-60 mm) was larger (3,0-6,0; x = 5,1) than that of those
61-70 mm snout-vent. Births have been recorded in February to May, Septem-
ber, November, and December. The largest litters (5,0-21,0; X = 17,0 young)
were born in December; the smallest in April (3,0-6,0; x = 4,5), overall;
3,0-21,0 (x = 11,0). The difference in size of the young, according to parturition
month, is discussed later.

Table 37

Number of embryos and developing oviducal eggs per month in relation to the snout-vent length
of female Chamaeleo pumilus. (Means are in parentheses.)

Snout-vent length in millimetres

Month 51-60 61-70 71-80 81-90 QI-—100 IOI-110
Feb. 7 8-13 (10,5) 11-16 (13,5) 18

Mar. 3-5 (4,6) 11 6-15 (13,3)

June 18 21

July 13 7-18 (12,5) 12-13, (12,5) 17
Aug. 12 12

Sept. 6 7-10 (8,5) 18

Oct. 9 11-16 (13,5) 19

Dec. 10-11 (10,5) 14

Jan. 5 II 10

Table 36 gives the size of female Chamaeleo namaquensis, the size of clutches
laid by each, and all other pertinent data. C. namaquensis eggs have been
recorded from May to September. Regardless of the size of the laying female,
the clutch complement was largest in those laid in July (10,0-22,0; X = 13,0)
and smallest in those of September (6,0-13,0; ¥ = 9,5). The majority of those
laying in September were recently matured females, though considerably
larger and older females laid the same number (Table 39). The overall clutch
complement was 6,0-22,0 (KX = 13,2). September clutch eggs were slightly
larger (18,0-26,0 x 10,0-13,0 mm; 1,2-1,9 g; X = 21,4 X 11,3 mm; 1,5 g) than
those of other months (Table 36). Females laid two to three, possibly four
clutches per year (Tables 30, 40).

117

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN)

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118 ANNALS OF THE SOUTH AFRICAN MUSEUM

FitzSimons (1943) gives a clutch size of 20 eggs for Chamaeleo namaquensis.
Clutch size in other oviparous chamaeleons varies from 10 in C. chamaeleon
zeylanicus (Minton 1966) and C. dilepis (Brain 1961) to as many as 31 in C.
chamaeleon zeylanicus (Trench 1912) and 45 in C’. gracilis (Menzies 1958), and as
high as 57 in C. dilepis (Wager 1958). The average clutch complement of

oviparous chamaeleons is 30-40.

Table 39

The monthly number of oviducal eggs and yolked ovarian follicles at or greater than five
millimetres in diameter in relation to the snout-vent length of female Chamaeleo namaquensis.
Means are in parentheses.

Snout-vent length in millimetres

81-90 gI—100 101-110 111-120 121-130 131-140
Apr.
Oviducal eggs 5 13
Ovarian 3
June
Oviducal eggs 10
Ovarian 14 2 II
Aug.
Oviducal eggs 10
Ovarian 14 2 12
Nov.
Oviducal eggs
Ovarian F 2 8-13 (10,5)
Reb:
Oviducal eggs
Ovarian 10 20 15 25

Table 40

The growth and reproductive states in captivity of five male and five female Chamaeleo namaquensis.
Dimensions are in millimetres; weights in grams.

April August November
Sex s-v-+tail Wt Rep. s-v-+tail Wt Rep. s-v + tail Wt Rep.
3d 105 77 43 IBL 108 80 50 IBL 115 82 52 IBL
3d 97 84 B IBL 101 88 42 IBL 112 100 51 IBL
bd 135 72 50 IBL 136 82 54 IBL 140 103 66 IBL
feXe4 120 70 45 IBL AG 1G) 47 IBL 130 75 54 IBL
3d UD BE 13 IBL 86 58 18 IBL go 60 27 IBL
ore) 108 go 50 GR 110 90 57 GR 110 90 62 LYF
go 127 85 85 GR 19 FRE 86) GR 13 2 113 GR
29 117 83 700 GR 120 90 60 TLNGi8 121 100 51 SYF
le) 86 85 47 GR 100 70 61 LYF 109 92 81 GR
Oe) 82 78 A5 GR 98 80 40 SYF lor = 89 49 LYF
* = Part of tail bitten off in a territorial dispute over an egg-laying site with another
female.
S-V = snout-vent
Wt = weight
Rep. = reproductive state

IBL = in bloom (g¢ only)

GR = gravid (oviducal eggs)

SYF = small yolked follicles (<5 mm diam.)
LYF = large yolked follicles (+5 mm diam.)

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 119

Oviparous chamaeleons lay far more eggs than saurians of comparative
size or slightly larger (Mayhew 1968), including the closely related agamids.
This prolificity is shared by viviparous chamaeleons. C’. pumilus was found to
have litter sizes as high as 21 young as did Spence (1966) for Microsaura damarana
(= C. pumilus). Of viviparous chamaeleons, the overall average of young per
litter is about 10, according to data from this study, Abel (1931), FitzSimons
(1943), Atsatt (1953), Bustard (1955, 1963) and Von Frisch (1962). Three is
the smallest recorded litter size, agreeing with this study. Angel (1933) records
a maximum litter size of 20 for C. letkipiensis (= hohneli), with an average of
12-13; and Bustard (1965) gives a litter size of 8,o-11,0 (x = 10,0) for C.
hohnelu. C. bitaeniatus has litters of 3,0-25,0 (X = 17,3) young (Bustard
1966).

6. Success of the litters of Chamaeleo pumilus and the clutches of Chamaeleo
namaquensis

Predation on eggs has never been recorded, but ants and burrowing insect
larvae may be a potential threat to Chamaeleo namaquensis eggs. Some females
did dig an extension to their retreat burrows for laying their eggs, and the
continued presence of the adult in such instances might convey a measure of
protection. Fitch (1956) felt the iguanid Crotaphytus collaris to suffer a high nest
mortality with some potential clutches not being represented by any hatchling.
In the field all the potential clutches of Chamaeleo namaquensis (Table 30) and
the litters of C. pumilus (Table 29) were represented. In the case of C. namaquensis
there appears to be evidence of a fourth clutch (Table 30). However, it is
better to consider this (Table 30) the first clutch of newly matured individuals,
since confirmation is lacking of any one marked female having four clutches a
year.

Clutch and litter success are complexly intermeshed with such factors as
weather, gestation, incubation, predation on gravid or pregnant females,
growth of the recently hatched or newborn young, and availability of food for
the young. In oviparous forms rainfall is very crucial to the success of certain
clutches (cf. Burrage 1966, for the iguanid Uta stansburiana hesperis, and Mayhew
1968, for all desert saurians), as unseasonal rains seem to destroy nests or
promote spoilage of the eggs, though, in fact, most desert saurian eggs quickly
shrivel up in dry sand and need direct application of water, maintenance of
100% humidity being insufficient. However, nests of U. s. hesperis exhumed
towards the end of incubation are quite dry, though moistness prevailed at
laying and during early incubation. Thus, on a purely meteorological basis, the
second and third clutches of this iguanid are the most likely to hatch. The
Chamaeleo namaquensis observed inhabits an area of scant and erratic rainfall,
though considerable moisture from fog condensate was closely associated with
the eggs throughout the entire incubation period. It would be interesting to
know the moisture relations of those eggs of C. namaquensis laid outside the fog

belt.

120 ANNALS OF THE SOUTH AFRICAN MUSEUM

7. Role of fat bodies

The work of Harris (1963) on the anatomy of Agama agama was applicable
for use with chamaeleons. Chamaeleo pumilus and C’. namaquensis have a four-lobed
fat body, consisting of two small ventral and two large dorsal lobes, all con-
nected at their posterior ends to the pelvis. Hahn & Tinkle (1965) demonstrated
the role of these fat bodies in the ovarian follicle development of the iguanid
Uta stansburiana. Their significance to the males, which are also subject to
cyclical fat body changes, has not been investigated. Hahn & Tinkle showed
that ovariectomy in Uta eliminated rapid lipid mobilization from the fat
bodies, which occurred in those sham-operated. Fat body excision in early
estrous Uta females induced a high incidence of follicular atresia, and retarded
the yolk deposition rate. In pre-estrous Uta females follicular growth is delayed
or inhibited by fat body excision. The extractable lipid in pre-estrous fat
bodies is nearly equivalent to the lipid content in a typical clutch of eggs.
Hahn & Tinkle concluded that the adaptive value of the fat bodies is associated
with the formation of the first egg clutch, which is the most important.

Tables 41 and 42 for Chamaeleo pumilus males and females, respectively,
and Tables 43 and 44 for C’. namaquensis males and females, respectively, and
Table 48 for juvenile C. pumilus and C. namaquensis show the fluctuation in fat
bodies according to the reproductive state. It will be noted that in the males
fat body size was greatest at those times the testes were active. In C. namaquensis,
females with developing follicles had the largest fat bodies, and those repro-
ductively quiescent or about to oviposit, the smallest. They follow the pattern
of utas. Fat bodies were larger in female C. pumilus with embryos over 10 mm
snout-vent and with yolking follicles, especially those in excess of 5 mm dia-
meter. ‘Thus, the fat bodies of C. pumilus would appear to have a dual role,
lipid mobilization for follicle development, and possibly sustenance of the
embryos in the later stages of pregnancy.

Fat body excision in four male C. pumilus and four male C. namaquensis
resulted in a decline of testicular activity. Controls which had been sham-
operated were unaffected. For four female C. namaquensis the results were as for
female uta. In six female C. pumilus, results on follicular development were as
for C’. namaquensis, and in pregnant ones, only those with very late term foetuses
(i.e., near birth) completed delivery of young. For the others, fat body excision
resulted in the termination of pregnancy, abortion or resorbtion of the embryos.

It appears that fat storage in chamaeleons and utas is primarily for
reproduction, whereas deserticulous gekkonids store sufficient caudal fat in
four days of food ingestion to sustain them for up to nine months (Bustard
1967¢).

8. Nature of gonads (adult non-reproductive)

Gonadal state was determined macroscopically and by microscopic
examination of serial sections of organs. Inactive testes presented a flattish or
squashed appearance externally, and internally the organ was somewhat

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 12]

transparent, as the epithelium of the tubules was thin and they were loosely
convoluted. Sperm ducts not containing semen were thin, whitish to opaque,
and wavy to moderately convoluted. Inactive males had a markedly less
swollen tail base. In June and July Chamaeleo pumilus had inactive testes (Table
41), though in the former month semen was present in the distal part of the
sperm duct. In July and August there was no semen in the distal part of the
sperm duct, though in August 95% of the males had active testes. In
C’. namaquensis inactive testes were predominant (75%) only in August
(Table 43), though all males sampled had semen in the distal part of the
sperm duct.

9. Nature of gonads (adult reproductive)

Reproductively active testes occurred from August to May in Chamaeleo
pumilus, and from February to April, June to August, and in November in
C. namaquensis in the field and from April to November in captivity. ‘These data
suggest virtually reproductively active testes throughout the year in C. nama-
quensis, and it is probably the method of sampling that makes it appear
discontinuous. Active testes were robust and spherical in external appearance.
Internally, they were yellowish with torturously convoluted tubules with thick
epithelium. Active testes weighed more than twice those inactive. In active
males the sperm ducts were white, thickened, and torturously convoluted, and
the tail base was much swollen. In reproductively active C. pumilus (Table 41)
100% testicular activity was recorded in all months but April (30%), May
(50%) and August (95%). The occurrence of testicular activity in April and
May indicates a secondary peak before winter quiescence. Apparently there
were a few (Table 29) active males in June amongst the undissected marked
population, but these might have had semen in the distal parts of the sperm
ducts and inactive testes.

In C. namaquensis males (Tables 40, 43) 100% had reproductively active
testes, except for August (25%), though 100% had semen in the distal parts
of the sperm ducts, except for November when 90% had semen in the distal
parts of their sperm ducts and all had active testes.

Yolked follicles were present in C. pumilus throughout the year (Table 42).
Yolk was deposited in follicles of 2 mm diameter, proceeding to and held at
4 mm diameter if oviducal embryos were present, as in all months, but April,
May and November. Yolking of follicles for the next litter was deferred until
the oviducally developing litter had at least reached pholidosis. Ovulation
occurred at a mean follicle (N = 157) size of 7,0-8,0 x 6,0-6,5 mm.

In C. namaquensis (Tables 37, 39, 44) yolk deposition began with follicles
of 2 mm diameter. In both species non-yolked follicles were from 0,5 to 2,0
mm in diameter, and a pearly white. There were no yolked follicles in the
February (50%) and November (20%) samples of female C. namaquensis.
Yolked follicles from 2,0 to 5,0 mm diameter were found in every sample
month. In C. namaquensis ovulation occurred at a follicle size of 13 mm or

ANNALS OF THE SOUTH AFRICAN MUSEUM

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126 ANNALS OF THE SOUTH AFRICAN MUSEUM

greater in diameter, the eggs being held in the oviducts (see gestation, p. 131)
until laying (Table 36).

When eggs were absent, C’. namaquensis oviducts were silvery-white, thick
and crumpled; the distinct crumpled portions were similar to the incubation
chambers of viviparous forms (see C. pumilus discussion, p. 131) and are called
uterine chambers by Kasturirangan (1951). Oviducal eggs (Table 39) were
found in the April, June and August samples (see also gestation, p. 135). While
oviducal eggs were present, follicle yolking was held at a maximum of 4 mm
diameter. When the oviducal eggs were being shelled or laying imminent,
development of the next clutch proceeded.

In C. namaquensis there was a distinct ovarian follicular and oviducal
development cycle. This was also a right-left offset cycle. That is, at one period
the right side had more oviducal than ovarian eggs, with the reverse situation
being true of the left side. This condition shifted for the next clutches under
development, with the left side having more oviducal and less ovarian eggs.
C. pumilus had an identical right-left offset cycling of developing embryos and
follicle development.

Intra-abdominal migration of ova occurred in C. pumilus and C. namaquensis,
but was not common in either. While this phenomenon in other reptiles is
recorded for xantusiids, iguanids, and teiids (Mayhew 1968), it is based on the
number of oviducal eggs and the occurrence of full-term or regressing corpora
lutea for each side. In the chamaeleons observed this method was somewhat
inaccurate, as these ovarian structures were sometimes discernible for nothing
apparent in either oviduct, and vice versa, which may indicate regression of
Ovarian structures and resorbtion of those in the oviduct to which they were
related at different paces. Hard yolk sacs bearing no trace of embryos were the
only oviducal structures that could not be matched to any corresponding
ovarian structure.

Saurian testicular cycles resemble those of birds, and the most common
saurian testicular cycle is: (1) with spermatogenesis in late summer and autumn,
occurring also during winter hibernation, with spermiogenesis taking place
largely in spring, but it may occur in autumn or winter. Mature sperm enter
the epididymides, and copulation usually occurs in spring; or, (2) some maintain
testes and sexual accessories at maximum through the summer; or, (3) those
at the extremes of their (northern) range are biennial in both sexes. Very little
is known of tropical forms, and most of the knowledge is based on temperate
species, especially the northern varieties.

Food, weather and moisture are some mediating effects of the cycle.
Photoperiod effects are hard to gauge, since reptiles expose or shield themselves
to and from light in controlling their body temperatures. Licht, Hoyer & Van
Oordt (1969) found male Lacerta sicula and L. muralis to be stimulated by warmth.
Licht & Basu (1967) found that Uma scoparia testes in vitro can produce repro-
ductive products at 37 C, and do not degenerate until held at 44 C. Body
temperatures of 44 C are reached by this species in summer when they are

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 127

maximally active reproductively and otherwise. Thus, male Uma can produce
reproductive products at temperatures far higher than can other vertebrates,
including desert birds (Riley 1937), which are capable of spermatogenesis only
in the cool of night. Mayhew (1967) has shown that apparently the amount of
soil moisture during winter determines the breeding of Uma. Where this places
C’. namaquensis in this regard is not known, for certainly it was subject to as
extreme environmental temperatures as Uma, but maintained lower body
temperatures. Perhaps of importance here are the lung diverticula (Fig. 12)
which surround the gonads in both sexes.

A problem of deciding on reproductive cycles, if any, in chamaeleons
(and perhaps other saurians) is the ability of the females of some species to
store sperm. The loci of sperm storage is variable, being the anterior segment
of the ‘vagina’ in the iguanids Callisaurus, Crotaphytus, Holbrookia, Phrynosoma,
Sceloporus, Urosaurus and Uta, the tube between the oviduct and infundibulum
in the gekkonids Coleonyx and Phyllodactylus (Cuellar 1965), and the distal part
of the oviduct in Chamaeleo basiliscus, C. chamaeleon and C. lateralis (Saint Girons
1962), and in C’. pumilus and C. namaquensis (this study). Such structures contain
large numbers of spermatozoa in females isolated from males for several
months, permitting production of one or more fertile clutches or litters. As
Cuellar observes, sperm storage permits an effective lengthening of the period
of fertile egg-laying.

Little value for sperm storage in C’. namaquensis can be seen, since the
males were reproductively active throughout the year, the sex ratio was almost
equal, and both sexes were readily available spatially and temporally to each
other. In C. pumilus sperm storage has a decided value, especially for the first
litter in September of the reproductive year. Cape winters feature considerable
rain and quite low temperatures from June to at least October, though such
inclement weather may begin as early as the end of April and persist into
mid-December. Males were totally inactive in July and August, thus sperm
storage in C’. pumilus females guarantees the first litter and possibly the last,
independent of the availability of sexually active males at those times.

Data on viviparous chamaeleons show that Chamaeleo pumilus is generally
credited with rarely more than one birth per year, corresponding to the
Southern Hemisphere summer (FitzSimons 1943; Von Frisch 1962; Bustard
1963; Spence 1966), but only Wager (1958) agrees with this study that litters
are multiple, being recorded in February to May, September, November and
December. Bustard (1966) records C. bitaeniatus births in April, May, July and
September to November, and C. hohnelii births in August and September
(Bustard 1965). Busack & Busack (1967) record November and February
births for C’. pumilus, and Atsatt (1953) February to May, July and November.
However, almost all of these records are based on captives, and Atsatt’s records
of November, April and May ‘births’ are due to injection with pituitrin of a
single female C. pumilus. This study’s records are of individuals in the field,
supplemented with data on captives.

128 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 12A-C.
The lung, air sac relationship to gonads in Chamaeleo namaquensis (A—B) and C. pumilus (C).

A. Lung (part between ‘8’ and ‘11’ on mm rule) at expiration shown to the top of black small
intestine, and anterior to right ovary. Note large yolking follicles in both ovaries; large white
stomach to right of left ovary, and juncture with small intestine and its black visceral peritoneum.

B. Lung (centre left above black small intestine) at almost full inspiration, totally obscuring
ovary, which is forced dorsally and medially. (The fat bodies, very large in this female, have
been partially excised to improve visibility of other structures.) Especially note transparent
(clearer in Fig. 12A) abdominal peritoneum of this species. (Anterior is to left in this photo.)

C. Male C. pumilus (anterior to right) with lung at almost full inspiration, almost obscuring right

testis, which is abnormally lacking a black visceral peritoneum and appears white. Its opposite

number, just posterior to (normal position of gonads), and below it in photo, has usual black

visceral peritoneum. Note everted hemipenes, fat bodies just anterior to pelvis, and black visceral

and abdominal peritoneum. Air sacs (a partly-filled air sac is marked by black arrow in Fig. 12B)
are attached to posterior part of lungs only in C. namaquensis. Scale in mm.

129

Fig. 12A

42
UULUAUAALAE

ii

130 ANNALS OF THE SOUTH AFRICAN MUSEUM

Discussion and review of the complex reptilian reproductive cycles are
given by Parkes (1956), Miller (1959), Forbes (1961) and Mayhew (1968),
almost all of which deal with north temperate reptiles and virtually no complete
information is given on chamaeleons. Bons & Bons (1960) found the Mediter-
ranean Chamaeleo chamaeleon mates in August or September and lays eggs in
October and November, which is the tropic cycle with egg-laying during or at
the end of the rainy season, and not of the Mediterranean, with egg-laying at
the end of spring. Bourgat (19685) found C. pardalis of Réunion does not have
spermatogenesis during July and August (winter). The East African C. dilepis
lays its eggs in March (Wager 1958), September, just after the rainy season
(Milner 1949), late summer (FitzSimons 1943), February (Cott 1934) and
February to April (Brain 1961). Of West African chamaeleons, C. gracilis lays
its eggs in September at the end of the rainy season (Menzies 1958), while C.
basiliscus lays its eggs in December in captivity (Shaw 1960). C. chamaeleon
zeylanicus of India lays its eggs in November (Trench 1912).

Ovarian cycles of reptiles are of several types, which are not yet possible
to correlate to taxonomic, geographic, or climatic differences: (1) much yolk
is deposited shortly prior to ovulation, but subsequent to a long slow initial
growth of the ova; (2) yolk deposition occurs gradually through most of the
year preceding ovulation; (3) yolk deposition occurs shortly after ovulation
and mature ova occur in the ovary through the winter; (4) two sets of ova are
produced and ovulated per year, each set being formed directly after ovulation
of its predecessor; (5) non-seasonal breeders, producing at any time of the year.
The mediating effects of the male cycle have been alluded to and presumably also
act on the female cycle. For example, Tinkle & Irwin (1965) found Uta females
to be stimulated by warmth, as did Marion (1970) for female Sceloporus undulatus.

10. Gestation

The corpora lutea of Chamaeleo pumilus appear as yellowish-white, imperfect
doughnut-shaped structures as large as 4 X 2 mm in females that have recently
ovulated, maintaining a diameter of 2 mm throughout pregnancy. Corpora
lutea of the previous litter were distinct at 1,8 mm diameter, but whitish, for
some time during the term of the next successive litter. Gestation in C. pumilus
was as short as 60 days in the case of litters conceived in March and born in
May, when subjected to the hottest environmental temperatures, but at other
times gestation was as long as approximately 90 days. The overall (N = 56),
average gestation period was 72 days. Those conceived in April and May and
born in September did not begin oviducal development until mid-June, or the
latter part of July. Three months is the approximate gestatory period for all
reported viviparous chamaeleons, C. pumilus (Atsatt 1953; Wager 1958; Von
Frisch 1962; Bustard 1963; Spence 1966; Busack & Busack 1967), C. bitaeniatus
(Bustard 1966) and C. hohnelii (Bustard 1965). This study cannot agree with

Rose’s (1950) casual observation that gestation in C. pumilus is, ‘.. . well overa
year’.

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) I31

Pregnant C’. pumilus nearly always maintained a Colour Index of ‘5’, and,
as such, were most conspicuous in their habitat and by their habits, being
abroad in inclement weather, long after the males and non-pregnant females
had sought shelter in the depths of the bushes. This greater activity of pregnant
females made them seem the predominant sex. Bourgat (1968a) notes that
gravid C. pardalis are the most active individuals. Continually basking pregnant
females improve development of their winter-borne young. The dermal
melanin deposit, the black abdominal, and uterine visceral peritoneum protect
the young from the intense insolation they were subjected to. Pregnant females
in warm months basked far less frequently, sought shade, and were lighter.
Young were quite harmed by excessive heat. In laboratory tests 5 pregnant
females that were subjected to temperatures above 35 C gave birth, usually
prematurely, to 56 young, of which 20% had malformations of the eyes and/or
head, 1% were club-tailed, and 10% were still-born.

Developing oviducal eggs (Chamaeleo namaquensis) and embryos (C. pumilus)
are arranged longitudinally in the oviducts on either side of the mid-line. As
they develop, the eggs (C. namaquensis) and embryos (C. pumilus) take up more
and more space until they almost fill the posterior part of the coelom, but
unlike many other lizards the viscera are not crowded anterior of their normal
position, rather they are forced ventrally. The developing oviducal eggs
(C. namaquensis) and embryos (C. pumilus) are offset, so that the egg or embryo
in the contralateral oviduct more or less fits between two eggs or embryos in
the ipsilateral oviduct, with the viscera forced ventrally. Such an arrangement
allows both species to continue their voracious feeding in maintenance of their
high metabolic rates. C. pumilus fed until a few days prior to birth; C. namaquensis
never stopped.

In C’. namaquensis the corpora lutea are about 2 mm in diameter and held
at that for the entire gestatory period of 35-45 days. They regress rapidly after
oviposition, though some were recognizable at the time of ovulation of the next
successive clutch. In those five C. pumilus that had corpora lutea excised, there
was no effect on litter development of foetuses that had passed pholidosis. But
in those with less mature embryos, these young were resorbed. In the four
gravid C. namaquensis excision of corpora lutea did not affect those eggs near
Oviposition, but resorbtion resulted of eggs recently ovulated. C. namaquensis
eggs are ovulated at sizes of 13 mm or greater in diameter, and are very large
at oviposition showing a clearly marked embryonic development. Compared
to the eggs of other oviparous chamaeleons so far examined, the highly advanced
states of development of recently oviposited eggs of C. namaquensis may indicate
that this species is developing ovoviviparity.

The oviducts of Chamaeleo pumilus have distinct incubatory chambers
(Figs 13, 14), each of which is supplied from a single large artery and drained
by a prominent vein running dorsally along the surface of the oviduct in mid-
line. These chambers are similar to those described by Weekes (1935) and
Kasturirangan (1951). C. pumilus oviducts maintain their shape even between

132 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 13.

A. Excised oviduct of Chamaeleo pumilus showing 10 full-term foetuses near birth, their yolk supplies

exhausted, and one egg being resorbed, which has been excised from the oviduct and is in centre

of photo. In excised ovaries (just to left of egg being resorbed) note 10 corpora lutea for full-term

foetuses in upper ovary, which matches this oviduct. The egg being resorbed has long since lost
its corporus luteum.

B. Incubatory chambers of an excised C. pumilus oviduct (anterior at top of photo). Incubatory

chamber at top has had an egg (embryo and yolk sac at top) removed to show vascular supply

of chamber. Egg at bottom of photo has had egg membrane peeled off, which is shown imme-

diately to the right to show foetal vascular supply. Note, at extreme right of photo, egg not ina
defined incubatory chamber, undergoing resorbtion. Scale in mm.

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 133

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ANNALS OF THE SOUTH AFRICAN MUSEUM

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ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 135

pregnancies and the chambers are distinct, crumpled areas. The placentae of
C. pumilus are best assigned to Weekes’ Type ‘I’, since the yolk content of the
eggs is not markedly reduced at ovulation. Recently ovulated eggs (7,0-8,0 x
6,0-6,5 mm) often have a developing embryonic area of 2-4 mm diameter.
In C. pumilus the yolk sac placentae eventually gives way to an allanto-placentae,
and most young about two weeks from birth have empty yolk sacs. Good
reviews of viviparous adaptations in other reptiles and the maternal-foetal
relationship are those of Boyd (1942), Cate-Hoedemaker (1933), Flynn (1923),
Hoffman (1970), Wislocki (1920) and Mossman (1937). Reptiles show all
gradations from the simplest maternal-foetal relationship to conditions little
removed from that in eutherian mammals.

The occurrence of two closely spaced births, or two markedly different
foetal age groups within the same oviducts of C. hohneli (Parker 1940), C. pumilus
(Atsatt 1953; Busack & Busack 1967) and C. bztaeniatus (Bustard 1966) has been
attributed to secondary fertilization via sperm storage, or superfoetation, that
is, two pregnancies from one mating. In these observations two closely-spaced
births occurred in the September litters. Bustard (1966) thinks none of the
suggested interpretations is wholly valid, as some of Parker’s material is explained
as atretic eggs which are being resorbed. Parker thought that such occurrences
indicated all is not well. Ectopic embryos were observed in C. pumilus, one of
which was a ‘lithopedion’, well-advanced and with partial adult type coloration.
It was affixed to the fat body.

Since pregnant female chamaeleons resist mating, any subsequent fertili-
sation would be most likely from sperm storage. C. pumilus eggs being resorbed
were all ones that were not in incubation chambers, nor were full-term corpora
lutea present for them, only atretic corpora lutea at best. This indicates that
on some occasions, viviparous chamaeleons ovulate more eggs than there are
gestation sites for. Such eggs would face resorbtion, and the data showed this
to be so. In September, C. pumilus had two litters of very small size (no more
than 8 young in each) that were probably conceived via sperm storage by
direct mating in April and May. They were probably small, because they
developed over winter in the female, on whom they must have been a consider-
able drain during this inclement season. Both were ovulated in mid-June or the
latter part of July, apart from each other, the second litter being potential and
held in the ovary at a follicular size of greater than 5 mm diameter. However,
triggered by oviducal site availability, the female’s physiological state, and/or
other conditions favouring the development of a larger first of the year litter
size, a second smal! September litter proceeded (ovulated) to oviducal develop-
ment. The relationship of the difference of follicle sizes and developing embryos
is shown in Tables 37 and 42. The September litters had the least variation in
complement of any litter. The time of parturition between these two differently
conceived litters was no more than two days in marked females in the field.
Some captives did stretch parturition over a week, perhaps reflecting nutrition
problems of captivity. The second September litter is best considered as

136 ANNALS OF THE SOUTH AFRICAN MUSEUM

superfoetation, conceived at and beginning oviducal development at a closely
spaced but later time from the first September litter. Both September litters
were essentially born at the same time and have been treated as single litters
(Table 38). The single small litters born in May were conceived by direct
mating in February and March and represented a means of achieving a litter
at the warmest time of the year. This allowed for recovery of the reserves of
the female before development of the September litter.

Chamaeleo namaquensis eggs grew from the ovulatory size of 13 mm or
greater in diameter to a mean of 20,5 * 11,6 mm; 1,5 g (max 26,0 X 14,5 mm;
2,8 g) in 25-30 days (warm season), 35-45 days (cool season) at the time they
were oviposited. A small, reddish embryonic area 2 mm diameter was visible
in a few recently ovulated eggs, and at the time of oviposition this area was as
great as 10 mm. The oviducts of C’. namaquensis contained distinct ‘gestatory’
chambers, each of which housed an egg. The vascular supply to such chambers
was, however, less distinct than that of the incubatory chambers of the vivi-
parous forms.

Brain (1961) gives a 120-day gestation period for C. dilepis. The gestation
period of C. namaquensis is closest to C’. chamaeleon zeylanicus (Trench 1912) and
C’. chamaeleon (Bons & Bons 1960) of reported oviparous chamaeleons, and to
some iguanids (Burrage 1966).

11. Incubation

The overall incubation increment of C. namaquensis eggs was: length:
14-40% (KX = 19,8%); width: 4-16% (x = 9,8%); weights 18-0593 —
37%). In just two days of incubation, length increased by 4-19% (% = 8,2%);
width 4-9% (X = 6,0%); weight 12-40% (X = 27,3%). Increments after 60
incubatory days were slight and essentially as for the entire period. During the
later stages of incubation, the large, black developing C. namaquensis embryo
was clearly discerned through the shell. Increments for the first two and 60
incubation days were less in those clutches laid in May through July, which
had the longest incubation period (May, 112; June, 100; July, 97 days). Eggs
laid in early August took g1 days, as did those laid in October and September,
and those of late August took g2 days. The overall (N = 250) incubation time
was 98,4 days.

The following data are available in the literature on incubation times of
chamaeleon eggs: Chamaeleo dilepis : go days (FitzSimons 1943), 219-365 days
(Milner 1949; Wager 1958; Brain 1961); C. gracilis: 210 days (Menzies 1958);
C. basiliscus: 179 days (Shaw 1960); C. chamaeleon: 280 days (Haas 1947), and
250-260 days (Bons & Bons 1960). It was accounted by people at Cape Cross
South West Africa, that C. namaquensis eggs laid there took twelve months to
hatch. However, this is thought to have been multiple usage by several females
of the same nest site, with different hatching times of the several clutches laid
at various dates. Or, conversely, different clutches laid at different dates by
one, perhaps two females. On the average, chamaeleon eggs take longer to

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 137

hatch than those of other saurians, but about the same time as the Australian
deserticulous agamid Moloch horridus (56 days, White 1948; go-132 days,
Sporn 1965). Many of these chamaeleon incubation times are based on captive
records, under different conditions, clutches at different times of the year, and
for clutches laid by females of widely separated geographic populations.

The effect of temperature on incubating saurian eggs has been discussed
in several papers, with the expected observation that longer incubation obtains
at cooler times of the year. Cooper (1965) experimentally incubated clutches
of lacertid eggs at different temperatures, finding maximum incubation time
(122-160 days) accrued when the eggs were subject to temperature variation
(18,5-21,0 C by day; 12,5 C by night), and least (46 days) when the eggs were
incubated at a uniform 27 C. Great disparity has been recorded in the incuba-
tion time of the eggs in natural nests of the American scincid Eumeces fasciatus,
Fitch (1954) giving 27-47 days, and Cagle (1940) nine days. Undoubtedly, as
Fitch (1954) asserts, temperature is important, but it may not be the only
factor. Burrage (1966) discusses the influence of different thermal gradients of
various substrates on incubation times of the eggs of Uta, noting that site
selection at oviposition is also important, since some substrates are more
favourable throughout the year. Bons & Bons (1960) have shown that chamaeleon
eggs do not hatch quicker when maintained at higher temperatures (27-28 C),
but gross cephalic deformities result. Table 45 shows the temperatures of dune
sand and gravel for inland and coastal sites at the 200-250 mm depth where
Chamaeleo namaquensis laid its eggs. There was some difference in sand and gravel
temperatures, but markedly higher inland substrate temperatures occurred
especially in June and July, when fog was the rule at coastal sites. The greater
prevalence of fog and the moderating effect of the Benguela Current depressed
coastal air and surface substrate temperatures. The surface substrate maximum
temperature, occurring at approximately 14:00 hours, was only reflected the
following day at a depth of 200-250 mm. No oviducal eggs were found Novem-
ber to March (Tables 39, 44), which might be because the temperature at the

Table 45

Twenty-four hour substrate temperature (in °C) records at 200-250 mm
depth for dune sand and gravel at coastal and inland locations.
Means are in parentheses.

Coastal Inland
Month Dune sand Gravel Dune sand Gravel
1969
April 23,5-28,5 23,0-28,0 27,;0-3535 25;0—31,0
(26,5) (25,5) (31,5) (28,5)
June 15,0—-20,0 14,0—21,0 21,0-30,0 20,0-33,5
(17,5) (17,3) (26,0) (24,5)
November 22,0-31,0 21,0—33,0 26,0—33,0 27,5-34,0
(25,5) (25,0) (29,5) (31,0)
1970
February 27,0-35,0 25,0-33,0 32,0-39,0 31,0-39,0
(30.3) (28,6) (35,5) (34,0)

138 ANNALS OF THE SOUTH AFRICAN MUSEUM

laying depth was too high from February to April. At this time all the young
had hatched and in the May clutch development proceeded only in late April
as cooler temperatures returned at the laying depth. Regardless, C. namaquensis
eggs incubated at temperatures above the 27-28 C ‘harm’ limit of Bons & Bons
(1960), indicative of adjustment to their environment.

12. Young

Birth size data for Chamaeleo pumilus are given in Tables 38 and 47. The
young for most litters averaged a snout-vent length of about 22 mm—the tail
usually equal to or slightly less than this, and rarely in excess, regardless of
sex—and a weight of 0,3—0,4 g. The smallest young (snout-vent x = 20 mm)
were those born in September, perhaps reflecting the effects of superfoetation,
and the largest young (max snout-vent 27 mm; X = 25 mm) were born in
November. Males were slightly smaller than females. Table 46 gives the sex
and pattern types of newborn C’.. pumilus. Recently born viviparous chamaeleons
resemble the adults, except in colour and pattern, though some (Table 46),
mostly males, had a true adult pattern. Brown individuals at birth were
mostly females, and did not acquire the adult colour at maturity. The disparity
in pattern between the young and adult of viviparous chamaeleons is noted for
C. pumilus by Abel (1931), Von Frisch (1962) and Bustard (1963); C. bitaeniatus
(Bustard 1966); and C. hohnelu (Angel 1933; Bustard 1965). The sex ratio at
birth in C. pumilus was nearly equal. Von Frisch (1962) thinks that the newly
born young of C. pumilus have to ‘learn’ to aim their tongues, but Bustard (1966)
does not agree, with which this study concurs. However, it was observed that
slightly premature young aimed poorly at first, but improvement of their aim
is probably due to maturation of their senses, rather than ‘learning’.

Table 46

Sex and pattern types at birth of 614 Chamaeleo pumilus expressed as percentages. The number

not enclosed in parentheses shows the percentage of a given sex having a particular pattern

type, while the number enclosed in parentheses shows the percentage of that sex of that particular
pattern type in the total sample.

Pattern types

Sexes Adult Gray-green Gray Brown
Male Female Male Female Male Female Male Female Male Female
38-64 36-62 50,0 16,5 25,0 26,4 15,0 221 10,0 34,0
xX = 51 xX = 49 (20,0) (10,0) (10,0) (16,0) (6,0) (14,0) (4,0) (20,0)

Data on Chamaeleo namaquensis oviposition and hatching dates and the time
to reach maturity are given in Table 49. Recently hatched male C. namaquensis
varied in total length from 45,0-55,0 mm (20,0-25,0-+25,0-30,0 mm) ; means:
total length: 50,0 mm; snout-vent: 22,5 mm; tail: 27,5 mm; and all weighed
about 0,6 g. Females were larger, varying in total length from 55,0-65,0 mm
(30,0-35,0+25,0-30,0 mm); means: total length: 60,0 mm; snout-vent:
32,5 mm; tail: 27,5 mm; and weighed 1,0-1,7 g (% = 1,5 g). The young were

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 139

mere miniatures of the adults as to pattern and colour, but possessed more
vertebral knobs (see also FitzSimons 1943). C. dilepis (Brain 1961) and C.
basiliscus (Shaw 1960) hatchlings are also miniatures of their adults. C. nama-
quensis young hatched out late in the evening and during the night, and rapidly
dispersed. Unlike the adults, they preferred to climb and could be found on
grass stems and other vegetation, or perched on rocks. (A February hatchling,
photographed in early March, is shown in Figure 11.)

13. Growth and longevity

The growth of young Chamaeleo pumilus is shown in Table 47. As time
passed, the size differences narrowed between the various litters. Data on
juvenile C. pumilus fat body weights, gonadal sizes and weights are given in
Table 48. In C. pumilus and C. namaquensis juvenile testes were flattish with
thin, whitish epithelium, and loosely convoluted tubules; the sperm ducts were
flat and thin, whitish opaque, straight to wavy. In females the oviducts were
collapsed and thin, black in C. pumilus, and silvery in C. namaquensis. The
ovaries were longer than they were wide and somewhat transparent, bearing
follicles no larger than 1,5 mm diameter. Upon hatching and at birth, follicle
size was not more than 0,25 mm, and the entire ovaries were about 2,0 X 1,0 mm.
The testes were about 1,0 X0,75 mm and translucent.

Table 47

Mean growth rates to maturity of 148
Chamaeleo pumilus in the field. Both sexes
mature at a snout-vent length of 50 mm.
Roman numerals represent months.

Mean
snout-vent Mature
Birth (mm) at date

date birth (days)
Il 22,0 210
Ill 22,0 240
IV 22,0 240
Vv 22,0 240
IX 20,0 169
XI 25,0 85
XII 22,0 108

Busack & Busack (1967) give data on the growth of a November brood
of 12 Microsaura pumila (= C. pumilus) over 300 days, some of which present
different growth curves. One of Busack & Busack’s young chamaeleons reached
60 mm (snout-vent) in 175 days, another measured 37 mm (s-v), and one
43 mm (s—v) in 135 days. One chamaeleon reached 60 mm (s-v) in 262 days,
and another did not grow in 143 days from 20 mm (s-y) at birth. Half of
Busack & Busack’s sample did not live over 50 days. Bustard (1965) records a
male Chamaeleo hohneli that increased in 18 days from a total length of 95 to
110 mm, acquiring sexual maturity, though he is not sure of its exact age.

ANNALS OF THE SOUTH AFRICAN MUSEUM

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ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) I4!I

C. pumilus and C. namaquensis in the field grew faster and less erratically than
those in captivity. A captive C. pumilus grew faster than those viviparous
chamaeleons reported in the literature, but some registered the same sort of
erratic growth and there were runts, who grew little or not at all. Also, most
literature references do not record the sex of the young.

Table 49 shows growth rates for C. namaquensis young from hatching to
maturity. Females reached maturity in 150 days at a snout-vent length of
75-80 mm. Males reached maturity in 210 days at a snout-vent length of
70-75 mm. Table 48 shows fat body weights, gonadal sizes and weights of
juvenile C. pumilus and C’. namaquensis. Growth was steadier and faster in female
C’. namaquensis; while the overall male growth rate was slower it was faster over
the first and last 30 day periods (3 mm per diem). Juvenile C. namaquensis
preferred climbing and were far more adept at this than adults. Their thermo-
regulatory pattern was adult in every respect. As they neared maturity, their
increased stockiness and larger size made for injurious falls, when they tried
climbing the same structures that easily supported them at a smaller size.

Table 49

Mean growth rates to maturity of 107-++ Chamaeleo namaquensis, mostly in
the field. Males matured in 210 days at a snout-vent length of 70-75 mm;
females matured in 150 days at a snout-vent length of 75-80 mm.

Incubation Number of days
period for young
Month eggs laid (in days) Sex to reach maturity
May-July Q7-112 feXe4 210
go 150
August gI feet 210
oe 150
August-September Qi— 92 feXe) 210
99 150
October QI 3d 210
Oe 150

Considerable differences have been reported for the growth of oviparous
chamaeleons. Brain (1961) feels that C. dilepis takes a long time to acquire
maturity, citing a two-year-old that was still juvenile and sexually immature.
However, Wager (1958) notes a C. dilepis, 45 mm long at hatching, had reached
152 mm seven months later. After seven months the growth of this individual
slowed, and at 13 months its total length was 216 mm, having gained only
63 mm in the final six months of observation. Wager thinks C. dilepis matures
in a year. The growth rate of chamaeleons does not seem unusually slow or
fast in comparison with that of other saurians recorded in the literature
(Mayhew 1968) and the influence of hatching times of different clutches of
different species and populations undoubtedly varies, as the geographic and
climatic conditions obtaining in the respective areas each inhabits. Menzies
(1958) reports that C. gracilis hatch at the onset of the rainy season, which

142 ANNALS OF THE SOUTH AFRICAN MUSEUM

might be inclement enough to retard growth. C. namaquensis was little affected
by rainy seasons, and all young hatched out after the fogs of June and July.
Furthermore, food in the Namib Desert was always abundant and young and
old chamaeleons gorged to the limit; a condition not often enjoyed by captives,
whose feeding by their captors is an exhausting task (see also Abel 1931 and
Bustard 1963). As Bustard (1963) observes, captive chamaeleons are at a
liability, the limits of captivity showing the mere minimum they are capable of.

There is no good knowledge of the life-span of chamaeleons, though
Brain (1961) feels that C. dilepis reaches 10-20 years, and hearsay puts C.
pumilus at a maximum of six years. Three years of study on marked C. pumilus,
showed amazing longevity of individuals in the field, some 40% of the adults,
plus some progeny recorded and marked in February, 1969, being recovered
in February, 1971. C’. namaquensis was not observed over a long enough period —
though recovery was quite high—but, as with C. pumilus, and as Bourgat (1968)
observed for C. pardalis, there was tremendous fluctuation according to the
season. At the end of a year he recovered 60 of 140 he had marked.

IV. SuMMARY.

Various aspects of the life histories of the chamaeleonids Chamaeleo pumilus
(Gmelin) and C. namaquensis A. Smith were investigated in the field and
laboratory from 13 January 1969 to 30 November 1970 in the Republic of
South Africa and South West Africa. A total of 494 C. pumilus and 207 C.
namaquensis were marked for field studies by branding or leg bands. C. pumilus
inhabit any vegetation guaranteeing a plentiful source of prey. They were
studied at Port Nolloth, Leeu-Gamka, Beaufort West, Van der Stel station,
The Strand and chiefly at Stellenbosch. While primarily of arboreal habits,
C’. pumilus frequently walks along the ground, such ground-dwelling habits
being especially true of those inhabiting arid and semi-arid areas. C’. namaquensis
is ubiquitous in desert and near desert areas. Adults are exclusively ground-
dwelling, even invading the desert littoral intertidal zones. C. namaquensis was
observed in South West Africa at Gobabeb, Tsondab, Geluk Farm, Solitaire,
Rehoboth, and on the coast from Walvis Bay north to Cape Cross.

The only recorded instance of ectoparasites were Culex mosquitoes feeding
on C. namaquensis at Gobabeb. There was some seasonal and sexual variation
in the incidence and degree of endoparasitism in C. pumilus, the females
harbouring more parasites than the males. The nematode Strongyluris was the
principal intestinal helminth of C. pumilus. The cestode Oochoristica africana was
the principal intestinal helminth of C. namaquensis. Cysts and larval worms
occurred in both chamaeleons. Snakes and birds were the principal predators
on C. pumilus. Raptorial birds were the chief predators on C. namaquensis.
Physical factors and human activities also affect chamaeleons.

The body temperatures of 549 C. pumilus active in the field ranged from
3,5 G to 37,0 C (mean 22,4 C; median 22,8 C). The body temperatures of

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 143

351 C. namaquensis active in the field ranged from 14,0 C to 39,7 CG (mean
28,7 CG; median 28,8 C). In laboratory preferred body temperature gradients,
20 C’. pumilus were active from 7,0 C to 30,0 C (mean 25,0 C) and 18 C. nama-
quensis were active from 18,5 C to 36,2 C (mean 29,3 C). While body tempera-
tures of C. pumilus varied according to the weather and season, those of C.
namaquensis were much more stable, though the body temperatures of inland
and coastal populations differed slightly. Field records of nocturnal body
temperatures of both species at rest were close to the environmental temperature,
while those in captivity were slightly higher.

Chamaeleons regulate their body temperatures by a complexly integrated
physiological process, involving dermal colour lability with attendant vasomotor
and other cardiovascular adjustments, body posturing, thermo-pneumatic
changes in the volumes of the lungs and air sacs, and panting. The role of
dermal colour lability was examined in laboratory experiments using 30
Chamaeleo pumilus and 28 C. namaquensis. Dark-adapted chamaeleons are
warming, light-adapted individuals are cooling. By changing the body contour
by compression and posturing, chamaeleons regulate the heat and light load
striking their bodies. At any given temperature, the heart rates of 5 each of
C. pumilus and C. namaquensis were higher during heating than cooling. Live
chamaeleons heated faster than they cooled, whereas dead ones heated and
cooled at the same rate.

The peak oxygen consumption in 15 C. pumilus was at 25 C, while the
greatest active Q,, (1,29) value was over the 5-15 C range. The peak oxygen
consumption of 15 C. namaquensis was at 35 C, while the greatest active Q 4
(2,91) value was over the 25-35 C range.

C. pumilus and C. namaquensis were active throughout the season under all
weather conditions, and were active from about sunrise to sunset, except
Ovipositing C. namaquensis were active throughout the night. Many newly
hatched C. namaquensis came out during the night.

Partially blinded chamaeleons either naturally or experimentally developed
an accuracy of 57,0-63,0% (X = 60,0%) in catching prey, whereas the
accuracy of normal C. pumilus was 75,0-92,0% (X = 86,0%) and that of C.
namaquensis was 80,0—90,0% (X = 85,0%).

In C’. pumilus the tongue can pull a weight equal to two-thirds or one-half
of the body weight and be maximally projected to a length about two-thirds of
the total length of the animal. In C. namaquensis the tongue can pull a weight
equal to the body weight of the individual chamaeleon and be maximally
projected to a length equivalent to that of the snout-vent of the animal. The
prey is held by a mechanical overlapping of the bi-lobed tongue knob at the
tip of the tongue.

By selecting prey of certain sizes, both chamaeleons could realize a greater
intake of food than by eating very large prey items. C. pumilus realized maximal
ingested volumes by selecting muscid flies, its principal prey, and small tene-
brionid beetles. C. namaquensis realized its greatest daily volumes of food when

144 ANNALS OF THE SOUTH AFRICAN MUSEUM

meals were composed of small locustids and large tenebrionids. C’. namaquensis
took about 19 or 23 large tenebrionids per meal, with a minimum of 5 to a
maximum of 15 (xX = 12) daily meals. C. pumilus and C. namaquensis were
voracious feeders and rapidly food. Two to five hours were required to digest
and eliminate meals taken in during the day and up to 12 hours for meals
taken before retirement and digested overnight.

In Chamaeleo pumilus ($964; 9986) there were seasonal and apparently
sexual variations in diet. Dipterans were the main prey item, but the families
selected varied with the sex of the chamaeleons. At some times of the year the
prey eaten by the females, for example, was either not the same as that eaten
by the males, or the proportions taken varied tremendously. Inland (N = 64)
and coastal (N = 157) C. namaquensis preyed mostly on large tenebrionids.
Plant and inorganic matter were also ingested. Mammal hair and bird feathers
occurred in inland samples, and reptiles were taken by coastal C’. namaquensis.
Strand-dwelling C’. namaquensis fed on flies, intertidal arthropods, tenebrionids,
and reptiles.

Water is of crucial importance to chamaeleons, and they cannot survive
on food alone. Desiccation experiments were run on 18 each of C. pumilus and
C’. namaquensis. In one test they were given food but no water for 12 days and
then food and water for 3 additional days. In a second test they were without
food and water for 7 days. In both experimental sets, the haematocrit values
of dehydrated C. pumilus were 28,6-33,7 (X = 31,3) and plasma osmolality
values 395,0-440,0 mOsm (X = 421,3), and the haematocrit values of de-
hydrated C. namaquensis were 14,6-19,8 (X = 17,6) and the plasma osmolality
values 230,0-255,0 mOsm (X = 246,3). In rehydrated C. pumilus the haemato-
crit values were 14,5-29,0 (X = 21,4) and the plasma osmolality values
200,0-210,0 mOsm (X = 203,8), and the haematocrit values of rehydrated C.
namaquensis Were 15,5-32,5 (X = 24,6) and the plasma osmolality values
219,0-292,0 mOsm (xX = 261,3). These data suggest water storage in the
vascular space of both chamaeleons. Seven freshly caught C. pumilus had
haematocrit values of 29,0-30,5 (X = 29,9) and plasma osmolality values of
200,0-210,0 mOsm (X = 203,8). Eight freshly caught C. namaquensis had
haematocrit values of 42,0-50,0 (X = 46,6) and plasma osmolality values of
220,0-290,0 mOsm (XK = 250,8).

C. namaquensis has a salt gland and samples of the exudate of this showed
excretion of sodium, chloride, and potassium in the ratio of 6,4: 7,0: 1,0;
respectively. While this gland undoubtedly is of value in strand-dwelling
chamaeleons to excrete any salt ingested with the intertidal prey on which they
feed, its chief function is probably to enable C. namaquensis to produce a urine
of low water content by re-excreting electrolytes which have been reabsorbed
in the cloaca. This would greatly benefit the water economy of those C. nama-
quensis inhabiting regions outside the fog belt.

Chamaeleo pumilus adults were most dense in December (195 individuals,
2 437,5 g per hectare), with significant secondary peaks in January (118

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 145

individuals, 1 105,0 g per hectare), and October (120 individuals, 1 116,0 g
per hectare). Juveniles were most dense in February and March as components
of the overall population. Of all C. pumilus marked in February 1969, 40%
were recovered two years later. Biomass and density of adult C. namaquensis
were relatively consistent, increases in the biomass reflecting the heavier
weights of gravid females. C’. namaquensis also had a high recovery rate.

C. pumilus and C’. namaquensis display in a series of side-to-side head bobs.
C. pumilus and C. namaquensis resort to fighting if the transgressing chamaeleon
does not leave the defender’s presence.

Both sexes of C. pumilus have an undefended, shifting, vertical home range
averaging 10 m? in plan view. However, since these chamaeleons use their
home ranges as if they were layered, the actual area is about 600 m?. If the
food sources failed, the home range locus was shifted. Only a favoured perch
was defended by both sexes of this species.

C’. namaquensis occupied very rigidly delimited territories. Female territories
and territories limited to one biotope or habitat were the smallest. Male
territories increased in area during courting and those of females enlarged
during egg-laying. Juveniles occupied a small, shifting home range within the
rigidly defended territories of the adults from whom they were free of challenge.

In June and July male C. pumilus showed total regression of the testes and
in August most male C’. namaquensis had inactive testes. Yolk deposition occurred
in follicles of 2 mm diameter in adult female C. pumilus and C. namaquensis.
C. pumilus eggs were ovulated at 7,0—-8,0 x 6,0-6,5 mm and in C. namaquensis
at a diameter of 13 mm or greater. Development of ovarian follicles is brought
to and held at 4 mm diameter if oviducal development of embryos or eggs is
in progress. Ovarian follicular development does not proceed until the litter
developing in C’. pumilus had at least reached pholidosis and in C. namaquensis
until the oviducal eggs were being shelled or their laying was imminent.
Recently ovulated C’. namaquensis eggs have a reddish embryonic area of 2 mm,
and at the time of oviposition this area was as great as 10 mm.

The gestation period in C. pumilus was as short as 60 days in the case of
litters conceived in March and born in May to as long as about go days at
other times. Gestation lasted 35-45 days in C. namaquensis. C. pumilus females
about to give birth select small-leaved shrubs, and C. namaquensis females
Oviposit in burrows which they dig to a depth of 200-250 mm.

Sexually mature female Chamaeleo pumilus had four litters annually, the
size of the female having some relation to the size of the litter. Births were
recorded in February to May, September, November and December. ‘The
largest litters (5-21; X = 17,0 young) were born in December; the smallest in
April (3-6; X = 4,5 young), for an overall range of 3-21 (KX = 11,0 young).
Newly born C. pumilus quickly freed themselves of their membranes, and have
a mean snout-vent of about 22 mm; the smallest are those born in September
(snout-vent mean of 20 mm) and the largest those born in November (snout-
vent mean of 25 mm). The pattern of the young differs from that of the adults.

146 ANNALS OF THE SOUTH AFRICAN MUSEUM

Growth is rapid, maturity being reached in both sexes at a snout-vent of 50 mm,
taking 85 days for those born in November to as much as 240 days in those
born in March, April and May.

C. namaquensis had at least two to three clutches of eggs per year, and these
eggs are laid from May to September. Clutches laid in September (6-13;
X = 9,5 eggs) were the smallest in complement and those laid in July (10-22;
X = 13,0 eggs) were the largest. Of 250 C. namaquensis eggs examined, sizes at
oviposition varied from 17,5-26,0 x 10,0-14,5 mm}; 1,2-2,8 g (KX = 20,5 x 11,6
mm; 1,5 g). Eggs laid in September were slightly larger than those laid at
other times. When first laid, eggs were beige, becoming immaculate white with
thin parchment-like shells.

Eggs laid in early August, September, and October took 91 days to hatch,
while those laid in May took 112 days. The overall incubation period was 98,4
days. The length of the incubation period is apparently related to the tempera-
tures at the depth at which the eggs were laid. ‘The overall incubation increment
of C. namaquensis eggs was: length 14-40% (x = 19,8%); width 4-16% (x =
OO )2 choral Welt WOR U. (Cx == B70 %7,)).

Recently hatched male C. namaquensis varied in total length from 45-55
mm and all weighed about 0,6 g. Females were larger, varying in total length
from 55-65 mm and weighed 1,0-1,7 g (KX = 1,5 g). They were identical to the
adults in appearance, except the young had more vertebral knobs. The young
have an affinity for climbing. Male C. namaquensis matured in 210 days at a
snout-vent of 70-75 mm and females in 150 days at a snout-vent of 75-80 mm.

Excision of the fat bodies resulted in a decline of testicular activity in
four males each of C. pumilus and C. namaquensis. Excision of the fat bodies in
four female C’. namaquensis retarded or prevented ovarian follicular growth in
pre-estrous females. In early estrous females fat body excision induced a high
incidence of follicular atresia and retarded the yolk deposition rate. In six
female Chamaeleo pumilus fat body excision retarded or prevented ovarian
follicular development, and only pregnant females with the young near birth
actually completed delivery.

Corpora lutea were large and prominent in C. pumilus and C. namaquensis
females during the gestation period. Excision of corpora lutea in five pregnant
female C. pumilus had no effect on litter development of those young that had
passed pholidosis, but in those females with more immature young, corpora
lutea excision resulted in resorbtion. In four gravid female C. namaquensis,
excision of the corpora lutea did not affect the oviposition of those eggs about
to be laid, but recently ovulated eggs were resorbed. Developing oviducal
embryos in C.. pumilus and developing oviducal eggs in C. namaquensis apparently
rest in specific chambers in the oviducts during gestation, and if insufficient
sites are available in C. pumilus, the surplus ovulated eggs were resorbed and
their corpora lutea degenerated.

ECOLOGY AND BEHAVIOUR OF CHAMAELEO PUMILUS PUMILUS (GMELIN) 147

ACKNOWLEDGEMENTS

This study was submitted as a thesis in partial requirement of the degree
of Doctor of Philosophy at the University of Stellenbosch, January 1972.

I wish to express gratitude to my promoter Professor G. N. Louw and co-
promoter Professor C. A. du Toit, who helped me in innumerable ways during
this study, generously offered material aid and encouragement, and introduced
me to the wide horizons of research in South Africa. I gratefully acknowledge
financial assistance from the South African Council for Scientific and In-
dustrial Research during the early part of this study. Indebtedness is also
expressed to the late Dr C. Koch, Drs R. Jensen, M. K. Jensen, Messrs R. de
Bruine, E. Holm, and K. Schaer of the Namib Desert Research Station
(Gobabeb). Dr V. Wolfe, Chemical Pathology Department, University of
Stellenbosch, kindly analysed nasal salt exudates from Chamaeleo namaquensis.
Dr Prudhoe of the British Museum (Natural History) identified parasitic
material removed from both chamaeleons. Messrs Lintvelt, Van Eeden, and
Teuteberg of the technical staff of the University of Stellenbosch gave inval-
uable assistance in providing experimental equipment. Especial thanks are
due to Miss Joyce E. Miller, who gave much assistance during the earlier
phases of this study. Miss D. A. F. Shamley assisted with the statistical analyses.
Messrs C. Hector, and V. Muller greatly assisted in procuring specimens.

Especial thanks are owing to Dr Barry and the South African Museum
for providing a venue for the later stages of the work, and to Mr A. Byron for
the reproduction of the photographs.

I wish to thank my wife, Sylvia, for proof-reading and assisting in pre-
paring the manuscript for publication.

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by capital letters (A, B, C etc.).

REFERENCES

Harvard system (name and year) to be used: author’s name and year of publication given
in text; full references at the end of the article, arranged alphabetically by names, chronologi-
cally within each name, with suffixes a, b, etc. to the year for more than one paper by the same
author in that year.

For books give title in italics, edition, volume number, place of publication, publisher.
For journal articles give title of article, title of journal in italics (abbreviated according to the

World list of scientific periodicals. 4th ed. London: Butterworths, 1963), series in parentheses,

volume number, part number (only if independently paged) in parentheses, pagination.

Examples (note capitalization and punctuation)

BuL.toucu, W. S. 1960. Practical invertebrate anatomy. 2nd ed. London: Macmillan.

FiscHER, P.-H. 1948. Données sur la résistance et de le vitalité des mollusques. 7. Conch., Paris
88: 100-140.

FiscHEr, P.-H., Duva, M. & Rarry, A. 1933. Etudes sur les échanges respiratoires des littorines.
Archs Zool. exp. gén. 74: 627-634.

Konn, A. J. 1960a. Ecological notes on Conus (Mollusca: Gastropoda) in the Trincomalee region
of Ceylon. Ann. Mag. nat. Hist. (13) 2: 309-320.

Konn, A. J. 19605. Spawning behaviour, egg masses and larval development in Conus from the
Indian Ocean. Bull. Bingham oceanogr. Coll. 17 (4): 1-51.

THIELE, J. 1910. Mollusca: B. Polyplacophora, Gastropoda marina, Bivalvia. In: scHULTZE, L.
Koologische und anthropologische Ergebnisse einer Forschungsreise im westlichen und zentralen Siid-
Afrika. 4: 269-270. Jena: Fischer. Denkschr. med.-naturw. Ges. Jena 16: 269-270.

ZOOLOGICAL NOMENCLATURE

To be governed by the rulings of the latest International code of zoological nomenclature issued
by the International Trust for Zoological Nomenclature (particularly articles 22 and 51).
The Harvard system of reference to be used in the synonymy lists, with the full references
incorporated in the list at the end of the article, and not given in contracted form in the synonymy
list.

Example

Scalaria coronata Lamarck, 1816: pl. 451, figs 5 a, 6; Liste: 11. Turton, 1932: 80.

Bryan Ronald Burrage

COMPARATIVE ECOLOGY AND BEHAVIOUR OF
CHAMAELEO PUMILUS PUMILUS (GMELIN)
AND C. NAMAQUENSIS A. SMITH

(SAURIA: CHAMAELEONIDAE)

x4

ANNALS OF THE SOUTH AFRICAN MUSEUM
ANNALE VAN DIE SUID-AFRIKAANSE MUSEUM

VOLUME 62

HE TRUSTEES OF THE DIE TRUSTEES VAN DIE
OUTH AFRICAN MUSEUM SUID-AFRIKAANSE MUSEUM
PE TOWN KAAPSTAD

1973-1974

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ANNALS OF THE
SOUTH AFRICAN MUSEUM

VOLUME 62

NEW GENERIG AND SUBGENERIC NAMES
PROPOSED IN THIS VOLUME

Chaka Griffiths, 1974
Schroederobatis Hulley, 1973
Stinobatis Hulley, 1973 (

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LIST OF CONTENTS

Cooper, M. R.
Cenomanian ammonites from Novo Redondo, Angola (published August 1973)

HUuttey, P. A.

Interrelationships within the Anacanthobatidae (Chondrichthyes, Rajoidea), with
a description of the lectotype of Anacanthobatis marmoratus Von Bonde & Swart,
1923 (published November 1973)

GriFrFitus, C. L.

The Amphipoda of southern Africa. Part 2. The Gammaridea and Caprellidea of
South West Africa south of 20°S (published January 1974) Be

Gruirritus, C. L.
The Amphipoda of southern Africa. Part 3. The Gammaridea and aro es of
Natal (published January 1974)

GRINDLEY, J. R.
See
KeEnsLEy, B. F. & GrinbLeEy, R. D.

KENSLEY, B. F.

The genus Callianassa (Crustacea, Decapoda, Thalassinidae) from the west coast
of South Africa, with a key to the South African species (published March 1974)

KeEnsLeEy, B. F. & GRINDLEY, J. R.
South African parasitic Copepoda (published October 1973)
Prins, A. J.
African Formicidae (Hymenoptera) in the South African Museum. Description of
four new species and notes on Tetramorium Mayr (published August 1973)
Tuurston, M. H.

A new species of Paramelita (Crustacea: eae from South Africa anes
November 1973) a ; : : me

Page

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131

209

265

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ANNALS

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ANNALS OF THE SOUTH AFRICAN MUSEUM
ANNALE VAN DIE SUID-AFRIKAANSE MUSEUM

Volume 62 °&£2Band
August 1973 Augustus
Part I Deel

AFRICAN FORMICIDAE (HYMENOPTERA) IN
THE SOUTH AFRICAN MUSEUM

DESCRIPTION OF FOUR NEW SPECIES AND
NOTES ON TETRAMORIUM MAYR

By
A. J, PRINS

Cape Town Kaapstad

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AFRICAN FORMICIDAE (HYMENOPTERA) IN
THE SOUTH AFRICAN MUSEUM. DESCRIPTION OF
FOUR NEW SPECIES AND NOTES ON TETRAMORIUM MAYR.

By

A. J. PRINs
South African Museum, Cape Town

(With 40 figures)

[MS. accepted 11 October 1972]

CONTENTS

Introduction . : ‘ : ‘ : : : I
Description
A. Myrmicinae
Tetramorium solidum Emery 3
Tetramorium solidum Emery tuckeri Ataralcl 5
Tetramorium solidum Emery signata Emery : ; 7
Tetramorium capense Mayr 8
Tetramorium peringueyt Arnold 9
I

Tetramorium peringueyt Arnold dichroum Santen pert
Tetramorium aspinatum n.sp. . . : - - 12
Tetramorium rutilum n.sp. : : : ; ee ata:
Tetramorium jaurest Forel : : é ‘ cael
Key for the identification of the species . : : 18
B. Formicinae
Camponotus namacolus n.sp.. : : é eee 20)
Camponotus sellidorsatus n.sp. . ‘ : : Bee esl
Summary : : ; : A : : 5 BF
Acknowledgements . ‘ : J : ‘ 2s
References ‘ ‘ ‘ ‘ 4 ; ‘ 23
Figures 1-40 ‘ : , : : : spe 2A
INTRODUCTION

In view of the fact that most of the descriptions of the various types of ants
of South Africa are inadequate and the drawings which are available lack any
detail of the sculpture and setae, I have decided to illustrate those available to
me in museums in South Africa and Rhodesia, and I hope that this will help
other myrmecologists who find it almost impossible at the moment to identify
the various forms. As no types or paratypes are available of Tetramorium solidum
Emery signata Em. and T. jaurest Forel, drawings were made from specimens
determined by Arnold for the purpose of clarifying their position in the pro-
posed key.

Among the Tetramoriini, those species that belong to the solidum group,
which have the epinotal spines as long as wide at their bases, have always been

Ann. S. Afr. Mus. 62 (1), 1973: 1-40, 40 figs.

2 ANNALS OF THE SOUTH AFRICAN MUSEUM

identified with great difficulty, especially those from the north-western Cape
where marginal or transitional forms usually occur. For separation of the
different species of these ants the body setae and sculpture of the head and
abdomen seem to be very important and for this purpose I have enlarged a small
area of the vertex of the head and the middle of the first abdominal segment of
each form to illustrate the sculpture and position of the setae. As the abdomen
of ants is usually very variable due to shrinkage or swelling, depending on the
method of preservation prior to pinning, the length of the insect as a whole is
therefore approximate; the length from the apex of the clypeus to the apex of
the petiole (or postpetiole) is more accurate, but it should be remembered that
with old and fixed specimens this length would vary slightly according to the
position in which the ant was fixed to the card.

In the first paragraph of each description the lengths of the various seg-
ments and their indices, most of them according to Brown (1949), Taylor (1968)
and Sze-Li Hsu (1970), are given as follows (I have also included the cephalo-
thoracic index, that is, the length of the head expressed as a percentage of the
length of the truncus or HL x 100/WL):

ED = Distance between compound eyes
CL = Clypeal length
FL = Frontal length
HFL = Hind femur length
HL = Head length (from the anterior margin of the clypeus to the
posterior border; wherever a comparison is made in this paper,
the mandibles are excluded unless otherwise stated)
I. = Length from apex of clypeus to apex of petiole (or postpetiole)
LO = Length from hind margin of clypeus to middle ocellus.
MFL = Middle femur length
OD = Distance between hind ocelli
PL = Petiolar length (the length of the node only, excluding the
peduncles)
PPL = Postpetiolar length (peduncles excluded)
SL = Scape length (from its apex to the tip of its basal lobe)
TL = Total length of insect including the mandibles
WL = Length of truncus (similar to that of Weber’s, marked by arrows
in the drawing)
CI = Cephalic index
CLI = Cephalothoracic index
FI = Frontal index
i —seenolarncex
PPI = Postpetiolar index
SI = Scape index
TI = Thoracic index

AFRICAN FORMICIDAE (HYMENOPTERA ) 3

DESCRIPTION

A. Myrmicinae

Tetramorium solidum Emery, 1886
(Figs 1-4, 27A, B)

® TL 3,68 mm; HL 1,04 mm; WL 1,00 mm; PL 0,28 mm; PPL 0,28 mm;
HFL 0,92 mm; MFL 0,80 mm; ED 0,96 mm; SL 0,72 mm; CL 0,24 mm;
Pino.co mm; 1) 2584 mm; Cl ro7,7; CL) 104; CLI 341,60; FI 120; Sl 64,3;
miroe Pil 123°6;'PPI 164,93.

Arnold (1917) gives the colour as piceous, but the type specimen before me
is rather dark burnt sienna to dark reddish brown; the antennae paler, the
mandibles almost dark raw sienna. Fairly dull, the abdomen shining and very
finely and superficially reticulate, the sculpture somewhat stronger on the base.
Head longitudinally striate, the striae or rugae on the anterior part of the sides
rather coarse, finely and superficially reticulate between the rugae. Clypeus
with about 8 to g coarse longitudinal striae, continuous with those on the front
and vertex. Mandibles striate and rather shining, the teeth black. Antennae
microscopically and superficially reticulate—rugulose. Truncus very finely
reticulate with some longitudinal striae or rugae superimposed dorsally, the
sides obliquely striate; the nodes also finely reticulate and rugulose. Legs very
superficially and finely reticulate and shining.

Pubescence short and decumbent more abundant on the legs and antennae.
Pilosity sparse, consisting of a transverse row of curved setae on the anterior
margin of the clypeus, a few long hairs on the frontal carinae, vertex and
occipital corners of the head, the pro- and mesonotum, nodes and apical
segments of the abdomen.

Head almost square, slightly wider than long, nearly two-fifths wider than
the pronotum, the sides and hind margin almost straight. Frontal area indistinct,
eyes small, with more than 60 facets, occupying about one-fifth of the length of
the head, and situated in the middle of the sides.

Frontal carinae wide apart, extending to about the middle of the head.
Clypeus almost flat above, the anterior face fairly high, its junction with the
dorsum rounded, widely and deeply excised in the middle. Flagellum about
three-tenths longer than the scape; the latter not reaching the hind margin by
one-fifth of its length. The first joint of the flagellum as long as the second and
third taken together; the 2nd to 5th slightly wider than long, the 6th about as
long as wide, the rest longer than wide.

Truncus about four-ninths longer than wide over the pronotum and about
three-fifths wider in front than behind over the bases of the spines, the thoracic
sutures obsolete above, the meso-epinotal suture slightly indicated by a faint
transverse ridge. In profile the dorsum forms a slight curve with the epinotum
lower than the pronotum, the latter obtusely marginate in front. The dec/ivity

4 ANNALS OF THE SOUTH AFRICAN MUSEUM

of the epinotum almost vertical and transversely rugose, the dorsum nearly flat;
the spines twice as long as wide at their bases and acute. First node of petiole
a little more than one-fifth wider than long, seen from above the hind as well as
the short front margin is almost straight, the node much narrower in front than
behind, almost trapezoidal. In profile it is nearly quadrate, the front and hind
faces vertical, the dorsum very slightly convex and about as high as wide behind;
the subpetiolar process is present as a small acute tooth at the extreme base and
pointing forward. Second node about as high as the first, seen from above two-
fifths wider than long, the sides convex; in profile nearly one-fifth higher than
long; the subpostpetiolar process developed as broad rounded lobes on each
side. Legs moderately long. Abdomen truncate at base.

Type series: 2 99 (1 damaged). Locality and date unknown.

© (Figs 3, 4). TL + 5,6 mm; HL 1,18 mm; WL 1,70 mm; PL ome
PPL 0,32 mm; HFL 1,12 mm; MFL 0,86 mm; ED 1,10 mm; OD e776),
LO 0,48 mm; SL 0,84 mm; CL 0,30 mm; FL 0,88 mm; L 3,76 mm; Gia
CP 69,4; CLI 346; Fl 125; Sl] 6450; Tl 62:4) Pl 14751, PPro

Burnt umber to castaneous red, mandibles, legs and antennae paler, light
reddish brown, the swollen parts of the femora dark brown. Dull all over, the
abdomen slightly shining. Head and dorsum of truncus longitudinally striate,
finely reticulate between the striae, the scutellum of the mesonotum with some-
what finer striae. Epinotum finely reticulate-punctate and with some trans-
verse rugae. Parapsidal furrows present, but not clearly visible from above
(under low magnification). Sides of pro-, meso- and metathorax longitudinally
striate, those on the latter oblique, the sides of the epinotum merely rugulose;
the declivity reticulate-punctate and with some fine rugae superimposed. Both
nodes finely reticulate-punctate, the first node with fine transverse rugae; the
abdomen superficially and finely reticulate, the reticulation somewhat stronger
on the basal portion. Pubescence and pilosity similar to those of the worker, the
pubescent hairs longer on the whole body and also more abundant on the
abdomen. Mesopleurae almost devoid of setae.

Head very slightly wider than long, almost square, the eyes occupy a little
less than one-quarter of the length of the head. Truncus longer than the head,
in profile the dorsum is almost straight, the spines long, about as long as wide
at their bases, or slightly shorter than the length of the eyes. First node of petiole
almost trapezoidal when seen from above, front margin straight with definite
anterior corners, anterior and posterior faces vertical. In profile it is one-fifth
higher than long, the dorsal face straight, the subpetiolar process present as
a small acute tooth as in the worker. Second node of petiole about one-third higher
than long; seen from above it is slightly more than twice as wide as long, the
sides convex, not drawn out and flattened.

Material: 1 9 Santschi, 1916. Locality unknown. Specimen determined by
G. Arnold.

AFRICAN FORMICIDAE (HYMENOPTERA) 5

Tetramorium solidum Emery subsp. tuckerzt Arnold n. comb.
(Figs Saye 28A, B)
Tetramorium solidum Emery var. tuckeri Arnold, 1923 n. syn.

8 (The head, truncus and first node of petiole intact, the second node and
abdomen broken off.)

HL 1,40 mm; WL 1,44 mm; PLo,38 mm; HFL 1,30 mm; MFL 1,10 mm;
ED 1,16 mm; SL 0,94 mm; CL 0,34 mm; FL 1,06 mm; L (length from apex of
clypeus to apex of petiolar node) 3,68 mm; CI 104,3; CTI 97,2; CLI 300;
Binnee4: SI 58,9; TI 50,7; PI 121,1.

Arnold gives the colour as black, but the type specimen in the collection is
light castaneous to dark brick red, the antennae, mandibles and legs, except
the middle portions of the femora which are of the same colour as the body,
ferruginous. Almost dull, or with a very slight gloss, more shining than solidum,
the sculpture similar to that of the latter, but stronger, the head more evenly
striate, the declivity of the epinotum as coarsely and transversely striate (and
reticulate).

The head is slightly wider than long, two-fifths wider than the truncus, the
sides almost straight, the hind margin shallowly excised in the middle; the eyes
large, occupying nearly two-sevenths of the length of the head. Frontal area
indistinct, frontal sulcus obsolete, the frontal carinae wide apart, extending to
about the middle of the head. Anterior face of clypeus less rounded than in
solidum; the scapes not reaching the hind margin of the head by about one-
quarter of their length.

Truncus about two-fifths longer than wide over the pronotum and about
two-thirds wider in front than over the bases of the spines. The pronotum is
margined in front, much more so than in solidum and the dorsum of the epino-
tum when seen in profile appears to be somewhat concave (slightly convex in
the latter) ; the meso-epinotal suture is present as a wide notch and just behind this
notch on the middle line is a small tooth-like prominence or tubercle. ‘The
pro-mesonotal suture which is absent in the type of the species and its other
varieties, clearly demarcates the mesonotum. Sides of the epinotal dorsum
almost parallel, the declivity vertical, the spines short, shorter than wide at the
base and slightly longer than the episternal.

First node of petiole, seen from above, oval and slightly more than one-fifth
wider than long, slightly wider behind than in front, both anterior and posterior
margins convex, the latter somewhat angular in the middle; in profile it is
quadrate as in solidum, the dorsum being almost straight, the hind face inclined
backwards, forming an angle with the dorsum; subpetiolar process present as
a minute rounded tooth or denticle.

Type: 1 & Brehden, South West Africa, 20 December 1915 (R. W. E.
Tucker).

In other specimens collected in Brehden, South West Africa (20 December
1915) (TL 5,0-5,2 mm; L 3,6 mm; PPI 200) the pro-mesonotal suture is almost

6 ANNALS OF THE SOUTH AFRICAN MUSEUM

obsolete in the middle, but still indicated on each side of the pronotal disc. In
this case the tooth-like tubercle behind the meso-epinotal suture is absent, so
that the epinotal dorsum does not really appear concave; the spines (Figs 6B,
C) are longer and resemble those of solidum; first node of petiole is more tri-
angular, being slightly more than one-fifth wider than long (PI 122,2~-123,5),
the posterior margin is more rounded and not angular in the middle; in profile
its anterior and posterior faces are almost vertical, the dorsal face slightly convex.
Second node of petiole is nearly twice as wide and about three-eighths (exclud-
ing the subpostpetiolar process) higher than long, transversely rugose and finely
reticulate between the rugae, the sides somewhat drawn out and flattened
posteriorly; the subpostpetiolar process as broad rounded teeth.

The abdomen is superficially reticulate and shining, the reticulation stronger
towards the base where it is also finely longitudinally rugulose (Fig. 28B).

Unfortunately Arnold did not state whether these specimens were collected
from the same nests as the holotype; however, if more specimens become avail-
able from that area, I shall not be surprised if this subspecies 1s raised to specific
rank.

In specimens from the north-western Cape (TL 5,16-5,8 mm; L 3,6—3,96
mm; PI 122,1-141,1; PPI 214,3-180) which are very similar to the specimens
from South West Africa, the spines are almost of the same length (Fig. 6A),
but the pro-mesonotal suture is very well indicated, making the mesonotum
somewhat gibbous as in the type specimen. Although the abdomen in this case
is also superficially reticulate, the reticulation is much closer and the striae
on the base almost absent.

© (Figs 8, 9) TL 6,7.mm; HL 1,40 mm; WL 2,04 mm; PL 0,32 mm;
PPL 0,32 mm; HFL 1,26 mm; MFL 1,0 mm; ED 1,20 mm; OD 0,34 mm;
LO 0,54 mm; SL 0,90 mm; CL 0,36 mm; FL 1,04 mm; L 4,28 mm; CI 107,1;
CTI 68,6; CLI 311, 1; Fl 115,43; 51 60; 1 58,8; Bl 16255. PPl one

Slightly larger than the female of solidum, with similar colour and sculp-
ture, the striae forming a reticulation on the pronotum, the latter not so sharply
margined laterally as in that species. Both nodes with transverse rugae which
are much stronger than in solidum. Abdomen very finely and superficially
reticulate or reticulate-coriaceous, the sculpture stronger on the basal third,
where it is also finely longitudinally striolate. Pubescence and pilosity as in solidum.

Eyes somewhat bigger, occupying nearly two-sevenths of the length of the
head; the hind ocelli closer together than in that species. Truncus with parap-
sidal furrows more clearly visible than in the latter, the suture between the
scutellum and paraptera also clathrate; the suture between the meso-epimeron
and mesosternite shallower but more clathrate.

The dorsum of the epinotum with oblique rugae, the declivity finely
reticulate-punctate, dull and transversely striate. The spines short, about half as
long as wide at their bases or about as long as the episternal. First node of
petiole seen from above somewhat oval, the sides rounded, hind margin almost
straight, front margin shallowly excised in the middle; it is about three-eighths

AFRICAN FORMICIDAE (HYMENOPTERA) 7

wider than long and also about as high as wide; in profile the dorsum is almost
flat, the front and hind faces vertical; the subpetiolar process as in the worker.
The second node is about twice as high and more than twice as wide as long, the
sides less convex than in the workers from South West Africa and north-western
Cape; and also drawn out and flattened posteriorly; the subpostpetiolar
process more pointed than in solidum.

Type: 1 2 Brehden, South West Africa, 20 December 1915 (R. W. E.
®ucker).

Tetramorium solidum Emery var. signata Emery, 1895

(Figs 37, 38)

® TL 4,40-4,8 mm; HL 1,16-1,25 mm; WL 1,16-1,28 mm; PL 0,32-
0,36 mm; PPL 0,26-0,30 mm; HFL 1,04-1,18 mm; MFL 0,88-0,98 mm;
ED 0,94-1,04 mm; SL 0,80-0,90 mm; CL 0,28—-0,30 mm; FL 0,88—-0,95 mm;
L 3,0-3,40 mm; CI 1oo-101,7; CTI 97,7-100; CLI 320-335,7; FI 106,8-
109,53 SI 67,9—-71,4; TI 59,4-61,7; PI 111,1-112,5; PPI 160-164,3.

Brown to dark brown, the mandibles, antennae and legs paler, more
yellowish brown, middle portions of the femora somewhat darker. Eyes, mandi-
bular teeth and epinotal spines black. The inner margins of the frontal carinae,
the front margin of the pronotum, front and hind margins of petiole and some
of the rugae on the body also blackish. With a slight gloss, the abdomen fairly
polished. Head longitudinally striate as in tucker, finely reticulate or reticulate-
punctate between the striae. Median area of clypeus with about 8-9 striae, the
middle one the strongest. Mandibles strongly longitudinally striate and shining.
Pronotum reticulate-rugose, rest of truncus longitudinally rugose; finely
reticulate-punctate between the rugae, the latter also longitudinally and some-
what obliquely arranged on the sides. First node reticulate-rugose, the reticula-
tion not so clearly visible in some specimens, the second node merely rugose
with some indistinct reticulation; both nodes finely reticulate-punctate between
the rugae. Basal portion of the abdomen very finely reticulate, also finely and
jongitudinally rugulose and duller than the rest which is more superficially
reticulate or reticulate-coriaceous. Legs and antennae microscopically reticulate,
the scapes duller. Pubescence and pilosity as in tuckert.

Head about as long as wide, about two-fifths wider than the pronotum,
quadrate, the sides and hind margin almost straight. Clypeus with front margin
slightly excised in the middle. Frontal carinae as in tuckeri, extending to about
the middle of the head, the frontal area obsolete. Eyes occupy about one-quarter
or slightly more of the length of the head, situated in the middle of the sides.
The scapes falling short of the hind margin by about one-sixth of their length,
they are about seven-tenths as long as the flagella; the 2nd to 6th joints nearly
as long as wide, the rest longer than wide. Truncus about two-fifths longer than
wide in front, the meso-epinotal suture clearly indicated on the dorsum as a
transverse furrow, and on the sides as a clathrate impression. Pro-mesonotal

8 ANNALS OF THE SOUTH AFRICAN MUSEUM

suture fairly clear dorso-laterally in one specimen, but obsolete in others. In
profile the truncus and nodes are similar to those of tuckeri; the spines short,
about as long as wide at the base, slightly longer than the episternal, the epinotal
decliity almost vertical, transversely striate and finely reticulate-punctate
between the striae. The first node triangular, with rounded apex, the sides and
hind margin slightly convex; it is about one-eighth wider than long and about
as high as wide. Seen from the side, the front and hind faces vertical, the dorsum
slightly convex, the peduncle a little shorter than the node. The second node oval,
about one-third wider and one-quarter higher than long; in profile the dorsal
surface is rounded. Both the subpetiolar and subpostpetiolar processes as in
tuckert. Legs moderately long; abdomen truncate at base.

Material: 3 99 Willowmore, C.P., 1912 (H. Brauns). Specimens deter-
mined by G. Arnold.

Both these two forms are bigger than the type of the species, but may easily
be recognized by the shorter spines and the first node which is rounded in front,
whereas in solidum the node has a short, almost straight front margin; tuckert on
the other hand has a broad second node, almost twice as wide as long, while in
signata the node is much narrower, being only one-third wider than long; in
the latter form the pro-mesonotum is also reticulate or reticulate-rugose.

Teiramorium capense Mayr, 1865

(Figs 35, 36)

° TL 3,60 mm; HL 0,92 mm; WL 0,94 mm; PL 0,20 mm; PPL 0,20 mm;
HFL 0,74 mm; MFL 0,64 mm; ED 0,76 mm; SL 0,66 mm; CL 0,20 mm; FL
0,72 mm; L 2,48 mm; CI 91,3; CTI 97,9; CLI 330; FI 105,6; SI 78,6; T1 57,4;
JIL 1xOs IPCI W410).

Yellowish red, the mandibular teeth and eyes black, abdomen slightly more
brownish; body with a faint gloss, the legs and antennae more shining, the
abdomen very shining. Head longitudinally striate in the middle, rugoso-striate
and also reticulate on the sides, finely reticulate between the striae and rugae.
Clypeus with about 6 to 8 longitudinal striae, the median one the strongest.
Mandibles longitudinally striate and moderately shining. Truncus and nodes
finely reticulate, almost reticulate-punctate, with longitudinal rugae super-
imposed, some of the rugae connected by anastomoses, almost forming an
indistinct reticulation. Sides of truncus also with longitudinal rugae, the lower
rugae rather coarse, the fine reticulation on the meso- and epipleurae somewhat
bigger than on the dorsum. Abdomen very superficially and finely reticulate,
almost reticulate-coriaceous. Antennae and legs microscopically reticulate-
rugulose, the sculpture somewhat stronger on the scapes. Pubescence almost as in
solidum, the abdomen appears to be almost glabrous. Pilosity long erect, yellow-
ish, more abundant on the head and abdomen than in the latter species; there
are at least six setae on the petiole and four on the postpetiole.

Head one-eleventh longer than wide and about one-third wider than the

AFRICAN FORMICIDAE (HYMENOPTERA) fe)

pronotum, the sides slightly convex, the hind margin straight; as wide in front
as behind. Frontal area fairly well indicated as a triangular impression, the
frontal carinae somewhat convergent in front, parallel behind and extending to
about the posterior two-ninths of the head, hardly forming a demi-scrobe.
Clypeus fairly flat in the middle, the front margin slightly convex, with a very
small wide emargination in the middle. Eyes small, with about thirty facets,
occupying about one-eighth of the length of the head and situated in the middle
of the sides. Scapes shorter than the head, not reaching the hind margin by about
one-eighth of their length, the flagellum as long as the head, the 2nd—4th
joints slightly wider than long, the 5th—8th about as long as wide and the rest
longer than wide, the last joint the longest.

Truncus similar to that of peringueyi, about five-twelfths longer than wide and
about seven-elevenths wider in front than over the bases of the spines, somewhat
constricted between the meso- and epinotum, the sutures obsolete above. In
profile the dorsum is moderately convex with the epinotum lower than the
mesonotum as in the other species already described; the spines long and acute,
about three-eighths longer than wide at the base and about as long as the
interval between their bases. (In solidum the spines are narrower at their bases.)
Otherwise as in peringueyi. First node of petiole one-third higher and about one-
sixth wider than long, seen from above it appears cuneiform, almost trapezoidal,
widest over the posterior third, the anterior margin straight. Seen in profile
truncate in front, the anterior face nearly as long as the oblique hind face, the
dorsal face almost straight and much shorter than in solidum and shorter than the
peduncle (in the latter species it is longer than the peduncle); the subpetiolar
process as a minute rounded tooth. The second node as long as the first, about
one-fourth wider than long and about as high as wide, almost oval when seen
from above; in profile the dorsum is much more convex than in solidum, the
subpostpetiolar process without a lobe on each side. Abdomen not truncate at
base but rounded. Legs moderately long.

Type: Locality and date unknown.

Very similar to peringueyi Arnold dichroum Santschi, but differs from it by
the smaller eyes, the finer sculpture of the truncus and nodes, the lighter colour
and by the pilosity which is less abundant, especially on the abdomen. It differs
from all the species described in this paper by the truncate first node and by the
abdomen which is rounded at the base. According to Arnold (1917, 1923) it may
be separated from popovici by the dorsal face of the first node which is as wide as
or wider than long. I have not seen fopovici in life and cannot therefore comment
on this point; it seems however if the latter could be a synonym of capense.

Tetramorium peringueyi Arnold, 1923

(Figs 19, 20, 31A, B)

© TL 4,60-4,80 mm; HL 1,20 mm; WL 1,24-1,26 mm; PL 0,34 mm;
PPL 0,34-0,36 mm; HFL 1,12 mm; MFL 1,0 mm; ED 1,10 mm; SL 0,90 mm;

10 ANNALS OF THE SOUTH AFRICAN MUSEUM

CL 0,26 mm; FL 0,94 mm; L, 3,40-3,32 mm; CI 106,7; CTI 96,8-95,2; CLI
384,6; FI 117; SI 70,3; TI 62,9-63,5; PI 129,4-135,3; PPI 158,8—-155,6.

Pale to dark brick red, the middle portion of the head somewhat darker,
the abdomen brown to mahogany with the basal portion paler. Mandibular
teeth black. Head, truncus, petiole and basal third of the abdomen slightly
shining, rest of abdomen and legs shining. Head coarsely and longitudinally
striate, widely reticulate on the sides and at the back, the striae on the occiput
divergent on each side. Mandibles coarsely longitudinally striate and shining.
Middle portion of the clypeus with about 6 to 8 striae, the median one not
particularly stronger than the others. ‘Truncus rugoso-reticulate dorsally, the
sides rugoso-striate; the epinotal declivity strongly and transversely striate and
shining. Sides and dorsal surfaces of both nodes rugoso-reticulate, the floors of
the reticulation and the spaces between the striae like those of the head and
truncus very finely and superficially reticulate; the rugae on the posterior faces
of both nodes somewhat transversely arranged. Abdomen very superficially reticu-
late and shining, the sculpture on the basal third stronger, the striolation longi-
tudinally arranged. Tibiae and scapes finely and longitudinally striolate and
fairly dull, rest of legs superficially sculptured and shining. Pubescence present
only on the flagellum. Pzlosity long, fairly abundant all over including the legs,
erect and yellowish white in colour; some of the hairs on the head, especially
those on the anterior border of the clypeus longer than the rest.

Head about one-sixteenth wider than long and about three-eighths wider
than the pronotum, the sides parallel, the hind margin straight. Frontal area
indistinct, the frontal carinae wide apart and divergent behind, extending to about
the middle of the head, the clypeus widely and fairly deeply emarginate in front.
The eyes occupy one-fifth of the length of the head, situated in middle of the
sides. Scapes fall short of the hind margin by about one-sixth of their length; all
the joints of the flagellum longer than wide, except the third which is slightly
wider than long. Truncus about three-eighths longer than wide over the pro-
notum and more than twice as wide here than over the bases of the spines.
Thoracic sutures obsolete above; on the sides the pro-mesonotal suture is fairly
well indicated, the meso-epinotal suture is represented by a wide impression,
the alitrunk being slightly constricted in this area. Pronotum submarginate in
front, the neck also rugoso-reticulate, the rugae transversely arranged. In profile
the dorsum of the alitrunk forms a wide curve, with the epinotum lower than
the pro-mesonotum. The spines long, slightly more than twice as long as wide
at the base and slightly longer than the interval between their bases, thin and
acute, directed outwards and slightly upwards.

First node of the petiole trapezoidal, seen from above much wider behind than
in front, about one-quarter wider than long, front and hind margins straight;
in profile it is about as high as wide, the front and hind faces vertical, the dorsal
face flat, the peduncle about as long as the node, the subpetiolar process very
similar to that of solidum. The second node is oval, the sides rounded, about one-
third wider and seen from the side about one-sixth higher than long, rounded,

AFRICAN FORMICIDAE (HYMENOPTERA) II

the subpostpetiolar process as in solidum. Abdomen truncate at the base. Legs
moderately long.
T ype series: 2 89, Kimberley, 1916 (G. Arnold).

Tetramorium peringueyi Arnold ssp. dichroum Santschi n. comb.
(Migs nei e2N eB)
Tetramorium solidum Emery var. dichroum Santschi, 1932 n. syn.

& TL 3,76-3,80 mm; HL 1,02-1,04 mm; WL 1,0-1,04 mm; PL 0,30 mm;
PPL 0,24 mm; HFL 0,84 mm; MFL 0,76 mm; ED 0,90—-0,92 mm; SL 0,68—
0,70 mm; CL 0,22-0,24 mm; FL 0,80 mm; L 2,72-2,76 mm; CI 105,9; CTI
102-100; CLI 372,7-350; FI 112,5-115; SI 62,9-63,6; TI 66-63,5; PI 120;
PPh 175:

Light burnt sienna (Santschi described it as red), the head, abdomen,
femora and tibiae darker, dark burnt sienna; mandibular teeth black. Head
longitudinally striate the striae finer than in feringueyi; on the sides and at the
back with some wide reticulations; very finely reticulate-punctate between the
striae. Middle area of clypeus with 6 to 8 striae, the median one stronger than
the rest. Dorsum of the truncus longitudinally rugose, with some transverse
anastomoses, especially on the epinotum and frontal portion immediately behind
the neck; sides longitudinally rugose. Both nodes reticulate-rugose, almost as in
peringueyi, the spaces between the striae, as in the case of the head and truncus,
finely reticulate-punctate. Abdomen finely and superficially reticulate, the
reticulation slightly more pronounced than in the latter species, fairly coarse
on the basal third, where it is also longitudinally striolate. Body only slightly
shining, somewhat duller than feringueyi; abdomen except its basal part more
shining than the head and truncus. Antennae and legs microscopically reticu-
late-punctate and slightly shining. Pilosity and pubescence similar to that of the
latter.

Head very slightly (about one-twenty-secondth) wider than longer and about
two-fifths wider than the alitrunk, the sides parallel, the hind margin slightly
concave in the middle. Frontal area indistinct, the frontal carinae wide apart,
extending to about the middle of the head; clypeus widely and deeply emarginate
in the middle; scapes slightly shorter than in feringueyi, falling short of the hind
margin by about one-fifth of their length; the flagellum nearly two-ninths
longer than the scape, the 3rd joint a little wider than long, the 2nd to 5th as
wide as long, the rest longer than wide. Eyes situated in the middle of the sides,
occupying about one-fifth of the length of the head. Truncus two-fifths longer than
wide and nearly two-thirds wider in front than over the bases of the spines.
The sutures obsolete above, only indicated on the sides, the meso-epinotal by
a wide impression so that the truncus appears somewhat constricted in this
area when seen from above. In profile the dorsum forms a wide curve with the
epinotum lower than the pro-mesonotum, the vertical declivity transversely

12 ANNALS OF THE SOUTH AFRICAN MUSEUM

striate; the spines nearly twice as long as wide at the base (or about as long as
the interval between their bases).

First node trapezoidal, seen from above the margins straight (the sides
slightly convex in peringueyt), only a little more than one-eighth wider behind
than long and about as high as wide, the peduncle shorter than the node
(nearly as long in feringueyr) , seen from the side the front and hind faces vertical,
the dorsal face very slightly convex; the subpetiolar process as in the latter
species. The second node about three-sevenths wider than long, oval, the sides
rounded, seen from the side about two-sevenths higher than long, the subpost-
petiolar process as in peringueyt. Abdomen and legs as in the latter.

Type series: 3 99, Kimberley, 1924 (G. Arnold).

It is quite obvious that according to sculpture, setae and occurrence, this
form is a subspecies of peringueyi and not a variety of solidum; in life it is very
similar to the first although much smaller.

Tetramorium aspinatum n.sp.
(Figs 10-13, 290A, B)

% TL 3,88-4,0 mm; HL 1,02-1,04 mm; WL 1,0-1,04 mm; PL 0,26—0,28
mm; PPL 0,24 mm; HFL 0,go-0,96 mm; MFL 0,74-0,78 mm; ED 0,86—0,90
mm; SL 0,76—0,78 mm; CL 0,24-0,26 mm; FL 0,76-0,78 mm; L2,92—2,94
mm; CI ro0o-103,9; CTI 98,1-104; CLI 323-333,3; FI 113,2-118,4; SI-
71,7-74,53; TI 58,8-64; PI 121,4-123,1; PPI 116,7—183,3.

Dark brown or blackish brown, legs and peduncle of the first node paler
in colour, antennae and mandibles reddish, mandibular teeth and eyes black.
Head, truncus and nodes moderately shining, abdomen very shining. Head
longitudinally striate as in solidum, the striae on the cheeks stronger than on the
rest of the head, finely reticulate between the striae. Median area of clypeus
with 6 to g striae, the middle one somewhat stronger than the rest. Mandibles
striate and shining. Truncus finely reticulate or reticulate-punctate with fine
longitudinal rugae superimposed, those on the lower parts of the meso- and
epipleurae stronger. Both nodes and basal third of the abdomen also finely
reticulate or alutaceous, the reticulation stronger on the sides of the nodes and
on the peduncle, almost superficial on the abdominal base, very superficial on
the rest of the abdomen; the nodes of some specimens however almost reticulate-
rugulose. Legs and antennae microscopically reticulate and shining.

Pubescence consists of fairly long sparse, yellowish-white decumbent hairs,
transversely arranged on the head and truncus, more abundant on the flagellum.
Pilose hairs present as follows: a transverse row on the anterior margin of the
clypeus, one hair in front on each frontal carina, two on the vertex, one on each
occipital corner, some on the 2nd to last abdominal segments and on the ventral
part of the body. (In solidum long setae occur also on the truncus and nodes.)

Head about as long as wide, or very slightly wider than long and about
one-third to five-twelfths wider than the truncus, the sides parallel, the hind

AFRICAN FORMICIDAE (HYMENOPTERA) 13

margin straight, occipital angles rounded. Frontal area indistinct; frontal carinae
wide apart, divergent behind, extending to the middle of the head. Clypeus with
front margin only slightly excised in the middle, therefore appearing to be
longer than that of solidum. Eyes situated in the middle of the sides occupying
about one-quarter of the length of the head. Scapes falling short of the hind
margin by about one-eighth of their length, the flagellum nearly one-quarter
longer than the scape; 2nd to 3rd joints about as long as wide, the rest longer
than wide, the first joint almost as long as the ninth. Truncus about two-fifths
longer than wide, narrower behind than in front, narrowed in the region of the
meso-epinotal suture, epinotal dorsum rounded from side to side, all the sutures
dorsally absent except for a slight transverse depression between the meso- and
epinotum. In profile the dorsum forms a wide curve, with the efznotum lower
than the pro-mesonotum; the declivity reticulate, oblique and forming a rounded
angle with the dorsum; spines absent or represented by a small tubercle on each
side. The first node seen from above almost triangular, with the angles rounded,
the front margin and sides almost forming a semicircle in some specimens,
about one-fifth wider than long and about as high as wide; seen from the side
the front and hind faces vertical; the peduncle almost as long as the node, the
subpetiolar process present as a minute tooth in front. The second node oval, from
three-eighths to almost twice as wide as long; seen from the side about one-
seventh higher than long, the subpostpetiolar process somewhat more pointed
than in solidum. Legs as in that species. Abdomen truncate at base.

Type series: 4 99, South African Museum. Port Nolloth, 20 April 1963
Cie Gillie).

3 99, Plant Protection Research Institute, Pretoria. Same locality and
date.

ee @res 12) 19) PC 656 mma; Hil 1,92 mm; Wi 2:0 mm: PL o.38 mm;
Petrozo mm; HEE 1,99 mm; MEPL 1,08 mm; ED 1,22 mm; OD 0,38 mm;
LO 0,54 mm; SL 0,96 mm; CL 0,36 mm; FL 0,96 mm; L 4,40 mm; CI 110,8;
emir o5o. Cll 294.4; Fl 129,8;/S1 66,7; Il 62,0; PI 142,1; PPI 195.

Blackish brown, abdomen and neck brown, antennae, mandibles, legs,
except the middle portions of the femora which are blackish brown, reddish;
mandibular teeth black. Whole body moderately shining. Head and truncus,
except the epinotum longitudinally striate, the striae somewhat coarser on the
sides; epinotum transversely striate, finely reticulate between the striae, the
reticulation on the head as dense as on the truncus. Clypeus with the median
stria somewhat stronger than the rest. Sutures between meso-epimeron and
mesosternite, as well as that between the scutellum and paraptera clathrate;
parapsidal furrows clearly visible from above. Both nodes finely reticulate-
rugulose, with some fine transverse rugae superimposed, on the second node the
rugae present mostly on its posterior half. Abdomen very finely reticulate-
alutaceous, the reticulation stronger on the basal third, elsewhere superficial or
even shagreened. Legs microscopically reticulate, the fore tibiae appearing
duller. Pubescence fairly long, decumbent, similar to solidum, but slightly more

14 ANNALS OF THE SOUTH AFRICAN MUSEUM

abundant on the abdomen. Pilose hairs as in that species. Meso-epimeron and
mesosternite almost glabrous, only with some hairs round the edges.

Head about one-tenth wider than long and about one-seventh wider than
the truncus, almost square, the sides and hind margin straight. Frontal area
indistinct, anterior margin of clypeus only slightly excised in the middle. Eyes
occupying about one-quarter of the length of the head; situated in the middle of
the sides; scapes falling short of the hind margin by a fraction of their length; all
the joints of the flagellum longer than wide, except the 3rd which is about as
long as wide. Truncus about three-eighths longer than wide; in profile the
scutellum is somewhat gibbous, its dorsum slightly higher than that of the
mesonotum (the same height in solidum). Epinotal teeth almost obsolete, repre-
sented by two very small broad dents, shorter than the episternal teeth.
Epinotal declivity vertical, finely reticulate and strongly and transversely
striate. First node of the petiole rounded, almost three-ninths wider than long and
about as high as wide; in profile, both faces somewhat oblique, the peduncle
about as long as the node. The second node oval, about twice as wide as long and
one-sixth wider than high, the subpetiolar and subpostpetiolar processes as in the
worker. Otherwise like the female of solidum.

Type: 1 9, South African Museum. Port Nolloth, 20 April 1963 (J. J. Cillie).

This species is very similar to solidum in size and body shape but may easily
be recognised by the absence of any spines. In life it responds in the same way
as the latter and seems to be present only in sandy soil along the coastal areas
in the west and probably also further inland.

Tetramorium rutilum n.sp.
(Figs. 14-18, 30A, B)

8 TL 4,4-4,8 mm; HL 1,14-1,22 mm; WL 1,18-1,24 mm; PL 0,26=
0,28 mm; PPL 0,26-0,28 mm; HFL 1,04-1,12 mm; MFL 0,88-0,90 mm;
ED 1,00-1,04 mm; SL 0,80 mm; CL 0,26-0,28 mm; FL 0,86-0,94 mm;
L 3,08-3,28 mm; CI 103,3-103,5; CTI 90,3-96,6; CLI 328,6-346,1; FI 113,6-
115,33; SI 63,5-67,8; TI 61-62,7; PI 142,9-146,2; PPI 176,9-178,6.

Brick red, the clypeus, anterior margin of the cheeks, coxae especially the
front coxae, mesosternum, epinotal sides, scapes, femora, tibiae and posterior
third or so of abdomen piceous; eyes, inner margins of frontal carinae, mandibu-
lar teeth and spines pitch black. Moderately shining, abdomen slightly more
polished than the rest of the body. (In some specimens from the same locality,
the insects are very shining, the dorsal surfaces of the nodes are just as super-
ficially sculptured as the abdomen, and the striae on the head very incon-
spicuous.) Head finely reticulate and also finely and longitudinally striate, the
striae on the cheeks and clypeus stronger than on the rest of the head (which
appears merely finely reticulate-striate.) Mandibles striate and shining.

Truncus and nodes of the petiole very finely and somewhat superficially
reticulate, almost reticulate-rugulose, the reticulation stronger on the sides;

AFRICAN FORMICIDAE (HYMENOPTERA) 15

the meso- and epipleurae also finely and obliquely rugoso-striate as in aspinatum.
Abdomen alutaceous. Legs and antennae microscopically rugulose, the legs
moderately shining, the sculpture coarser on the scapes which are dull. Pube-
scence short, scanty, decumbent and inconspicuous, more abundant on the
antennae. Erect pilosity exactly as in aspinatum.

Head very slightly wider than long and about two-fifths wider than the
thorax, quadrate, the sides and hind margin straight. Frontal area indistinct,
frontal carinae wide apart, divergent behind, extending nearly to the middle of
the head. Front margin of the clypeus with a narrow angular emargination in the
middle; eyes placed in the middle of the sides and occupying about one-quarter
of the length of the head. Flagellum one-fifth longer than the scape, the latter
falling short of the hind margin of the head by about one-sixth of its length;
and to 8th joints of the flagellum as long as wide, the rest longer than wide.
Truncus about three-eighths longer than wide, much wider in front than behind,
all the sutures obsolete above, the meso-epinotal suture sometimes indicated
by a faint transverse impression. In profile the truncus is similar to that of
aspinatum, the demarcations between the mesonotum and mesosternum and
between the meso- and episternum clathrate. The declivity of the epinotum
sculptured as the thorax, with some fine transverse rugae superimposed. Spznes
present as short, broad triangular teeth, about as long as the episternal and
about half as long as the interval between their bases. First node, seen from
above, semicircular, the hind margin almost straight or slightly convex, the
posterior angles rounded, about one-third wider than long; seen from the side
almost as high as wide, anterior face oblique, posterior face vertical, the
peduncle only very slightly longer than the node, the subpetiolar process
absent or present as a very minute tubercle. Second node about four-ninths
wider than long, oval, seen from the side, about three-tenths higher than long,
the subpostpetiolar process present as a broad rounded tooth on each side,
more pointed than in aspinatum. Abdomen truncate at base. Legs as in that species.

Type series: 3 $9, South African Museum. Vanrhynsdorp, C.P., 19
April 1963 (J. J. Cillie).

4 9%9, Plant Protection Research Institute, Pretoria. Same locality and date.

In some of the smaller workers the head is nearly one-twelfth wider than
long and somewhat longer than the truncus, the following measurements being
representative: TL 4,32 mm; HL 1,06 mm; WL 1,00 mm; PL 0,26 mm;
PPL 0,24 mm; HFL 0,98 mm; MFL 0,84 mm; ED 0,94 mm; SL 0,72 mm;
@Eio:26 mm; FL 0,76 mm; L 2,88 mm; CI 107,5;.CTI 106; CLI 338,5; FI
Bel 69.9: 72,0; PI 190,83 PPI 175.

In some specimens collected near Bitterfontein, Cape Province (9g October
1959, A. J. Prins) the postpetiolar process forms a minute acute tooth at the
extreme base of the petiolar peduncle; the colour being similar to that described
above, but in the same species from Klawer, Cape Province (19 April 1963,
J. J. Gillie) the colour is much paler, yellowish red, the basal part of the abdo-
men yellowish to ochreous; the truncus is about as long as the head or slightly

16 ANNALS OF THE SOUTH AFRICAN MUSEUM

shorter (CTI 100-103,8), the spines of similar length but the head and truncus
smaller in comparison to the Vanrhynsdorp specimens (HL 1,08-1,10 mm;
WL 1,04-1,08 mm; CI 101,1-101,8; TI 61,8-63,5); both nodes of similar
length but somewhat narrower (PL 0,26 mm; PPL 0,26 mm; PI 130,8-138,5;
PPI 169,2); the postpetiolar process resembles that of the Bitterfontein forms. In
one nest found near Vanrhynsdorp (24 August 1962, J. J. Gillie) the workers are
much smaller (TL 3,68-3,80 mm; L 2,64-2,72 mm; HL 1,0-1,02 mm; WL
1,0-1,02 mm; PL 0,24-0,26 mm; PPL 0,20 mm; HFL 0,88—-0,90 mm; MFL
0,76 mm; ED 0,86-0,88 mm; SL 0,70—-0,72 mm; CL 0,24—0,26 mm; FL 0,76
mm; CI 103,9-104; CTI 100; CLI 315,4-333,3; FI 113,2-115,8; SI 67,3-
67,9; TI 62-62,7; PI 130,8-133,3; PPI 200-210). The colour is paler, of a
yellowish brown instead of red, the spines (Fig. 15) a little longer, the head as
long as the truncus and the second node more than twice as wide as long,
otherwise like the type of the species.

2 (Figs 17,18) TL 6,0 mm; HL 1,22 mm; WL 1,76 mm; PL 0,28 mm;
PPL 0530 mm; HFL 1,16 mm; MFL 0,98 mm; ED 1,14 mm OD ioral,
LO 0,52 mm; SL 0,86 mm; CL 0,34 mm; FL 0,88 mm; L 3,84 mm; CI 109,8;
CT 6053; CLI 305,09; FI 128.4; Sl 64,27 Dl oad; Pl 1714 eles

Brownish red, vertex of the head paler, posterior half of abdomen, clypeus,
anterior margins of cheeks, middle portions of scapes, femora and tibiae as well
as the meso- and episterna and ventral part of abdomen brownish black.
Mandibular teeth, eyes, inner margins of the frontal carinae, a small area just
in front of the pro-mesonotal suture, the metanotum, margins of the scutellum
and paraptera, margins of the mesonotum above the wing roots and the tips
of the spines pitch black. Head and truncus, except the scutellum and epinotum
finely longitudinally striate, the striae on the cheeks and clypeus stronger; the
scutellum transversely rugose, very finely reticulate between the striae, the
epinotum and both nodes finely reticulate or reticulate-rugulose with some fine
transverse rugae superimposed, especially on the posterior part of the first node.
The sides of the truncus also finely reticulate and longitudinally rugoso-striate,
the rugae indistinct in the region near the spines, the suture between the
paraptera and scutellum as well as that between the meso-epimeron and meso-
sternum clathrate. Abdomen finely and superficially reticulate over the basal
area, elsewhere aciculate. Body fairly shining, abdomen somewhat more
polished, the sculpture of this insect weaker than in aspinatum. Antennae and
legs microscopically reticulate-rugulose and shining, the scapes duller.

Pubescence yellowish, shorter and more inconspicuous than in the latter,
sparser on the abdomen. Pilosity of head and abdomen the same as in that
species, the truncus seems to be without any pilosity.

Head slightly more than one-tenth wider than long and one-seventh wider
than the truncus. Scapes falling short of the hind margin by one-eleventh of their
length; eyes occupying three-elevenths of the length of the head. Epznotal
declivity nearly vertical, finely reticulate and also coarsely and transversely
striate; the spines longer than in aspinatum, forming definite triangular teeth, as

AFRICAN FORMICIDAE (HYMENOPTERA) 17

long as the episternal. First node two-fifths wider than long and as high as wide,
seen from above the sides and front margin almost forming a semi-circle, hind
margin slightly convex; in profile it is much thinner than in aspinatum, the hind
face vertical, the front face slightly oblique, the peduncle one-quarter longer
than the node, the postpetiolar process obsolete. Second node slightly more than
twice as wide and nearly two-fifths higher than long, otherwise like the female
of aspinatum, except that it is somewhat smaller.

Type: 1 9, South African Museum. Same date and locality as §.

Quite distinct from the other forms in this group by its red colour and finely
sculptured, almost smooth integument. The distribution seems to be the same
as for aspinatum.

Tetramorium jaurest Forel, 1914

(Figs 39, 40)

ey 7-o3 wml: EME e;96 mm: WiLi1,24 mm; PL 0,28 mm; PPL 0,24
mm; HFL 0,74 mm; MFL 0,64 mm; ED 0,74 mm; SL 0,62 mm; CL 0,24 mm;
Miron jopminl— 19°93 muni; Cl 93°38; GI 77,4; CLI 283.3; Fl 102,8; SI 68,9;
fivas-4-0rT 100; PPI 141,7:

Light brown to brown, mandibles, flagellum, tarsi and basal half of second
abdominal segment paler, more yellowish. Whole body with a slight gloss, the
nodes somewhat duller, apical part of abdomen more shining. Head longitu-
dinally striate in the middle, the median one the strongest, and continuing over
the clypeus where it is much weaker developed, the cheeks reticulate-rugose, the
sides above the eyes rugulose, the rugae just above the eyes stronger, finely
reticulate or reticulate-punctate between the rugae and striae. Mandibles
longitudinally and. superficially striate, also superficially reticulate-punctate
between the striae and shining. Truncus reticulate-rugulose with indistinct
longitudinal rugae superimposed; anterior portion of pronotum, dorso-lateral
areas of epinotum and probably also of the pro-mesonotum indistinctly rugoso-
reticulate; some stronger longitudinal striae appear on the lower part of the
epipleurae; a small oval area on the middle of the mesonotum dorsum very
shining with the sculpture effaced, the reticulation very superficial. Epinotal
declivity finely reticulate, also transversely striate and shining. Both nodes
finely reticulate-punctate and indistinctly rugose, the first node also some-
what reticulate-rugose on the dorso-lateral and anterior sides, a small area over
its middle has the sculpture effaced and appears very shining. Abdomen very
finely reticulate-rugulose, especially the basal half; where it is dull. Rest of
abdomen shining. Pubescence very scanty, more abundant on the legs and
antennae, almost absent from the rest. Pzlosity consisting of some long erect
yellowish hairs on the clypeus, vertex and occiput of the head and the abdomen,
similar to capense, but only two on the truncus and second node, the first node
seems to be devoid of pilose hairs.

Head longer than wide (about one-fifteenth when measured over the eyes.

18 ANNALS OF THE SOUTH AFRICAN MUSEUM

Arnold (1917) mentions one-fifth; this could be true if the mandibles are
included) and one-third wider than the pronotum, quadrate, the sides almost
parallel, the hind margin slightly concave. When viewed from above the
mandibles extend further beyond the anterior margin of the clypeus than in
solidum and its varieties, making the head appear even longer. Frontal area present
as an indistinct triangular impression, traversed by the median stria. Frontal
carinae almost parallel, extending nearly to the hind margin, but not forming
scrobes. Eyes fairly convex, situated in the middle of the sides and occupying
nearly one-fifth of the length of the head. Scapes not reaching the hind margin of
the head; they are about three-fifths the length of the flagellum; 2nd—8th
joints wider than long, the rest longer than wide.

Truncus about twice as long as wide and about two-thirds wider over the
pronotum than over the bases of the spines, the shoulders less pronounced than
in solidum, the pro-mesonotal suture faintly indicated as a very shallow impres-
sion; meso-epinotal suture indicated on the sides where the truncus is also
somewhat constricted, the demarcation of the two segments on the dorsum
indicated by short longitudinal rugae; the mesonotum appearing margined on
each side. In profile the dorsum is less convex, almost flat, the spines short,
as long as the episternal, directed upwards, slightly shorter than wide at the
base and much shorter than the interval between their bases; the declivity of
the epinotum almost vertical and shorter than the dorsum. The first node seen
from above almost conical, the sides, hind and front margins convex, as long as
wide, narrowed upwards towards the median line; when seen from the side,
the front and hind faces almost vertical, about one-fifth higher than long, the
peduncle shorter than the node, the subpetiolar process present as a rounded
tooth pointing forward. Second node oval when viewed from above, about three-
tenths wider than long and about as high as wide; from the side the dorsum is
convex and the subpostpetiolar process almost as in feringueyi. Abdomen only
narrowly truncate at the base. Legs fairly short, the femora more swollen than
in solidum.

Material: 1 3, Park Ryne, Natal, 1914 (G. Arnold).

The locality is the same as that of the type.

Very different from the other species mentioned here by the longer head

and the first node which is narrowed upwards. It has been collected only along
the south coast of Natal.

KEY FOR THE IDENTIFICATION OF THE SPECIES

In view of the fact that some of the early myrmecologists have been in
error concerning the length of the epinotal spines of these species, it is quite
clear that the keys for identification of these groups of ants (Arnold 1923:
244-245, couplets 83-102) should be altered as follows:

(96) 83 Epinotal spines or teeth distinctly longer than wide at the base (or about as
| long in vexator and solidum signata)
(91) 84. No demiscrobes present (or only a very slight trace of it, hardly described as

demiscrobes)

(88)

(87)

(86)
(87b)

(10rb)

(101a)

89b

go
gI
92
93

94

95

96

-100b

IOI

10la

1o1b

AFRICAN FORMICIDAE (HYMENOPTERA) 19

Pronotum finely striate or rugoso-striate, not really reticulate, especially
on the dorsum; hairs sparse

Dorsal face of the first node distinctly longer than wide. Dark yellowish red
526 ib. Sic th oncsalleicnasucicweschcle oom ene CORON LG CIEE cee ata eee popovici Forel

Dorsal face of the first node as wide as or wider than long

Eyes small with about 30 facets; head longer than wide, first segment of
abdomen with pilose hairs, rounded at the base, not truncate. First node
truncate in front. Pale ochreous...... capense Mayr and the var. braunsi Forel

Eyes larger, with about 60 or more facets. Head wider than long. First
abdominal segment devoid of any pilose hairs, truncate at the base. First node
not truncate in front. Dark reddish brown................-- solidum Emery

Pronotum reticulate or rugoso-reticulate. Hairs abundant
Nodes of petiole dull

Whole dorsum of pro-mesonotum reticulate, larger species 4,60-4,68 mm.
Spines long, more than twice as long as wide at their bases (longer than the
Mmenyval betweenmthein ASeS) enol «2 «cos Line lef. a ees ee peringueyi Arnold

Dorsum of pro-mesonotum longitudinally rugose or with some indistinct
transverse anastomoses) ; small species 3,7-3,8 mm; spines shorter, less than
twice as long as wide (shorter than the interval between their bases) --.
‘tes Si ATS AIRE el lak Aamo Sas a tee are peringueyt Arnold dichroum Santschi

Nades@lpetiole shine. mans casas donk ssc Seek eects cies + grassi Emery
Demiscrobe present
USEMOGEICUNEILORIM eC Rene tho ei. oe ne sg Sane ee ae kale vexator Arnold

Ist node not cuneiform, with a distinct dorsal as well as anterior and posterior
faces

Base of abdomen not sculptured. Head (excluding the mandibles) nearly
one-sixth longer than wide. Clypeus with a median carina............
guineense Fabricius

eee ee ee eee eee see eee eset HP esse esses ese eee eee sees eeee

Basal two-fifths of abdomen dull and longitudinally striate. Head (excluding
mandibles) hardly longer than wide. Clypeus without a carina..........
bacchus Forel

i

Epinotal spines or teeth not longer than wide at the base. (In vexator they are
about as wide, or slightly longer, but in this species the first node is cuneiform,
a definite demiscrobe is present and the pilosity is very sparse)

Larger species not less than 3,5 mm long

No trace of scrobes

Epinotal teeth longer than the episternal

Second node about twice as wide as long; pro-mesonotal suture usually fairly
distinct (in some specimens not so clearly indicated). Pro-mesonotum more or
less without a distinct reticulation, merely rugose, also finely reticulate-
punctate, between the rugae...2.....5..0..4- solidum Emery tuckeri Arnold
Second node only about one-third wider than long; pro-mesonotal suture
usually obsolete (in some specimens indicated to a certain extent dorso-
laterally). Pro-mesonotum with a more definite reticulation (also finely
reticulate-punctate between the rugae)........ solidum Emery signata Emery
Epinotal teeth not longer than the episternal or almost entirely absent (in
solidum Emery tuckeri Arnold the spines are sometimes just as long as the
episternal, but in this case the pro-mesonotal suture is clearly visible)
Epinotal teeth obsolete, or represented by a very small tubercle or a small
RIG e AOI ACIMSIGe am Sei yee oe ae ete es deslee yaw et aspinatum N.sp.

Epinotal teeth present

20 ANNALS OF THE SOUTH AFRICAN MUSEUM

(102b) =‘ 102a Head as wide as or slightly wider than long; first node not narrowed upwards
towards the median line, broad above and wider than long. Colour reddish
a alin) lave. 4: iepive save nlie th cayatoecd a) ys fel Coble ayia, Ah ante ee eae Con ete er er rutilum n.sp.

(102a) 102b Head longer than wide; first node narrowed upwards towards the median
line, about as wide as long, colour brownish .................- jaurest Forel
(98) 103 A more or less distinct demiscrobe present. (The species in this category may

be distinguished from vexator by either abundant pilosity on the abdomen or
by the first node which has a definite dorsal surface)

B. Formicinae
Camponotus subgenus Mayria Forel

Camponotus namacolus n.sp.

(Figs 23, 24, 33A, B)

® TL 5,0-5,17 mm; HL 1,06-1,08 mm; WL 1,64-1,66 mm; PL 0,32 mm;
HFL 0,74-0,80 mm; MFL 1,04 mm; ED 0,68-0,70 mm; SL 1,04-1,06 mm;
CL 0,30-0,32 mm; FL 0,76 mm; L 3,20-3,24 mm; CI 87,2-90,7; CTI 64,6—
65,1; CLI 237,5-240; FI 89,5-92,1; SI 108,4-110,6; TI 45,1-48,2; PI 87,5-
93,8.

Pale brick red to brownish all over, except the eyes and abdomen which
are black; the apical margins of the latter testaceous. In the darker specimens
the coxae, apical half of the flagella, apical portions of the scapes and the cheeks
somewhat darker in colour. Mandibular teeth blackish brown to brownish.
Head and truncus fairly dull, the mandibles, clypeus and node a little more
shining, legs and abdomen shining. Head, truncus and the node reticulate-
rugulose, the fine rugae almost concentrically arranged on each side of the disc
of the pronotum, semi-circularly on the mesonotum and transversely on the
epinotum and petiole, obliquely so on the sides of the truncus. Mandibles finely
longitudinally striolate and dull on the basal half, the sculpture effaced on the
apical portion and more shining. Abdomen also finely reticulate-rugulose, the
rugae transversely arranged, the sculpture stronger on the basal segment,
becoming more superficial towards the apex. Legs and antennae microscopi-
cally rugulose, the scapes somewhat duller. Pubescence short, decumbent,
yellowish, sparse, more abundant on the coxae and flagella, somewhat longer
on the abdomen. Pilosity erect, long, yellowish, consisting of the following: a
transverse row of about 8-9 on the anterior border, and 4 on the median area
of the clypeus; 4 on the vertex; 2 on the occiput; 2 each on the pro- and meso-
notum; 2 on the brow of the epinotum; 4 on the posterior side of the node,
and two transverse rows on each abdominal segment, one in front of the apical
margin and one of 4 setae in the middle; there are also some pilose hairs on the
ventral side of the body.

Head nearly two-seventeenths to one-eleventh longer than wide and about
one-fifth wider than the pronotum, the sides almost straight, the hind margin
very convex, about as wide in front as behind, frontal area not very clearly

AFRICAN FORMICIDAE (HYMENOPTERA) 21

demarcated behind, frontal sulcus indicated by a thin, shining line. Frontal
carinae sinuate, extending to the posterior two-fifths of the head, the distance
between them behind being about equal to their length, the eyes occupying
nearly three-tenths of the length of the head and situated behind the middle of
the sides. Clypeus obtusely carinate on the posterior half, without lobe, the front
margin convex. Mandibles triangular, projecting well in front of the head, with
five sharp teeth, the apical one the largest, the basal and masticatory margins
each with a row of long hairs. Scapes about as long as the head, extending beyond
the hind margin by nearly three-eighths of their length; the flagellum almost
two-fifths longer than the scape; all the joints longer than wide, the 2nd—roth
about equal in length, the first joint as long as the apical and much longer than
whe rest.

Truncus about twice (or slightly more) as long as wide and nearly five-
eighths wider over the pronotum than over the brow of the epinotum, the pro-
mesonotal suture distinct, the meso-epinotal suture fairly well indicated, continuing
on the sides as an oblique impression behind the meso-thoracic stigmata. In
profile the pro-mesonotum forms a wide curve up to the meso-epinotal suture,
behind this point the efznotal dorsum is very concave and saddle-shaped, forming
a small prominence behind this suture on the median line and a high rounded
brow at the back, the declivity oblique and about three-fifths the length of the
dorsum, fairly shining and finely and transversely striolate; seen from above the
floor of the epinotal concavity is flat and narrower in front than in the middle,
the sides almost parallel. Petiolar node subglobose, very slightly longer than wide,
seen in profile as high as wide, the dorsum slightly convex, the very short front
and longer hind faces vertical, the ventral surface somewhat concave; its
peduncle very short. Abdomen rounded at the base, the acidopore with a fringe
of very short setae. Legs moderately long.

Type series: 299, South African Museum. Garies, Namaqualand, 5 October
1959 (A. J. Prins).

2 $%, Plant Protection Research Institute, Pretoria. Same date and
locality.

This species has also been collected near Bitterfontein, C.P., and near
Hondeklip Bay, C.P., and I should not be surprised if it eventually is found to be
distributed throughout Namaqualand and Great Namaland.

Camponotus sellidorsatus n.sp.

CRIES QE, BG, Baar, 16))

9 TL 5,0-5,4 mm; HL 0,96-1,02 mm; WL 1,30-1,32 mm; PL 0,24 mm;
HFL 1,0-1,10 mm; MFL 0,82-0,90 mm; ED 0,66—-0,72 mm; SL 0,88—0,94 mm;
CL 0,28-0,30 mm; FL 0,68-0,72 mm; L 2,68-2,80 mm; CI 95,8-98,03; CTI
73,8-77,3; CLI 242,9-260; FI 97,1-100; SI 94-95,7; TI 53,8-56,1; PI 141,7.

22 ANNALS OF THE SOUTH AFRICAN MUSEUM

Brownish black, the flagella, tarsi and mandibles more brownish, apical
margins of abdominal segments and peduncle of the petiole paler or testaceous;
basal margins of mandibles black, the teeth brownish red. Moderately shining,
the legs and abdomen more shining than the rest, the hind part of the head
duller; the mandibles very finely reticulate-striolate, the fine striae longitudi-
nally arranged, and with large piliferous punctures, the anterior part of the
mandibles fairly shining. Finely reticulate-rugulose all over, the fine rugae
obliquely arranged on the sides of the truncus; transversely so on the epinotum
and nodes; the antennae and legs microscopically reticulate-rugulose. Pube-
scence and pilosity as in namacolus, although there seem to be four setae on the
occiput and on the brow of the epinotum.

Head very slightly longer than wide and about two-ninths to almost one-
fourth wider than the truncus, the sides a little convex, narrower in front than
in the middle, the hind margin as convex as in namacolus, the frontal area more
clearly marked, the frontal carinae as in that species, the frontal sulcus somewhat
more distinct. The eyes oval, occupying about three-tenths of the length of the
head and situated behind the middle of the sides. ‘The clypeus as in namacolus. ‘The
scapes slightly shorter than the head, extending beyond the hind margin by
almost one-third to two-fifths of their length, their bases widened and as wide
here as their apices; the flagellum two-fifths (or slightly more) longer than
the scape, all the joints longer than wide, the 2nd the shortest, the 3rd—10th
equal in length, the 1st longer than the rest and about as long as the apical
joint.

The truncus nearly twice as long as wide (or slightly less) and also about five-
eighths wider over the pronotum than over the brow of the epinotum, the meso-
epinotal suture obsolete above but indicated on each side by a triangular impres-
sion. In profile the mesonotum appears somewhat gibbous, the epinotal con-
cavity being shorter than in namacolus and therefore deeper but almost as flat;
the brow of the epinotum and its declivity similar to those of the latter species.
Petiolar node about two-sevenths wider than long, seen from above the outline is
oval, seen from the side as high as wide, the dorsal surface sloping forward, the
short front and longer hind faces nearly vertical, the ventral surface almost
straight, its peduncle short. Abdomen rounded at the base, the acidopore with
a fringe of short setae as in the previous species. Legs moderately long, the hind
legs shorter than in namacolus.

Type series: 1 3, South African Museum. Hondeklip Bay, Namaqualand,
8 January 1971 (A. J. Prins).

2 99%, Plant Protection Research Institute, Pretoria. Same date and
locality (in alcohol) (A. J. Prins).

The Tetramorium-like namacolus may easily be distinguished from sellidor-
satus by the reddish head and truncus; the latter very closely resembles a cock-
tail ant when moving slowly over the ground; both seem to have the same distri-
bution although they have not yet been found together. I have placed these two
species in the subgenus Mayria until more material is available for further study.

AFRICAN FORMICIDAE (HYMENOPTERA) 23

SUMMARY

In this paper five types and 2 series of determined specimens have been
redescribed, apart from the descriptions of four new species, together with the
necessary illustrations and a proposed key for the identification of the ants
belonging to the solidum group is added for the reader’s convenience. T. solidum
Emery var. dichroum Santschi is raised to a subspecies of peringuey: Arnold.

ACKNOWLEDGEMENTS

I am very grateful to Dr A. J. Hesse of this Museum for assisting me in the
naming of the new species described here.

REFERENCES

ARNOLD, G. 1917. A monograph of the Formicidae of South Africa. Ann. S. Afr. Mus. 14: 1-766.

ARNOLD, G. 1923. A monograph of the Formicidae of South Africa. Ann. S. Afr. Mus. 23: 191-
295.

Brown, W. L. 1949. Revision of the ant tribe Dacetini. 1. Fauna of Japan, China and Taiwan.
Mushi 20: 1-25.

Emery, C. 1886. Alcune formiche africane descritte da. Boll. Soc. ent. ital. 18: 355-366.

Emery, C. 1895. Voyage de M. E. Simon dans 1’Afrique australe. Formicides. Annls Soc. ent. Fr.
64: 15-56.

Fore, A. 1914. Formicides d’Afrique et d’Amerique nouveaux ou peu connus. Bull. Soc. vaud.
Sci. nat. 50: 211-288.

Mayr, G. 1865. Formicidae In: Reise der Osterreichischen Fregatte Novara um die Erde in den Jahren
1857, 1858, 1859. Zoologischer Theil. 2 (3): 1-119. Wien: K.K. Hof-und Staatsdruckerei.

SANTsCHI, F. 1932. Formicides sud-africains. Annls Soc. ent. Fr. Livre centen.: 381-392.

SzE-L1, Hsu. 1970. Biometrical study on interspecific differences and affinities of the genus
Formica L. (Hym. Form.). Bull. Inst. Zool. Acad. Sinica. 9: 69-81.

Taytor, R. W. 1968. Notes on the Indo-Australian basicerotine ants (Hymenoptera: Formicidae).
Austr. FJ. Kool. 16: 333-348.

ANNALS OF THE SOUTH AFRICAN MUSEUM

24

Figs 1-2. Tetramorium solidum Emery &.

25

AFRICAN FORMICIDAE (HYMENOPTERA)

mm

Figs 3-4. Tetramorium solidum Emery 9.

26

ANNALS OF THE SOUTH AFRICAN MUSEUM

:
ee
2:
Ur
Ss

pice mse oo
3 = =
SASS Ad EE Aon Wey
~ SS My
SC SS SESE NN

S|
{

fy =

gee
SORE
eS,
RWS.

mm

Figs 5-7. Tetramorium solidum Emery tuckeri Arnold §. 6A. Truncus of specimens from north-
western Cape. 6B. Dorsal outline of truncus of specimens from South West Africa. 6C. Dorsal

view of spines of specimens from South West Africa.

AFRICAN FORMICIDAE (HYMENOPTERA)

SS
a wen s\

mm

Figs 8-9. Tetramorium solidum Emery tuckeri Arnold 9.

27

ANNALS OF THE SOUTH AFRICAN MUSEUM

28

(=>)

mm

ium aspinatum n.sp. ¥.

Figs 10-11. Tetramor

29

AFRICAN FORMICIDAE (HYMENOPTERA)

Figs 12-13. Tetramorium aspinatum n.sp. &.

ANNALS OF THE SOUTH AFRICAN MUSEUM

30

Spear,

mm

15. Tetramorium rutilum, smaller form, Vanrhynsdorp.

Figs 14-16. Tetramorium rutilum n.sp. ¥.

31

AFRICAN FORMICIDAE (HYMENOPTERA)

—4

mm

Figs 17-18. Tetramorium rutilum n.sp. &.

32 ANNALS OF THE SOUTH AFRICAN MUSEUM

LS

~N

d LEIS

SS 1.

SSRN
‘ = 5

Figs 19-20.

Tetramorium peringueyi Arnold &.

33

AFRICAN FORMICIDAE (HYMENOPTERA)

su

SSN

eS

Figs 21-22. Tetramorium peringueyi Arnold dichroum Santschi ¥.

ANNALS OF THE SOUTH AFRICAN MUSEUM

34

mm

Figs 23-24. Camponotus namacolus n.sp. &.

AFRICAN FORMICIDAE (HYMENOPTERA)

Figs 25-26. Camponotus sellidorsatus n.sp. %.

go

ANNALS OF THE SOUTH. AFRICAN MUSEUM

36

GS Se eS

TAIT OE, aN

SN

Hoare (SOLE

ee

Se SES Tees EIS]
f a ee i. 7 ews HO" ECS :
OER aL cre

i Sa

29A

28A

A

27

29B

27. T. solidum Emery; 28. T.

29. T. aspinatum n.sp.; 30. T. rutilum n.sp.

30B

28B

30A

wiilane

iM RLSETIS

SSS SS

of (A) the vertex of the head and (B) the middle of the 1st abdominal

segment to show the sculpture and the position of the setae.
solidum Emery tuckert Arnold;

Figs 27-30. 0,5 mm?

on

AFRICAN FORMICIDAE (HYMENOPTERA)

f
Vv

Ford wus Vea I Ew
22x: eS . ’ Ri ~
yO DE sey wy x
Se -? go
ce Ca, GUE 2K

gt ve 4 »
aan

33A

ee
Ca as

to

1
1
De
HEg

Noe
on

a ae

Gao
Ss

J ee

7

c7
rales

2B

=
met

3

L528
=——

=}. Se
.
- a

ey rs =
OG See:

ors

OOS Re,

P

mesoreaeee
ARMS \E
SYR ore

31A

Sean ee
oe PT IR mer?

a ay EGS, fa
ESS
PLT PTay ye eae,

34. C. sellidorsatus n.sp.

>

34B

A

) the vertex of the head and (B) the middle of the 1st abdominal

segment to show the sculpture and the position of the setae. 31. JT. peringueyi Arnold; 32. J &

34

of (A
peringueyt Arnold dichroum Santschi; 33. C. namacolus n.sp.

Figs 31-34. 0,5 mm?

38 ANNALS OF THE SOUTH AFRICAN MUSEUM

f

4 1
? yy By | Gear) \a\ hs
Wh NAG
Q% ( (EN ASS DAS
2

Pig Ll ANAT a

Figs 35-36. Tetramorium capense Mayr §.

AFRICAN FORMICIDAE (HYMENOPTERA)

LSID

PESTS: eal tn
5 eae

\

Rus Li \

14:
WIAD

mm

\
\\
\
J

Figs 37-38. Tetramorium solidum Emery signata Emery &.

39

40

ANNALS OF THE SOUTH AFRICAN MUSEUM

Figs 39-40. Tetramorium jauresi Forel §.

INSTRUCTIONS TO AUTHORS
Based on

CONFERENCE OF BIOLOGICAL EDITORS, COMMITTEE ON FORM AND STYLE. 1960.

Style manual for biological journals. Washington: American Institute of Biological Sciences.

MANUSCRIPT

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REFERENCES

Harvard system (name and year) to be used: author’s name and year of publication given
in text; full references at the end of the article, arranged alphabetically by names, chronologi-
cally within each name, with suffixes a, b, etc. to the year for more than one paper by the same
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For books give title in italics, edition, volume number, place of publication, publisher.
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volume number, part number (only if independently paged) in parentheses, pagination.

Examples (note capitalization and punctuation)

BuLLoucu, W. S. 1960. Practical invertebrate anatomy. 2nd ed. London: Macmillan.

FiscHER, P.-H. 1948. Données sur la résistance et de le vitalité des mollusques. 7. Conch., Paris
88: 100-140.

FiscHer, P.-H., Duvat, M. & Rarry, A. 1933. Etudes surles échanges respiratoires des littorines.
Archs Zool. exp. gén. 74: 627-634.

Konn, A. J. 1960a. Ecological notes on Conus (Mollusca: Gastropoda) in the Trincomalee region
of Ceylon. Ann. Mag. nat. Hist. (13) 2: 309-320.

Koun, A. J. 19605. Spawning behaviour, egg masses and larval development in Conus from the
Indian Ocean. Bull. Bingham oceanogr. Coll. 17 (4): 1-51.

THIELE, J. 1910. Mollusca: B. Polyplacophora, Gastropoda marina, Bivalvia. In: scHULTZE, L.
Koologische und anthropologische Ergebnisse einer Forschungsreise im westlichen und zentralen Siid-
Afrika. 4: 269-270. Jena: Fischer. Denkschr. med.-naturw. Ges. Jena 16: 269-270.

ZOOLOGICAL NOMENCLATURE

To be governed by the rulings of the latest International code of zoological nomenclature issued
by the International Trust for Zoological Nomenclature (particularly articles 22 and 51).
The Harvard system of reference to be used in the synonymy lists, with the full references
incorporated in the list at the end of the article, and not given in contracted form in the synonymy
list.

Example
Scalaria coronata Lamarck, 1816: pl. 451, figs 5 a, 6; Liste: 11. Turton, 1932: 80.

A. J. Prins
AFRICAN FORMICIDAE (HYMENOPTERA) IN
THE SOUTH AFRICAN MUSEUM

DESCRIPTION OF FOUR NEW SPECIES AND
NOTES ON TETRAMORIUM MAYR

OLUME 62 PART 2. AUGUST 1973

THE SOUTH AFRICAN
MUSEUM

tAPE TOWN

ANNALS OF THE SOUTH AFRICAN MUSEUM
ANNALE VAN DIE SUID-AFRIKAANSE MUSEUM

Volume 62 Band
August 1973 Augustus
Part 2 Deck

CENOMANIAN AMMONITES
FROM NOVO REDONDO, ANGOLA

By
MICHAEL R. COOPER

Cape Town Kaapstad

The ANNALS OF THE SOUTH AFRICAN MUSEUM

are issued in parts at irregular intervals as material
becomes available

Obtainable from the South African Museum, P.O. Box 61, Cape Town

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Price of this part/Prys van hierdie deel
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ISBN 0 949940 28 3

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Court Road, Wynberg, Cape Courtweg, Wynberg, Kaap

CENOMANIAN AMMONITES FROM NOVO REDONDO,
ANGOLA

By
MicHAEL R. CooPEerR

South African Museum, Cape Town
(With 13 figures)

[Ms. accepted 11 December 1972]

CONTENTS
PAGE
Introduction : : : eat
Geology : : : ‘ =) 42
Systematics . : : : 243
Age of the fauna . : : Ey 152
Summary . ‘ 5 : = 266
Acknowledgements ‘ : «~ “66
References . : : 5 2 766
INTRODUCTION

No previous ammonite faunas have been recorded from Novo Redondo
(Fig. 1), although Thiele (1933) mentioned an Acanthoceras sp. and the Turonian
Mammites conciliatus (Stoliczka) from this area. The latter was probably a mis-
identification of the Middle Cenomanian Euomphaloceras cunningtoni, the outer
whorls of which take on a mammitid appearance.

Beside the well-known Upper Cenomanian locality at Salinas, few
undoubted Cenomanian ammonites have been recorded from Angola. Haas
(1942) described a worn Manielliceras? sp., together with the new species
Sharpeiceras goliath, from north of Cabiri. Kennedy (1971: 66) considers the
latter species ‘. . . is probably not separable from S. laticlavum’. An unsuccessful
attempt was made to locate the collecting site mentioned by Haas, but no
ammonites were found. Haughton (1925: 271) referred to a Mantelliceras sp.,
SAM 6728, herein confirmed and considered to represent M. cf. saxbi (Sharpe),
from south of Porto Amboim.

All catalogue numbers refer to the collections housed in the South African
Museum. Measurement abbreviations are as follows—D, diameter; H, height,
i.e. distance from umbilical seam to venter; Hi, intercostal height; Hc, costal
height; Wi, intercostal width; Wc, costal width; Ui, diameter of umbilicus
between umbilical seams; Uo, diameter of umbilicus between umbilical bullae;
T, thickness, i.e. distance from venter of penultimate whorl to venter of final
whorl. All measurements are in millimetres.

4I

Ann. S. Afr. Mus. 62 (2), 1973: 41-67, 13 figs.

42 ANNALS OF THE SOUTH AFRICAN MUSEUM

Collecting sites
Road

CA.

axe
fi 29/2

4
7
Svo Redondo Luanda

Porto Amboim

Novo Redondo

Fig. 1. Locality map.

GEOLOGY

Post-Cretaceous folding and faulting has tended to obscure the geological
relationships, but the following very broad geological sequence is apparent.

Cretaceous strata extend as far east as the Cuvo River falls, where pale,
unfossiliferous silts lie directly on Basement rocks. These are followed by thin,
white, extremely hard, lacustrine limestones with fresh-water molluscs’
(Loc. 29/8). The succeeding pale silts are overlain by gypsiferous beds. Some-
what higher up, the first marine fossils occur in sandy limestones and silts, with

CENOMANIAN AMMONITES FROM NOVO REDONDO, ANGOLA 43

the appearance of WNeithea tricostata (Coquand), ‘Trigonia’ sp., other bivalves,
gastropods, echinoids, and the ammonite Mantelliceras. ‘These beds (Loc. 29/7)
are of Lower Cenomanian age. Closer to Novo Redondo (Loc. 29/2) higher beds
of grey, coarse-grained calcareous sandstones and grits are entirely lacking in
fossils. At Novo Redondo, dark grey shales, from a trench being excavated
around the perimeter of the chapel, yielded crushed specimens of Turrilites
costatus Lamarck and Anisoceras plicatile (J. Sowerby), together with indetermi-
nate acanthocerate fragments. Somewhat higher beds, exposed both to the
north (Loc. 29/4) and to the south (Loc. 29/6 & 34) of the town, contain a
fauna rich in echinoids and the ammonites Turrilites acutus Passy, Euomphaloceras
cunningtont (Sharpe) and Forbesiceras obtectum (Sharpe). Bivalves and gastropods
are uncommon.

SYSTEMATICS

Order AMMONOIDEA Zittel, 1884
Suborder LYTOCERATINA Hyatt, 1889
Superfamily TURRILITACEAE Meek, 1876
Family Hamitidae Hyatt, 1900
Genus STOMOHAMITES Breistroffer, 1940
Type species: Hamites virgulatus Brongniart, 1822
Stomohamites aff. simplex (d’Orbigny)

Fig. 2E

aff. Hamites simplex d’Orbigny, 1842: 550, pl. 134, figs 12-14.
aff. Stomohamites simplex (d’Orbigny) Kennedy, 1971: 6, pl. 1, figs 1-8.

Description

A single, poorly-preserved hamitid, SAM K2703, appears to be related to
d’Orbigny’s species, mainly by virtue of their equivalent ages in the Middle
Cenomanian, S$. duplicatus (Pictet & Campiche) being a Lower Cenomanian
form.

The whorl section of the Angolan specimen is unknown, but would appear
to be circular. Ornament consists of radial annular ribs of which there are about
seven in a distance of 5 mm, a distance approximately equal to the diameter.

Discussion

The unique Angolan specimen differs from S. simplex in its apparently finer
ribbing, and is thus closer to the Hamites simplex figured by Collignon (1928: 55,
pl. 7, figs 1-3), which Sornay (1956) and Kennedy (1971) consider to belong to
another species,

44. ANNALS OF THE SOUTH AFRICAN MUSEUM

ae

EY

Y
Y),

YY,
Y

iy
yy

Wy;

Wy, Y

Yy

Wi Yyyjy ji Yi yy
YY Wi Wy Y y (08)

Li MY
1 YY,
j yy

lower row of

tubercles concealed. Loc. 34. X 1. E. Stomohamites aff. simplex (d’Orbigny). SAM K2703. Loc. 29/4. x 1. F—G. Acanthoceras

°
>

A. Forbesiceras obtectum (Sharpe). Lateral view of poorly preserved nucleus, SAM Ke7o0. Loc. 29/4. X 2. B-C. Exogyra sp.
cf. tunetana Pervinquiére. Ventral and lateral views of SAM K2928. Loc. 29/5. X 2/3.

Left and right valves of SAM K2577. Loc. 29/6. x 1. D. Turrilites (Turrilites) acutus Passy. SAM K4126

CENOMANIAN AMMONITES FROM NOVO REDONDO, ANGOLA 45

Family Anisoceratidae Hyatt, 1900
Genus ANISOCERAS Pictet, 1854
Type species: Ammonites saussureanus Pictet, 1847
Anisoceras plicatile (J. Sowerby)
Fig. 3D

Hamites plicatilis J]. Sowerby, 1819: 281, pl. 234, fig. 1.
Anisoceras plicatile (J. Sowerby) Kennedy, 1971: 12, pl. 3, figs 12, 13; pl. 4, figs 1-3.

Description

A single very crushed specimen, SAM K3545, is assigned to this genus by
virtue of the association of two lateral ribs per ventro-lateral tubercle. It is
preserved as a composite internal mould in shale.

The shell has a typical Anisoceras form and is loosely coiled in a single (?)
plane. The whorl section is unknown. The ornament consists of rather dense,
fine, flexuous, distinctly rursiradiate ribbing, narrower than the interspaces
which are about 3 mm wide. There are septate spines high up on the flank, with
each of which are associated two flank ribs. There are generally two ribs
between each spine. The nature of the venter is unknown.

Discussion

The apparent lack of lateral tubercles, possibly due to crushing, makes its
assignation to Anisoceras somewhat tentative. In all other respects, however, the
ornament closely resembles Anzsoceras plicatile which, according to Kennedy
(1971: 13) ‘.. . is frequent in the lower part of the rhotomagense Zone’.

Family Turrilitidae Meek, 1876
Genus TURRILITES Lamarck, 1801
Type species: Turrilites costatus Lamarck, 1801
Turrilites (Turrilites) costatus Lamarck
Fig. 3E

Turrilites costata Lamarck, 1801: 102.
Turrilites (Turrilites) costatus Lamarck, Clarke, 1965: 53, figs 20a, b; pl. 20, figs 1, 2, 7, 8.
Kennedy, 1971: 30, pl. 6, fig. 3, pl. 8, figs 12-14.

Description

A number of crushed specimens, preserved as internal moulds, undoubtedly
belong to this species, showing the characteristic development of ribs on the
adapical portion of the outer whorl surface, which join the upper row of
tubercles, the latter being bullate.

ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 3
A-C. Turrilites (Turrilites) acutus Passy. A. SAM Kgior. X 2/3. B. SAM K4103; lower row of
tubercles concealed. x 1. C. SAM K4100; lower row of tubercles exposed. x 2/3. All from

Loc. 29/6. D. Anisoceras plicatile (J. Sowerby). SAM K3545. Loc. 29/1 xX 1. E. Turrilites

(Turrilites) costatus Lamarck. SAM K3540. Loc. 29/1. x 1. F-G. Mantelliceras cf. saxbit
(Sharpe). Ventral and lateral views of SAM 6728. x 1.

CENOMANIAN AMMONITES FROM NOVO REDONDO, ANGOLA 47

Discussion

This species ranges from the top of the Mantelliceras mantelli zone, through-
out the rhotomagense zone, attaining its greatest abundance at the base of the
latter zone, where Kennedy (1971) has recognized a Turrilites costatus faunal
assemblage.

Turrilites (Turrilites) acutus Passy
Figs 2D, 3A—C, 8D, 13B

Turrilites acutus Passy, 1832: 334; Diener, 1925: 79. Collignon, 1964: 53, fig. 1489. Clarke, 1965:
54, pl. 19, fig. 7. Kennedy, 1971: 30, pl. 7, figs 7, 8.

Turrilites dearingt Stephenson, 1952: 30, pl. 44, figs 6-8. Clarke, 1965: 55, pl. 20, fig. 4. Kennedy,
LOZ: 3l-

Description

This well-known species is represented by numerous large examples from
Novo Redondo, both with the lower row of tubercles exposed, as in T. dearingz,
or concealed, as in 7. acutus, indicating the two ‘species’ to represent nothing
more than intra-specific variation.

The shell is spirally coiled, sinistral, with a very acute spiral angle. ‘The
whorls are in contact, with the outer face gently convex intercostally, but
angular, polygonal in costal section.

The outer face is ornamented with three spiral rows of prominent tubercles,
arranged on weak, oblique ribs, of which there are 19-20 per whorl. The upper
tubercles are the most prominent and are somewhat bullate, lying slightly above
mid-flank. The lower pair of tubercles are more conical, and not as prominently
developed. The distance between the middle and upper row of tubercles is
greater than that between the middle and lower row. The lowest row may be
exposed (Fig. 3C), or concealed (Fig. 3B) by the succeeding whorl. The upper
line of contact of each whorl is crenulated. The lower surface is gently convex
and lacking in ornament. The upper whorl surface is strongly concave, with an
acute shoulder. The suture-line is well preserved in some of the specimens

(Fig. 4).

a ie
oe
See ceneoe®

of Sects
e

Fig. 4
Suture-line of Turrilites acutus Passy. x 2}.

48 ANNALS OF THE SOUTH AFRICAN MUSEUM

A single, aberrant specimen (Fig. 13B) develops a shallow spiral groove
between the middle and upper row of tubercles, slightly above mid-flank, on the
final two whorls, and is associated with the disappearance of the upper row of
tubercles and a marked weakening of the lower two rows. Other specimens at
similar, and larger, growth stages show no sign of this phenomenon.

Discussion

Kennedy (1971: 31) pointed out that the only difference between T. acutus
and T. dearingi was that the lower row of tubercles was exposed on the outer
flanks of the whorls of the latter species, and concluded that this species
‘... may merely be an aberrant TJ. acutus’. Whilst the Angolan material shows
T. (Turrilites) dearingi not to be aberrant, it must be considered to fall within the
intra-specific limits of 7. acutus. From the Angolan material it appears that
the lower row of tubercles is covered during the early ontogenetic stages,
becoming exposed with age.

Superfamily DESMOCERATACEAE Zittel, 1895
Family Desmoceratidae Zittel, 1895
Subfamily Puzostinae Spath, 1922
Genus puzosiA Bayle, 1878
Type species: Ammonites subplanulatus Schliter, 1871
?Puzosia sp. indet.
Description

A puzosiid fragment is referable to either this genus or Austiniceras. The
specimen is moderately large, with an evenly-arched venter and slightly convex
flanks, which converge towards the venter. The venter is ornamented with
distinct, narrow, prorsiradiate ribs which form a chevron across the venter.
There are six ribs within a 15 mm distance along the venter.

Superfamily ACANTHOCERATACEAE Hyatt, 1900
Family Lyelliceratidae Spath, 1921
Subfamily Forbesiceratinae Wright, 1952
Genus FORBESICERAS Kossmat, 1897
‘Type species: Ammonites largilliertianus d’Orbigny, 1841
Forbesiceras obtectum (Sharpe)

Figs 5, 6A—B

Ammonites obtectus Sharpe, 1853: 20, pl. 7, figs 4a—c.
Forbesiceras obtectum (Sharpe) Kennedy, 1971: 47, pl. 16, fig. 3; pl. 9, figs 3a, b; pl. 46, fig. 3

Description

This species, together with Turrilites acutus Passy, forms the most abundant
component of the Novo Redondo fauna and is represented by gigantic oxycones,

CENOMANIAN AMMONITES FROM NOVO REDONDO, ANGOLA 49

nearly all of which are, unfortunately, weathered composite internal moulds.
Consequently, the ornament is known only from a single, small, specimen,
SAM K2684. It is extremely involute and compressed, discoidal, with broad,
slightly convex flanks. The very narrow venter is slightly convex, with a faint
median keel. The ribbing is extremely faint, but is visible as strongly prorsi-
radiate striae on the inner half of the flanks The outer half of the flanks
shows rursiradiate ribbing projecting strongly backwards. The suture-line is
well preserved in a number of specimens (Fig. 5).

Fig. 5

Suture-line showing first lateral saddle of Forbesiceras
obtectum (Sharpe), SAM Ka25q41. X I.

Measurements
No. D. lel W. Ake
SAM K2684 See te 5) 79 28 e
SAM K2688 a > 140 49 100
SAM Koe6o1 ay BOR f +60 ?
SAM K26o02 23) 205 ? +50 ?
SAM K2687 ee 1O5 120 42 +90
Discussion

According to Kennedy (1971: 46) Forbesiceras is a medium-sized, rare
ammonite genus. Neither of these statements is applicable to the Novo Redondo
forms which are both extremely abundant and extremely large. Small nuclei of
this genus (Fig. 2A), and presumably this species, occur at Locality 29/4 and
show distinct ventro-lateral tubercles, with slightly prorsiradiate ribbing on the
outer parts of the flank.

ANNALS OF THE SOUTH AFRICAN MUSEUM

50

s

BESS

eee

6
Lateral and ventral v

1g

F

iews of SAM K2684. Loc. 29/6. x 1.

(Sharpe)

btectum

A-B. Forbesiceras o

CENOMANIAN AMMONITES FROM NOVO REDONDO, ANGOLA 51

Family Acanthoceratidae Hyatt, 1900
Subfamily Mantelliceratinae Hyatt, 1900
Genus MANTELLICERAS Hyatt, 1900
Type species: Ammonites mantelli J. Sowerby, 1814
Mantelliceras cf. saxbu (Sharpe)

Figs 3F—G; 7C-—D

cf. Ammonites saxbii Sharpe, 1857: 45, pl. 20, figs ga, b.

cf. Ammonites mantelli Sharpe, 1857: 40, pl. 18, figs 4a, b only (non Sowerby).

cf. Ammonites feraudianus Sharpe, 1857: 51, pl. 23, figs 6a—c (non d’Orbigny).

cf. Mantelliceras hyatti Spath, 1925: 197.

cf. Mantelliceras ventnorense Diener, 1925: 170. Kennedy, 1971: 62, pl. 26, figs 2a—c.

Description

A single somewhat worn specimen, SAM K2506, was collected from the
lowest fossiliferous marine horizon studied (Loc. 29/7). It is matched by an
almost identical specimen, SAM 6728, from the ‘sea-cliffs south of Benguela
Velha (Porto Amboim)’, discussed by Haughton (1925: 271) and now figured
(Figs 3F—-G).

The Novo Redondo specimen, SAM K2506, is preserved as a composite
internal mould. The shell is compressed, with a whorl height: whorl width
ratio of 1,25, and rather involute. The umbilicus is deep and fairly narrow, with
a steep umbilical wall and a subrounded shoulder. The broad flat flanks
converge slightly to the narrow, evenly-rounded venter. ‘The ornament com-
prises alternating long and short prorsiradiate ribs, the former arising from
small but distinct umbilical bullae. All ribs are ornamented with both upper
and lower ventro-lateral tubercles. There are 15 ribs per half whorl, of which
7 are long ribs. The umbilical bullae extend on to the umbilical walls as radial
primary ribs. The ribs pass straight up the flank to lower ventro-lateral tubercles,
from which they bend sharply forwards to the upper ventro-lateral tubercles
before joining across the venter. The latter is flat between the upper ventro-
lateral tubercles.

Measurements
No. D. H. Wi. We. Ui. Wo 7 or.
SAM K2506 oP 40 20 16 ? 9 15 le
SAM 6728 He AI 20 18 ? 10 16 ?
Discussion

Mantelliceras mantelli (J. Sowerby) differs from this species in being more
inflated, with an octagonal whorl section, and in possessing mid-lateral
tubercles. Mantelliceras lymense (Spath) is more finely ribbed than the Angolan .
example, with 25 ribs per half whorl, of which 7 are long ribs arising from

ANNALS OF THE SOUTH AFRICAN MUSEUM

52

"1 X *£/6% ‘90°T ‘g0Szx JVS JO SMOIA [eUDA pue [e193] *(adxeys) 22gxvs “Jo
spsanyaunpy “QD “1 X °9/6% ‘2077 “1LSz yy WYS Jo SMoIA [eIWUDA puL ]eIA}e] ‘UOUTT[OD v7v{S0I42g asuauoosaj09 sv4a909qq0/) “G—-W

L sty

CENOMANIAN AMMONITES FROM NOVO REDONDO, ANGOLA 53

umbilical bullae, whereas there are only 15 per half whorl in the Novo Redondo
specimen. Kennedy & Hancock (1971) considered M. ventnorense Diener closely
related to M. saxbu, and of doubtful specific status. This species has about
34 alternating long and short flexuous ribs per whorl, and is thus very close to
the Angolan specimen. The ribbing in the latter is straight, however, and not
flexuous.

The Angolan specimen bears a close resemblance to the holotype of
M. hyattit Spath, considered a synonym of M. saxbiu by Kennedy & Hancock
(1971), but is more coarsely ribbed. ‘The Isle of Wight specimen has 19 ribs per
half whorl at a slightly larger diameter, of which 9 are long ribs. However,
Haughton’s example from Porto Amboim has a similar number of ribs, but
appears to increase rather rapidly in inflation on the anterior portion of the
outer whorl.

Genus CALYCOCERAS Hyatt, 1900
Type species: Ammonites navicularis Mantell, 1822
Calycoceras coleroonense percostata Collignon

Figs 7A—B

Calycoceras coleroonense Stoliczka var. percostata Collignon, 1964: 118, pl. 361, fig. 1584.
? Calycoceras newboldi var. ankomakaensis Collignon, 1937: 16, pl. 3, figs 7, 7a; pl. 8, fig. 6.
Collignon, 1964: 120, pl. 362, fig. 1588.

Description

Two slightly crushed specimens appear to belong to this subspecies. Both
are preserved as composite internal moulds.

In SAM Ka571, which has suffered slight lateral compression, the shell is
compressed and evolute, with a wide, shallow umbilicus and a rounded
umbilical shoulder. The flanks are almost flat and converge slightly to the
evenly rounded venter. The outer whorl increases very slowly in height.

The ornament comprises rather dense, rounded, slightly flexuous ribs,
generally alternating long and short, although occasionally there may be two
short ribs intercalated between adjacent long ribs. The long ribs are ornamented
with small but distinct umbilical bullae, while all ribs show the faintest hint of
lower ventro-lateral swellings, and small, but distinct, upper ventro-lateral
clavi. On the posterior portion of the outer whorl siphonal tubercles are very
weakly developed. There are about 22 ribs per half whorl, 11 of which are long
ribs. The greatest width is at the umbilical shoulder.

For comparative purposes measurements of other species are included
below, with percentages in brackets.

54. ANNALS OF THE SOUTH AFRICAN MUSEUM

Measurements
No. D. H. Wi. We. Ui. Uo. ale
SAM Ka571 = .- = 94-—S ss 335(37) = 3.4(36) = 35 ? 52 ?
I) yee a a. (ait) (42) = (35) =a a
Dey be 61 (48) (48) — (26) Me aa
Bee pe I, (G9) (43) oe) = =
Ay 105 (40) (43) —— | (32) cea

The other species are as follows: 1 the type species of C’. newboldi ankoma-
kaensis; 2 the specimen figured by Collignon (1964); 3 the type species of
C. coleroonense percostata; 4 the type species of C. sinuosum.

Discussion

Calycoceras coleroonense (Stoliczka) has flat flanks, with 25-35 ribs per whorl,
and a sulcate venter in mature forms, although Stoliczka (1861: 71) considered
the ‘. . . chief distinctive character of this species lies in the very gradual
increase of the whorls in height and in the septa’. The Angolan form does not
have a concave venter, while the ribbing is denser.

Calycoceras coleroonense percostata Collignon was erected for a more densely
ribbed variety with 45 ribs per whorl, in which the venter was only very
slightly concave, a feature not apparent in the figure. There appears no
difference whereby the Angolan form can be separated from this subspecies.

Calycoceras sinuosum Collignon has the same general form as C. coleroonense
percostata, indeed the measurements are virtually identical, with about 42 ribs
per whorl, but apparently has finer, more flexuous ribbing. The differences are
slight.

Calycoceras newboldi newbold: (Kossmat) is more inflated, with a narrower
umbilicus, fewer, stronger ribs, and more prominent tuberculation. Calycoceras
newboldi ankomakaensis Collignon differs from the type in having flatter flanks,
more evolute coiling, more ribs (42), higher whorls, and weaker tuberculation.
It thus closely approaches C. coleroonense percostata. A comparison of the dimen-
sions of these two forms shows that the type of C. newboldi ankomakaensis is
transitional between the smaller example figured by Collignon (1964: 120,
pl. 362, fig. 1588) and the larger holotype of C. coleroonense percostata. It seems
possible that the differences in the Madagascan species are due to comparison
of different ontogenetic stages.

Calycoceras annulatum Collignon
Figs 8A—C
Calycoceras annulatum Collignon, 1964: 127, pl. 366, figs 1597, 1598.
Description

Two fragments of the outer whorls of rather large forms are assigned to this
species, both preserved as composite internal moulds.

CENOMANIAN AMMONITES FROM NOVO REDONDO, ANGOLA

Fig. 8

A-C. Calycoceras annulatum Collignon. A-B. lateral and ventral views of SAM
K2559. X 2/3. C. lateral view of SAM K2580. x 2/3. Both from Loc. 29/6.
D. Turrilites (Turrilites) acutus Passy. SAM K2568. Loc. 29/6. X 2/3.

95

56 ANNALS OF THE SOUTH AFRICAN MUSEUM

In SAM Ke2559 the whorl section is slightly compressed, oval intercostally
and with an angular, polygonal costal section. ‘The umbilicus was wide and
probably rather shallow, with sloping umbilical walls and an evenly-rounded
umbilical shoulder. The flanks are convex and converge towards the rounded
venter. Ornament comprises long and short ribs, which do not alternate. Thus,
while 7 ribs arise at the umbilical shoulder only 10 cross the venter. The long
ribs are ornamented with weak, strongly bullate umbilical tubercles, while all
ribs have rather weak lower ventro-lateral tubercles and more prominent
upper ventro-lateral tubercles. The ventro-lateral tubercles are also bullate due
to the peculiar nature of the ribbing. The ribs are radial and very strongly
flared, especially across the venter where the interspaces are strongly concave.
Across the venter the costal section is slightly concave between the upper
ventro-lateral tubercles. ‘There is no sign of siphonal tubercles.

SAM Ke258o, which represents a much larger, still septate, growth stage
and presumably belongs to this species, has fewer flared ribs, whilst also showing
the faintest sign of siphonal clavi.

Measurements

No. D. Hi. Hc. Wi. We. Wir Uo. li
SAM K2559 SAI) AB BG) 42 +53
SAM K258o0 ? 48 52 43 +48 ? P ?
Discussion

The distant, prominently flared, ribbing of this species, recorded from the
‘Lower Cenomanian’ Zone a Mantelliceras mantelli et Calycoceras newboldi of
Madagascar, is distinctive. The relation between this large species and the small
Calycoceras paucinodatum (Crick), also associated with Turrilites acutus, requires
looking into, especially in view of ‘. . . the considerable range of variation
admitted in this species (C. paucinodatum)’ by Kennedy (1971: 77).

Genus EUCALYCOCERAS Spath, 1923
Type species: Ammonites pentagonus Jukes-Browne, 1896

Eucalycoceras sp.

Figs g9C-D; 10C-D
Description

Two very worn fragments belong to this genus. Both are preserved as
composite internal moulds.

The first example, SAM Ke259, is a distinctly compressed form, with
convex sides, converging slightly to the flattish venter. The maximum width is
at the umbilical shoulder. Sinuous, slightly prorsiradiate long ribs arise either
singly or in pairs from weak umbilical bullae. There is invariably one,
occasionally two, shorter intercalated ribs between adjacent long ribs. ‘There

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57

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CENOMANIAN AMMONITES FROM NOVO REDONDO, ANGOLA

ANNALS OF THE

SOUTH AFRICAN MUSEUM

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CENOMANIAN AMMONITES FROM NOVO REDONDO, ANGOLA 59

are very weak lower ventro-lateral tubercles and upper ventro-lateral clavi.
The venter is not preserved.

The second example, SAM K2595, would appear to have similar flank
ornament to the above specimen, whilst also showing the nature of the venter.
The latter is flattish with distinct upper ventro-lateral clavi joined across the
venter by ribs which show faint siphonal swellings.

Measurements
No. D. H. W. Wor Ui a
SAM K2593 Me Abe ? 22 19 P ? Rn
SAM K2595 Si he ? 2g 20 ? p 21
Discussion

The undoubtedly evolute, high-whorled form and flat flanks suggest that
the above specimens belong to LEucalycoceras rather than Calycoceras. ‘The
appearance of this genus in the Turrilites acutus assemblage is at an earlier stage
than any British occurrence. According to Kennedy (1971: 81) ‘. . . the earliest
English Eucalycoceras appear at the top of the rhotomagense Zone’. E. gothicum
(Kossmat) has umbilical tubercles projecting into the umbilicus; E. pentagonum
(Jukes-Browne) has less flexuous, denser ribbing which is effaced at mid-flank
at about the growth stage of the Angolan specimens. It also has more prominent
siphonal tuberculation, as well as being an Upper Cenomanian form. Fucalyco-
ceras rowei Spath is also an Upper Cenomanian form, closely resembling the
above specimens, but also with denser, less flexuous ribbing.

Subfamily Acanthoceratinae Hyatt, 1900
Genus ACANTHOCERAS Neumayr, 1875
Type species: Ammonites rhotomagensis Brongniart, 1822
Acanthoceras cf. tunetana Pervinquiére

Figs 2F-—G

cf. Acanthoceras confusum (Guéranger) var. tunetana Pervinquiére, 1907: 268, pl. 13, figs 4a, b.
cf. Acanthoceras tunetana Pervinquiére, Kennedy, 1971: 90, pl. 40, fig. 5.

Description

Numerous crushed fragments preserved in green shales would appear
closest to this species. However, the state of preservation of the Angolan material
leaves much to be desired and comparison is difficult.

The largest and best-preserved specimen, SAM K2qg28, was almost
certainly very compressed and evolute. The umbilical wall is steep, with a
subrounded umbilical shoulder. The flanks are broad and flat, with a narrow,
tabulate venter. Ornament comprises sharp, well-rounded ribs which begin

60 ANNALS OF THE SOUTH AFRICAN MUSEUM

close to the umbilical seam, and pass backwards (rursiradiate) to the umbilical
shoulder where they swell slightly to form distinct umbilical bullae. There are
occasional intercalated ribs. From the bullae slightly prorsiradiate, convex
forwards, ribs pass up the flanks to prominent, swollen lower ventro-lateral
tubercles. Faint ribbing joins the lower ventro-lateral tubercles across the
narrow, almost flat venter, and is ornamented with weak upper ventro-lateral
clavi. There is no sign of siphonal tuberculation.

Abundant smaller examples, presumably assignable to this species, all very
fragmentary and crushed, differ only in having closer, more prominent ribbing
and much weaker tuberculation.

A complete, but somewhat crushed example, SAM K2558 (Figs gA—B)
shows similarities to the other Angolan forms and is thus doubtfully included
within this genus. This specimen is strongly compressed and very evolute. The
umbilicus is rather wide and shallow with a rather broad, vertical umbilical
wall and an angular umbilical shoulder. The broad flanks are flat and parallel.
The ventro-lateral shoulders are acute, with a narrow, tabulate venter.
Ornament on this specimen comprises fairly prominent umbilical bullae which
give rise to distinctly prorsiradiate ribs that fade away before mid-flank. There
is no other sign of ornament. This specimen differs from the above described
material largely in the absence of tuberculation. The acute nature of the ventro-
lateral shoulder furthermore seems to suggest that the lack of tuberculation is
not due to erosion. Consequently, even the generic assignation of this specimen
becomes difficult.

Measurements

No. D. lel, W. Ui. ale
SAM K2558 bes 132 55 =1S20 35 ?

Discussion

The distant ribbing, compressed form and prominent lower ventro-lateral
tubercles of this form are characteristic. Euomphaloceras alvaradoense (Moreman)
(Stephenson 1955: 63, pl. 7, figs 1-9) from the uppermost Cenomanian
basal Eagle Ford of Texas bears a superficial resemblance, presumably
due to convergence.

Kennedy (1971) assigned a specimen from the Turrilites acutus faunal
assemblage of southern England to Acanthoceras tunetana, but it differs from the
type, and the Angolan material, in having swollen, rounded umbilical tubercles
and not bullae.

The Angolan example figured differs from the type in having slightly closer
ribbing, being more compressed and having prosiradiate, not rursiradiate,

ribbing.

CENOMANIAN AMMONITES FROM NOVO REDONDO, ANGOLA 61

Genus EUOMPHALOCERAS Spath, 1923
Type species: Ammonites euomphalus Sharpe, 1855
Euomphaloceras cunningtont meridionale (Stoliczka)

Figs 10A—B; 11; 12A—B; 13A

Ammonites meridionalis Stoliczka, 1864: 76, pl. 41, figs 1a—c.

Acanthoceras meridionale (Stoliczka) Pervinquiére, 1907: 278, pl. 15, figs 2-6.

Euomphaloceras meridionale (Stoliczka) Matsumoto et al., 1969: 272, pl. 33, figs 1, 2; pl. 34, fig. 1;
text-fig. 6.

Euomphaloceras cunningtoni meridionale (Stoliczka) Kennedy, 1971: 93.

Description

This species is the most abundant of the well-preserved acanthocerates
from these beds. The shell is very evolute and strongly depressed, with a sub-
rectangular intercostal section. The costal section is angular, polygonal. The
umbilicus is wide and deep, with a steep umbilical wall and rounded umbilical
shoulder. ‘The flanks are flat and parallel, and rather narrow. The venter is
broad and slightly convex.

All the specimens are preserved as composite internal moulds. External
ornament comprises distinct umbilical bullae, which extend very faintly on to
the umbilical wall. On the earlier growth stages these bullae are weakly
connected to prominent lower ventro-lateral spines on the ventral shoulder, by
single, radial ribs. From the lower ventro-lateral spines, ribs arise in looped
pairs, occasionally with an intercalated rib between spines. Each rib is orna-
mented with upper ventro-lateral and siphonal tubercles. Thus, at about 80 mm
diameter, in SAM K2554, there are 19 upper ventro-lateral and siphonal
tubercles associated with only g lower ventro-lateral spines. At this stage the
latter point diagonally outwards.

With age the siphonal tubercles disappear and the ventro-lateral tubercles
amalgamate to form prominent horns. At this stage the flank ribs become much
more prominent and robust. The suture-line is preserved in SAM K2552 and
is reproduced in Figure 11.

Measurements

No. D. Elica, Ha Win) We. Ui. Wo: ff.
SAM Ka552 .. +120 54. 45 60 Fi +60 ? ?
SAM Ka554 .. 81 BS 29 44 48 31 45 :
SAM Ka554 .. +50 20 20 33 38 15 26 ?
SAM Ka557 .. ? 64 57 67 79 ? : 54
Discussion

Euomphaloceras cunningtoni meridionale (Stoliczka) differs from E. cunningtoni
cunningtont (Sharpe) in that the latter has more siphonal than upper ventro-

62 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 11

Suture-line, slightly eroded, of Euomphaloceras cunnington
meridionale (Pervinquiere), SAM K2552. X 1.

lateral tubercles. Both these varieties are well treated by Kennedy (1971).

The holotype is from the top of the Turrilites costatus faunal assemblage of
Wiltshire.

Aptychus sp.
Description

A single small Aptychus was collected at Novo Redondo in association with
indeterminate acanthocerate fragments, Turrilites costatus and Anisoceras
plicatile, and is consequently of low Middle Cenomanian age.

The specimen is preserved as an internal mould, and has a strongly
trigonal shape. The inner margin was broken during extraction, but it formed
almost a right angle with the harmonic margin. The surface of the mould,
i.e. the inner surface of the Aptychus, is ornamented with very fine, concentric
striae which fade away on the adharmonic ridge.

Discussion

The specimen seems closest to Spinaptychus Trauth, but the latter is known
only from Senonian beds, commonly in association with Texanites (Klinger
1971). Consequently its generic assignation is uncertain.

AGE OF THE FAUNA

The most detailed biostratigraphic subdivision of the Cenomanian is that
of Kennedy (1971) for southern England. This author has recognized 5
biostratigraphic zones:
Upper Cenomanian:
Metotcoceras gourdoni Zone
Metoicoceras geslinianum Zone
Calycoceras naviculare Zone

CENOMANIAN AMMONITES FROM NOVO REDONDO, ANGOLA 63

He

Fig. 12

A-B. Euomphaloceras cunningtoni meridionale (Pervinquiére). Lateral and ventral views of

fragment of outer whorl of mature individual, SAM K2557, showing coalescence of

ventro-lateral tubercles to form horns, and disappearance of siphonal tubercles.
Loc. 29/6. x 2/3.

64 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 13

A. Euomphaloceras cunningtoni meridionale (Pervinquiére). Front view showing whorl
section of SAM K4106. Loc. 29/6. x 1. B. Turrilites (Turrilites) acutus Passy.
?Aberrant specimen SAM K2543 showing shallow spiral groove at about mid-
whorl on body chamber. Loc. 29/6. x 1. C. Tiny ammonite nuclei, probably
acanthocerate, crowded on bedding plane. SAM K2695. Loc. 29/4. X 2.

CENOMANIAN AMMONITES FROM NOVO REDONDO, ANGOLA 6 5

Middle Cenomanian:
Acanthoceras rhotomagense Zone
Lower Cenomanian:
Mantelliceras mantelli Zone

Confined to the Lower Cenomanian are the genera Mantelliceras, Sharpeiceras
and Hyphoplites, while the heteromorph Hyfoturrilites is particularly abundant
in this stage. The strata near Novo Redondo yielding Mantelliceras cf. saxbii
may therefore be assigned to this stage.

The Middle Cenomanian is marked by the appearance of the genera
Acanthoceras and Calycoceras. Kennedy (1971: 102) recognized three strati-
graphically separate faunal assemblages within this zone, some of the more
important faunal constituents of which are listed below:

Acanthoceras jukesbrownei faunal assemblage:

Acanthoceras jukesbrowne: (Spath) and related forms dominate this assem-
blage, together with Scaphites equalis J. Sowerby and Calycoceras spp. Turrilites
costatus, IT. acutus and T. scheuchzerianus Bosc are all rare.

Turrilites acutus faunal assemblage:

Acanthoceras rhotomagense (Brongniart) and related forms are common in
this assemblage which is characterized by the abundance of T. acutus.
Also common are Calycoceras paucinodatum (Crick), C. newbold: (Kossmat) and
related forms, Austiniceras austini (Sharpe), etc., while Euomphaloceras cunningtont,
Forbesiceras obtectum, Turrilites costatus and Acanthoceras tunetana have been
recorded.

There is little doubt that the faunas at Novo Redondo, characterized by
the abundance of Turrilites acutus and Forbesiceras obtectum, correspond to this
faunal assemblage.

Turrilites costatus faunal assemblage:

Especially common in this assemblage are Turrilites costatus, Sciponoceras
baculoide {Mantell), Anisoceras plicatile, and Acanthoceras of the rhotomagense group.
It seems likely that the crushed fauna occurring in green shales around the
chapel at Novo Redondo may be assigned to this faunal assemblage.

Thus, not only are the faunal associations at Novo Redondo virtually
identical with those recorded by Kennedy (1971) from southern England, but the
same ammonite succession may also be recognized, thereby providing ample
evidence for the validity of this biostratigraphic zonation.

The well-documented Cenomanian ammonite faunas of Madagascar
(Collignon 1964) are at present of little biostratigraphic value, since the zonal
scheme recognized by Collignon (1964) undoubtedly represents collecting from
different palaeontological horizons. Most of the Angolan species are, however,
known from this island.

From Zululand Crick (1907) has recorded a rich Turrilites acutus faunal
assemblage, dominated by Calycoceras spp., T. acutus, Acanthoceras of the rhoio-
magense group, together with T. costatus, T. scheuchzerianus, Forbesiceras largillier-
tianum (d’Orbigny), etc.

66 ANNALS OF THE SOUTH AFRICAN MUSEUM

SUMMARY

A typical Cenomanian fauna characterizes Novo Redondo and environs.
The lowest beds, although poorly fossiliferous, have yielded examples of the
Lower Cenomanian Mantelliceras cf. saxbi (Sharpe). A higher horizon at Novo
Redondo itself contains Turrilites costatus Lamarck and Anisoceras plicatile
(J. Sowerby), and is correlated with the Turrilites costatus faunal assemblage of
low Middle Cenomanian age. To the north and south of the town alternating
limestones and shales are rich in Turrilites acutus Passy, Euomphaloceras cunningtoni
(Sharpe), Forbesiceras obtectum (Sharpe), Calycoceras annulatum Collignon,
Acanthoceras cf. tunetana Pervinquitre, and C. coleroonense percostata Collignon.
No higher beds were recorded from this area. The ammonite succession and
faunal associations are virtually identical with those recorded from southern
England by Kennedy (1971).

ACKNOWLEDGEMENTS

I should like to thank Dr W. J. Kennedy of Oxford for his constructive
criticism of the manuscript. The assistance given to me in Angola by the
Instituto de Investigacao Cientifica de Angola is gratefully acknowledged.

REFERENCES

CriarKE, D. L. 1965. Heteromorph ammonoids from the Albian and Cenomanian of Texas and
adjacent areas. Mem. geol. Soc. Am. 95: 1-99.

Cotiicnon, M. 1928. Paléontologie de Madagascar. xv. Les céphalopodes du Cénomanien
pyriteux de Diego-Suarez. Annls Paléont. 17: 139-160.

Co.tiicnon, M. 1929. Paléontologie de Madagascar. xv. Les céphalopodes du Cénomanien
pyriteux de Diego-Suarez. Annls Paléont. 18: 1-56.

Cotiicnon, M. 1933. Fossiles cénomaniens d’Antsatramahavelona. Annls géol. Serv. Mines
Madagascar 3: 50-80.

Cotiicnon, M. 1937. Ammonites cénomaniennes du sud-ouest de Madagascar. Annls géol. Serv.
Mines Madagascar 8: 28-72.

Couicnon, M. 1939. Fossiles cénomaniens et turoniens du Menabe. Annls géol. Serv. Mines
Madagascar 10: 61-126.

Cotuicnon, M. 1964. Atlas des fossiles caractéristiques de Madagascar (Ammonites). XI, Cénomanien.
Tananarive: Service géologique.

Cotuicnon, M. 1966. Les céphalopodes crétaces du bassin cétier de Tarfaya. Notes Mém. Serv.
Mines Carte géol. Maroc 175: 1-148.

Crick, G. C. 1907. Cretaceous fossils of Natal. Part III. Rep. geol. Surv. Natal Zululand 3: 161-250.

Haas, O. 1942. Some Upper Cretaceous ammonites from Angola. Am. Mus. Novit. 1182: 1-24.

Haucuton, S. H. 1925. Notes on some Cretaceous fossils from Angola (Cephalopoda and
Echinoidea). Ann. S. Afr. Mus. 22: 263-288.

Kennepy, W. J. & Hancock, J. M. 1971. Mantelliceras saxbii (Sharpe) and the horizon of the
Martimpreyi Zone in the Cenomanian of England. Palaeontology 14: 437-454.

Se W. J. 1971. Cenomanian ammonites from southern England. Spec. Pap. Palaeont.

> 1-133.

Kuncer, H. 1971. The possible association of Spinaptychus with the genus Texanites. Ann. geol.
Surv. S. Afr. 73 105-109.

Moreman, W. L. 1942. Palaeontology of the Eagle Ford Group of north and central Texas.
J. Paleont. 16: 192-220,

CENOMANIAN AMMONITES FROM NOVO REDONDO, ANGOLA 67

PERVINQUIERE, L. 1907. Etudes de paléontologie tunisienne. 1. Céphalopodes des terrains secondaires.
(Régence de Tunis . . . Carte géologique de la Tunisie.) Paris: De Rudeval.

Sornay, J. 1956. [Hamites simplex d’Orbigny 1840.] Palaeont. univers. (n.s.) 18: [1-2].

STEPHENSON, L. W. 1952. Larger invertebrate fossils of the Woodbine Formation (Cenomanian)
of Texas. Prof. Pap. U.S. geol. Surv. 242: 1-226.

STEPHENSON, L. W. 1955. Basal Eagle Ford fauna (Cenomanian) in Johnson and Tarrant
Counties Texas. Prof. Pap. U.S. geol. Surv. 274—G: 53-65.

StoriczKa, F. 1863-1866. The fossil Cephalopoda of the Cretaceous rocks of southern India.
Mem. geol. Surv. India Palaeont. indica (3) 1-13: 41-216.

TutEteE, S. 1933. Neue Fossilfunde aus der Kreide von Angola mit einem Beitrag zur Stammes-
geschichte der Gattung Pervinguieria Bohm. <entbl. Miner. Geol. Paldont. (B) 1933: 110-123

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Michael R. Cooper

CENOMANIAN AMMONITES
FROM NOVO REDONDO, ANGOLA

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ANNALS OF THE SOUTH AFRICAN MUSEUM
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(With 35 figures)

[Ms. accepted 16 October 1972]

CONTENTS
PAGE
Introduction . 5 : ; : ; 69
Description of species:
Order Notodelphyoida
Family Notodelphyidae : : : 70
Order Caligoida
Family Caligidae : : é 72
Family Cecropidae : : : go
Family Euryphoridae . : : gI
Family Pandaridae : é : ; 03
Family Anthosomatidae : : F 93
Family Eudactylinidae : ; ; 102
Family Pseudocycnidae : : : 104
Family Lernaeoceridae ‘ : : 106
Family Pennellidae : , ‘ 110
Order Lernaeopodoida
Family Lernaeopidae . : : : 110
Family Naobranchiidae : ; : iy)
Family aS : : : ; 119
Summary ‘ ; : : 120
enon ledeemears , 120
Catalogue of material in the Semin econ
Museum : ‘ i : ; : 121
References : , : é s ; 129
INTRODUCTION

A comprehensive account of South African parasitic Copepoda was
published by the late K. H. Barnard in 1955 (Barnard 1955a). In this paper
the majority of the species known up to that date were described and figured.
Many other papers including Bannister & Grindley (1966), Barnard (1948,
19550, 1957), Calman (1908), Ho (1972), Kensley (1970), Paterson (1958),
and Stebbing (1900, 1905) also describe parasitic Copepoda from the South
African region.

Since 1955 many more species have been added to the collections of the

69

Ann. S. Afr. Mus. 62 (3), 1973: 69-130, 35 figs.

70 ANNALS OF THE SOUTH AFRICAN MUSEUM

South African Museum. The authors and various ichthyologists on the staff
of the South African Museum including Dr P. A. Hulley, Mr S. Kannemeyer,
Dr M.-L. Penrith, Mr M. Penrith, and Dr F. Talbot collected many of the
specimens. Dr D. Eccles collected a large number of specimens from fish caught
by anglers, commercial line boats, and trawlers between 1951 and 1953 while
he was at the University of Cape Town. Many specimens from game fish and
sharks were obtained during the long-line game-fish survey carried out by the
South African Museum under the direction of Dr F. H. Talbot in 1960 and
1961. A large collection of specimens of the genus Pennella were collected from
various species of whales by Dr P. Best. The largest contribution, however,
was made by Dr Mary-Lou Hanson Pritchard of the University of Nebraska
during six months of collecting in 1961. Dr Pritchard visited South Africa to
collect Trematoda parasitic on fishes but agreed also to collect parasitic
Copepoda for the second author. Her intensive and meticulous collecting
brought many new records and several new species to light.

This study was initiated by the second author but the preparation of this
paper has been almost entirely the work of the first author. Preliminary
drawings for this work were prepared by Mr M. Leiserowitz but the final
drawings are the work of the first author. That a further study of South African
parasitic Copepoda was required is clearly evidenced by the description here
of no less than fourteen species new to science.

A catalogue of all the species of parasitic Copepoda in the South African
Museum is provided, giving details of the material, localities, hosts, catalogue
numbers, and type material. Full descriptions and figures are given of species
new to science and descriptions are also given of species recorded for the first
time from South Africa, and of species that were previously inadequately
described.

The nomenclature of the parts of parasitic Copepoda and in particular
of their mouthparts has given rise to much confusion in the past. The studies
of Bocquet & Stock (1963) and Lewis (1969) have done much to clarify the

situation and their recommendations are followed in this work.

Order NOTODELPHYOIDA
Family Notodelphyidae
Gunenotophorus blaizei n. sp.
(Fig. 1a-7)
Description
?. Head bent ventrally, with lateral margins somewhat ventrally produced.
Thorax (2nd to 4th segments) strongly inflated, containing eggs. Abdomen
4-segmented, terminal segment slightly dorsally flexed and spinose, caudal rami
dorsally curved, apically blunt. 1st antenna with segmentation obscure, apex
curved, distally covered with fine, short bristles. 2nd antenna 3-segmented,
2 basal segments broad, terminal segment tapering, with stout apical hook.

Ws

SOUTH AFRICAN PARASITIC COPEPODA

Vig

SS

NUD)

«a
ll Ih} }

a
a

Fig. 1. Gunenotophorus blaizei n. sp. a. ovigerous @ in lateral view; 6. 1st antenna; ¢. 2nd antenna;
d. urosome; ¢. apex of 2nd maxilla; f. apex of maxilliped; g. 1st thoracic leg; 4. 2nd thoracic
leg, with apex of endopod further enlarged; i. endopod of 3rd thoracic leg; j. 4th thoracic leg.

72 ANNALS OF THE SOUTH AFRICAN MUSEUM

Mouthparts agreeing with G. globularis.i 1st pair thoraric legs biramous, closely
applied to mouthparts, exopod and endopod 3-segmented, both rami bearing
long plumed setae. 2nd thoraric legs with endopod slightly longer than exopod,
endopod 4-segmented, bearing 5 encircling membranes formed by fused setae
on distal half, apex with minute pincer. Exopod 3-segmented, basal segment
bearing single distal spine, median segment bearing 2 distal spines, terminal
segment armed with 2 spines on outer margin and single apical spine. Exopods
of grd and 4th legs stout, 3-segmented, flexed dorsally, terminal segment
armed with apical spine and numerous minute spinules. Endopod of 3rd
thoracic leg 4-segmented, bearing 6 setiferous membranes and apical pincer.
Endopod of 4th thoracic leg 2-segmented, basal segment short, distal segment
elongate, bearing 4 setiferous membranes and apical pincer.

Material

2 ovigerous 99, from ascidian Gynandrocarpa unilateralis, taken in 62 m off
Cape St Blaize, NxWsW, 8 km. Total length 1,5-1,8 mm. Holotype
S.A.M. A13049, paratype S.A.M. A1goq1.

Remarks

Although the present species is closely related to G. globularis Buchholz,
and G. giganteus Schellenberg, both of which have been recorded from Pyura
stolonifera from South Africa, several characteristics demand a specific separa-
tion. The size of the largest specimen (1,8 mm) is considerably less than that of
G. globularis (3-5 mm) or G. giganteus (7,2-8,4 mm). The 2nd pair of thoracic
legs show some differences. The endopod of G. globularis is without spines, or,
as in Schellenberg’s figure 38 of 1922, with a few minute spinules, while
G. giganteus is completely unarmed. The condition in the present species, with
I or 2 spines per segment on the outer margin of the exopod, approaches
G. spimpes Schellenberg, which also, however, possesses strong spination on the
inner margin of the distal segment of the exopod. The markedly-curved terminal
segment of the 2nd exopod of G. curvipes (Illg 1958) immediately separates
it from the present species.

Order CALIGOIDA
Family Caligidae
Caligus cf. affinis Heller
(Fig. 2a—g)
Caligus affinis: Brian, 1934: 193, fig. 15; 1939: 178, fig. 1.
Description

2. Carapace obviously less than half total length. Genital segment flask-
shaped, slightly longer than carapace, posterior lobes not very prominent.
Abdomen 2-segmented, slightly shorter than genital segment, proximal segment
about 3 times length of distal segment. Sternal furca small, arms crescentic.

SOUTH AFRICAN PARASITIC COPEPODA 73

g

Fig. 2. Caligus cf. affinis Heller. a. female in dorsal view; 6. 1st thoracic leg, 9; ¢. 4th thoracic leg
Q; d. 3rd thoracic leg, 9; e. sternal furca; f. male in dorsal view; g. maxilliped, ¢.

Terminal segment of 1st thoracic leg bearing 3 strong spines, single large simple
seta, one minute seta on posterior margin. Penultimate segment with tiny scale-
like spine on anterior margin. Spine of exopod of 3rd thoracic leg slightly
curved. 4th thoracic leg 3-segmented, terminal segment bearing 4 spines,
ultimate spine about twice length of the others, penultimate segment bearing
distal spine. ‘Terminal segment of 1st maxilla a simple hooked spine.

74. ANNALS OF THE SOUTH AFRICAN MUSEUM

3. Carapace slightly less than half total length. Genital segment flask-
shaped but relatively narrower than in 9. Abdomen 2-segmented, segments
equal in length, slightly shorter than genital segment. Maxilliped subchelate,
with large blunt thumb-like spine, and second blunt spine on ‘palm’.

Material

I ovigerous + 19, 14, from Pomatomus saltator, Durban. Total length 2
A PAl-Al, ONG, G YO) Towed.

Previous records

From Sphyraena sp., at mouth of Congo River. From Umbrina cirrhosa,
from Adriatic and Mediterranean.
Remarks

The present material agrees well with the descriptions of C. affinis, and
falls within the size range given for 92 (3,30-5,45 mm) by Brian (1934). The
only difference appears to be the shape of the genital segment in the 9, which
in the Mediterranean and West African specimens seems to be slightly broader
than in the present material.

Caligus aesopus Wilson
(Fig. 34S)
Caligus aesopus Wilson, 1940: 72. Hewitt, 1963: 71, figs 4, 5. Yamaguti, 1963: 49, pl. 53, fig. 3.
Material

10 ovigerous 29, 25 99, 4 gJ; from yellowtail, False Bay. Total length 9
Al P50) OMEN, (0) 1000,

Previous records

From scombrid (? Seriola peruana) from Juan Fernandez. From Seriola
grandis, New Zealand.

Remarks

The 4-segmented 4th thoracic leg, the shape of the genital segment, with

its angular posterior corners, and the single segmented abdomen distinguish
this species.

Caligus confusus Pillai
(Fig. 3a-c)
Cahgus confusus Pillai, 1961: 104, fig. 10. Kirtisinghe, 1964: 68, figs 70-71.
Caligus alalongae (non Kroyer), Yamaguti, 1954: 379, pl. 2, fig. 19, pl. 3, fig. 21.
Caligus constrictus (non Heller), Wilson, 1937: 25, pl. 3, fig. 3.
Material

I ovigerous 9, 2 $3, from gill chamber of Caranx djedaba, Durban. Total
length 9 4,0 mm.

SOUTH AFRICAN PARASITIC COPEPODA 75

Fig. 3. Caligus confusus Pillai. a. female in dorsal view; b. sternal furca; c. 4th thoracic leg, 9. Caligus
aesopus Wilson. d. genital segment and abdomen, 9; e. sternal furca; f. 4th thoracic leg, 9.

Previous records

From carangids taken from Panang, Galapagos, on Elagatis sp. and Caranx
sp. Celebes, south India.

Caligus coryphaenae Steenstrup & Liitken
(Fig. 4a-f)
Caligus coryphaenae Lewis, 1967: 101, figs 37-39. Pillai, 1962a: 514, fig. 1.
Material

6 ovigerous 9° from Thynnus obesus, off Cape Point. 1 ovigerous 2, 3 dd
from Euthynnus pelamis, off Cape Point. Total length 9 7,2-8,5 mm, ¢ 5,4 mm.
Colour when alive, salmon pink, genital segment and abdomen yellowish.

Previous records

See Lewis (1967: 102)

76 ANNALS OF THE SOUTH AFRICAN MUSEUM

y, i}, Thy '
4] GUEETT) iff |
LT EY fT
Lif Of HE J+.)
Wifi) /
/ //

©

Fig. 4. Caligus coryphaenae Steenstrup & Liitken. a. female in dorsal view; b. sternal furca; c. and
maxilla, 2; d. 4th thoracic leg, 9; e. distal segment of abdomen, 9; f. 3rd thoracic leg.

Remarks

Three important characters by which this species may be distinguished were
given by Pillai (1962a). These are the sternal furca arms which are apically
pointed and divergent, the basal hook of the exopod of the 3rd thoracic leg,
which is straight or outcurved, and the ultimate claw of the 4th thoracic leg
which is obviously longer than the penultimate one. As the present material
agrees on all these points, it is placed in this species.

Caligus mortis Kensley
Caligus mortis Kensley, 1970: 167, figs 1, 2.

Material
10 ovigerous 99, taken from intertidal fish from Torra Bay, S.W.A., Mowe

Bay, 8.W.A., Swakopmund, S.W.A., and Saldanha Bay, Cape. Host species
include Clinus superciliosus, Blennius cornutus and Chorisochismus dentex.

SOUTH AFRICAN PARASITIC COPEPODA WG

Caligus penrithi n. sp.
(Figs 5a, b, 6a—m, 7a-—d)
Description

®. Carapace broadest posteriorly, less than half total length, cephalic
region longer than thoracic area. Lunules tiny. Margin with narrow membran-
ous fringe. Posterior sinuses relatively wide. Thoracic region extending well
beyond postero-lateral borders. Eyes tiny, contiguous, in anterior half of
cephalic area. Free thoracic segment about 3 length of genital segment. Latter
slightly broader than long, rectangular, antero-lateral corners more rounded
than postero-lateral corners. Abdomen conical, 2-segmented, slightly shorter
than genital segment. Ist antenna 2-segmented, basal segment only slightly
longer than distal segment, bearing about 12 plumose setae. Terminal segment
with 12 distal simple setae. 2nd antenna 3-segmented, basal segment short and
broad, middle segment longer and broad, terminal segment tapering, with
setule at base of strong falcate process. Mandible indistinctly 3-partite, with
12 subapical denticulations.

Postantennal process a simple spine-like structure. Ist maxilla consisting
of broad basal area bearing tiny lobe with 3 setae, and triangular spine-like
process. 2nd maxilla 2-segmented, basal segment slightly more than 4 length
of distal segment, twice as broad. Distal segment with membranous scale-like
process slightly beyond midpoint, 2 distal spines, curved, inner slightly longer
than outer, bearing 4 spinules and setiferous fringe, outer spine bearing seti-
ferous fringe only. Maxilliped 2-segmented, basal segment broad, tapering,
terminal segment short, bearing strong falciform process, single seta present
at distal end of segment. Sternal furca having divergent arms, latter apically
truncate, straight-sided. 1st thoracic leg biramous, endopod reduced to tiny
process bearing single short spine, on protopodite. Latter consisting of single
segment with single proximal plumed seta, shorter than Ist exopod segment.
Latter three times longer than wide, with spine at outer distal angle, inner
margin bearing fringe of setae. Terminal segment 4 length of Ist segment
twice longer than wide, bearing 3 curved distal spines, and 3 stout plumose
setae on inner margin. 2nd thoracic leg biramous, both rami 3-segmented.
Protopodite 2-segmented, Ist segment less than 4 length of 2nd segment,
bearing single plumose seta on inner margin. 2nd segment only slightly longer
than wide, with membranous fringe of setae and single stronger seta on inner
margin. Basal segment of exopod equal in length to 2 distal segments together,
bearing serrate spine at outer distal angle, plumose seta at inner distal angle.
Middle segment short, also bearing serrate spine at outer distal angle, plumose
seta at inner distal angle. ‘Terminal segment longer than 2nd, bearing 2 simple
spines on outer distal margin, 6 plumose setae on distal and inner margin,
seta adjacent to spines shortest. Basal segment of endopod bearing single
plumose seta on inner margin. 2nd segment longer than basal or terminal
segments, with 2 distal plumose setae on inner margin, and pad of closely

78 ANNALS OF THE SOUTH AFRICAN MUSEUM

yt Ao y
\) eas i: <>
Rea Ses

Fig. 5. Caligus penrithi n. sp. a. female in dorsal view; 6. male in
dorsal view.

packed setules around outer margin. Terminal segment with similar smaller
pad and 6 plumose setae. 3rd thoracic leg biramous. Protopodite expanded,
2 rami somewhat separated. Exopod 2-segmented, basal segment with distal
plumose seta on inner angle and smaller spine at outer distal angle, outer
margin fringed with setae. Terminal segment bearing 4 plumose setae and 3
short spines. Hook-like bipartite process arising at base of exopod with fine
membranous margin distally. Endopod 3-segmented, basal segment very
narrow, with single plumose seta, 2nd and 3rd segments subequal, 2nd segment
with 2, 3rd segment with 4 plumose setae. 4th thoracic leg uniramous, 4-
segmented, basal segment equal in length to 3 distal segments together, 2nd
and 3rd segments each with single fringed spine, terminal segment with 3
slightly curved fringed spines, apex of segment acute. 5th thoracic leg situated
at postero-lateral corner of genital segment, consisting of single tiny segment

SOUTH AFRICAN PARASITIC COPEPODA

79

iL

LES

IE
ie
(lis

Wee

en

—-

RLS

ss

Fig. 6. Caligus penrithi n. sp.9.a. 2nd antenna; b. 1st antenna; c. maxilliped; d. 1st maxilla;
e. 2nd maxilla; f. 1st thoracic leg; g. and thoracic leg; h. 3rd thoracic leg; 7. 4th thoracic leg;
Jj. 5th thoracic leg; k. caudal ramus; /. sternal furca; m. mandible.

80 ANNALS OF THE SOUTH AFRICAN MUSEUM

bearing 3 plumose setae. Caudal ramus slightly longer than wide, with 1
simple and 4 plumose setae.

g. Carapace 3 total length, widest posteriorly, lunules small, margin with
narrow membranous fringe, posterior sinuses wide. Thoracic region extending
beyond postero-lateral borders. Eyes small, contiguous, in anterior half of
cephalic region. Free thoracic segment about } length of genital segment.
Latter twice longer than wide. Abdomen 2-segmented, segments subequal,
narrower than genital segment. Ist antenna 2-segmented, basal segment
shorter than terminal segment, bearing about 16 plumose setae on outer
margin. Terminal segment with 2 long and 8 short simple setae distally. 2nd
antenna 3-segmented, basal segment broad, shorter than middle segment,
latter broad, tapering, with 2 distal grooved bulges. Terminal segment short,
with short simple seta proximally, plus 2 stout hook-like processes, one elongate
the other short. Postantennal process a simple narrowly triangular spine. Ist
maxilla a narrow spine-like process, with basal lobule bearing 3 setae. 2nd
maxilla as in 9. Maxilliped 2-segmented, basal segment very broad, with 2
pointed tooth-like processes proximally. ‘Terminal segment short, bearing distal
simple seta, and strong slightly curved process which meets tooth-like processes
of basal segment. Sternal furca with arms relatively shorter than in Q, basally
slightly curved. 1st thoracic leg biramous, endopod reduced to tiny process
bearing 2 terminal spinules. Protopodite consisting of single segment, with small
plumose seta proximally, $rd length of basal segment of exopod. Latter
2-segmented, with inner margin fringed with setae, and small spine on outer

d

b

Fig. 7. Caligus penrithi n. sp. $. a. 1st antenna; b. 2nd antenna;
c. sternal furca; d. maxilliped.

SOUTH AFRICAN PARASITIC COPEPODA SI

distal angle. Terminal segment slightly less than 4 length of basal segment,
with 3 curved spines and 3 large plumose setae. 2nd thoracic leg biramous,
protopodite 2-segmented, basal segment short, with single plumose seta. 2nd
segment with inner margin fringed with setae, and single setae at outer distal
angle. Exopod 3-segmented, basal segment equal in length to 2 distal segments
together, with strong serrate spine at outer distal angle, and plumose seta at
inner distal angle. Middle segment 4 length of terminal segment, carrying
single serrate spine, and single plumose seta. Terminal segment with 2 short
spines on outer margin, and 6 large plumose setae. Endopod 3-segmented,
Ist and 3rd segments subequal, middle segment longer. Basal segment bearing
single plumose seta, middle segment with 2 plumose setae and pad of closely
packed spinules. Terminal segment with similar pad, plus 6 plumose setae.
3rd thoracic leg biramous, protopodite expanded, bearing setal fringe. Exopod
2-segmented, with bipartite spine-like process at base, basal segment with
single plumose seta, terminal segment with 4 plumose setae and 3 small spines.
Endopod 2-segmented, basal segment narrow, with single plumose seta,
terminal segment with 6 plumose setae and margin of fine hairs. 4th thoracic
leg 4-segmented, basal segment slightly longer than 3 distal segments together.
and and 3rd segments each with single fringed spine, terminal segment with
3 slightly curved fringed spines, terminal one longest, apex of segment
acute. Caudal ramus longer than wide, with 1 small and 4 large plumose
setae.

Material

5 ovigerous + 1 99, 8 $3, from Chilodactylus fasciatus, from Mowe
Bay, S.W.A. Holotype and allotype S.A.M. A13050, paratypes S.A.M.
A13051. Total length 9 4,5 mm. Length of egg sacs 2,5 mm. Total length
@ 3,0 mm.

Remarks

Of the species of Caligus having the carapace less than half the total length,
and a 2-segmented abdomen about equal in length to the genital segment,
the present species most closely resembles C. robustus Bassett-Smith. The elongate
nature of the genital segment and abdomen of the latter species are very
different, however, from C. penrithi, with its roughly quadrate genital segment
and conical abdomen.

There is some resemblance to C. djedabae Rangnekar, particularly in the
shape of the carapace and genital segment of the female. The abdomen,
however, consists of a single segment, albeit conical, and is relatively shorter
than in C. penritht. Other differences also exist in the shape of the sternal furca
and the 4th thoracic legs of the 9.

The species is named for Dr M.-L. and Mr M. J. Penrith of the State
Museum, Windhoek, who caught the fish host of this species.

82 ANNALS OF THE SOUTH AFRICAN MUSEUM

Lepeophtheirus lalandei n. sp.
(Figs 8a, 5, ga—l, 10a—d)

Description

Q. Carapace about 3 total length, obviously longer than wide, sides almost
parallel, with moderately wide membranous fringe. Cephalic region longer
than thoracic region, with contiguous eyes at about midpoint. Posterior sinuses
narrow. Thoracic region extending slightly beyond postero-lateral borders.
Free thoracic segment about 3 length of genital segment, wider than long.
Genital segment longer than wide, with well-developed posterior lobes, 5th legs
just visible beneath these. Abdomen slightly shorter than genital segment,
unsegmented, twice longer than wide. Ist antenna 2-segmented, basal segment
broadly tapering, bearing about 13 plumose setae on anterior margin, terminal
segment shorter than basal segment, with about 12 distal setae. 2nd antenna
3-segmented, basal segment narrow, 2nd segment broad, stout, terminal
segment more slender, with simple seta below curved hooked apex, strong
spine at base. Postantennal process a small simple slightly curved spine. Ist
maxilla bifid, arms short and rounded. 2nd maxilla 2-segmented, basal segment
slightly shorter but stouter than terminal segment, latter bearing a rounded
scale at midpoint, terminally with 2 curved fringed spines, unequal in length,
Mandible slender, with 12 distal denticulations, apically curved. Maxilliped
2-segmented, basal segment stout, terminal segment about { length of basal
segment, with terminal strongly falcate process, and single seta at base. Sternal
furca very small, arms stout, stubby. 1st thoracic leg biramous, endopod
reduced to tiny process on protopodite. Latter broad, about same length as
Ist exopod segment. Exopod 2-segmented, basal segment twice longer than
broad, inner margin fringed with setae, and bearing single short spine at outer
distal angle. Terminal segment slightly more than } length of basal segment,
roughly rectangular, bearing 3 large plumose setae on inner margin, 1 short
plumose seta at inner distal angle, and 3 short fringed spines, inner 2 each
having an accessory spinule at midpoint. 2nd thoracic leg biramous. Protopodite
2-segmented, basal segment about + length of znd segment, with single plumose
seta on inner margin. 2nd segment with setal fringe on inner margin. Exopod
3-segmented, basal segment equal in length to 2 distal segments together, with
1 plumose seta on inner margin, and strong fringed spine on outer distal angle.
and segment similarly armed. Terminal segment with 6 plumose setae and 2
fringed spines. Endopod 3-segmented, middle segment longer than 1st or 3rd.
Ist and 2nd segments each with single plumose seta on inner margin, terminal
segment with 6 plumose setae. 3rd thoracic legs biramous, protopodite broad
and expanded. Exo- and endopod close together. Exopod 2-segmented, basal
segment with single plumose seta at outer and inner distal corners. Terminal
segment with 3 simple setae, and 4 plumose setae. A broad membranous
process at base of exopod, bearing spine on median edge. Endopod 2-segmented,
basal segment narrow, with single plumose seta, terminal segment with 5

SOUTH AFRICAN PARASITIC COPEPODA 83

Fig. 8. Lepeophtheirus lalandei n. sp. a. female in dorsal view; b. male
in dorsal view.

plumose setae. 4th thoracic leg uniramous, 4-segmented, basal segment stout,
about twice longer than wide, at least 2-3 times wider than other segments.
and segment shorter than 3rd, anterior margin elongated, and joint therefore
diagonal, apex of elongation bearing tiny spine and semicircular flange. 3rd
segment bearing apically a strong fringed spine with semicircular flange,
posterior margin with small spine near apex. Terminal segment bearing 3
strong curved fringed spines, decreasing in size towards anterior margin.
Posterior margin bearing 2 small spines at distal end. 3rd and 4th segments
both bearing fringe of short fused setae on entire length of anterior margins.
5th thoracic legs situated on ventral surface of genital segment, roughly fig-
shaped, bearing apical spine, and 3 plumose setae.

g. Carapace more than } entire length, longer than wide, free thoracic
segment wider than long, about 3 length of genital segment. Latter only slightly
longer than wide, with flattened flap posteriorly, corresponding to lobes in 9.

84 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 9. Lepeophtheirus lalandei n. sp. a. 1st antenna, 9; 5. 1st maxilla, 9; c. sternal furca; d. 2nd
maxilla, 2; e. maxilliped, 9; f caudal ramus; g. mandible; A. 2nd antenna, Q; 7. 1st maxilla, 3;
j. 5th thoracic leg, 9; k. 2nd antenna, ¢; /. maxilliped, g. ;

Abdomen 2-segmented, Ist segment shorter than 2nd. Caudal rami broadly
oval, bearing 4 elongate plumose setae. Ist antenna 2-segmented, basal segment
slightly longer than terminal segment, with about 12 plumose setae on anterior
margin. Terminal segment bearing about 13 simple distal setae. 2nd antenna
2-segmented, apically bearing a curved hook with simple seta, basal segment
bearing large proximal ridged area, separated from distal ridged cushion,
latter bearing 2 blunt spines, inner one twice length of outer. 1st maxilla bifid,
also bearing accessory spine on inner margin. 2nd maxilla as in 9. Maxilliped
subchelate, with short bifid spine on basal segment almost meeting tip of apical

SOUTH AFRICAN PARASITIC COPEPODA 85

Wf //
LAL? Lay \
= \
LI > ’
x SN nee \\
PAY : ~.
Si, ' “Vy \\\
~ —— t > / \
= f / AT \\ \
LS ’ ; : T
Z Bs ] rT
NEES { |
7

Fig. 10. Lepeophtheirus lalandei n. sp. 9. a. 1st thoracic leg; b. 2nd thoracic leg; c. 3rd thoracic leg;
d. 4th thoracic leg.

hook. 1st to 5th thoracic legs as in 9. Caudal ramus longer than wide, with 1
small and 4 large plumose setae.

Material

7 29, 14, from Seriola lalandi, taken at Vema Seamount. Holotype and
allotype $.A.M. A13052, paratypes S.A.M. A13053. @ total length 10,3 mm,
carapace length 5,2 mm. ¢ total length 6,4 mm, carapace length 4,0 mm.

86 ANNALS OF THE SOUTH AFRICAN MUSEUM

Remarks

Of the species of Lepeophtheirus in which the carapace is about half the
entire length, the present material resembles five species to some degree, viz.
L. argentus, L. constrictus, L. longipes, L. salmonis and L. thompson.

L. argentus Hewitt differs from the present species in the carapace shape
of the 9, the 1st maxilla and the segmented abdomen. The male of L. argentus
has an abdomen much longer than in the present species, does not possess a
subchelate maxilliped, has a differently shaped 2nd antenna, and does not
possess an accessory spine on the Ist maxilla.

L. constrictus Wilson closely resembles the present species in the shape of
the sternal furca, the 4th and 5th thoracic legs, the 1st maxillae, and the
undivided abdomen in the female. The carapace shape, however, differs, while
the genital segment does not possess posterior lobes. L. constrictus at 6,6 mm
total length is considerably smaller than the present species.

L. longipes Wilson differs in possessing a segmented abdomen, which is
relatively smaller, and in the shape of the sternal furca and 1st maxilla.

L. salmonis Wilson differs from the present species in the relatively shorter
segments of the 4th thoracic leg in the female, the undivided 1st maxilla and
in the shape of the carapace. The male of L. salmonis is very similar to the
present species.

L. thompson Baird differs in possessing a segmented abdomen, a relatively
smaller 4th pair of thoracic legs, in the shape of the furca and Ist maxilla,
and in the shape of the carapace in the female.

Lepeophtherrus longispinosus Wilson
(Fig. 11a, b)

Lepeophthetrus longispinosus Wilson, 1908: 604, pl. 52. Yamaguti, 1963: 74, pl. 99, fig. 5.
(non Lepeophtheirus sp. of Barnard, 19554: 252)
Material

3 ovigerous 99 from Carcharinus leucas. Total length 2,9-3,0 mm.

Previous records

On Sphyrna zygaena from N. America.

Remarks

The character of the 1st maxilla and the furca makes this species easily
recognizable. The former is slender, elongate, armed with a slender spine at
the base. The furcal arms are widely divergent, apically spatulate, and bear
a slender secondary branch on the inner margin.

SOUTH AFRICAN PARASITIC COPEPODA 87

OGINS

b

Fig. 11. Lepeophtheirus longispinosus Wilson.
a. sternal furca; 6. oral cone and ist
maxilla.

Lepeophtheirus natalensis n. sp.

(Figs 12, 13a-k)

Description

Q. Carapace more than half total length, slightly longer than wide,
cephalic region longer than thoracic area, with narrow membranous fringe.
Eyes situated at posterior end of cephalic region. Posterior sinuses moderately
wide. Free thoracic segment about 3 length of genital segment. Latter roughly
rectangular, with rounded posterior lobes. Abdomen unsegmented, 3 length
of genital segment, longer than broad, with narrow posterior slit. Ist antenna
with basal segment slightly longer than terminal segment, former bearing about
19 plumose setae, latter with 12 simple setae distally. 2nd antenna 3-segmented,
middle segment bearing striated rounded process, terminal segment bearing
simple seta, and tapering hook-like process. Postantennal process a simple stout
hook. 1st maxilla flanking oral cone, consisting of simple stout posteriorly-directed
hook. 2nd maxilla 3-segmented, 2 distal segments slender, 2nd bearing 2 fringed
spines, terminal segment bearing single elongate fringed spine. Maxilliped
2-segmented, basal segment stout, 5 times longer than terminal segment,
bearing strongly-curved apical process. Branches of sternal furca slender,
divergent, apically rounded. 1st thoracic leg biramous, endopod reduced to
tiny process on protopodite. Latter shorter than Ist segment of exopod, with

88 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 12. Lepeophtheirus natalensis n. sp.
Female in dorsal view.

short plumose seta at outer distal angle, and at midpoint of posterior margin.
Endopod 2-segmented, basal segment bearing fringe of setae on posterior
margin, and tiny spine at outer distal angle. Terminal segment bearing 3 large
plumose setae on posterior margin, and 1 small simple spine and 3 serrate
spines distally, inner 2 each with accessory spinule. 2nd thoracic leg biramous.
Protopodite 2-segmented, basal segment 4 length of 2nd segment, with single
plumose seta. 2nd segment with setal fringe on posterior margin, and simple
spine at outer distal angle. Exopod 3-segmented, basal segment slightly longer
than 2 distal segments together, bearing strong fringed spine at outer distal
angle, single plumose seta at inner distal angle. 2nd segment similarly armed.
Terminal segment with 6 large plumose setae, and 2 short spines. 3rd thoracic
leg biramous, protopodite expanded, exopod 2-segmented, basal segment small,
bearing single plumose seta, terminal segment with 6 plumose setae and single
short spine. Strong bipartite hooked and striated process at base of exopod.
Endopod 2-segmented, basal segment narrow, with single plumose seta,

SOUTH AFRICAN PARASITIC COPEPODA 89

os

SSSI
S

Fig. 13. Lepeophtheirus natalensis n. sp. 9. a. ist antenna; b. 2nd antenna; c. maxilliped; d. oral
cone and Ist maxillae; e. 2nd maxilla; f. sternal furca; g. 1st thoracic leg; h. 2nd thoracic leg;
t. 3rd thoracic leg; 7. caudal ramus; k. 4th thoracic leg.

terminal segment with 6 plumose setae. 4th thoracic leg uniramous,
3-segmented, basal segment slightly shorter than 2 distal segments together, with
single distal plumose seta. Middle segment bearing distal fringed spine.
Terminal segment bearing distally 1 long and 2 short fringed spines. 5th
thoracic legs reduced to 3 setae on each side of genital segment. Caudal rami
very short, rounded, bearing plumose setae.

go ANNALS OF THE SOUTH AFRICAN MUSEUM

Material
6 ovigerous 99 from Carcharinus leucas, from Natal. Holotype S.A.M.
A13054, paratypes S.A.M. A13055. Total length (excluding egg sacs) 5,1—

Remarks

In general shape and proportions the present species most closely resembles
L. insignis Wilson, of the species of the genus known from South Africa. It can,
however, immediately be distinguished from this and all the other South
African species by the 1st maxilla, which is a simple stout spine, and not
bifurcate. Amongst the other species of the genus which possess an undivided
Ist maxilla and an abdomen of a single segment, this species most closely
resembles L. parviventris Wilson, from the North Pacific. It differs from this
species in the greater length of the furcal arms, and in the 1st maxillae which
in the former are bifurcate.

Family Cecropidae
Cecrops exiguus Wilson
(Fig. 14a, 5)
Cecrops exiguus Wilson, 1923: 1, figs 1-15. Yamaguti, 1963: 89. Shiino, 1965: 381, figs 1-4.
Material

7 ovigerous 9° with attached $4, 9 99, 3 gd, from Mola lanceolata, Bantry
Bay, Cape. Total length 2 10,0-13,5 mm, Jf 6,0 mm.

Fig. 14. Cecrops exiguus Wilson.
a. female in dorsal view;
b. male in dorsal view.

ares
ravnernnis mney eae
Thats

SOUTH AFRICAN PARASITIC COPEPODA OI

Previous records

From shark taken off Florida. From Mola mola, Japan.

Remarks

Cecrops exiguus may be easily separated from the more common C. Jatrezllei
being about half the size of the latter species. Differences also exist in the shape
of the dorsal plates of both the male and female. The females of C. exiguus
are pale-ochrous yellow with olive-green ovisacs, while the males are a pale
creamy colour.

Family Euryphoridae
Elytrophora hemiptera Wilson
(Fig. 15a—-d)
Elytrophora hemiptera Wilson, 1921: 4, pl. 2, figs 13-19. Yamaguti, 1963: 103, pl. 123, fig. 2.
Material

1 9 from yellowfin tunny, Thunnus albacares, Table Bay. 1399 from bluefin
tunny, Zhunnus thynnus, 48 km west of Cape Point. Total length 2 7,8 mm,
So 6,1 mm.

Fig. 15. Elytrophora hemiptera

Wilson. a. female in dorsal

mews OO. sternal furca, 9;

c. male in_ dorsal view;
d. sternal furca, ¢.

Q2 ANNALS OF THE SOUTH AFRICAN MUSEUM

Previous records

From Thunnus thynnus, Thunnus albacares, Isurus glaucus, Japan.

Remarks

The status of the male specimens is not absolutely certain. They are to
some extent intermediate in form between E. hemiptera Wilson from Japan and
E. atlantica Wilson from the North Atlantic. The status of this parasite may be
of interest in relation to the status and movements of their hosts in this area.
Their colour when alive is light yellowish with fine reticular brown markings
giving a general appearance of light brown.

Gloiopotes watson Kirtisinghe

Gloiopotes watsoni Kirtisinghe, 1934: 167. Cressey, 1967a: 7, figs 38-39.
Glotopotes auriculatus Barnard, 1957: 11, fig. 8.

Description

2. Carapace longer than broad, half total length. Postero-median lobe of
thorax with 2 anterior and 1 or 2 posterior spines on each postero-lateral
rounded corner. Dorsal plates of 4th thoracic segment completely separate,
ear-shaped. Genital segment with row of 3 spines on either side of dorsal
convexity. Posterior lobes spinulose on inner surface, usually in single row
proximally. Ovate projection on posterior lobes spinose on inner and outer
margins. Abdomen 2-segmented, distal segment about twice length of proximal.
Latter with 4 dorsal spines, distal segment with 10 dorsal spines, 8-10 lateral
spines. Caudal rami elongate, bearing about 11 spines.

g. Carapace longer than broad, slightly less than half total length.
Posterior median lobe of thorax with 2 lateral and 2 posterior spines on each
side. Dorsal plates of 4th thoracic segment completely separate, subtriangular,
with 3-5 spines near posterior margin. Genital segment as broad as long, with
single spine on each side near centre, single smaller spine laterally, 3-4 spines
on each rounded postero-lateral corner. Genital segment projections slender,
elongate, with about 4 spines on inner (dorsal) margin, 7 on outer (ventral)
margin. 3 strong apical spines. Abdomen 2-segmented, proximal segment
half length of distal. Former bearing 2 spines, latter with variable arrangement,
usually 4 or 5. Caudal rami as in 9.

When fresh the general colour of the thorax and abdomen is blue with
purple markings on the dorsal surface. The egg sacs are salmon pink. They
occur most abundantly between the anal fins and around the anus of their
host where they may produce extensive wounds.

Material

Numerous 99 and $4, from black and striped marlin (Makaira indica and
Makaira audax), from Cape.

SOUTH AFRICAN PARASITIC COPEPODA 93

Family Pandaridae
Echthrogaleus torpedinis Wilson
(Fig. 16)

Echthrogaleus torpedinis Wilson, 1907: 371, pl. 21. Yamaguti, 1963: 120, pl. 137, fig. 2. Cressey,

19675: 58, figs 291-294.
Material

3 ovigerous 99, from Torpedo sp., taken west of Slangkop, Cape. Total
length 2 11,4-13,2 mm.
Previous records

From Tetranarce occidentalis, east coast of U.S.A.

Remarks

No differences can be found between the present material and the descrip-
tion given by Cressey (1967).

Fig. 16. Echthrogaleus torpedinis Wilson.
Female in dorsal view.

Family Anthosomatidae
Lernanthropodes natalensis n. sp.
(Fig. 17a—h)
Description
Cephalothorax slightly ventrally flexed, widest posteriorly, rectangular
in lateral view. Trunk narrow, cylindrical, about same width as cephalothorax.

Ist antenna 7-segmented, bearing several setae. 2nd antenna with uncinate
strongly chitinised apical segment, basal segment broadly tapering. Mouth tube

94 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 17. Lernanthropodes natalensis n. sp. a. female in dorsal view; b. 2nd maxilla; c. cephalothorax
in lateral view; d. posterior margin of 3rd thoracic leg ‘sheath’; e. 1st antenna; f. 2nd antenna;
g. ist maxilla; h. 2nd thoracic leg.

CU ing

conical. 1st maxilla biramous, each ramus of single segment tipped with setae.
2nd maxilla 3-segmented, terminal segment armed with 2 rows of short spines,
median segment with distal seta, basal seta broad. Maxilliped 2-segmented,
terminal segment hook-shaped. 1st and 2nd thoracic legs biramous, rami each
of one segment, outer segment broader than inner, armed with 5 short spines,
inner ramus tipped with single seta, papilla external to exopod bearing single
seta. 3rd thoracic legs almost as long as trunk, fused to form broad lamella
completely ensheathing genital segment and abdomen ventrally, leaving
narrow gap dorsally. Lamella with single point posteriorly on each side. 4th
legs inside sheath formed by 3rd legs, biramous, rami fused only at
base, lamellar, protruding beyond sheath. Genital segment spindle-shaped.
Abdomen slightly shorter than genital segment, with pair of lamellar caudal
rami.

SOUTH AFRICAN PARASITIC COPEPODA 95

Material

I ovigerous 9, from Chorinemus tol, Durban. Holotype S.A.M. A13034.
Total length 3,5 mm. Egg sac length 1,7 mm.

Remarks

Three species of the genus Lernanthropodes have been described, viz.
L. cucullus (Bere 1936) and L. chorinemi and L. trachinoti (Pillai 1962a). L. cucullus
has the sheath formed by the grd thoracic legs completely enclosing the genital
segment and abdomen, and 4th thoracic legs, none of which are ventrally
visible. The posterior margin of this sheath is divided into 2 lobes on either
side, unlike the present species, which has only a slight median indication of
subdivision.
L. trachinoti, taken from Trachinotus blochi from India, also has the posterior
margin of the sheath divided into 2 lobes on either side, while the cephalo-
thorax is rectangular, rather than triangular as in the present material.
L. chorinem, recorded from Chorinemus lysan from India, closely resembles the
present species, but several differences make a specific separation seem desir-
able. L. chorinemi, with a total length of 8,2 mm, is considerably larger than
the ovigerous female of L. natalensis (3,5 mm). The evenly rounded posterior
margin of the sheath in Pillai’s species differs from the slightly bilobed condition
in L. natalensis. Several differences exist in the structure of the appendages.
The ist antenna of L. chorinemi has 4 segments, as against the 7 of L. natalensis,
while the 2nd antenna of the Indian species possesses 3 small spines at the base
of the terminal segment, not found in the present species.

Lernanthropus corniger Yamaguti

(Fig. 18a, b)

Lernanthropus corniger Yamaguti, 1954: 387, pl. 4, figs 35-39, pl. 5, figs 40-41; 1963: 148, pl. 161,
fig. 1. Pillai, 1963: 660, fig. 3.

Material

II Ovigerous + 10 99, total length (from ‘horns’ to end of dorsal plate)
3,4-3,7 mm. From Caranx djedaba, Durban.
Previous records

On Megalaspis sp., from Macassar, and on Megalaspis cordyla from
Trivandrum, India.
Remarks

No differences can be detected between the present material and Yama-
guti’s descriptions and figures. The ventro-lateral extensions of the head
forming the prominent ‘horns’, and the 3 ventral lamellae of the 3rd legs,
make this species unmistakable.

96 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 18. Lernanthropus corniger Yamaguti. a. female in dorsal view; b. female in ventral view.

Lernanthropus ecclesi n. sp.
(Figs 1ga—c, 20a—1)
Description

2. Body somewhat cylindrical, head separated by constriction from rest
of body, slightly less than } total length. Dorsal plate situated posteriorly,
slightly wider than rest of body, posterior margin variable, evenly rounded
to very slightly bilobed. 1st antenna and bases of 2nd antenna dorsally visible.
Ist antenna 7-segmented, terminal segment shortest, with 4 blunt spines.
2nd antenna 2-segmented, basal segment curved, tapering, terminal segment
shorter, strongly falcate. 1st maxilla 3-segmented, terminal segment conical,
basal segment with 2 broad spines distally. 2nd maxilla 3-segmented, terminal
segment with 2 rows of blunt teeth and blunt spine on inner margin, middle
segment with single distal spine. Maxilliped 2-segmented, basal segment
broad, terminal segment shorter, tapering distally with falcate striated process
and short blunt spine. 1st thoracic leg biramous, exopod of 1 segment, bearing
5 blunt distal spines, endopod of 1 segment, bearing elongate blunt distal spine.
Tiny papilla-like process at base of endopod. 2nd thoracic leg biramous,
exopod of 1 segment, bearing 4 short distal spines, tiny papilla bearing single

SOUTH AFRICAN PARASITIC COPEPODA 97

eit

Be

Rey RS
eee
==
==
=—s=
=—=
ap ph ==
==

Fig. 19. Lernanthropus ecclesi n. sp. a. female in dorsal view; 6. female in ventral view; c. male in
dorsal view.

seta at base of exopod. Endopod of 1 segment, bearing single terminal spine.
3rd legs lamellar, uniramous, much shorter than 4th legs. Latter biramous,
inner ramus slightly longer than outer, both lamellar with long tapering apex.
5th leg of single lamella, not dorsally visible. Caudal rami similar in form to
5th legs.

3. Slightly more than } length of 9, body slender. 1st antenna dorsally
visible, structure as in 9. 2nd antenna 2-segmented, basal segment broadly
tapering, with tiny spine on inner face near base, terminal segment short,
with strong striated falcate distal process, and short blunt spine at midpoint.
Mandible slender, apex with 7 denticles. 1st and 2nd maxilli and maxilliped
as in 9. 1st thoracic leg biramous, exopod of 1 segment, with 5 short distal
spines. Endopod 1-segmented, with slender bristled seta, 2nd thoracic leg
biramous, exopod distally expanded, bearing 3 submarginal spines, endopod
shorter than exopod, armed with short bristles and terminal fringed seta. 3rd
thoracic leg biramous, outer ramus about twice length of inner. 4th legs
biramous, rami subequal, lamellar. 5th legs absent. Caudal rami short, slender.

98 ANNALS OF THE SOUTH AFRICAN MUSEUM

DING

Fig. 20. Lernanthropus ecclesi n. sp. a. 2nd antenna, 9; 6. 1st antenna, 9; c. maxilliped, 9; d. 3

variations in the posterior margin of the dorsal plate, 9; e. mandible; f. 1st maxilla; g. 2nd

maxilla; A. 1st thoracic leg, 9; 1. 2nd thoracic leg, 9; 7. 2nd antenna, g; k. 1st thoracic leg, 3;
/. and thoracic leg, g.

Material

9 ovigerous + 2 99, 5 with attached ¢¢ + 2 $4, from yellowtail, Seriola
lalandi, Kalk Bay. Holotype and allotype S.A.M. A13jo021, paratypes S.A.M.
A13057. Total length 9 7,8 mm, ¢ 3,4 mm.

Remarks

Wilson (1932) described Lernanthropus paenulatus taken from Seriola lalandt
from Woods Hole, U.S.A. Undoubtedly, the present material, taken from the
same host, is closely related to Wilson’s species, but some differences do exist.
The female of L. paenulatus, at 9,5 mm, is somewhat larger than L. ecclest

SOUTH AFRICAN PARASITIC COPEPODA 99

(6,9-7,3 mm), while the male (2,5 mm) is smaller (3,0-3,3 mm). The dorsal
plate almost completely conceals the 4th legs in the American species while
in the present material the 4th legs are dorsally conspicuously visible, while
the tips of the 5th legs can also be seen. The 1st maxilla of the female of L. ecclesi
is more slender, and armed with a single terminal and 2 subterminal spines,
while in L. paenulatus the 1st maxilla has 2 terminal spines, plus another one
third the length from the base. The 2nd leg of the female of L. ecclesi lacks
the heel-like structure found in L. paenulatus while the male of the latter species
lacks a spinose exopod, as found in L. eccles:. These subtle differences may
reflect differences within separate populations of the same species, or may
indicate a specific separation. It would be of interest in this respect, to ascertain
the amount of contact between the American and South African populations
of the host species. Until more material becomes available, it would seem best
to separate the present species.

Lernanthropus sarbae n. sp.
(Figs 21a—c, 22a-1)

Description

Q. Head } total length. 2nd thoracic segment forms ‘neck’. 3rd thoracic
segment fused with 4th and genital segment, segments indicated by slight
lateral indentations. Dorsal plate forms large almost circular shield posteriorly.
Genital segment with small lateral knob at point of attachment of egg sacs.
Abdomen small, rounded. Ist antenna dorsally visible, indistinctly 7-segmented,
with 8 or g terminal setae. 2nd antenna 2-segmented, basal segment about
twice length of terminal segment, broadly tapering, terminal segment short,
with stout striated apical process. 1st maxilla bilobed, inner lobe short, with
single terminal spine, outer lobe elongate, with 2 terminal spines. 2nd maxilla
3-segmented, terminal segment short, armed with numerous spines, median
segment slender, with single distal spine. Maxilliped 2-segmented, basal
segment with tiny spine on inner surface, distal segment short, with hooked
terminal process. 1st leg biramous, exopod consisting of single segment with
5 strong terminal spines, endopod of single segment and distal bristled spine,
short setose process at base. 2nd leg biramous, exopod of single segment with
4 distal spines, endopod of single segment. 3rd legs lamellar, curved ventrally.
4th legs consisting of 2 elongate slender processes, fused basally for short
distance. 5th leg consisting of tiny digitiform process. Caudal rami short,
tapering.

3. Slightly shorter than 9, head about # total length. 1st antenna as in Q.
2nd antenna 2-segmented, basal segment broadly tapering, with 2 blunt
processes on inner surface near base. Distal segment short, with strong striated
falcate process terminally, and short spine on inner margin. 1st and 2nd
maxilli as in 9. Maxilliped 2-segmented, basal segment broad, with tiny spine

100 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 21. Lernanthropus sarbae n. sp. a. female in ventral view; 6. female in dorsal view; c. male in
dorsal view.

on inner margin, terminal segment short, with curved striated distal process,
with short spine on inner margin. rst thoracic leg as in 2. 2nd thoracic leg
biramous, exopod somewhat expanded, endopod of single tapering bristled
segment, bearing short terminal seta. 3rd thoracic leg situated laterally,
biramous, inner ramus shorter than outer. 4th legs as in 9. Caudal rami
elongate, almost equal in length to genital segment and abdomen.

Material

I ovigerous + 1 9, 1 3, from Rhabdosargus sarba, Durban. Holotype and

allotype S.A.M. A13020, paratype S.A.M. A13056. Total length 2 3,0 mm,
Goan iii:

SOUTH AFRICAN PARASITIC COPEPODA IOI

Fig. 22. Lernanthropus sarbae n. sp. a. 1st antenna, 9; b. 2nd maxilla, 9; c. maxilliped, 9; d. 2nd
antenna, 9; e. 1st maxilla, 9; f 1st thoracic leg, 9; g. 2nd thoracic leg, 9; h. 2nd antenna, 3;
1. and thoracic leg, 3.

Remarks

The present species falls into the group characterized in the female by the
possession of a large almost circular extension of the dorsal plate, the curved
lamellar 3rd legs, and very elongate rami of the 4th legs, which are fused
basally for a short distance. This group includes L. amplitergum Pearse, L. kroyeri
Van Beneden, L. giganteus Kroyer, L. chrysophrys Shishido, L. latis Yamaguti,
L. eddiwarnert Delamare-Deboutteville & Nunés-Ruivo, L. rathbuni Wilson, and
L. opisthoptert Pillai.

L. amplitergum differs from the present species in the possession of a posteri-
orly notched dorsal plate in the female, while the 3rd legs of the male have
both rami of equal length. L. kroyeri possesses a more rounded cephalothorax
than the present species, and the rami of the 4th legs in both the female and
male relatively shorter. L. giganteus in the female possesses dorso-lateral exten-
sions of the dorsal plate, above the bases of the 3rd legs. The 3rd legs of the

102 ANNALS OF THE SOUTH AFRICAN MUSEUM

male have the rami very unequal, the inner one being a mere papilla. L.
chrysophrys is very similar to the present material, but has postero-lateral
extensions of the cephalic shield, and a 2nd maxilla rather more spinose.

L. latis in the female has the rami of the 4th legs relatively shorter than
in the present species, and these possess at their tips a spine-covered knob. In
the male, the 3rd and 4th legs are relatively shorter and also possess spinose
apices. There is also a considerable difference in size between the species.

L. eddiwarneri in the female possesses a more squat body than in the present
species, and a posteriorly notched dorsal plate, while the abdomen is not
dorsally visible.

L. rathbuni in the female has a distal spine on the penultimate segment
of the 2nd maxilla and relatively stout caudal rami, and the inner ramus of
the 1st legs armed with bristles.

L. opisthoptert in the female is a squatter animal and has the carapace
extended forward to form 2 rounded lobes. ‘The 4th legs are more slender than
the present species while the 2nd antenna possesses 3 spines, and the 2nd
maxilla possesses 2 spines on the middle segment, unlike the present species.

Family Eudactylinidae
RKroyerta carchariaeglauct Hesse

(Fig. 23a—c)

Kroyeria carchariaeglauca: Delamare-Debouteville & Nunés-Ruivo, 1953: 209, fig. 4
Yamaguti, 1963: 162, pl. 187, fig. 2.

Material

15 ovigerous 99 + 4 d¢ from Prionace glauca, False Bay.
Total length 9 6,3 mm, 35,5 mm.
Previous records

From Prionace glauca W. Pacific, Mediterranean, N.E. America, and from
Carcharias milberti and Galeus glaucus, Martha’s Vineyard, N.E. America.
Remarks

The present material agrees well with the above descriptions and figures;
the only detectable difference is that the abdomen is not obviously segmented.

Nemesis lamna Risso
(iicsee7))
Nemesis lamna: Wilson, 1932: 461, pl. 32. Yamaguti, 1963: 167.
Description

2. Body elongate, cephalothorax longer than broad, with lateral indenta-
tions. 4 free thoracic segments more or less of equal length and breadth, with
deep gaps between them. Genital segment broader than long, about one-fifth

SOUTH AFRICAN PARASITIC COPEPODA 103

Fig. 23. Kroyeria carchariaeglauci Hesse. a. female in dorsal view; 5. 2nd
maxilla, 2; c. 4th thoracic leg, 9.

Fig. 24. Nemesis lamna Risso. Female in
dorsal view.

104 ANNALS OF THE SOUTH AFRICAN MUSEUM

length of preceding free thoracic segment. Abdomen 2-segmented, distal
segment longer than proximal segment. Spermatophores spherical, almost

black.

Material
Numerous ovigerous 99, length up to 11 mm, from gills of Carcharodon
carcharias from False Bay, Cape.

Previous records

From Mediterranean, eastern U.S.A., California, Japan, Argentina, on
sharks of the genera Alopias, Carcharias, Carcharodon, Cetorhinus, Isurus, Odontasprs,
and Oxyrhina.

Remarks

The greater length, the very obvious lateral indentations, and the width
of the 5th free segment immediately distinguish this species from WV. pallida,
the other species recorded from this area.

Family Pseudocycnidae
Pseudocycnoides rugosa n. sp.

(Figs 25a, b, 26a—)
Description

Ist thoracic segment fused with carapace. Latter shield-like, anteriorly
narrowed, ist antenna dorsally visible. 2nd thoracic segment well-defined,
3rd and 4th segments less-well defined, fused with genital segment. 2nd, 3rd
and 4th segments each with blunt lateral process. 5th segment indicated only
by single lateral seta. Genital segment cylindrical, 5 times longer than wide.
Abdomen short, bearing blunt distal spine. 1st antenna g-segmented, with
large blunt spine on 3rd segment. 2nd antenna 3-segmented, terminal segment
strongly hooked, bearing proximally a small hook, and single strong median
spine. Oral tube conical, flanked by 1st maxillae. Latter 2-segmented, terminal
segment spine-like, base rounded. 2nd maxilla exterior to 1st maxilla,
3-segmented, basal segment broad, twice thickness of median segment, latter
distally curved, terminal segment short, serrate. Maxilliped 2-segmented,
basal segment very broad, roughly oval, outer surface rugose, bearing fleshy
rugose process anteriorly, terminal segment slender, strongly hooked, folding
against inner surface of fleshy process of basal segment. 2nd thoracic segment
with dorso-lateral rounded fleshy process, ventral to which, a large rounded
lobe, somewhat rugose, bearing tiny lobe medially. Latter bears 2 single
segments representing biramous leg. Outer ramus of latter bearing 2 short
terminal spines, inner bearing 2 curved spines. 3rd thoracic segment similar
to 2nd, but rudimentary leg uniramous, bearing strong terminal spine, plus

SOUTH AFRICAN PARASITIC COPEPODA 105

Fig. 25. Pseudocycnoides rugosa n. sp. 9. a. female in dorsa view; 6. anterior region of female in
ventral view.

2 more slender spines. No trace of 4th legs, 4th thoracic segment marked by
dorso-lateral process.

Material

4 ovigerous 99 from Scomberomorus maculatus gills, Durban. Holotype
S.A.M. A13058, paratypes S.A.M. A13059. Total length ranging from 5,5 mm
to 6,0 mm. Colour red when fresh.

Remarks

The following characteristics of the female place the present material
in the genus Pseudocycnoides: Head fused with 1st thoracic segment, 2nd thoracic
segment free, 3rd and 4th segments fused with genital segment, marked by
lateral digitiform processes, basal segment of maxilliped with large fleshy
process, 1st thoracic legs very reduced, biramous, 2nd legs uniramous, 3rd
legs lacking. Two species of this genus have been described, viz. P. scomberomori
(Yamaguti 1939), and P. armata (Bassett-Smith 1898).

106 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 26. Pseudocycnoides rugosa n. sp. 9. a. Ist antenna; 6. 2nd antenna; c. 1st maxilla; d. 2nd
maxilla; e. maxilliped; f. apex of caudal ramus; g. abdomen; h. ist thoracic leg; 7. 2nd thoracic

leg.

P. armatus possesses a 6-7 segmented 1st antenna which lacks a proximal
process, whereas the present species has an 8-9 segmented Ist antenna with
proximal process. The former species possesses a slightly rugose maxilliped,
with a tooth on the inner margin of the terminal segment, and a small fleshy
process on the basal segment. The present species has a very rugose maxilliped,
lacks the tooth on the terminal segment, and has a much larger fleshy process.

Family Lernaeoceridae
Lernaeeniscus gonostomae n. sp.
(Fig. 27a—-h)
Description

Head with 2 lateral unbranched horns, each with bulbous base, tapering,
curved, apically pointed. Proboscis large, cylindrical, springing from bases of
horns, dorsally with 1st and gnd antennae, distally narrowed. 1st antenna

SOUTH AFRICAN PARASITIC COPEPODA 107

Uy,

Sette’ '
Nii Wand Raa WMS KT,

Fig. 27. Lernaeeniscus gonostomae n. sp. 2. a. female; b. head region further enlarged; c. 1st antenna;
d. 2nd antenna; e. 1st maxilla; f. 2nd maxilla; g. 3rd thoracic leg; A. 1st thoracic leg.

indistinctly segmented, bearing several elongate plumose setae, 2 of which
longer than appendage itself. 2nd antenna 2-segmented, apically strongly
chelate. 1st maxilla simple, 2-segmented, with 2 terminal setae. 2nd maxilla
indistinctly 3-segmented, terminally with flattened hook bearing fine striations
on inner surface. Median segment with 2 patches of very fine setae. 4 pairs

108 ANNALS OF THE SOUTH AFRICAN MUSEUM

of thoracic legs present on ventral surface just below horns. Ist 2 pairs biramous,
posterior 3 pairs uniramous. Ist and 2nd thoracic legs with broad protopodite,
exopod 2-segmented, basal segment with single plumose seta on inner margin,
distal segment with 2 fringed spines and 5 plumose setae. Endopod 2-segmented
basal segment unarmed, distal segment with 7 plumose setae. 3rd and 4th
thoracic legs uniramous, rami 2-segmented, distal segment with 5 plumose
setae and single fringed spine. Neck equal in length ro slightly longer than
trunk, buried to its base in host, cylindrical. ‘Trunk more or less cylindrical,
with very short abdominal region. Egg sacs elongate.

Material

3 ovigerous 99 from mesopelagic Gonostoma elongatum, 26° 30’ S, 33° 40’ E.
Holotype S.A.M. A11751, paratypes S.A.M. A13091, Argr7gsienenon
trunk 8,5-10,8 mm; neck length approximately 11,0-14,0 mm.

Remarks

As several descriptions and figures of species described in the nineteenth
century are not available, new specific status is given the present species with
some trepidation. L. cerberus Leigh-Sharpe possesses horns similar to the present
species, but also has a blunt dorsal horn not found in the present species.
L. gonostomae closely resembles L. spratta (Sowerby) but does not possess a
moniliform neck region, while the proboscis is much larger than in the latter
species. L. radiatus (Le Sueur) is variable with regard to the number of horns,
and has been recorded with 2 (Wilson 1917: 60). These horns, however, are
blunt, as they are not used for actual attachment, but merely for anchoring.
Several other differences, including the length of the abdominal region, the
segmented nature of the Ist antenna, and the maxilliped separate L. radiatus
from the present material.

L. anchoviellae Sebastian & George, 1964, resembles the present species to
some extent. The ‘neck’ of the former species, however, is longer, compared
to the length of the trunk, while the head possesses 2 blunt postero-dorsal
horns, rather than the 2 tapering and more elongate horns of L. gonostomae.
The abdominal region of the latter is hardly developed, while L. anchoviellae
possesses a moderately elongate and tapering ‘abdomen’.

Peniculisa furcata (Kroyer)

(Fig. 28a-e)
Peniculisa furcata: Leigh-Sharpe, 1934: 28, fig. 26. Shiino, 1956: 602. Yamaguti, 1963: 203,
pl. 224, fig. 3.
Description

Body elongate, cephalothorax oval, irregular band of black pigment
stretching from cephalothorax, through trunk, into posterior processes. 2nd
antenna stout, bearing strongly curved hook shielded by disc-like expansion.

SOUTH AFRICAN PARASITIC COPEPODA 109

Maxilliped 3-segmented. Four pairs of thoracic legs present, first 3 pairs
dorsally visible, 4th pair at proximal end of genital segment. Each leg very
reduced, consisting of single short lobe folded on itself with minute hook at
apex. Genital segment bearing 2 elongate parallel processes, at least two-thirds
length of trunk. Abdomen very short with rounded posterior processes. Caudal
rami consisting of minute laminae bearing 4 short setae. ‘Trunk with short
lobe ventrally, at base of elongate processes. Egg sacs originate just below
short lobes.

Material

6 ovigerous + 1 non-ovigerous 99, length range from 2,1 mm to 3,0 mm.
On Paramonacanthus barnardi, Inhaca Island, Mocgambique.

Fig. 28. Peniculisa furcata (Kroyer).
a. female in dorsal view; 6. 2nd
antenna, 9; c. maxilliped, 9; d. Ist
thoracic leg, 9; e. genital segment
and abdomen in ventral view, 9.

12 0) ANNALS OF THE SOUTH AFRICAN MUSEUM

Previous records

On Ostracion punctatus, from Indonesia. On Holacanthus sp., from Indian
Ocean. On Tetrodon sp., from Ceylon.

Remarks

The present material differs from descriptions of P. furcata only in the
possession of the short ventral lobes and the tiny hook at the base of the legs.

Family Pennellidae

Pennella sp.
Material

Numerous 99, from Sei, Fin, and Sperm whales from Donkergat Whaling
Station, Saldanha Bay.

Remarks

Most of the present material possesses 3 horns, of varying length, on the
head. The head in most cases agrees well with the figures given by Delamare-
Deboutteville & Nunés-Ruivo (1953) and Barnard (1955a) for P. crassicornis.
The proportion of head length to trunk length is also very variable. In some
specimens the neck is about 14 times the trunk length, while in others it is
up to twice the length of the neck. Using the characters given by Wilson (1917)
some of these specimens would agree with P. balaenopterae, while others would
agree with P. crassicornis.

A morphometric study of this collection was made in collaboration with
Dr P. Best, who collected the specimens. The total length and the lengths of the
lateral and nuchal horns, neck, trunk, abdomen, and egg strings were measured.
The material appeared to separate into groups but with considerable overlap
between them. The groups did not appear to be related either to the variations
of head morphology or to the species of their host. Type specimens of species
described by Quido were borrowed from the Paris museum for comparison
but they could not be satisfactorily related to the present material. No specific
status will be given to the present material until a reliable method of distinguish-
ing the species has been established.

Order LERNAEOPODOIDA
Family Lernaeopodidae
Brachiella lithognathae n. sp.

(Fig. 29a-g)

Description

?. Cephalothorax slender, elongate, with slight bulge at base on either
side. Ist antenna 4-segmented, terminal segment bearing 3 spines and a blunt
projection. 2nd antenna biramous, outer ramus overhangs inner, apically

SOUTH AFRICAN PARASITIC COPEPODA III

rounded and slightly roughened. Inner ramus 2-segmented, apically bearing
rounded lobe armed with minute spines, and cluster of 6 large spines. Ist
maxilla distally with 2 lobes each bearing stout seta. Palp short, bearing 2
stout seta. Mandible with 6 teeth. Maxilliped apically with strong claw and
strong subapical claw, spinose pad on basal segment. 2nd maxillae stout, about
one-quarter length of cephalothorax, separate, fused at tips. Trunk roughly
rectangular, genital process a rounded papilla. 2 small posterior processes
present.

dg. Cephalothorax with carapace much shorter than trunk, latter broadly
rounded, 2nd maxilla and maxilliped large, prehensile. Length 0,6 mm.

Fig. 29. Brachiella lithognathae n. sp. a. female; 6. male; c. 1st antenna, 9; d. 2nd antenna, 9;
e. Ist maxilla, 9; f. maxilliped, 9; g. posterior genital segment in ventral view, 9.

2 ANNALS OF THE SOUTH AFRICAN MUSEUM

Material

2 ovigerous 99 from Lithognathus lithognathus, Milnerton, Cape. 3 ovigerous
09 from Lithognathus aureti, Rocky Point, S.W.A. Holotype and allotype S.A.M.
A13030, paratypes S.A.M. A13060, A1r1792.

Remarks

Of the species of Brachiella possessing a relatively elongate cephalothorax
and 2 tiny posterior processes on the trunk, the present species most closely
resembles B. exigua Brian, recorded from Pagellus erythrius from the Mediter-
ranean, from Dentex vulgaris from Mauritania, and from Merluccius sp. from
the Dry Tortugas. The most obvious differences between these 2 species lies
in the size, as the table illustrates. Further differences exist in the 2nd antennae,
which in the present species is not as spinose distally as in B. exigua, and in the
maxilliped which lacks the strong subapical spination of B. exigua.

B. exigua B. lithognathae

cephalothorax be 1,90 mm 4,0 mm
trunk Oe: et 1,47 mm 3,0 mm
egg sacs A ae 1,90 mm 5,2 mm

Dimensions for B. exigua taken from Nunés-Ruivo (1954).

Lernaeopoda etmopterr Yamaguti

(Fig. 30a-f)
Lernaeopoda etmopteri Yamaguti, 1939: 549, pl. 44, figs 104-106. Shiino, 1956: 275, figs 4, 5.
Description

Cephalothorax with dorsal carapace, short, in line with trunk. Latter
pear-shaped, 34-4 times length of cephalothorax. No distinct neck. No genital
process, but 2 sausage-shaped posterior processes present, with a pair of tiny
spiniform processes between them. Ist antenna 4-segmented, with 4 terminal
setae. 2nd antenna biramous, outer ramus distally rounded, inner ramus
indistinctly 2-segmented, distally bilobed, both lobes bearing spines. Mandible
with 7 teeth. 1st maxilla distally trilobed, each lobe ending in single stout seta,
palp some way below trilobed apex, bearing 3 spines. 2nd maxilla very elongate
slender, twice length of trunk, corrugated, distally fused only at tips, bulla
small. Maxilliped strongly subchelate, apex strongly hooked, inner margin of

basal segment with large finely spinose pad distally, smaller spinose pad
proximally, and short spine.

Material

2 ovigerous 99 (one with posterior processes detached) from shark,
Etmopterus sp., taken west of Cape Point, in 450 metres. Length of cephalo-
thorax + trunk 12,6 mm, 8,0 mm. Length of 2nd maxilla 22,0 mm, 8,0 mm.

SOUTH AFRICAN PARASITIC GCOPEPODA I13

e d

Fig. 30. Lernaeopoda etmopteri Yamaguti. a. female; 6. mandibular apex; c. ist antenna, 9; d. 2nd
antenna, 2; ¢. 1st maxilla, 9; f, maxilliped, &.

Previous records

On Etmopterus lucifer, from Japan.

Remarks

The present material agrees well with both Yamaguti’s and Shiino’s
descriptions, especially with regard to the appendages. Slight differences do
exist. The 2nd maxilla of the present material is far more elongate than that
figured by Shiino. The Japanese material, however, is described as wrinkled;

114 ANNALS OF THE SOUTH AFRICAN MUSEUM

possibly the 2nd maxillae were contracted, while in the present material they
are fully relaxed. The somewhat lobose appearance of the trunk as figured
by Shiino may also be due to contraction.

Schistobrachia ramosa (Kroyer)

(Fig. 31)
Schistobrachia ramosa (Kroyer), Kabata, 1964: 99.
Charopinus ramosus: Scott & Scott, 1913: 191, pl. 55, figs 6, 7. Yamaguti, 1963: 253, pl. 272,
9% Bs :
Material

3 ovigerous 99 from Raza batis, Table Bay. Total length approximately
g,0 mm.

Previous records

On Raza clavata and R. maculata, from Irish and North Sea. On R. radiata
from Iceland and Barents Sea. On R. scabrata from Canada.

Fig. 31. Schistobrachia ramosa (Kroyer). Female.

SOUTH AFRICAN PARASITIC COPEPODA el

Remarks

The 2nd maxillae, which are distally fused, and each split into 2 slender
‘fingers’ easily identify this species. This would seem to be the first record
of the species from the Southern Hemisphere.

Clavellisa cf. ilishae Pillai

(Fig. 32a-f)
Description

Cephalothorax extremely elongate, slender, of uniform thickness. Trunk
regularly oval, twice as broad as long. Ist antenna indistinctly 3-segmented,
armed with 7 setae. 2nd antenna biramous, outer ramus broadly rounded,
bearing 3 setae, inner ramus shorter and more slender than outer, with 4

Big, 32. Clavellisa’ ch. ilishae Pillai.
@etemale; 6. maxilliped; 9; ¢. and
antenna, 2; d. ist antenna, Q; e. Ist
maxilla, 2; f. trunk and 2nd maxillae, 9.

116 ANNALS OF THE SOUTH AFRICAN MUSEUM

apical setae. 1st maxilla with 3 terminal curved spines, palp with 2 curved
spines. 2nd maxillae springing from trunk, some distance from base of ‘neck’,
separate, but apically fused into bulla. Maxilliped 2-segmented, terminal
segment curved, with strong apical hook and numerous short spines on inner
margin, bearing one strong seta. Egg sacs globular, with small prominence
between them, representing fused anal laminae.

Material
3 ovigerous 99 from gills of Sardinops ocellata, False Bay.
Dimensions: breadth of trunk 22) Toman 0,8 mm 0,8 mm
Sue SES a .. 64mm 0,3 mm | o,onm
cephalothorax length HO worn = A, semiaan 1,5 mm
Remarks

The present material closely resembles C. ilishae described from Ilisha
filigera and Euplatygaster indica from India. The dimensions and appendages
agree well with Pillai’s description (1962:79), while a few differences do exist.
The egg sacs of the present material are spherical, while C. ilishae possesses
pyriform sacs. The present material also lacks the 2 pairs of tubercles, each
bearing a seta, on the anterior border of the trunk, as well as the cylindrical
process adjacent to the anal laminae. These differences hardly seem to warrant
the erection of a new species.

Clavellopsis appendiculata Kirtisinghe

(Fig. 33a-c)
Clavellopsis appendiculata Kirtisinghe, 1950: 84, figs 40-43. Pillai, 19685: 129, figs 7, 8.
Tsobranchia appendiculata Heegaard, 1947: 239, figs 1-4. Yamaguti, 1963: 260, pl. 287, fig. 1.

Description

°. Cephalothorax cylindrical, elongate, dorsally flexed. 2nd maxillae
completely fused, bulla cup-like. Trunk pear-shaped, slightly dorso-ventrally
flattened. 2 dorsal posterior processes situated laterally, 2 ventral processes
situated closer to midline. 1st antenna 4-segmented, bearing 3 terminal setae
and single short spine. 2nd antenna biramous, outer ramus apically rounded,
inner ramus of 1 segment with single apical spine. Maxilliped subchelate, with
strong terminal hook-like claw, and serrated region on inner basal area. Basal
segment with short spine on inner margin.

g. Ist antenna 3-segmented, with 3 terminal setae and 1 short spine.
and antenna biramous, inner ramus 4-segmented, terminal segment with large
curved spine, smaller accessory spine, and row of tiny curved spines. Outer

ramus indistinctly 3-segmented, terminal segment rounded, bearing single
short spine.

SOUTH AFRICAN PARASITIC COPEPODA tL)

Material

2 ovigerous 99, 1 ¢ from Chirocentrus dorab, Durban. 2 length cephalothorax
2,0 mm, length trunk + posterior processes 3,6 mm.

Previous records

From Chirocentrus dorab, Iranian Gulf.

——w))

Fig. 33. Clavellopsis appendiculata Kirtisinghe. a. female; b. 1st antenna, ¢; c. 2nd antenna, d.

Family Naobranchiidae

Naobranchia pritchardae n. sp.

(Fig. 34a-c)
Description

Cephalothorax elongate, slender, only slightly longer than distance from
base of cephalothorax to tip of egg sacs. Head demarked by slight constriction.
Ist antenna indistinctly 3-segmented with stout apical spine. 2nd antenna
bilobed, each ramus consisting of single segment with distal spine. Maxilliped
2-segmented, terminal segment a strong curved hook with accessory spine and
tiny spine near base. Buccal cone flanked by rounded striated process. Egg sacs
lateral, trunk broad, each side with 3 slender elongate processes embracing
egg sacs, 1 dorsal pair, 1 ventro-lateral pair, 1 ventral pair. Egg sacs extend
both anterior and posterior to oviduct. Abdomen with single pair of slender
caudal rami, enclosed in membranous sac, which also encloses egg sacs and
trunk processes. Abdomen situated at about midpoint of length of egg sacs,

118 ANNALS OF THE SOUTH AFRICAN MUSEUM

deep notch between latter. 2nd maxillae form 2 basally fused bands, on ventral

surface of trunk.

Material
2 ovigerous 99, from Pomadasys operculare, Durban. Holotype, S.A.M.
A13042, paratypes S.A.M. A13063. Total length 4,0 mm, cephalothorax

length 2,0 mm.

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Fig. 34. Naobranchia pritchardae n. sp. a. female in lateral view; b. dorsal view of trunk, 9;
c. maxilliped, 9.

Remarks

Of the 15 known species of the genus Naobranchia, the present material
most closely resembles three species described by Nunés-Ruivo, in 1963, viz.
N. pagelli, N. sargi and N. smaridis. These three species from West Africa,
as with the present species, possess 3 pairs of processes on the trunk. WV. pagelli,
does not possess a posterior notch between the egg sacs, and is about twice
the length of the present species. Neither WV. sargi nor NV. smaridis was an oviger-
ous specimen, and the presence or absence of a posterior notch can thus not be

SOUTH AFRICAN PARASITIC COPEPODA II9g

determined. Neither possesses the strong ‘shoulders’ of WV. pritchardae, while both
are somewhat larger than the latter. They also differ in general proportions.
NV. smaridis has a cephalothorax about twice the length of the trunk, WN. sargi
14 times the length of the trunk, while in the present species the cephalothorax
is less than 14 times the length of the trunk.

The species is named for Dr Mary-Lou Pritchard of the University of
Nebraska, who collected it, along with numerous other parasitic copepods,
for the South African Museum.

Family Sphyriidae
Lophoura elongata n. sp.

(Fig. 35a—-d)
Description

Cephalothorax very elongate, narrow. Neck shorter than cephalothorax,
but of same thickness, bearing lobed and knobbed process distally. Genital
segment flask-shaped, bearing posteriorly a median raised process flanked by
oviduct openings. Single pair of processes bearing numerous sausage-shaped
lobes attached medially to oviducal openings.

Fig. 35. Lophoura elongata n. sp. a. female, specimen A; 6. lobed process further enlarged;
c. female, specimen B; d. lobed process further enlarged.

I20 ANNALS OF THE SOUTH AFRICAN MUSEUM

Material
2 99 from Synaphobranchus bathybius, off Cape Point. Cephalothorax apex
missing in both cases. Holotype S.A.M. A11802, paratype S.A.M. A13064.

Specumen A Specimen B
remains of cephalothorax 47,0 mm —
length of neck nee 23,0 mm 22,0 mm
length of trunk bs 15,0 mm 25,0 mm

Remarks

Of the seven species of Lophoura mentioned and figured by Yamaguti
(1963) the cephalothorax is never more than 10 times longer than wide. In
this character the present material differs markedly, having the cephalothorax
at least 30 times longer than wide. In the structure of the knobbed process
situated at the distal end of the ‘neck’, the present material resembles L.
tripartita and, to a lesser extent, L. edwards: in some of the variations figured by
Nunés-Ruivo (1954: fig. 5). The knobbed process of L. tripartita is spikier and
more branched than the present material (Wilson 1935: fig. 75). L. magna
(Szidat 1971) possesses a relatively short cephalothorax, although the neck
and trunk resemble L. elongata. L. laticervix (Hewitt 1964) has a short, stout
neck, while the knobbed process at the base of the cephalothorax resembles
the present material to some extent.

SUMMARY

A systematic account of South African parasitic Copepoda is given which
supplements and revises earlier work. A catalogue of all the species of parasitic
Copepoda in the South African Museum is provided. Full descriptions and
figures are given of species new to science and descriptions are also given of
species newly recorded from South Africa. The following new species are
described: Gunenotophorus blaizei, Caligus penrithi, Lepeophtheirus lalandei, Lepeoph-
theirus natalensis, Lernanthropodes natalensis, Lernanthropus ecclesi, Lernanthropus
sarbae, Pseudocycnoides rugosa, Lernaeeniscus gonostomae, Brachiella lithognathae,
Naobranchia pritchardae and Lophoura elongata.

ACKNOWLEDGEMENTS

We thank the many collectors of specimens who made the present work
possible. We are particularly grateful to Dr Mary-Lou Hanson Pritchard who
collected most of the material described here. We are grateful to Dr P. A. Hulley
for checking the names of host fishes in this paper. We thank the South African
Council for Scientific and Industrial Research for grants to the second author
enabling the employment of Mr Leiserowitz who prepared preliminary
drawings of the material.

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SOUTH AFRICAN PARASITIC COPEPODA 129

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BAssETT-SMITH, P. W. 1898. Some new parasitic copepods found on fish at Bombay. Ann. Mag.
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BERE, R. 1936. Parasitic copepods from Gulf of Mexico fish. Am. Midl. Nat. 17: 577-628.

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Brian, A. 1939. Copépodes parasites recueillis par M. E. Darteville 4 l’?embouchure du fleuve
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Caiman, W. T. 1908. On a parasitic copepod from Cephalodiscus. Mar. Invest. S. Afr. 5: 177-184.

Cressey, R. F. 1967a. Genus Gloiopotes and a new species, with notes on host specificity and
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Cressey, R. F. 19675. Caligoid copepods parasitic on sharks of the Indian Ocean. Proc. U.S.nain.
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DELAMARE-DEBOUTTEVILLE, C. & Nunés-Ruivo, L. 1953. Copépodes parasites des poissons
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DELAMARE-DEBOUTTEVILLE, G. & Nunts-Rutvo, L. 1954. Parasites de poissons de mer ouest
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GNANAMUTHU, C. P. 1948. A new copepod parasite, Clavellisa dussumieriae belonging to the
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HEEGAARD, P. E. 1947. A new lernaeopodid (Isobranchia appendiculata, nov. gen. nov. sp.) from
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Hewrrt, G. C. 1963. Some New Zealand parasitic Copepoda of the family Caligidae. Trans. R.
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Ho, J. S. 1972. South African chondracanthids. Parasitology 65: 147-158.

Inic, P. L. 1958. North American copepods of the family Notodelphyidae. Proc. U.S. natn. Mus.
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KeEnsLey, B. F. 1970. A new species of Caligus from South West Africa (Copepoda, Caligidae).
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KiRTISINGHE, P. 1934. Gloiopotes watseni n.sp. and Lernaeeniscus seeri n.sp. Parasitic copepods of
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130 ANNALS OF THE SOUTH AFRICAN MUSEUM

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INSTRUCTIONS TO AUTHORS

Based on

CONFERENCE OF BIOLOGICAL EDITORS, COMMITTEE ON FORM AND STYLE. 1960.

Style manual for biological journals. Washington: American Institute of Biological Sciences.

MANUSCRIPT

To be typewritten, double spaced, with good margins, arranged in the following order:
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(2) Contents. (3) The main text, divided into principal divisions with major headings; sub-
headings to be used sparingly and enumeration of headings to be avoided. (4) Summary
(5) Acknowledgements. (6) References, as below.

Figure captions and tables to be on separate sheets.

ILLUSTRATIONS

To be reducible to 12 cm Xx 18 cm (19 cm including caption). A metric scale to appear
with all photographs.

All illustrations to be termed figures (plates are not printed; half-tones will appear in their
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REFERENCES

Harvard system (name and year) to be used: author’s name and year of publication given
in text; full references at the end of the article, arranged alphabetically by names, chronologi-
cally within each name, with suffixes a, b, etc. to the year for more than one paper by the same
author in that year. i
For books give title in italics, edition, volume number, place of publication, publisher.

For journal articles give title of article, title of journal in italics (abbreviated according to the

World list of scientific periodicals. 4th ed. London: Butterworths, 1963), series in parentheses,

volume number, part number (only if independently paged) in parentheses, pagination.

Examples (note capitalization and punctuation)

But.toucu, W. S. 1960. Practical invertebrate anatomy. 2nd ed. London: Macmillan.

FiscHER, P.-H. 1948. Données sur la résistance et de le vitalité des mollusques. 7. Conch., Paris
88: 100-140.

FiscHER, P.-H., Duvat, M. & Rarry, A. 1933. Etudes sur les échanges respiratoires des littorines.
Archs Kool. exp. gén. 74: 627-634.

Konn, A. J. 1960a. Ecological notes on Conus (Mollusca: Gastropoda) in the Trincomalee region
of Ceylon. Ann. Mag. nat. Hist. (13) 2: 309-320.

Koun, A. J. 19606. Spawning behaviour, egg masses and larval development in Conus from the
Indian Ocean. Bull. Bingham oceanogr. Coll. 17 (4): 1-51.

THIELE, J. 1910. Mollusca: B. Polyplacophora, Gastropoda marina, Bivalvia. In: SCHULTZE, L.

_ Koologische und anthropologische Ergebnisse einer Forschungsreise im westlichen und zentralen Siid-

Afrika. 4: 269-270. Jena: Fischer. Denkschr. med.-naturw. Ges. Jena 16: 269-270.

ZOOLOGICAL NOMENCLATURE

To be governed by the rulings of the latest International code of zoological nomenclature issued
by the International Trust for Zoological Nomenclature (particularly articles 22 and 51).
The Harvard system of reference to be used in the synonymy lists, with the full references
incorporated in the list at the end of the article, and not given in contracted form in the synonymy
list.
Example

Scalaria coronata Lamarck, 1816: pl. 451, figs 5 a, 6; Liste: 11. Turton, 1932: 80.

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VOLUME 62 PART 4 NOVEMBER 1973

OF THE SOUTH AFRICAN
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CAPE TOWN

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ANNALS OF THE SOUTH AFRICAN MUSEUM
ANNALE VAN DIE SUID-AFRIKAANSE MUSEUM

Volume 62 ~ Band
November 1973 November
Rant « 4) Deel

INTERRELATIONSHIPS WITHIN
THE ANACANTHOBATIDAE
(CHONDRICHTHYES, RAJOIDEA),

WITH A DESCRIPTION OF THE LECTOTYPE OF
ANACANTHOBATIS MARMORATUS
VON BONDE & SWART, 1923

By
P. A. HULLEY

Cape Town Kaapstad

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Court Road, Wynberg, Cape Courtweg, Wynberg, Kaap

INTERRELATIONSHIPS WITHIN
THE ANACANTHOBATIDAE (CHONDRICHTHYES, RAJOIDEA),
WITH A DESCRIPTION OF THE LECTOTYPE OF
ANACANTHOBATIS MARMORATUS VON BONDE & SWART, 1923
By
P. A. HuLLEY
South African Museum, Cape Town

(With 14 figures and 2 tables)

[MS. accepted 5 March 1973]

CONTENTS
PAGE
Introduction . : 5 4 : : , ; ron
Material and methods. f ‘ 5 132
Designation and description of lociasaze of.

Anacanthobatis marmoratus f : ; : ? 132
Pelvic girdle . : : ; 5 BE
Rostral filament and feomiaal sqonielan : : : 7
Pectoral and pelvic fin radials . f : : : 137
Clasper structure . P ; , : : ; 139
Discussion . : : : : ; ; : 147
Key to species : 5 GS
Taxonomic arrangement of the Avacamtnobatces : 152
Summary . : : ; ‘ , . 156
Oganeuiedeerenis: : ; F : . Gy
References. : : : : : : . 158

INTRODUCTION

In 1923 Von Bonde & Swart described two new species of skate, Anacan-
thobatis marmoratus and A. dubius, from off the coast of Natal, South Africa (the
proposed name Lezobatis being preoccupied — Errata Slip, Von Bonde & Swart
1923). The species were included in a separate family Anacanthobatidae, which
was considered to be part of the Masticura (=Myliobatoidea). Because of this
suggested relationship and because of the structure of the teeth and lack of
dorsal fins, Barnard (1925), Fowler (1941) and Smith (1961) included the
genus in the family Dasyatidae. However, Bigelow & Schroeder (1951, 1953,
1962) and Hulley (1972a) consider that the nature of the pelvic fins, the
presence of lateral prepelvic processes on the pelvic girdle and the number
of proximal basal segments in the clasper preclude their incorporation with the
Dasyatidae, and recognize the Anacanthobatidae as a distinct family of the
order Rajoidea. This distinction is supported by the typical rajoid egg case
in Anacanthobatis marmoratus (Wallace 1967).

At present, two genera are recognized within the family, Anacanthobatis

131

Ann. S. Afr. Mus. 62 (4), 1973: 131-158, 14 figs, 2 tables

132 ANNALS OF THE SOUTH AFRICAN MUSEUM

(A. marmoratus, A. longirostris, A. americanus, A. borneensis) and Springeria (S.
foliorostris, S. melanosoma, S. ort), and A. dubius is now considered to be a junior
synonym of A. marmoratus (Bigelow & Schroeder 1962; Wallace 1967). Many
of the initial definitive characters for the genus Springeria (Bigelow & Schroeder
1951) have fallen away with further taxonomic investigation (Bigelow &
Schroeder 1953, 1962; Chan 1965a; Wallace 1967), so that the recognition
of the genus now rests solely on the terminal leaf-like expansion of the snout.

During the course of investigations on the interrelationships of southern
African Rajidae (Hulley 1972a), the claspers of Anacanthobatis marmoratus and
A. americanus were briefly examined by the author. Basic major differences
in the clasper structure suggested that two genera were possibly involved and
that the family Anacanthobatidae, as defined at present, might be diphyletic
and have a comparatively early origin (Hulley 1972a: fig. 57). However, these
conclusions were only tentatively advanced until an investigation could be
extended to other anacanthobatid species. ‘This paper represents the results
of such an investigation.

MATERIAL AND METHODS

Type specimens of the following species were examined: Anacanthobatis
marmoratus (RUSI 662), A. borneensis (BMNH 10965. 1. 29.1), A. longirostris
(USNM 196446), Springerta melanosoma (USNM 198121) and S. ori (ORI B 187,
B 188); and specimens of A. marmoratus (ORI B 2, B 3, B 174, B 202), A.
longirostris (ORE 10827), A. americanus (ORE 10602/SAM 26626) and S.
foliorostris (ORE 10440, 10898) were also examined. X-ray photographs of the
type specimen of Springeria foliorostris (USNM 152546) were supplied by the
United States National Museum.

BMNH=British Museum (Natural History) ; ORE=‘Oregon II’ Station (material at USNM);
ORI=Oceanographic Research Institute, Durban; RUSI—J. L. B. Smith Institute of

Ichthyology, Grahamstown; SAM=South African Museum; USNM= United States National
Museum.

‘The structure of the claspers appears to be the most reliable basis on which
to interpret interrelationships within the Rajoidea (Ishiyama 1958; Stehmann
1970; Hulley 1970, 1972a), so that this method has been employed in the
present study. However, Springeria melanosoma and S. ori are known only from
juvenile females, so that additional criteria have been used.

DESIGNATION AND DEscRIPTION OF THE LECTOTYPE OF
ANACANTHOBATIS MARMORATUS

The type-species Anacanthobatis marmoratus Von Bonde & Swart, 1923 was
based on two syntypes, a female (245 mm total length) and a male (238 mm
total length) both trawled at 30°09, 45'S, 30°58, 02’E in 292,5 m. These
specimens were housed in the collection of the Government Marine Survey,

INTERRELATIONSHIPS WITHIN THE ANACANTHOBATIDAE 133

Cape Town. Unfortunately, this collection was later broken up and a large
proportion of it was lost to posterity. However, during the preparation of his
book Sea fishes of southern Africa, a number of specimens from this collection
was donated to the late Professor J. L. B. Smith, among which was a single
male specimen of Anacanthobatis marmoratus. Smith was informed that this
specimen was the ‘type’ (M. M. Smith, personal communication), and it was
photographed for inclusion in the book (Smith 1961: fig. 84). The female
specimen is missing.

I now designate this male specimen (RUSI 662), housed in the collection
of the J. L. B. Smith Institute of Ichthyology, Grahamstown, as the lectotype
of the species Anacanthobatis marmoratus Von Bonde & Swart, 1923.

Anacanthobatis marmoratus Von Bonde & Swart, 1920
(Fig. 1A, B)

Lectotype

A male (232,9 mm total length), trawled at 30°09, 45'S, 30°58, 02’E in
292,5 m by the S.S. Pickle (Station 152); in the collection of the J. L B. Smith
Institute of Ichthyology (RUSI 662).

Description

Disc from base of rostral filament about 1,2 times as broad as long, its
width 1,5 in total length excluding filament; maximum angle from base of
filament to level of spiracles about 102°; end of snout with rostral filament
arising from small, bluntly-rounded protuberance; anterior margins of disc
concave behind level of protuberance and again at level of spiracles; outer
angles rounded; posterior margins evenly convex. Axis of greatest breadth 1,1
times as far from base of filament as from posterior edge of disc. Tail slender,
about 2,0 in total length from base of filament, with narrow lateral folds
extending to its base.

Skin perfectly naked everywhere and without dermal denticles of any sort,
but with 2 rows of hooked alar spines at outer angles of disc.

Snout in front of orbits 3,8 times as long to base of filament as distance
between orbits; its length in front of mouth 3,9 times as great as distance
between nostrils. Eye 1,7 times as long as spiracles; distance between orbits
I,1 times as great as length of orbit. Rostral cartilage extending to base of
rostral filament as hard bar, without a segment; tip of rostral bar forming
bluntly-rounded protuberance at base of filament. Anterior rays of pectorals
extending almost to rostral appendices.

Mouth slightly arched; nasal curtain fringed; expanded posterior margin
of nostril fringed, and overlapping corners of mouth. Teeth arranged in 29
regular rows in upper jaw, with large round bases and laterally directed, sharp,
posterior cusps.

134 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 1. Anacanthobatis marmoratus Von Bonde & Swart. LECTOTYPE (RUSI 662). A. dorsal
view; B. ventral view.

INTERRELATIONSHIPS WITHIN THE ANACANTHOBATIDAE 135

TABLE I

Anacanthobatis marmoratus. (Lectotype.) Measurements expressed in millimetres and as percentage
of the total length to base of filament. Figures in parentheses refer to Von Bonde & Swart (1923).

mm on

Total length 2 : Si ae Fame 23 2.00230) —
Total length to ses of Semen: oy Sis 230.4, 100,0
Length of filament + oe a ee ae 255 Lt
Disc width oe oe & be oe Seg E5297 (15), (Ont
Disc length ie oF se SO 7 56,7
Snout to greatest fee width oe 2 -. “et IGO55 30,2
Snout to axils of pelvics .. oe oy: Nee SOAs 41,0
Snout length: in front of orbits .. a a ce) OTST 13,5
in front of mouth 4. we 2a) 1 Qies5 13,6
in front of nostrils a Sh =, 26:6 11,5
Eye: horizontal diameter ae at - ae 754 ED
distance between eyes ae - - ae 8,1 355
Spiracle: length .. : i: am ee: 455 1,9
. distance penveer spiracles Ee ae 4. 1956 8,5
Mouth: width... st he a3 15,4 6,7
Nostrils: distance pence: inner ands in a ae E456 6,3
Gill slits: length 1st <. are “fe ee fe 2,1 0,9
grd i = a om ore 2,6 Tel
5th Le = ss 3 Re 2,0 0,9
distance between ist .. oe aie =. 20,6 12,4
Filo oe sf sy Ba) RESO 6,9
Pelvics: length anterior margin .. up ae a2 1360:0 15,6
length posterior margin oF = sa Sey) 14,1
base width Be oe - - rz 8,2 3,6
Caudal fin: upper base length .. a oe ee 752 754
lower base length .. Ae ae e 9,6 4,1
Snout to middle of vent .. y ~ a eg Plk 22 48,3
Middle of vent to tip of tail aE ow Ne ae LIQS2 (129)! 51-7

Pelvics divided into slender, limb-like, anterior lobe, arising separately
from ventral surface of disc, and posterior, fin-like lobe. Posterior lobe free
from inner pectoral margin, but posterior margin joined to tail almost to tip
of fin.

Dorsal fins absent. Caudal fin membraneous, with epiural lobe larger
than hypural lobe.

Colour (in alcohol): dorsal surface irregularly mottled light brown and
white, with scattered ocelli; papillae and rostral filament dark brown. Ventral
surface uniformally pale.

PELvic GIRDLE

The pelvic girdles of Anacanthobatis marmoratus and A. americanus have been
described by Hulley (19722).

In all Rajoidea, the pelvic girdle consists of a simple transverse bar, which
is expanded at the iliac regions and possesses a pair of anteriorly-directed,
lateral prepelvic processes. Paired iliac processes arise posteriorly from the iliac
region, but recurve dorsally to terminate as blunt processes.

The pelvic girdle in the Anacanthobatidae (Fig. 2) is typically U-shaped

136 ANNALS OF THE SOUTH AFRICAN MUSEUM

Meds &
D E
VA De

F G

B

on

Fig. 2. Pelvic girdles of the Anacanthobatidae. A. Anacanthobatis marmoratus (3); B. A. borneensis
(3); C. A. americanus ($); D. A. longirostris ($); E. Springeria foliorostris (3); F.S. ort (2); G.
S. melanosoma (¢). Scale 20 mm.

INTERRELATIONSHIPS WITHIN THE ANACANTHOBATIDAE 137

with the iliac regions considerably more developed than in the Rajidae, and
possesses elongate prepelvic processes. ‘These appear to serve only for the attach-
ment of the abdominal musculature and have no relationship to the musculature
of the anterior, limb-like lobe of the pelvic fin. The three groups of muscles
which are responsible for dorso-ventral movement of the anterior lobe (ventral
muscles of the marginal ray—Frechkop 1925) insert at the bases of the prepelvic
processes. The comparative lengths of the prepelvic processes vary considerably:
Anacanthobatis marmoratus (0,6—0,8 times the girdle width); A. longirostris (0,6-
0,7); A. americanus (0,8) ; A. borneensis (0,6); Springeria foliorostris (0,6—0,8) ; S. ori
(0,8); and S. melanosoma (0,5). In all species, the processes project laterally,
except in Anacanthobatis longirostris and Springeria foliorostris (Fig. 2), in which
the distal extremities recurve medially.

There is a single, large obturatorial foramen on each side in all species.
Sexual dimorphism is exhibited by the girdle, so that the girdle in females has a
comparatively longer ischio-pubic bar. This is probably associated with the
oviparous behaviour of the family.

RosTRAL FILAMENT AND [TERMINAL EXPANSION

The rostral filament and terminal expansion of the snout of all described
anacanthobatid species are illustrated in Figure 3. The rostral filament, which
varies in length intraspecifically, arises from a small, bluntly-rounded protuber-
ance at the anterior extremity of the snout. This protuberance is found in all
species and should not be confused with the terminal leaf-like expansion of the
snout in Springeria foliorostris (Fig. 3E). In this species, the anterior margins
of the disc are markedly constricted against the rostral bar some little distance
behind the protuberance, so as to encompass the rostral appendices, i.e. the
appendices themselves form the expansion. This is not found in either Springeria
ort or S. melanosoma (Figs 3F, G). In these species, only a blunt anterior pro-
tuberance is present. This is formed by the anterior extremity of the rostral
bar in relation to the leading edges of the rostral appendices, and has its
counterpart in all other species of the genus Anacanthobatis (Fig. 3).

PECTORAL AND PELvic FIN RADIALS

Quignard (1965) and Stehmann (1970) have discussed the distribution
of pectoral fin radials in the Rajidae and the taxonomic value of the total
number of radials in each wing. It appears that while the distribution of
pectoral radials may vary intraspecifically and may even vary on opposite
sides of the same individual, the total count may, in some cases be used to
distinguish between closely related species, e.g. Raja oxyrhynchus and &.
nidarosiensis. Furthermore, it appears that this criterion may even be valid at
the subgeneric level in certain instances, e.g. Raja alba (Stehmann 1970: fig. 13).
However, Stehmann (1970) points out that in general natural combinations

138 ANNALS OF THE SOUTH AFRICAN MUSEUM

AXA

4

NO)

Fig. 3. Rostral filament and terminal expansion of the Anacanthobatidae. A. Anacanthobatis
marmoratus; B. A. americanus; C. A. borneensis; D. A. longirostris; E. Springeria foliorostris; ¥.S.
melanosoma; G. S. ori. Scale 5 mm.

INTERRELATIONSHIPS WITHIN THE ANACANTHOBATIDAE 139

of species cannot be recognized by mean values of the count.

To assess the value of this method in the Anacanthobatidae, pectoral and
pelvic fin radial counts were made from X-ray photographs. The results are
presented in Table 2. Since there is no overlap of the pectoral and pelvic fins,
direct counts could be obtained from the plates. This method could not be
applied to Springeria melanosoma and to certain counts in S. 071, due to the poor
degree of calcification of the radial cartilages.

TABLE 2

Pectoral and pelvic radials in the Anacanthobatidae.

No. Total No. No. Total

Species Specimens __ Pectoral Mesopterygial Intercalary Pelvic

A. marmoratus 5 72-78 3-5 II-13 13-18
A. borneensis I 75 4 15 14

A. longirostris 2 88—90 4-5 16-19 14-19
A. americanus I 66 3 gt iD

S. foliorostris 3 87-89 6 16-18 16-19

S. ort I 70 — — 13-14

CLASPER STRUCTURE

A description of the external and internal structure of the claspers of
Anacanthobatis marmoratus and A. americanus has already been given (Hulley
1972a). The terminology of the various components and cartilages of the species
examined in this paper are in accordance with the definitions given by Hulley
(1972a). However, a further term, palp, is now defined:

palp
A fleshy pad, situated in the dorsal lobe of the clasper glans at about the level of the
hypopyle, and lying along the outer lateral margin of the closed glans: with or without a
distal filament; the internal support provided by the distal projection of the dorsal marginal
cartilage.

It should be noted that the component usually associated with the distal
projection of the dorsal marginal is the pseudorhipidion. However, the distinc-
tion between these two components has been made because the pseudorhipidion
extends distally and medially in the glans as a sharp-edged cartilaginous tongue
while the palp extends distally and laterally as a well-developed fleshy pad,
not unlike the foot of a bivalve mollusc. Furthermore, in species in which the
pseudorhipidion is present, the rhipidion is absent, the probable function of
the pseudorhipidion being to spread the ejaculating spermatozoa (Leigh-
Sharpe 1920). But anacanthobatids which possess a palp, also possess a rhi-
pidion, indicating a different function for the palp and pseudorhipidion.

Springeria foliorostris (Figs 4, 5, 6)

Claspers comparatively short and naked, with slightly expanded glans
more or less dorso-ventrally flattened and pointed; pseudosiphon absent; spur
well developed, forming, together with palp, the outer lateral margin of dorsal

ANNALS OF THE SOUTH AFRICAN MUSEUM

140

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ds

de

INTERRELATIONSHIPS WITHIN THE ANACANTHOBATIDAE I4!I

Fig. 5. Springeria foliorostris. Terminal cartilages of the right clasper. dT,, dT,, dT;, dT,, vT—
dorsal view; aT,, aT,—ventral view. Scale 10 mm.

142 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 6. Springeria foliorostris. Cartilages of right clasper with dT, and vT removed. Scale 10 mm.

INTERRELATIONSHIPS WITHIN THE ANACANTHOBATIDAE 143

lobe; inner dorsal lobe with proximal cleft and large fleshy palp, without a
distal filament; rhipidion at level of hypopyle with pent extending distally
from the rhipidion along inner lateral margin of shield; sentinel well developed
and covered with pleated epithelia, partially covering spike; sentinel and
spike situated medially.

Proximal cartilaginous elements (basal group): b, and b, cartilages, with
covering f-cartilage arising from stepped axial to about one-half the length
of the b,-cartilage. Four dorsal terminal cartilages: dT, plate-like, without a
proximal shelf, situated entirely on dorsal side of organ, poorly calcified
proximally; dT, comparatively small and connecting dM with dT; dT, well
developed and projecting laterally outwards as a sharp point, the spur; dT,
flat and poorly calcified, bonded to outer lateral edge of pointed Ax. vT dorsally
concave with pointed distal tip and short anterior notch at about half the
length of the cartilage. al, comparatively narrow and elongate, with sharp-
pointed, dorso-ventrally flattened tip. Bifurcate aT,, with spinal projection
extending distally to a somewhat expanded, dorso-ventrally flattened blade-like
tip, and with well developed attachment process arising at about one-third
the length of the cartilage and tightly bonded to lateral edge of Ax.

Anacanthobatis longirostris (Figs 7, 8, 9)

Clasper comparatively short with naked, slightly expanded and dorso-
ventrally flattened tip; pseudosiphon absent; spur well developed, forming
outer lateral margin of dorsal lobe with palp; inner dorsal lobe with proximal
cleft; slender palp arising at level of rhipidion, with a short distal filament;
rhipidion at level of hypopyle, without a pent; shield dorsally convex and
distally truncate, without laminate integument; sentinel with sharp point and
covered basally with pleated integument, partially overlying spike; sentinel
and spike situated medially.

Proximal cartilaginous elements (basal group): b, and b, cartilages with
dorsally situated f-cartilage, arising from stepped Ax to about one-half the
length of b,-cartilage. Four dorsal terminal cartilages: dT, without proximal
shelf but with distal point, situated dorsally but with inner lateral edge curved
to wrap around Ax on to ventral side; dT, comparatively small and comma-
shaped, connecting dM with dT,; dT, asymmetrical proximally and broadly
expanded distally, with sharp-pointed, Z-shaped outer lateral projection, the
spur, and short, truncate, inner lateral extension; dT, shield-like and poorly
calcified, with proximal inner extension fusing with dT. vT simple, dorsally
convex with truncate distal tip and with short anterior notch at about one-half
the length of the cartilage. aT, dorso-ventrally flattened with condyle-like
proximal end and slightly expanded, knife-like distal point. Bifurcate aT’, with
spinal projection extending distally to somewhat expanded, dorso-ventrally
flattened, blade-like tip, and with well developed attachment process, arising
at about one-third the length of the cartilage, tightly bonded to lateral edge
of Ax.

ANNALS OF THE SOUTH AFRICAN MUSEUM

144

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INTERRELATIONSHIPS WITHIN THE ANACANTHOBATIDAE

GAG

VT

PP ere
Stator reared LD

Fig. 8. Anacanthobatis longirostris. Terminal cartilages of the right clasper. dT,, dT,, dT;, dT,;
vI—dorsal view; aT,, aT.,— ventral view. Scale 10 mm.

146 ANNALS OF THE SOUTH AFRICAN MUSEUM

oP woe ge

°,
.

Vase

2°,

Fig. 9. Anacanthobatis longirostris. Cartilage of right clasper with dT, and vT removed. Scale
10 mm.

INTERRELATIONSHIPS WITHIN THE ANACANTHOBATIDAE 147

Anacanthobatis borneensis (Figs 10, 11, 12)

Claspers short with naked, slightly expanded and dorso-ventrally flattened
glans; pseudosiphon, spur and palp absent; inner dorsal lobe with 2 proximal
clefts; rhipidion at level of hypopyle; shield small, without pent; sentinel and,
spike similar in size and shape, with dorso-ventrally flattened, blade-like tips
situated laterally in glans; sentinel capable of rotation.

Proximal cartilaginous elements (basal group): b, and b, cartilages with
dorsally situated 8-cartilage arising from stepped Ax almost to b,/basipterygium
junction. Two dorsal terminal cartilages: dT, absent, the m. dilatator inserting
at proximal region of dI',; dT, small and comma-shaped joining dT, with
dM; dT asymmetrical proximally with a small window, and distally elongated
to form a straight, flat, lateral extension, which does not develop into a spur;
short, inner lateral extension of dT, loosely connected with pointed Ax; dT,
absent. vI expanded proximally to form a short shield, with elongate anterior
notch situated at about one-third the length of the cartilage and wrapping
around inner lateral margin of the organ on to the dorsal side; distal extremity
of vl pointed and curving laterally inwards. Simply-pointed aT, with expanded
joint-like proximal region. aT, asymmetrical, spinal process slightly Z-shaped
with dorso-ventrally flattened blade-like tip; attachment process small and only
slightly calcified, arising at about one-quarter the length of the cartilage and
loosely bonded to lateral edge of Ax.

DIscussION

Consideration should be given to the fact that the number of species in the
family Anacanthobatidae is small, so that further division into subgeneric
groupings does not appear to serve a useful taxonomic purpose. However,
within the Rajoidea, such subdivision serves not only for taxonomy but may
also be employed in the construction and interpretation of phyletic relation-
ships. It is within this context that the subgenera within the Anacanthobatidae
will be considered.

There can be no doubt that a single family is involved in the cases of all
described anacanthobatid species. All possess the U-shaped pelvic girdle
characteristic of the Anacanthobatidae (Hulley 1972a). Furthermore, there are
two proximal segments in the basal group of the clasper cartilages, which
together with the presence of a pair of lateral prepelvic processes on the pelvic
girdle, fully substantiate the inclusion of the family within the Rajoidea.

As already stated, the recognition of the genus Springeria is based solely
on the terminal leaf-like expansion of the snout. The interpretation of this
feature does not now appear to have been constant among the various authors
of species in this genus (Bigelow & Schroeder 1951; Chan 19654; Wallace 1967).
The terminal expansion in Springeria foliorostris is well marked and is formed
in an entirely different manner to the ‘terminal expansion’ in either S. or or
S. melanosoma. In these species, there is merely a blunt protuberance at the base

148 ANNALS OF THE SOUTH AFRICAN MUSEUM

sp

Fig. 10. Anacanthobatis borneensis. A. dorsal view of right clasper. B. lateral view of right clasper
opened to show structural features of the glans. Scale 10 mm.
cf—cleft; hp—hypopyle; rh—rhipidion; sh—shield; sp—spur; st—sentinel.

INTERRELATIONSHIPS WITHIN THE ANACANTHOBATIDAE 149

Fig. 11. Anacanthobatis borneensis. Terminal cartilages of the right clasper. dT,, dT,, vl, aT,
(head only) — dorsal view; aT, (complete) aT,— ventral view. Scale 5 mm.

ANNALS OF THE SOUTH AFRICAN MUSEUM

150

+ eben

3°

rn
me ¥:

=
=

Ax

Fig. 12. Anacanthobatis borneensis. Cartilages of right clasper with vT only removed. Scale 5 mm.

INTERRELATIONSHIPS WITHIN THE ANACANTHOBATIDAE Syl

of the rostral filament, a condition which is approximated in all anacanthobatid
species including S. folzorostris. ‘These facts, when considered in the light of the
similarity in clasper structure of Springeria foliorostris and Anacanthobatis longi-
rostris (Figs 4-9), indicate that the genus Springeria as based on this character
is invalid, and that a terminal leaf-like expansion of the snout is a character
applicable only at the species level to S. foliorostris.

This conclusion is further supported by the fact that the number of radials
in both the pectoral and pelvic fins does not allow for the separation of Springeria
as a separate genus. It appears that the number of mesopterygial radials in
Springeria foliorostris is slightly higher than in other Anacanthobatis species.
Unfortunately, counts of the number of mesopterygial radials in S. ori and
S. melanosoma were not possible, due to the small degree of calcification of these
cartilages.

X-ray examination has shown that unlike the Rajidae, the pectoral girdle
in the Anacanthobatidae is sexually dimorphic. In males the propterygium
consists of two articulated segments, while in females there is a single proptery-
gial element (Fig. 13). In rajids two articulated propterygial elements are
found in both sexes. The comparative size of the mesopterygium varies in
different species, but its use as a specific, subgeneric or generic diagnostic
character is difficult to assess at this stage.

To summarize, the genus Springeria cannot be distinguished from Anacan-
thobatis; the terminal leaf-like expansion of the snout is applicable only to S.
foliorosiris and lends itself as a diagnostic character at the species level.

On the basis of the external and internal anatomy of the claspers, the
characters of which appear to be the most reliable criteria in the taxonomy of
the Rajoidea, the following species of Anacanthobatis are now distinguished:
A. marmoratus, A. americanus, A. longirostris, A. borneensis and A. foliorostris.

A B
ead

Fig. 13. Pectoral girdles of Anacanthobatis marmoratus. A. female; B. male. Scale 10 mm.

152 ANNALS OF THE SOUTH AFRICAN MUSEUM

Anacanthobatis ori appears to resemble A. marmoratus in the complete fusion of the
inner margin of the pelvic fin with the base of the tail, a character which is
unique to these two species. However, for the moment, Anacanthobatis ori is
retained as a separate species on the basis of a lower teeth count (20-24 rows
in upper jaw in A. ori; 32-35 rows in A. marmoratus), a comparatively longer
and more slender tail, larger eyes (which Wallace (1967) associates with the
light intensity of a shallower depth habitat) and a nasal curtain which does not
overlap the corners of the mouth. Similarly, A. melanosomus is retained for the
moment as a separate species to the sympatric A. borneensis because of differences
in the disc shape, snout length, tail length, nasal curtain and presence of
minute thorns along the midline of the base of the tail (Chan 19654, b). It
should be noted that there is no difference in teeth count in these two species
(24 rows in upper jaw). The low value of 14 rows in A. melanosomus reported
by Chan (19652) arises because the teeth are arranged in quincunx, but are
widely separated. Since adult males of Anacanthobatis ori and A. melanosomus are
unknown, it is impossible to comment on them further.

Key TO SPECIES

1 (a) Dorsal surface of disc with dermal papillae
(b) Dorsal surface of disc without dermal papillae . :
2 (a) Pelvics completely fused along entire length with root of tail
(b) Pelvics not completely fused along entire length with root of tail .

moO OM N

3 (a) 20-24 rows of teeth in upper jaw; nasal curtain not overlapping corners of mouth
A. ort

(b) 32-35 rows of teeth in upper jaw; nasal curtain overlapping corners of mouth
A. marmoratus

4 (a) Length of tail from middle of vent greater than distance from middle of vent to

base of rostral filament; interorbit about 3 in snout length to base of filament
A. melanosomus

(b) Length of tail from middle of vent less than distance from middle of vent to base
of rostral filament; interorbit about 7 in snout length to base of filament A. borneensis

5 (a) Length of snout about 4-5 times as long as diameter of eye . ; ; A. americanus
(b) Length of snout about 7-9 times as long as diameter of eye : : ; ; 6

6 (a) Snout with terminal leaf-like expansion; length of tail from middle of vent greater
than distance from middle of vent to tip of snout : ‘ . A. foliorosiris

(b) Snout without terminal leaf-like expansion; length of tail fom middle of vent less
than distance from middle of vent to tip of snout ; ; , ; A. longirostris

TAXONOMIC ARRANGEMENT OF THE ANACANTHOBATIDAE

On the basis of clasper structure, the family Anacanthobatidae can be
taxonomically arranged as follows. It should be noted however that Hulley
(1972a) has erroneously confused the sentinel/spike and aT,/aT, in Anacan-
thobatis americanus.

INTERRELATIONSHIPS WITHIN THE ANACANTHOBATIDAE 153

Family Anacanthobatidae
Genus Anacanthobatis Von Bonde & Swart, 1923
type-species Anacanthobatis marmoratus Von Bonde & Swart, 1923

I. subgenus Anacanthobatis Von Bonde & Swart, 1923
type-species Anacanthobatis marmoratus Von Bonde & Swart, 1923

species: (?) Anacanthobatis ort (Wallace, 1967)—no adult male

Definition

Claspers comparatively small, with spur on lateral dorsal border, but
without pseudosiphon; inner dorsal lobe with proximal cleft and with slender
proximal palp; palp without a terminal filament; rhipidion present; shield
prominent with well developed eperon; sentinel and spike medially positioned;
Ax spatulate; three dT elements, with spur developed from dT;; vT proximally
pointed with serrate outer lateral margin and with anterior notch well developed
from windowed inner lateral margin; aT’, distally spoon-shaped; aT, simply-
pointed, attachment process absent.

2. subgenus Springeria Bigelow & Schroeder, 1951
type-species Anacanthobaitis foliorostris (Bigelow & Schroeder, 1951)

species: Anacanthobatis longirostris Bigelow & Schroeder, 1962

In accordance with Article 67k of the International Code of Zoological
Nomenclature, the name Springeria is retained, but is now redefined.

Definition

Claspers comparatively small, with spur developed on lateral dorsal margin
but without pseudosiphon; inner dorsal lobe with proximal cleft and with
proximal palp; palp with or without a distal filament; rhipidion present;
shield well developed, eperon absent but pent present or absent; sentinel and
spike positioned medially; Ax with pointed distal extremity; four dT elements,
with spur developed from dT,; vT simple and rounded proximally, with small
anterior notch; aT, distally pointed or slightly blade-like; aT, with well
developed blade-like spinal projection and well developed attachment process.

3. subgenus Sznobatis n. subgen.
type-species Anacanthobatis borneensis Chan, 1965

species: (?) Anacanthobatis melanosomus (Chan, 1965)—no adult male

Definition

Claspers small, without spur on dorsal lateral margin and without pseudo-
siphon; inner dorsal lobe without palp but with two proximal clefts; rhipidion
present; shield poorly developed laterally, but expanded medially to wrap

154 ANNALS OF THE SOUTH AFRICAN MUSEUM

around Ax stem as small dorsal bump; sentinel and spike simple, with slight
blade-like distal ends, situated laterally with sentinel capable of rotation; two
dT cartilages, but dT, absent; spur not developed from distal projection of
dT,; Ax simply pointed distally; aI’, simple with blade-like end; aT, with
slender spinal projection and poorly developed attachment process.

4. subgenus Schroederobatis n. subgen.

type-species Anacanthobatis americanus Bigelow & Schroeder, 1962

Definition

Claspers small, with pseudosiphon in outer dorsal wall; spur absent; inner
dorsal lobe without palp and cleft; rhipidion present; shield absent; sentinel
and spike simple and positioned laterally, with sentinel capable of rotation;
two dT cartilages with dT, well developed; Ax simply-pointed; vT absent;
aT’, and aT, similar in shape with slightly pointed, blade-like distal ends.

As has been pointed out, Hulley (1972a) has made tentative suggestions
regarding the phylogenetic position of the Anacanthobatidae. He has proposed
an early origin for the family, deriving it from the hypothetical Dipturus ancestral
stock. ‘This would mean therefore that certain characters of the Anacan-
thobatidae would also be exhibited by the Crurirajidae, Dipturus, Amblyraja,
Raella and Leucoraja species (Hulley 1972a: fig. 56).

The presence of an erectile rhipidion in all anacanthobatids, as well as
the retention of the well developed distal projection to the dM, in the form of
the palp, in Anacanthobatis foliorostris, A. marmoratus and A. longirostris (Figs 4,
7; Hulley 1972a: fig. 10) would substantiate this theory. However, the distal
projection of the dM is not well developed in A. americanus and A. borneensis
(Fig. 12; Hulley 1972a: fig. 11), but the lack of a vT and dT, respectively in
these species, indicates a somewhat specialized condition of the claspers. This
specialization is further emphasized by the arrangement and number of dT
cartilages in A. americanus (Hulley 1972a: fig. 44), and by the peculiar develop-
ment of the anterior notch of the vT in A. borneensis (Fig. 11).

The Crurirajidae might be considered to be directly ancestral to the
Anacanthobatidae, since both families are characterized by the anterior limb-
like lobe of the pelvic fin, and the absence of dorsal fins would then appear as a
progression away from the crurirajid condition. Furthermore, the attachment
process of the aT’, in Anacanthobatis could then be interpreted as a development
from the terminal bridge in Cruriraja (Hulley 1972a: figs 40, 41, 42). This
terminal bridge links the aT, with the Ax. However, the position of the dT,,
nature of the Ax and typical condition of the aT, and aT, in Cruriraja preclude
a direct development of the Anacanthobatidae from this family. Furthermore,
an attachment process to the aT, is also developed in the Rajella/Leucoraja/
Amblyraja line of evolution (Hulley 1972a: fig. 26).

A relationship with the Amblyraja/Rajella/Leucoraja line is further exempli-
fied by the well developed dT, (spur) in almost all anacanthobatids, a frame-

INTERRELATIONSHIPS WITHIN THE ANACANTHOBATIDAE 155

work arrangement of the dT cartilages, the medial position of the anterior
notch of the vT and the reduction in size of the dT. However, Anacanthobatis
lacks the external pseudosiphon so typical of this group. The pseudosiphon in
Anacanthobatis americanus (Hulley 1972a: fig. 11), although having a direct
relationship with the dI,, is not comparable to the form of this structure in
Amblyrga and (?) Raella.

To conclude, the Anacanthobatidae appear to have arisen separately from
the same ancestral stock as both the Crurirajidae and the Amblyraja/Rajella/
Leucoraja lines, and probably represent a direct modification of the Dipturus
ancestral stock, which lost the pseudosiphon but retained the distal projection
of the dM (palp) during the development of the rhipidion (Fig. 14). On the
basis of clasper comparison therefore, the family does not now appear to have
a diphyletic origin.

ANACANTHOBATIDAE CRURIRAJIDAE RAJIDAE

Dipturus Amblyraja Leucoraja Rajella

Breviraja

Bathyraja
Raja

Rostroraja

Fig. 14. Proposed phyletic relationships of the Anacanthobatidae.

Springeria probably represents the least specialized subgenus, closest to the
basic ancestral stock, since the Ax is pointed, the distal end of the dM is well
developed and the vT is relatively simple. Furthermore, the primitive condition
of an elongate snout is retained, cf. Dipturus (Hulley 1972a). The anterior
leaf-like expansion of the snout in Anacanthobatis foliorostris represents a direct
modification of the condition in A. longirostris and would suggest a lesser age for
A. foliorostris, a fact which is supported by the complete dorsal rotation of the
af.

The subgenus Anacanthobatis would then represent a split from the above
condition, in which the snout was reduced, probably as an increased advantage
in grubbing (Ishiyama 1958; Hulley 1972a). Further, there was a change in

156 ANNALS OF THE SOUTH AFRICAN MUSEUM

form of the Ax and vT cartilages. The presence of a spatulate Ax, together
with the loss of the dT, might be interpreted as a condition arising from the
pointed Ax/plate-like dT, typical of Springeria. ‘The windowing of the vl may
represent the initial stages leading to the reduction (e.g. A. borneensis) and
complete loss (e.g. A. americanus) of the vI. However, the retention of the
primitively pointed Ax in these species precludes a direct modification of
Sinobatis and Schroederobatis from Anacanthobaits.

Rather the complete loss of the vl, dT, and dT, cartilages in Schroederobatis
represents a specialized condition, which may be associated with the lateral
shift in position of aT, and aTl’,. This suggestion may be valid if we consider
that essentially the clasper of the male skate plugs the cloaca of the female.
In Schroederobatis the dT, does not show complete dorsal rotation and, as has
been pointed out above, the Ax retains its pointed condition, facts which
suggest a specialization of the condition in Springeria.

Similarly, Sznobatis would represent a specialized condition arising from
Springeria: the Ax is pointed and the dT; is comparatively well developed,
although it does not manifest itself as a spur in the glans. Again the loss of the
dT, may be associated with the lateral shift in position of the aT, and aT,
cartilages, together with the peculiar development of the anterior notch of the
vI’, which runs around the Ax stem on to the dorsal surface of the glans.

It has already been suggested (Hulley 1972a, b) that the Crurirajidae and
Breviragja may have had their origin in the waters of the central western Atlantic
and may have spread from this area to the southern African region at a later
date. On the evidence presented above, this would also seem to be the case in
the Anacanthobatidae, since not only are the most primitive forms known from
the western central Atlantic but this region also shows the greatest species
diversity of Anacanthobatidae.

SUMMARY

The lectotype of Anacanthobatis marmoratus Yon Bonde & Swart, 1923 is
designated and described.

The pelvic girdles, rostral filaments, pectoral and pelvic radials of the
Anacanthobatidae and the clasper structure of Anacanthobatis longirostris, A.
borneensis and Springeria foliorostris are described.

On the basis of the above, it appears that the anterior leaf-like expansion
of the snout is present only in S. foliorostris and is valid only as a diagnostic
character at the species level. The genus Springeria is taxonomically invalid
at the generic level, and all species should be referred to the genus Anacan-
thobatis. A key to the species is given.

Since there are relatively few species involved in the family Anacan-
thobatidae, further division into subgenera does not serve a useful taxonomic
purpose. However, for interpretation of the phylogeny of the family, subgeneric
groupings, based on the clasper structure, have been constructed as follows:

INTERRELATIONSHIPS WITHIN THE ANACANTHOBATIDAE 157

Family Anacanthobatidae

Genus Anacanthobatis Von Bonde & Swart, 1923

type-species Anacanthobatis marmoratus Von Bonde & Swart, 1923

1. subgenus Anacanthobatis Von Bonde & Swart, 1923
type-species Anacanthobatis marmoratus Von Bonde & Swart, 1923

species: (?) Anacanthobatis ort (Wallace, 1967)

2. subgenus Springeria Bigelow & Schroeder, 1951
type-species Anacanthobatis foliorostris (Bigelow & Schroeder, 1951)

species: Anacanthobatis longirostris Bigelow & Schroeder, 1962

3. subgenus Sinobatis n. subgen.
_type-species Anacanthobatis borneensis Chan, 1965

species: (?) Anacanthobatis melanosomus (Chan, 1965)

4. subgenus Schroederobatis n. subgen.

type-species Anacanthobatis americanus Bigelow & Schroeder, 1962

In accordance with Article 67(k), of the International Code of Zoological
Nomenclature, Springeria is retained as a subgenus, but is redefined.

The phyletic interrelationships of the family are discussed in terms of these
morphological details and an evolutionary pattern is proposed. On this evidence
it seems likely that, as in the case of the Crurirajidae and of Breviraja, the
Anacanthobatidae had their origin in the central western Atlantic.

ACKNOWLEDGEMENTS

I am extremely grateful to the following persons for placing valuable
material at my disposal: Mrs M. M. Smith, J. L. B. Smith Institute of Ich-
thyology, Grahamstown; Mr A. Wheeler, Department of Fishes, British
Museum (Natural History), London; and Drs Victor G. Springer and William
R. Taylor, Division of Fishes, National Museum of Natural History,
Washington.

My thanks are also due to Mr S. X. Kannemeyer, South African Museum,
Cape Town, for his valuable assistance with the photography, and to Dr M.
Stehmann, Institut fiir Seefischerei, Hamburg, for many helpful comments.

REFERENCES

BARNARD, K. H. 1925. A monograph of the marine fishes of South Africa. Ann. S. Afr. Mus.
21: 1-418.

BicrLow, H. B. & ScHROEDER, W. C. 1951. A new genus and species of anacanthobatid skate
from the Gulf of Mexico. 7. Wash. Acad. Sci. 41: 110-113.

158 ANNALS OF THE SOUTH AFRICAN MUSEUM

BicELow, H. B. & ScHROEDER, W. C. 1953. Fishes of the western North Atlantic. Part 2.
Sawfishes, guitarfishes, skates and rays. Chimaeroids. Mem. Sears Fdn mar. Res. 1 (2): i-xv,
1-588.

BicELow, H. B. & ScHROEDER, W. C. 1962. New and little known fishes from the western
Atlantic. Bull. Mus. comp. Kool. Harv. 128: 159-244.

Cuan, W. L. 1965a. A new anacanthobatid skate of the genus Springeria from the South China
Sea. Jap. F. Ichthyol. 13: 40-45.

Cuan, W. L. 19656. Anacanthobatis borneensis, the second new anacanthobatid skate from the
South China Sea. Jap. F. Ichthyol. 13: 46-51.

Fow er, H. W. 1941. Contributions to the biology of the Philippine archipelago and adjacent
regions. The fishes of the groups Elasmobranchii, Holocephali, Isospondyli and Ostarophysi,
obtained by the United States Bureau of Fisheries steamer ‘Albatross’ in 1907 to 1910,
chiefly in the Philippine Islands and adjacent seas. Bull. U.S. natn. Mus. 100 (13): i-x,
1-879.

FRECHKOP, S. 1925. Sur la structure et le dévelopment de l’organe copulateur des raies dans
ses rapports avec la structure de la nagoire ventrale. Archs biol. Liége-Paris 35: 207-268.

Hutiey, P. A. 1970. An investigation of the Rajidae of the west and south coasts of southern
Africa. Ann. S. Afr. Mus. 55: 151-220.

Hutiey, P. A. 1972a. The origin, interrelationships and distribution of southern African
Rajidae (Chondrichthyes, Batoidei). Ann. S. Afr. Mus. 60: 1-103.

Hutiey, P. A. 19725. A new species of southern African brevirajid skate (Chondrichthyes,
Batoidei, Rajidae). Ann. S. Afr. Mus. 60: 253-263.

IsHtyAMA, R. 1958. Studies on the rajid fishes (Rajidae) found in the waters around Japan.
J. Shimonoseki Coll. Fish. 7: 193-394.

LEIGH-SHARPE, W. H. 1920. The comparative morphology of the secondary sexual characters
of elasmobranch fishes. Memoir I. The claspers, clasper siphons and clasper glands. 7.
Morph. 34: 254-265.

QuiGNARD, J. P. 1965. Les raies du Golf du Lion. Nouvelle méthode de diagnose et d’étude
biogéographique. Rapp. P.—v. Réun. Commn int. Explor. scient. Mer Méditerr. 18: 211-212.

SmiTH, J. L. B. 1961. The sea fishes of southern Africa. 4th ed. Cape Town: C.N.A.

STEHMANN, M. 1970. Vergleichend morphologische und anatomische Untersuchungen zur
Neuordnung der Systematik der nordostatlantischen Rajidae (Chondrichthyes, Batoidei).
Arch. Fisch Wiss. 21: 73-164.

Von Bonpe, C. & Swart, N. B. 1923. The Platosomia (skates and rays) collected by the S.S.
‘Pickle’. Rep. Fish. mar. biol. Surv. Un. S. Afr. 3 (Spec. Rep. 5): 1-22.

WaL.ace, J. H. 1967. The batoid fishes of the east coast of southern Africa. Part III. Skates
and electric rays. Investl Rep. oceanogr. Res. Inst. 17: 1-62.

INSTRUCTIONS TO AUTHORS

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REFERENCES

Harvard system (name and year) to be used: author’s name and year of publication given
in text; full references at the end of the article, arranged alphabetically by names, chronologi-
cally within each name, with suffixes a, b, etc. to the year for more than one paper by the: same
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For books give title in italics, edition, volume number, place of publication, publisher.

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Examples (note capitalization and punctuation)

BuLLoucu, W. S. 1960. Practical invertebrate anatomy. 2nd ed. London: Macmillan.

FiscHER, P.-H. 1948. Données sur la résistance et de le vitalité des mollusques. 7. Conch., Paris
88: 100-140.

FiscHER, P.-H., Duva, M. & Rarry, A. 1933. Etudes surles échanges respiratoires des littorines.
Archs Zool. exp. gén. 74: 627-634.

Konn, A. J. 1960a. Ecological notes on Conus (Mollusca: Gastropoda) in the Trincomalee region
of Ceylon. Ann. Mag. nat. Hist. (13) 2: 309-320.

Koun, A. J. 19606. Spawning behaviour, egg masses and larval development in Conus from the
Indian Ocean. Bull. Bingham oceanogr. Coll. 17 (4): 1-51.

THIELE, J. 1910. Mollusca: B. Polyplacophora, Gastropoda marina, Bivalvia. In: SCHULTZE, L.
Koologische und anthropologische Ergebnisse einer Forschungsreise im westlichen und zentralen Siid-
Afrika. 4: 269-270. Jena: Fischer. Denkschr. med.-naturw. Ges. Jena 16: 269-270.

ZOOLOGICAL NOMENCLATURE

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The Harvard system of reference to be used in the synonymy lists, with the full references
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Example
Scalaria coronata Lamarck, 1816: pl. 451, figs 5 a, b; Liste: 11. Turton, 1932: 80.

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P. A. Hulley

INTERRELATIONSHIPS WITHIN

THE ANACANTHOBATIDAE
(CHONDRICHTHYES, RAJOIDEA),

WITH A DESCRIPTION OF THE LECTOT Yi
ANACANTHOBATIS MARMORATUS

VON BONDE & SWART, 1923

me 7.29

VOLUME 62 PART 5 NOVEMBER 1973

4
;

{
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OF THE SOUTH AFRICAN
~~ "" MUSEUM

}CAPE TOWN

mNNALS OF THE SOUTH AFRICAN MUSEUM
ANNALE VAN DIE SUID-AFRIKAANSE MUSEUM

Volume 62 °#£Band
November 1973 November
ani ese Deel

PONE TopinG bho iOr PARAM EET A
(CRUSMACEA: AMPHIPODA)
FROM SOUTH AFRICA

By
MICHAEL H. THURSTON

Cape Town Kaapstad

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A NEW SPECIES OF PARAMELITA (CRUSTACEA: AMPHIPODA)
FROM SOUTH AFRICA

By
MicHAEL H. THuRsTON
Institute of Oceanographic Sciences, Wormley, Godalming, Surrey, England
(With 3 figures)
[MS. accepted 25, April 1973)

CONTENTS
PAGE
Introduction. ; ‘ : : . 159
Material : : ; ; : é 160
Description : : ‘ : : . 160
Discussion 4 ; : § : 5 166
Summary f : ‘ : : . 168
Acknowledgemen : ; . : : 168
References : : : 5 , ; 168
INTRODUCTION

In his major contribution to the amphipod fauna of South Africa, Barnard
(1916) assigned to the genus Gammarus four new species from fresh-water
localities in the Cape Peninsula. These records were the first of fresh-water
amphipods from South Africa, and with the exception of Gammarus pulex (L.)
as noted by Krauss (see Stebbing 1g1o: 456), the first record of the genus from
South Africa. Schellenberg (1926) erected the genus Paramelita for the new
species P. ctenodactyla described from material collected by the Deutsche Siid-
polar-Expedition. In the following year, Barnard published results obtained
from collections made in fresh-water localities in the south-western part of the
Cape Province (Barnard 1927). Although Barnard was able to equate P. cteno-
dactyla with Gammarus capensis Barnard, 1916, he found it necessary to erect a
further six species, thus raising to ten the number of Gammarus known from
fresh-water localities in South Africa. Schellenberg (1937) showed that the
South African species assigned to Gammarus were sufficiently distinct from those
of Palaearctic and Nearctic Regions to warrant generic separation, and so
transferred them to Paramelita.

In 1970 I received from Miss Mary Hazleton, Honorary Biological
Recorder of the Cave Research Group of Great Britain, a small collection of
amphipods which, among the European material, contained two specimens
from South Africa. This material clearly belonged to the genus Paramelita.
A comparison with syntype material of most of the species described by Barnard,
which had been deposited at the British Museum (Natural History) in 1928,
precluded the present specimens from any of these species. The two specimens
are therefore described herein as a new species, Paramelita barnardi sp. nov.

159

Ann. S. Afr. Mus. 62 (5), 1973: 159-168, 3 figs.

160 ANNALS OF THE SOUTH AFRICAN MUSEUM

The species is dedicated to the late K. H. Barnard in recognition of his significant
contributions to the knowledge of the fauna of South Africa and of tropical
and Southern Hemisphere amphipods.

MATERIAL

The holotype, a 9 mm male, has been deposited in the collection of the
British Museum (Natural History) under the registration number 1972:542:1,
and the allotype, a 9 mm female, is registered in the collection of the South
African Museum under number S.A.M. A13199.

Both specimens were collected from Boomslang Cave, Gave Peak, above
Kalk Bay, near Cape Town, South Africa. They were found by M. Ware ina
small muddy pool in the dark zone on 23 June 1969.

DESCRIPTION

The description is based on the holotype, which differs from the allotype
only in minor details of setation and spination. Body moderately compressed,
peraeon five fourths length of pleon. Peraeon, coxae 1 to 4, depth a little less
than corresponding segments, segments 2 to 7 bearing branchiae, those of
segment 7 the smallest. Accessory branchiae present on peraeon segments 2 to
7; one on segments 2 and 3, two on segments 4, 5 and 7 and four on segment 6.
Pleon segments with setae dorsally, segments 1-3 each with 6—7 setae at posterior
margin, segments 4 and 5 with 2-4 setae on posterior margin and paired groups
of 5-6 setae a little anterior and lateral to the mid-point of the posterior margin;
segment 6 similar to 4 and 5 but with a spine and 3 setae in each lateral group.
Epimeron 1, distally rounded, posterior margin convex and armed with ca
12 short, fine setae set in minute notches; two ranks of ten and six
setae exteriorly just above distal margin. Epimeron 2, deeper than epimeron 1,
distally rounded; posterior margin barely convex, armed with fine setae; five
ranks of 7, 13, 15, 6 and 13 setae above distal margin; a spine among the setae
of the third rank. Epimeron 3, similar to second but a little broader; setae on
posterior margin less regularly spaced; six ranks of 7, 8, 12, 2, 10 and g setae
above distal margin; first two ranks also contain single spines.

Head longer than first peraeon segment; rostrum obsolete, eye lobe deep,
but not sharply produced, broadly rounded above, obtusely angled below;
post-antennal angle sub-acute with 3-4 short setae anteriorly; margin between
eye lobe and post-antennal angle excavate to accommodate inflated basal
article of antenna 2; epistome straight, not protruding beyond upper lip;
eye small, unpigmented in alcohol, apparently degenerate and lacking ommati-
dia. Antenna I, length equal to that of head and peraeon segments 1 to 6 com-
bined; lengths of peduncle articles in ratio 3:2:1; flagellum of 35 articles, just
more than twice length of peduncle, each article with several short, fine setae,
disto-ventrally; accessory flagellum of 5 articles, just shorter than article 2
of peduncle. Antenna 2, % length of antenna 1; article 1 of peduncle inflated,

A NEW SPECIES OF PARAMELITA FROM SOUTH AFRICA 161

Fig. 1. Paramelita barnardi sp. nov.

a. Habitus. b. Epimeron 1. c. Epimeron 2. d. Epimeron 3. e. Pleopod 1. f. Locking spines of
pleopod 1. g. Uropod 1. h. Uropod 2. i. Uropod 3. j. Second article of outer ramus of uropod 3.

162 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 2. Paramelita barnardi sp. nov.

a. Head, b. Antenna 1. c. Antenna 2. d. Upper lip. e. Left mandible. f. Apex of right mandible.
g. Lower lip. h. Maxilla 1. i. Maxilla 2. j. Maxilliped. k. Inner plate of maxilliped. 1. Outer
plate of maxilliped. m. Dactyl of palp of maxilliped.

A NEW SPECIES OF PARAMELITA FROM SOUTH AFRICA 163

broadly ovoid, article 4 stouter than and { longer than fifth article; flagellum 2
to 2 length of peduncle, of 17 articles, each article bearing groups of graded
setae anteriorly and posteriorly close to the distal margin. Upper lip rounded,
distally setose. Left mandible, incisor process bluntly five-toothed; lacina mobilis
with four blunt teeth; spine row consisting of three hooked spines, each strongly
and bilaterally pectinate; molar cylindrical, triturating surface oblique, armed
with ridges and teeth and with a long plumose seta proximally at the edge of the
triturating surface; palp rather longer than body of mandible; first article just
longer than wide; second much longer than first, with seven setae on distal
half of slight anterior expansion; third article narrowly pyriform, 3 length of
second article, anterior half of margin naked, distally armed with row of short,
sharp setae, and terminal } bearing ca 14 long, stout setae in two parallel rows.
Right mandible, differs from left in having the incisor process with four blunt
teeth, lacina mobilis bifurcate, each branch bearing four sharp teeth and spine
row of two straight, stout, unilaterally pectinate spines and two plumose setae.
Maxilla 1, inner plate triangular, apex subacute and bearing five plumose setae,
inner margin pubescent; outer plate with 10 to 11 stout, toothed spines distally;
palp, moderately broad, second article with broadly rounded apex armed with
eight spines and two subapical setae on posterior margin. Maxilla 2, inner
plate a little shorter and narrower than outer, apex broadly rounded, two ranks
of setae, one apical and the other subapical, just extend on to inner margin,
inner margin proximally pubescent; outer plate with broadly rounded apex
bearing row of ca 15 setae, the posterior surface bears a submarginal row of 11
long stout setae just below the apex. Lower lip, inner lobes absent, outer lobes
strongly setose on inner margin, mandibular process well developed. Maxilliped,
inner plate apically truncate, armed with three stout and two slender spines at
the apex and a subapical row of seven plumose setae which is contiguous with
the row of ten plumose setae on inner margin; outer plate longer than inner,
extending to 2 length of palp article 2, rounded apex with five long curved
pectinate spines, inner margin with ca 16 stout, blunt and closely set spine
teeth; palp article 2 the longest, second and third articles densely setose
medially; dactyl rather slender with five setae on medial margin, unguis
forming nearly half of total length.

Gnathopod I, coxa rectangular, distal margin setose; basal longer than
depth of coxa, carpus and propod subequal, together as long as basal; propod
distally expanded, length 3 of breadth, palm gently convex, as long as posterior
margin, armed with ca 25 setae of various lengths; palmar angle with 5 spines;
dactyl as long as palm. Gnathopod 2, coxa slightly narrowed distally, rather
longer than coxa 1, distally setose; carpus and propod combined a little longer
than basal; propod nearly twice as long as carpus, otherwise similar to gnatho-
pod 1. Peraeopod 3, coxa similar in form to that of gnathopod 2, but a little
deeper, depth just greater than length: basal $ length of coxa; article 4 3 length
of basal, equal to carpus and propod combined, length four times breadth,
somewhat expanded, strongly setose posteriorly and with three groups of spines

164 ANNALS OF THE SOUTH AFRICAN MUSEUM

and setae anteriorly; carpus more slender than merus, stouter and just shorter
than propod, carpus and propod strongly armed with spines and setae pos-
teriorly; dactyl half length of propod, somewhat hooked, with three spine setae
posteriorly. Peraeopod 4, coxa rectangular, height and length subequal, shallowly
excavate posteriorly, posterior angle obtuse, setose on posterior and posterior-
ventral margins; distal articles similar to, but slightly shorter than those of
peraeopod 3. Peraeopod 5, coxa, longer than deep, bilobed, anterior lobe the
deeper, three short setae on posterior margin, basal expanded posteriorly,
breadth 2 of length, posterior distal lobe rounded, weak, anterior margin armed
with spines and setae, posterior margin with ca 18 short fine setae; merus 2
length of basal, rather stout, strongly setose anteriorly, a single stout spine on
posterior margin; carpus and merus subequal, but former only half width of
latter, armed with setae on anterior margin and spines posteriorly; propod
subequal in length, but more slender than carpus, armed with spines anteriorly
and setae posteriorly; dactyl apically hooked, with six spine setae anteriorly.
Peraeopod 6, ca = length of peraeopod 5, coxa weakly bilobed, three short setae
on margin above posterior-distal angle; basal expanded, breadth ? of length,
posterior distal lobe rounded, weak, anterior margin with spines and setae,
posterior margin just concave, lined with 22 fine setae; merus # length of basal,
length three times breadth, strongly setose anteriorly, two stout spines pos-
teriorly; carpus subequal in length to merus, but more slender, strongly armed
anteriorly with spines and setae; propod a little shorter than basal, rather
slender, breadth less than 3 of length, strongly spinous anteriorly and with
many setae posteriorly; dactyl 4 length of propod, similar in form to that of
peraeopod 5. Peraeopod 7, just shorter than peraeopod 6; coxa semicircular,
setose on posterior 4 of free margin; basal expanded, distinctly tapering distally,
posterior-distal lobe obsolete, armed with spines and setae anteriorly and short
setae posteriorly; merus rather stout but not strongly produced distally; carpus
3 length of merus, breadth # of length; propod 4 longer, but more slender
than carpus; merus, carpus and propod densely clothed with spines and setae
anteriorly, less so posteriorly, dactyl 4 length of propod, structure as in peraeo-
pods 5 and 6.

Pleopods are fully developed, rather slender, length of peduncle four times
breadth, setae of rami rather short. Uropod 1, rather stout, dorso-lateral margins
of peduncle with nine spines, dorso-medial margin with three; rami subequal,
length of peduncle, outer ramus with three spines on each margin, inner ramus
with three on outer margin and two on inner, each ramus with two long and
three shorter apical spines. Uropod 2, short, stout, extending posteriorly only as
far as apices of uropod 1; peduncle with three pairs of spines on outer margin
and two single spines on inner; inner ramus % length of peduncle with two
spines on each margin; outer ramus 2 length of peduncle with two and one
spines on outer and inner margins respectively; each ramus with five apical
spines. Uropod 3, peduncle short, stout, breadth ca 3 of length; inner ramus
short, tapering distally, length 4 of peduncle, lateral spines zero and two respec-

A NEW SPECIES OF PARAMELITA FROM SOUTH AFRICA 165

& 4 <
Jy =
Zz y "
(t

a

Fig. 3. Paramelita barnardi sp. nov.

a. Gnathopod 1. b. Gnathopod 2. c. Palm of gnathopod 2. d. Peraeopod 3. e. Peraeopod 4.
f. Peraeopod 5. g. Peraeopod 6. h. Peraeopod 7. i. Dactyl of peraeopod 7.

166 ANNALS OF THE SOUTH AFRICAN MUSEUM

tively, apically four spines and two setae; first article of outer ramus much
longer than inner, length more than twice that of peduncle, breadth 4 of
length, laterally strongly armed with 4 + 4 groups of stout spines and some
setae, apex truncate with corona of ten stout spines; second article very short,
ca #5 length of first article, apically with two spines and a seta, length of second
article together with apical spines not exceeding that of apical spines of first
article. Telson, rather broader than long, cleft ¢ length, lobes a little dehiscent
distally; apices irregularly rounded, armed with one or two apical spines and
four or five apical or subapical setae, dorsal surface with four to six short setae
asymmetrically arranged and two or three short plumose setae close to the
lateral margin of each lobe.

DISCUSSION

The genus Paramelita in South Africa consists of a closely related group
of species some of which show curious morphological modifications involving
the peduncle of antenna 2 and, in one case, peraeopod 3. These variations are
fully developed only in adult males, but are usually distinguishable in a weaker
form in immature males. Differences between females of the various species
are more subtle. Apart from antenna 2 and peraeopod 3, some degree of sexual
dimorphism is usually apparent in the gnathopods, although this is rarely as
obvious as is the case in many European species belonging to Gammarus and
allied genera.

Paramelita barnard: is characterized by the following attributes: medium
size, unpigmented eyes, unmodified male antenna 2, oblique palmar margins
and the relative size of propods of gnathopods 1 and 2, unmodified male
peraeopod 3, rectangular and weakly excavate coxa 4, strongly spinose and
setose peraeopods 5-7, and minute second article of uropod 3.

The weakly excavate coxa 4 of P. barnardi distinguishes this species from
P. capensis and P. nigroculus. P. capensis also differs in having more broadly
expanded basal articles of peraeopods 5-7 and setose rather than spinose
uropod 3. Additional characters separating P. nigroculus from P. barnardi are
the pigmented eye, slender gnathopod 2 propod and acutely produced posterior-
distal angle of epimeron 3 of the former. Epimera 3 of P. nigroculus var. persetosus
more nearly resemble those of P. barnardi than the typical variety, but the
marked difference in the degree of setal armature of antenna 2 affords an addi-
tional character by which the new species can be distinguished.

P. auricularis, P. crassicornis, P. seticornis, P. spinicornis and P. tulbaghensis
are all characterized by modifications of the peduncle of antenna 2 in the male,
whereas in P. barnardi the male antenna 2 does not differ from the condition
found in the female. The bizarre subchelate condition of the male peraeopod 3,
nearly transversely palm of gnathopod 2 and narrow basal article of peraeopod 7
also distinguish P. auricularis from P. barnardi. Peraeopods 5-7 of P. crassicornis
are shorter, stouter and less setose than those of the new species which can also

A NEW SPECIES OF PARAMELITA FROM SOUTH AFRICA 167

be distinguished by the oblique palmar margins of the gnathopods. The forms
of both pairs of gnathopods are also additional characters separating P. seticornis
from P. barnardi. The relatively slender propods of gnathopods 1 and 2 and the
deep coxa 4 are features which separate P. spinicornis and the present species.
Additional characters distinguishing P. tulbaghensis from P. barnardi are the
strongly produced eye lobe, elongate first peduncle article of antenna 1, short
convex palm of gnathopod 2 and narrow basal articles of peraeopods 6 and7
of the former species. P. granulicornis has a strongly convex palm on gnathopod 2,
unexcavate coxa 4, and a distally expanded merus on peraeopods 3 and 4.
In the key to Paramelita species given by Barnard (1927: 167) the species
described herein keys down to the couplet separating P. kogelensis and P.
aurantius, and it is to these two species that P. barnardi appears most closely
related. Both of these species are smaller than P. barnardi. P. kogelensis can be
separated from P. barnardi by the rather strongly setose flagellum of antenna 1,
the shorter palm of gnathopod 2, the form of coxa 4, and the presence of a small
blunt tooth at the posterior-distal angle of epimeron 3. P. aurantius is dis-
tinguished from P. barnardi: by the relatively greater disparity in size between
enathopods 1 and 2, the more nearly transverse palms of these appendages
and the deeper coxa 4.

Schellenberg (1926) and Barnard (1927) have noted the presence of sternal
processes in species of Paramelita. Schellenberg (1930) has reviewed the presence
of such structures in this and other genera, and shown that they are probably
respiratory in function. Both specimens of P. barnardi possess sternal processes. In
each case a single medial process occurs on the second and third peraeon seg-
ments, pairs on segments 4, 5 and 7, and two pairs on segment 6. Histological
sections of coxal gills and sternal processes from the present material show that
the two types of appendage are basically similar in structure. The most obvious
differences are the smaller and less regular longitudinal lumina of the sternal
appendages. Coxal gills also show well-developed transverse lumina, which
are absent from the sternal structures. Despite these differences, a respiratory
function for the sternal processes seems probable, as was suggested by
Schellenberg.

The ecological significance of sternal gills is not clear. Amphipod species
bearing sternal gills are known from many fresh-water habitats in South
America, South Africa, Australia, Japan, Alaska, Scandinavia and northern
Russia. Many of these species belong to the family Gammaridae, but those
from Japan are eusirids of the genus Paramoera, while most of the South Ameri-
can representatives belong to Hyalella (Hyalellidae). Sternal gills occur in most
of the Ayalella species found in Lake Titicaca (Dr R. J. Lincoln, personal
communication). In some cases the incidence of sternal gills can be correlated
with adverse ecological conditions during part of the year (e.g. Barnard 1927),
but it seems unlikely that this is the case with the whole of the Hyalel/a-complex
in Lake Titicaca where speciation has allowed the occupation of a wide variety
of niches.

168 ANNALS OF THE SOUTH AFRICAN MUSEUM

The discovery of P. barnard: in the dark zone of a cave, the unpigmented
eyes of all species except P. nzgroculus and the ecological data given by Barnard
(1927) suggest that some members of the genus are partially troglobitic or
phreatic in habit. The elongate appendages and loss of ocular elements in
Niphargus suggest that Paramelita has not yet attained the obligatory subterra-
nean status of the palaearctic genus.

SUMMARY

A new species of Paramelita is described from material collected in the
hypogean zone of a cave on the Cape Peninsula. Evidence is presented favour-
ing the theory of a respiratory function for the sternal processes found in this

genus.

ACKNOWLEDGEMENTS

I am most grateful to Miss Mary Hazleton of the Cave Research Group of
Great Britain for making available the two specimens of Paramelita. My thanks
are due to Dr A. L. Rice for allowing me to examine material in the collection
of the British Museum (Natural History), to Dr R. J. Lincoln of the same
institution for information on Hyalella, and to Mr B. F. Kensley for comparing
drawings of the holotype with material in the South African Museum. I greatly
appreciate the skilled assistance of Mrs Christine Darter who produced the
illustrations from my pencil drawings.

REFERENCES

BARNARD, K. H. 1916. Contributions to the crustacean fauna of South Africa. 5. The Amphipoda.
Ann. S. Afr. Mus. 15: 105-302.

BARNARD, K. H. 1927. A study of the freshwater isopodan and amphipodan Crustacea of South
Africa. Trans. R. Soc. S. Afr. 142 139-215.

SCHELLENBERG, A. 1926. Die Gammariden der Deutschen Siidpolar-Expedition 1901-1903.
Dt. Stidpol.-Exped. 18 (Zool. 10): 235-414.

SCHELLENBERG, A. 1930. Stisswasseramphipoden der Falklandinseln nebst Bemerkungen tiber
Sternalkiemen. Zool. Anz. 91: 81-90.

SCHELLENBERG, A. 1937. Kritische Bemerkungen zur Systematik der Siisswassergammariden.
Aool. Fb. (Syst.) 6g: 469-516.

StTeBBING, T. R. R. 1910. General catalogue of South African Crustacea. Part V. Ann. S. Afr.
Mus. 6: 281-593.

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in text; full references at the end of the article, arranged alphabetically by names, chronologi-
cally within each name, with suffixes a, b, etc. to the year for more than one paper by the same
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FiscHER, P.-H. 1948. Données sur la résistance et de le vitalité des mollusques. 7. Conch., Paris
88: 100-140.

FiscHer, P.-H., Duvat, M. & Rarry, A. 1933. Etudes sur les échanges respiratoires des littorines.
Archs Zool. exp. gén. 74: 627-634.

Koun, A. J. 1960a. Ecological notes on Conus (Mollusca: Gastropoda) in the Trincomalee region
of Ceylon. Ann. Mag. nat. Hist. (13) 2: 309-320.

Koun, A. J. 1960. Spawning behaviour, egg masses and larval development in Conus from the
Indian Ocean. Bull. Bingham oceanogr. Coll. 17 (4): 1-51.

TuHIELE, J. 1910. Mollusca: B. Polyplacophora, Gastropoda marina, Bivalvia. In: SCHULTZE, L.
Koologische und anthropologische Ergebnisse einer Forschungsreise im westlichen und zentralen Siid-
Afrika. 4: 269-270. Jena: Fischer. Denkschr. med.-naturw. Ges. Jena 16: 269-270.

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MICHAEL H. THURSTON

A NEW SPECIES OF PARAMELITA
(CRUSTACEA: AMPHIPODA)
FROM SOUTH AFRICA

VOLUME 62 PART 6 JANUARY 1974

gL or

ANNALS

‘OF THE SOUTH AFRICAN
MUSEUM

| CAPE TOWN

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ANNALS OF THE SOUTH AFRICAN MUSEUM
ANNALE VAN DIE SUID-AFRIKAANSE MUSEUM

Volume 62 Band
January 1974 Januarie
Part = 6 Deel

THE AMPHIPODA OF SOUTHERN AFRICA
eek ie?
GiE GAMMARIDEA AND CAPRELLIDEA OF
SOUTH WEST AFRICA SOUTH OF 20°S

By
Gh Tye AU aI NSS

Cape Town Kaapstad

The ANNALS OF THE SOUTH AFRICAN MUSEUM

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Courtweg, Wynberg, Kaap

THE AMPHIPODA OF SOUTHERN AFRICA
PART 2
THE GAMMARIDEA AND CAPRELLIDEA OF SOUTH WEST AFRICA
SOUTH OF 20°S
By

C. L. GriFFITHs
C.S.I.R. Oceanographic Research Umt, Zoology Department, University of Cape Town

(With 7 figures)

[MS. accepted 20 March 1973]

CONTENTS

PAGE
Introduction . ‘ ‘ é é 5 169
The collecting stations : ; : 170
Systematics : : : : 5 AD
Gammaridea . : 3 : : : 19/7)
Caprellidea ‘ : ; e205
Summary . : : : é 200
Acknowledgements. : . 206
References : : : : 4 . 206

INTRODUCTION

The present paper is the second of a series aimed at reviewing present
knowledge of the gammaridean and caprellid amphipod fauna of Africa south
of 20°S. The first of the series (Griffiths 1973) dealt with the coast of Mocam-
bique below 20°S and recognized 65 species, 3 of them new to science and over
30 new to Mocambique. South West Africa has been chosen as the second area
for analysis since its fauna makes an interesting comparison with that of
Mocambique, particularly because collecting effort in the two areas has been
comparable.

The marine environment of South West Africa is considerably colder than
that of Mocambique, the dominant water current being the northerly flowing
Benguela current, in contrast with the warm Mocambique current which
bathes the east coast. The flow of the Benguela current is most intense in
summer with a flow of $ to 1 knot 150 km offshore between 34°S and 23°S.

At Walvis Bay temperature at 50 m varies between 17°C in summer and
10°C in winter. Off Mocambique the main body of the southward flowing
current passes some 90 to 120 km offshore at a surface velocity of about 3 knots
(the velocity falling rapidly with depth). Inshore counter-currents often form,
their intensities varying with local wind conditions. Temperature at 50 m
varies from 24 to 27°C.

169

Ann. S. Afr. Mus. 62 (6), 1974: 169-208, 7 figs.

170 ANNALS OF THE SOUTH AFRICAN MUSEUM

The first record of an amphipod from South West Africa appears to have
been one of a species of Podocerus by Schultze (1907). ‘These animals were about
2 mm long with transverse brown bands across their backs and were found
living in small upright tubes attached to firm objects in mud and projecting
about 4 mm above the surface. This species has not yet been identified or
described.

Since this early record little work has been done on the Amphipoda of the
area. A few records are to be found in the works of K. H. Barnard and in J. L.
Barnard (1961) while more detailed surveys have been conducted by Schellen-
berg (1925, 1953) and Penrith & Kensley (1970).

In 1925 Schellenberg recorded 17 species from South West Africa to which
11 further species were added in 1953, 5 of them new to science. A time of
inactivity followed Schellenberg’s work and it was not until 1970 that Penrith &
Kensley, while undertaking a survey of rocky shores in the vicinity of Lideritz,
recorded 28 species of amphipod, 15 of them new to the area; a striking demon-
stration of the work still to be done.

The University of Cape Town Ecological Survey has been collecting in
South West Africa since 1946, particularly between 1956 and 1964. In the
following account records resulting from these collections are incorporated with
those of earlier workers in listing the fauna of the area. The University’s collec-
tions are coded according to area and the various areas are discussed separately
below: the stations are shown on Figures 1 and 2.

THE COLLECTING STATIONS
South West Africa dredge stations (SWD)

The series of samples referred to by this code consists of 95 grabs and
dredges taken by the Division of Sea Fisheries research vessel Sardinops, the
R.V. Rockeater and the University of Cape Town’s vessel the R.V. Gilchrist.
Thirty-four of the 95 samples contained amphipods with a total of 37 species
being recorded. The general pattern of distribution indicates a number of
locally abundant species, well differentiated into soft and hard substrate types,
plus a larger number of relatively rare but well distributed species.

Most of the samples from soft substrates were dominated by a single
species, but different species dominated closely adjoining samples. The number
of amphipods in a 0,2 m? grab often exceeded 400 individuals of the dominant
species, while the total population per m? was frequently in excess of 1 000.
This patchy distribution is well exemplified by the two common ampeliscids
of the area, Ampelisca brevicornis and A. palmata. Although each dominated most
of the samples in which it was found, and both occurred in close proximity to
each other, they were seldom recovered from the same sample. Each of the
species probably prefers a particular substrate type although unfortunately
insufficient data has been collected to confirm this.

Apart from the species of Ampelisca mentioned, the common species of mud

THE AMPHIPODA OF SOUTHERN AFRICA orf!

SOUTH WEST
AFRICA
CAPE CROSS
IN
_ a
D60@
~62

SWD 13-53, 56 and 58
(see map of Lideritz Bay
and vicinity.)

| Fig. 1. South West Africa south of 20°S showing the positions of collecting stations mentioned
in the text.

172 ANNALS OF THE SOUTH AFRICAN MUSEUM

and sandy-mud off South West Africa were Eriopisa epistomata n. sp, Perioculodes
longimanus, Photis longidactylus n. sp, Photis longimanus and Megaluropus nama-
quaeensis. Paramoera capensis was also common but it is found on the bottom and
in the plankton in all areas, whether hard or soft bottomed.

The total population density in rocky areas was generally lower than that
of mud and sand (where shelter and food are more abundant). However,
occasional areas of high population density were found, especially where
sponges and bryozoa covered the rocks. Laetmatophilus purus and Caprella
equilibra were the most common species found in rocky areas.

South West Africa dredge station data

G = grab D = dredge A = airlift pump
Catalogue Date Position Depth Substrate Gear Temp.

no. (m) °C.
SWD 10 10/6/63 26 °34’8/14.°55’E 128 Mud and rock D 11,6
SWD 11 10/6/63 26 °34’8/14.°55’E 128 Mud and gravel G 11,6
SWD 13 10/6/63 26°35’S/15°o1’E ai Rock D 12,1
SWD 16 10/6/63 26 °36’S/15 °06’E 26 Sandy mud D 12,2
SWD 18 10/6/63 26 °36’S/15 °06’E 26 Sandy mud and shells G 12,2
SWD 21 11/2/63 26°37'S/15 °04’E 35 Rock and shells D 17,6
SWD 24 11/2/63 26 °38’S/15 °06’E 11 Mud and shells D 11,6
SWD 26 11/2/63 26°38’S/15 °06’E 11 Mud and shells D 11,6
SWD 27 11/2/63 26°38’S/15 °06’E 11 Mud and shells G 11,6
SWD 30 13/2/63 26 °38’S/15 °08’E 6 Grey mud G 13,6
SWD 33 13/2/63 26 °38’S/15 °08’E 6 Grey mud G 13,6
SWD 36 11/2/63 26 °38’S/15 °08’E 9 Dark mud D 13,4
SWD 37 11/2/63 26 °38’S/15 °08’E 9 Dark mud G 13,4
SWD 39 12/2/63 26°37’S/15°04’E 40 Rock G 11,9
SWD 40 12/2/63 26°36’S/15°06’E 35 Fine sand D 11,9
SWD 41 13/2/63 26 °36’S/15 °06’E 35 Fine sand, shells G 11,9
SWD 44 13/2/63 26 °36’S/15°10’E 5 Mud and sand G 149 |
SWD 45 13/2/63 26 °36’S/15°10’E 5 Mud and sand G 12,7
SWD 46 13/2/63 26 °25’S/15°090’E 5) Mud and sand G 12,9
SWD 47 13/2/63 26 °25’S/15°09’E 7 Mud and sand G 12,9
SWD 48 13/2/63 26 °37’S/15°10’E 6,5 Mud and sand G 12,8
SWD 49 13/2/63 26°37’S/15°10’E 6,5 Mudand sand G 12,8
SWD 51 14/2/63 26°37’S/15°07’E 20 Fine mud and sand D 11,9
SWD 54 14/2/63 26°40’S/14.°50’E QI Rock D 11,9
SWD 56 14/2/63 26°37’S/15°07’E 20 Muddy sand G 11,9
SWD 58 14/2/63 26 °39’S/15 °02’E 73 Mud and gravel D 11,9
SWD 60 9/9/63 22°53/S/14.°27'E 7,6 Dark mud G =
SWD 61 9/9/63 =. 22°53’S/14.°27’E 14 — G =
SWD 62 9/9/63 22 °53'S/14°27’E 14 Black mud G =
SWD 72 —/6/64 27°37'S/15 °28’E 23 Rock A —
SWD 81 22/7/64 27°19’S/15°15 32 Rock A =
SWD 84 21/6/64 27°30'S/15°25’E 24 Gravel, rock A =
SWD 86 20/6/64 37°30'S/15 °25’E 35 Gravel, stone A =
SWD 88 20/9/64 27°31’S/15°26’E 35 — A —

Liideritz shore (LU)

One hundred and twenty-two shore samples have been taken by the
University of Cape Town in the Liideritz area and are denoted by the code LU.
Liideritz Bay (Fig. 2) is situated on the coast of South West Africa at

26°50’S

THE AMPHIPODA OF SOUTHERN AFRICA

SHEARWATER Sale
BAY @ SHARK
SWD

GRIFFITH

BAY LUDERITZ

REDFORD BAY

|- TRANSECT POINT

Fig. 2. Collecting stations in the Liideritz Bay area.

174 ANNALS OF THE SOUTH AFRICAN MUSEUM

26°36'S/15°08’E. The main bay is divided into a number of subsidiary bays
and contains three rocky islands, Seal Island, Penguin Island and Shark Island.
The shore north of the town is either sandy or rocky while the sheltered southern
arm of the bay is lined with rock interspersed with considerable areas of mud,
particularly to the south of Redford Bay. Shearwater Bay and Big Bay are
sandy bays moderately sheltered from wave action by rocky headlands. The
area between these two bays, and south of Big Bay, is rocky and exposed to
powerful wave action.

The University of Cape Town team has collected 27 species of amphipod
in this area. The fauna of muddy areas of the southern area of the bay lacked
diversity, being dominated by Ampelisca palmata, which was extremely abundant
(although this is inadequately reflected by the number of specimens collected
since very small samples were taken at each station). ‘The only other species of
importance in muddy areas were Lysianassa ceratina and Eriopisa epistomata n. sp.

The intertidal sand flats of Shearwater Bay were almost completely barren
of amphipods, with just a few Talorchestia quadrispinosa occurring along the drift
line. The barren nature of the intertidal zone here can probably be attributed
to the extreme heat and high rate of desiccation experienced in the area at
low tide.

The most diverse fauna in the bay was that of rocky areas, where the
greatest diversity of niches was available. Members of the genus Hyale were
abundant, five species of that genus being recorded. Many other species were
locally common, among them Allorchestes inquirendus on seaweeds and Calliopiella
michaelsent under limpets. Further details of amphipod records in rocky areas
of Liideritz Bay may be found in Penrith & Kensley (1970).

As well as the bottom samples mentioned above, a single plankton haul
was taken at night near the town, revealing considerable numbers of Paramoera
capensis and Lysianassa ceratina.

Liideritz station data

Catalogue Date Locality
no.
LU 8 16/7/46 =
LU 33 —/7/57 Intertidal rocks (location not recorded)
LU 34 —/7/57 Intertidal rocks (location not recorded)

LU 36 23/2/63 Redford Bay (mud transect, general sievings)
LU 41 23/2/63 Redford Bay (mud transect, general sievings)
LU 42 23/2/63 Redford Bay (mud transect, general sievings)
LU 44 23/2/63 Redford Bay (mud transect, general sievings)
LU 46 23/2/63 Redford Bay (mud transect, general sievings)
LU 52 24/2/63 Animals from seaweeds, Diaz Point

LU 53 24/2/63 General collection, Diaz Point

LU 54 24/2/63 General collection, Diaz Point

LU 55 24/2/63 Exposed rock, Diaz Point

LU 56 24/2/63 Exposed rock, Diaz Point

LU 57 24/2/63 Exposed rock, Diaz Point

LU 58 24/2/63 Exposed rock, Diaz Point

LU 61 25/2/63 Liideritz township, general collection

LU 64 25/2/63 Shearwater Bay sand transect

THE AMPHIPODA OF SOUTHERN AFRICA 175

Catalogue Date Locality
no.

LU 66 25/2/63 Shearwater Bay sand transect
LU 76 26/2/63 End of Big lagoon, general digging
LU 78 11/2/63 Redford Bay, general mud collection
LU 81 26/2/63 End of Big Lagoon, general collection from muddy rocks
EU 82 26/2/63 End of Big Lagoon, general collection from muddy rocks
LU 86 11/2/63 Diaz Point, general collection, rocks
LU 94 21/2/63 Redford Bay, under muddy stones
LU 97 22/2/63 Shark Island, west side
LU 98 22/2/63 Shark Island, west side
LU 99 22/2/63 Shark Island, west side
LU tor 22/2/63 Shark Island, west side
LU 103 22/2/63 Shark Island, west side
LU 104 22/2/63 Shark Island, west side
LU 105 22/2/63 Shark Island, west side
LU 106 22/2/63 Shark Island, west side
LU 107 22/2/63 Shark Island, west side
LU 108 22/2/63 Shark Island, west side
EU 112 22/2/63 Shark Island, west side, bases of Laminaria
LU 113 22/2/63 Shark Island, west side, bases of Champia
LU 114 22/2/63 Shark Island, west side
LU 121 22/2/63 Plankton haul, Liideritz township, 11 p.m.

‘Africana’ dredges (AFR)

Material collected by vessels of the Division of Sea Fisheries, notably the
R.S. Africana Ii, and donated to the University of Cape Town, is denoted by
the symbol AFR. Few of these samples fall within the region considered here,
and only two of these include amphipods. Three species were recovered from
these samples; Paramoera capensis and Atylus guttatus from 7 m, and Lemboides
crenatipalma from 60 m depth.

Africana station data

Catalogue
no. Date Vessel Locality Depth Substrate
AFR 1278 9/11/48 Palinurus 26°07’S/14°58’E 7 m Sand and mud
AFR 1335 13/11/48 Africana 25°51'S/14°50’E 60m Green mud

South West Africa shore (SWA)

This symbol denotes material collected from the South West African
shore other than the Liideritz area. Amphipoda were collected at only three
SWA stations, five species being recovered, none of them common.

South West Africa shore station data

Catalogue

no. Date Location
SWA 1 -/7/57 Swakopmund—general collection
SWA 2 -/7/57 Elizabeth Bay—general collection

SWA 4 12/7/57 Cape Cross shore—general collection

176 ANNALS OF THE SOUTH AFRICAN MUSEUM

Orange River mouth (OR)

This material was collected when the University of Cape Town Ecological
Survey Team, under Professor A. C. Brown, visited the Orange River mouth in
1956. The results of this survey have been published in detail by Brown (1959).

The Orange River estuary was found to be faunistically barren, indeed
no true estuarine species of any group was found. ‘This paucity can be attributed
to the fact that during the wet season fresh-water flow extends throughout the
system and estuarine conditions cease to exist. Those animals which were
recovered represented either true fresh-water types (found in the upper reaches),
or true marine types (from the sea shore). The only amphipod found, YT alorchestia
quadrispinosa, occurred above the drift line on the beach and amongst the sand
dunes surrounding the river mouth.

Orange River station data
Catalogue
no. Date Location
OR 2 7/7/56 Above H.W.S. at mouth of estuary

SYSTEMATICS

In the following account families and genera are presented in alphabetical
order. No attempt has been made to provide a full list of synonyms or references
for each species, but reference is given to one or more of the better and more
readily available descriptions. Preference has been given to descriptions which
incorporate good figures, or which refer specifically to the southern African
region. Brief diagnostic descriptions are given for those species not described
in Part I of this series. The diagnoses, are intended to differentiate the species
in question from others of the same genus, or in the largest genera (e.g. Ampelisca)
from those members of the genus found in the southern African area.

Diagnoses of Gammaridean families and genera, and keys to generic level,
may be found in J. L. Barnard (1969), 1970). References to all known caprellid
species and species lists for various areas are found in McCain & Steinberg
(1970). ‘Taxonomy within the Caprellidea follows McCain (1970). The type
material of all new species has been placed in the South African Museum,
Cape Town.

The limbs of the pereon are refered to throughout as gnathopods 1 and 2,
followed by pereiopods 1 to 5 (as in K. H. Barnard and J. L. Barnard). It
should be noted that authors such as McCain, Schellenberg and Ledoyer
number pereiopods according to the pereon segments on which they occur,
i.e. gnathopods 1 and 2 followed by pereiopods 3 to 7. The articles of a limb
are numbered from 1 to 7, the coxal plate (whether present or absent) being the
first article. Numbers in brackets following each catalogue number refer to the
number of individuals in that sample. Material from depths of over 1 000 m

is not considered to form a part of the continental fauna and has thus been
excluded,

THE AMPHIPODA OF SOUTHERN AFRICA Or iy |

Suborder GAMMARIDEA
Family Ampeliscidae
Ampelisca brachyceras Walker, 1904
Ampelisca brachyceras Walker, 1904: 252, pl. 2, fig. 13.
Records: SWD aiF (1).

Diagnosis: Antennae subequal, less than $ body length, antenna 2 originating
immediately below 1; gnathopod 1 normal; article 5 of pereiopods 3 and 4
produced postero-distally for ? length of article 6; article 3 of pereiopod 5
longer than article 4, article 4 not lobed posteriorly; hind margin of third
pleonal epimeron convex, lower corner upturned.

Distribution: Ceylon, southern Africa.

Ampelisca brevicornis (Costa, 1853)
Ampelisca brevicornis: Ledoyer, 1967: 123, fig. 2. Reid, 1951: 204-210, figs 9-15.
Records: SWD 44J (10), SWD 46] (9), SWD 47N (33), SWD 48R (3), SWD 490
(47); Liideritz (Schellenberg 1925, Penrith & Kensley 1970).
Diagnosis: Antenna 1 shorter than peduncle of 2, antenna 2 half body length,
its origin well separated from that of antenna 1; gnathopod 1 normal; article 5
of pereiopods 3 and 4 not produced posteriorly-distally; article 3 of pereiopod 5
slightly shorter than article 4, article 4 lobed postero-distally to completely
overlap triangular article 5; hind margin of third pleonal epimeron deeply
bisinuate, lower corner with a large upturned tooth.

Distribution: Cosmopolitan.

Ampelisca fusca Stebbing, 1888
Ampelisca fusca Stebbing, 1888: 1052, 1651, pl. 105.

Records: SWD 84W (6), SWD 88E (1), SWD 86B (common).
Distribution: Mocambique to South West Africa.

Remarks : The present specimens are much larger (12 mm excluding antennae)
than those from the east coast and differ from them in having a distinct red
pigment spot behind the upper pair of eyes and short plumose setae on the inside
of article 2 or pereiopod 5.

Ampelisca palmata K. H. Barnard, 1916
Ampelisca palmata K. H. Barnard, 1916: 136, pl. 28, figs 30-31.

Records: SWD 16K (17), SWD 18C (8), SWD 21G (14), SWD 26G (11),
SWD 27M (11), SWD 33E (448), SWD 36C (116), SWD 37K (188), SWD 4o0L
(5), SWD 41H (7), SWD 44G (1), SWD 45F (1), SWD 48P (2), SWD 51H
(6), SWD 60C (32), SWD 61C (159), SWD 62C (55); LU 46B (21), LU 78E
(Ss), LU 121J (1).

178 ANNALS OF THE SOUTH AFRICAN MUSEUM

Distribution: Senegal to Mocambique.

Remarks: This species is more variable than indicated by Barnard’s description,
in particular the antennae may be considerably shorter than in the type
specimens. This has led to confusion between this species and Ampelisca spinimana
but the two can be readily distinguished by the presence of a produced lobe
on the anterior margin of article 4 of pereiopod 5 in A. palmata.

Ampelisca spinimana Chevreux, 1887

Ampelisca spinimana: Chevreux & Fage, 1925: 81, fig. 73.
Ampelisca spinimana f. aspinosa Schellenberg, 1925: 127.

Records: Liideritz (Schellenberg 1925).

Diagnosis: Antenna 1 slightly exceeding peduncle of 2; antenna 2 less than 4
body length, its origin well separated from that of antenna 1; palm of gnathopod
I spinose (variable); article 5 of pereiopods 3 and 4 not produced postero-
distally; article 3 of pereiopod 5 longer than article 4, article 4 not lobed
anteriorly or posteriorly; hind margin of third pleonal epimeron straight, lower
corner quadrate.

Distribution: Eastern Atlantic.

Family Amphilochidae
Cyproidea ornata Haswell, 1880
Cyproidea ornata: Schellenberg, 1953: 113, fig. 2. Ledoyer, 1967: 125, fig. 4a.
Records: Lideritz, Walvis Bay (Schellenberg 1953).

Diagnosis: Article 3 of gnathopod 2 postero-distally produced into an acute
lobe, terminating in two large spines; article 6 not expanded distally, palm
smooth.

Distribution: Indo-Pacific, extending to South West Africa.

Gitanopsis pusilla K. H. Barnard, 1916
Gitanopsis pusilla K. H. Barnard, 1916: 144.
Records: Swakopmund, Liideritz (Schellenberg 1925); Liideritz (Penrith &
Kensley 1970).
Distribution: Mocambique to South West Africa.

Hoplopleon medusarum K. H. Barnard, 1932
Hoplopleon medusarum K. H. Barnard, 1932: 105, fig. 54.
Records: Liideritz (Penrith & Kensley 1970).
Diagnosis: Hind margin of article 2 of pereiopods 4 and 5 straight; dactyl of
gnathopod 2 simple; palm of gnathopod 2 transverse, concave, defining angle
rounded, bearing four strong spines.
Distribution: Endemic, Saldanha Bay to Liideritz.

THE AMPHIPODA OF SOUTHERN AFRICA 179

Hoplopleon similis Schellenberg, 1953
Hoplopleon similis Schellenberg 1953: 113. fig. 2.

Records: Liideritz (Schellenberg 1953).

Diagnosis: Hind margin of article 2 of pereiopods 4 and 5 straight; dactyl of
gnathopod 2 cut into two teeth; palm of gnathopod 2 transverse, concave,
defined by a single very large spine.

Distribution: Endemic, known only from the above record.

Family Ampithoidae
Ampithoe falsa K. H. Barnard, 1932

Ampithoe brevipes: K. H. Barnard, 1916: 255, pl. 28, fig. 34.
Ampithoe falsa: Ruffo, 1969: 57, figs 18-20.

Records: Liideritz (Penrith & Kensley 1970).

Diagnosis: Article 2 of gnathopod 2 not lobed; article 6 of gnathopod 1 rect-
angular, palm transverse; palm of gnathopod 2 concave but otherwise not
distinct from hind margin, a small rectangular tooth at the finger hinge;
article 2 of pereiopods 1 and 2 ovate, strongly expanded.

Distribution: Gulf of Aden, Arabian Sea, India, southern Africa.

Ampithoe ramond: (Audouin, 1826)

Ampithoe vaillanti: K. H. Barnard, 1916: 253.
Ampithoe ramondi: Ledoyer, 1967: 135, fig. 24.

Records: LU 61Z (1), LU 1128 (2); Liideritz (Penrith & Kensley 1970).

Distribution: Cosmopolitan in warm and temperate seas.

Family Aoridae
Aora typica Kréyer, 1845
Aora typica: Ledoyer, 1967: 131, fig. 15.
Records: LU 112V (2); SWD 51N (1); Liideritz (Schellenberg 1953, Penrith &
Kensley 1970).

Distribution: Cosmopolitan.

Lemboides afer Stebbing, 1895
Lemboides afer: K. H. Barnard, 1932: 222, fig. 137.
Records: SWD 26] (2).

Diagnosis: Pereon of $ with ventral processes on segments 2-6; gnathopod 1 3
palm transverse, a broad denticulate cavity between a strong tooth near finger
hinge and two smaller teeth at defining angle, dactyl hardly exceeding palm;

180 ANNALS OF THE SOUTH AFRICAN MUSEUM

gnathopod 2 palm concave, defined by a large stout spine, dactyl slightly
longer than palm, denticulate.

Distribution: Endemic, False Bay to South West Africa.

Lemboides crenatipalma K. H. Barnard, 1916
Lemboides crenatipalma K. H. Barnard, 1916: 240, pl. 28, figs 9-10.
Records: SWD 13T (4), SWD 21M (2), SWD 58B (8); AFR 1335 (present).

Diagnosis: Pereon of $ without ventral processes; gnathopod 1 g, palm trans-
verse, crenulate, defined by a blunt lobe-like projection; dactyl overlapping
palm; gnathopod 2 palm concave, defined by a long, stout, subacute tooth
with a short spine at its base; dactyl longer than palm, denticulate.

Distribution: Endemic, Saldanha Bay to South West Africa.

Lembos hypacanthus K. H. Barnard, 1916
Lembos hypacanthus K. H. Barnard, 1916: 237, pl. 28, figs 5-6.

Records: SWD 60B (3), SWD 61B (8), SWD 62B (9); Swakopmund (Schellen-
berg 1925). |

Diagnosis: Male pereon segments 3—7 with strong medio-ventral spines; article 6
of gnathopod 1 3 equal to article 5, palm slightly oblique, a small tooth near
the finger hinge and a spiniform process and stout spine at the defining angle,
finger serrate, longer than palm; gnathopod 2 ¢ with distal apex of article 2
produced into a recurved hook.

Distribution: Endemic, Natal to South West Africa.

Lembos teleporus K. H. Barnard, 1955
Lembos teleporus K. H. Barnard, 1955: 94, fig. 47. Ledoyer, 1967: 133, figs 16-17.

Records: SWD 13U (4), SWD a1P (4).

Distribution: Southern Africa, Madagascar.

Family Calliopiidae
Calliopiella michaelsent Schellenberg, 1925
Calliopiella michaelseni Schellenberg, 1925: 147. K. H. Barnard, 1940: 451, fig. 24.
Records: LU 33H (1), LU 81P (2), LU 96C (1), LU 108A (1); SWA 2T (1);
Swakopmund (Schellenberg 1925); Liideritz (Penrith & Kensley 1970).

Diagnosis: Found under limpets, where it is common. Article 6 of gnathopod
2 twice as long as broad, palm oblique, defined by 2-5 large spines, dactyl
cut into 5 teeth, a setule in each notch; uropod 3 with rami equal to peduncle,
spination variable; telson varying from cleft to rounded with age.

THE AMPHIPODA OF SOUTHERN AFRICA 181

Distribution: Endemic, False Bay to South West Africa.

Remarks: Extensive sampling throughout the range of this species has shown it
to be much more variable than was previously thought. Colour varies with the
species of Patella under which the animal lives and there seems to be a preference
for particular hosts. For example, 90% of Patella compressa shelter Calliopiella
of a bright pink to plum colour, whereas 50% of Patella tabularis reveal pale
blue specimens with bright red dorsal stripes. Less favoured species are Patella
barbara (5%, pale brown), P. cochlear (5%, pale brown to green), P. argenvillei
(10%, whitish with green gut), and P. granularis (20%, pale brown to green).
Other species of Patella show an intermediate percentage of amphipods.

In all species of Patella there is a size relationship between the host and
amphipod, specimens of Calliopiella being as large as 17 mm in the largest
Patella compressa. ‘The amphipods are almost always found in pairs, the male
and female being of similar size.

A number of morphological changes with age have been noted, for exam-
ple, in the smallest specimens (4 mm) the telson is up to 40% cleft, a continuous
range being found through notched and emarginate, to smoothly rounded in
the largest specimens (17 mm). The uropods are also extremely variable,
uropod 3 ranging from pointed to rounded and showing a variable number of
spines on its inner surface. Terminal setae may or may not be present.

The number of defining spines on gnathopod 2 varies between 2 and 5.
These morphological changes appear to vary solely with size and are indepen-
dent of the species of Patella occupied.

Metaleptamphopus membrisetata J. L. Barnard, 1961
Metaleptamphopus membrisetata J. L. Barnard, 1961: 105, fig. 73.
Records: 20°04'S/11°56’E, 537 m (J. L. Barnard 1961).

Diagnosis: Antenna 1 longer than antenna 2, accessory flagellum uniarticulate;
upper lip rounded below, not incised; gnathopods subchelate, not greatly
elongate, article 5 slightly shorter than 6; article 7 of pereiopods 1-5 bearing
anterior pectinations in the form of short spines; rami of uropod 3 subequal to
the elongate peduncle, spinose, outer slightly the shorter; telson apically
rounded, smooth.

Distribution: The above record is the only one to date.

Family Corophiidae
Corophium acherusicum Costa, 1857
Corophium acherusicum: Sivaprakasam, 1970): 156, fig. 14.
Records: Liideritz (Penrith & Kensley 1970).

Diagnosis: Article 4 of antenna 2 ¢ distally produced into a large curved tooth
with a smaller tooth on its inner edge; rostrum obsolete, head deeply invagi-

182 ANNALS OF THE SOUTH AFRICAN MUSEUM

nated in dorsal view; article 7 of gnathopod 2 tridentate; pleon segments
coalesced.
Distribution: Cosmopolitan in tropical and temperate seas.

Grandidierella chelata K. H. Barnard, 1951
Grandidierella chelata K. H. Barnard, 1951: 708, fig. 7.

Records: SWD 135 (2).

Diagnosis: Body without ventral spines; coxae 1 and 2 semicircular, very
shallow, not pointed; gnathopod 1 ¢ with article 5 ovoid, lower margin with a
strong spiniform projection proximally and a stout tooth distally, the teeth
becoming further apart with growth; gnathopod 1 @ with article 5 ovate and
article 6 with four strong spines on its lower margin.

Distribution: Endemic, Natal to South West Africa. This is the first record of
this species from the open sea.

Stphonoecetes dellavalle: Stebbing, 1893
Siphonoecetes dellavallei: Stebbing, 1906: 684.
Records: SWD a2tH (1).

Diagnosis: Rostrum acute; eyes well developed; antenna 1 scarcely extending
to the tip of peduncle of antenna 2, flagellum less than half as long as peduncle,
five-articulate; coxa 1 blunt anteriorly.

Distribution: Bay of Naples, southern Africa.

Family Dexaminidae
Atylus guttatus (Costa, 1851)
Nototropis guttatus: Chevreux & Fage, 1925: 194, figs 201-203.

Records: AFR 1278F (1).

Diagnosis: Pereon segment 7 and pleon segments 1-3 each with a single dorsal
carina; urosomite 1 with two teeth separated by a marked slit; composite
urosomite 2-3 with two spinose humps; pereiopod 3 with article 2 moderately
produced postero-distally.

Distribution: Mediterranean, Atlantic.

Atylus swammerdami (Milne-Edwards, 1830)
Atylus swammerdami: Chevreux & Fage 1925: 195, fig. 204.

Records: SWD 16N (3), SWD 21K (3), SWD 26H (3).

Diagnosis: Pereon and pleon dorsally smooth; urosomite 1 with a small dorsal
tooth followed by a much larger one; composite urosomite 2-3 without spinose
humps; pereiopod 3 with article 2 moderately produced.

Distribution: Mediterranean, Atlantic (including south coast of South Africa).

-— eee

THE AMPHIPODA OF SOUTHERN AFRICA 183

Guernea (Guernea) rhomba n. sp.
Pig?

Guernea laevis: K. H. Barnard, 1916: 213-215.
Guernea coalita laevis: Schellenberg, 1953: 118-119 (Liideritz).
Guernea laevis: Penrith & Kensley 1970: 230 (Liideritz).

Description of female (3 mm): Head slightly longer than two pereon segments;
eyes composed of regularly sized, closely compacted ommatidea; article 1 of
antenna 1 lacking a dorsal notch, longer than articles 2 plus 3, flagellum
4-articulate, accessory flagellum not visible; article 4 of antenna 2 lobed
ventrally, distally finely setose, flagellum 3-articulate; palp of maxilla 1 extend-
ing to tip of outer lobe, terminating in five setae; inner plate of maxilla 2 tipped
by seven strong setae, outer plate longer than inner, apex rounded, six long
setae terminally and another on the outer margin.

Coxa 1 60% as long as coxa 2; apex subacute, rounded; articles 5 and 6
of gnathopod 1 subequal, article 5 with a group of strong setae postero-inferiorly,
palm defined by three strong spines; article 2 of gnathopod 2 widening from
its origin, articles 5 and 6 longer than those of gnathopod 1, palm straight,
transverse, defined by four strong spines, a row of small spines along inner
margin of palm; article 5 of pereiopod 1 with six strong spines along its posterior
margin, article 6 with four spines; pereiopod 2 with three strong terminal spines
on article 5 and four posterior and two lateral spines on article 6; article 2 of
pereiopod 3 rhomboidal, anterior margin convex, posterior margin extended
into a subacute process, anterior margin naked, article 4 with a single plumose
seta antero-distally and another postero-distally, articles 5 and 6 terminating
in small spines; article 2 of pereiopod 4 evenly rounded posteriorly, article 4
with a few plumose setae anteriorly, article 5 with two posterior and two
terminal spines; article 2 of pereiopod 5 quadrate, article 4 and 5 with plumose
setae on both posterior and anterior margins, article 6 unarmed.

Pleonal epimera postero-inferiorly rounded; urosomite 1 slightly concave
dorsally, urosomites 2 and 3 fused, not notched, not spinose, evenly rounded
posteriorly; uropod 1 with outer ramus slightly longer than inner, terminating
in two lateral spines and a medial spine which is less than 25% the length of the
ramus (fig. 3F); uropod 2 similar to 1 but shorter; uropod 3 broader than 1
and 2, rami unarmed.

Cuticular ornamentation moderate, fairly strong polygons visible on
article 2 of pereiopods.

Colour (in life): Yellowish, pereon segments 6 and 7 and pleon segment I
bright orange.

Holotype: SAM A2936, female, 3 mm.

Type-locality: Sea Point, near Cape Town, 26 February 1914. This specimen;
rather than one from South West Africa, has been chosen as the holotype as
it is the one erroneously described by K. H. Barnard as G. Jaevis.

ANNALS OF THE SOUTH AFRICAN MUSEUM

184

3)

2)

THE AMPHIPODA OF SOUTHERN AFRICA 185

Remarks: ‘These specimens, although they lie close to Guernea coalita (Norman),
differ from that species in the following respects:

Urosomite 2 plus 3 is not dorsally notched; article 4 of antenna 2 is lobed;
the inner lobe of maxilla 2 has seven rather than two setae; article 2 of pereiopod
3 lacks anterior setae and has a pronounced posterior semiacute process; the
spines on uropods 1 and 2 are much shorter.

The short spines on the uropods of this species also distinguish it from other
members of the subgenus Guernea.

Species of the subgenus Prinassus are distinguished by a retrose dorsal
process on the urosome of the female and a high dorsal keel in the male.

Distribution: Liideritz to Cape Town.

Polycheria atolli Walker, 1905

Polycheria antarctica: K. H. Barnard, 1916: 211.
Polycheria atolli: Ledoyer, 1967: 131, fig. 13a.

Records: Liideritz (Schellenberg 1925).

Distribution: Antarctic and southern oceans, tropical Indian Ocean.

Family Eusiridae
Paramoera bidentata K. H. Barnard, 1932
Paramoera bidentata K. H. Barnard, 1932: 211, figs 118 m, 129.

Records: Liideritz (Penrith & Kensley 1970).

Diagnosis : Rostrum small, acute; post-antennal angle of head acutely produced;
eyes nearly meeting on top of the head; pleon segments 1 and 2 postero-dorsally
produced into subacute triangular teeth; third pleonal epimeron quadrate
with a small postero-inferior point; urosomite 1 with a dorsal transverse
depression medially; apices of telson acute, with 2 unequal spiniferous notches.

Distribution: Endemic, Still Bay to South West Africa.

Paramoera capensis (Dana, 1853)
Paramoera capensis: K. H. Barnard, 1916: 183-186; 1932: 210, figs 118 m, 129.

Records: SWD 16H (18), SWD 26B (190), SWD 27K (2), SWD 30F (1),
SWD 33F (2), SWD 36E (1), SWD 37N (2), SWD 41K (4), SWD 44K (70),
SWD 45E (1), SWD 46K (3), SWD 47P (22), SWD 48M (65), SWD 49R
(75); LU 52H (4), LU 54E (5), LU 57H (1), LU 58M (1), LU 61Z (7),
mvEso® (1), LUigoi) G), LU 101Z (2), LU 11r2R (21), LU 121K (53); AFR
1278E; Swakopmund, Possession Island, Liideritz (Schellenberg 1925);
Liideritz (Penrith & Kensley 1970).

Diagnosis: Rostrum represented by a short point; post-antennal angle of head
rounded-quadrate, not produced; eyes nearly meeting on top of the head; pleon

186 ANNALS OF THE SOUTH AFRICAN MUSEUM

segments lacking teeth; third pleonal epimeron rounded-quadrate with a small
postero-inferior point; urosomite 1 not dorsally depressed; apices of telson
truncate, cut into five to eleven teeth.

Distribution: Atlantic, and Indo-Pacific.

Family Gammaridae
Ceradocus rubromaculatus (Stimpson, 1855)
Ceradocus rubromaculatus: Ledoyer, 1968: 39, fig. 14.

Records: SWD 81E (1); LU 54A (6); Swakopmund, Liideritz (Schellenberg
1925); Liideritz (Penrith & Kensley 1970).

Diagnosis: Pleon segments 1-5 postero-dorsally toothed; pleonal epimera 1-3
strongly serrate posteriorly and slightly serrate below; gnathopod 2 with
article 6 large, palm oblique, defined by a large tooth and with a large flat
topped tooth along its length; rami of uropod 3 large, foliate, subequal, both
margins strongly serrate; telson cleft nearly to base, two spines at apex of each
lobe; colour mottled or banded rose pink.

Distribution: Indo-Pacific, extending to South West Africa.

Elasmopus japonicus Stephensen, 1932

Elasmopus spinimanus (non Walker 1905): K. H. Barnard, 1925: 358.
Elasmopus japonicus: Sivaprakasam, 1968: 278, figs 3-5.

Records: LU 57H (1).

Distribution: Japan, India, southern Africa.

Eriopisa epistomata n. sp.
Fig. 4

Description of male (14 mm): Anterior margin of head concave, eyes absent;
antenna 1 extending to end of body, articles 1 and 2 subequal, article 3 very
short, flagellum 30-40 articulate, twice as long as peduncle, accessory flagellum
of two small articles; antenna 2 less than half as long as 1, article 2 produced
ventrally, articles 4 and 5 subequal, flagellum of one long and two small articles;
primary cutting edge of mandible with five teeth, secondary cutting edge of four
teeth, palp article 3 medially expanded and setose, subequal to article 2; inner
plate of maxilla 1 heavily setose, outer plate with six spines; inner and outer
plates of maxilliped with plumose setae.

Article 4 of gnathopod 1 with a posterior pellucid lobe, articles 5 and 6
subequal, palm evenly convex, dactyl equal to palm; coxa 1 strongly produced
anteriorly; gnathopod 2 much larger than 1, article 5 subtriangular, article 6
oval, palm oblique, irregularly nodulose, convex near finger hinge but concave
proximally, defined by two large spines; dactyl marginally longer than palm;

187

THE AMPHIPODA OF SOUTHERN AFRICA

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‘wu V1 ‘opeur ‘odAjojoy ‘ds -u vyowojsida vsidowuy “b *314

188 ANNALS OF THE SOUTH AFRICAN MUSEUM

branchiae large, extending beyond the end of article 2 of gnathopods; pereio-
pods 1-3 much smaller than 4 and 5, branchiae extending to tip of article 3;
article 2 of pereiopods 4 and 5 expanded, especially that of pereiopod 5;
article 4 of both limbs with 4 or 5 posterior serrations.

Pleonal epimera 1 and 2 rounded-quadrate, ventrally bearing a few
plumose setae; third pleonal epimeron postero-distally produced into an
upturned tooth; peduncle of uropod 1 quadrate in section, dorsal surface
terminating in two spines, inner ramus with one dorsal and two terminal
spines, outer ramus with three dorsal and two terminal spines; uropod 2
shorter than 1 but with similar spination; peduncle of uropod 3 subtriangular,
inner ramus small, oval with two terminal spines; outer ramus as long as plecn
and urosome together, articles 1 and 2 subequal, article 1 distally excavate and
laterally slightly serrate, its distal corners spinose, article 2 with 5 serrations on
each edge and a dense terminal tuft of setae; telson extending to tip of peduncle
of uropod 3, cleft to base, outer margin of each lobe with four spines.

Female: Similar to male but with a smaller second gnathopod, its palm less
deeply concave; antenna 1 shorter than that of male.

Holotype: SAM A13070, male, 14 mm.

Type-locality: SWD 37L, 26°38’S/15°08’E, 11 February 1963, depth 9 m,
substrate dark mud.

Remarks: This species belongs to the group with an elongate article 2 to the
outer ramus of uropod 3. From amongst these species the lack of eyes and pro-
duced third pleonal epimeron distinguish it from E. chilkensis (Chilton) while
the inner plate of maxilla 1 differs from that of E. garthi J. L. Barnard, and the
anteriorly produced coxa 1 from that of E. philippensis Chilton. E. elongata
(Bruzilius) can be distinguished by its lateral cephalic notch.

Material: SWD 27N (8), SWD 30B (25), SWD 33B (31), SWD 36B (13),
SWD 37L (24), SWD 47Q (1), SWD 48N (1), SWD 49T (1); LU 78B (8).

Eriopisella epimera n. sp.
Fig. 5

Description of male (5 mm): Ocular lobes angularly rounded, eyes composed of
about nine well spaced ocelli; article 1 of antenna 1 large, remaining segments
missing; article 2 of antenna 2 ventrally produced, article 4 extending to tip
of article 1 of antenna 1, flagellum 9 articulate; maxilla 2 setose only terminally;
articles 2 and 3 of mandibular palp subequal, article 3 terminally with three
long setae.

Coxa 1 produced forwards as far as rear of eye; coxae 1-4 each with two
small setae in minute notches at antero-distal corners; article 4 of gnathopod 1
finely setose posteriorly, article 6 as long as 5, palm convex, not defined; palm
of gnathopod 2 defined by a large spine and bearing six large spines along its
length, each with a seta on its posterior margin; article 5 of pereiopods 1 and 2

THE AMPHIPODA OF SOUTHERN AFRICA 189

Q
Z
es
y] EZ
ae ——
Lid
fea)

Fig. 5. Eriopisella epimera n. sp., holotype, male, 5 mm.
A. Lateral aspect. B. Maxilla 2. C. Palm of gnathopod 2. D. Uropod 3. E. Telson.

190 ANNALS OF THE SOUTH AFRICAN MUSEUM

with three groups of heavy spines along posterior margins, article 6 with four
groups of spines, dactyl medially constricted, bearing two accessory setae at the
constriction; pereiopods 3—5 with article 2 progressively wider and faintly
serrate posteriorly, a short seta in each notch.

First pleonal epimeron postero-distally quadrate with two long setae on
its outer surface; second pleonal epimeron with about 20 lateral setae; third
pleonal epimeron broadly convex below, posteriorly produced into a large
upturned tooth, scattered setae on its lower external surface; peduncle of
uropod 1 with a large proximal spine on its ventral surface and another large
spine at its apex; rami subequal; outer ramus of uropod 2 slightly shorter than
inner; outer ramus of uropod 3 20% as long as inner ramus, with three terminal
and two lateral spines, inner ramus bi-articulate, article 2 hardly 10% as long
as article 1, article 1 with four lateral fascicles of spines on its inner margin,
four single spines along its outer edge and a terminal group of spines which
extend to the tip of article 2; telson 70% cleft, two large terminal and a small
lateral spine on each lobe.

Female: Exactly like the male except for the possession of brood lamellae.
Ovigerous at 4,5 mm.

Colour (as preserved): Uniform brown.
Holotype: SAM A13071, male, 5 mm.

Type-locality: SWD 13R, 26°35'/15°o1’E, 10 February 1963, depth 71 m,
substrate rocky.

Remarks: ‘The present species is readily distinguishable from Eriopisella capensis
K. H. Barnard and E. pusilla Chevreux by its relatively well-developed eyes
and produced third pleonal epimeron. It lies closer to E. sechellensis Chevreux
and E. nagatai Gurganova, but of these the former has a hirsute article 2 to
pereiopod 5 and a longer article 2 of uropod 3, while in the latter article 2 of
pereiopod 5 overhangs article 3 and articles 5 and 6 of gnathopod 2 are
triangular.

Material: SWD 13R (9).

Maera grossimana (Montagu, 1808)
Maera grossimana: Chevreux & Fage, 1925: 239, figs 248, 250.

Records : Swakopmund (Schellenberg 1925).

Diagnosis: Coxa 1 acutely produced forwards; article 6 of gnathopod 2 longer
than broad, palm oblique, regularly serrate (3) or irregularly notched (9),
defined by a distinct tooth; third pleonal epimeron posteriorly smooth, postero-
distally acutely produced; uropod 2 slightly exceeding 1 and 2, rami equal,
truncate, terminally strongly setose.

Distribution: Mediterranean, Atlantic.

THE AMPHIPODA OF SOUTHERN AFRICA IQ!

Maera hirondellei Chevreux, 1900
Maera hirondellei: Chevreux & Fage, 1925: 241, fig. 252. Reid, 1951: 239, fig. 34.
Records: Liideritz (Penrith & Kensley 1970).

Diagnosis: Coxa 1 acutely produced forwards; article 6 of gnathopod 2 longer
than broad, palm oblique, irregularly toothed but always with a larger tooth
near finger hinge and an acute defining tooth; third pleonal epimeron pos-
teriorly smooth, postero-distally slightly produced; uropod 3 considerably
exceeding 1 and 2, rami subequal, rounded, terminally moderately setose.

Distribution: Eastern Atlantic, Mediterranean.

Maera inaequipes (Costa, 1851)
Maera inaequipes: J. L. Barnard, 1959: 25, pl. 5.
Records : SWD 21J (1), SWD 84Y (1); LU 86X (1), LU 99H (1), LU 112V (2),
LU 114W (1); Ltideritz (Penrith & Kensley 1970).

Distribution: Cosmopolitan in tropical and temperate seas.

Maera vagans K. H. Barnard, 1940

Elasmopus levis K. H. Barnard, 1916: 200, pl. 27, fig. 15.
Maera vagans K. H. Barnard, 1940: 459.

Records: Liideritz (Penrith & Kensley 1970).

Diagnosis: Coxa 1 not acutely produced forwards; article 6 of gnathopod 2
longer than broad, palm oblique, irregularly dentate, most of the teeth bearing
spines; third pleonal epimeron posteriorly smooth, postero-distally slightly
produced; uropod 3 slightly exceeding 1 and 2, rami equal, lanceolate, apices
acute, not setose.

Distribution: Endemic, Mossel Bay to Lideritz.

Megaluropus namaquaeensis Schellenberg, 1953
Megaluropus namaquaeensis Schellenberg, 1953: 117, fig. 5.
Records: SWD 16J (4), SWD 18D (6), SWD 26C (200), SWD 27L (7), SWD
41K (8), SWD 51F (88); Walvis Bay (Schellenberg 1953).
Diagnosis: Gnathopods simple; gnathopod 2 with article 5 medially dilated,
article 6 linear; uropod 3 exceeding uropod 1, rami equal, foliaceous, outer
I-articulate.
Distribution: Endemic, Saldanha Bay to Walvis Bay.

Melita appendiculata (Say, 1818)

Melita fresnelii: K. H. Barnard 1916: 189, pl. 28, fig. 32.
Melita appendiculata: J. L. Barnard 19706: 161, figs 103, 104.

Records: SWD 21N (1), SWD 36G (2), SWD 37Q (1).
Distribution: Cosmopolitan.

192 ANNALS OF THE SOUTH AFRICAN MUSEUM

Melita orgasmos K. H. Barnard, 1940
Melita orgasmos K. H. Barnard 1940: 454. Sivaprakasam, 1966: 114, fig. 12k—m.

Records: LU 54B (11), LU 112V (1); Liideritz (Penrith & Kensley 1970).

Diagnosis: Upper apex of article 6 of gnathopod 1 overhanging base of dacty];
article 6 of gnathopod 2 ¢ longer than broad, palm transverse, shorter than
hind margin, defined by a rounded lobe, otherwise smooth, dactyl normal;
pleon segments 1-3 smooth, 4 produced into a slender median tooth, 5 with two
submedian spines on each side.

Distribution: India, southern Africa.

Melita subchelata (Schellenberg, 1925)
Melita fresnelii var. subchelata Schellenberg, 1925: 153. K. H. Barnard, 1932: 211, fig. 130.
Records: SWD 61F (3), SWD 62F (6); Liideritz (Schellenberg 1925); Walvis
Bay (K. H. Barnard 1932).

Diagnosis: Upper apex of article 6 of gnathopod 1 not produced; article 6 of
gnathopod 2 ¢ broader than long, palm transverse, as long as hind margin,
a single tooth near finger hinge; dactyl massive, inner margin sinuous, distally
hooked; pleon segments all dentate.

Distribution: Endemic to South West Africa.

Family Haustoriidae
Bathyporeta sp.
Bathyporeia gracilis: K. H. Barnard, 1951: 704 [non Sars 1891]

Records: SWD 18A (3), SWD 26L (4), SWD 27M (2), SWD 48Q (1), SWD
51E (11), SWD 56S (2).
Diagnosis: Antenna 2 of adult 3 as long as body; apex of article 1 of antenna 1
broadly rounded with four or five feathery setae on the ventral margin; article 4
of pereiopod 3 expanded.

Distribution: Endemic, False Bay to South West Africa.

Remarks: Barnard’s material has been re-examined by Vader (1970) and found
to differ from B. gracilis Sars, the main point of difference being that in B. gracilis
Sars the antenna 2 dis short, having only 12 flagellar articles. The material lies
close to but is not identical with B. tenuipes and is to be described as a new
species by Vader.

Urothoe grimald: Chevreux, 1895
Urothoe grimaldii: Chevreux & Fage, 1925: 99, fig. 93. K. H. Barnard, 1955: 84, fig. 41b.
Records: SWD 41L (8).

Diagnosis: Accessory flagellum long, five-articulate; gnathopods similar, article

THE AMPHIPODA OF SOUTHERN AFRICA 193

6 elongate, slender, with a short blunt palm; article 5 of pereiopod 3 twice as
wide as long; dactyl shaped like a pruning-knife, six to eight slender spines in a
single row along the front margin.

Distribution: India, eastern Atlantic, Mediterranean.

Family Isaeidae
Photis longidactylus n. sp.
Fig. 6

Description of male (5 mm): Head not quite as long as pereon segment 1; ocular
lobes short, angular; eyes small, dark, composed of closely packed ommatidea;
antenna 1 with ratio of peduncular articles 2:3:2, flagellum 7-articulate,
accessory flagellum absent; antenna 2 equal to 1, article 2 produced ventrally,
articles 4 and 5 equal, flagellum shorter than peduncle, 7-articulate.

Coxa 1 slightly produced forwards, 1,5 times as long as broad, coxae 2-4
similar in shape but slightly longer than coxa 1; article 2 of gnathopod 1
widening rapidly from a narrow attachment, article 6 hardly wider than,
and about 1,2 times as long as article 2; palm slightly excavate, not defined,
dactyl considerably longer than palm, cut into four teeth; gnathopod 2 with
article 6 about 1,5 times as wide as article 2, palm concave, defined by a blunt
process on the inner margin of the palm; dactyl extending beyond this process
about halfway along hind margin of hand and closing outside the defining
process, inner margin of dactyl cut into five teeth; pereiopod 1 longer than 2,
article 4 slightly shorter than article 2, anteriorly hirsute; articles 4 and 5 of
pereiopod 2 wider and stouter than those of pereiopod 1; article 2 of pereiopod 3
subrotund, article 6 distally with one large and one small spine, dactyl with a
pair of accessory cusps; pereiopod 4 similar to 3; pereiopod 5 more elongate
than 3 or 4, dactyl straight with two accessory cusps.

Pleonal epimera 1-3 smoothly rounded; uropods 1-3 terminating on the
same plane; uropod 1 with its subequal lanceolate rami slightly upturned
distally and 2 length of peduncle; outer ramus of uropod 2 slightly shorter that
inner, each with four dorsal spines and one long terminal spine, peduncle with a
single distal spine on dorsal surface; outer ramus of uropod 3 subequal to
peduncle, article 2 very short, with two small terminal spines and a group of
setae lying alongside its origin, inner ramus less than 20% length of outer,
terminating in one short spine; telson subquadrate, one seta at each distal
corner.

Female: Ovigerous at 4 mm. Coxae much longer than those of the male, extend-
ing to end of article 2 of gnathopods and pereiopods. Gnathopods smaller, but
of similar structure to those of the male.

Holotype: SAM A13072, male, 5 mm.

Type-locality: SWD 51L, 26°37'S/15°07’E, 14 February 1963, depth 20 m,
substrate fine muddy sand.

194. ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 6. Photis longidactylus n. sp., holotype, male, 5 mm:
A, Head. B. Mandibular palp. C. Gnathopod 1. D. Gnathopod 2. E. Pereiopod 1. F. Pereiopod 2.

G, Pereiopod 3 with tip of article 6 enlarged. H. Pereiopod 5 with tip enlarged. I. Uropod 3.

J. Telson.

THE AMPHIPODA OF SOUTHERN AFRICA 195

Remarks: Taxonomy of the genus Photis is complicated by the fact that males
appear to pass through a series of developmental stages before attaining their
terminal features. Despite the number of individuals which have been found, I
have been unable to allocate these specimens to any known species. They bear
some relationships to P. africana Schellenberg but have a longer dactyl to
gnathopod 2 and lack a defining spine on gnathopod 1. Amongst southern
African species they can be confused with P. uncinata Barnard, but lack the
antero-distal process on article 2 of gnathopod 2 which characterizes that
species.

Material: SWD 16P (1), SWD 18B (3), SWD 26D (39), SWD 40H (2), SWD
48S (1), SWD 51L (53), SWD 56T (3), SWD 58A (5).

Photis longimanus Walker, 1904
Photis longimanus: K. H. Barnard, 1916: 244. Sivaprakasam, 1970a: 567, fig. 8.

Records: SWD 30C (11), SWD 33C (12), SWD 36F (4), SWD 37M (21),
SWD 51M (4), SWD 61D (21); Liideritz (Schellenberg 1925).

Diagnosis: Gnathopod 2 ¢ with a large terminal rounded lobe on article 2
reaching to the tip of article 3; article 3 with a rounded lobe projecting hori-
zontally inwards, palm very oblique, defined by a strong, elongate curved
tooth, two other smaller teeth along the palmar margin.

Distribution: Southern Africa, India, Ceylon.

Remarks: ‘The palmar teeth of these specimens are much more pronounced than
those figured by Walker (1904) or Sivaprakasam (1970a). The defining tooth
is strongly curved terminally and the other two teeth more elongate. The dactyl
is shorter than the palm, whereas in Barnard’s specimens it extended to the
middle of the hind margin. These differences are probably growth changes —
the present specimens of over 5 mm being larger than those of previous
authors.

Family Ischyroceridae
Ischyrocerus anguipes Kroyer, 1838

Ischyrocerus anguipes: K.H. Barnard, 1916: 264. Schellenberg, 1953: 120, fig. 7a—-c. J. L. Barnard,
1969: fig. 107b.

Records: SWD 21L; LU 52H (1); Liideritz (Schellenberg 1953, Penrith &
Kensley 1970).

Diagnosis: None of pereon segments dorsally carinate; article 2 of gnathopod
2 g-elongate, curved, anteriorly smooth, article 6 extremely large, elongate,
palm almost parallel with convex anterior margin and bearing a broad denti-
culate tooth near finger hinge, dactyl smooth; rami of uropod 3 equal, the
outer minutely hooked apically and bearing four or five small denticles on
upper margin.

Distribution: Atlantic, Indo-Pacific.

196 ANNALS OF THE SOUTH AFRICAN MUSEUM

Ischyrocerus carinatus K. H. Barnard, 1916
Ischyrocerus carinatus K. H. Barnard 1916: 266, pl. 28, fig. 18.
Records: Swakopmund (K. H. Barnard 1916).

Diagnosis: Pereon segments 1, 2, 6 and 7 each with a high mediodorsal carina;
article 2 of gnathopod 2 ¢ remarkably elongate and slender, anterior margin
proximally and distally serrate, article 6 of moderate size, narrow-oval, palm
almost parallel with convex anterior margin and bearing a medial step and a
distal bifid tooth, dactyl smooth; inner ramus of uropod 3 shorter than outer,
outer ramus with an apical recurved spine and two minute dorsal denticles.

Distribution: Endemic, False Bay to South West Africa.

Ischyrocerus ctenophorus Schellenberg, 1953
Ischyrocerus ctenophorus Schellenberg, 1953: 121, fig. 7d—-g.
Records: Liideritz (Schellenberg 1953).

Diagnosis: None of pereon segments dorsally carinate; article 2 of gnathopod
2 2 (g unknown) elongate, anteriorly smooth, article 6 moderately elongate,
palm oblique, defined by a narrow acute tooth, crenulate near finger hinge,
dactyl with combs of setae on both faces; rami of uropod 3 equal, the outer
almost as broad as long, bearing an apical spine and three large dorsal teeth.

Distribution: Endemic, the above record is unique.

Jassa falcata Montagu, 1808
Jassa falcata: Sexton & Reid, 1951: 30-47, pls 4-30. J. L. Barnard, 19694: 155, figs 38-39.
Records: Swakopmund (K. H. Barnard 1916, Schellenberg 1925).

Diagnosis: Article 6 of gnathopod 2 ¢ elongate, hind margin ending in an enor-
mous distally-directed acute process, palm bearing a stout tooth near finger
hinge; rami of uropod 3 half length of peduncle, outer ramus bearing two
dorsal flattened cusps and a large curved basally-immersed terminal spine;
telson dorsally smooth.

Distribution: Cosmopolitan in shallow waters.

Jassa frequens (Chilton, 1883)
Jassa frequens: Schellenberg, 1953: 119, fig. 6.
Records: Liideritz (Schellenberg 1953).

Diagnosis: Article 6 of gnathopod 2 ¢ oblong, hind margin ending in a square
process distal to which the palm is deeply indented, palm otherwise smooth;
rami of uropod 3 almost as long as peduncle, slender, nearly naked; telson with
two or three sharp dorsal denticles.

Distribution: Chile, New Zealand, South West Africa.

THE AMPHIPODA OF SOUTHERN AFRICA 197

Family Leucothoidae
Leucothoe spinicarpa (Abildgaard, 1789)
Leucothoe spinicarpa: K. H. Barnard, 1916: 148. Sivaprakasam 1967: 384, fig. 1.
Records: SWD a21E (6).

Distribution : Cosmopolitan.

Family Liljeborgiidae
Listriella lindae n sp.
bic 7

Description of male (8 mm): Lower anterior corner of head rounded and slightly
produced, eyes oblique-oval, well developed, enclosed in a distinct capsule;
antenna 1 extending to middle of article 4 of antenna 2, articles 1 and 2 of
penducle subequal, article 3 short, flagellum subequal to peduncle, 11-articu-
Tate; accessory flagellum 4-articulate, extending to article 3 of primary
flagellum; antenna 2 as long as pereon, flagellum slightly shorter than peduncle,
15-articulate; article 1 of mandibular palp elongate but shorter than article 2
which is medially bent.

Palm of gnathopod 1 oblique, extremely convex, with a series of alternating
small and large spines along its length, the longer spines with accessory cusps,
hind margin separated from palm by an indistinct step; gnathopod 2 much
larger than 1, palm defined by a single strong spine, finely setose throughout,
a distinct step near, finger-hinge (Fig. 7F); dactyl as long as palm, a distinct
rugose hump on its inner margin opposite the palmar step; pereiopods as in
L. goleta J. L. Barnard.

Third pleonal epimeron upturned with a small notch at the postero-
inferior corner; urosome segment 1 with a small dorsal tooth on its posterior
margin, urosomite 2 with two such teeth; peduncle of uropod 1 with a large
distal spine; rami of uropod 3 subequal, outer narrower than inner and with
a small second article, four fascicles of spines along outer edge of basal article,
inner margin of inner ramus proximally spinose, outer margin with a single
row of small spines, seven strong spines around tip; telson with two large spines
at apex of each lobe.

Colour (as preserved): Pereon and top of head uniform dark, otherwise white.
Holotype: SAM A13073, male, 8 mm.

Type-locality: SWD 40J, 26°36'S/15°06’E, 12 February 1963, depth 35 m,
substrate fine sand.

Remarks: Gnathopod 2 of juveniles and females resembles gnathopod 1 in size
and shape and has a more transverse, less convex palm than the adult male
figured. Small specimens (3 mm) show a distinct dark brown band across
article 3 of antenna 1 and article 4 of antenna 2 as well as various pereiopod
segments.

198 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 7. Listriella lindae n. sp., holotype, male, 8 mm:
A. Antennae 1. B. Antenna 2. C. Mandible. D. Maxilla 1. E. Gnathopod 1 with portion of palm
enlarged. F. Gnathopod 2. G. Uropod 3. H. Telson.

THE AMPHIPODA OF SOUTHERN AFRICA 199

This species can be distinguished from L. albina J. L. Barnard and L. eriopisa
J. L. Barnard by virtue of its well-developed eyes. The very short article 2 of
the outer ramus of uropod 3, the urosomal teeth and the oblique palm of gnatho-
pod 2 male distinguish it from the other species of the genus. The closest known
relative appears to be L. goleta J. L. Barnard but the spination of uropod 3 and
form of gnathopod 2 are different.
Material: SWD 11N (3), SWD 16M (4), SWD 30A (9), SWD 33A (9), SWD
40J (2), SWD 41J (8), SWD 48T (1), SWD 498 (4), SWD 54] (3).

Family Lysianassidae
Amaryllis macrophthalma Haswell, 1880
Amaryllis macrophthalma: K. H. Barnard, 1916: 114.

Records: LU 56B (1), LU 99M (8), LU 101Y (2), LU 112V (1); SWA 2P (1).
Distribution: Indo-Pacific, extending to South West Africa.

Remarks: ‘These specimens display a marked increase of the length of the
flagellum of antenna 1 with size. A specimen of 4 mm had a 14-articulate
flagellum, while one of 10 mm, had 26 articles to its flagellum.

Aristias symbiotica K. H. Barnard 1916
Aristias symbiotica K. H. Barnard, 1916: 122. Schellenberg, 1953: 111.

Records: Liideritz (Schellenberg 1953).
Distribution: Endemic, Mogambique to South West Africa.

Cyphocaris challengeri Stebbing, 1888
Cyphocaris challengeri Stebbing, 1888: 661, pl. 17. Bowman & McCain 1967: 1-14, figs 1-9.

Records: 24°318'12°15’E (K. H. Barnard 1932).

Diagnosis: First pereon segment dorsally humped such that the top of the head
faces forwards, the profile becoming lower and more rounded during develop-
ment; hind margin of article 2 of pereiopod 3 acutely produced to the tip of
article 6, the process having 3—7 teeth on its upper surface, none on its lower;
article 2 of pereiopods 4 and 5 posteriorly cut into 14 and 13 strong teeth
respectively; uropod 3 extending beyond the telson.

Distribution: Cosmopolitan, pelagic 25-2 200+ m.

Lysianassa ceratina (Walker, 1889)

Lysianassa cubensis: K. H. Barnard, 1916: 120.

Lysianassa ceratina: Chevreux & Fage, 1925: 42, fig. 23. Reid, 1951: 194.

Records: SWD 10B (1); LU 8C (1), LU 41B (1), LU 61Z (4), LU 862 (1),
LU 94C (4), LU roryY (2), LU 103M (4), LU 112Q (2), LU 114Y (3), LU 121L
(31); Liideritz (Schellenberg 1925, Penrith & Kensley 1970).

200 ANNALS OF THE SOUTH AFRICAN MUSEUM

Diagnosis: Article 1 of antenna 1 twice as long as wide, a flat lateral tooth on
inner margin, accessory flagellum 5-articulate; eyes large, vertically elongate;
third pleonal epimeron postero-distally rounded; inner ramus of uropod 2
strongly constricted; peduncle of uropod 3 strongly keeled, rami shorter than
peduncle, subequal; telson oval, entire.

Distribution: Eastern Atlantic, Mediterranean, southern Indian Ocean.

Lysianassa minimus (Schellenberg, 1953)
Proannonyx minimus Schellenberg, 1953: 108, fig. 1.

Records: Liideritz, Walvis Bay (Schellenberg 1953).

Diagnosis: Article 1 of antenna 1 twice as long as wide, without lateral tooth,
accessory flagellum 2-articulate; eyes small, round; third pleonal epimeron
postero-distally rounded-quadrate; inner ramus of uropod 2 simple; peduncle
of uropod 3 with a plate-like distal expansion, outer ramus equal to peduncle,
inner ramus shorter than outer; telson rounded, entire.

Distribution: Endemic, known only from the above records.

Lysianassa variegata (Stimpson, 1855)
Lysianassa variegata: Stebbing, 1888: 682, pl. 23.
Records: LU 61Z (1); Liideritz (Penrith & Kensley 1970).

Diagnosis: Article 1 of antenna 1 twice as long as wide, without lateral tooth,
accessory flagellum 4-articulate; eyes large, dark, vertically elongate; third
pleonal epimeron postero-distally upturned with a small tooth; inner ramus of
uropod 2 simple; peduncle of uropod 3 faintly keeled, rami shorter than
peduncle, the outer slightly the longer; telson subquadrate, notched.

Distribution: Africa south of the equator.

Orchomene plicata (Schellenberg, 1925)

Orchomenopsis chilensis: Schellenberg, 1925: 119, fig. 3. K. H. Barnard, 1925: 330.
Orchomenella plicata: K. H. Barnard, 1940: 440.

Records: SWD 26K (24); Liideritz (Schellenberg 1925).

Diagnosis: Eyes elongate oval, nearly meeting on top of head, third pleonal
epimeron quadrate; telson twice as long as broad, ¢ cleft; article 1 of antenna 1
very stout, almost as broad as long and twice as long as articles 2 plus 3, flagel-
lum 10-12 articulate, accessory flagellum 6-articulate; gnathopod 1 stout,
article 2 twice as long as broad, article 5 very short with a narrow apical
posterior lobe, palm transverse, cut into four or five little teeth; lower apex of
article 5 of gnathopod 2 produced into an acute thumb, dactyl straight, closely
fitting; article 4 of pereiopods 3 and 4 strongly expanded posteriorly.

Distribution: Cosmopolitan.

THE AMPHIPODA OF SOUTHERN AFRICA 201

Tryphosella normalis (K. H. Barnard, 1955)
Tryphosa normalis K. H. Barnard, 1955; 80, fig. 39.
Records: SWD 490V (1).

Diagnosis: Eyes absent; third pleonal epimeron postero-inferiorly bluntly
quadrate; first urosomite with a rounded dorsal hump; palm of gnathopod 1
very oblique, almost as long as hind margin, defined by two slender spines;
telson with two pairs of dorsal spines and a pair of small spines at apex of each

lobe.
Distribution: Endemic, False Bay to Liideritz.

Family Ochlesidae
Ochlesis levetzowi Schellenberg, 1953
Ochlesis levetzowi Schellenberg, 1953: 115, fig. 4. J. L. Barnard, 1969): 372, fig. 134a.
Records: Liideritz, Walvis Bay (Schellenberg 1953).

Diagnosis: Maxillipedal palp absent; pleon segments not posteriorly carinate;
third pleonal epimeron postero-inferiorly quadrate, not upturned; peduncular
articles of antenna 1 not ventrally produced.

Distribution: Endemic to South West Africa.

Family Oedicerotidae

Perioculodes longimanus (Bate & Westwood, 1868)
Perioculodes longimanus: Chevreux & Fage, 1925: 162, figs 162-3. Ledoyer, 1967: 127, fig. 7.

Records: SWD 16L (100), SWD 18E (3), SWD 26A (195), SWD 27J (12),
SWD 30D (2), SWD 33D (2), SWD 36D (5), SWD 37R (6), SWD 40K (8)
SWD 41G (15), SWD 46H (1), SWD 49U (1), SWD 51G (125), SWD 56R (1),
SWD 62D (22), SWD 72L (1).

Distribution: Mediterranean, Atlantic and Indian Oceans.

Family Phliantidae
Temnophiias capensis K. H. Barnard, 1916
Temnophlias capensis K. H. Barnard, 1916: 158, pl. 26, figs 25-35.
Records: LU 53M (3).

Diagnosis: Pereon smooth, coxae subrectangular; pleon segment 2 ¢ with a
pair of anterior submedian tubercles, a second pair near the posterior margin,
posterior margin of segment ventrally produced backwards as a rounded lobe
overhanging segment 3; pereiopods 1-3 of ¢ chelate, 4 and 5 simple.

Distribution: Endemic, Still Bay to South West Africa.

202 ANNALS OF THE SOUTH AFRICAN MUSEUM

Family Podoceridae
Laetmatophilus purus Stebbing, 1888
Laetmatophilus purus Stebbing, 1888: 1198, pl. 132. K. H. Barnard, 1916: 274.
Records: SWD 21S (500), SWD 30P (16).

Podocerus africanus K. H. Barnard, 1916
Podocerus africanus K. H. Barnard, 1916: 278, pl. 28, figs 24-25; 1925: 367; 1937: 176, fig. 19.
Records: LU 52G (1).

Diagnosis: Body not carinate, article 4 of gnathopod 2 ¢ strongly and
acutely produced, palm with a short area of plumose setae distally and two
strong teeth near the hinge; antero-distal margin of article 2 of pereiopods 1
and 2 lobed; article 2 of pereiopods 3—5 widest at base and tapering distally.

Distribution: South Arabian coast, Natal to South West Africa.

Podocerus cristatus (Thompson, 1879)
Podocerus cristatus: K. H. Barnard, 1916: 276. J. L. Barnard, 1962: 67, fig. 31.
Records: Swakopmund (Schellenberg 1925).

Distribution: Cosmopolitan in tropical and warm temperate seas.

Family Stenothoidae

Stenothoe valida Dana, 1853

Stenothoe affinis: K. H. Barnard, 1925: 345.
Stenothoe valida: Ledoyer, 1967: 125, fig. 4b. Sivaprakasam, 1967: 373, fig. 2a—b.

Records: LU 112V (1).

Distribution: Cosmopolitan in tropical and temperate seas.

Superfamily TALITROIDEA
Family Hyalidae
Allorchestes inquirendus K. H. Barnard, 1940

Allorchestes inquirendus K. H. Barnard, 1940: 477, fig. 34b-c.

Records: LU 8B (1), LU 55A (1), LU 105C (2), LU 106D (4), LU 107A (1),
LU 108B (1), LU 112P (10) 114X (7); SWA4J (2).

Diagnosis: Article 5 of gnathopod 2 ¢ lobed, the lobe extending between
articles 4 and 5; palm oblique, defined by a pocket-like cavity and two spines,
hind margin quite long.

Distribution: Endemic, Port Elizabeth to South West Africa.

THE AMPHIPODA OF SOUTHERN AFRICA 203

Hyale diastoma K. H. Barnard, 1916
Hyale diastoma K. H. Barnard, 1916: 232, pl. 28, fig. 8.

Records: LU 52F (1), LU 56C (3), LU 57H (1), LU 61W (4), LU goL (1),
LU 103L (4), LU 112V (13); Lideritz (Penrith & Kensley 1970).

Diagnosis: Antenna 1 extending to centre of flagellum of antenna 2, articles 1
and 2 not distally lobed; coxae 1-4 with triangular process at centre
of hind margins; article 2 of gnathopod 2 ¢ with large anterior lobe, article 3
not lobed, palm nearly transverse, sinuous, defined by two spines, dactyl
stout, inner margin sinuous; article 2 of pereiopod 5 subcircular, bearing a
few posterior setiferous indents.

Distribution: Endemic, False Bay to South West Africa.

Hyale grandicornis Kroyer, 1845
Hyale grandicornis: K. H. Barnard, 1916: 230. Stephensen, 1949; 33, figs 14-15. K. H. Barnard,
1955: 93, fig. 46.
Records: LU 331; Liideritz (Penrith & Kensley 1970).

Distribution: Indo-Pacific, southern Atlantic.

Hyale hirtipalma (Dana, 1852)
Hyale hirtipalma: K. H. Barnard, 1916: 234. Stephensen, 1949: 30, fig. 13.

Records: LU 52H (4), LU 54E (1), LU 57H (1), LU 86Y (5), LU 1o1W (1),
LU 106C (1), LU 112N (7); SWA 2N (1); Liideritz (Penrith & Kensley 1970).

Diagnosis: Antenna 1 extending } way along flagellum of antenna 2, articles 1
and 2 not distally lobed; coxae 1-4 with triangular process at centre of hind
margin; article 2 of gnathopod 2 ¢ with a large anterior lobe, article 3 not
lobed, palm very oblique, strongly setose, defined by two spines, dactyl evenly
tapering; article 2 of pereiopod 5 oval, posteriorly faintly crenulate.

Distribution: Pacific, South Atlantic.

Hyale macrodactyla Stebbing, 1899

Hyale macrodactyla: K. H. Barnard, 1916: 235. Sivaprakasam, 1969: 308.

Records: LU 52H (12), LU 54C (26), LU 61Y (15), LU ro1V (5), LU 103 J
Gay EU 112M (22).

Diagnosis: Antenna 1 extending } way along flagellum of antenna 2, articles 1
and 2 not distally lobed; coxae 1-4 posteriorly smooth; articles 2 and 3 of
gnathopod 2 ¢ anteriorly lobed, palm very oblique, bordered on both sides by
rows of slender spinules, defined by two spines in a pocket, dactyl widest
medially, reaching end of article 4; article 2 of pereiopod 5 circular, posteriorly
serrate.

Distribution: India, southern Atlantic.

204. ANNALS OF THE SOUTH AFRICAN MUSEUM

Hyale saldanha Chilton, 1912
Hyale saldanha Chilton, 1912: 509, pl. 2, figs 24-29. K. H. Barnard, 1916: 229, pl. 27, fig. 37.
Records: LU 33S (1), LU 52E (6), LU 54D (6), LU 61X (12), LU 82Q (1),
LU 990K (5), LU 101X (4), LU 103H (13), LU 105B (1), LU 112 L (10);
SWA 1P (6); Liideritz (Schellenberg 1925, Penrith & Kensley 1970).
Diagnosis: Antenna 1 extending 4 way along flagellum of antenna 2, articles 1
and 2 distally lobed; coxae 1-4 posteriorly smooth; articles 2 and 3 of gnatho-
pod 2 g anteriorly lobed, palm oblique, straight except for a small lobe near
the hinge, defined by two spines in a pocket; dactyl evenly tapering, equal to
palm; article 2 of pereiopod 5 circular, smooth.
Distribution: Endemic, East London to South West Africa.

Orchestia rectipalma (K. H. Barnard, 1940)
Parorchestia rectipalma K. H. Barnard, 1940: 473, fig. 32.

Records: LU 34F (15), LU 36B (7).

Diagnosis: Scabrous lobes on articles 4 to 6 of gnathopod 1 4, article 6 of
gnathopod 2 ¢ widest at defining angle, palm straight, separated from the hind
margin by a distinct step carrying a short strong spine, dactyl evenly convex,
fractionally longer than palm; article 2 of pereiopod 5 with very faint setiferous
serrations posteriorly.

Distribution: Endemic, Natal to South West Africa.

Talorchestia australis K. H. Barnard, 1916
Talorchestia australis K. H. Barnard, 1916: 220, pl. 27, figs 33-34; 1940: 470, fig. 30.

Records: Lideritz (Penrith & Kensley 1970).
Distribution: Mocgambique to South West Africa.

Talorchestia quadrispinosa K. H. Barnard, 1916
Talorchestia quadrispinosa K. H. Barnard, 1916: 217, pl. 27, figs 29-32.

Records: LU 8A (1), LU 64C (5), LU 66A (1); OR 2 (fairly common) ; Walvis
Bay, Prince of Wales Bay (Schellenberg 1925); Liideritz (Penrith & Kensley
1970).

Diagnosis: Eyes separated dorsally by less than their diameter; coxa 2 not
lobed; pleon segments 1 and 2 (and sometimes 3) each with 2 medio-dorsal
tubercles in adult g; article 4 of gnathopod 1 ¢ not lobed, article 5 distally
lobed, article 6 shorter than 5, not widening much distally; palm of gnathopod 2
g distally concave, a strong triangular tooth near the hinge, defined by a tuber-
cle from short hind margin; dactyl as long as palm or extending well beyond it,
slightly emarginate proximally.

Distribution: Endemic, False Bay to South West Africa.

THE AMPHIPODA OF SOUTHERN AFRICA 205

Suborder CAPRELLIDEA
Family Caprellidae
Caprella danilevskit Czerniavski, 1868
Caprella danilevskii: Chevreux & Fage, 1925: 454, fig. 432. McCain, 1068: 22-95, figs 10-11.

Records: Swakopmund (K. H. Barnard 1916).

Diagnosis: Head elongate, anteriorly rounded-quadrate; article 2 of gnathopod
2 shorter than pereon segment 2, article 6 elongate, palm oblique, equal to
hind margin, bearing a distal rectangular tooth and defined by a poison tooth,
dactyl shorter than palm; gills elliptical, long axis usually parallel to body,
pereiopods 3-5 lacking grasping spines.

Distribution: Widespread, pan-tropical.

Caprella equilibra Say, 1818
Caprella equilibra: McCain, 1968: 25-30, figs 12-13.

Records: SWD 2iR (37), SWD 26F (1), SWD 27H (3), SWD 39R (38);
Swakopmund (K. H. Barnard 1916).

Distribution: Cosmopolitan 0-300 m.

Capreila penantis Leach, 1814
Caprella penantis: McCain, 1968: 33-40, figs 15-16.

Records: Liideritz (Penrith & Kensley 1970).

Diagnosis: Head short, bearing a large triangular antero-dorsal process; article 2
of gnathopod 2 shorter than pereon segment 2, palm occupying almost whole
length of hand, bearing a rectangular projection near hinge and defined by a
poison tooth, dactyl equal to palm; gills subcircular, pereiopods 3—5 each with
a pair of grasping spines.

Distribution: Cosmopolitan in tropical and temperate seas.

Caprella scaura Templeton, 1836
Caprella scaura: K. H. Barnard, 1925: 371. McCain, 1968: 40-44, figs 17-18.
Records: LU 113N (1).
Distribution: Cosmopolitan.
Family Phtisicidae
Phtisica marina Slabber, 1769
Phtisica marina: K. H. Barnard, 1916: 283. McCain, 1968: 91-97, figs 46-47.

Records: SWD 21Q (12), SWD 26E (3), SWD 39Q (1), LU 121M (1).
Distribution: Atlantic, Black Sea, Mediterranean, east coast of southern Africa.

206 ANNALS OF THE SOUTH AFRICAN MUSEUM

Caprellina longicollis (Nicolet, 1849)
Caprellina longicollis: McCain, 1969: 289, fig. 2.
Records: Liideritz (Penrith & Kensley 1970).

Diagnosis: Body dorsally smooth, a pair of antero-lateral projections on pereon
segments 2 and 3; palm of gnathoped 2 ¢ half as long as hand, cup-shaped
distally; pereiopods 1 and 2 absent, periopod 3 three or four-segmented.

Distribution: Southern oceans, Mediterranean.

Caprellina springer K. H. Barnard, 1916
Caprellina spiniger K. H. Barnard, 1916: 282, pl. 28, fig. 35; 1955: 99.
Records: Lideritz (Penrith & Kensley 1970).

Diagnosis: Pereon segment 3 bearing a forward-directed longitudinally-
bifid dorsal tubercle, segments 2 and 4 sometimes with similar but smaller
tubercles; a pair of antero-lateral spines on pereon segment 2 above insertion
of gnathopod 2; gnathopod 2 as in C. longicollis; pereiopods 1 and 2 absent,
pereiopod 3 of 3 segments.

Distribution: Endemic, False Bay to Lideritz.

SUMMARY

The records of the University of Cape Town Ecological Survey have been
incorporated with the findings of previous workers in listing the known gamma-
ridean and caprellid amphipod fauna of South West Africa south of 20°S.

Eighty-one species are recognized in all. Of these five are presented here as
new to science, namely Guernea rhomba n. sp., Eriopisa epistomata n. sp., Eriopisella
epimera n. sp., Photis longidactylus n. sp. and Listriella lindae n. sp. A further 26
species are recorded from South West Africa for the first time. References and
synonyms are given for all the species and short diagnoses for those not described
in Part I of this series.

ACKNOWLEDGEMENTS

I wish to express my thanks to Professor J. H. Day for his advice and
encouragement throughout the preparation of this paper; also to Mr B. F.
Kensley of the South African Museum, for the loan of type specimens, and
Mr George Branch of the University of Cape Town, for unpublished informa-
tion on the ecology of Calliopiella michaelsent. Financial support for this work was
provided by the South African Council for Scientific and Industrial Research.

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THE AMPHIPODA OF SOUTHERN AFRICA 207

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BARNARD, J. L. 19695. The families and genera of marine gammaridean Amphipoda. Bull. U.S.
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BARNARD, J. L. 1970. The identity of Dexamonica and Prinassus with a revision of Dexaminidae
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BARNARD, K. H. 1916. Contributions to the crustacean fauna of South Africa. 5. The Amphi-
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BARNARD, K. H. 1925. Contributions to the crustacean fauna of South Africa No. 8. Further
additions to the list of Amphipoda. Ann. S. Afr. Mus. 20: 319-380.

BARNARD, K. H. 1932. Amphipoda. ‘Discovery’ Rep. 5: 1-326.

BARNARD, K. H. 1937. Amphipoda. Scient. Rep. John Murray Exped. 1933-34 4: 131-201.

BARNARD, K. H. 1940. Contributions to the crustacean fauna of South Africa. XII. Further
additions to the Tanaidacea, Isopoda and Amphipoda, together with keys for the identifica-
tion of hitherto recorded marine and fresh-water species. Ann. S. Afr. Mus. 32: 381-543.

BARNARD, K. H. 1951. New records and descriptions of new species of isopods and amphipods
from South Africa. Ann. Mag. nat. Hist. (12), 4: 698-709.

BARNARD, K. H. 1955. Additions to the fauna-list of South African Crustacea and Pycnogonida.
Ann. S. Afr. Mus. 43: 1-107.

Bowman, T. E. & McCain, J. C. 1967. Variation and distribution of the pelagic amphipod
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Brown, A. C. 1959. The ecology of South African estuaries 9. Notes on the estuary of the Orange
River. Trans. R. Soc. S. Afr. 35: 463-473.

CHEvREUX, E. & Face, L. 1925. Amphipodes. Faune Fr. 9: 1-448.

CuiLton, C. 1912. The Amphipoda of the Scottish National Antarctic Expedition. Trans.
R. Soc. Edinb. 48: 455-520.

GrirFiTus, C. L. 1973. The Amphipoda of southern Africa. Part I. The Gammaridea and
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LepoyER, M. 1967. Amphipodes gammariens des herbiers de phanérogames marines de la
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LeporEr, M. 1968. Amphipodes gammariens de quelques biotopes de substrat meuble de la
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McCarn, J. C. 1968. The Caprellidae (Crustacea: Amphipoda) of the Western North Atlantic.
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McCann, J. C. 1969. New Zealand Caprellidae (Crustacea: Amphipoda). V.Z. Fl mar. Freshwat.
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McCain, J. C. 1970. Familial taxa within the Caprellidea (Crustacea: Amphipoda). Proc.
biol. Soc. Wash. 82: 837-842.

McCain, J. C. & SrTeEmnBERG, J. E. 1970. Amphipoda 1, Caprellidea 1, Fam. Caprellidae.
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of South West Africa. Part 1: Liideritzbucht. Cimbebasia (A) 1: 191-239.

Rew, D. M. 1951. Report on the Amphipoda (Gammaridea and Caprellidea) of the coast of
tropical West Africa. Atlantide Rep. 2: 189-291.

Rurro, S. 1969. Studi sui crostacei anfipodi. LX VII. Terzo contributo alla conoscenza degli
anfipodi del mar Rosso. Memorie Mus. civ. Stor. nat. Verona 17: 1-77.

Sars, G. O. 1891. An account of the Crustacea of Norway, with short descriptions and figures of all the
species. 1. Amphipoda: 121-142, Pontoporeiidae. Christiania, Copenhagen: Cammermeyers.

SCHELLENBERG, A. 1925. Crustacea VIII: Amphipoda. Beitr. Kennt. Meeresfauna Westafr. 3:
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SCHELLENBURG, A. 1953. Erganzungen zur Amphipodenfauna Siidwest-Afrikas nebst Bemerkun-
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SIVAPRAKASAM, T. E. 1968. A new species and a new record of Amphipoda from the Madras
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SIVAPRAKASAM, T. E. 1969. Amphipoda from the east coast of India. 2. Gammaridea and
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SIVAPRAKASAM, T. E. 1970a. Amphipoda from the east coast of India. 2. 7. Bombay nat. Hist.
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REFERENCES

Harvard system (name and year) to be used: author’s name and year of publication given
in text; full references at the end of the article, arranged alphabetically by names, chronologi-
cally within each name, with suffixes a, b, etc. to the year for more than one paper by the same
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For books give title in italics, edition, volume number, place of publication, publisher.
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BuLLoucn, W. S. 1960. Practical invertebrate anatomy. 2nd ed. London: Macmillan.

FiscHER, P.-H. 1948. Données sur la résistance et de le vitalité des mollusques. 7. Conch., Paris
88: 100-140.

FiscHer, P.-H., Duvat, M. & Rarry, A. 1933. Etudes sur les échanges respiratoires des littorines.
Archs Zool. exp. gén. 74: 627-634.

Konun, A. J. 1960a. Ecological notes on Conus (Mollusca: Gastropoda) in the Trincomalee region
of Ceylon. Ann. Mag. nat. Hist. (13) 2: 309-320.

Koun, A. J. 19606. Spawning behaviour, egg masses and larval development in Conus from the
Indian Ocean. Bull. Bingham oceanogr. Coll. 17 (4): 1-51.

THIELE, J. 1910. Mollusca: B. Polyplacophora, Gastropoda marina, Bivalvia. In: SCHULTZE, L.
Koologische und anthropologische Ergebnisse einer Forschungsreise im westlichen und zentralen Stid-
Afrika. 4: 269-270. Jena: Fischer. Denkschr. med.-naturw. Ges. Jena 16: 269-270.

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2

C. L. Griffiths

THE AMPHIPODA OF SOUTHERN AFRICA
PART 2.

THE GAMMARIDAE AND CAPRELLIDAE OF
SOUTH WEST AFRICA SOUTH OF 20°S

JOT EE

VOLUME 62 PART 7 JANUARY 1974

‘OF THE SOUTH AFRICAN
MUSEUM

| CAPE TOWN

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THE AMPHIPODA OF SOUTHERN AFRICA
PART 3
THE GAMMARIDEA AND CAPRELLIDEA
OF NATAL

By
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THE AMPHIPODA OF SOUTHERN AFRICA

PART 3

THE GAMMARIDEA AND CAPRELLIDEA OF NATAL
By

C. L. GrRiFFITHs

C.S.L.R. Oceanographic Research Umt, University of Cape Town

(With 8 figures)

[MS. accepted 30 April 1973]

CONTENTS

PAGE
Introduction . ; : : : 5 | PX)
The collecting stations 5 ; : 5 AO
Systematics : : : : : 5 ALG)
Gammaridea . : : : 3 220
Caprellidea ; : : : : 254
Summary ‘ : : : ‘ 5 AOI
Acknowledgments. : : : 5 AON
References : é : : : . 261

INTRODUCTION

The aim of this third paper in the series on the benthic Amphipoda of
southern Africa is to bring together existing information concerning the marine
gammaridean and caprellid amphipod fauna of Natal. The main body of data
has been drawn from the collections of the University of Cape Town Ecological
Survey and of the National Institute for Water Research of the South African
Council for Scientific and Industrial Research. To these have been added the
records of previous workers in the area, notably T. R. R. Stebbing (1918),
K. H. Barnard (1916, 1925, 1940) and J. L. Barnard (1961).

A considerable number of estuaries are situated along the Natal coast
and these have been the subject of much of the collecting effort in the area.
As a result the estuarine fauna is well known while the marine environment
has been less thoroughly sampled. Collecting in deeper waters has been par-
ticularly neglected, indeed the area between 200 and 1 000 m remains virtually
untouched and there can be little doubt that many new species await discovery
there.

209

Ann. S. Afr. Mus. 62 (7), 1974: 209-264, 8 figs.

CS" OU i ee

210 ANNALS OF THE SOUTH AFRICAN MUSEUM

The Natal seaboard is of a subtropical type, being warmed by the southerly
flowing Agulhas current. The continental shelf is narrow, except in the stretch
between Richard’s Bay and Durban, and hence the current flows close inshore
and has a profound effect upon the littoral fauna. The mean sea temperature
is in fact maintained at a level some 10°C higher than found at the same latitude
on the west coast, the normal range being between about 25°C in summer
and 19°C in winter.

The collecting areas of the University of Cape Town and National Institute
for Water Research (NIWR) are described briefly below and shown on
Figure 1.

THE COLLECTING STATIONS

The various collections incorporated into this survey are best considered
as falling into two groups—those from estuaries and brack-water lakes,
and those from the open sea. Each of these categories is further divided accord-
ing to the source of the samples.

Samples from the open sea

(a) Collections of the National Institute for Water Research (NIWR)

This series of some 50 benthic samples was collected by the R.V. Meizring
Naudé on behalf of the National Institute for Water Research of the South
African Council for Scientific and Industrial Research. Amphipods were
recovered from 36 of these samples and kindly loaned to the author for identifi-
cation. Examination of the samples revealed 47 recognizable species including
four new to science and two others (Ampelisca miops and Metaprotella macrodacty-
los) previously known only from the holotype. Most of the samples were domi-
nated by burrowing species, the most common being Mandibulophoxus stimpsont,
which was present in 22 of the samples. Other prominent species were Byblis
gaimardi, Microdeutopus thumbellinus n. sp., Ampelisca diadema and Unciolella
spinosa Nn. sp.

Station data for samples containing amphipods are provided below. The
samples were collected on three separate cruises and this is reflected in the
catalogue numbers which are coded: NIWR/cruise/station number, the cruises
being referred to as 1 and 2 and ‘Umlass’ (UM). Thus, station NIWR/1/3 is
the third sample from cruise 1.

N.ILW.R. station data

Catalogue no. Date Location Depth
(m)
NIWR/1/3 15/5/72 28°36’S/32°26’E 55
NIWR/1/5 15/5/72 28°48’S/32°11’E 32
NIWR/1/6 15/5/72 28°48'S/32°11’E 50

NIWR/t1/9 15/5/72 28°56’S/32°01’E 22

THE AMPHIPODA OF SOUTHERN AFRICA Pee |

Catalogue no. Date Location Depth

(m)
NIWR/1/13 15/5/72 29°34'S/31°17’E 48
NIWR/1/14 15/5/72 29°34'S/31°17'E 53
NIWR/1/15 15/5/72 29°34'S/31°17’E 60
NIWR/1/24 15/5/72 30°21’S/30°52’E 52
NIWR/1/26 15/5/72 30°36'S/30°37'E 52
NIWR/1/27 15/5/72 30°37'S/30°40’E 58
NIWR/2/17 19/7/72 30°03'S/30°58’E 52
NIWR/2/18 19/7/72 30°04’S/30°01’E 155
NIWR/2/19 19/7/72 30°13'S/30°49’E 19
NIWR/2/20 19/7/72 30°14'S/30°52’E 44
NIWR/2/21 19/7/72 30°15'S/30°55 E 148
NIWR/2/22 19/7/72 30°19’S/30°45’E 23
NIWR/2/23 19/7/72 30°20'S/30°48’E 60
NIWR/2/24 19/7/72 30°21’S/30°52’E 102
NIWR/2/25 19/7/72 30°35/S/30°35'E 38
NIWR/2/27 19/7/72 30°37'S/30°40’E 71
NIWR/2/28 19/7/72- 30°45 '5/30°29'E 32
NIWR/2/29 19/7/72 30°46'S/30°31E 49
NIWR/2/30 19/7/72 30°47'S/30°33'E 56
NIWR/2/31 19/7/72 30°53'S/30°23E 32
NIWR/2/32 19/7/72 30°53°S/30°26’E 50
NIWR/2/33 19/7/72 30°54’S/30°29’E 86
NIWR/2/35 19/7/72 31°04'S/30°17’E 42
NIWR/2/36 19/7/72 31°05’S/30°19’E 72
NIWR/UM/P5 15/9/70 29°59'S/31°03’E 60
NIWR/UM/03 15/9/70 29°59’S/31°03’E 51
NIWR/UM/R3 15/9/70 29°59S/31°03’E 55
NIWR/UM/P1 15/9/70 29°59'9/31°03’E 25
NIWR/UM/M4 15/9/70 29°59'S/31°03’E 55
NIWR/UM/Mr1 3/11/72 29°59'5/31°03’E 30
NIWR/UM/Ma2 3/11/72 29°59°S/31°03’E 40
NIWR/UM/M3 3/11/72 29°59’S/31°03’E 50

(b) Natal dredge (NAD)

Benthic samples from Natal in the collections of the University of Cape
Town are denoted by this code. To date there are 93 samples in the series,
ranging from 18 to 200 m in depth. Only 24 of the samples include amphipods,
a total of 39 species being recorded. Although this is a considerable number of
species it is notable that 32 of them were recorded only in one sample and that
the total number of individuals is small. This, coupled with the fact that species
most common in the NIWR series (above) are generally poorly represented
or absent in the NAD samples, indicates that a large number of benthic species
are still to be found in the area.

Tube-building forms such as Ampelisca brevicornis, A. spinimana, A. anisuropa
and Photis kapapa dominated sandy and muddy samples in the series, while
Eusiroides monoculodes was common in rocky areas. The two best represented
species in the series, Gammaropsis atlantica and Melita appendiculata occurred in
both hard and soft substrate areas.

Station data for those samples in which amphipods were represented are
given below.

ANNALS OF THE SOUTH AFRICAN MUSEUM

J yy,
AF Richard's Bay

J Umkomaas -™oababa RR.

Scotfburgh¢ Amalangha R.

¥ Port Edward
Up,
)
My
Un,
*

Fig. 1. Collecting stations along the Natal coast. Numbers represent NAD stations.

THE AMPHIPODA OF SOUTHERN AFRICA 213
NAD station data
Catalogue Date Location Depth (xm) Substrate Gear
no.
NAD 4 17/5/58 30°4.7'S/30°29’E 44 Stones —
NAD 7 17/5/58 30°4.7'S/30°29’E 44 Stones —
NAD 11 23/4/58 29°46’S/31°17’E 110 Stones =
NAD 12 23/4/58 29°46’S/31°17’E 110 — —
NAD 15 13/8/58 30°47'S/30°27’E 36 — —
NAD 16 13/8/58 30°47'S/30°27’E 36 — —
NAD 19 12/8/58 29°58/S/31°02’E AQ — —
NAD 27 13/7/59 29°53°S/31°06’E 71 Mud Dredge
NAD 39 9/9/64. 29°35'9/31°38’E 150 Sandy mud Grab
NAD 43 9/9/64 29°34’S/31°39’E 115 Sandy mud Grab
NAD 49 9/9/64 29°35'S/31°42’E 138 Coral, gravel Grab
NAD 56 9/9/64 29°29'5/31°45'E 86 Mud Grab
NAD 57 9/9/64. 29°26’S/31°46’E a] Mud Dredge
NAD 61 9/9/64 29°26’S/31°46’E Gl Mud Grab
NAD 64 9/9/64 29°21'S/31°36’E 57 Shelly sand Dredge
NAD 66 9/9/64. 29°21'S/31°36’E 57 Shelly sand Grab
NAD 70 9/9/64 29°18'S/31°33’E 47 Mud Grab
NAD 72 10/9/64 29°16'S/31°32’E 35 Mud Grab
NAD 81 29/7/64 29°11'S/31°37’E 18 Rock Dredge
NAD 86 29/7/64 29°10'S/31°51’E 43 Sand Trawl
NAD g0 30/7/64 29°11’S/32°02’E 70 Rock shell Dredge
NAD 92 30/7/64 29°10'S/32°05’E 170 Rock, sand Grab

(c) Shore stations

Early shore collections made by the University of Cape Town are denoted
by single letter codes. Five stations in this series fall into our area: Umpangazi
(G), Umhlati (U), Durban (D), Umtwalumi (M) and Port Edward (W).
The records are purely of a presence—absence type, no data on abundance
having been kept. Of the 13 species recorded, Hyale grandicornis and Elasmopus
pectenicrus appear to be the best distributed.

More recently shore samples have been lumped together under a single
code (NA). Only five NA samples include amphipods, 17 species being found
in all. The fact that the last of these samples added eight species to the list gives
some indication of the inadequacy of the sampling coverage to date. ‘The
position at present indicates that the most common rocky intertidal species are
Maera inaequipes, Caprella penantis, Podocerus africanus, fassa falcata and Hyale
grandicornis.

NA station data

Catalogue no. Date Location
NA 189 13/7/56 Port St. Johns, general collection
NA 191 13/7/56 Port St. Johns, general collection
NA 205 13/7/56 Port St. Johns, general collection
NA 243 25/7/72 Umhlanga, general collection from weeds
NA 244 a al GP Scottburgh, general collection from weeds

(d) Anton Bruun dredge (ABD)

A small collection of dredge samples collected by the S.S. Anton Bruun
during 1964 is allocated to this code. Very few of the stations fall into the area

214 ANNALS OF THE SOUTH AFRICAN MUSEUM

under consideration here, and from these only one amphipod, Monoliropus
falcimanus Mayer, is recorded.

ABD station data

Catalogue no. Date Location Depth
ABD 14 8/9/64 29°45’S/31°40’E 440 m

Samples from estuarine areas
(a) Kost Bay (KOS)

A preliminary survey of Kosi Bay has been conducted by Broekhuysen &
Taylor (1959), while details of the benthos of Nhlange and Sifungwe Lakes
have been investigated by Boltt (1969)). The system is composed of a series of
lakes running from south-west to north-east and opening to the sea just south
of the Mocambique border. Two rivers flow into, the uppermost and largest
lake, Lake Nhlange, and this is joined to the smaller Sifungo and Mponowini
Lakes by a narrow winding channel. These in turn communicate with a tidal
basin into which two further rivers discharge and which is connected to the
sea by a short straight channel about 20 m wide.

At the time of Broekhuysen & Taylor’s (1959) original survey the water in
the system was exceptionally clear. Salinity in the tidal basin varied between
10 and 16%, compared with 6-8%, in Mpunowini and Sifungo and 3%, in
Nhlange, while water temperatures fell between 20 and 24°C. Full details of
physical and biological features of the lakes at the time of sampling may be
found in Broekhuysen & Taylor (1959).

In 1966 the Kosi system was flooded during a cyclone which raised the
water level some 2 m before the sandbar at the mouth opened. This inundation
caused a considerable accumulation and subsequent decay of organic matter
in Lake Nhlange and several years passed before the water cleared fully.
Details of the recovery of the lakes after these floods may be found in Boltt
(19695).

Four species of amphipod were recorded in the system by Broekhuysen &
Taylor (1959) and to these Boltt (1966) has added two further benthic species.
Of the six species Urothoe serrulidactylus is found only in the sandy shallows of
Lake Sifungo. Afrochiltonia capensis and Melita zeylanica are distributed through-
out the upper reaches of the system, while Orchestia ancheidos is common along
the driftline. The benthos of the lakes is dominated by Grandidierella bonniert
and Corophium triaenonyx. These two species have increased greatly in both
density and range as conditions have improved following the floods of 1966,
reaching a density of over 1 000 m/sq. in places by 1969.

Kosi Bay station data

Catalogue no. Date Location

KOS 6 18/4/48 Nhlange Lake, shore

KOS 15 12/7/49 Shore of tidal basin

KOS 53 15/7/49 Northern tip of Nhlange Lake

THE AMPHIPODA OF SOUTHERN AFRICA 215

Catalogue no. Date Location

KOS 52 16/7/49 Between tidal basin and Mpunowini Lake
KOS 69 17/7/49 Between tidal basin and Mpunowini Lake
KOS 74 17/7/49 Shore of Mpunowini Lake

KOS 78 18/7/49 Shore of Mpunowini Lake

KOS 81 18/7/49 Shore of Sifungo Lake

KOS 82 18/7/49 Shore of Sifungo Lake

KOS 83 19/7/49 Shore of Sifungo Lake

(b) St. Lucia (STL)

The main body of the St. Lucia system is a saline lake shaped like the
letter H and about 18 km wide by 40 km long, the western limb being known as
False Bay, the crosspiece as Hell’s Gates and the eastern limb as Lake St. Lucia
proper. The eastern limb of the lake is further subdivided into the North Lake
from which elongate shallow South Lake is almost completely separated by an
island known as Fanie’s Island. On the western shore of the South Lake les
the settlement of Charter’s Creek and from its southern tip winds a long narrow
channel some 15 km long and seldom more than 2 m deep. Some 2 km from
the mouth of this channel lies the village of St. Lucia, reached by a bridge
across the channel. At the time of sampling the large Umfolosi River flowed
into the system just before its junction with the sea but the river mouth has
since been diverted south.

Several rivers flow into the main lake, notably the Hluhluwe, flowing into
False Bay and the Mkuze, which enters North Lake. Variations in rainfall and
evaporatien cause wild fluctuations of depth, salinity and substrate in the
system. However, the bottom is chiefly muddy and the depth of the lake
averages I m or less. Salinity is generally higher than that of the sea but falls
violently when the system is flushed by heavy rains. Considerable water tur-
bidity is normal while temperatures generally fall between 20° and 30°C.

Two surveys of the lake system have been undertaken by the University
of Cape Town resulting in the publications of Day, Millard & Broekhuysen
(1953) and Millard & Broekhuysen (1965). Detailed descriptions of the physical
and biological conditions at the times of sampling (1948-51 and 1964—5 respect-
tively) are provided therein. It should be emphasized, however, that conditions
in the lakes have changed considerably since the collections reported upon were
taken. As well as the diversion of the Umfolosi River, the channel has been
dredged to facilitate water movement and faunal migration, and the mouth has
been stabilised by breakwaters. Despite these efforts to improve conditions,
salinity in the system in recent years has risen at times to well in excess of
100%,. This has undoubtedly affected the fauna but the nature of such effects
will only be determined by further sampling.

At the time of sampling eight species of amphipod were found. Afrochiltonia
capensis and Orchestia rectipalma were common in areas of low salinity where
rivers enter the system, while Grandidierella bonnieri and Melita zeylanica appeared
tolerant of conditions of salinity from o-50%, and more. Orchesiia ancheidos
was found along the driftline throughout the system. Also recorded were

216 ANNALS OF THE SOUTH AFRICAN MUSEUM

Corophium triaenonyx, found locally throughout the lakes, Ampelisca anisuropa
from South Lake and Enriopisa chilkensis from mangroves near the mouth.

St. Lucia station data

Catalogue no. Date Location

STL 11 4/7/48 Stony shore, Charters Creek

STL 18 4/7/48 Amongst Zostera, Charters Creek
STL 52 9/7/48 Mouth of estuary, shore collection
STL 67 12/7/48 Drift line near Charters Creek

STL 73 12/7/48 Decaying ostera near Charters Creek
STL 77 15/7/48 Black mud, shore near Charters Creek
STL 89 19/7/48 River mouth, False Bay

STL 1o1 3/7/48 Near Charters Creek, plankton haul
STL 102 19/7/48 Hluhluwe River

STL 135 6/7/49 Amongst ostera, Charters Creek
STL 148 8/7/49 Sandy shore, Charters Creek

SUL Wait 11/7/49 Sandy beach, mouth of estuary

sii 178 19/7/49 Sandy stones, False Bay

STL 188 20/7/49 Plankton haul, False Bay

STL 193 7/2/49 Mangrove swamps near mouth

STL 204 21/1/51 Stomach of fish, Charters Creek
STL 223 20/1/51 Stomach of fish, Charters Creek
STL 232 3/7/64. Seine netting, opposite Charters Creek
STL 243 1/7/64 River mouth, channel

STL 251 24/6/64 South Lake

STL 252 24/6/64 South Lake

STL 270 5/7/64 Rocky shore, South Lake

STL 274 26/6/64 Mangrove swamps above bridge
STL 296 10/1/65 Seine netting above bridge

STL 299 11/1/65 Shore collection, channel

STL 304 12/1/65 Shore collection, channel

STL 309 14/1/65 Seine, North Lake

STL 312 15/1/65 Seine, northern False Bay

STL 317 16/1/65 Shore collections, southern False Bay
STL 318 16/1/65 Shore collection, western False Bay
STL 337 23/1/65 Shore collection, North Lake

STL 339 24/1/65 Charters Creek, seine

STL 342 25/1/65 Shore stations, South Lake

STL 343 25/1/65 Charters Creek

STL 344 25/1/65 Charters Creek

(c) Richard’s Bay (RHB)

Full details of the physical and biotic features of the area are to be found
in Millard & Harrison (1954), but a brief summary is given here for the sake
of convenience. Richard’s Bay is a subtropical estuary situated 28°48’S/32°05’E.
The estuary receives several sizeable rivers and is about 40 sq. km in area,
consisting of a large triangular shallow lake opening to the sea through a narrow
mouth. The body of the lake averages about 1 m depth but has a deeper
perimeter. The bottom is mostly soft mud with a good growth of Zostera and
the banks are generally marshy with occasional areas of mangrove. The channel
flows from the north-east corner of the lake, its bottom changing from mud to
sand as it approaches the sea. An hotel is situated on the north bank of the
channel, while in its centre there is a small island known as Pelican Island.

THE AMPHIPODA OF SOUTHERN AFRICA 27

In parts the channel may be 5 m deep.

Salinity in the main lake usually lies between 18-24%,, varying according
to season. Near the river mouths the salinity decreases to zero, while it increases
to that of sea water along the length of the channel.

A series of sampling expeditions to the lake between 1948 and 1951 by
teams from the University of Cape Town revealed seven species of amphipod.
Grandidierella bonniert was abundant amongst the rich fauna of the Zostera
beds, Gztanopsis pusilla and Melita zeylanica being found in lesser numbers in
the same habitat. Around the shore of the system Orchestia ancheidos was com-
mon while Eriopisa chilkensis was recorded in the mangroves and marshes.
Afrochiltonia capensis and Orchestia rectipalma were to be found in areas of low
salinity where rivers flowed into the lake.

Richard’s Bay station data

Catalogue no. Date Location

RHB 5 21/7/48 Muddy bank opposite hotel

RHB 38 —/2/49 Sandy beach near mouth

RHB 39 26/1/49 Muddy shore, Pelican Island.
RHB 40 24/1/49 Amongst Zostera off Pelican Island
RHB 84 16/7/49 Trawl in Zostera bed

RHB 86 16/7/49 Netting in Zostera bed

RHB 93 17/7/49 Sandy beach below hotel

RHB 109 30/1/49 Muddy sand near mouth

RHB 113 25/1/51 Netting in Zostera, Pelican Island
RHB 114 25/1/51 Netting in shallows of channel
RHB 124 25/1/51 Netting in reeds at river mouth
RHB 127 26/1/51 Netting in mangroves near mouth
RHB 129 26/1/51 Hand-netting at river mouth
RHB 132 26/1/51 Sievings from Zostera near mouth

(d) Durban Bay (DBN)

A description of Durban Bay and its ecology may be found in Day &
Morgans (1956). This landlocked bay has been extensively developed to form
one of the largest harbours in the Southern Hemisphere. The narrow entrance
is guarded by a pier to the north and a breakwater to the south. From the
entrance the bay extends for about 6 km inland having a maximum width of
about 4 km. The north, and much of the south bank, have been developed as a
harbour, but at the time of sampling there were areas of mangrove to the
south-west and large central sandbanks which were relatively undisturbed.

Two small polluted rivers flow into the bay but they do not significantly
lower the salinity or affect tidal flow in the bay as a whole. Surface temperatures
in the system vary between 20-25°C while currents and wave action are slight
except in the entrance.

Durban Bay was visited on four occasions between 1950 and 1952 by
zoologists from the University of Cape Town. The teams collected for about two
weeks on each occasion, netting and dredging in deeper waters and digging or
hand collecting intertidally.

Fifteen species of amphipod are represented in the collections. ‘These

218 ANNALS OF THE SOUTH AFRICAN MUSEUM

predominantly consist of hard-substrate types such as Caprella equilibra, Stenothoe
valida, Podocerus brasiliensis, Elasmopus pectenicrus and Ericthonius brasiliensis, which,
to a large extent, inhabit artificial structures in the bay. Only five of the species
were recorded from soft substrates and none of these were common. Although
the muddy bottoms of the channels were sampled, no amphipods were recorded.

It is evident from these results that the fauna of the bay has been radically
altered by human factors. Dredging and pollution of the channels have
destroyed the benthic fauna of these areas while the intertidal sand flats have
also been adversely affected by oil spillage, bait collecting and the like. The
construction of wharfs has compressed much of the shoreline into vertical
faces which lack the variety of niches found naturally, although favouring the
proliferation of certain species.

Collection stations in the bay are denoted by the symbol DBN, those
stations from which amphipods were recovered are listed below.

Durban Bay station data

Catalogue no. Date Location

DBN 2 7/7/50 Scraped from floating jetty

DBN 44 17/7/50 Amongst shelly sand, edge of channel
DBN 50 18/7/50 From sponge on muddy sand, centre banks
DBN 52 18/7/50 Netting in main channel

DBN 62 20/7/50 Collection from stones at culvert entrances
DBN 77 16/7/50 From Zostera, western shore

DBN 79 22/7/50 Sandy rocks, southern shore

DBN 131 15/1/51 Scrapings from ships hulls

DBN 143 9/1/51 Among algae, North Pier

DBN 158 30/9/51 Sand and drain pipes, southern shore
DBN 165 30/9/51 Intertidal rocks, southern shore

DBN 176 1/10/51 Hard objects at low tide, centre banks
DBN 192 2/10/51 Solid objects on causeway

DBN 199 3/10/51 From rocks, North Pier

DBN 201 3/10/51 From rocks, North Pier

DBN 241 23/4/52 From loose rocks, harbour entrance
DBN 251 24/4/52 Scrapings from buoy, mid channel
DBN 264 25/4/52 Surface of centre banks at low tide
DBN 271 26/4/52 Balanoid zone of pier

DBN 322 28/4/52 Concrete wall, south bank

DBN 371 30/4/52 Concrete wall, harbour entrance
DBN 373 30/4/52 Stones, harbour entrance

DBN 379 1/5/52 Scrapings from hull of launch

DBN 396 24/4/52 Scrapings from ship’s hull

DBN 404 23/4/52 From buoy in channel.

(e) Estuaries in the Umkomaas area (UMK)

The samples in this series were collected from small estuaries between
Durban and Umkomaas. The fast flowing muddy Umkomaas river proved
devoid of amphipods while several species were found in the adjoining relatively
clear estuaries of the Umgababa, Umzimbazi, Amalangha and Isipingo Rivers.

These rivers had estuaries typical of the area in that they are closed most
of the year, breaking through to the sea during summer. Typical amphipods
found under these conditions are Afrochiltonia capensis and Orchestia rectipalma,

THE AMPHIPODA OF SOUTHERN AFRICA 219

found in conditions of low salinity, and Melita zeylanica, Corophium triaenonyx,
Grandidierella bonniert and Grandidierella lignorum, found nearer the mouths.
Orchestia ancheidos is to be found along the banks of these estuaries.

UME station data

Catalogue no. Date Location

UMK 18 29/1/50 Muddy sand near mouth, Umzimbazi River
UMK 19 29/1/50 Stones near mouth, Umzimbazi River
UMK 23 30/1/50 Amongst Zostera near mouth, Umzimbazi River
UMK 24 30/1/50 Shore collection, Umgababa River

UMK 25 30/1/50 Netting 1 km from mouth, Umgababa River
UMK 26 30/1/50 Collection from stones, Umgababa River
UMK 27 30/1/50 Kostera bed, Umgababa River

UMK 29 19/7/47 Grass around mouth, Amalangha River
UMK 33 19/7/50 Sandy bottom of Isipingo River

UMK 35 7/7/46 Umzimbazi River lagoon

(f) Estuaries near Port Shepstone (SHP)

Collections from the Umzimkulu, Umtentwini and Uvongo River estuaries
are incorporated in this series. The clear sandy Uvongo lagoon did not reveal
any amphipods but in the rich muddy Umzimkulu estuary Grandidierella
lignorum was common. Orchestia ancheidos was found commonly around the
banks of the Umtentwini.

SHP station data

Catalogue no. Date Location
SHP 2 22/1/50 Muddy rocks, mouth of Umzimkulu River
SHP 5 22/1/50 Grass on bank of Umtentwini River

(g) Estuaries near Port Edward (EDW)

During a brief visit to the Umtamvuna River estuary, 3 km from Port
Edward, two species of amphipod were recorded. These were Orchestia rectipalma
and Afrochiltonia capensis, which were both found along the driftline near the
mouth of the estuary.

SYSTEMATICS

The systematic text is presented in alphabetical order of families, genera
within each family, and then of species within each genus. Taxonomy follows
J. L. Barnard (1969, 1970a) for the Gammaridea, and McCain (1970) for the
Caprellidea. World species lists of these groups may be found in J. L. Barnard
(1958), and McCain & Steinberg (1970) respectively.

Samples in the collections of the University of Cape Town are labelled
according to a catalogue—sample—species code. Thus all samples from a
particular area are denoted by a letter code, usually a triplet suggesting the
name of the area covered (e.g. RHB for Richard’s Bay). The first sample in
this series is RHB 1 and the species within that sample are labelled RHB 1A,
RHB 1B etc. This system has the advantage of enabling species to be labelled
before their identity is known. Where the number of individuals of a species

220 ANNALS OF THE SOUTH AFRICAN MUSEUM

has been recorded this is given after the catalogue number in brackets. Occa-
sionally only an index of abundance (A—abundant, C—common, P—present)
was recorded, in which case this is provided instead.

All previous records of amphipods from Natal in the literature are also
noted. The location of benthic samples was frequently given by these authors
in a somewhat vague fashion (e.g. ‘off Cape Natal’). In these cases I have given
the location in terms of the latitude/longitude square in which the sample
was taken, followed by the depth. Thus 28/32/100 m indicates a record from
the latitude/longitude square 28°S/32°E at a depth of 100 m. The source of
the record follows the code in brackets. In a few cases in K. H. Barnard’s
papers the material reported on was derived from University of Cape Town
collections. In these cases duplication has been avoided by giving only the
University code.

Analysis is restricted to species occurring in less than 1 000 m of water,
species occurring below this depth being regarded as abyssal, rather than as
members of the South African fauna. Terrestrial and truly fresh-water species
are omitted while estuarine species and those dwelling on the strand are
included. No attempt has been made to provide a full list of synonyms but the
reader is referred to at least one description of each species, preference being
given to those incorporating good figures or pertaining specifically to the
southern African region. Where brief diagnoses are given these are intended to
differentiate the species from others in that genus. Generic diagnoses may be
found in J. L. Barnard (1969b) for gammaridean genera or via McCain &
Steinberg (1970) for caprellid genera. Where no diagnoses are provided here
they may be found in Parts 1 and 2 of this series.

Limbs of the pereon have been referred to throughout as gnathopods
1 and 2, followed by pereiopods 1-5. This follows K. H. Barnard and J. L.
Barnard, but it should be noted that many authors, including McCain, Ledoyer
and Schellenberg number pereiopods according to the pereon segments on
which they occur (i.e. gnathopods 1 and 2 followed by pereiopods 3-7).

T'ype-specimens of all new species have been placed in the South African
Museum, Cape Town.

Suborder GAMMARIDEA
Family Ampeliscidae
Ampelisca anisuropa (Stebbing, 1908)
Byblis anisuropus Stebbing, 1908: 72, pl. 10. K. H. Barnard, 1955: 82, fig. 4ob.
Records: NIWR/1/15B(1), NIWR/2/33C(2); NAD 39B(8), NAD 66T(2).
Diagnosis: Antenna 1 as long as peduncle of antenna 2; antenna 2 as long as
body; anterior margin of head oblique, sinuous; two pairs of eyes, with corneal

lenses; article 3 of pereiopod 5 shorter than 4, article 4 slightly lobed posteriorly,
5 not notched anteriorly, distally lobed to embrace the narrow article 6,

THE AMPHIPODA OF SOUTHERN AFRICA 221

7 minute; third pleonal epimeron postero-distally rounded; pleon segment 4
bearing a triangular dorsal carina.

Distribution: Endemic, Natal to west coast of South Africa.

Remarks : This species is one of three intermediate between Ampelisca and Byblis.
Normally Ampelisca can be distinguished from Byblis by virtue of the longer
telson, which is more than 50 per cent cleft, by the lack of setae on the anterior
margin of article 2 of pereiopod 5 near its junction with article 3, and by the
lamellar article 6 and lanceolate article 7 of pereiopod 5.

Ampelisca byblisoides (K. H. Barnard), Ampelisca subantarctica (Schellenberg)
and Byblis anisuropus Stebbing display a cleft telson, sparse setation of article
2 of pereiopod 5 and a narrow article 6 and minute article 7 of pereiopod 5.
Since two of the species have been assigned previously to Ampelisca [A. sub-
antarctica was moved from Byblis by J. L. Barnard (1966)]| the move proposed
here of B. anisuropus to the genus Ampelisca will enable these two genera to be
clearly distinguishable by the degree of division of the telson and by the density
of setae on pereiopod 5.

Ampelisca brachyceras Walker, 1904

Ampelisca brachyceras Walker, 1904: 252, pl. 2, fig. 13.
Records: NIWR]2/30G(2), NIWR/2/33H(1).

Distribution: Ceylon, southern Africa.

Ampelisca brevicornis (Costa, 1853)
Ampelisca brevicornis: Reid, 1951: 204-210, figs 9-15.

Records: NIWR/1/14C(1), NIWR/UM/Mg4A(1), NIWR/UM/P1A(1), NIWR/
2/33B(3), NIWR/2/36E(8); NAD 27B(3), NAD 43D(1), NAD 61B(1), NAD
86P(1).

Distribution: Mediterranean, Atlantic, Indo-Pacific.

Ampelisca chiltom Stebbing, 1888

Ampelisca chiltoni Stebbing, 1888: 1042, pl. 103. J. L. Barnard, 1961: 61, fig. 31.
Records: NIWR/1/27F(1); NAD 11T(1).

Diagnosis: Antenna 1 as long as peduncle of 2; antenna 2 as long as body;
anterior margin of head almost transverse; two pairs of eyes, with corneal
lenses; article 3 of pereiopod 5 slightly shorter than 4, article 4 slightly lobed
posteriorly, 5 notched anteriorly, not embracing 6, which is almost as wide
as 5, 7 as long as 6; third pleonal epimeron with a small postero-distal tooth;
pleon segment 4 not carinate.

Distribution: Indo-Pacific.

222 ANNALS OF THE SOUTH AFRICAN MUSEUM

Ampelisca diadema (Costa, 1853)

Ampelisca diadema: K. H. Barnard, 1916: 133. Chevreux & Fage, 1925: 82, fig. 74.

Records: NIWR/1/6A(1), NIWR/1/14B(1), NIWR/1/15C(4), NIWR/UM/
D3D, NIWR/UM/R3F(6), NIWR/UM/Me2D(1), NIWR/UM/M3E(2),
NIWR/2/27F(1), NIWR/2/33G(1), © NIWR/2/13A(1), © NIWR/2/14K(1),
NIWR/2/17D(2), =NIWR/2/21C(1), NIWR/2/23D(14); NAD 4X(3);
30/30/24 m (K. H. Barnard 1916).

Distribution: Cosmopolitan.

Ampelisca fusca Stebbing, 1888

Ampelisca fusca Stebbing, 1888: 1052, pl. 105.

Records: NIWR]/2/36G(4).
Distribution: Endemic, Mocgambique to South West Africa.

Ampelisca miops K. H. Barnard, 1916

Ampelisca miops K. H. Barnard, 1916: 134, pl. 26, fig. 6.

Records: NIWR/1/27E(1), NIWR/2/30J(1); 29/31/80 m (K. H. Barnard
1916).

Diagnosis: Antenna 1 slightly exceeding peduncle of 2; antenna 2 as long as
body; anterior margin of head oblique; one pair of eyes with corneal lenses;
article 3 of pereiopod 5 twice as long as 4, article 4 not lobed posteriorly, 5 not
notched anteriorly, slightly produced over 6 anteriorly, 6 wider and much
longer than 5, 7 almost as long as 6; third pleonal epimeron postero-distally
acute, bi-sinuate above; pleon segment 4 with an acute dorsal carina.

Distribution: Endemic to Natal, the above records being the only ones to date.

Ampelisca natalensis K. H. Barnard, 1916

Ampelisca natalensis K. H. Barnard, 1916: 137, pl. 26, fig. 7.

Records: 29/31/200 m, 30/30/48 m (K. H. Barnard 1916).

Diagnosis: Antenna 1 considerably longer than peduncle of 2; antenna 2
shorter than body; anterior margin of head oblique; two pairs of eyes with
corneal lenses; article 3 of pereiopod 5 equal to 4 plus 5, 4 not lobed posteriorly,
5 not notched, not embracing 6 which is equal to 3; 7 almost as long as 6;
third pleonal epimeron postero-distally slightly produced; pleon segment 4
with a slight dorsal keel.

Distribution: Endemic to Natal.

THE AMPHIPODA OF SOUTHERN AFRICA 223

Ampelisca palmata K. H. Barnard, 1916

Ampelisca palmata K. H. Barnard, 1916: 136, pl. 28, figs 30-31.
Records: NIWR/2/24A(1), NIWR/2/36F(4); 29/31/200 m (K. H. Barnard
1916).

Distribution: Southern and west Africa.

Ampelisca spinmmana Chevreux, 1887

Amfpelisca spinimana: Chevreux & Fage, 1925: 81, fig. 73.

Records: NAD 27A(22), NAD 49S(1), NAD 56C(7), NAD 61C(2), NAD
66U(2); NA 189W(1).

Distribution: Eastern Atlantic, extending to Natal.

Byblis gaimardi (Kroyer, 1846)
Byblis gaimardi: Mills, 1971: 367-370, figs 6A, 7.

Records : NIWR/A/3A(1), NIWR/1/14A(2), NIWR/1/15A(2). NIWR/1/26B(2),
NIWR/1/27C(3), NIWR/UM/Me2C(1), NIWR/UM/M3B(3), NIWR
2/27A(5), NIWR/2/30H(1), NIWR/2/36D(9), NIWR/2/23B(5); 29/31/200 m
(K. H. Barnard 1916).

Diagnosis: Front margin of head concave, corneal lenses present; article 4 of
pereiopod 5 more than twice as long as article 3; articles 4 and 5 parallel sided,
5 not embracing 6 distally, 6 almost as long as 5; uropod 3 barely exceeding
1 and 2; telson 20 per cent cleft.

Distribution: North Atlantic, ? Pacific, Arctic, South Africa.

Triodos insignis K. H. Barnard, 1916

Triodos insignis K. H. Barnard, 1916: 140, pl. 26, figs 8-10.

Records : 29/31/2000 m (K. H. Barnard 1916).

Diagnosis: As this genus is monotypic the characters of the genus diagnose the
species. One pair of eyes, antero-ventral corner of head produced; flagellum of
antenna 2 of about 28 articles; article 2 of pereiopod 5 greatly expanded distally,
posterior edge oblique, articles 3 and 4 equal, together equal to 5, 6 narrow,
7 spiniform; pleon with segments 4 and 5 keeled, keels bearing tufts of setae;
telson ovate, cleft nearly to base.

Distribution: The above record is the only one to date.

224 ANNALS OF THE SOUTH AFRICAN MUSEUM

Family Amphilochidae
Amphilochus neapolitanus Della Valle, 1893

Amphilochus neapolitanus: J. L. Barnard, 1962b: 126, fig. 3.
Records: DBN 50D.

Diagnosis: Eyes round or slightly oval, fairly small; antenna 1 extending beyond
peduncle of antenna 2; coxa 1 quadrate; article 5 of gnathopod 1 extending
75 per cent of way along hind margin of 6; gnathopod 2 larger than 1, article
5 produced along entire hind margin of 6, palm transverse; telson much shorter
than peduncle of uropod 3.

Distribution: Cosmopolitan in tropical and temperate seas.

Cyproidea ornata (Haswell, 1880)

Cyproidea ornata: J. L. Barnard, 1972: 21, figs 4-5.

Records: NIWR/2/24G(1), NIWR/2/30Q (1), NIWR/2/36M(1); Port Shepstone
(K. H. Barnard 1925).

Distribution: Indo-Pacific, extending to South West Africa.

Gitanopsis pusilla K. H. Barnard, 1916

Gitanopsis pusilla K. H. Barnard, 1916: 144.

Records : NIWR/1/5B(1), NIWR/1/9A(1), NIWR/1/27M(3),
NIWR/2/24J(1), | NIWR/2/27K(1), NIWR/2/30N(1), | NIWR/2/35B(1),
NIWR/2/36L(5), NIWR/UM/M1C(1); RHB 40B(2).

Distribution: Southern Africa, southern ocean islands.

Family Ampithoidae
Ampithoe africana K. H. Barnard, 1925

Ampithoe africana K. H. Barnard, 1925: 361.

Records: DBN 143D(1), DBN 241V(1), DBN 271D(1), DBN 322F(1); NA
244J(5).

Diagnosis: Antenna 2 strongly setose; article 2 of gnathopods 1 and 2 lobed,
article 6 of gnathopod 1 ovate, palm oblique, sinuate; article 6 of gnathopod
2 ovate-oblong, palm oblique, straight or slightly concave, defining angle obtuse
with a short stout spine, dactyl serrulate; article 2 of pereiopods 1 and 2 not
strongly expanded, twice as long as broad.

Distribution: Endemic, Knysna to Durban.

THE AMPHIPODA OF SOUTHERN AFRICA 225

Cymadusa filosa Savigny, 1818

Cymadusa australis: K. H. Barnard, 1940: 480.
Cymadusa filosa: J. L. Barnard, 1955: 29, fig. 15.

Records: G 13D, G 15D.

Distribution: Circumtropical.

Exampithoe natalensis K. H. Barnard, 1925

Exampithoe natalensis K. H. Barnard, 1925: 363, pl. 34, figs 16, 17.
Records: Port Shepstone (K. H. Barnard 1925).

Diagnosis: This genus is monotypic so the characters of the genus identify the
species. Antenna 1 without accessory flagellum; mandible with slender palp,
molar greatly reduced; gnathopod 1 stouter but shorter than 2; article 6 of
pereiopods 3—5 apically expanded; outer ramus of uropod 3 with two hooks.

Distribution: The above record is the only one to date.

Family Aoridae
Aora typica Kroyer, 1845

Aora typica: Ledoyer, 1967: 131, fig. 15.
Records: Durban (K. H. Barnard 1916).

Distribution: Cosmopolitan.

Lemboides acanthiger K. H. Barnard, 1916

Lemboides acanthiger K. H. Barnard, 1916: 239, pl. 28, figs 7-8.
Records: NAD 27Q(1), NAD 56E(2); 29/31/110 m (K. H. Barnard 1916).

Diagnosis: Ventral surface of pereon segments 3 and 4 with large forwardly-
directed curved spines, smaller spines on segments 5-7; palm of gnathopod
1 oblique, defined by a large acute tooth, dactyl nearly twice as long as palm,
smooth; palm of gnathopod 2 smoothly concave.

Distribution: Endemic; Natal to False Bay.

Lembos hypacanthus K. H. Barnard, 1916

Lembos hypacanthus K. H. Barnard, 1916: 237, pl. 28, figs 5-6.

Records: NAD 43E(t1).
Distribution: Endemic, Natal to South West Africa.

226 ANNALS OF THE SOUTH AFRICAN MUSEUM

Microdeutopus thumbellinus n. sp.
Fig. 2

Description of male (3,5 mm): Head as long as first two pereon segments, ocular
lobes short, acute, eyes large, oval, their centres dark but the peripheries
colourless; (both antennae missing); primary cutting edge of mandible with
four teeth, lacinia mobilis with five teeth, spine row of five spines, molar
quadrate, triturative, palp short and stout, 3—articulate; maxilla 1 with
2-articulate palp exceeding outer plate, palp tipped by nine spines and three
setae, outer plate with 10 terminal spines, inner plate tipped by a single seta;
inner and outer plates of maxilla 2 subequal; maxilliped of normal structure,
bearing 4-articulate palp.

Coxa 1 produced antero-distally into an acute point (Fig. 2A), ventral mar-
gin concave, remaining coxae rounded-quadrate, diminishing in size posteriorly ;
article 2 of gnathopod 1 expanding distally from a narrow base, article 5 greatly
enlarged, its posterior margin distally produced into a single triangular tooth,
an unusual large blunt process arises from the centre of the inner surface of the
article (Fig. 2B), article 6 shorter and considerably narrower than 5, dactyl
subequal to 6; gnathopod 2 subchelate, much smaller than 1, articles 5 and 6
subequal, dactyl slightly exceeding oblique undefined palp; (pereiopods 1-5
missing) ; pereon segments lacking any ventral processes.

Pleonal epimera 1-3 postero-distally rounded; uropods extending equally;
peduncle of uropod 1 (Fig. 2C) bearing four dorsal spines and a large terminal
spine, inner ramus slightly the longer, rami strongly spinose dorsally and ter-
minally; uropod 2 (Fig. 2D) similar to 1 but without a terminal peduncular
spine; uropod 3 (Fig. 2E) with a single dorsal spine on the peduncle, rami sub-
equal, spinose; telson quadrate, fleshy, a short thick spine and two setae at
each distal apex.

Holotype: SAM A13222, male, 3,5 mm.
Type-locality: NIWR/UM/P1E, 15 September 1970; 29°59’S/31°03’E, depth
60 m.

Female: Similar to the male except for the structure of gnathopod 1 (Fig. 2H),
which is like gnathopod 2, and the presence of brood pouches.

Relationships: Adults of this species are easily distinguished by virtue of the
unusual projection arising from the inner surface of article 5 of gnathopod
1 male. In male specimens under 3 mm this process is less obvious (Fig. 2G),
but specimens can still be identified by the lack of accessory teeth on article 5
of gnathopod 1, and by the relative size of article 5 and 6, which features are
unusual for the genus. Microdeutopus damnoniensis (Bate) is probably the most
closely related species but has rounded ocular lobes and smaller eyes, as well
as lacking the process on article 5 of gnathopod 1.

Material: NIWR/UM/P1E(2), NIWR/UM/M1E(2), NIWR/2/21A(1), NIWR/
2/24D(9), NIWR/2/30R(1), NIWR/2/36R(5).

THE AMPHIPODA OF SOUTHERN AFRICA 24549

Fig. 2. Microdeutopus thumbellinus n. sp.
Male, 3,5 mm: A—lateral aspect; B—dorsal view of articles 5—7 of gnathopod 1; C, D, E—
uropods 1, 2, 3; F—telson. Male, 3 mm: G—dorsal view of articles 5~7 of gnathopod 1. Female,
3 mm: H—gnathopod 1; I—gnathopod a2.

228 ANNALS OF THE SOUTH AFRICAN MUSEUM

Family Colomastigidae
Colomastix pusilla Grube, 1864
Colomastix pusilla: J. L. Barnard, 1955: 39-42, fig. 20.
Records: NAD 7B(2).

Distribution: Cosmopolitan in tropical and temperate seas.

Family Corophidae
Cerapus tubularis Say, 1817

Cerapus tubularis: J. L. Barnard, 19625: 61, figs 27-28.

Records: NIWR/2/27E(2), NIWR/2/28A(1), NIWR/2/30L(6); NAD 19C(3);
NA 244K(1); 28/32/165 m (K. H. Barnard 1916 as C. abditus); 29/31/430 m
(J. L. Barnard 1961).

Distribution: Cosmopolitan in warm and temperate seas.

Corophium acherusicum Costa, 1857

Corophium acherusicum: J. L. Barnard, 1971: 59, figs 17, 26.

Records: DBN 50C(P), DBN 131H(P) DBN 176V(2), DBN 251F(1), DBN
271C, DBN 396C(4); Durban Bay (K. H. Barnard 1916).

Distribution: Cosmopolitan in tropical and temperate seas.

Corophium triaenonyx Stebbing, 1904

Corophium triaenonyx Stebbing, 1904: 25, pl. 6A.

Records: STL 252G, STL 296V(3), STL 309G(70), STL 312H(2); UMK
18T(C), UMK 19V(C), UMK 23P(C), UMK 25E(P), UMK 26D(C).
UMK 27P(C); Lake Sibayi (Boltt 1969).

Distribution: Mediterranean, Atlantic and Indian Oceans.

Ericthonius brasiliensis (Dana, 1853)
Ericthonius brasiliensis: J. L. Barnard, 1971: 61, fig. 17E.

Records: DBN 50B(P), DBN 131N(1), DBN 241U(C), DBN 251E(C), DBN
264H(P), DBN 396B(P); NA 243D(1).

Distribution: Cosmopolitan in tropical and temperate seas.

Grandidierella bonniert Stebbing, 1908
Grandidierella bonnieri: Ledoyer, 1967: 137, fig. 28A.

Records: DBN 44M, DBN 50A(P), DBN 52R, DBN 77B(4), DBN 165P(1);
STL 89J(P), STL 1o1B, STL 188A, STL 204F, STL 223A(2), STL 3128(1);

THE AMPHIPODA OF SOUTHERN AFRICA 229

RHB 5G(A), RHB 39A(1), RHB 40A(C), RHB 84D(A), RHB 86L, RHB
rogA(t), RHB i13J(C), RHB 114C(1); UMK 11E(P), UMK 23R(O),
UMK 27M(C); Umlalazi estuary (Hill 1966).

Distribution: Caribbean, Atlantic and Indian Oceans.

Grandidierella lignorum K. H. Barnard, 1935
Grandidierella lignorum K. H. Barnard, 1935: 300, fig. 14.
Records: UMK 18S(A), UMK 238(P), UMK 25D(P), UMK 26F(P), UMK
27C(P), UMK 33D(2); SHP 2A(C); Lake Sibayi (Boltt 1969).
Diagnosis: Pereon segments of male without ventral processes; coxae 1 and 2
sharply pointed antero-distally; article 5 of gnathopod 1 ovoid, a pointed
process on lower distal corner, another on distal margin and a third on hind
margin.

Distribution: Endemic to brack waters on east coast of South Africa.

Siphonoecetes dellavalle: Stebbing, 1893
Siphonoecetes dellavalle:: Chevreux & Fage, 1925: 361, fig. 360.

Records: NIWR/1/26D(3), NIWR/1/27N(1), ©. NIWR/2/21D(1), NIWR/
2/23F(3).
Distribution: Mediterranean, southern Africa.

Siphonoecetes orientalis Walker, 1904
Siphonoecetes orientalis Walker, 1904: 294, pl. 7, fig. 49. K. H. Barnard, 1916: 270.

Records: NAD 86Q (9); 29/31/200 m (K. H. Barnard 1916).
Distribution: Tropical Indo-Pacific.

Unciolella spinosa n. sp.
Pigg 3
Description of male (7 mm): Head as long as first two pereon segments, eyes
fairly large, round, colourless, head produced into a small lobe immediately
below eye; antenna 1 as long as pereon plus pleon, articles 1 and 3 subequal,
each 80 per cent as long as article 2, flagellum shorter than peduncle, g-articu-
late, accessory flagellum of two long articles and one small article; (antenna 2
missing); mandible (Fig. 3B) with triturative molar and 3-articulate palp,
spine row of eight strong spines, articles 2 and 3 of palp slightly longer than
article 1, article 3 with an oblique row of medial plumose setae and a row of
about 25 setae terminally; inner plate of maxilla 1 tipped by a single seta,
outer plate bearing eight serrate spines, palp bi-articulate, terminally bearing
three setae and five spine teeth; inner plate of maxilliped (Fig. 3D) with a row of

230 ANNALS OF THE SOUTH AFRICAN MUSEUM

l/h aimee ag

Fig. 3. Unciolella spinosa n. sp.
Male, 7 mm: A—lateral aspect; B— mandible; C—maxilla 1; D—maxilliped; E—uropod 3;
F—telson.

THE AMPHIPODA OF SOUTHERN AFRICA 231

lateral plumose setae and three terminal spine teeth, outer plate marginally
bearing eight successively longer spine teeth, palp 4-articulate.

Surface of body porcelainous with scattered pits and furrows but these
less marked than in U. foveolata K. H. Barnard, 1955; coxae 1-4 quadrate,
remaining coxae rounded; gnathopod 1 slightly larger than 2, article 2 expand-
ing markedly from its base, article 5 slightly longer than 5, palm oblique,
minutely pectinate, defined by two very large spines, dactyl cut into 3 teeth,
equal to palm; gnathopod 2 resembling 1 but slightly smaller and more elon-
gate, palm pectinate, defined by 2 spines, dactyl serrate; (pereiopods all
missing); pereon segments 3-5 each with a single mid-ventral forwardly
directed spine, spines becoming smaller posteriorly.

Pleonal epimera 1-3 smoothly rounded; uropod 1 large (Fig. 3A), peduncle
with four dorsal spines, rami equal, each with four dorsal and 3-4 terminal
spines; uropod 2 extending as far as 1, exceeding uropod 3 by nearly the whole
length of the rami, outer ramus 70 per cent as long as inner, bearing two
dorsal and two terminal spines; uropod 3 uniramous, much shorter than 1 and 2,
peduncle medially expanded (Fig. 3E), bearing single seta, ramus 1,5 times
peduncle, bearing a single lateral spine, 2-3 terminal setae and a minute second
article which is hardly more than an expanded base to the single large seta
it bears; telson large, fleshy, distally emarginate with a single seta at each apex
and 2 marginal setae on each side.

Holotype: SAM A13217, male 7 mm.

Type-locality: NIWR/1/27P, 15 May 1972, 30°47'S/30°33’E, depth 58 m.
Female: Similar to the male except for the possession of broad plates and the
absence of mid-ventral spines on the pereon segments; ovigerous at 5 mm.
Relationships: There are only two other species in this genus, U. foveolata K. H.
Barnard, 1955 and U. lunula Chevreux, 1910. The present species can be dis-
tinguished from these by the enlarged uropods 1 and 2, which in the other two
species barely exceed uropod 3; by the presence of mid-ventral spines on seg-
ments 3—5 and by the 3-articulate accessory flagellum (this is uni-articulate in
U. lunula and 4-5 articulate in U. foveolata).

Remarks: It is characteristic of this species, and of U. foveolata to which it is
obviously closely related, to autotomize its appendages when preserved. Animals
almost invariably lack antennae and pereiopods, although the gnathopods are
seldom lost. Over 100 individuals of the present species are represented in the
collections of the University of Cape Town, and of these only one, the holotype,
possesses a first antenna enabling it to be described.

The placement of this genus in Corophiidae as opposed to Isaeidae or
Aoridae, to which it could equally well belong, underlines the impossibility
of distinguishing these three families and the necessity for their fusion.
Material: NIWR/1/13B(1), NIWR/1/27P(2), NIWR/UM/PIC(1), NIWR/
UM/P5A(2), NIWR/2/21B(2), NIWR/2/24C(18), © NIWR/2/27D(2),
NIWR/2/30F (1), NIWR/2/36P(9).

232 ANNALS OF THE SOUTH AFRICAN MUSEUM

Family Dexaminidae
Atylus granulosus (Walker, 1904)
Atylus granulosus: Ledoyer, 1967: 127, fig. 8.

Records: NIWR/2/36K(1); 30/30/200 m, 29/32/50 m (K. H. Barnard 1916).

Diagnosis: K. H. Barnard’s (1916) specimens agree with Walker’s (1904) brief
description except that pleon segment 1 as well as 2 and 3 show carinae produced
into small acute teeth posteriorly; the urosomal carinae are much larger than
figured by Ledoyer (1967); urosome segment 1 has a small setiferous notch
followed by a deep depression and a hoodlike arched process, segment 2 plus
3 smoothly arched distally; article 2 of pereiopod 3 postero-distally produced
into a strong curved process extending beyond the tip of article 3.

Distribution: Indian Ocean.

Polycheria atoll1 Walker, 1905
Polycheria atolli: Ledoyer, 1967: 131, fig. 13A.
Records: NIWR/1/14L (1); D 96A; NAD 16P(2).

Distribution: Southern oceans, extending into tropical Indian Ocean.

Family Eusiridae
Eusiroides monoculodes (Haswell, 1880)

Eusiroides monoculodes: J. L. Barnard, 1964: 221, fig. 1.

Records: NAD 4W(2), NAD 81J(2), NAD 191G(2); 30/30/24 m, 29/31/100 m
(K. H. Barnard 1916).

Distribution: Cosmopolitan.

Paramoera capensis (Dana, 1853)

Paramoera capensis: K. H. Barnard, 1916: 183-186.
Paramoera schizurus Stebbing, 1918: 66, pl. 10.

Records: D 261; M 19F; Durban (Stebbing 1918); Port Shepstone (K. H.
Barnard 1940).

Distribution: Atlantic, Indo-Pacific.

Rhachotropis grimaldi: Chevreux, 1887
Rhachotropis grimaldii: K. H. Barnard, 1916: 179.
Records: 29/3/800 m (K. H. Barnard 1916).

Diagnosis: Pereon not carinate but segment 7 in male with a small median
tooth; pleon segments 1-3 dorsally tricarinate, all the carinae ending in acute

THE AMPHIPODA OF SOUTHERN AFRICA 233

scarcely-upturned teeth, pleon segment 4 with a single median carina; article
2 of pereiopod 5 with serrate hind margin, postero-distal angle rounded; pleonal
epimera 2 and 3 posteriorly serrate.

Distribution: Atlantic, extending to Natal.

Family Gammaridae

Ceradocus natalensis n. sp.
Biga4

Description of male (10 mm): Head slightly shorter than two pereon segments, a
pronounced slit below the eye, which is large and dark; antenna 1 reaching
end of pereon, articles 1 and 2 subequal, 3 short, flagellum of 20-25 articles,
accessory flagellum of about nine articles; antenna 2 slightly shorter than
antenna I, article 2 produced ventrally to tip of article 3; article 1 of mandibular
palp with inner margin distally produced, article 3 slightly less than half
length of article 2 (Fig 4D), inner plate of maxilla 1 densely setose, outer plate
armed with forked and serrate spines, palp with about 11 apical setae; inner
plate of maxilla 2 densely setose medially and terminally; outer plate of
maxilliped armed with serrate spines.

Coxa 1 acutely produced anteriorly, lower margin with a few fine setae;
article 2 of gnathopod 1 expanded just below its origin, articles 5 and 6 sub-
equal and densely setose posteriorly; palm oblique, setose, not defined; dactyl
equal to palm (Fig. 4A); gnathopod 2 differing on the two sides, that of the
left side very large, article 2 anteriorly keeled, article 5 cup-shaped, 6 very large;
palm transverse with a strong defining tooth, a few irregular crenulations and
then a square topped tooth and a step near the finger hinge; dactyl as long as
palm, abruptly constricted near its origin to fit the step in palm; gnathopod 2
of right side much smaller, article 6 less than twice length of 5, palm oblique,
convex; dactyl equal to palm, not constricted; pereiopod 1 slightly longer than 2
(pereiopods 3-5 missing).

Pleon segments 1-3 with posterior margins dorsally serrate; segments |
and 2 with 6 teeth on each side, the central pair the smallest and the second
pair the largest; third pleon segment also with 6 pairs of teeth dorsally, the most
lateral pair the largest; first pleonal epimeron with a tooth at postero-inferior
corner and a much smaller one above and below it, an oblique ridge runs across
the epimeron to the corner tooth; second pleonal epimeron similar but with
two teeth on posterior margin; third pleonal epimeron without oblique ridge,
three teeth on lower margin, a larger one at postero-inferior corner, and five
along the posterior margin; pleon segment 4 with a flat-lying mid-dorsal tooth
flanked by a pair of much larger upstanding teeth; pleon segment 5 smooth
mid-dorsally, with three pairs of small lateral teeth; uropod 1 extending slightly
beyond uropod 2, rami equal, subequal to peduncle; outer ramus of uropod 2
slightly shorter than inner; uropod 3 (Fig. 4F) extending well beyond 1 and 2,

234 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 4. Ceradocus natalensis n. sp.
Male, 10 mm: A—lateral aspect; B— maxilla 1; C—maxilla 2; D—mandible; E—maxilliped;
F—uropod 3; G—telson.

THE AMPHIPODA OF SOUTHERN AFRICA 235

rami broad, subequal, heavily spinose; telson cleft almost to base, each lobe
with four plumose setae on lateral margin and three long terminal spines, three
small spines lying at bases of long spines. (Fig. 4G).

Holotype: SAM A13164, male 10 mm.

Type-locality: NAD 4N, 30°47’'S/30°29’E, 17 May 1958, depth 44 m, substrate

stones.

Relationships: The genus Ceradocus was revised by Sheard (1939). The present
species falls into his subgenus Denticeradocus by virtue of its multi-dentate pleon
segments. It can be distinguished from other species in the group by details
of pleonal armature and structure of the telson, as well as by the shape of
gnathopod 2. Closely related species include Ceradocus chevreuxt Sheard, which
has five large spines on each lobe of the telson, and C. hawaiensis J. L. Barnard
which has two spines at each telsonic apex and a more strongly toothed second
gnathopod.

Material: NAD 4N, two males.

Cerodocus rubromaculatus (Stimpson, 1885)
Cerodocus rubromaculatus : J. L. Barnard, 1972: 220, fig. 129.
Records: NIWR/1/27B(1), NIWR/UM/R3A(1); NAD 4T(4).
Distribution: Indo-Pacific, extending to South West Africa.

Elasmopus affinis Della Valle, 1893
Elasmopus afinis: Sars, 1895: 521, pl. 183.
Records: NAD 7A(1).

Distribution: Mediterranean, Atlantic, southern Indian Ocean.

Elasmopus japonicus Stephensen, 1932
Elasmopus japonicus Stephensen, 1932: 490, figs 1-2. Sivaprakasam, 1968: 278, figs 3-5.

Records: D 273; Durban (K. H. Barnard 1925 as E. spinimanus); Isipingo
(K. H. Barnard 1940).

Distribution: Japan, India, southern Africa.

Elasmopus pectenicrus Bate, 1862
Elasmopus pectenictus: J. L. Barnard, 19706: 125, figs 73-74.

Records: DBN 2V, DBN 62G(C), DBN 79A, DBN 131G(C), DBN 158X(1),
DBN 176U(3), DBN 192L(1), DBN 199V(C), DBN 201H(3), DBN 241T(Q),
DBN 251D(C), DBN 264L, DBN 396A(C), DBN 371E(1), DBN 379B(FC);
G 15H; U 28F; M 19D; Durban (K. H. Barnard 1916).

236 ANNALS OF THE SOUTH AFRICAN MUSEUM

Diagnosis: Eyes without black pigment; outer ramus of uropod 3 lacking
article 2, inner ramus # outer; telson of medium length, apices truncate, with
4-6 apical spines; gnathopod 2 male with hirsute, S-shaped, undefined palm,
a small process distally and a ridge on inner proximal surface; dactyl simple,
curved, longer than palm; article 2 of pereiopod 4 male postero-distally excavate
and serrate.

Distribution: Cosmopolitan in tropical and temperate seas.

Eniopisa chilkensis (Chilton, 1921)
Niphargus chilkensis Chilton, 1921: 531, fig. 4.
Records: RHB 127J(1); STL 193A(1).

Diagnosis: Eyes small, irregular; head without lateral cephalic notch; article
4 of gnathopod 1 produced posteriorly into a rounded lobe; palm of gnatho-
pod 2 oblique, sinous, sub-equal to hind margin; articles 1 and 2 of outer
ramus of uropod 3 subequal; pleonal epimera 1 and 2 not setose, third pleonal
epimeron postero-distally quadrate, slightly produced; telson cleft to base, a
single stout seta at apex of each lobe.

Distribution: India, east coast of South Africa.

Maera hamigera (Haswell, 1880)

Maera hamigera: K. H. Barnard, 1916: 196 pl. 27, figs 11-12. J. L. Barnard, 1965: 507, fig 16.

Records: NIWR/1/26G(1), NIWR/2/27J(1); 29/31/170 m (K. H. Barnard
i @)i(0)),
Distribution: Indo-Pacific.

Maera inaequipes Costa, 1851
Maera inaequipes: J. L. Barnard, 1959: 25, pl. 5.
Records: NIWR/1/27L(2), NIWR/2/36J(1); NA 189X(12), NA _ 191F(3),
NA 205K(1); M 19G.

Distribution: Cosmopolitan in tropical and temperate seas.

Mallacoota subcarinata (Haswell, 1880)

Maera subcarinata: K. H. Barnard, 1940: 460, fig. 26.
Mallacoota subcarinata: J. L. Barnard, 1972: 247, figs 144-145.

Records: D 117; NAD 16R(g2); ‘Natal’ (K. H. Barnard 1940).
Distribution: Mediterranean, Indo-Pacific.
Remarks: J. L. Barnard (1972) has redefined the genus Maera such that species

with paired dorsal carinae on pleon segment 4 are transferred to a new genus,

Mallacoota. M. subcarinata is the only species from South Africa affected by
this change.

THE AMPHIPODA OF SOUTHERN AFRICA 237

Megaluropus namaquaeensis Schellenberg, 1953

Megaluropus namaquaeensis Schellenberg, 1953: 117, fig. 5.

Records: NIWR/UM/M1D(1).
Distribution: Endemic, Natal to South West Africa.

Melita appendiculata Say, 1818

Melita appendiculata: J. L. Barnard, 1970b: 161, figs 103-104.

Records: NAD 4L(180), NAD 56B(11), NAD 66S(1), NAD 81G(6); DBN
131L(1), DBN 396D(3); Durban, 29/31/54 m, ‘Morewood Cove’ 50 m (K. H.
Barnard 1916 as M. fresnelit).

Distribution: Cosmopolitan.

Melita zeylanica Stebbing, 1904

Melita zeylanica: J. L. Barnard, 1972: 235, figs 139-141.

Records: DBN 373Y(2); STL 89H(C), STL 179E(P), STL 243U, STL 251L,
STL 274G, STL 296UG0), STL 299Y(A), STL 302N(6), STL 305E(A),
SMenIoG . OLL, o18C(1), STL 337B(6), SIL 33q9UGQ), STL 343F(11),
STL 343K(2), STL 344D(A); KOS 53G(P), KOS 62C(1), KOS 69F (19),
KOS 74D(11), KOS 78F(18), KOS 82D(C), KOS 83N(3); RHB 5H(1),
RHB 4o0C(2), RHB 84E, RHB 114C(1); UMK 18Q0(C), UMK 19U(Q),
UMK 230(P), UMK 26E(C), UMK 27K(P), UMK a29B(P), UMK 35];
Umlalazi estuary (Hill 1966).

Distribution: Indo-Pacific region, in brack water.

Family Haustoriidae

Platyischnopus herdmant Walker, 1904

Platyischnopus capensis K. H. Barnard, 1925: 338, pl. 34, figs 13, 14.
Platyischnopus herdmani: Rabindranath, 1971: 521, figs 1, 2.

Records: NIWR/1/14,J(1).

Diagnosis: Head longer than first four pereon segments, rostrum oblong,
anteriorly rounded, encircled basally by weak spines, eyes present, sub-
cutaneous, without ocelli; third pleonal epimeron postero-distally produced
and upturned, pleon segment 3 with large medio-dorsal tooth and three lateral
teeth on each side.

Distribution: India, South Africa.

238 ANNALS OF THE SOUTH AFRICAN MUSEUM

Urothoe coxalis n. sp.

Fig. 5

Description of male (2,5 mm): Head equal to first three pereon segments, eyes
small, round; antenna 1 with 4-articulate flagellum, accessory flagellum 2-articu-
late; antenna 2 about half length of body, flagellum of 15 rather broad arti-
cles; palp of maxilla 1 bi-articulate, tipped by three plumose setae, outer plate
terminally bearing about eight strong spines, inner plate with a single terminal
seta; mandible with large smooth molar and 3-articulate palp; articles 2 and 3
of palp subequal, twice length of 1; maxilliped with 4-articulate palp, article 2
densely setose medially, outer plate of maxilliped with four spine teeth on inner
margin, inner plate terminally with three spines and four setae.

Coxa I, narrow, evenly tapering to an acute point; coxa 2 slightly pro-
duced posteriorly and bearing three setae postero-distally; coxa 3 similar to
2; coxa 4 (Fig. 5G) hugely produced postero-distally into an acute upturned
tooth, apex of the tooth extending beyond the posterior margin of coxa 5,
coxa 5 bilobate, 6 and 7 rounded; gnathopod 1 (Fig. 5F) simple, article 5
expanded posteriorly, longer and twice as wide as 6; gnathopod 2 (Fig. 5E)
slightly chelate, article 6 widening medially; pereiopods 1 and 2 with dactyl
nodulose, article 6 strongly spinose postero-distally; pereiopod 3 (Fig. 5H, I)
with article 2 quadrate, 4 with four antero-distal spines, 5 14 times as wide as
long, two groups of spines anteriorly, the proximal group of six spines and the
distal group of five, also two groups of five and six spines on posterior margin,
article 6 with three anterior fascicles of three, five and three spines and two
posterior groups of four and three spines, dactyl broad, bearing two very
strong spines in notches on its anterior border, below which it is minutely
serrulate; pereiopods 4 and 5 not greatly expanded, posterior margin of
article 2 bearing a few scattered plumose setae, dactyl bearing nodules on
anterior margin.

First pleonal epimeron rounded postero-distally, second slightly produced,
bearing long plumose setae on exterior surface, third pleonal epimeron strongly
produced into an acute point above which it is bisinuate; uropods 1 and 2
with rami equal, unarmed; peduncle of uropod 3 (Fig. 5L) quadrate, rami
broadly foliacious, bearing long plumose setae marginally, outer ramus with
a small article 2; telson (Fig. 5M) slightly exceeding peduncle of uropod 3,
cleft to base, each lobe terminating in a single spine and a plumose seta.

Holotype: SAM A13211, male, 2,5 m.
T ype-locality: NIWR/1/5D, 15 May 1972, 28°48’S/32°11'E, depth 16 m.
Female: Eyes of comparable size to those of the male, antenna 2 (Fig 5B) with

3-articulate flagellum, otherwise like male. The specimen figured measured
3 mm and was carrying four large ova.

Relationships: The greatly produced fourth coxa and the unusual dactyl of
pereiopod 3 serve to diagnose this species. Only two other species, Urothoe

THE AMPHIPODA OF SOUTHERN AFRICA 239

Fig. 5. Urothoe coxalis. n. sp.
Female, 3 mm; A—antenna 1; B—antenna 2; C—mandible; D—maxilliped; E—gnathopod 1;
F—gnathopod 2; G—pereiopod 2; H—pereiopod 3; I—dactyl of pereiopod 3; J—pereiopod 5;
K—dactyl of pereiopod 5; L—uropod 3; M—telson. Male, 2,5 mm: N—antenna 2.

240 ANNALS OF THE SOUTH AFRICAN MUSEUM

grimaldii Chevreux, and U. spinidigitus Walker, have spinose dactyls on pereiopod
3, but both bear more spines and lack the produced coxa 4 of U. coxalis n. sp.

Material: Single male and female from the type locality.

Urothoe elegans Bate, 1857

Urothoe elegans: Chevreux & Fage, 1925: 101, fig. 95.

Records: NIWR/1/14E(4), NIWR/1/27G(3), NIWR/UM/R3D(1), NIWR/
UM/M3D(25), NIWR/2/23E(1), NIWR/2/27G(2), NIWR/2/30C(1), NIWR/
2/32C(1), NIWR/2/33E(1).

Distribution: Atlantic and Indian Oceans.

Urothoe pinnata K. H. Barnard, 1955
Urothoe pinnata K. H. Barnard, 1955: 86, fig. 42.
Records: NIWR/2/20B(1).

Diagnosis: Antenna 1 of female with 6-8 articulate flagellum, accessory flagellum
5-6 articulate; article 6 of gnathopod 1 slightly expanded but simple; gnathopod
2 subchelate, palm rounded, dactyl equal to palm; pereiopod 3 with article
2 oval, about 14 times as long as broad, article 5 twice as broad as long, 6
quadrate, dactyl narrow, minutely serrulate; article 2 of pereiopod 5 about
1% times as long as broad.

Distribution: Endemic, Natal to False Bay.

Urothoe pulchella (Costa, 1853)
Urothoe pulchella: Chevreux & Fage, 1925: 99, fig 92. K. H. Barnard, 1955: 83, fig. 41A.
Records: NIWR/1/5C(1), NIWR/1/13C(3), NIWR/]2/17C(5).

Diagnosis: Antenna 1 of female with 5-articulate flagellum and 3-articulate
accessory flagellum; gnathopod 1 very weakly subchelate, article 6 expanding
distally; gnathopod 2 distinctly subchelate, palm transverse; article 5 of
pereiopod 3 about 14 times as wide as long, dactyl slender, not cultriform,
minutely pectinate.

Distribution: Mediterranean, Atlantic, South Africa.

Urothoe serrulidactylus K. H. Barnard, 1955
Urothoe serrulidactylus K. H. Barnard, 1955: 85, fig. 41C. Ledoyer, 1969: 185, fig. 3.
Records: KOS 82G(8).

Diagnosis: Antenna 1 of female with 6-8 articulate flagellum and 3-6 articulate
accessory flagellum; gnathopod 1 simple, article 6 elongate; gnathopod 2
with article 6 slightly expanded distally, palm transverse, defined by a single

THE AMPHIPODA OF SOUTHERN AFRICA 241

spine; article 5 of pereiopod 3 twice as wide as long, dactyl cultriform, broad,
anterior margin distally serrate; article 2 of pereiopod 5 subcircular.

Distribution: Natal, Madagascar.

Remarks: Rabindranath (1971) synonymized Urothoe serrulidactylus with U. ruber
Giles but this is incorrect, as can be seen by comparing Rabindranath’s figures
with those of either K. H. Barnard (1955) or Ledoyer (1969). The dactyl of
pereiopod 3 in serrulidactylus is distinctly wide and cultriform and quite naked
of setae, while that of U. ruber is very narrow, evenly tapering and bears a
number of small setae. The palm of gnathopod 2 is also markedly chelate in
U. ruber but more transverse in serrulidactylus and there are a number of
differences in the minute structure of the mouth parts and antennae.

Urothoe tumorosa n. sp.
Fig. 6

Description of male (3,5 mm): Head as long as three pereon segments; eyes
large, dark, separated dorsally by about 4 of their diameter; antenna 1 (Fig 6A)
with 6-articulate flagellum and 3-articulate accessory flagellum, peduncular
articles subequal; antenna 2 (Fig 6K) as long as body, article 4 of peduncle
heavily spinose, article 5 and flagellum bearing aesthatascs, flagellum 36-
articulate; mandible with very large circular molar, incisor simple, heavily
chitinized, palp 3-articulate, articles 2 and 3 subequal, each twice article 1;
palp of maxilla 1 bi-articulate, tipped with three long plumose setae, outer
plate terminally bearing about ten strong serrate spines; maxilla 2 normal;
maxilliped bearing 4-articulate palp, article 3 expanding distally from a very
narrow base, outer lobe distally bearing five spine teeth interspersed with
fine setae, inner plate terminating in two spines and five short setae.

Coxa 1 triangular, remaining coxae subquadrate, not produced (cf.
U. coxalis n. sp.), but each bearing a few setae postero-distally; gnathopods
similar, subchelate; article 5 of gnathopod 1 bearing nine strong spines on distal
margin, palm undefined, minutely pectinate; article 5 of gnathopod 2 lacking
spines, palm defined by two short spines, minutely pectinate; articles 5 and 6
of pereiopods 1 and 2 posteriorly strongly spinose, dactyl bearing 3-4 pro-
nounced knobs; pereiopod 3 strongly spinose (Fig 6F), a group of very long
plumose setae arising from inner margin of article 4, articles 5 and 6 about as
wide as long, bearing rows of strong blunt spines and occasional plumose
setae, dactyl wide, evenly tapering, bearing about seven pronounced knobs on
anterior margin; pereiopod 4 with posterior margin of article 4 bearing plumose
setae, dactyl with anterior knobs; pereiopod 5 like 4 but lacking plumose setae
and considerably shorter.

Pleonal epimera 1-3 postero-distally rounded, the second bearing a
prominent group of long plumose setae which extend to the posterior end of
the body; peduncle of uropod 1 setose and bearing a lateral and two distal

242 ANNALS OF THE SOUTH AFRICAN MUSEUM

A

Fig. 6. Urothoe tumorosa n. sp.
Female, 3,5 mm: A—antenna 1; B—antenna 2; C—gnathopod 1; D—gnathopod 2; E—pereio-
pod 2; F—pereiopod 3; G—dactyl of pereiopod 3; H—pereiopod 5; I—uropod 3; J—telson.
Male 3,5 mm: K—antenna 2.

THE AMPHIPODA OF SOUTHERN AFRICA 243

spines, outer ramus equal to peduncle and bearing a single mediodorsal spine,
inner ramus naked, 80 per cent length of outer; uropod 2 half length of 1, pedun-
cle with two strong distal spines, rami equal, unarmed; peduncle of uropod
3 quadrate, distally spinose, rami subequal, the outer with a minute second
article, both rami marginally bearing plumose setae; telson (Fig. 6J) as long
as broad, 80 per cent cleft, each lobe with a terminal spine and three setae
and with two small lateral setae.

Holotype: SAM A13214, male, 3,5 mm.
Type-locality: NIWR/2/20A, 19 July 1972, 30°14’S/30°52’E, depth 44 m.
Female: Similar to the male except for the second antennae, which are much

shorter than those of the male (Fig 6B), and the smaller third uropods (Fig 61)
which have fewer, shorter plumose setae than those of the male.

Relationships: ‘The marked protuberances on the dactyls, particularly that of
pereiopod 3, are sufficient to identify this species. Stebbing (1906) quotes two
other species, U. marina (Bate), and U. irrostrata Dana as possessing nodulose
dactyls, but fuller descriptions of these species in Chevreux & Fage (1925)
and Della Valle (1893) respectively show the dactyls to be minutely serrulate
in both cases.

Material: NIWR/UM/M2B(1), NIWR/2/20A(2), NIWR/2/33D(1).

Family Isaeidae
Cheiriphotis megacheles (Giles, 1885)

Cheiriphotis durbanensis K. H. Barnard, 1916: 247.
Cheiriphotis megacheles: J. L. Barnard, 1962a: 17, fig. 4.

Records: Durban Bay (K. H. Barnard 1916 as C. durbanensis) ; Durban (Stebbing
1918).
Distribution: Indo-Pacific.

Chevalia aviculae Walker, 1904.

Chevalia aviculae: J. L. Barnard, 1971: 88, fig. 42.
Records: NAD 16N(7); NIWR/UM/D3B(1), NIWR/UM/P1B(1), NIWR|
2/36H(4).

Distribution: Circumtropical and warm temperate.

Gammaropsis afra (Stebbing, 1888)
Gammaropsis afra: J. L. Barnard, 1970): 170, fig. 108.
Records : 29/31/430 m (J. L. Barnard 1961).

Distribution: Almost circumtropical.

244. ANNALS OF THE SOUTH AFRICAN MUSEUM

Gammaropsis atlantica (Stebbing, 1888) new synonymy

Eurystheus imminens K. H. Barnard, 1916: 250; 1937: 165, fig. 11.
Gammaropsis atlantica: J. L. Barnard, 1970): 174, figs 111-113.

Records: NIWR/1/26F(1), NIWR/UM/D3A(1), NIWR/UM/R3B(1), NIWR/
2/24E(3), NIWR/2/30M(5), NIWR/2/36B(13); ABD 8Q(2); NAD 4S(2)
NAD 11R(11), NAD 19G(10), NAD 56A(41), NAD 61A(1), NAD 64F(6),
NAD 66R(3), NAD 7oV(2), NAD 81H(1), NAD goT(22), NAD g92N(7),
NAD 92 (P); ‘Morewood cove’ 50 m (K. H. Barnard 1916 as E. imminens).

Distribution: Almost circumtropical.

Remarks: K. H. Barnard (1916) erected G. imminens on the basis of two charac-
ters—the relative sizes of the palmar teeth of gnathopod 2 male, and the shape
of the eyes (‘elongate oval’). I have examined his type material and find the
eyes to be of a shape consistent with those of G. atlantica from the same area
(vertically elongate but not markedly constricted dorsally). Although the
relative size of the palmar teeth is unusual their general shape is consistent with
G. atlantica, and this cannot be regarded as taxonomically significant in the
light of the variability of G. atlantica which has been demonstrated in recent
years (e.g. J. L. Barnard 19705). Moreover, the fact that the specimens were
found amongst samples of G. atlantica suggests that they merely represent
aberrations of the normal form.

Gammaropsis chelifera (Chevreux, 1901)

Eurystheus semichelatus K. H. Barnard, 1957: 8, fig. 5.
Gammaropsis chelifera: Ledoyer, 1972: 239, pl. 54A.
Gammaropsis semichelatus: Griffiths, 1972: 290.

Records: NA 191J(8).

Distribution: Indian Ocean.

Gammaropsis holmes: (Stebbing, 1908) new synonymy

Eurystheus holmesi Stebbing, 1908: 85, pl. 14A. K. H. Barnard, 1955: 95, figs 48 A—D.
Eurystheus semidentatus K. H. Barnard, 1916: 250, pl. 28, figs 13, 14.

Records: NAD 7D(2), NAD 19Q(14); Durban (Stebbing 1918).

Diagnosis: Gnathopod 2 powerful, hind margin much shorter than oblique,
dentate palm, palm defined by a small tooth; hind margins of article 2 of
pereiopods 3—5 strongly serrate posteriorly; pleon segment 4 dorsally tridentate,
median tooth the smallest, segment 5 with a pair of dorso-lateral teeth.

Distribution: Endemic, Natal to Saldanha Bay.

Remarks: As originally described by K. H. Barnard (1916), G. semidentatus
could be distinguished from G. holmesi by the less marked and more regular
serrations along the posterior margin of article 2 of pereiopods 3-5, and by
differences in the teeth of the palm of gnathopod 2. However it has since been

THE AMPHIPODA OF SOUTHERN AFRICA 245

found that Stebbing’s original material was unusually well developed as regards
these features, the usual form of G. holmes: being described and figured by
K. H. Barnard (1955). As can be seen by comparing these figures with those
depicting semidentatus, the two species have become indistinguishable, holmes
merely representing a more highly developed phenotype of semidentatus. Since
holmesi has preference, semidentatus thus falls into synonymy with it.

Photis longimanus Walker, 1904
Photis longimanus: K. H. Barnard, 1916: 244. Sivaprakasam, 1970: 567, fig. 8.

Records: Durban Bay (K. H. Barnard 1916).
Distribution: Indian Ocean, extending to South West Africa.

Photis kapapa J. L. Barnard, 1970
Photis kapapa J. L. Barnard, 19700: 192, figs 124, 125.

Records: NIWR/UM/R3@(5), NIWR/2/27H(3), NIWR/2/33F(3); NAD
19E(23), NAD 56D(2), NAD 64G(1).
Distribution: Hawaii, east coast of southern Africa.

Photis uncinata K. H. Barnard, 1932

Photis longicaudata: K. H. Barnard, 1916: 243, pl. 28, fig. 26.
Photis uncinata K. H. Barnard, 1932: 223, fig. 138.

Records: NIWR/1/6B(1), NIWR/1/14D(2), NIWR/UM/D3C(1), NIWR/
2/22B(1); 29/31/50 m, ‘Morewood Cove’ 50 m (K. H. Barnard 1916).

Diagnosis: Articles 5 and 6 of gnathopod 1 subequal, palm very oblique, faintly
denticulate; article 2 of gnathopods 1 and 2 antero-distally terminating in a
small curved acute process tipped by two setae; article 6 of gnathopod 2 oblong,
defining angle rectangular, slightly produced, palm nodulose, dactyl serrate;
outer ramus of uropod 3 very small.

Distribution: Endemic to South Africa.

Family Ischyroceridae
Ischyrocerus anguipes Kroyer, 1838
Ischyrocerus anguipes: Schellenberg, 1953: 120, fig. 7A—C.

Records : NIWR/3/30S(1), NIWR/2/35C(1).
Distribution: Atlantic, Indo-Pacific.

Jassa falcata (Montagu, 1808)
Jassa falcata: Sexton & Reid, 1951: 30-47, pls 4-30. J. L. Barnard, 1969a: 155, figs 38, 39.
Records: DBN 131P(1); D 276(2); NA 244F(23).
Distribution : Cosmopolitan.

246 ANNALS OF THE SOUTH AFRICAN MUSEUM

Family Leucothoidae

Leucothoe ctenochr K. H. Barnard, 1925

Leucothoe ctenochir K. H. Barnard, 1925: 342, pl. 34, fig. 8.

Records: NAD 4P(7); Port Shepstone (K. H. Barnard 1925).

Diagnosis: Readily identified by the form of the palm of gnathopod 2 which is
cut into five or six regular comb-like teeth, the tooth nearest the finger-hinge
obscurely bifid; third pleonal epimeron postero-distally subquadrate, lacking
a posterior sinus; antenna 1 extending to pereon segment 3.

Distribution: Endemic to east coast of South Africa.

Leucothoe dolichoceras K. H. Barnard, 1916

Leucothoe dolichoceras K. H. Barnard, 1916: 157, pl. 26, fig. 14; 1925: 343.
Records: NIWR/2/36Q (1); NAD 4Q(1).

Diagnosis: Antenna 1 extending to pleon segment 3 (unusually long); article 6
of gnathopod 1 long and narrow, palm with two large blunt-tipped tubercles
near finger-hinge, a third proximal to them and a series of small denticles near
defining angle; dactyl equal to palm, a deep semicircular incision bounded by a
denticle near its base (this form of gnathopod 2 only fully developed in speci-
mens over 8 mm); third pleonal epimeron acutely produced with a deep sinus
above postero-distal corner.

Distribution: Endemic to South Africa.

Leucothoe richard: Lessona, 1865

Leucothoe richiardi: Sivaprakasam, 1967: 385, fig. 2.
Records: NAD 4R(6).

Diagnosis: Antenna 1 extending to pereon segment 3; article 6 of gnathopod 2
elongate oval, palm convex, denticulate distally; third pleonal epimeron
postero-distally acute, a sinus above corner (obscure in females).

Distribution: Mediterranean, India, South Africa.

Leucothoe spincarpa (Abildgaard, 1789)

Leucothoe spinicarpa: K. H. Barnard, 1916: 148. Sivaprakasam 1967: 384, fig. 1.

Records: NIWR/3/24F(4); NAD goU(22); NA 243B(1); 30/30/50 m (K. H.
Barnard 1916).

Distribution: Cosmopolitan.

THE AMPHIPODA OF SOUTHERN AFRICA 247

Family Liljeborgiidae
Liljeborgia epistomata K. H. Barnard, 1932
Liljeborgia epistomata K. H. Barnard, 1932: 144, fig. 83; 1955: 89, fig. 44.
Records: NAD 15M(2).

Diagnosis : The male differs considerably from the female and is relatively rare.
Male coxa 1 ovoid, enormously enlarged; article 6 of gnathopod 2 14 times as
long as broad, palm oblique, sinuous, a prominent bilobed tooth near finger-
hinge, dactyl with 7-8 large serrations, closing into a shallow pit on inner surface
of hand which is armed by three spines. Female coxa 1 normal, gnathopod
2 palm not toothed. Both sexes lack eyes and dorsal teeth on pleon segment 1;
pleon segments 2, 4 and 5 have single medio-dorsal teeth, those of segments 4
and 5 forming the termination of medio-dorsal keels.

Distribution: Endemic, Saldanha Bay to Natal.

Family Lysianassidae
Amaryllis macrophthalma Haswell, 1880

Amaryllis macrophthalma: J. L. Barnard, 1972: 262, figs 156-158.

Records: NIWR/1/26C(1), NIWR/1/27D(1), NIWR/UM/M3C(2), NIWR|
2/17B(2), NIWR/2/32B(8), NIWR/2/36C(13); NA 205J(1); 30/30/50 m,
29/31/100 m (K. H. Barnard 1916).

Distribution: Southern Hemisphere.

Hippomedon longimanus (Stebbing, 1888)
Hippomedon longimanus Stebbing, 1888: 643, pl. 12. K. H. Barnard, 1916: 125.
Records: 29/31/80 m (K. H. Barnard 1916).

Diagnosis: Eyes absent; article 1 of antenna 1 longer than articles 2 plus 3,
article 1 of flagellum elongate; gnathopods 1 and 2 long and slender, article
5 longer than 6: pleon segment 4 dorsally depressed anteriorly and posteriorly
carinate; third pleonal epimeron with a short point postero-inferiorly; telson
6o per cent cleft, apices somewhat divergent, each ending in a spine.

Distribution: Atlantic, extending to Natal.

Hippomedon onconotus (Stebbing, 1908)
Tryphosa onconotus Stebbing, 1908; 65, pl. 35.
Records: NIWR/UM/M1B(1).

Diagnosis: Eyes absent; article 1 of antenna 1 as long as 2 plus 3; article 5 of
gnathopods 1 and 2 longer than article 6; pleon segment 4 with a deep dorsal
depression followed by an upturned acute triangular process; third pleonal

248 ANNALS OF THE SOUTH AFRICAN MUSEUM

epimeron smoothly rounded; telson 80 per cent cleft, each lobe with an apical
and a lateral spine and two proximal setae.

Distribution: Endemic to South Africa.

Lysianassa ceratina (Walker, 1889)

Lysianassa cubensis: K. H. Barnard, 1916: 120.
Lysianassa ceratina: Chevreux & Fage, 1925: 42, fig. 23.

Records: NIWR/1/27J(2), NIWR/2/27C(4), NIWR/2/30A(6); NA 244H(3),
G 15N; M 10E.

Distribution: Mediterranean, Atlantic, Indian Ocean.

Lysianassa variagata (Stimpson, 1855)
Lysianassa variagata: Stebbing, 1888: 682. pl. 23.

Records: NAD 4M(2), NAD 81K(3).

Distribution: Africa south of the equator.

Maicrolysias xenoceras Stebbing, 1918

Microlysias xenoceras Stebbing, 1918: 64, pl. 9.

Records: Durban (Stebbing 1918).
Distribution: Endemic, Durban to Plettenberg Bay.

Trischizostoma remipes Stebbing, 1908
Trischizostoma remipes Stebbing, 1908: 61, pl. 34. K. H. Barnard, 1925: 321.
Records: NAD 11S(1).

Diagnosis: Article 6 of gnathopod 1 very large, showing some torsion, palm
elongate, evenly convex, minutely serrulate, dactyl curved, inner margin
smooth; eyes very large, nearly meeting on top of head; rostrum small; acces-
sory flagellum of antenna 1 of a single laminar joint followed by a short linear
one; article 6 of pereiopod 5 slightly longer and wider than 5, forming a narrow
blade-like lamina; telson 40 per cent cleft. .

Distribution: Endemic, Natal to False Bay.

Trischizostoma serratum K. H. Barnard, 1925
Trischizostoma serratum K. H. Barnard, 1925: 320, pl. 34, fig. 1.

Records : “Various localities on Natal coast’ (K. H. Barnard 1925).

Diagnosis: Close to T. remipes but differing in the form of gnathopod 1 which
has a straight or concave palm with defining angle produced into a blunt point
with 1 or 2 stout blunt spines, palm entire, armed with seven stout marginal

THE AMPHIPODA OF SOUTHERN AFRICA 249

and five submarginal spines, inner margin of dactyl with a series of conical
denticles at regular intervals.

Distribution: Endemic, Natal to False Bay

Tryphosella normalis K. H. Barnard, 1955
Tryphosella normalis K. H. Barnard, 1955: 80, fig. 39.

Records: NIWR/1/26E(2), NIWR/1/27H(6), NIWR/UM/P1D(1), NIWR/
2/30D(2).
Distribution: Endemic, Natal to South West Africa.

Uristes natalensis K. H. Barnard, 1916
Uristes natalensis K. H. Barnard, 1916: 126.

Records: Port Shepstone (K. H. Barnard 1916).

Diagnosis: Coxa 1 widening distally, oblong, not greatly reduced; pleon seg-
ment 4 somewhat depressed basally but neither carinate nor produced; telson
oblong, apices divergent.

Distribution: Endemic to east coast of South Africa.

Family Ochlesidae
Ochlesis lenticulosus K. H. Barnard, 1940
Ochlesis lenticulosus K. H. Barnard, 1940: 447, fig. 23.
Records: NIWR/2/30T(1).

Diagnosis: Pereon and pleon dorsally carinate, the carinae of pereon segment 7
and pleon segments 1 and 2 produced posteriorly into a blunt dorsal projection,
pleon segment 3 with an upstanding triangular projection about the middle
of its length; third pleonal epimeron postero-distally produced into a sharply
upturned tooth; lower distal margins of articles 1 and 2 of antenna 1 produced
into spinose projections.

Distribution: Endemic, Natal to False Bay.

Family Phliantidae
Palinnotus natalensis K. H. Barnard, 1940

Palinnotus natalensis K. H. Barnard, 1940: 445, fig. 22.

Records : D 279; Isipingo (K. H. Barnard 1940) ; Port Shepstone (K. H. Barnard
1955):

Diagnosis: Body dorsally depressed, coxae splayed; article 2 of pereiopod 5
strongly expanded, as wide as long in adults; article 4 distally strongly lobed;
uropod 3 lacking rami.
Distribution: Natal, India.

250 ANNALS OF THE SOUTH AFRICAN MUSEUM

Family Phoxocephalidae
Mandibulophoxus stimpsom (Stebbing, 1908)

Pontharpinia stimpsoni Stebbing, 1908: 75, pl. 11.
Mandibulophoxus stimpsoni: J. L. Barnard, 1957: 436-438, figs 3, 4.

Records : NIWR/1/5A(2), NIWR/1/14F(1), NIWR/1/24A(1), NIWR/1/26A(8),
NIWR/1/27A(5), NIWR/UM/R3E(1), NIWR/UM/P5B(1), NIWR/UM/
Mi1A(2), NIWR/UM/M2A(3), NIWR/UM/M3A(3), NIWR/2/17A(3),
NIWR/2/19A(1), =NIWR/2/21/F(1), NIWR/2/22A(1), NIWR/2/23A(2),
NIWR/2/27B(5), NIWR/2/29A(1), NIWR/2/30B(5), NIWR/2/32A(1),
NIWR/2/33A(4), NIWR/2/35A(2), NIWR/2/36A(1); NAD 27C(1).

Diagnosis : Eyes present; rostrum extending beyond tip of peduncle of antenna 1,
apex drawn out into a curved downturned point; third pleonal epimeron with
an oblique setal row on its exterior surface; rami of uropods 1 and 2 dorsally
and apically spinose; telson cleft to base.

Distribution: West and southern Africa.

Family Podoceridae
Laetmatophilus durbanensis K. H. Barnard, 1916
Laetmatophilus durbanensis K. H. Barnard, 1916: 275.

Records: Durban Bay (K. H. Barnard 1916).

Diagnosis: Pereon transversely ridged; gnathopod 1 with article 6 not at all
widened, narrower than article 5, palm smooth, not defined from hind margin;
article 2 of gnathopod 2 male with two anterior keels, both apically acute,
article 6 broadly ovate, palm straight, with a low denticulate process extending
from the finger-hinge about 4} way along the palm and a pointed tooth
proximal to it, dactyl nearly straight, matching palm.

Distribution: ‘The above record is the only one to date.

Laetmatophilus purus Stebbing, 1888
Laetmatophilus purus Stebbing, 1888: 1198, pl. 132.

Records: NIWR/2/30E(18).
Distribution: Endemic, South West Africa to Mocgambique.

Laetmatophilus tridens K. H. Barnard, 1916

Laetmatophilus tridens K. H. Barnard, 1916: 275, pl. 28, fig. 22.
Records: NAD 15L(1).
Distribution: Endemic, Mocambique to Saldanha Bay.

THE AMPHIPODA OF SOUTHERN AFRICA 251

Podocerus africanus K. H. Barnard, 1916
Podocerus africanus K. H. Barnard, 1916: 278, pl. 28, figs 24-25; 1937: 176, fig. 19.

Records: NA 244D(30); Port Shepstone (K. H. Barnard 1925).
Disiribution: Arabia, Natal to South West Africa.

Podocerus brasiliensis (Dana, 1853)

Podocerus brasiliensis: J. L. Barnard, 1970: 237, figs 156-157.

Records: DBN 2W(15), DBN 62J(G), DBN 131J(A), DBN 131K(1), DBN
251C(C), DBN 271F(2), DBN 379D(P); Durban Bay (K. H. Barnard 1916
as P. synapochir).

Diagnosis: Body lacking dorsal processes; coxa 1 weakly produced forwards,
apically rounded; male gnathopod 2 with article 2 not anteriorly keeled,
obscurely lobed distally, palm occupying whole posterior margin of article
6, undefined and smooth except for a slight distal bulge, dactyl half length
of palm; peduncles and inner rami of uropods 1 and 2 moderately and
irregularly spinose.

Distribution: Cosmopolitan in tropical and temperate seas.

Podocerus inconspicuus (Stebbing, 1888)

Podocerus palinuri K. H. Barnard, 1916: 277, pl. 28, fig. 23.

Podocerus inconspicuus: Nagata, 1965: 322, fig. 43.

Records: NIWR/2/19A(1); NA 191H(1); Durban (Stebbing 1918).
Distribution: Indo-Pacific, extending along west coast of South Africa.

Podocerus multispinis K. H. Barnard, 1925

Podocerus multispinis K. H. Barnard, 1925: 367, pl. 34, fig. 18.
Records: NAD 4V(a2).

Diagnosis: Body not dorsally keeled but bearing two transverse rows of 3 spini-
form tubercles on segment 1 and a single row on each of segment 2-7; coxa I
produced forwards to level of the eye, apically acute; male gnathopod 2 with
article 2 strongly keeled on inner and outer anterior margins, both keels ending
in rounded setiferous lobes; palm 60% length of article 6, defined by a strong
conical tooth, an obscure bifid tooth halfway along the palm and another
square topped tooth near the finger-hinge, dactyl almost as long as palm;
inner margins of peduncles and inner ramis of uropods 1 and 2 with comb-like
rows of closely set spines.

Distribution: Endemic, Natal to Saldanha Bay.

252 ANNALS OF THE SOUTH AFRICAN MUSEUM

Family Stenothoidae
Proboloides rotunda (Stebbing, 1917)

Metopa rotundus Stebbing, 1917: 39, pl. 7A.
Proboloides rotunda: K. H. Barnard, 1940: 444.

Records: NIWR/2/30P(1), NIWR/2/36N(11); NAD 19M(z1).

Diagnosis: Body round; flagellum of antenna 1 and 2 shorter than peduncle,
accessory flagellum absent; article 6 of gnathopod 1 parallel-sided, twice as
long as broad, palm smooth, oblique; gnathopod 2 much larger than 1, palm
oblique, convex, serrate near finger-hinge then abruptly stepped to form a
cavity within which the dactyl closes; article 4 of pereiopods 4 and 5 produced
posteriorly into an acute lobe extending to the end of article 5; peduncle of
uropod 3 longer than ramus, article 1 of ramus longer than spiniform second
article.

Distribution: Endemic to South Africa.

Stenothoe gallensis Walker, 1904.

Stenothoe gallensis: K. H. Barnard, 1925: 344. J. L. Barnard, 1955: 3, fig. 1; 1971: 120, figs 62-63,

Records: NAD 17Q(1); Durban (K. H. Barnard 1916); Port Shepstone (K. H.
Barnard 1925).

Distribution: Cosmopolitan.

Remarks: K. H. Barnard’s (1925) identification was queried by J. L. Barnard
(1955) on the basis of the shape of uropod 3. I have examined the single male
K. H. Barnard (1925) referred to, but find the third uropods to be missing.
However, other material from South Africa conforms with his description, the
third uropod differing from the usual form (figured in J. L. Barnard 1971)
in that article 2 of the ramus is proximally almost circular and has an almost
straight distal process arising from the superior half of its distal margin, the
process is ridged in the usual pattern for the species. The process is not demar-
cated in any way from the proximal part of the article. Although the shape of
the third uropod is unusual, I feel that in the light of increasing variability
which has been found in this species, and its relative S. valida Dana, in recent
years, it would be unwise to erect a new species for this form.

Stenothoe valida Dana, 1853

Stenothoe valida: Sivaprakasam, 1967: 373, fig. 2 a-b. J. L. Barnard, 19700: 250, fig. 165.

Records: DBN 2U(C), DBN 62H(C), DBN 131M(P), DBN 251G(1), DBN
379C(P), DBN 396E(P); Durban (K. H. Barnard 1925).

Distribution: Cosmopolitan in tropical and temperate seas.

THE AMPHIPODA OF SOUTHERN AFRICA 253

Family Synopiidae
Tiron australis Stebbing, 1908

Tiron australis Stebbing, 1908: 79, pl. 38.
Records: NIWR/2/20Q(1), NIWR/2/36S(2).

Diagnosis: Accessory eye of four ommatidea; mandible with 3-articulate palp;
inner plate of maxilla 2 with a medial submarginal row of setae; dactyls of
pereiopods stubby but apically sharp; article 2 of pereiopods 4 and 5 not strongly
setose, that of 5 crenulate posteriorly; pleonites 1-3 dorsally crenulate; each
lobe of telson with a median row of large spines.

Distribution: Endemic to east and south coasts of South Africa.

Superfamily TALITROIDEA
Family Hyalellidae
Afrochiltonia capensis (K. H. Barnard, 1916)

Chiltonia capensis K. H. Barnard, 1916: 224, pl. 27, figs 38-40.
Afrochiltonia capensis: K. H. Barnard, 1955: 93.

Records: STL 89G(A), STL 102C(C); KOS 62B(3), KOS 74G(5), KOS
78H (6), KOS 81E(1), KOS 82F(1); RHB 1290 (2); UMK 1rq9W(C), UMK
23W(2), UMK 25C(P), UMK 26H(C), UMK 27N(C), UMK 290A(A);
EDW 3B(C).

Diagnosis: Since the genus is monotypic the generic characters diagnose the
species. Habitat estuarine and brack water; maxilla 1 lacking palp; gnathopods
of both sexes subchelate; male gnathopod 2 not larger than gnathopod 1;
female gnathopod 2 like gnathopcd 1; male pleopod 1 normal; uropod 3
lacking rami; telson entire.

Distribution: Endemic, Zululand to Saldanha Bay.

Parhyalella natalensis (Stebbing, 1917)

Exhyalella natalensis: Stebbing, 1918; 67, pl. 11.
Parhyalella natalensis: K. H. Barnard, 1925: 359.

Records: Durban (Stebbing 1918; K. H. Barnard 1925).

Diagnosis: Flagellum of antenna 1 and 2 at least as long as peduncle; article 5
of gnathopod 1 male larger than 6; article 5 of gnathopod 2 male with a narrow
posterior lobe intervening between articles 4 and 6, palm oblique, elongate,
spine fringed, having a very short hind margin; uropod 3 very small, peduncle
much larger than ramus; telson entire.

Distribution: Not recorded outside Durban.

254 ANNALS OF THE SOUTH AFRICAN MUSEUM

Family Hyalidae
Hyale grandicornis (Kroyer, 1845)
Hyale grandicornis: Stephensen, 1949: 33, figs 14, 15.
Records: G 15F; V 28L; D 118; M 19H; NA 243C(1), NA 244G(18); Port
Shepstone, Isipingo, Port Edward (K. H. Barnard 1955).

Distribution: Cosmopolitan in tropical and temperate seas.

Family Talitridae
Orchestia ancheidos (K. H. Barnard, 1916)

Talorchestia ancheidos K. H. Barnard, 1916: 221, pl. 27, figs 35, 36.
Orchestia ancheidos: Ruffo, 1958: 43, figs 3, 4.

Records: STL 11D(4), STL 18D, STL 52G, STL 67B, STL 73A, STL 77A,
STL 135B(2), STL 148B(8), STL 171A(2), STL 232D, STL 270B, STL
299R(2), STL 317D(2), STL 342G(A), STL 343J(5), STL 344; KOS
6A(A), KOS 15A(2), KOS 78G(g); RHB 38A(15), RHB 93A(3), RHB
132D(20); UMK 24N; SHP 5B(C); Umlalazi estuary (Hill 1966).

Distribution: Madagascar, Mogambique, South Africa.

Orchestia rectipalma (K. H. Barnard, 1940)

Parorchestia rectipalma K. H. Barnard, 1940: 473, fig. 32.

Records: STL 89F(A), STL 102D(1); RHB 124N(1), RHB 129C(3); EDW
3A(C); UMK 19F, UMK 29C(P), UMK 33C(8).

Distribution: Endemic; Natal to South West Africa.

Suborder CAPRELLIDEA
Family Aeginellidae
Metaprotella macrodactylos Stebbing, 1910

Metaprotella macrodactylos Stebbing, 1910: 469, pl. 48A.
Records: NIWR/2/30K(1).

Diagnosis: Last two thoracic segments distinct but not movable upon each
other; head bearing an acute forward-directed process, rest of the body lacking
dorsal processes; pereiopods 1 and 2 minute, less than } length of branchiae;
second gnathopods large, hand very long and bearing a pronounced acute
tooth on the palm near the articulation of the dactyl, dactyl extending whole
length of hand.

Distribution: Endemic, this is only the second record of this species, the first
being from the Port Elizabeth area.

THE AMPHIPODA OF SOUTHERN AFRICA 255

Monoliropus falcimanus Mayer, 1904
Monoliropus falcimanus: Sivaprakasam, 1967: 382, fig. 4G—H.
Records: ABD 14K(1).

Distribution: Indian Ocean.

Pseudaeginella tristanensis (Stebbing, 1888)
Pseudaeginella tristanensis: Stephensen, 1949: 52, fig. 23.
Records: NIWR/2/30U(1); NA 244B(1).

Diagnosis: Branchiae on pereon segments 2 and 3; pereiopods 1 and 2 absent,
pereiopod 3 6-articulate; abdomen lacking appendages; pereon segment 1
with a large upright antero-dorsal tooth and a smaller posterior one, segments
2—4 each with three dorsal tubercles, the largest in the centre of the segments,
the others sometimes obscure; gnathopod 2 with a small acute tooth half way
along the palm and two smaller rounded teeth distally.

Distribution: ‘Tristan da Cunha, South Africa.

Family Caprellidae
Caprella cicur Mayer, 1903
Caprella cicur Mayer, 1903: 75, 97, pl. 4, figs 5-7, pl. 8, figs 3-5.
Records: G 15K; U 28H; J 11C.

Diagnosis: Head with short rostral point; basis of gnathopod 2 shorter than
pereon segment 2, outer margin anteriorly keeled, the keel ending in an acute
point; a spine ventrally between the insertions of gnathopod 2, hand of male
gnathopod 2 elongate, palm defined by an acute forward directed process, a
triangular tooth near finger-hinge.

Distribution: Endemic, Natal to west coast of South Africa.

Caprella danilevskt Czerniavski, 1868
Caprella danilevskii: Chevreux & Fage, 1925: 454, fig. 432. McCain, 1968: 22-25, figs 10-11.
Records: J 11C.

Distribution: Widespread in tropical seas.

Caprella equilibra Say, 1818
Caprella equilibra: McCain, 1968: 25-30, figs 12-13.

Records: DBN 2X(A), DBN 131C(P), DBN 241 W(1), DBN 251A(A), DBN
379A(C), DBN 396F(C); NAD 15J(6); Durban (K. H. Barnard 1916).

Distribution: Cosmopolitan, 0-300 m.

256 ANNALS OF THE SOUTH AFRICAN MUSEUM

Caprella laevipes Mayer, 1903
Caprella laevipes Mayer, 1903: 108, pl. 5, fig. 2, pl. 8, figs 14-16.
Records: ‘Port Natal’ (= Durban, Mayer 1903).

Diagnosis: Head with large anteriorly directed rostral spine; basis of gnathopod
2 longer than pereon segment 2; no spine between insertions of second gnatho-
pods, hand elongate and expanding distally in adult males, palm with two
strong teeth and a distal rectangular projection; pereiopods 5—7 lacking grasping
spines (distinguishing the species from C. scaura).

Distribution: Endemic, Natal to west coast of South Africa.

Caprella natalensis Mayer, 1903.

Caprella acutifrons var. natalensis: Mayer, 1903: 81, pl. 3, figs 22, 23.
Caprella penantis (non Leach, 1814): Stebbing, 1910: 465.

Caprella penantis var. natalensis: K. H. Barnard, 1916: 281.

Caprella angusta: Laubitz, 1970: 40, fig. 11.

Caprella natalensis: Laubitz, 1972: 47, pl. 9, figs F,G, pl. 10, figs F-K.

Records: Durban (Mayer 1903; K. H. Barnard 1916).

Diagnosis: Head with anteriorly directed rostrum; basis of gnathopod 2 shorter
than pereon segment 2; no spine between insertions of second gnathopods,
hand twice as long as broad, palm sparsely setose with proximal poison tooth
and distal rectangular projection.

Distribution: Pacific North America, Tristan de Cunha, South Africa.

Remarks : ‘This form was originally described by Mayer as one of twenty varieties
of C. acutifrons which he recognized. These varieties were analysed by McCain
(10968) who assigned eight of them including var. natalensis, to C. penantis.
Laubitz (1970) subsequently elevated one of these eight, C. angusta, to specific
level but then (1972) synonymized this with a newly elevated C. natalensis.
This species can be distinguished from C. penantis by its long pereonite 5 (as
long as 6+-7) and the sparse setification of the palm of gnathopod 2, as well as
the absence of pleura, which are usually well developed in adult C. fenantis.

Caprella penantis Leach, 1814
Caprella penantis: McCain, 1968: 33-40, figs 15-16.
Records: D 272; NA 244A (26).

Distribution: Cosmopolitan in tropical and temperate seas.

Caprella scaura Vempleton, 1836
Caprella scaura: McCain, 1968: 40-44, figs 17-18.
Records: DBN 131E(1).

Distribution: Cosmopolitan.

THE AMPHIPODA OF SOUTHERN AFRICA 257

Paracaprella pusilla Mayer, 1890
Paracaprella pusilla: McCain, 1968: 82-86, figs. 32 a—b, 41, 42, 53.
Records: DBN 131D(1).

Diagnosis: Mandibular palp absent; antero-ventral margin of male pereon
segment 2 acutely produced forwards; basis of gnathopod 2 short, a distinct
hump on posterior margin near origin, palm with proximal grasping spine
followed by a tooth, a pronounced excavation midway along palm; pereiopods
I and 2 2-articulate; pereiopod 3 6-articulate.

Distribution: Cosmopolitan in tropical and temperate seas.

Family Gyamidae
Cymus balaenopterae K. H. Barnard, 1931
Cyamus balaenopterae: K. H. Barnard, 1932: 309, fig. 171.

Records: Ectoparasitic on a fin whale, Durban (K. H. Barnard 1932).

Diagnosis: Maxilliped with palp; body narrow in dorsal view, parallel sided in
male, ovate in female; pereon segment 1 completely fused with head, pereon
segment 2 not laterally hooked; branchiae on segments 3 and 4 single, about as
long as segments 2 and 3, male branchiae with single short pointed accessory
gills; male with a pair of ventral tubercles on each of pereon segments 6 and 7;
female with a pair of oblong ventral processes on segment 5, and a pair of
tubercles on each of segments 6 and 7.

Distribution: Widespread on fin whales and blue whales.

Cyamus boopis Lutken, 1873

Paracyamus boopis: K. H. Barnard, 1932: 312.

Cyamus boopis: Margolis, 1955: 124, figs 7-12.

Records : Ectoparasitic on humpback and sperm whales, Durban (K. H. Barnard
1932).

Diagnosis: Maxillipedal palps absent, body ovate (but more slender than
C. erraticus) pereon segment 2 not postero-laterally hooked; branchiae single
with the bifurcate accessory gills in male shorter than pereon segments 2-5;
male with one pair of ventral spines on each pereon segments 5—7, female with 2
pairs on segment 5 and one pair each on 6 and 7.

Distribution: Widespread on humpback whales.

Cyamus erraticus Roussel de Vauzéme, 1834

Paracyamus erraticus: K. H. Barnard, 1932: 310, fig. 172.
Cyamus erraticus: Margolis, 1955: 132, figs 1-6.

Records: Humpback whale, Durban (Stebbing 1910).

258 ANNALS OF THE SOUTH AFRICAN MUSEUM

Diagnosis: Maxilliped with or without palps; body broadly ovate, pereon seg-
ment 2 postero-laterally produced into a forwardly directed hooked process;
branchiae single, as long as pereon segments 2—7 and with small bifid accessory
lobe in adult male; male with 2 pairs of ventral spines on segments 5 and 6
and a single pair on 7, female with a single pair of spines on segments 5 and 7
and two pairs on 6.

Distribution: Widespread on right whales.

Family Phtisicidae
Phtisica marina Slabber, 1769
Phtisica marina: K. H. Barnard, 1916: 283. McCain, 1968: 91-97, fig. 46.
Records: 30/30/80 m (K. H. Barnard 1916).

Distribution: Principally Atlantic but extending to Mocambique, Medi-
terranean and Black Sea.

Caprellina longicollis (Nicolet, 1849)
Caprella longicollis: McCain, 1969: 280, fig. 2.
Records: DBN 404A(C).

Distribution: Southern oceans, Mediterranean.

Subfamily Phtisicinae
Chaka n. gen.

Diagnosis: Flagellum of antenna 2 tri-articulate, swimming setae present;
mandible with 3-articulate palp, setal formula of terminal article 1-X-1, molar
absent; outer lobe of maxilliped equal to inner lobe; gills on pereonites 2-4;
pereiopods 1 and 2 fully developed, pereiopod 3 tri-articulate; abdomen of
male and female with two pairs of bi-articulate appendages.

T ype-species: Chaka leoni n. sp.

Relationships: The configuration of the pereiopods in this genus is unique.
Other genera in the subfamily Phtisicinae have five or six-articulate third pereio-
pods, while genera in the subfamily Dodecadinae have pereiopods 1 and 2 more

or less reduced.
Chaka leonzi n. sp.
Figs 7, 8

Description of male (11 mm): Head produced into a short flat-lying process
(Fig. 7A), antenna 1 about as long as first five pereon segments, flagellum less
than half peduncle, 11-articulate; antenna 2 shorter than peduncle of antenna

THE AMPHIPODA OF SOUTHERN AFRICA 259

Fig. 7. Chaka leoni n. gen., n. sp.
Male, 11 mm: A—lateral aspect; B— mandible; C—maxilliped; D—lateral view of abdominal
appendages.

260 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 8. Chaka leoni n. gen., n. sp.
Female, 8 mm: A—lateral aspect; B—dorsal view of abdomen.

1, flagellum 3-articulate, swimming setae present; mandible with 3-articulate
palp, setal formula of terminal article 1-2-1, incisor of mandible (Fig. 7B)
five toothed, lacinia mobilis smooth, two accessory plates present, below
which lies a row of ten strong setae, molar absent; inner and outer lobes
of maxilliped equal, inner lobes nearly fused, armed distally with serrate
spines.

Propodos of gnathopod 1 subtriangular, palm evenly concave, defining
angle produced into a rounded lobe; gnathopod 2 very large, propodos with
proximal poison tooth followed by a pair of small protuberances, palm distally
with a strong pointed tooth separated from a triangular tooth near the hinge
by a semicircular excavation; dactyl strong, equal to palm; branchiae elongate-
elliptical, three pairs found on pereon segments 2-4; pereiopods 1 and 2
6-segmented, palm of propodos proximally with three spines; pereiopod 3
3-segmented, propodos lacking palm and without spines; (pereiopods 4 and 5
missing).

Abdomen with two pairs of bi-articulate appendages (Fig. 7D); article 1
of each dorsally with closely packed short spines set in a row, article 2 of each
appendage distally finely setose.

Female: Rostral projection shorter and of different shape to that of the male;

THE AMPHIPODA OF SOUTHERN AFRICA 261

antenna 2 as long as peduncle of antenna 1; propodos of gnathopod 2 smaller
than that of male, palm evenly convex with a row of 12 short strong spines
evenly spaced along its length and a small poison tooth at defining angle;
pereiopods as in male but 1 and 2 lacking spines; pereon segments 3 and 4
ventro-laterally produced into projecting keels, ventrally with large brood
pouches; abdomen as in male.

Holotype: SAM A13165, male, 11 mm.
Type-locality: NAD 15K, 13 August 1958, 30°47'S/30°27’E, depth 36 m.
Material: ‘Three males and three females from the type-locality.

SUMMARY

Data from the considerable collections amassed by the University of
Cape Town Ecological Survey and the National Institute for Water Research
have been incorporated with the records of previous authors in listing the known
gammaridean and caprellid amphipod fauna of Natal. A total of 115 species is
recognized from the area. Of these six species and one genus are described as
new to science, namely Microdeutopus thumbellinus n. sp., Unciolella spinosa n. sp.,
Ceradocus natalensis n. sp., Urothoe coxalis n. sp., Urothoe tumorosa, n. sp., and
Chaka leont n. gen., n. sp., (Phtisicidae). In addition two existing species,
Gammaropsis imminens K. H. Barnard and Gammaropsis semidentatus K. H. Barnard
are synonymized with Gammaropsis atlantica Stebbing and Gammaropsis holmesi
Stebbing respectively.

References to and distributions for each species are given, as well as brief
diagnoses of those species not previously described in Parts 1 and 2 of this series.

ACKNOWLEDGEMENTS

I am indebted to Professor J. H. Day for his advice and constructive
criticism throughout the preparation of this work; also to Mr T. P. McClurg
of the National Institute for Water Research for the loan of material and Mr
B. F. Kensley for the loan of type specimens in the possession of the South
African Museum.

My thanks also go to Miss Belle Leon for her enthusiastic assistance in
cataloguing of specimens and drafting the manuscript. Financial support
for this work was provided by the South African Council for Scientific and
Industrial Research.

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264 ANNALS OF THE SOUTH AFRICAN MUSEUM

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—————— ET ——————OrrrCr-Ssé=i‘é‘ ts”t;t”tt

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Buttoucu, W. S. 1960. Practical invertebrate anatomy. 2nd ed. London: Macmillan.

FiscHER, P.-H. 1948. Données sur la résistance et de le vitalité des mollusques. 7. Conch., Paris
88: 100-140.

Fiscuer, P.-H., Duvat, M. & Rarry, A. 1933. Etudes sur les échanges respiratoires des littorines.
Archs Zool. exp. gén. 74: 627-634.

Konn, A. J. 1960a. Ecological notes on Conus (Mollusca: Gastropoda) in the Trincomalee region
of Ceylon. Ann. Mag. nat. Hist. (13) 2: 309-320.

Koun, A. J. 19606. Spawning behaviour, egg masses and larval development in Conus from the
Indian Ocean. Bull. Bingham oceanogr. Coll. 17 (4): I-51.

THIELE, J. 1910. Mollusca: B. Polyplacophora, Gastropoda marina, Bivalvia. In: SCHULTZE, L.
Zoologische und anthropologische Ergebnisse einer Forschungsreise im westlichen und zentralen Stid-
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Gods Griffiths

THE AMPHIPODA OF SOUTHERN AFRICA
PART 3

THE GAMMARIDEA AND CAPRELLIDEA
OF NATAL

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OLUME 62 PART 8 MARCH 1974

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ANNALS OF THE SOUTH AFRICAN MUSEUM
ANNALE VAN DIE SUID-AFRIKAANSE MUSEUM

Volume 62 ~ Band
March 1974 March
Part 8 Deel

THE GENUS CALLIANASSA (CRUSTACEA,
DECAPODA, THALASSINIDEA)
FROM THE WEST COAST OF SOUTH AFRICA
WITH A KEY TO SOUTH AFRICAN SPECIES

By
Brian Kensley

Cape Town Kaapstad

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THE GENUS CALLIANASSA (CRUSTACEA, DECAPODA,
THALASSINIDEA)
FROM THE WEST COAST OF SOUTH AFRICA

WITH A KEY TO THE SOUTH AFRICAN SPECIES

By
BRIAN KENSLEY

South African Museum, Cape Town

(With 5 figures)

[Ms. accepted 12 February 1974]

CONTENTS

PAGE
Introduction ; F ‘ ; : : : : . 265
Description ; ‘ 4 . ; ‘ : , . 266
Key to the South African species of Callianassa . : sr aes
Distribution of the South African species of Callianassa . eae
Summary , : ’ : ; : 3 ; Aad iF,
Acknowledgements 3 : , . : é . 278
Gazetteer : : 5 : ; : f : Sey 0)
References ; ; : 3 5 : ; : : 278

INTRODUCTION

When two species of Callianassa submitted to the South African Museum
for identification proved to be problematic, it was decided to re-examine all
the available mud-shrimp material from the west coast. As a result of this
investigation, where previously three species were recorded from the area,
five are now known, two of which have proved to be undescribed. In the
accompanying figures, all dimensions are in millimetres.

265

Ann. S. Afr. Mus. 62 (8), 1974: 265-278, 5 figs.

266 ANNALS OF THE SOUTH AFRICAN MUSEUM

DESCRIPTION

Callianassa adamas sp. n.

Figs 1, 2
Description
¢g. Front of carapace evenly convex, rostrum a low rounded protuberance.
First two abdominal segments more slender than following segments. Abdominal
segments three to five with transverse band of short setae on mid-lateral areas.
Eyestalks touching only at bases, tapering distally, reaching slightly beyond
midpoint of 2nd antennular peduncle segment.
Antennule, peduncle three-segmented, basal segment somewhat shorter than
and segment, latter half length of distal segment.
Antenna, peduncle five-segmented, two distal segments subequal, three basal
segments together equal in length to fourth segment.
Mandible, palp three-segmented, terminal segment bearing numerous curved
spines, grading proximally into slender elongate spine-like setae. Incisor
portion bearing nine well-separated teeth, molar portion consisting of single
blunt tooth.
First maxilla, exopod shorter than outer endopod lobe, distally flexed.
Second maxilla, scaphognathite broadly oval.
First maxilliped endopod oval in outline, with broad band of densely packed
setae on outer face. Exopod distally rounded.
Second maxilliped, dactyl with seven or eight spines on inner distal margin,
one-third length of propodus. Latter distally swollen, bearing numerous
elongate setae. Carpus very short, carpus and propodus together equal in
length to merus, latter curved, with broad setal fringe on inner margin. Exopod
leaf-shaped, curved, reaching to end of carpus.
Third maxilliped operculiform, propodus and carpus expanded, latter one-
third longer than former, both with strong rounded longitudinal ridge on
outer face. Merus and ischium together forming very broad plate-like structure,
spines lacking on inner face.
First pereiopod, smaller cheliped, dactyl slightly longer than palm, extending
beyond fixed finger, cutting edge entire. Cutting edge of fixed finger with few
tiny denticulations proximally. Carpus slightly more than twice longer than
wide, merus and ischium narrower than carpus, ischium slightly longer than
merus.
First pereiopod, larger cheliped, three distal segments together 24 times mid-
dorsal length of carapace. Dactyl extending beyond tip of propodal fixed
finger, slightly more than half length of palm, distally strongly curved, cutting
edge with strong rounded tooth proximally, another at about midpoint, inner
surface with several scattered granules. Margin of fixed finger entire, with row
of very faint granules on inner surface. Propodus ventrally carinate. Carpus a
little longer than propodus and dactyl together, disto-ventral corner acute,

THE GENUS CALLIANASSA FROM THE WEST COAST OF SOUTH AFRICA 267

=== S
S531
y aA

BW Xe
suis NY \ S

AWA WY

Ah Wits

Fig. 1. Callianassa adamas sp. n. 3. Holotype
A. Anterior carapace, antennae, and eyes in dorsal view. B. Telson and right uropod. C. First
maxilla. D. Second maxilla. E. Second maxilliped with dactyl further enlarged. F. Mandible.
G. Third maxilliped. H. First maxilliped.

268 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 2. Callianassa adamas sp. n. 6. Holotype
A. Large cheliped, with chela further enlarged. B. Smaller cheliped. C. Second pereiopod,
D. Third pereiopod. E. Fourth pereiopod. F. Fifth pereiopod with chela further enlarged.
G. First pleopod. H, Second pleopod. J. Third pleopod, with reduced appendix interna
further enlarged.

THE GENUS CALLIANASSA FROM THE WEST COAST OF SOUTH AFRICA 269

disto-dorsal corner rounded, proximo-ventral corner evenly rounded, finely
denticulate. Merus three-fifths length of carpus, ventral margin and part of
outer surface granulate, proximo-ventral corner somewhat expanded into
rounded crest. Ischium five-fourths length of merus, with broad hook-like
process at midventral margin, most of outer surface grantulate.

Second pereiopod chelate, dactyl two-thirds length of propodus, latter broadly
triangular. Carpus distally broadened, about three-quarters length of merus.
Ventral margins of merus, carpus and propodus heavily setose.

Third pereiopod dactyl and propodus heavily setose. Propodus produced into
rounded-conical posterior lobe. Dactyl triangular. Carpus and merus subequal
in length.

Fourth pereiopod non-chelate, dactyl about half length of propodus, latter
with dense disto-ventral setal ‘brush’. Propodus two-thirds carpus length,
carpus slightly shorter than merus.

Fifth pereiopod chelate, dactylus one third total length of propodus. Dactyl and
propodus apically spooned, rounded apical areas marked by minute row of
denticles. Dactyl and distal portion of propodus heavily setose. Propodus and
carpus equal in length, merus somewhat longer.

First pleopod two-segmented, basal segment slightly less than half length of
distal segment. Latter flexed at about midpoint, bearing very few setae.

Second pleopod biramous, basopodite slightly less than length of inner ramus.
Latter broad, tapering distally, outer ramus small, about one-sixth length of
inner.

Third pleopod, inner ramus triangular, appendix interna reduced to a pad of
rounded hooks on median margin of segment.

Uropod rami reaching well beyond telsonic apex. Inner ramus 23 times longer
than wide, apically tapering, rounded. Outer ramus distally evenly convex,
with broad band of short dense setae, and with median curved ridge.

Telson wider than long, with tiny medio-distal notch, proximally with median
convex area, and two lateral convex areas.

Q. First chelipeds similar to smaller cheliped of male.

First and second pleopods as in male.

Material

Holotype S.A.M.A12103 3 C.L. 15,8 mm T.L. 65 mm
Orange River mouth

Allotype S.A.M.A12103 2 C.L. 14,0 mm T.L. 58 mm
Orange River mouth

Paratype S.A.M.A10985 3 C.L. 14,0 mm T.L. 59 mm
Olifants River mouth

Paratype LBT.77A 2 C.L. 12,9 mm T.L. 51 mm

Lambert’s Bay

Numerous immature specimens with an average total length of 14 mm were
obtained off Lambert’s Bay. The shape of the eyestalks and telson, and the

270 ANNALS OF THE SOUTH AFRICAN MUSEUM

appendages generally, indicate that these are probably juveniles of the present
species.

The holotype and allotype were collected by the diamond dredge Emerson-K
off the Orange River mouth in 1962, and were mentioned in a report on the
material from the diamond grading grids by Grindley & Kensley (1966:9).
The depth of the sampling was between 10 and 35 m. The female paratype
and the numerous juveniles were obtained off Lambert’s Bay by the Zoology
Department of the University of Cape Town, using a suction sampling device.
The material came from a depth of about 60 cm in the fine mud/silt substrate,
in a water depth of 10-15 m. The male paratype was collected at the mouth of
the Olifants River in 1960, but no depth or substrate information was recorded.

Remarks

The most striking feature of the present species is the elongate nature of
the large cheliped of the male, quite unlike any species previously recorded
from South Africa. Of the numerous species of Callianassa described from other
parts of the world, only two would seem to have a similar elongate first cheliped.
These are C. major Say, recorded from the eastern United States of America,
especially the southern states where it occurs intertidally, and C. islagrande
Schmitt, known from Louisiana.

Callianassa major can easily be separated from the present species on the basis
of the large cheliped of the male. The dactylus of C. major possesses a single blunt
tooth proximally on the cutting edge, as opposed to two large rounded teeth
in the present species. The merus of the American species has a distinct tri-
angular process on the proximo-ventral margin, whereas, although the merus
of the present species is somewhat expanded proximo-ventrally, there is no
distinct process. The telson of C. major would seem to be more rounded than
C. adamas, while the eyestalks are relatively shorter in Say’s species, reaching to
the end of the first antennular peduncle segment. In the present species the
eyestalks extend to beyond the middle of the second antennular peduncle
segment.

The resemblance of C. adamas to C. islagrande is much greater; indeed,
using both keys to the genus Callianassa from Florida provided by Biffar (1971),
the species is run down to C. islagrande. From Schmitt’s description (1935:5),
and the rather inadequate photograph, several differences emerge on com-
parison with the present species. These are given in the following table, and
would seem to warrant specific separation, not altogether surprising, the two
species being separated by the width of the Atlantic Ocean.

C’. islagrande C’. adamas
Eyestalks Twice as long as broad, con- ‘Three times longer than
tiguous to level of cornea broad, contiguous only at

bases, cornea not distinct

THE GENUS CALLIANASSA FROM THE WEST COAST OF SOUTH AFRICA 271

Antenna

Large
Cheliped g

Third
Maxilliped

Uropod

C’. islagrande

Fourth peduncle segment
reaching end of second anten-
nular peduncle segment

Merus with low denticulate/
granulate tooth at posterior
third

Carpus finely denticulate on
upper margin for almost whole
length, lower margin with
widely separate granules or
denticles on distal four-
sevenths

Dactylus with conspicuous
blunt right-angled tooth on
upper border of terminal hook
No strong rounded tooth at
mid-point of cutting margin

Fixed finger of propodus arises
from deep sinus in palm
Inner face of ischium with
crescentic row of tiny granula-
tions

Inner ramus four times longer
than wide

C’. adamas

Fourth peduncle segment
reaching mid-point — or
slightly beyond, second
antennuiar peduncle segment
Merus widened proximally,
no distinct tooth

Carpus weakly granulate on
upper margin for proximal
third, lower margin smooth

No tooth on upper border of
terminal hook

Strong rounded tooth pre-
sent at mid-point of cutting
margin

Sinus at base of fixed finger
barely apparent

No granulations on inner face
face of ischium

Inner ramus 24 times longer
than wide

The specific name ‘adamas’ is from the Latin for a diamond, the species having
been caught on the Diamond Coast of South Africa.

Description

Callianassa subterranea australis subsp. n.

Figs 3-5

3. Front with shallow rostrum, sides slightly concave, no lateral projections

present.

Eyestalks medially contiguous, reaching almost to midpoint of second antennu-
lar peduncle segment. Pigmented area situated centrally. Antennule with two
basal peduncular segments together equal in length to distal segment, peduncle
reaching to about midpoint of third antennal peduncle segment.
Antennae with first three segments short, third with two squat spines distally,
fifth segment about three-quarters length of fourth, both slender.

272

ANNALS OF THE SOUTH AFRICAN MUSEUM

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Aes

—~

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‘|| Z
| 4 j ; LE
5 SE
\ YEE
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-_— =
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oo SESS 0
AF MS
ht y th \
£ OL yl
Wf Z

Fig. 3. Callianassa subterranea australis subsp. n. g. Holotype

A. Anterior carapace, antennae, and eyes in dorsal view. B. Telson and left uropod. C. First

maxilla. D. Second maxilla. E. First maxilliped. F. Second maxilliped. G. Third maxilliped,
with inner view of ischium. H. Mandible.

THE GENUS CALLIANASSA FROM THE WEST COAST OF SOUTH AFRICA 273

Mandible with incisor portion bearing 12-13 strong teeth, molar portion with
four strong teeth and row of six tiny denticulations. Palp three-segmented
distal segment equal in length to two proximal segments together.

First maxilla, exopod slender, distally bearing flattened portion at right angles
to rest of segment. Outer lobe of endopod, median margin bearing numerous
short spines. Inner lobe bearing several serrate spines on median (inner) face.
Second maxilla, exopod with short rough triangular distal segment, and
elongate proximal segment.

First maxilliped, exopod distally rounded, fringed with setae. Epipod with
small median lobe, and larger acute external lobe.

Second maxilliped, merus elongate, four times longer than wide, ischium
bearing two small projections on inner margin, exopod three-quarters length
of endopod merus.

Third maxilliped, merus and ischium broad, latter with sinuous row of about
15 or 16 strong conical denticles on inner surface.

First pereiopod, smaller cheliped, dactyl and fixed finger of propodus slightly
longer than palm, cutting margins entire. Carpus four times longer than wide,
only slightly longer than propodus. Merus broad, margins convex. Ischium
more slender than merus, slightly longer.

First pereiopod, larger cheliped, dactyl strongly hooked, cutting edge bearing
broad proximal very finely denticulate portion, followed by small blunt tooth.
Propodus broad, fixed finger evenly curved, cutting edge entire, dorsal margin
carinate, ventral margin finely crenulate. Dactyl and propodus together 2}
times length of carpus, latter with proximo-ventral angle evenly and broadly
rounded, finely crenulate, dorsally carinate. Merus slightly shorter than dorsal
length of carpus. Dorsal margin with five small denticulations proximally.
Ventral margin with strong denticulate hook-like process proximally, followed
by denticulate convex crest.

Ischium and merus equal in length. Ischium proximally narrow, widening
distally, ventral margin with about 10 small denticles, dorsal margin with
hook-like process proximally.

Second pereiopod chelate, propodus equal in length to carpus, merus somewhat
longer; all three distal segments, and ventral margin of merus fringed with setae.
Third pereiopod, dactyl slightly less than half length of propodus, covered
with fine setae, elongate-triangular. Propodus with ventral margin bearing five
isolated tufts of setae flanked by broad band of setae; posterior lobe not extend-
ing beyond ventral margin of carpus. Carpus about four-fifths length of merus,
bearing distal setae.

Fourth pereiopod non-chelate, dactyl about half length of propodus, covered
with numerous setae. Propodus with ventral margin and external surface
bearing three bands of dense setae.

Fifth pereiopod with propodus, carpus, and merus elongate. Tiny chela formed
by small dactyl and even smaller ‘thumb’ of propodus. Latter with dense pad
of setae on distal outer surface.

274 ANNALS OF THE SOUTH AFRICAN MUSEUM

Fig. 4. Callianassa subterranea australis subsp. n. g. Holotype
A. Larger cheliped. B. Smaller cheliped. C. Second pereiopod. D. Fourth pereiopod. E. Fifth
pereiopod. F. Third pereiopod. G. First pleopod. H. Second pleopod. J. Third pleopod,
with appendix interna further enlarged. K. Callianassa subterranea subterranea, two distal segments
of third pereiopod.

THE GENUS CALLIANASSA FROM THE WEST COAST OF SOUTH AFRICA 275

First pleopod cylindrical, two-segmented, segments subequal.

Second pleopod consisting of single segment, basally swollen.

Third pleopod, endopod two-segmented, triangular, with appendix interna
on median margin of distal segment, fringed with plumose setae.

Uropod with inner ramus distally rounded, only slightly longer than telson,
longer than wide. Outer ramus with broad rounded ridge, distally rounded,
bearing fringe of dense slender spines in addition to fringe of setae.

Telson distally truncate, with minute median and two lateral spinules, as long
as wide, sides straight, converging distally.

Q. First pereiopod, larger cheliped, dactyl about equal to palm in length,
slightly longer than fixed finger of propodus, evenly serrate on cutting edge.
Fixed finger with cutting edge entire, distally slightly upturned. Lower margin
of propodus finely serrulate, upper margin entire, carinate. Carpus slightly
shorter than palm of propodus, proximo-ventral corner broadly rounded,
margin finely serrulate. Merus equal in length to dorsal length of carpus, with
four or five small denticulations on proximo-dorsal edge, ventral margin with
broad hook-like process, ventrally denticulate, and with convex denticulate
crest. Ischium longer than merus, ventral margin finely serrulate, distally
broader than proximally.

First pleopod uniramous, two-segmented basal segment about half length of
distal segment, slightly curved. Distal segment becoming leaf-like for slightly
less than distal half, with rounded setae-bearing bulge at base.

ei

Fig. 5. Callianassa subterranea australis subsp. n. 2. Allotype
A. Large cheliped. B. First pleopod. C. Second pleopod.

276 ANNALS OF THE SOUTH AFRICAN MUSEUM

Second pleopod biramous. Basopodite broader than rami. Inner ramus of one
segment elongate and slender. Outer ramus of two segments, basal segment
twice length of distal, with rounded bulge distally, bearing elongate setae.

Material

Holotype S.A.M.A13531
Allotype S.A.M.A13532
Paratype S.A.M.A13533
Paratype S.A.M.A13534
Paratype S.A.M.A12103

C.L. 14,9mm T.L. Liideritzbucht
C.L. 13,8mm T.L. 50mm _ Liideritzbucht
C.L. 9,9mm T.L.32mm_ Lideritzbucht
C.L. 12,3mm T.L.41mm_ Liideritzbucht
C.L.13,0mm T.L.53mm Orange River
mouth

RO) SRO) Obs, SRO) (On

In addition, the following paratypes from Liideritzbucht, in the collection of
the Zoology Department, University of Cape Town, catalogue number
SWD.5U: 7 gg T.L. range 34-48mm, 8 99 T.L. range 43-48mm

The Liideritzbucht material was dredged from a depth of 180m by the John D.
Gilchrist of the University of Gape Town, from a bottom of fine gravel and rock.
The total length of the holotype cannot be given as the abdomen is detached.

Remarks

Of the four species of Callianassa recorded from South Africa only C. rotundi-
caudata does not possess a well-developed lobe on the propodus of the third
pereiopod, as is the case in the present species. The shape and relative size of
the telson, and the character of the larger cheliped of the male easily serve to
separate these species.

The resemblance between the present species and C. subterranea (Montagu)
known from the coasts of Great Britain, the Mediterranean, the North Sea,
and the Atlantic coasts of Western Europe and North Africa (Poulsen 1940;
De Man 1928) is unmistakable. From the full description of this species given by
De Man (1928) and from comparison with material from Plymouth, England,
only two differences emerge in the South African material. These are in the
shape of the propodus of the third pereiopod, and in the larger chela of the
male.

The propodus of the third pereiopod in C. subterranea has a posterior lobe
somewhat rounded and tapered, while in the present material, the posterior
lobe is relatively broader and squarer.

The larger chela in the male of the European species has the cutting edges
of both the dactyl and the fixed finger unarmed except for some fine denticula-
tions. This resembles very closely the larger cheliped of the female of the present
material. In the male, however, the cutting edge of the dactyl in the larger
chela possesses a strong flat-topped proximal tooth and a smaller reunded distal
tooth.

With only these two differences, and with the almost identical structure
of the body and all the other appendages, the close affinity between the European

THE GENUS CALLIANASSA FROM THE WEST COAST OF SOUTH AFRICA Pt S|

and the South African species cannot be denied. With no records of C. sub-
terranea between that in North Africa and the present South African records,
it may be postulated that this is a case of antitropical distribution, with the
southern form beginning to diverge from its (presumably) northern stock. With
no further information available, it is perhaps best to designate the South
African material as a different subspecies from the European form. Thus the
latter is Callianassa subterranea subterranea, while the form here described is
Callianassa subterranea australis.

eS rf

C.
C
C
C.
C

C.

KEY TO THE SOUTH AFRICAN SPECIES OF CALLIANASSA

Third pereiopod with propodus produced into well-developed pau or hammer-

headed posterior lobe : : : gh
Third pereiopod with posterior soxien of seagate not prodeeed ; : : ae ad
Inner ramus of uropod oval, extending well beyond telsonic apex. 5 a) a pike
Inner ramus of uropod distally square, not extending beyond telsonic sae natalensis
Third, fourth, and sixth segments of third maxilliped expanded

Large chela with strong blunt proximal tooth on dactyl . : 3 A kraussi
Third, fourth, and sixth segments of third maxilliped not aapenaed

No strong blunt proximal tooth on dactyl oflarge chela_ . ‘ : ‘ . gilchristi
Uropods extending well beyond telsonic apex

Dactyl of large chela in male lacking broad flat-topped proximal tooth . : ees

Uropods not extending well beyond telsonic apex
Dactyl of large chela in male with broad flat-topped proximal tooth subterranea australis
Telson distally evenly rounded

Ischium of larger cheliped in male lacking ventral hook-like spine. . rotundicaudata
Telson distally broadly bilobed
Ischium of larger cheliped in male with broad ventral hook-like process. : adamas

DISTRIBUTION OF THE SOUTH AFRICAN SPECIES
OF CALLIANASSA

adamas sp. n. Orange River mouth, Olifants River mouth, Lambert’s Bay,
10-35m depth
. gilchristi Barnard Saldanha Bay, False Bay to Durban, 36 m depth
. krausst Stebbing Saldanha Bay, False Bay to Zululand
natalensis Barnard off Natal
. rotundicaudata Stebbing Orange River mouth, Saldanha Bay, False Bay, Algoa Bay,
10-35m depth
subterranea australis subsp. n. Liideritzbucht, Orange River mouth, 10-180m depth
SUMMARY

A new species and a new subspecies of the mud-shrimp genus Callianassa

is described from the west coast of South Africa. The six southern African
species of Callianassa are reviewed, and a key to the species is provided.

278 ANNALS OF THE SOUTH AFRICAN MUSEUM

ACKNOWLEDGEMENTS

I am grateful to Dr R. W. Ingle of the British Museum (Natural History)
for making specimens of Callianassa subterranea available for comparison, and
for his critical reading of the manuscript, and to Professor J. H. Day and Mr
N. Christie of the Department of Zoology of the University of Cape Town for
providing material of both the new species and new subspecies here described.

GAZETTEER
Algoa Bay 33.589., 25.36E.
Durban 29.539., 31.00E.
False Bay 34.128., 18.56E.
Lambert’s Bay BO} OAM So, MAO! Oi
Lideritzbucht 26.38S., 15.10E.
Olifants River mouth BU AMES 18) 1B) eh,
Orange River mouth 28.38S., 16.27E.
Saldanha Bay 33.009., 17.56E.

REFERENCES

BirFarR, T. A. 1971. The genus Callianassa (Crustacea, Decapoda, Thalassinidea) in south Florida,
with keys to the western Atlantic species. Bull. mar. Sci. 21: 637-715.

DE Man, J. G. 1928. A contribution to the knowledge of twenty-two species and three varieties
of the genus Callianassa Leach. Capita zool. 2 (6): 1-56.

GRINDLEY, J. R. & KeEnsLey, B. F. 1966. Benthonic marine fauna obtained off the Orange
River Mouth by the diamond dredger Emerson-K. Cimbebasia 16: 1-14.

Poutson, E. M. 1940. On the occurrence of the Thalassinidea in Danish waters. Vidensk. Meddr
dansk naturh. Foren. 104: 207-239.

Scumitt, W. L. 1935. Mud shrimps of the Atlantic coast of North America. Smithson. misc. Collns

93 (2): I-21.

INSTRUCTIONS TO AUTHORS

Based on

CONFERENCE OF BIOLOGICAL EDITORS, COMMITTEE ON FORM AND STYLE. 1960.

Style manual for biological journals. Washington: American Institute of Biological Sciences.

MANUSCRIPT

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Figure captions and tables to be on separate sheets.

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To be reducible to 12 cm X 18 cm (19 cm including caption). A metric scale to appear
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All illustrations to be termed figures (plates are not printed; half-tones will appear in their
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REFERENCES

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For books give title in italics, edition, volume number, place of publication, publisher.
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volume number, part number (only if independently paged) in parentheses, pagination.

Examples (note capitalization and punctuation)

But.LoucnH, W. S. 1960. Practical invertebrate anatomy. 2nd ed. London: Macmillan.

FiscHER, P.-H. 1948. Données sur la résistance et de le vitalité des mollusques. 7. Conch., Paris
88: 100-140.

FiscHER, P.-H., Duva., M. & Rarry, A. 1933. Etudes sur les échanges respiratoires des littorines.
Archs Zool. exp. gén. 74: 627-634.

Konn, A. J. 1960a. Ecological notes on Conus (Mollusca: Gastropoda) in the Trincomalee region
of Ceylon. Ann. Mag. nat. Hist. (13) 2: 309-320.

Koun, A. J. 1960). Spawning behaviour, egg masses and larval development in Conus from the
Indian Ocean. Bull. Bingham oceanogr. Coll. 17 (4): 1-51.

THIELE, J. 1910. Mollusca: B. Polyplacophora, Gastropoda marina, Bivalvia. Jn: scHULTZE, L.
Koologische und anthropologische Ergebnisse einer Forschungsreise im westlichen und zentralen Stid-
Afrika. 4: 269-270. Jena: Fischer. Denkschr. med.-naturw. Ges. Jena 16: 269-270.

ZOOLOGICAL NOMENCLATURE

To be governed by the rulings of the latest International code of zoological nomenclature issued
by the International Trust for Zoological Nomenclature (particularly articles 22 and 51).
The Harvard system of reference to be used in the synonymy lists, with the full references
incorporated in the list at the end of the article, and not given in contracted form in the synonymy
list.

Example
Scalaria coronata Lamarck, 1816: pl. 451, figs 5 a, 6; Liste: 11. Turton, 1932: 80.

Brian Kensley

THE GENUS CALLIANASSA (CRUSTACEA,
DECAPODA, THALASSINIDEA)

FROM THE WEST COAST OF SOUTH AFRICA
WITH A KEY TO THE SOUTH AFRICAN SPECIES

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