PHYLOGENETIC RELATIONSHIPS AND TAXONOMIC
REVISION OF THE BLENNIID FISH GENERA
Cirripectes AND Sear t ichthys

By
JEFFREY TAYLOR WILLIAMS

A DISSERTATION PRESENTED TO THE GRADUATE
SCHOOL OF THE UNIVERSITY OF FLORIDA IN

PARTIAL FULFILLMENT OF THE REQUIREMENTS
FOR THE DEGREE OF DOCTOR OF PHILOSOPHY

UNIVERSITY OF FLORIDA
1986

ACKNOWLEDGEMENTS

During my work on this project, many people have assisted me in
various ways. I thank all of them. In particular, I thank W. F.
Smith-Vaniz, E. Bohlke, W. Saul, and staff (Academy of Natural Sciences
of Philadelphia); P. C. Heemstra (J. L. B. Smith Institute of
Ichthyology); T. Iwamoto, W. N. Eschmeyer, L. Dempster, and staff
(California Academy of Sciences); R. Winterbottom and staff (Royal
Ontario Museum); C. R. Gilbert, G. Burgess and J. B. Miller (Florida
State Museum); K. Hartel (Museum of Comparative Zoology, Harvard); M.
L. Bauchot and M. Desoutter (Museum National d'Histoire Naturelle); A.
G. Gerberich, K. A. Bruwelheide, L. P. Norrod , S. L. Jewett, J. R.
Gomon, and Victor G. Springer (Smithsonian Institution), and the staff
at all other museums that provided specimens, radiographs, and/or other
technical assistance. I thank V. G. Springer, W. F. Smith-Vaniz, and
H. Bath for their gracious hospitality while I was visiting museums.
For providing color transparencies of specimens, I thank J. E. Randall,
V. G. Springer, R. Winterbottom, and B. Carlson.

C. R. Gilbert and V. G. Springer generously gave their time to
discuss my project. I gratefully acknowledge their help.

Financial support for this study was provided in part by the
Department of Zoology and Florida State Museum, University of Florida;
the California Academy of Sciences; and the National Science Foundation

11

(Predoctoral Improvement Grant DEB 8207313). I thank my parents for
their support throughout the study.

Finally, I thank my wife, Karen, for her support, editorial
comments, and seemingly limitless understanding.

in

TABLE OF CONTENTS

PAGE

ACKNOWLEDGEMENTS "

ABSTRACT vi

INTRODUCTION 1

HISTORICAL TREATMENT OF THE BLENNIIDAE 6

METHODS 9

Taxonomic Methods 9

Methods of Phylogenetic Analysis 10

PHYLOGENETIC ANALYSIS 12

Family Blenniidae 15

Salariini-"Blenniini" Group 18

"Blenniini" 19

Salariini 20

Alticus Group 28

Node I Group

Genus Istiblennius 32

Node II Group 32

Genus Entomacrodus 36

Node III Group 36

Genus Stanulus 37

Node IV Group 38

Genus Pereulixia - 45

Node V Group 49

Genus Exal lias 54

Node VI Group 54

Genus Cirripectes ■>

Node VII Group 61

Genus Ophioblennius 61

Genus Scartichthys 62

DISCUSSION OF PHYLOGENETIC ANALYSIS OF GENERA 63

PHYLOGENETIC RELATIONSHIPS OF CIRRIPECTES SPECIES 68

Node VIII Group 68

Node IX Group

Node X Group 73

LV

Node XI Group 76

Node XII Group 76

Node XIII Group 77

Node XIV Group 80

Node XV Group 80

Node XVI Group 81

Node XVII Group 82

Cirripectes SWAINSON 87

Key to the Species of Cirripectes 109

Cirripectes alboapicalis (Ogilby) 143

Cirripectes auritus Carlson 149

Cirripectes castaneus (Valenciennes) 155

Cirripectes chelomatus Williams and Mauge 165

Cirripectes filamentosus (Alleyne and Macleay) 170

Cirripectes fuscoguttatus Strasburg and Schultz 180

Cirripectes gi^berti new species 184

Cirripectes hutchinsi new species 189

Cirripectes imitator Williams 195

Cirripectes jenningsi Schultz 199

Cirripectes kuwamurai Fukao 203

Cirripectes obscurus (Borodin) 205

Cirripectes perustus Smith 209

Cirripectes polyzona (Bleeker) . . . , 213

Cirripectes quagga (Fowler and Bail) 219

Cirripectes randalli new species. 226

Cirripectes springeri new species.,,, 230

Cirripectes stigmaticus Strasburg and Schultz 234

Cirripectes vanderbilti (Fowler) 241

Cirripectes variolosus (Valenciennes) 246

Scartichthys JORDAN AND EVERMANN 254

Key to the Species of Scartichthys 260

Scartichthys crapulatus new species 265

Scartichthys gigas (Steindachner) 267

Scartichthys variolatus (Valenciennes) 272

Scartichthys viridis (Valenciennes) 276

Exallias JORDAN AND EVERMANN 282

Exallias brevis (Kner) 283

HISTORICAL ZOOGEOGRAPHY 291

APPENDIX 302

LITERATURE CITED 307

BIOGRAPHICAL SKETCH 314

Abstract of Dissertation Presented to the Graduate School
of the University of Florida in Partial Fulfillment of the
Requirements for the Degree of Doctor of Philosophy

PHYLOGENETIC RELATIONSHIPS AND TAXONOMIC
REVISION OF THE BLENNIID FISH GENERA
Cirripectes AND Scartichthys

By

Jeffrey Taylor Williams

May 1986

Chairman: Carter R. Gilbert
Major Department: Zoology

The blenniid fish tribe Salariini comprises a group of marine shore
fishes found circumglobally in tropical and subtropical seas. Members
of the tribe are quite similar ecologically, with most being herbivores
or deposit feeders and inhabiting rocky or coralline areas.

The salariin genera Cirripectes , Scartichthys , Exallias ,
Ophioblennius , and Pereulixia form a monophyletic group closely related
to the genera Stanulus , Entomacrodus , and Istiblennius . A phylogenetic
analysis supports the hypothesis that each of the following genera is
the sister genus to a combination of all preceding genera:
Scartichthys , Ophioblennius , Cirripectes , Exallias , Pereulixia,
Stanulus , Entomacrodus , and Istiblennius (including at least the J_.
gibbifrons species complex). A hypothesis of the relationships among
the species of Cirripectes is illustrated in a cladograra.

VI

The genera Cirripectes and Scartichthys are taxonomically revised.
Cirripectes occurs throughout the Indo-Pacific region and comprises the
following 20 species: C_. alboapicalis (Australia to Easter Island), C_.
auritus (western Indian Ocean to Line Islands), C_. castaneus (Indian
Ocean and Red Sea to western Pacific Ocean), C_. chelomatus (Coral Sea
to Tonga Islands), C. f ilamentosus (western Indian Ocean to western
Pacific Ocean), C_. fuscoguttatus (Pacific Plate), C_. gilberti new
species (Indian Ocean), C. hutchinsi new species (western Australia),
C_. imitator (Taiwan to Japan and Ogasawara [Bonin] Islands), £.
jenningsi (Gilbert Islands to Tuamotu Archipelago), C_. kuwamurai
(Japan), C_. obscurus (Hawaiian Islands), C_. perustus (western Indian
Ocean to Gilbert Islands), C. polyzona (western Indian Ocean to Line
Islands), C. quagga (western Indian Ocean to Pitcairn Island Group), C_.
randalli new species (Mauritius and Cargados Carajos Shoals), C.
springeri new species (Philippines to Solomon Islands), C_. stigmaticus
(western Indian Ocean to Samoa), C. vanderbilti (Hawaiian Islands and
Johnston Island), and _C. variolosus (Pacific Plate).

Scartichthys is restricted to the eastern Pacific Ocean and
comprises four species: S. crapulatus new species (northern Chile and
vicinity of Valparaiso), S^. gigas (Panama to northern Chile), S_.
variolatus (San Felix, San Ambrosio, and Juan Fernandez Islands), and
S_. viridis (vicinity of Valparaiso to southern Peru).

Area cladograms derived from the phyiogenetic analyses are
analyzed. Eleven geographic patterns indicated by the cladogram are
discussed .

Vll

INTRODUCTION

The blenniid fish tribe Salariini comprises a group of marine shore
fishes found circumglobally in tropical and subtropical seas. Members
of the tribe are quite similar ecologically; most are herbivores or
deposit feeders and inhabit rocky or coralline areas.

The objectives of the present study are to 1 ) test the hypotheses
that the genera Cirripectes , Scartichthys , Ophioblennius , Pereulixia
and Exallias comprise a monophyletic group and are each monophyletic ;
2) if the first hypotheses are confirmed, form phylogenetic hypotheses
of interrelationships of the species of Cirripectes ; 3) taxonomically
revise Cirripectes and Scartichthys , and provide complete species
descriptions of and distribution maps for each of the included species;
and 4) analyze the distribution patterns of these genera and their
included species.

Smith-Vaniz and Springer (1971) gave a synopsis of the Salariini to
provide a foundation for future work on the tribe. They pointed out
several genera that needed additional study and provided a preliminary
hypothesis of the relationships of the 24 genera they recognized in the
tribe. Their method was not cladistic, but they did establish the
monophyletic nature of the tribe Salariini. Although they did not
cladistically analyze the members of the tribe, they provided a
dendrogram (Smith-Vaniz and Springer, 1971: fig. 51) of the genera

showing their interrelationships. This dendrogram suggests that the
genera Cirripectes , Scartichthys , Exallias , Pereulixia, and
Ophioblennius are more closely related to each other than to other
members of the tribe.

The genus Cirripectes Swainson is widespread throughout the
Indo-Pacif ic . It is a common inhabitant of coral and rocky reefs and
is usually common in heavy surge areas. Specimens of Cirripectes are
common in museum collections, but complex nomenclatural problems and
the lack of adequate keys to the species have resulted in numerous
misidentif ications. Smith-Vaniz and Springer (1971) listed 24 nominal
species of Cirripectes , and four additional species have since been
described (Table 1). There has been no comprehensive revision of the
genus and all published keys to species have been of a regional nature
(Chapman, 1951, for the Indo-Australian Archipelago; Fukao , 1984, for
Japan; Schultz and Chapman, 1960, for the Marshall and Mariana Islands;
Smith, 1959, for the western Indian Ocean). As a result, numerous
populations from different geographic areas have been described as new
species, even though these populations are actually members of the same
widespread species. There is also sexual polychroraatism in some
species and, in many instances, each color morph has been named as a
distinct species. Like most genera of marine shore fishes, there has
been no phylogenetic analysis of the interrelationships of the
Cirripectes species.

Table 1. List of nominal species of Cirripectes with correct
identifications. Arrangement is alphabetical by species name.

Species, Author, Publication Date

Salarias alboapicalis Ogilby, 1899
Cirripectes auritus Carlson, 1981
Blennius canescens Garman, 1903
Ophioblennius capillus Reid , 1943
Salarias castaneus Valenciennes in Cuv. and

Val., 1836
Cirripectes chelomatus Williams and Mauge , 1983
Ophioblennius clarki Reid, 1943
Salarias cruentipinnis Day, 1888
Cirripectes cruentus J. L. B. Smith, 1959
Salarias f ilamentosus Alleyne and Macleay, 1877
Cirripectes fuscoguttatus Strasburg and Schultz, 1953
Cirripectus gibbifrons J. L. B. Smith, 1947
Cirripectes imitator Williams, 1985
Cirripectes indrambaryae H. M. Smith, 1934
Cirripectes jenningsi Schultz, 1943
Cirripectes kuwamur-ai Fukao , 1985
Cirripectes lineopunctatus Strasburg, 1956
Salarias nigripes Seale, 1901
Exallias obscurus Borodin, 1927
Cirripectes perustus J. L. B. Smith, 1959
Salarias (Cirripectes) polyzona Bleeker, 1868
Rupiscartes quagga Fowler and Ball, 1924
Cirripectes reticulatus Fowler , 1946
Salarias sebae Valenciennes in Cuv. and

Val., 1836
Cirripectes stigmaticus Strasburg and Shultz, 1953
Ophioblennius vanderbilti Fowler, 1938
Salarias variolosus Valenciennes in Cuv. and

Val., 1836
Cirripectus variolosus patuki De Buen , 1963

Correct Identification

alboapicalis

auritus

polyzona

vanderbilti

castaneus

chelomatus
variolosus
f ilamentosus
stigmaticus
f ilamentosus
fuscoguttatus
castaneus
imitator

filamentosus

jenningsi

kuwamurai

quagga

variolosus

obscurus

perustus

polyzona

quagga

castaneus

castaneus

stigmaticus
vanderbilti
variolosus

alboapicalis

Cohen (1956) briefly reviewed the eastern Pacific genus
Scartichthys Jordan and Evermann. He examined specimens of several
nominal species, provided a partial synonymy tor the genus, and
recognized _S. gigas and _S. viridis as valid species. He did not
attempt to treat all of the nominal species, thus leaving the status of
many species in doubt. Smith-Vaniz and Springer (1971) listed thirteen
nominal species (Table 2) and estimated that there were only two valid
species of Scartichthys .

Ophioblennius Gill (reviewed by Springer, 1962), Pereulixia Smith,
and Exallias Jordan and Evermann, and their individual species, are
relatively well-defined, but their interrelationships within the
Salariini have not been formally hypothesized.

Concerning generic relationships, Smith-Vaniz and Springer
(1971:20) suggested that Scartichthys might be congeneric with
Cirripectes , but deferred combining them until more detailed studies
were made. Their statement (p. 20) about the relationship between
these two genera is inconsistent with statements made elsewhere in
their paper. They suggested (p. 24) that Exallias appeared to be most
closely related to Cirripectes and (p. 36) that Ophioblennius appeared
to be most closely related to Scartichthys . Later in the paper (their
Figure 51), they suggested that Cirripectes and Scartichthys are sister
groups, which are in turn the sister group of Exallias, and that these
three genera together form the sister grouy of Pereulixia.
Ophioblennius is then shown as the sister group of all of these
genera. This confusion concerning the relationships among these genera
illustrates the need for a complete and thorough analysis of their
interrelationships .

Table 2. List of nominal species of Scartichthys with correct
identifications. Arrangement is alphabetical by species name.

Species, Author, Publication Date

Correct Identification

Salarias concolor Philippi, 1896 viridis

Salarias cuvieri Gunther , 1861 viridis

Salarias eques Steindachner , 1898 gigas

Ophioblennius fernandezensis Clark, 1938 variolatus

Salarias gigas Steindachner, 1876 gigas

Ophioblennius mazorkae Hildebrand, 1946 gigas

Salarias modestus Philippi, 1896 viridis

Salarias petersoni Fowler, 1940 viridis

Salarias rubropunctatus Valenciennes in Cuv. and variolatus

VaTT, 1836
Blennophis semif asciatus Kner and Steindachner, 1866 viridis

Salarias variolatus Valenciennes in Cuv. and variolatus

VaTT, 1836
Salarias viridis Valenciennes in Cuv. and Val., 1836 viridis

Ophioblennius xiphiodon Clark, 1938 gigas

HISTORICAL TREATMENT OF THE BLENNIIDAE

Springer (1968b) reviewed the literature dealing with
classification of the Blenniidae. He cited numerous studies of higher
level (family or above) relationships, but noted that Norman (1943)
provided the only comprehensive intrafamilial classification. Norman
(1943) recognized three blenniid subfamilies: Ophioblenniinae ,
Blenniinae, and Salariinae. Springer (1968b) split Norman's Blenaiinae
into the subfamily Blenniinae, comprised of the tribes Salariini .
Blenniini, and Omobranchini , and the subfamily Nemophidinae and noted
that Norman's Ophioblenniinae was based on larval stage individuals
belonging to several different genera, all but one of which (Somersia,
Labrisomidae) he placed in the tribe Salariini. Springer and
Smith-Vaniz (1972) chose not to recognize blenniid subfamilies,
preferring instead to recognize five tribes in the family Blenniidae
(Blenniini, Salariini, Omobranchini, Nemophini, and Phenablenniini) .
Springer (1968b) proposed that Blennius was most closely related to the
Omobranchini and Nemophini line. Smith-Vaniz (1976), noting that the
Blenniini of Springer and Smith-Vaniz (1972) was polyphyletic , removed
Blennius (which would be the true Blenniini) from the Blenniini, and
hypothesized a sistsr group relationship between Blennius and a group
comprised of the tribes Omobranchini, Phenablenniini, and Nemophini.

Smith-Vaniz (1976) did not propose a hypothesis for the relationship of
his monophyletic group to the remaining members of the Blenniidae,
leaving the Salariini, "Blenniini," and Blennius in an unresolved
trichotomy (his Figure 88).

In his revision of the tribe Blenniini, Bath (1977) commented on
the sutured dentaries of Blennius but retained it in the tribe
Blenniini. Bath stated that the tribe was defined by a group of
unspecialized characters, thus leaving open the possibility that some
of the genera would ultimately be removed.

Springer (1968b) stated that the Salariini were either offshoots of
the Blenniini or shared a common ancestor with them. Smith-Vaniz and
Springer (1971) and Springer and Smith-Vaniz (1972) supported a close
relationship between the tribes Salariini and Blenniini, but proposed
no distinctive characters to support this hypothesized relationship.

Smith-Vaniz and Springer (1971) provided data supporting the
monophyletic nature of the tribe Salariini and discussed in detail the
nature of the dentition and jaws. Although the lateral portions of the
premaxillary capsule are enclosed in certain genera, they found that at
least the mesial portion of each premaxilla was an open capsule (i.e.
no anteroventral wall of bone) in all genera of the Salariini.
Smith-Vaniz and Springer (1971) diagnosed all genera they recognized in
the Salariini and presented their partially intuitive concept of the

relationships among the genera in a dendrogram (Smith-Vaniz and
Springer, 1971:Figure 51).

METHODS
Taxonomic Methods

Counts and measurements follow Smith-Vaniz and Springer (1971) and
Williams (1985). Specimens used for osteological examination were
prepared by clearing and counter-staining with Alizarin-red S and
Alcian blue following the method of Dingerkus and Uhler (1977). Counts
of vertical fin rays and characters associated with the vertebral
column (i.e. pleural ribs, epipleural ribs, etc.) were taken from
radiographs. When the last anal-fin ray was split through base, it was
counted as one.

Species accounts are arranged alphabetically by species. Only
primary synonyms are listed. In the material examined section for each
species, the presence of a standard length measurement associated with
a catalog number indicates that counts and measurements were taken from
that specimen(s). All other material listed was examined to confirm
identification and for use in establishing geographic ranges.

Counts of dentary and premaxillary incisors are approximate due to
the difficulty of counting these tiny teeth.

Institutional abbreviations used in listings of material examined
are from Leviton et al . (1985). Other abbreviations used are
SL — standard length, HL — head length, LL — lateral line, AN — anterior

10

nostril; EIP — extra interorbital sensory pore position;

IFO — infraorbital sensory pore series; MD — mandibular sensory pore

series; MSP — mid-snout pores; PBN — pore positions behind nuchal flap;

PN — posterior nostril; POP — preopercular sensory pore series;

SO — supraorbital sensory pore series; ST — supratemporal sensory pore

series.

Methods of Phylogenetic Analysis

Procedures used to determine relationships between taxa follow the
general principles of Hennig (1966), as discussed by Vari (1978) and
Parenti (1981). Only monophyletic groups (i.e. a group that includes
all descendants and only descendants of a hypothetical common ancestor)
are recognized as valid taxonomic units. Each monophyletic group is
defined by shared derived characters ( synapomorphies) . Polarity of
each character (i.e. the character state toward which the character is
assumed to have evolved in the taxa being analyzed) is determined by
outgroup analysis (Maddison et al . , 1984). The principle of parsimony
is used to resolve cases where derived (apomorphic) characters support
conflicting hypotheses of relationship (i.e. homoplasiously distributed
characters). Although evolution may not proceed in accordance with the
principle of parsimony, this approach minimizes the number of
assumptions that must be made to explain character transformatioas .

11

The result of a phylogenetic analysis is a hierarchical arrangement
of increasingly inclusive monophyletic groups. This arrangement,
usually illustrated as a branching diagram (cladogram), pioviaes a
hypothesis of the phylogenetic relationships of the taxa analyzed. The
phylogenetic method is the preferred technique for this study as it
provides a clear hypothesis of relationships that can be tested further
by examining other characters.

PHYLOGENETIC ANALYSIS

In this section, I review the synapomorphies of the Blenniidae and
other taxonomic groupings at decreasing levels of universality that
lead to Cirripectes and its allies. Although much work remains to be
done before the relationships of blenniid genera and species are fully
resolved, this discussion will provide data necessary to support my use
of certain taxa as outgroups for determining character polarities.
Characters used to define groupings at higher taxonomic levels (i.e.
family, tribe) are based on a general survey of selected species within
each group. The major emphasis of my study is on Cirripectes and its
allies in the Salariini. The' relationships among the genera closely
related to Cirripectes are depicted in the cladogram of Figure 1.
Groupings of genera on this cladogram will be referred to in the text
by the node number. Generic groupings outside the Cirripectes
assemblage of Figure 1 are not shown on a cladogram because the
relationships proposed herein for these taxa are tentative and require
additional study.

The goal of this study is to provide a working phylogenetic
hypothesis of blenniid relationships and should be considered a first
step in the dynamic process of phylogenetic analysis.

12

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15

Family Blenniidae

Springer (1968b) provided an extensive osteological description of
the family Blenniidae, based primarily on Entomacrodus nigricans. He
also discussed three characters that distinguish the Blenniidae from
all other blennioids: (1) coracoid reduced and fused to cleithrum; (2)
distinctive relationship of the interopercle with the epihyal
(=posterior ceratohyal) and interhyal; and (3) distinctive premaxillary
and dentary dentition of adults.

In addition to these three characters, monophyly of the Blenniidae
is supported by two other shared derived characters. The first is a
distinctive relationship of the urohyal with the dorsal and ventral
hypohyals, a condition not found in any other blennioids. The blenniid
urohyal has two lateral projections (one dorsal and one ventral) on
each side (Figure 2), each with a strong ligamentous attachment to its
respective hypohyal(s). There is variation in the positioning of the
lateral projections among the blenniid tribes, but all members have
this distinctive urohyal-hypohyal association.

The other derived character shared by the Blenniidae is the
presence of fleshy rugosities on the anal-fin spines of adult males.
As anal-fin spine rugosities are not found in other blennioid fishes
(sensu George and Springer, 1981), or other Porciform fishes, the

Figure 2. Urohyal bone. (Anterior toward left; A and C — left
lateral views; B and D — dorsal views.) A and B — no developed lateral
processes (Acanthemblemaria aspera). C and D — well-developed lateral
processes (Chasmodes saburrae).

17

B

18

Presence of these fleshy rugosities is the apomorphic condition. The
Omobranchini-Phenablenniini group of Smith-Vaniz (1976) and certain
genera of the Salariini are the only Blenniidae not having anal-fin
spine rugosities. The most parsimonious explanation (based on
Smith-Vaniz1 s [1976] cladogram as modified in my discussion of the
Salariini-"Blenniini" group) of this character's distribution among
blenniid taxa is that the absence of anal-fin spine rugosities
represent two independent reversals (losses), one in the
Omobranchini-Phenablenniini group and one in the ancestral line giving
rise to the Salariini, with a secondary derivation of the rugosities in
one lineage within the Salariini.

Salariini-"Blenniini" Group

Springer (1968b) and Smith-Vaniz and Springer (1971) proposed a
close relationship between the Salariini and Blenniini, but did not
provide a character to support this relationship. I follow Smith-Vaniz
(1976) in separating Blennius , which is now the only member of the true
Blenniini, from the remaining genera of the tribe, which I will refer
to as the "Blenniini." A thorough study of the "Blenniini" is needed
to determine whether it is monophyletic.

The hypothesized sister-group relationship between the "Blenniini"
and Salariini is supported by two synapomorphies : (1) premaxillary
ascending process only weakly attached to main body of bone, and (2)
2-0-2 pectoral radial formula. The ascending process of the

19

premaxillary bone has an ossified connection to the axain body of the
bone only at the anteriormost and posteriormost edges, while the middle
part is loosely attached by connective tissue. Springer (1968b) stated
that the blenniid ascending process was weakly joined (ossified
connection) at two points, anteriorly and posteriorly, to the ventral
portion of the premaxilla. Although this is true of the
Salariini-"Blenniini" line, other blenniids and blennioids have the
entire base of the ascending process weakly or strongly connected by
bone to the main body of the premaxilla. In addition, the ascending
process is an independent ossification in Pereulixia and Scartichthys ,
where the anterior and posterior connections to the main body of the
premaxilla have been replaced by connective tissue. Alticus has an
intermediate condition in that a bony anterior connection has been
lost, but the posterior connection has been retained.

Springer (1968b) proposed that the most primitive pectoral radial
formula for blenniids is 2-1-1. Therefore, the 2-0-2 formula is
considered to be a derived condition. Some members of both tribes have
the 2-1-1 formula, which I interpret as a secondary reversion to the
2-1-1 condition.

"Blenniini"

As discussed previously, the "Blenniini" referred to here comprises
those genera included in the tribe by Bath (1977), but excluding
Blennius.

20

Monophyly of the "Blenniini" is supported by two synapomorphies .
The first character is the first basibranchial shaped like a broad,
shallow U, curving downward between the posterior end of the basihyal
and the anteroventral edge of the second basibranchial (Figure 3C). I
have not found a similarly shaped basibranchial in any other blennioid
examined and consider this condition as derived compared with the
straight basibranchial of most other blennid genera or a basibranchial
with the anterior end slightly upturned ( Istiblennius , Antennablennius ,
Atrosalarias , Ecsenius , Entomacrodus , and Litobranchus) .

The second character uniting the "Blenniini" is their distinctively
shaped fourth epibranchial bones (Figure 4B). The "blenniin" fourth
epibranchial is a relatively smooth bone with a flattened longitudinal
bony flange projecting dorsally from the lateral half of the shaft of
the bone. All other blennioids examined have a fourth epibranchial
bone with one or two dorsally directed bony projections situated
dorsally on the shaft slightly before the articulation of the
epibranchial shaft with the infrapharyngobranchial plate. This type of
projection is lacking in the "Blenniini."

These characters have been examined in only a small percentage of
"blenniin" species. Thus, this hypothesis of monophyly for the tribe
needs to be further tested.

Salariini

Two characters support monophyly of the Salariini: (1)
premaxillary bone an open capsule and (2) distinctively shaped

Figure 3. Left lateral view of basibranchial bone. (Anterior
toward left.) A — plesiomorphic rod-shaped structure (Cirripectes
filamentosus) . B — slightly upturned anterior end ( Atrosalarias
fuscus ) . C — derived shallow-U shape of "Blenniini" (Chasmodes
saburrae) .

22

B

Figure 4. Fourth epibranchial bone. Left dorsolateral view.
(Anterior toward left.) A — single, broad, mid-shaft process
(Atrosalarias fuscus). B — no mid-shaft process (Chasmodes saburrae).
C — two mid-shaft processes positioned at mid-shaft (Cirripectes
filamentosus) . Abbreviation: PR — mid-shaft process.

24

B

25

infrapharyngobranchial plate (Figure 5F-K). The first character was
discussed in detail by Smith-Vaniz and Springer (1971). The
premaxillary bone of the Salariini has a band of connective tissue in
place of the anteroventral bony wall present in all other blennioid
fishes.

The infrapharyngobranchial plate of the Salariini has a broad,
flattened bony flange projecting medially from the tooth-bearing
portion of the bone. This flange extends anteriorly to articulate with
the medial tip of the second epibranchial . Further elaborations of the
infrapharyngobranchial flange occurring in Cirripectes and its allies
are discussed in the account for the node III group. In the
Tripterygiidae , "Blenniini" (the hypothesized sister group of the
Salariini), and all other groups in the- family Blenniidae, the
infrapharyngobranchial plate is composed primarily of the tooth-bearing
portion with a narrow medial flange of bone that has an anterior
rod-shaped protuberance articulating with the second epibranchial. The
families Dactyloscopidae , Chaenopsidae , Clinidae, and Labrisomidae also
have an infrapharyngobranchial plate with a large bony flange
projecting anteromedially from the tooth-bearing portion, but the
lateral edge of the flange is developed as a rod-shaped cartilaginous
swelling. The expanded bony flange appears to have developed
independently in the two groups and, thus, is considered a synapomorphy
of the Salariini.

I recognize two major groups within the Salariini, which I refer to
as the Alticus group and the Rhabdoblennius group.

Figure 5. Dorsolateral views of left infrapharyngobranchial
plates. (Anterior toward left.) A — Enneanectes altivelis.
B — Acanthemblemaria aspera. C — Chasmodes saburrae. D — Omobranchus
punctatus . E — Meiacanthus grammistes. F — Atrosalarias fuscus.
G — Stanulus seychellensis . H — Ophioblennius atlanticus .
I — Cirripectes perustus. J — Cirripectes polyzona. K — Cirripectes
quagga. Dashed line indicates anteriormost limit of tooth-bearing
portion of bone. Abbreviations: F — medial flange; RC — rod-shaped
cartillage.

28

Alticus Group

The Alticus group comprises the genera Ecsenius , Andamia, Alticus,
Dodekab lennos , Praealticus , Istiblennius , Ophioblennius , Pereulixia,
Exallias , Cirripectes , Scartichthys , Stanulus , Entomacrodus ,
Nannosalarias , Crossalarias , Atrosalarias , Salarias , and Glyptoparus.
These genera share a distinctive dentary bone that forms an open
capsule as a result of the loss of the anterodorsal bony wall. The
anterodorsal bony wall of the dentary is present in all other blennioid
fishes, but is only poorly developed in the salariin genera Hirculops
and Rhabdoblennius . With the exception of one of about 45 species (V.
G. Springer, 1971 and pers. comm.) of Ecsenius , members of the Alticus
group have a very high number of premaxillary teeth (55 to almost 400)
and dentary teeth (39 to about 300) as adults. The remaining salariin
genera have 17-50 premaxillary teeth and 16-38 dentary teeth. All
other blenniids typically have tooth counts less than or in the lower
end of the range found in the Salariini.

The relationships of the remaining salariin genera (the
Rhabdoblennius group), Cirrisalarias , Medusablennius , Mimoblennius ,
Litobranchus , Antennablennius , Alloblennius , Hirculops and
Rhabdoblennius , are unresolved. The occurrence of lower tooth counts
in these genera than in the Alticus group cannot be used to infer
relationships, as this is the plesiomorphic condition. It is not known
whether they form a monophyletic group. A comprehensive analysis of
the interrelationships of all salariin genera is needed.

29

Node I Group

Although generic interrelationships within the Alticus group are
unresolved, the genera referred to here as the node I group appear to
represent a monophyletic unit. Springer (1968b) suggested these genera
were related because they all have the terminal anal pterygiophore
supporting two rays. Relationships within the node I group are
presented in the cladogram in Figure 1. Monophyly for this group,
comprising the genera Istiblennius , Entomacrodus , Stanulus , Pereulixia,
Scartichthys , Ophioblennius , Exallias , and Cirripectes , is supported by
three derived characters at node I: (1) last pleural ribs borne on
first or second caudal vertebral centrum (this is usually centrum 11 or
12); (2) terminal anal pterygiophore bearing two rays; (3) each dentary
of ophioblennius stage larvae with a large recurved canine positioned
midlaterally on each dentary.

The node I group, with the exception of Stanulus , consistently has
the last pleural ribs borne on the first or second caudal vertebra.
Stanulus (some specimens rarely have them on the first caudal
vertebra), the "Blenniini," and other blenniids typically have the last
pleural ribs borne on the last precaudal vertebra. Among the salariin
genera, only Alticus , Atrosalarias , and Salarias contain one or more
species that usually have the last pleural ribs borne on a caudal
vertebra, but each of these genera also has members with the last
pleural ribs borne on a precaudal vertebra. Dodekablennos also has the
last pleural ribs borne on a caudal vertebra and may be the sister-
group to the node I group, but the unavailability of cleared and

30

stained material leaves its status uncertain. The condition of the
last pleural ribs borne on a caudal vertebra is considered apomorphic,
while the last pleural rios borne on a precaudal vertebra is
plesiomorphic. Within the node I group, only Stanulus typically has
the last pleural ribs on the last precaudal vertebra (Springer , 1968a) .
Although this character argues for the exclusion of Stanulus from this
clade, additional characters at node II support its inclusion on the
basis of parsimony. Some species of the genus Istiblennius have the
last pleural ribs borne on a precaudal vertebra. This and other
characters suggest that Istiblennius, as presently defined, ^ay be
polyphyletic. A complete revision of Istiblennius is needed to define
its limits.

The second character supporting monophyly for the node I group is
the presence of two rays on the terminal anal pterygiophore . Although
Smith-Vaniz and Springer (1971) stated that Praealticus frequently has
the last anal-fin ray divided through the base, I found this to be an
extremely rare and probably exceptional condition in Praealticus.
Istiblennius shows variation in this character that appears to be
species specific. Many Istiblennius species have the last two anal
rays on one pterygiophore, whereas other species have the last two rays
borne on separate pterygiophores. Most genera in the node I group show
some variation in this character, as discussed by Springer (1967), but
they usually have the last anal pterygiophore bearing two distinct
rays. Other blenniids and many blennioids (including the Chaenopsidae ,
Labrisomidae, and Ophiclinini) have the last anal pterygiophore bearing
a single ray. The presence of two rays on the last anal

31

pterygiophore is considered the derived condition for blenniid fishes,
and supports monophyly for the node I group. I should note that the
last anal ray split to base is pleisomorphic for the Perciformes.
Among blennioids, at least the Blenniidae (except the node I group) and
Chaenopsidae do not have the last ray split. The simplest explanation
for the presence of the split ray in the node I group is that it is a
reversal and, thus, is apomorphic at this node.

The third character supporting monophyly for the node I group is a
characteristic of the ophioblennius stage larvae. The ophioblennius
stage larvae of each of the genera in the node I gro^, except
Pereulixia, for which a larval stage has not been found, have two
posterolateral^ directed, large, recurved canines located about
midlaterally on each dentary. Istiblennius is problematical in that an
ophioblennius larval stage is known only for members of the _I.
gibbifrons species complex (Smith-Vaniz and Springer, 1971). If the
absence of this larval stage in other Istiblennius species is real and
not a collecting artifact, then the genus as presently defined may be
polyphyletic . No other blennioid larvae possess these large hooked
canines midlaterally on each dentary. Larval Nemophini have large
canines in the jaws, but these teeth are not hooked. The presence of
large hooked teeth is considered a derived condition and is evidence
for monophyly of the node I group Although larval Pereulixia are not
known, the presence of several additional characters, discussed later
in this paper, places this genus in the node I group on the basis of
parsimony.

32

Genus Istiblennius

Tbe genus Istiblennius as defined by Smith-Vaniz and Springer
(1971) (or some part of the genus including the Istiblennius gibbifrons
species complex) appears to be the sister group of the remaining
members of the node I group. As indicated above, I know of no
character that supports a hypothesis of monophyly for the species
included in Istiblennius. The genus is presently being revised.

Node II Group

This group of genera (Entomacrodus , Stanulus , Pereulixia,
Scartichthys , Ophioblennius , Cirripectes , and Exallias ) shares two
derived characters: (1) each anal-fin spine of adult males enveloped
in a fleshy rugosity and (2) posteriormost branchiostegal ray with an
elongated proximal portion extending well onto the posterior ceratohyal
and passing dorsad of the proximal end of the preceding branchiostegal
ray (Figure 6C).

In addition to the node II group, adult males of Nannosalarias
typically have fleshy rugosities enveloping each anal-fin spine. As
discussed in the Blenniidae section, this condition is a synapomorphy
of the Blenniidae. Based on my hypothesis of relationships within the
Salatiini, the occurrence of anal-fin spine rugosities in the node II
group must be a secondary derivation because the rugosities have been
lost at the hypothesized node at which the Alticus and Rhabdoblennius
groups diverge. Inasmuch as the genera of the node II group and

Figure 6. Left lateral view of branchiostegals and associated
bones. (Anterior toward left.) A — fifth and sixth branchiostegal rays
extending about equally onto ceratohyals (Crossosalarias macrospilus) .
B — sixth branchiostegal ray extending slightly dorsad of fifth
(Stanulus seychellensis) . C — sixth branchiostegal extending dorsad of
and anterior to fifth (Cirripectes perustus). Abbreviations:
AC — anterior ceratohyal; DH — dorsal hypohyal; PC — posterior ceratohyal;
VH — ventral hypohyal.

34

B

35

Nannosalarias do not share other characters defining the "Blenniini,"
the most parsimonous explanation is that this apomorphic character is
either independently derived or convergent. Within the Alticus group,
the rugosities appear to have been independently derived in
Nannosalarias because it does not share the other characters defining
the node I group. I interpret the presence of fleshy anal-fin spine
rugosities as a synapomorphy of the node II group at this level of
analysis .

The sixth (=posteriormost) branchiostegal ray, although variously
shaped among blenniid genera, has two distinctive conditions associated
with the development of the proximal portion (herein referred to as the
head) that overlaps the posterior ceratohyal: (1) head of
posteriormost and preceding branchiostegal rays extending equally far
onto'the posterior ceratohyal (Figure 6A) or (2) head of posteriormost
ray extending as much as three to four times as far onto posterior
ceratohyal as preceding ray (Figure 6C). Condition 1 is the typical
condition found in other salariin and blennioid fishes and is
considered the plesiomorphic state. The node II genera, except
Pereulixia, which has condition 1, share condition 2. The most
parsimonious explanation for the occurrence of condition 1 in
Pereulixia is that it is a reversal to the plesiomorphic condition.

In condition 2, the elongated head of the sixth branchiostegal ray
has an anterodorsally directed component projecting over the dorsal tip
of the preceding ray(s) and a posteriorly directed spur sometimes

36

extending along a slight groove in the posterior ceratohyal . There is
a ligamentous connection of the elongated portion of the branchiostegal
head to the posterior ceratohyal. Condition 2 does not occur in other
blennioid fishes and, thus, is a synapomorphy of the node II genera.

The head of the sixth branchiostegal ray in Stanulus is not as
extensively developed as in the node II genera. In Stanulus , the head
is only slightly elongated in an anterodorsal direction, reaching a
point just above the preceding ray (Figure 6B) . Stanulus is a genus of
small species and the condition might be neotenic. This condition is
interpreted as being z modification of condition 2.

Genus Entomacrodus

I know of no uniquely derived character that will define the genus
Entomacrodus as a monophyletic taxon. Entomacrodus has vomerine teeth,
but vomerine teeth are also present in Pereulixia and some Stanulus.

Smith-Vaniz and Springer (1971) and Springer (1967, 1968a) stated
that Entomacrodus is most closely related to Stanulus , based on their
similarity in overall appearance. I have found no synapomorphy to
support this hypothesis.

Node III Group

This group comprises the genera Stanulus , Pereulixia , Scartichthys ,
Ophioblennius , Cirripectes , and Exallias . I have found only one
character that defines this assemblage. These genera, except

37

Pereulixia and Scartichthys , possess a distinctively shaped
infrapharyngobranchial bone (Figure 5G-K). The anteromedially
positioned flange of the infrapharyngobranchial plate (either a fused
complex of one or more of infrapharyngobranchial bones 2, 3, and 4, or
a loss of one or two of these bones) has one or two large foramina,
giving the bone a doughnut-shaped appearance (Figure 5). This
condition appears to be unique and defines these genera as a
monophyletic group.

The infrapnaryngobranchial plate of Pereulixia and Scartichthys is
typical of oth-r salariin genera (Figure 5F; see previous discussion
for the Salariini) and does not show the modifications present in the
other members of this group. This condition is interpreted as a
reversal based on parsimony.

Genus Stanulus

Stanulus , the hypothesized sister group of the other node III
genera, has a distinctive ophioblennius stage larva that is much
smaller than the larvae (at an equivalent stage of development) of
other genera in the node I group. Similarly, adult Stanulus are
smaller than other members of this group (except Entomacrodus
thalassinus and E. strasburgi). In addition, Stanulus has scalelike
flaps along the anterior portion of the lateral line. Pereul ixia and
several species of Cirripectes have similar scalelike flaps associated
with the anterior lateral line pores, but these genera possess
additional characters that argue for an independent derivation of the
flaps in each genus.

38

Node IV Group

The node IV group comprises Pereulixia, Scartichthys ,
Ophioblennius , Cirripectes, and Exallias . Three derived characters
define this group: (1) transverse row of cirri extend across nape
(Figure 7); (2) symphyseal portion of the premaxillary bone connected
to remainder of premaxillary by a slender bridge of bone beneath the
anterior edge of the base of the ascending process, symphyseal portion
is free posteriorly (Figure 8B); (3) lacrimal with an elongate
anter?'. antral extension that reaches ventral ly as far as the lower edge
of the maxillary bone and has a sensory canal opening at or near its
ventral edge (Figure 9B).

A distinctive transverse row of cirri across the nape in the node
IV genera manifests itself variously in the different genera. Although
some genera of the Labrisomidae ( sensu George and Springer, 1981) also
have a transverse row of nuchal cirri, this character is considered to
be convergent, as these groups are clearly not closely related. The
different patterns of this transverse row of cirri will be discussed
later for each genus or group of genera.

The distinctive shape of the body of the premaxillary bone in the
node IV group appears to have resulted from a loss of bone in the
concavity beneath the base of the ascending process. The posterior tip
of the free symphyseal portion is tightly connected by ligaments to the
posterior edge of the base of the premaxillary ascending process and
the anterior edge of the maxillary bone. The base of the ascending
process straddles the unossified concavity in the body of the

Figure 7. Dorsal views of nuchal cirri. (Anterior toward top.)
A — type A, Cirripectes kuwamurai . B — type B, C_. variolosus . C — type
C, C. gilberti. D — type D, C_. perustus . E — type E, £. alboapicalis .
F — type F, C. jenningsi. G — type G, C_. vanderbilti. H — Pereulixia
kosiensis (dashed line indicates cirri not illustrated). 1 — Exallias
brevis . J — Scartichthys viridis .

40

j ^

fil

ilk \m

F

ill

'(in*

™ wim^

Figure 8. Dorsal views of left premaxillary bones (ascending
process removed from each bone). (Anterior toward top.) A — Alticus
s aliens . B — Scartichthys gigas .

42

Figure 9. Left lateral views of left lacrymal bones. (Anterior

toward left.) A — pores exit near main canal (Alticus saliens).

B — branch of canal almost reaches ventral margin of bone (Scartichthys
gigas).

44

B

45

premaxillary bone and appears to serve as a point of attachment for
connective tissue holding the teeth in place. Other genera of the
Blenniidae either do not have an open gap in the body of the
premaxillary bone, or, if there is an opening, there is an anterior and
posterior bony connection to the main body of the premaxilla (Figure
8A). The loss of the posterior bony connection between the symphyseal
portion and the main body of the premaxillary is a synapomorphy of the
node IV group.

The distinctively shaped lacrimal (Figure 9B) of the node IV group
is not found elsewhere in the Blenniidae. In most other salar;in
genera, the lacrimal is much shorter and broader than it is in the node
IV group, and the ventrally directed sensory canal(s) exits from the
bone at a point relatively close to the main infraorbital canal. The
slender, elongate, anteroventrally directed extension of the lacrimal
is a synapomorphy of the node IV genera. Ecsenius is exceptional in
having an elongate lacrimal (Springer, 1968b:pl.9), but the ventral
sensory canal exits relatively close to the main infraorbital canal.

Genus Pereulixia

The genus Pereulixia forms the sister group of the node V group and
is distinctive in having a nuchal cirri arrangement consisting of four
slightly overlapping groups of cirri. The cirri are frequently
complex, with multiple branches arising from a single base. The skull

Figure 10. Left lateral view of supraoccipital region of skull of
Pereulixia kosiensis illustrating well-developed crest.

47

CREST

48

of Pereulixia has a high bony crest extending anteriorly from the
dorsalmost edge of the supraoccipital bone to a point above the
posterior edge of the orbits (Figure 10). The crest is formed from
dorsal expansions of the frontal and parietal bones, each of which
comprises about half of the crest and are firmly sutured to each
other. Other Salariini may have short bony crests on the skull, but
the crest does not reach the height of the dorsalmost tip of the
supraoccipital bone. Even salariin taxa with well-developed fleshy
crests have only low bony crests on the skull. Both of these
characters are considered derived. In other blenniid tribes, a large
bony crest is present in large Hypleurochilus and Omobranchus
aurosplendidus . These occurrences are considered independent
derivations .

Pereulixia has larger (thus fewer) dentary incisors than
premaxillary incisors. Exallias has a similar dentition, but has more
incisors in both jaws. Ecsenius has dentary incisors larger than
premaxillary incisors, but there are fewer incisors. This character of
dentary incisors larger than premaxillary incisors is considered to be
a derived condition. Based on the characters defining the node III and
V groups, I hypothesize independent derivations in these genera.

The relationship of Pereulixia to other salariin genera is somewhat
tentative. Although it shares several characters with the node IV
group, its placement here is only slightly more parsimonious (two fewer
steps) than placing it as the sister group to Istiblennius and the node
II group.

49

Node V Group

The node V group includes Scartichthys , Ophioblennius , Cirripectes,
and Exallias . This assemblage is defined by the following five
synapomorphies : (1) fourth epibranchial with two distinct processes
located on the dorsal side near the midpoint of the shaft of the bone,
one process directed anterodorsally and the other posterodorsally
(Figure 4); (2) fifth ceratobranchial with an expanded flange directed
ventrally and posteriorly from the main tooth-bearing portion of the
bone, flange with a straight Vertical margin posteriorly that forms a
sharp right angle where it meets the relatively straight ventral margin
of the flange (Figure 11); (3) each premaxillary bone of ophioblennius
stage larvae with one or two large recurved canines near symphysis of
premaxillaries ; (4) each dentary bone of ophioblennius stage larvae
with one or two large recurved canines at symphysis of dentaries; and
(5) dorsal-fin membrane attached to caudal fin. The above characters 1
through 4 are present in (and exclusive to) all node V genera and are
synapomorphies of the group. Character 5 is a derived character but
occurs homoplasiously.

No other blennioids have two distinct processes on the fourth
epibranchial bone. The plesiomorphic condition is a single broad
dorsal projection in this position on the fourth epibranchial and
occurs in all blennioids except the "Blenniini" and node V group.
There appear to be two derived conditions for the f oui i_h epibranchial:
two projections or no projections. The former condition is a
synapomorphy of the node V group and the latter a synapomorphy of the
tribe "Blenniini."

Figure 11. Left lateral views of left fifth ceratobranchial
bones. (Anterior toward left.) A — Acanthemblemaria aspera.
B — Chasmodes saburrae. C — Mimoblennius atrocinctus . D — Hirculops
cornifer. E — Alticus saliens . F — Scartichthys gigas. Abbreviations
CN — constriction; PF — posterior flange; DF — unconstricted flange;
VF — ventral flange.

51

52

In the node V group, the fifth ceratobranchial has a distinctive,
unconstricted, ventroposteriorly directed flange (Figure 11F) that
extends posteriorly to a point beyond the main body (tooth-bearing
portion) of the bone. Alloblennius , Mimoblennius , Hirculops , and
Litobranchus also have a posteriorly directed flange, but, in these
genera, the flange is quite distinctive in having a rounded extension
of the flange at the posterior edge and a constriction separating it
from an angular process on the ventral edge (Figure 11C-D). Other
salariin genera have a reduced posterior flange that does not project
posteriorly beyond the ddrsal limb of the fifth ceratobranchial (Figure
HE). Genera of the "Blenniini" have a rounded flange of bone on the
posterior edge of the dorsal limb of the fifth ceratobranchial, another
flange located ventral ly below the tooth-bearing portion of the bone,
and a distinct constriction between the flanges at the dorsoposterior
edge of the tooth-bearing portion (Figure 11B). All other blennioids
have a slender fifth ceratobranchial bone with a very narrow flange of
bone on the ventromedial edge of the tooth-bearing portion (Figure
11A). The slender fifth ceratobranchial with a very narrow flange of
bone is considered the plesiomorphic condition. The unconstricted,
extensively developed flange of bone on the fifth ceratobranchial bone
is a synapomorphy of the node V group.

The third and fourth synapomorphies for the node V group are
dentitional characters of the ophioblennius stage larvae. The first of
these is the presence of large, hooked canines at the symphysis of the

53

premaxillary bones. The second character is the presence of large,
hooked canines at the symphysis of the dentary bones. Watson (in Leis
and Rennis, 1983) distinguished the genera Exallias , Entomacrodus ,
Cirripectes , and Stanulus from the Nemophini by their large, hooked
canines in the jaws. Although Watson suggested that the hooked canines
serve to identify salariin larvae, these dentitional characters define
only the node V genera. The genera of the node V and I groups share in
having a large hooked canine midlaterally on each dentary, but, unlike
the node V group, other members of the node I group do not have hooked
cymphyseal canines. These distinctive hooked symphyseal canines also
are lacking in all other blennioid larvae; thus, I consider them to
represent a derived condition.

Most members of the node V group have the dorsal-fin membrane
attached to the caudal fin at a point above or posterior to the
caudal-fin base as adults. Most salariin genera have the dorsal-fin
membrane attached to the caudal peduncle anterior to the caudal-fin
base. Although the dorsal fin is attached to the caudal fin in many
other blennioids, this attachment is considered to be apomorphic at
this level of analysis, inasmuch as the dorsal fin is not attached to
the caudal fin in other node I genera (except some species of
Istiblennius ) . Although the dorsal-fin membrane is not attached to the
caudal fin in Scartichthys and a few species of Cirripectes , I consider
this condition to be either a reversal, or a secondary derivation,
based on parsimony.

54

Genus Exallias

Exallias , a monotypic genus, is the sister group of the node VI
group and is distinctive among all blennioids in having the lateralmost
of the nuchal cirri very short, with cirri increasing in length toward
the nape.

Both sexes of Exallias lack dentary canines. Although some species
of Istiblennius also lack dentary canines, all other genera in the node
I group have them. The most parsimonious explanation is that the lack
of dentary canines in Exallias is an apomorphy at this level of
analysis.

Exallias differs from other members of the node V group in having
enlarged dentary incisors. Exallias usually has about three or four
times as many premaxillary incisors as dentary incisors. Pereulixia
has a similar dentition, but has fewer incisors on both jaws
(Smith-Vaniz and Springer, 1971: table 2). Other members of the
Salariini (see discussion of Ecsenius in Pereulixia section) have
similar sized incisors in each jaw with up to twice as many
premaxillary incisors as dentary incisors. I consider the possession
of enlarged dentary incisors an apomorphic condition that has been
independently derived in Exallias and Pereulixia.

Node VI Group

This group comprises Cirripectes, Scartichthys , and Ophioblennius
and is defined by one synapomorphy , a large prominence at about the

Figure 12. Posterior view of left maxillary bones. A — Alticus
saliens. B — Scartichthys gigas. Abbreviation: MP — maxillary
prominence.

56

57

midpoint of the posteromedial edge of the maxillary bone (serves as the
point of insertion for the primordial ligament).

The well-developed maxillary prominence (Figure 12B) is not present
in other blennioid fishes, but, occasionally a slender flange in
approximately the same position, or slightly anterior to this position,
is present in other salariin genera. The presence of a well-developed
maxillary prominence is a synapomorphy of the node VT group.

Genus Cirripectes

Cirripectes , sister group of the node VII group, contains a diverse
assemblage of species. I have found only two synapomorphies that
define Cirripectes : (1) distinctive nuchal cirri arrangement (Figure
7) and (2) adult male urogenital papilla with one or two tapering
filaments associated with gonopore (Figure 13).

All Cirripectes have nuchal cirri that are about equal in length,
typically simple, and arranged in a single row that may be divided into
as many as four groups. When there are two groups on one side of the
nape, the two groups do not overlap where their bases meet. In all but
two species, there is a small break in the row of nuchal cirri at the
nape. This condition differs from that of all other node IV genera.

Figure 13. Ventral views of male urogenital papillae. (Anterior
toward top.) A — type I, Cirripectes perustus. B — type II, C.
vanderbilti. C — type III with posteriorly positioned gonopore, C.
alboapicalis . D — type III with distally positioned gonopore.
E — Scartichthys viridis.

59

60

Exallias has the cirri increasing in length toward the nape and
typically in a single continuous row across the nape. Scartichthys and
Ophioblennius have a relatively short row of cirri on either side of
the nape, with a wide gap separating the two rows. Pereulixia has four
groups of nuchal cirri with overlapping bases. Large Pereulixia
specimens usually have the cirri extensively branched, sometimes
appearing as a series of palmate cirri. Because the nature and
arrangement of the nuchal cirri in Cirripectes is unique, I hypothesize
that the Cirripectes condition is a synapomorphy for the species of the
genus. No other apomorphic characters are shared by all —embers of the
genus .

Adult males have one or two slender filaments associated with the
gonopore (Figure 13A-C). These filaments are variously modified in
several species groups within Cirripectes . In all Cirripectes species
groups, except one, the filaments extend beyond the gonopore and taper
to a point. The relatively long tapering filaments contrast with the
short blunt-tipped f ilamart( s) found in Exallias and the node VTI
genera. Other blennioids have a gonopore at the tip of a short
papilla. I consider each of the following as a synapomorphy for its
group: the single short blunt protuberance in Exallias , che two blunt
protuberances in the node VII group, and the one or two slender pointed
filaments in Cirripectes .

61

Node VII Group

Scartichthys and Ophioblennius are included in the node VII group.
Three synapomorphies define this group: (1) male genital papilla
flattened anteroposterior^, with two short blunt projections on either
side of the gonopore (Figure 13); (2) transverse row of nuchal cirri in
two widely separated groups (Figure 7); and (3) high number of caudal
vertebrae (22-26). The distinctive shape of the male genital papilla
does not occur in other blennioids and I consider it to be a derived
condition.

The nuchal cirri arrangement in these two genera varies among
species, but always consists of a group of cirri (as few as two in some
Ophioblennius) on each side of the nape with a broad gap between the
groups. This condition is hypothesized to be a secondary modification
of the condition characterizing the node IV group and, as such, is a
synapomorphy for the node VII group.

Although other blenniids have a high number of caudal vertebrae,
all other genera included in the node TV group have 19 to 22 caudal
vertebrae (only a few species of Cirripectes have as many as 22). At
this level of analysis, I consider the high number of caudal vertebrae
(22-26) to be a synapomorphy for the node VII group.

Genus Ophioblennius

Ophioblennius is distinctive among blenniids in having disconnected
overlapping portions of the lateral line. The anterior section of the

62

lateral line ends at a point above the posterior section of the lateral
line near the middle of the body. The posterior section of the lateral
line begins slightly anterior to and beneath the end of the anterior
section of the lateral line and continues to the caudal-fin base
(frequently as a series of short tubes).

As discussed by Smith-Vaniz and Springer (1971), adults of this
genus have dentary canines that are as long as or longer than the pupil
diameter. Other members of the node I group have much shorter canines
(or none at all) as adults. These two characters are synapomorphies of
the species of Ophioblennius.

Genus Scartichthys

The genus Scartichthys is distinctive in that the posterior part of
the lateral line consists of about 18-21 (typically 21) short tubes,
each with a pore at either end. Other members of the node IV group
usually have from none to 10 lateral line tubes. The high number of
lateral line tubes is a synapomorphy of this genus.

DISCUSSION OF PHYLOGENETIC ANALYSIS OF GENERA

Although the results of my study are in many cases tentative, I
have attempted to present all supportive data clearly and concisely.
As this study is the first attempt to provide a phylogenetic analysis
of any group within the Salariini, it is possible that my hypothesis of
relationships will be altered as the taxa are analyzed in greater
depth.

The only previous attempt to provide a hypothesis of relationships
within the Salariini was a dendrogram based on overall similarity
(Smith-Vaniz and Springer, 1971; reproduced here as Figure 14). My
hypothesis of phylogenetic relationships (Figure 1) differs from
Smith-Vaniz and Springer's (1971) dendrogram in the relationships of
several genera. In my analysis, Istiblennius (based primarily on the
I_. gibbifrons species complex) is included in the node I group, whereas
Smith-Vaniz and Springer (1971) placed it with Praealticus , Alticus ,
and Andamia. It seems likely that this difference results from the
particular species of Istiblennius used in each analysis. I agree with
Srait'u-Vaniz and Springer (1971:50) who state that Istiblennius might be
polyphyletic and, thus, both placements could be correct for a specific
subset of Istiblennius species. A revision of Istiblennius is needed
before its relationships can be assessed adequately.

63

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Smith-Vaniz and Springer (1971) considered Nannosalarias to be the
sister group of my node II group. As I did not treat the
interrelationships of the members of my Alticus group, outside of my
node I group, it is possible that Nannosalarias is the sister group of
the node I group. Further study of the Salariini is needed to
determine the interrelationships of the remaining genera in the Alticus
group.

Smith-Vaniz and Springer (1971) considered Stanulus and
Entomacrodas to be sister genera that together form the sister group of
my node IV 3roup. They grouped Entomacrodus and Stanulus on the basis
of overall similarity, but did not provide a specific character to
support the hypothesized sister group relationship. In my analysis,
Entomacrodus is the sister group of the node III group, which includes
Stanulus and is defined by the presence of a large foramen in the
infrapharyngobranchial plate. Thus, Stanulus appears to be more
closely related to the node IV group than to Entomacrodus.

Smith-Vaniz and Springer (1971) also regarded Ophioblennius as the
sister group of the other genera in the node IV group. They placed it
in this position because it possesses a combination of unique and
distinctive characters that they felt isolated it from the other
genera. In a cladistic analysis, unique characters cannot be used to
infer relationship or lack of relationship with taxa not possessing
these characters. In my analysis, Ophioblennius and Scartichthys are
sister genera, which together are the sister group of Cirripectes. My
determination of the relationship of Ophioblennius to the other genera

67

in the node IV group is based on a suite of characters at nodes V, VI,
and VII.

Although many of the characters I used to determine relationships
among the genera in my node I group are homoplasiously distributed, a
cladistic analysis is the preferred method because it specifies how a
character is distributed and clearly illustrates weak and strong
components of the hypothesis. A cladistic hypothesis is defined by a
specific distribution of characters among taxa and can be tested by
adding additional characters or reassessing the original characters.
As a result of the relative ease of testing a cladistic hypothesis, it
is possible that any given hypothesis of relationships will change when
additional characters are added to the analysis. Because of the
potential for a given cladogram to change when additional characters
are added, formal taxonomic names should be applied with care in order
to minimize future nomenclatural confusion.

PHYLOGENETIC RELATIONSHIPS OF CIRRIPECTES SPECIES

I present a hypothesis of relationships among species of
Cirripectes in the cladogram in Figure 15. To avoid confusion I began
numbering the nodes on this cladogram with the next available node
number (VIII) from the generic cladogram (Figure 1). All references to
nodes I through VTI refer to groups on the cladogram in Figure 1. The
characters defining Cirripectes (the basal node in Figure 15) as a
monophyletic genus were given in the earlier account of Cirripectes and
will not be repeated here. Characters defining the terminal taxa
(species) are given in the species accounts in the systematic section
of this paper.

Morphological characters vary little among species of Cirripectes.
Most species are differentiated from each other by subtle differences
in color pattern or slight differences in meristic or other
characters. Because of the morphological similarity of the species,
few characters are available for use in a phylogenetic analysis. The
phylogenetic relationships I hypothesize herein should be considered a
working hypothesis of interspecific relationships.

Node VIII Group

This group is hypothesized to be the sister group of the remaining
Cirripectes species (node X group). The node VIII group comprises C.

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71

quagga, C. jenningsi , C. alboapicalis , and C. obscurus. These four
species are associated in an unresolved trichotomy between C^ quagga,
C. jenningsi , and the node IX group comprising C_. alboapicalis and C^.
obscurus . Four synapomorphies define the node VIII group: (1) lower
lip crenulate; (2) adult male genital papilla with a single slender
filament, gonopore located at distal tip of filament or on posterior
side near base of filament (Figure 13); (3) posteriormost pleural rib
borne on second caudal vertebra; and (4) foramen in

infrapharyngobranchial plate very large, reflecting a narrowing of the
posterior part of the bony ring encircling the foramen (Figure 5).

Members of the node VTII group have distinct crenulae on the
anteromedial edge of the lower lip. In other Cirripectes species, the
medial portion of the lower lip has a smooth edge. Among the node I
genera, a crenulate lower lip occurs only in certain species of
Istiblennius and Cirripectes and, on the basis of parsimony, I consider
these occurrences to be independent derivations of lower lip crenulae.
Exallias has a deeply plicate lower lip, but does not have distinct
crenulae on the anteromedial edge. The presence of distinct crenulae
on the lower lip is a synapomorphy of the node VIII group.

The shape of the male genital papilla is apparently unique to the
node VIII group and is considered a derived condition. The existence
of several different adult male genital papilla morphologies in the
node V group of genera makes it difficult to determine derived and
plesioraorphic conditions. Three distinctive papilla morphologies are
found among Cirripectes species. As none of these papilla morphologies

72

are found in other blennioids, I interpret each of all three conditions
as derived. Because each papilla morphology occurs only in
Cirripectes , it is not possible to use oatgroup analysis to polarize
the sequence of derivation of the three morphologies. Polarizing the
character based on the most parsimonious distribution of derived
characters for Cirripectes species results in a transformation series
beginning with the short blunt papilla (plesiomorphic) leading to the
following successively derived conditions: single slender filament,
two widely separated filaments, and two short, closely appressed
filaments. Although this technique can be considered circular
reasoning, I tentatively accept this sequence, while realizing that an
alteration of my cladogram could alter the polarity of this character.

The presence of the posteriormost pleural ribs on the second caudal
vertebra is considered to be a derived condition that has arisen
independently in some Scartichthys species and the node VIII group. I
interpret the occurrence of pleural ribs on the second caudal vertebra
as a synapomorphy of the node VIII group at this level of analysis.

In other members of the node V group with a foramen in the
infrapharyngobranchial bony plate, the posterior section of the ring of
bone encircling the foramen is relatively thick. As the bony portion
extends as far posteriorly in the node VTII group as in other members
of the node V group, it seems likely that the narrowing of the
posterior section of the bony ring in members of the node VIII group
resulted from a loss of bone from the interior edge of the posterior
section of the ring. I consider the reduction in thickness of the

73

posterior section of the ring of bone encircling the foramen to be a
synapomorphy of the node VIII group.

Node IX Group

Cirripectes obscurus and C^. alboapicalis have scalelike flaps
anteriorly on the lateral line. Stanulus and Pereulixia also have
scalelike flaps. As discussed in the accounts of Stanulus and
Pereulixia, this is an apmorphic character that has been independently
derived in three different lines. I consider the presence of
lateral-line flaps to be a synapomorphy of the node IX group at this
level of analysis.

Node X Group

The node X group comprises the remaining Cirripectes species, which
are in the node XI and XII groups The node X group is defined by two
apomorphic characters: (1) adult male genital papilla with two widely
separated filaments (Figure 13) and (2) adult males with bulb-shaped
testes (Figure 16).

Within blennioids, an adult male genital papilla with two slender
filaments, one on either side of the gonopore, is unique to the node X
group. This condition is modified in two groups of Cirripectes in that
the filaments are reduced in length and closely appressed , but there
are still two distinct filaments. The presence of two distinct
filaments on the male genital papilla is a synapomorphy of the node X
group.

Figure 16. Ventral view of left testis of two Cirripectes
species. (Anterior toward left.) A — elongate testis (Cirripectes
obscurus) . B — bulb-shaped testis (C. vanderbilti) .

75

T0 GONOPORI

GONOPORI

76

Adult males of the node X group have bulb-shaped testes. All other
blenniids examined have slender elongate testes. Bulb-shaped testes
are a synapomorphy of the node X group.

Node XI Group

Cirripectes imitator , C^. fuscoguttatus , and _£. gilberti are
associated in a trichotomy at node XI. These three species share a
distinctively shaped row of nuchal cirri (Figure 7). The nuchal cirri
are arranged in four groups of cirri with tSre cirri in the ventralmost
group on each side borne on a greatly enlarged flap. The node XI group
also has a higher number of cirri than any other Cirripectes. The
distinctive morphology of the row of nuchal cirri is a synapomorphy of
the node XI group.

Node XII Group

The node XII group is associated in an unresolved trichotomy
comprising Cirripectes variolosus , C. vanderbilti , and the node XIII
group. Members of the node XII group share a nuchal cirri morphology
in which there is, on either side of the nape, a slightly expanded
basal flap bearing the ventralmost cirri (Figure 7). The node XII
species usually have four groups of nuchal cirri. This arrangement has
been modified in C. vanderbilti , where the two groups of cirri on

77

either side of the nape are fused at their bases, reculting in two
continuous rows of cirri with a short gap between the rows at the
mid-point of the nape (Figure 7G). In C_. perustus , there are
frequently three groups of nuchal cirri, one group forming a continuous
row across the nape and a separate row ventral to the medial row on
each side (Figure 7D). The node XV group has a fourth condition, in
which the ventralmost group on either side is a greatly expanded flap
bearing rudimentary cirri, with the cirri dorsal to this flap not
connected basally (Figure 7A). Although there are four different
modifications of the arrangement of nuchal cirri in the node XII group,
all, except the highly modified condition in the node XV group, have a
slightly expanded flap bearing the ventralmost nuchal cirri. I
hypothesize that the general morphology (and secondary modif icatons) of
the nuchal cirri in the node XII group is a synapomorphy of the group.

Node XIII Group

The node XIII group is an unresolved trichotomy comprising
Cirripectes hutchinsi, C_. randalli, and the node XIV group. The node
XIII group lacks an interorbital pore (EIP) that is present in all
other Cirripectes (Figure 17), Exallias , Ophioblennius , and Stanulus.
The lack of an extra interorbital pore position is a synapomorphy of
the node XIII group.

Figure 17. Cephalic sensory pore patterns of Cirripectes . A and
B — complex pattern, dorsal and lateral views of Cirripectes imitator.
C — simple pattern, lateral view of C_. perustus . Dashed lines indicate
bases of cirri not illustrated. Abbreviations: AN — anterior nostril;
EIP — extra interorbital sensory pore position; IFO — infraorbital
sensory pore series; MD — mandibular sensory pore series; MSP — mid-snout
pores; PBN — pore positions behind nuchal flap; PN — posterior nostril;
POP — preopercular sensory pore series; SO — supraorbital sensory pore
series; ST — supratemporal sensory pore series. Lines indicate first and
last pores of each series.

79

MSP

B

POP

80

Node XIV Group

The node XIV group comprises the node XV, XVI, and XVII groups that
are associated in an unresolved trichotomy. Members of the node XIV
group, except Cirripectes polyzona, share a relatively simple cephalic
sensory pore system, in which most pore positions have one or two pores
(Figure 17C). Cirripectes polyzona and other members of Cirripectes
have a complex cephalic sensory pore system, in which there are usually
six or more pores at most positions (Figure 17A-B). Although a simple
pore pattern is found in many other blennioids, Exallias and most
Scartichthys have a complex pore pattern. The simple pore pattern is a
synapomorphy of the node XIV group at this level of analysis. The
complex pore pattern of C_. polyzona may be independently derived , as it
shares another derived character with the node XVI group. An
independent derivation of the complex pore pattern is the most
parsimonious explanation. If the simple pore pattern is not considered
an apomorphic character, the node XIV group collapses to form a
polychotomy with the node XIII group.

Node XV Group

The node XV group comprises Cirripectes auritus and _C. kuwamurai,
which share two apomorphic characters associated with the nuchal cirri

81

(Figure 7): (1) larg-? flap bearing rudimentary cirri present on each
side of nape and (2) medial cirri (those located dorsal to nuchal flap)
arising directly from skin, bases of cirri not connected by a low
membrane.

The distinctive nuchal flaps of Cirripectes auritus and C.
kuwamurai are unique among blennioids. These flaps are a synapomorphy
of the node XV group.

In the node XV group and many specimens of Cirripectes filamentosus
and J2. chelomatus , the dorsalmost nuchal cirri arise directly from the
skin. Other Cirripectes and those related genera with a transverse row
of nuchal cirri have the dorsalmost cirri on either side of the nape
connected to each other by a low basal membrane. The most parsimonious
explanation for the distribution of this character is that it has been
derived independently in Cirripectes filamentosus and the node XV
group. I consider the presence of independently based cirri to be an
apomorphic character that provides additional evidence for the
monophyly of the node XV group.

Node XVI Group

The members of the node XVI group are associated in an unresolved
trichotomy comprising Cirripectes polyzona , C_. castaneus , and C.
stigmaticus . The node XVI group shares in lacking a pore position
behind the ventral edge of trie row of nuchal cirri (Figure 17). Two
pore positions are present in Exallias , Ophioblennius , and
Scartichthys . I interpret the loss of the pore position as a
synapomorphy of this group.

82

Node XVII Group

The node XVII group comprises Cirripectes f ilamentosus , C.
chelomatus, £. springeri, and C_. perustus. Members of the node XVII
group have a smaller diameter foramen in the infrapharyngobranchial
plate (Figure 5) than other members of the node V group. I interpret
this decrease in size of the foramen in the infrapharyngobranchial
plate as a secondary modification and, as such, a synapomorphy of the
node XVII group.

Within the node XVII group, a sister group relationship between
Cirripectes chelomatus and _C. f ilamentosus is supported by two
apomorphic characters: (1) adult male genital papilla with two short,
closely appressed, slender filaments, with one of the filaments located
on either side of the gonopore (Figure 13) and (2) dorsalmost nuchal
cirri arising directly from the skin and not connected basally by a low
membrane (Figure 7).

The male genital papilla of C_. vanderbilti , C. chelomatus , and C.
f ilamentosus has been secondarily modified so that the filaments are
shorter and more closely appressed than are the two long, widely
separated, slender filaments in other members of the node X group. I
consider the closely appressed filaments in C. vanderbilti to be an
independent modification because this species does not share the
characters defining the node XIII and XIV groups. The presence of two
short, closely appressed, slender filaments on the adult male genital
papilla is interpreted as a synapomorphy of C. chelomatus and _C.
f ilamentosus .

83

As discussed in the account of the node XV group, the dorsalmost
nuchal cirri arising directly from the skin is an apomorphic condition,
while the dorsalmost cirri connected basally by a low membrane is
plesiomorphic . The nuchal cirri morphology in the node XV group is
unique among blennioids and appears to have evolved separately from the
independently based nuchal cirri in C^. chelomatus and C. f ilamentosus .
For this reason, I consider the independently based nuchal cirri in C.
chelomatus and _C. f ilamentosus as evidence of monophyly for these two
species.

Other relationships within the node XVII group are unresolved. The
three possible phylogenies for the node XVII group are shown in Figure
18. Three characters are involved in the different placements of taxa
in the cladograms in Figure 18: (1) loss of the mid-snout sensory pore
positions (Figure 17), (2) incomplete lateral line, and (3) a
dorsal-fin pterygiophore formula (representing the number of proximal
pterygiophores inserting into each of the first four interneural spaces
with the first value being the number of proximal pterygiophores
inserting anterior to the first neural arch) of 1-1-0-1.

Cirripectes f ilamentosus , C_. chelomatus , and C_. springeri lack
mid-snout pore positions. All other members of the node III group have
one or more pores in this position. The absence of mid-snout pores is
a synapomorphy of these three species.

An incomplete lateral line that extends posteriorly to about the
middle of the body is shared by Cirripectes f ilamentosus , C_.
chelomatus , and C. perustus . All other members of the node IV group

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86

have a complete lateral li.;e (reaches at least to caudal peduncle). An
incomplete lateral line is a synapomorphy of these three species.

A dorsal-fin pterygiophore formula of 1-1-0-1 is shared only by
Cirripectes stigmaticus, £. perustus, C. springeri, and Ophioblennius.
The dorsal-fin pterygiophore formula is typically 0-2-0-1 in the
Salariini. Although the dorsal-fin pterygiophore formula varies among
blennioid fishes, I have not found the 1-1-0-1 formula in other
blennioids. The 1-1-0-1 formula is apomorphic , but occurs
homoplasiously and, based on a parsimony argument, has been derived
independently in Ophioblennius and twice within Cirripectes (in the
node XVI and XVII groups).

Because the mid-snout pore, lateral-line, and dorsal-fin
pterygiophore formula characters each support a different pattern of
phylogenetic relationships, the relationships among Cirripectes
springeri, £. perustus, and the £. f ilamentosus-C. chelomatus group
must remain unresolved until one or more additional characters are
discovered that support one of the three hypotheses of relationship.

Cirripectes SWAINSON

Cirripectes Swainson, 1839:182, 275 (type species Salarias variolosus
Valenciennes _in_ Cuvier and Valenciennes, 1836, by original
designation). Spelled Cirripectus on pp. 79, 80.

Diagnosis . Cirripectes is a salariin blenniid with: (1) a
transverse row of uniform-length, simple, nuchal cirri that may be in a
coi.Linuous row or in up to four groups, but, when in more than one
group, with little or no gap at the dorsalmost point on the nape; and
(2) an adult male urogenital papilla with one or two tapering filaments
extending beyond the gonopore. Among blenniids, these conditions are
unique to Cirripectes .

Cirripectes may also be distinguished from other salariin genera
with a transverse row of nuchal cirri by the following combination of
characters: no vomerine teeth, large canine located posteriorly on
each dentary bone, 13-17 (rarely 13) segmented dorsal-fin rays, and
14-18 segmented anal-fin rays. Selected counts for the species of
Cirripectes are provided in Table 3.

Distribution. Cirripectes is widely distributed throughout the
Indo-Pacific region (Figures 19-26).

Nomenclatural discussion. Swainson (1839) used two spellings in
the publication describing this genus. Early in his paper, he

87

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104

Table 3. Counts for selected characters of the species of
Cirripectes . Table headings: 1st - primary modal count, 2nd -
secondary modal count for bimodal characters, n - number of specimens.

Segmented Dorsal Fin Rays Segmented Anal Fin Rays
Range 1st 2nd n Range 1st 2nd

alboapicalis

15-17

16

119

16-18

17

113

auritus

15-17

16

13

16-18

17

13

castaneus

13-15

14

861

14-16

15

852

chelomatus

14-16

15

143

15-17

16

139

f ilamentosus

13-16

15 14 574

14-17

16 15 554

fuscoguttatus

13-15

14

140

14-16

15

140

gilberti

14

22

15

23

hutchinsi

13-14

14

19

15-16

15

19

imitator

13-15

14

63

14-16

15

63

jenningsi

15-16

15

94.

15-17

16

94

kuwamurai

16

1

17

1

obscurus

15-17

16

50

16-17

17

47

perustus

14-15

14

78

14-16

15

78

polyzona

13-15

14

396

14-16

15

395

quagga

14-16

15

441

15-17

16

440

randalli

14-15

14

8

15-16

15

8

springeri

14-16

15

46

15-17

16

47

stigmaticus

14-16

15

213

15-17

16

211

vanderbilti

13-15

14

116

15-16

15

116

variolosus

13-15

14

491

14-16

i c

486

105

Table 3. Continued.

Caudal Vertebrae

Total Vertebrae

Range

1st

n

alboapicalis

21-23

22

115

auritus

21-23

22

13

castaneus

19-21

20

846

chelomatus

19-21

20

136

f ilamentosus

19-21

20

564

fuscoguttatus

20

135

gilberti

20

23

hutchinsi

20-21

20

19

imitator

20

63

jenningsi

21-22

21

94

kuwamurai

22

1

obscurus

21-23

22

47

perustus

20-21

20

78

polyzona

19-21

20

396

quagga

20-23

21

446

randalli

20

8

springeri

20-21

21

45

stigmaticus

20-22

21

203

vanderbilti

20-21

20

114

variolosus

19-21

20

483

Range

1st

n

31-33

32

115

31-33

32

13

29-31

30

839

29-31

30

112

29-31

30

564

30

135

30

23

30-31

30

19

30

63

31-32

31

94

32

1

31-33

32

47

30-31

30

74

29-31

30

396

30-32

31

446

30

8

30-31

31

45

30-32

31

203

30-31

30

114

29-31

30

483

106
Table 3. Continued.

Last Epipleural Rib on

Vertebral centrum Left+Right Orbital Cirri

Range

1st

2nd

n

Range

1st

2nd

n

alboapicalis

18-23

20

21

113

4-18

8

6

83

auritus

17-19

18

19

8

2-7

6

4

13

castaneus

17-23

19

18

840

6-49

10

11

200

chelomatus

15-18

16

17

133

3-93

8

6

82

filamentosus

13-17

15

14

557

4-13

6

8

147

fuscoguttatus

17-20

19

18

135

18-42

32

29

48

gilberti

17-19

17

18

23

17-48

27

22

24

hutchinsi

16-20

18

19

12-29

20

19

19

imitator

18-21

19

20

62

13-46

19

26

52

jenningsi

20-23

22

21

94

2-4

2

85

kuwamurai

19

1

12

1

obscurus

19-22

20

21

47

10-26

16

24

perustus

15-19

17

78

6-23

14

17

63

polyzona

15-19

17

389

4-15

10

11

78

quagga

19-24

21

22

451

2-15

6

2

166

randalli

18-20

19

8

12-41

8

springeri

16-19

17

44

2-9

6

46

stigmaticus

17-21

19

18

207

7-22

12

43

vanderbilti

18-21

19

20

115

7-22

14

95

variolosus

18-23

20

21

470

4-14

6

8

70

107

Table 3. Continued.

Left+Right Nasal Cirii
Range 1st 2nd n

Total Nuchal Cirri Bases

Range 1st 2nd n

alboapicalis

8-27

10

11

84

28-42

35

112

auritus

4-6

6

12

22-34

34

7

castaneus

6-49

10

8

222

29-44

36

37

215

chelomatus

6-82

10

85

22-45

28

29

67

f ilamentosus

4-34

8

148

22-39

29

26

149

fuscoguttatus

7-32

22

44

47-66

52

55

47

gilberti

11-33

12

24

50-64

59

56

23

hutchinsi

8-31

17

19

35-42

38

19

imitator

9-93

11

12

52

40-59

49

51

51

jenningsi

8-19

10

11

70

34-44

42

40

71

kuwamurai

10

1

31

1

obscurus

14-42

21

25

36-47

40

44

perustus

5-25

10

63

30-46

39

40

64

polyzona

5-24

10

76

32-44

39

38

76

quagga

6-16

10

11

158

23-36

28

30

160

randalli

10-18

17

7

36-42

40

41

8

springeri

5-23

6

7

47

27-38

31

45

stigmaticus

8-29

12

11

43

34-47

37

47

vanderbilti

7-23

9

8

96

31-42

36

38

94

variolosus

4-19

8

10

70

27-36

31

68

108

Table 3. Continued.

Last LL Tube Beneath

Dorsal Fin Element'

Range 1st 2nd

Number of LL Tubes in
Adults (over 35 mm SL)
Range 1st 2nd n

alboapicalis 12-end end

auritus

5-

-13

castaneus

5-

-end

end

chelomatus

12-

■15

5

4

filamentosus

XII-11

3

5

fuscoguttatus

13-

-end

end

gilberti

9-

-end

end

hutchinsi

13-

■end

end

imitator

9-

-end

end

jenningsi

15-

-end

end

kuwamurai

7

obscurus

end

perustus

5-

-11

6

7

polyzona

7-

-end

12

quagga

7-

-end

end

15

randalli

end

springeri

2-

-8

4

stigmaticus

7-

-end

11

12

vanderbiiti

7-

-end

12

10

variolosus

7-

-end

12

53
6

176
82

210
45
21
17
58
46
1
42
59
66

115
8
42
43
89
62

9-17

7-12

1-13

0-8

0-8

0-5

0-5

2-9

5-14

2-11

6
0-10
0-3
2-9
7-18
1-7
0-5
1-10
0-5
2-11

14
7
8
2
2
0
1
7

10
8

6

1
5
14
5
3
5
2

13

9
3
3
1
3
6

0
7
13
7
2

3

7

74
6

175
77

195
48
24
17
56
88
1
43
45
58

120
8
33
39
90
60

'end" means the last LL tube is on the base of the caudal fin.

109

mentioned the generic name and gave the spelling as Cirripectus, but in
the description of the genus on page 275, he used the spelling
Cirripectes. Schuliz and Chapman in Schultz et al . (1960) discussed
the problem of the valid spelling of this generic name. They stated
correctly that the first subsequent user of the name was Bleeker
(1868), who used it as a subgenus in his description of Salarias
(Cirripectes) polyzona, and that the first revisers were McCulloch and
McNeil (1918), who selected Cirripectes as the correct spelling and
treated Cirripectus as a synonym. Subsequent studies of the genus
Cirripectes using the spelling Cirripectus (eg. Norman, 1943; Smith,
1959; Strasburg and Schultz, 1953) are not first revisions and, thus,
can not be used to establish the spelling of the generic name.

Key to the Species of Cirripectes

la. Large fleshy flap bearing small nuchal cirri on either side of nape
(Figure 7A); sevcr?l independently based cirri across nape between
flaps 2

lb. Cirri not as above 3

2a. Body without longitudinal stripes auritus

(Figure 29)

2b. Body with five pale (red in life) longitudinal stripes. . .kuwamurai

(Figure 46)

110
3a. Dorsal fin XII, 15 or 16; anal fin 11,16 or 17 (some specimens of

£. stigmaticus have 14 dorsal rays and 15 anal rays) ., 4

3b. Dorsal fin XII, 14; anal fin 11,15.

11

4a. Lower lip crenulate medially; cephalic sensory pore system with 6
or more pores at each preopercular (POP) position (especially
upper positions ^5

4b. Lower lip entire medially; each POP position with 1 or 2 pores,

occasionally 4 or 5 at upper positions 8

5a. Lateral line with scalelike flaps anteriorly; segmented dorsal-fin
rays usually 16, anal rays usually 17; pupil-sized black spot
behind eye; first dorsal-fin spine not elongate in
adults g

5b. No lateral line flaps; dorsal-fin rays usually 15; anal rays
usually 16; no dark spot behind eye; first dorsal-fin spine
elongate in adult males #7

6a. Typically fewer than 9 distinct lateral line tubes; Hawaiian

Islands - obscurus

(Figures 47, 48)

Ill

6b. More than 8 lateral line tubes; South Pacific south of 20° S

latitude alboapicalis

(Figures 27, 28)

7a. Dorsal-fin membrane attached to caudal fin in adults; no gap in

row of nuchal cirri on nape jenningsi

(Figure 45)

7b. Dorsal-fin membrane not attached to caudal fin in adults; row of

nuchal cirri with a distinct gap ou nape quagga

(Figures 53-55)

8a. Dorsal fin entire; posterior half to three-quarters of body with

small brown spots (dark red in life) in both sexes chelomatus

(Figure 33)

8b. Doroal fin distinctly notched; color not as above 9

9a. Last lateral-line tube beneath or posterior to vertical at base of

segmented dorsal ray 9 stigmaticus

(Figures 59, 60)

9b. Last lateral-line tube anterior to vertical at base of segmented

dorsal ray 9 10

112
10a. Body uniformly brown and head with pale diagonally directed bars

or small pale spots; caudal vertebrae 20. . . ■ f ilamentosus (in part)

(Figure 34)

10b. Small dark-brown spots on body and small pale (red in life) spots

on head ; caudal vertebrae 21 springeri

(Figure 58)

11a. Pelvic fin with 3 apparent segmented rays 12

lib. Pelvic fin with 4 apparent segmented rays (inner ray small and

sometimes difficult to discern) 14

12a. Posteriormost lateral-line tube at or posterior to vertical from
base of segmented dorsal-fin ray 7; POP positions with 6 or more
pores at most positions; small pale spots on throat; body with

alternating dark and pale bars polyzona

(Figures 51, 52)

12b. Posteriormost lateral-line tube not reaching beyond vertical from
segmented dorsal-fin ray 7; most POP positions with 1 or 2 pores;
color pattern not as abo/e 13

113

13a. Dorsal fin notched; in alcohol, males and females with uniformly
brown body and small pale spots on head; male genital filaments

closely appressed (Figure 13) filamentosus (in part)

(Figure 34)

13b. Dorsal fin entire; in alcohol, males with head and body uniformly
brown (in life, anterior half of body yellowish brown and
posterior half of body reddish brown); females with small
dark-brown spots on brown body; male genital filaments widely

separated ( Figure 13) peruscus

(Figures 49, 50)

14a. Cephalic sensory pore system with 6 or more pores at each POP

position 16

14b. Each POP position with 1 or 2 pores, occasionally 4 or 5 at upper
positions in large specimens 15

15a. Snout and cheeks with very small, pale spots or bars (red in
life); body uniform brown; last lateral-line tube lies at or

before vertical from base of dorsal-fin ray 6 filamentosus

(in part; Figure 34)

15b. Color not as above; last lateral-line tube lies at or posterior to

vertical from dorsal-fin ray 6 cas taneus

(Figures 30-32; some stigraaticus may key to this couplet)

114
16a. Nuchal cirri arranged in four groups with lateralmost cirri borne
on a small-to-large fleshy flap (Figure 7C) 17

16b. Nuchal cirri arranged in two groups with a small gap at the nape
(Figure 7E); Hawaiian Islands and Johnston Island endemic

vanderbilti

(Figure 61)

17a. Lateralmost nuchal cirri borne on a greatly expanded fleshy flap

(Figure 7C); 43 or more distinct nuchal cirri bases 18

17b. Lateralmost nuchal cirri borne on a small fleshy flap (Figure 7D);
42 or fewer distinct nuchal cirri bases 20

18a. Number of lateral line tubes 7 to 14; Taiwan to southern Japan and

the Ogasawara Islands imitator

(Figures 43, 44)

18b. Number of lateral line tubes 0 to 5 19

19a. Color pattern of head and body of males and females consisting of
dark, brown spots on a pale brown background; widely distributed on

Pacific Plate as far west as Taiwan fuscoguttatus

(Figures 35, 36)

115

19b. Males with uniform brown head and body; females with pale (maroon
in life) spots on head and body; restricted to Indian

Ocean gilberti

(Figures 37-39)

20a. Total number of orbital cirri free tips on both sides 4 to 13;

Pacific Plate endemic variolosus

(Figure 63)

20b. Typically more than 13 orbital cirri free tips; Indian Ocean.... 21

21a. Color pattern of head and body of males and females with small
dark brown spots on brown background; Mauritius and Cargados

Caraj os Shoals randalli

(Figures 56, 57)

21b. Males with five or six broad dark brown bars on body; females

similar to males in color pattern but may have small dark brown
spots on head and anterior half of body; southwestern

Australia hutchinsi

(Figures 40-42)

Figure 27. Female Cirripectes alboapicalis , Lord Howe Island (AMS
1.17424-008: 66 mm SL).

Figure 28. Male Cirripectes alboapicalis , Mangaia, Cook Islands
(CAS uncat.: 122 mm SL).

Figure 29. Male Cirripectes auritus, South Africa (RUSI 8008: 37
mm SL) .

117

Figure 30. Male Cirripectes castaneus, Queensland, Australia (USNM
261272: 59 mm SL).

Figure 31. Reticulate color pattern of female Cirripectes
castaneus , Queensland, Australia (USNM 261272: 60 mm SL).

Figure 32. Uniformly brown color pattern of female Cirripectes
castaneus , Queensland, Australia (USNM 228189: 54 mm SL).

119

«*-r

Figure 33. Male Cirripectes chelomatus, Queensland, Australia
(USNM 258766: 83 mm SL).

Figure 34. Male Cirripectes f ilamentosus , Northern Territory,
Australia (NTM uncat.: 41 mm SL)~

121

Figure 35. Young male Cirripectes fuscoguttatus, Caroline Islands
(CAS 48937: 39 mm SL).

Figure 36. Male Cirripectes fuscoguttatus, Marshall Islands (BPBM
8008: 93 mm SL).

123

Figure 37. Male Cirripectes gilberti, holotype, Sumatra (USNM
274749: 82 mm SL).

Figure 38. Female Cirripectes gilberti, paratype , Chagos
Archipelago (ROM 46597: 90 mm SL).

Figure 39. Young female Cirripectes gilberti , Cocos-Keeling Atoll
(ANSP 134747: 38 mm SL).

125

Figure 40. Female Cirripectes hutchinsi illustrating barred color
pattern of speciemens from the northern end of the geographinc range;
Northwest Cape, Western Australia (WAM P. 25374-042: 69 mm SL).

Figure 41. Female Cirripectes hutchinsi from the southern end of
the range; Rottnest Island, Western Australia (AMS 1.20243-004: 81 mm
SL).

Figure 42. Male Cirripectes hutchinsi, holotype, Rottnest Island,
Australia (WAM P. 25744-003: 90~~ mm SL).

Figure 43. Male Cirripectes imitator , Ogasawara Islands (FAKU
48203: 67 mm SL).

Figure 44. Female Cirripectes imitator, Ogasawara Islands (FAKU
48187: 62 mm SL).

127

129

Figure 45. Male Cirripectes jenningsi, Line Islands (USNM 200615:
75 mm SL).

Figure 46. Female Cirripectes kuwamurai, holotype , Japan (FAKU
48479: 55 mm SL).

Figure 47. Male Cirripectes obscurus, Hawaiian Islands (BPBM
uncat.: 106 mm SL).

131

Figure 48. Female Cirripectes obscurus, Hawaiian Islands (BPBM
uncat . : 109 mm SL) .

Figure 49. Male Cirripectes perustus, Caroline Islands (CAS
38843: 44 mm SL).

Figure 50. Female Cirripectes perustus, Philippine Islands (USNM
228272: 62 mm SL).

33

•'

"

'

•

Figure 51. Young Cirripectes polyzona, Phoenix Islands (USNM
274295: 23 mm SL).

Figure 52. Female Cirripectes polyzona, Papua-New Guinea (USNM
274291: 45 mm SL).

135

Figure 53. Male Cirripectes quagga exhibiting spotted color
pattern, Line Islands (USNM 199460: 67 mm SL).

Figure 54. Female Cirripectes quagga exhibiting slightly barred
pattern, Line Islands (USNM 199460: 42 mm SL).

Figure 55. Male Cirripectes quagga exhibiting pale-peduncle color
pattern, Samoa (UF uncat.: 41 mm SL) .

137

138

Figure 56. Female Cirripectes randalli, paratype, Mauritius (RUSI
22306: 79 mm SL).

Figure 57. Male Cirripectes randalli , holotype, Cargados Carajos
Shoals (USNM 227873: 92 mm SL).

Figure 58. Male Cirripectes springeri, paratype , Papua-New Guinea
(USNM 228292: 54 mm SL).

Figure 59. Female Cirripectes stigmaticus, Queensland, Australia
(AMS 1.19473-095: 83 mm SL).

Figure 60. Male Cirripectes stigmaticus , Caroline Islands (USNM
223505: 60 mm SL).

140

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f

Figure 61. Male Cirripectes vanderbilti, Hawaiian Islands (USNM
205336: 53 mm SL).

Figure 62. Male Cirripectes variolosus, Pacific Ocean (USNM
198731: 61 mm SL).

Figure 63. Female Cirripectes variolosus exhibiting the spotted
color pattern, Pacific Ocean (USNM 198731: 55 mm SL).

142

143

Cirripectes alboapicalis (Ogilby)

Salarias alboapicalis Ogilby, 1899:742 (Lord Howe Island).
Cirripectus variolosus patuki De Buen, 1963:58 (Easter Island).

Diagnosis. A species of Cirripectes with the following
characters: small scalelike flaps over anterior portion of lateral
line, dark spot on head behind eye, 11 or more lateral-line tubes with
last tube positioned before caudal-fin base, and tiny white or brown
spots on body. It occurs south of 20° S latitude in the Pacific
Ocean.

Description. Dorsal fin XII, 15-17 (16 in 85.7% of specimens); anal
fin 11,16-18 (17 in 84.1%); total procurrent caudal-fin rays 10-14;
pelvic fin 1,4; vertebrae 10 + 21-23 (22 in 95.7%) = 31-32 (32 in
95.7%); last pleural ribs on vertebral centrum 12; last epipleural rib
on vertebral centrum 18-23 (19-22 in 96.5%); anal pterygiophores 1-1-1,
1-1-2, or i-2-1 (1-1-2 in 86.2%); nuchal cirri 28-42 (32-39 in 95.5%);
supraorbital cirri 4-18 (5-12 in 96.4%); nasal cirri 8-27 (8-17 in
91.7%); LL tubes 9-17 (11-17 in 95.9%); last LL tube positioned at
point between verticals from dorsal-fin ray 12 and caudal-fin base (14
to caudal-fin base in 96.2%); irregularly spaced scalelike flaps along
anterior part of lateral line; lower lip crenulate mesially (plicate

144

laterally); gill rakers 25-31 (based on 68 specimens); pseudobranchial
filaments on one side 7-13 (based on 79 specimens); premaxillary teeth
206-302 (based on 22 specimens; highest numbers in largest specimens);
dentary teeth 96-146 (based on 22 specimens); upper lip crenulae
approximately 34-52; nuchal cirri in two groups that do not overlap at
midpoint of nape, no nuchal flaps (type E; Figure 7); first dorsal-fin
spine of adults equal to or slightly longer than second (0-2.1 mm
longer in males, 0-2.0 mm longer in females); dorsal-fin membrane
deeply incised above last dorsal-fin spine; dorsal-fin membrane
attached to caudal peduncle in advance of base of caudal fin; cephalic
pore system complex (4 or more pores at most positions; Figure 17;
number of pores increases with increasing SL); mid-snout pores present
(Figure 17); extra interorbital pore position present (Figure 17); two
pore positions behind nuchal flap (Figure 17); male genital papilla
with urogenital orifice located at distal tip or on posterior side of a
single slender filament (less than 1.0 mm long) on a fleshy swelling
behind anus (types III or IV; Figure 13); testes elongate, length
equals 2-3 times width; maximum size about 125 mm SL; ophioblennius
larvae with 2-4 canines posteriorly on each dentary.

The smallest mature female (ova about 0.5 mm diameter) examined was
about 50 mm SL. Males mature by about 50 mm SL.

Color in alcohol. Ophioblennius stage larvae (based on two
specimens, 33 and 35 nm SL, from Rapa) with pale-brown head and body;
dark, spot present posteriorly on each side of lower lip and dt base of
symphyseal canines inside mouth; all fins pale; all cirri brown.

145

A 34 mm SL specimen from Rapa retains the larval dentition, but has
the dark spot behind the eye, pale tips of dorsal-fin spines, and tiny
spots on body that are typical of adults.

Typical color pattern (Figure 27) of young and adults of both sexes
consists of brown background color with tiny white or dark-brown spots
over head and some or all of body; dark-brown pupil-sized spot on each
side of head behind orbit; spinous-dorsal fin with tips of anterior
spines pale, remainder of fin brown; caudal fin dusky; anal fin
frequently with pale distal margin, remainder of fin dark brown,
usually with tiny pale spots; pectoral fin dusky with dark area at
bases of dorsal rays. Some males and females have a mottled
pale-and-brown color pattern overlaid with tiny pale or dark brown
spots .

Color in life. Similar to color in alcohol except as follows
(based on a color slide of a specimen from Lord Howe Island, and an
Easter Island specimen figured by Springer [1970]): tips of dorsal-fin
spines and upper caudal-fin rays reddish orange; anal fin bluish black
with tips of rays bluish white; iris with narrow inner yellow ring,
remainder black.

Comparisons . Cirripectes alboapicalis and C. obscurus differ from
their congeners in having small scalelike flaps over anterior portion
of lateral line and a dark spot on head behind eye. These two species
are allopatric and have an antitropical distribution pattern, with C.
obscurus restricted to the Hawaiian Islands and C. alboapicalis
occurring south of 20 S latitude in the Pacific Ocean. Adult £.
obscurus differ from adult C. alboapicalis in usually having nine or

146

fewsr (most C_. alboapicalis have 11 or more) lateral-line tubes with
the last tube (or the end of the continuous canal if there are no
tubes) on the caudal-fin base (versus usually before the caudal-fin
base). This combination of few or no lateral-line tubes with a
posterior termination point differentiates all but one of the available
specimens of £. obscurus and £. alboapicalis . Although this specimen,
a male, is the only specimen from the Cook Islands, it clusters with C.
obscurus in having nine lateral-line tubes with the last located on the
caudal-fin base and a high number of supraorbital cirri, it associates
with C_. alboapicalis geographically and in having fewer (14) nasal
cirri (only one C. obscurus specimen had as few as 14). The Cook
Islands male differs from males of both species in having a mottled
color pattern (Figure 28), typical of females of the two species, but
lacks the small pale spots seen on females. The mottled pattern has
not been observed on any other adult males but may be related to size,
as this is the largest specimen (about 125 mm SL) of Cirripectes
alboapicalis examined. I tentatively identify the Cook Islands male as
Cm alboapicalis , primarily because its collection locality is in the
middle of the geographic range of this species. Additional specimens
are needed to determine the correct placement of the Cook Islands male.
Distribution. Cirripectes alboapicalis occurs in the South Pacific
Ocean below 20 south latitude. It is known to occur at Easter
Island, Pitcairn Group, Tubuai Islands, Cook Islands, Kermadec Island,
Norfolk Island, Lord Howe Island, and Capricorn Group of the Great
Barrier Reef (Figure 19). This distribution pattern comprises, and
extends to eastern Australia, Rehder's (1981) Pitcairn-Kermadec
"Province."

147

Etymology. The specific epithet is a combination of the Latin
albus , meaning white, and apicalis , meaning at the apex, and refers to
the pale area at the tips of the dorsal-fin spines.

Comments . Counts and measurements do not vary geographically. The
degree of spotting on the body is variable within collections from a
single locality, ranging from a dense covering of tiny white spots to
no apparent spots (lack of spots seen only in preserved specimens).

Allen et al. (1976) state that Cirripectes alboapicalis , in
addition to other characters, is distinct "in lacking a median nuchal
pore." The specimens I examined have at least one pore (usually three
or more) at that position.

Nomenclatural discussion. Ogilby (1899) based his description of
Salarias alboapicalis on a 53 mm specimen from Lord Howe Island and
mentioned other specimens, initially identified (Ogilby, 1889) as
Salarias variolosus, measuring up to 125 mm. Ogilby (1899) also stated
that the specimen figured in Gunther (1877) as S. variolosus is the
same as his new species. The specimen Gunther figured is actually
Cirripectes quagga. McCulloch and McNeill (1918) stated that the
dorsal- and anal-fin ray counts made by Ogilby (1899) were in error.
My findings support their finding. Strasburg (1956) stated that the
holotype of C_. alboapicalis was lost. I examined 12 specimens in four
lots from the Australian Museum that are designated as syntypes. As
Ogilby (1899) did not specifically designate a holocype (although he
refers to a 53 run specimen), I concur with the Australian Museum's
designation of these specimens as syntypes. One of these specimens
(AMS 1.1863) is about 53 mm SL, and I designate this specimen as
lecLOtype of Salarias alboapicalis.

148

De Buen (1963) based his description of Cirripectus variolosus
patuki on two specimens from Easter Island. I have not examined these
specimens, but the description is sufficient to associate this
subspecies with C_. alboapicalis . Springer (1970) figured an Easter
Island specimen and identified it as C^ patuki , thereby recognizing
this form at the species level. I have examined specimens collected at
island groups between Lord Howe and Easter Island and have found no
differences that warrant recognition of two species. Therefore, I
place C^. patuki in the synonymy of C_. alboapicalis .

Material examined. Types: AMS 1.1863 (1 specimen: 54 mm SL),
lectotype of Salarias alboapicalis , Lord Howe Island, 31° 33' S,
159° 05' E, 12 July 1888; AMS 1.1861 (9: 26-33 mm SL), paralectotypes
of Salarias alboapicalis, same data as holotype. AMS 1.1860 and 1.1862
(98 and 71, respectively), paralectotypes of Salarias alboapicalis,
same data as lectotype.

Other material examined. Australia, Queensland: AMS 1.17445-040
(1:73). Lord Howe Island: AMS 1.4635 (1), AMS 1.4636 (1), AMS IB. 5490
(1), AMS IB. 5502 (1), AMS 1.5900 (1), AMS 1.5902 (1), AMS 1.17373-006
(1), AMS 1.17379-003 (1), AMS 1.17388-003 (1), AMS 1.17414-001 (1), AMS
I. 17424-008 (26: 27-71), BPBM 14853 (7), CAS-SU 9206 (2). Norfolk
Island: AMS I. 18497-008 (6), AMS 1.20268-008 (9), AMS 1.20271-005
(1), ANSP 75307 (5: 59-98). Kermadec Islands: AMS 1.10452-3 (2: 36,
36). Cook Islands: CAS UNCAT. (1: 123). Tubuai Islands: AMNH UNCAT.
(2: 36-58), AMNH UNCAT. (1: 33), AMNH UNCAT. (9: 32-35), BPBM 12916 (2:
39, 59), BPBM 13308 (2: 41, 46), BPBM 13413 (5: 33-48), BPBM 17222 (8:
32-56), BPBM 17302 (4: 34-38). Oeno Atoll: BPBM 16482 (2: 38, 42).

149

Henderson Island: BPBM UNCAT. (1: 30), BPBM 17096 (15). Ducie Atoll:
BPBM 12267 (2). Pitcairn Island: BPBM 16730 (2: 70, 83), BPBM 16974
(14: 35-58), BPBM 16996 (1). Easter Island: BPBM 6755 (3: 35-45),
BPBM 6756 (21: 33-82), BPBM 6757 (26: 34-92), LACM 6560-33 (3: 38-48),
USNM 65412 (2: 42-82), USNM 65413 (1: 38).

Cirripectes auritus Carlson

Cirripectes auritus Carlson, 1981:408 (Fanning Island, Line Islands).

Diagnosis . A species of Cirripectes with the following combination
of characters: greatly expanded black nuchal flap on either side of
nape, dorsal fin entire, supraorbital cirri 2-7, nasal cirri 4-6, and
small dark spots posteriorly on body.

Description. Dorsal fin XII-XIII (XII in 92.3% of specimens) , 15-1 7
(16 in 61.5%); anal fin 11,16-18 (17 in 69.2%); total procurrent
caudal-fin rays 10-13; pelvic fin 1,4; vertebrae 10 (11 in a specimen
with an aberrant anterior centrum) + 21-23 (22 in 84.6%) = 31-33 (32 in
84.6%); last pleural ribs on vertebral centrum 11-12 (11 in 84.6%);
last epipleural rib on vertebral centrum 17-19; anal pterygiophores
1-1-2 or 1-2-1; nuchal cirri 22-34; supraorbital cirri 2-7; nasal cirri
4-6; LL tubes 7-12; last LL tube positioned at point between verticals
from dorsal-fin ray 5-13 ( 5-9 in 83.3%); no scalelike flaps along LL;
lower lip smooth mesially (plicate laterally); gill rakers 21-25 (based
on 4 specimens); pseudobranchial filaments on one side 8-10 (based on 4
specimens); premaxillary teeth 143-161 (based on Carlson, 1981);

150

dentary teeth 64-80 (based on Carlson, 1981); upper lip crenulae
approximately 34-39; nuchal cirri arrangement consisting of 5-8
independent cirri distributed between two greatly expanded nuchal flaps
bearing minute cirri (type A; Figure 7); first dorsal-fin spine of
adults approximately equal to second in males and females; dorsal-fin
membrane very slightly or not incised above last dorsal-fin spine;
dorsal-fin membrane attached to caudal peduncle in advance of base of
caudal fin; cephalic pore system simple (1-2 pores at most positions;
Figure 17); mid-snout pores present (Figure 17); extra interorbital
pore position absent (Figure 17); pore positions behind nuchal flap i-2
(2 in 87.5%; Figure 17); male genital papilla with urogenital orifice
located basally between two widely separated slender filaments (less
than 1.0 mm long) on a fleshy swelling behind anus (type I, Figure 13);
testes bulbous, length equals width; maximum SL about 70 mm;
ophioblennius larvae with 2 canines posteriorly on each dentary.

The smallest mature female (ova about 0.5 mm diameter) examined was
about 50 mm SL. Males mature by about 45 mm SL.

Color in alcohol. Ophioblennius stage larva (based on a 28 mm SL
specimen from Christmas Island, Line Islands) with cream colored head
and body; no dark spots around mouth; all fins transluscent ; greatly
expanded nuchal flap and all cirri pale.

Adults of both sexes have body coloration (Figure 29) that can
consist of pale, brown, or mottled pale-and-brown background, but
always with tiny dark-brown spots on posterior half to three-fourths of
body. Head with two pale bars extending from orbit onto upper lip on
each side, remainder of head brown with irregular pale bars and spots;

151

underside of head with broad brown band across throat. Dorsal fin
dusky with pale spots on spines and pale streak extending
dorsoposteriorly from each ray base to midheight of interradial
membrane. Caudal fin dusky with tips of dorsalmost rays pale. Anal
fin brown. Pectoral and pelvic fins pale. Nuchal flap black with pale
cirri, cirri dorsal to nuchal flap brown to black; supraorbital and
nasal cirri brown. Males with pale rugosities on anal-fin spines.

Color in life. Adults (based on color slides of specimens from
Kenya, Thailand, and Fanning Island) with body coloration variable.
Large Kenyan male (about 80 mm SL; specimen not collected) "ith head
and anterior half of body with peach background color; head with
greenish-white spots on snout, around eye, and on nape; abdominal area
yellowish-orange; posterior half of body pink with tiny reddish-brown
spots; dorsal fin dusky with pink spots on spinous portion, pink
streaks on basal half of rayed portion, and narrow bluish-white margin;
caudal fin pinkish; anal fin bluish grey with tips of rays blue; anal
spine rugosities yellowish; pectoral fin pale yellow; pelvic fin white;
nuchal flap purplish black, bearing tiny yellow cirri, cirri dorsad of
flap brown; supraorbital and nasal cirri peach with pale-greenish tips;
iris with yellow inner ring and irregular reddish-brown outer ring.

Females at Similan Island, Thailand have a strongly mottled pattern
consisting of irregular reddish-brown and pinkish-white spots and
streaks on head, and irregular broad brown bars with pinkish-white
interspaces on body. Mid-body with small brownish-black spots ringed
with reddish-brown, spots becoming black posteriorly on body. Dorsal

152

fin with reddish-orange spots and streaks. Abdominal area white.
Color of other structures as described for Kenyan male.

Fanning Island females resemble Similan Island females except the
pale areas on head are all faintly pinkish, and those on body are light
brown or cream colored; spots and streaks in dorsal fin are pink.

Comparisons. Cirripectes auritus and _C. kuwamurai differ from
their congeners in having a greatly expanded black nuchal flap on
either side of the nape, with independently based cirri in a row across
the nape between the flaps (type A; Figure 7). Although large nuchal
flaps are present in members of the C. fuscoguttatus group, species in
tne Cm fuscoguttatus group have well-developed cirri on the nuchal
flaps and have the cirri between the nuchal flaps connected at their
bases by a low basal membrane (type C; Figure 7). Cirripectes auritus
differs from _C. kuwamurai (known from one female specimen) in having
the dorsal fin entire (versus notched over dorsal spine XII);
supraorbital cirri 2-7 (versus 12); nasal cirri 4-6 (versus 10); and
small dark spots posteriorly on body (versus narrow pale stripes, red
in life, on body) .

Distribution. As presently recognized (see comments), Cirripectes
auritus is known to occur in the Line Islands, Philippine Islands, at
Similan Island, and in the western Indian Ocean from Kenya to South
Africa (Figure 20). Although C_. auritus has been collected as deep as
20 m in the Comoros Islands (Carlson, 1981), it is usually found on
coral reefs at depths less than about 10 m. Specimens bearing the
catalog numbers USNM 222489 and ANSP 138366 were collected at Fanning
Island and have the same data as the holotype; Carlson (1981)
erroneously reported them as being from Kenya.

153

Etymology. The specific epithet is from the Latin auritus , meaning
eared, and refers to the enlarged nuchal flaps (Carlson, 1981).

Comments . The meristic and morphometric characters of Cirripectes
auritus do not vary geographically, but the color pattern does. Both
sexes at Fanning Island have a mottled pigmentation pattern on the
body, but, in the western Indian Ocean, only females have this
pattern. No males are available from Similan Island or the
Philippines, but Similan Island females resemble Fanning Island
specimens, whereas the single Philippine female available differs in
having an almost uniformly dark-brown background body color. Two South
African males have the dorsalmost nuchal cirri somewhat darker than
specimens from other areas. It is possible that these color pattern
differences are indicative of the presence of more than one species,
but there are too few specimens available to decide this with
confidence.

There are some differences between my counts and those of Carlson
(1981) for certain characters based on the same specimens. Carlson
(1981) stated that Cirripectes auritus has three segmented pelvic-fin
rays, but I found four on all specimens I examined. It is probable
that Carlson overlooked the small fourth ray, as it is only about half
the length of, and closely applied to, the third ray. Carlson included
only the independently bised cirri between the nuchal flaps in his
nuchai cirri counts, but I also included the smaller cirri borne on the
nuchal flaps. Although the total number of centra in Carlson's
vertebral counts on the two specimens in USNM 222489 are correct, they
are incorrectly allocated to precaudal and caudal vertebrae. I found

154

that the male has 10+22 (not 9+23) and the female has several aberrant
anterior vertebral centra resulting in a count of 11+21 (not 10+22; I
did not use this count to establish the range of variation for this
character). In addition, I found that the same male has the last
pleural ribs on centrum 11 (not 9), and the female appears to have
pleural ribs on centrum 12 (the last ribs of the female could be on
centrum 11, as it is difficult to tell on the radiograph). Based on a
radiograph of both specimens in CAS 34383, I found that both specimens
have small pleural ribs on centrum 11. Carlson (1981) lists one of the
specimens as having the last pleural ribs on centrum 10, but the ribs
are small and could easily have been overlooked.

Material examined. The following are paratypes of Cirripectes
auritus : ANSP 138366 (2 specimens: 43, 48 mm SL), Line Islands,
Fanning Island, English Harbor near village, 5 m, 5 Oct. 1975 (the
locality of this lot was erroneously cited by Carlson, 1981); CAS 34383
(2), Grand Comoro Island, north of Hahaia, 20 m, 23 Feb. 1975; CAS
4894C (1: 28), Line Islands, Christmas Island, London, 01° 58' 41" N,
157° 27' 57" W, 24 Aug. 1951; USNM 22489 (2: 50, 55), Line Islands,
in English Harbor near village, 5 m, 5 Oct. 1975; USNM 222490 (1: 32),
Philippine Islands, Apo Island, 09° 04' 30" N, 123° 16' 24" E,
0-2.4 m, 18 May 1979.

Other material examined. South Africa: RUSI 8888 (1: 38), RUSI
9547 (1: 48).

155

Cirripectes castaneus (Valenciennes)

Salarias castaneus Valenciennes J^n Cuvier and Valenciennes, 1836:324

(Isle-de-France [=Mauritius] ) .
Salarias sebae Valenciennes rn Cuvier and Valenciennes, 1836:323 (type

locality unknown).
Cirripectes reticulatus Fowler, 1946:173 (Aguni Shima, Ryu Kyu

Islands) .
Cirripectes gibbifrons Smith, 1947:815 (Inhaca Island).

Diagnosis. A species of Cirripectes with the following combination
of characters r simple cephalic sensory pore pattern, one sensory pore
posterior to ventral part of each nuchal flap, type I male genital
papilla, bars or spots on body, 14 segmented dorsal-fin rays, 15
anal-fin rays, and 20 caudal vertebrae.

Description. Dorsal fin XI -XIII (XII in 99.5% of specimens) , 13-15
(14 in 95.2%); anal fin 11,14-16 (15 in 93.4%); total procurrent
caudal-fin rays 10-14; pelvic fin 1,4; vertebrae 10-11 (11 in 99.8%) +
19-21 (20 in 97.0%) = 29-31 (30 in 97.0%); last pleural ribs on
vertebral centrum 11-12 (11 in 99.8%); last epipleural rib on vertebral
centrum 17-21 (18-20 in 91.5%); anal pterygiophores 1-1-1, 1-1-2, or
1-2-1 (1-1-2 in 88.2%); nuchal cirri 29-44 (32-40 in 95.8%);
supraorbital cirri 6-49 (6-20 in 94.8%); nasal cirri 6-49 (8-20 in
92.3%); LL tubes 1-13 (3-12 in 94.3%); last LL tube positioned at point
between verticals from dorsal-fin ray 5 and caudal-fin base (6 to
caudal-fin base in 97.7%); no scalelike flaps along LL; lower lip

156

smooth mesially (plicate laterally); gill rakers 20-32 (based on 179
specimens); pseudobranchial filaments on one side 7-12 (based on 181
specimens); premaxillary teeth 178-222 (based on 33 specimens); dentary
teeth 87-114 (based on 33 specimens); upper lip crenulae approximately
29-50; nuchal cirri in four groups with ventralmost group of cirri on
each side borne on a slightly expanded nuchal flap (type B; Figure 7);
first dorsal-fin spine of adults slightly longer than second (1.0-11.0
mm longer in males, 0-2.5 mm longer in females); dorsal-fin membrane
deeply incised above last dorsal-fin spine; dorsal-fin membrane
attached to caudal fin in adults; cephalic pore system simple (1-2
pores at most positions); mid-snout pores present (Figure 17); extra
interorbital pore position absent (Figure 17); pore positions behind
nuchal flap 1 or 2 (1 pore on at least one side in 92.6%; Figure 17);
male genital papilla with urogenital orifice located basally between
two widely separated slender filaments (less than 1.0 mm long) on a
fleshy swelling behind anus (type I, Figure 13); testes bulbous, length
equals width; maximum SL about 92 mm; ophioblennius larvae with 2
canines posteriorly on each dentary.

The smallest mature female (ova about 0.6 mm diameter) examined was
a Red Sea specimen about 36 mm SL. Males mature by about 35 mm SL.

Color in alcohol. Coloration of ophioblennius stage larvae (based
on 19-20 mm SL Red Sea specimens) varies from uniformly pale brown to
alternating pale and brown bars on head and body; all with about four
alternating pale and brown diagonal bars on each side of snout
extending from margins of -orbit onto upper lip; fins transluscent ;
cirri brown.

157

Juveniles (18-35 mm SL) of both sexes with brown head and body and
about 3-10 dark-brown bars laterally on sides; nuchal and supraorbital
cirri dark brown.

Males (Figure 30; Smith and Smith, 1963:pl. 37, fig. A, incorrectly
identified as C_. variolosus) larger than about 35 mm SL with
alternating dark-brown and brown bars on head (about 4 dark bars) and
body (about 10-11 dark bars), bars becoming fainter and background
color darker near posterior end of body; bars on head extending from
nape anteroventrally to underside of head, where they meet bars from
other side of nead , forming 3 dark bars across gular region; dorsal fin
dark brown with transluscent triangular area at tips of anterior
spines; upper quarter to half of caudal-fin rays with pale triangular
area on distal half of fin, remainder dark brown; anal fin dark brown
with distal tips of rays pale; anal fin rugosities cream to brown;
pectoral and pelvic fins dusky; nuchal cirri dark brown, other cirri
brown.

Females (Figures 31 and 32) larger than about 40 mm SL with three
types of color pattern: uniformly chocolate brown, barred (similar to
adult males), and reticulated. I have not seen more than two pattern
types in specimens from a given locality. South African females are
either uniformly brown or barred. Kenyan females have a very
dark-brown head and body; some specimens have dark-brown spots on the
brown background of the head. Most females in most other populations
have a reticulated pattern of pale pupil-sized spots and wavy brown
lines, but there are usually a few females with a uniformly brown head
and body. Generally, the reticulated pattern becomes less distinct

158

posteriorly on body as spots become darker and farther apart and
background color gets darker. Females usually have a pale bar on upper
lip beneath each pupil. Other pigmentation patterns resemble those of
males except the bars on throat may not be as distinct.

Color in life. Life colors of barred and uniform "brown" patterns
are not known. Females with the reticulated pattern (based on color
slides of specimens from the Red Sea, Chagos Archipelago, and Fiji; and
Randall, 1982b: fig. 273) have heads with pale greyish-brown spots
separated by narrow brown (in Red Sea and at Chagos) or reddish-brown
(at Fiji) wavy lines; anterior half of body reticulated or with narrow
brown bars and greyish-brown spots, which sometimes coalesce into bars;
posterior half of body with greyish-brown spots on dark-brown
background that gradually darkens posteriorly to caudal-fin base;
narrow brown lines extending from body onto lower half of doTsal-fin
membrane between each pair of elements; orange to reddish-orange
dorsal-fin spines extending through transluscent triangular area over
distal part of spinous-dorsal fin; tips of segmented dorsal-fin rays
orange to reddish orange; upper caudal-fin rays bright yellow (Red Sea
and Chagos) or reddish orange (Fiji), lower rays yellowish brown or
reddish brown, respectively; tips of ventralmost pectoral-fin rays
orange to reddish orange; iris with irregular red ring around outer
portion of eye, narrow yellow ring around pupil, and black area between
rings (in some specimens yellow replaces black area); other colors as
in alcohol.

Males have head and body (based on color slides of specimens from
the Red Sea, Chagos Archipelago, and Fiji; see comments section for

159

discussion of geographic variation) with alternating dark-brown and
paler bars, pale bars varying in color (red, rusty brown, grey, or
yellow); tips of dorsal-fin elements and upper caudal-fin rays varying
from bright yellow to red; colors of other fins and iris as described
for females.

Comparisons. Investigators frequently have confused Cirripectes
castaneus with C. stigmaticus , C_. polyzona, C_. f ilamentosus , and C.
imitator in areas where these species occur sympatrically. All these
species have similar male and/or female color patterns. Cirripectes
imitator and C. polyzona differ from the others in having a complex
cephalic sensory pore pattern. Of the remaining three species, C_.
castaneus and C. stigmaticus are distinct in having 1 pore behind each
nuchal flap (versus 2 in C_. f ilamentosus) , a type I (versus type II)
male genital papilla, and bars or spots on body (versus uniformly brown
body). Cirripectes castaneus differs from C. stigmaticus in having 14
segmented dorsal-fin rays (versus 15), 15 anal-fin rays (versus 16),
and 20 caudal vertebrae (versus 21).

Distribution. Cirripectes castaneus is a common and widely
distributed species. It occurs throughout the Red Sea, Indian Ocean,
and western Pacific to the margin of the Pacific plate ( sensu Springer,
1982; Figure 21). Its only known occurrence on the Pacific plate is in
the Caroline Islands. Although usually found on rocky and coralline
substrates at depths less than 10 m, it has been collected as deep as
30 m in the Red Sea and 32 m at Rowley Shoals, off Western Australia.

Etymology. The specific epithet is from the Latin castaneus ,
meaning brown, or of the color of chestnuts, and presumably refers to
the color of the holocype in alcohol.

160

Comments « Although I found no geographic variation in the
morphometric characters examined, life colors of male Cirripectes
castaneus vary geographically. In the Red Sea, some young males ( ,:o
about 40 mm SL) have relatively narrow red bars on a brown background
on head and anterior part of body. In the Chagos Archipelago, adult
males have alternating brown and dark-brown bars, brillant
yellow-orange dorsal-fin spine tips, and bright yellow upper caudal-fin
rays. Both Red Sea and Chagos males have a very dark-brown background
color of the head and body.

In Fiji, a nearly opposite life color pattern is found in
Cirripectes castaneus males, which have brown bars on a pale grey
background (versus brown bars on a dark-brown background). In a second
color morph occurring in Fiji, background color of the head and body is
yellow. As these are the only characters known to differ among these
populations, and the life colors found in intermediate populations are
as yet unknown, I do not believe these populations warrant taxonomic
recognition.

The geographic ranges of C_. castaneus and _C. variolosus overlap
only in the Caroline Islands and the northernmost Tonga Islands, where
they are easily distinguished by cephalic sensory pore pattern, which
is complex in C. variolosus .

Nomenclatural discussion. Cirripectes castaneus frequently has
been synonymized erroneously with C. variolosus (eg. Chapman, 1951;
Herre, 1953; Lotan, 1970; and Smith, 1959).

My examination of the type specimens of Salarias sebae and S.
castaneus revealed them to be conspecific. These two species were

161

described on adjacent pages (S_. sebae on page 323 and _S. castaneus on
324) by Valenciennes jjri Cuvier and Valenciennes (1836), which raises
the question of which name should be used. Fukao (1984), as the first
reviser to synonymize these names with each other, has clearly
established _S. castaneus as a senior synonym to S. sebae (no previous
reviser recognized the conspecif icity of the types of these species).
Prior to Fukao, as a result of the work of Chapman (1951) and Schultz
and Chapman (1960), Cirripectes sebae was applied most frequently to
specimens of the unrelated _C. polyzona. Chapman's (1951) description
of C_. sebae was based on a conglomerate of two or more species. Of the
three color-pattern types he described, the first two apply to female
C_. polyzona, and the third could apply to female C. castaneus (= C.
sebae) , female C^. stigmaticus , or either sex of C_. imitator. Schultz
and Chapman (1960) appear to have applied the name C. sebae only to
specimens of C_. polyzona, as the other similar species (except C.
stigmaticus) do not occur in the Marshall Islands. Bleeker, very
early, correctly applied the names C_. sebae and C_. polyzona, but his
findings were published only recently (Bleeker, 1983, pi. 4). Randall
(1982a) and Russell (1983) correctly applied the name C. castaneus , but
made no mention of the name C. sebae.

The descriptions of Cirripectes reticulatus Fowler (1946) and
Cirripectus gibbifrons Smith (1947) are based on the reticulated color
morph females of Cirripectes castaneus. Although Fukao (1984)
corrtctly recognized _C. castaneus as a valid name, he erroneously
synonymized _C. reticulatus and C. gibbifrons with C. polyzona
(Williams, 1985).

162

Material examined. Types: MNHN A. 1799 (1 specimen: 42 mm SL),
holotype of Salarias castaneus, Isle de France, collection date
unknown; MNHN A. 2059 (1: 43), holotype of Salarias sebae, from the
"Cabinet du Stathouder ," locality and date of collection unknown; ANSP
72043 (1: 67), holotype of Cirripectes reticulatus, Riu Kiu Islands,
Aguni Shima, 27 July 1945; RUSI 245 (1: 49), holotype of Cirripectus
gibbifrons , Mozambique, Inhaca Island, collection date unknown.

Other material examined. South Africa: RUSI UNCAT. (1), RUSI 75-5
(1: 54), RUSI 75-8 (1: 23), RUSI 75-9 (6: 37-55), RUSI 76-8 (5), RUSI
76-10 (5), RUSI 76-11 (11), RUSI 76-12 (1), RUSI 76-16 (3), RUSI 76-18
(1), RUSI 76-21 (20: 42-72), RUSI 76-23 (1), RUSI 76-28 (2), RUSI 77-16
(7), RUSI 77-17 (3: 61-82), RUSI 77-18 (1: 76), RUSI 9477 (1), RUSI
9824 (6), RUSI 9941 (3), RUSI 10024 (5), USNM 227345 (10).
Mozambique: RUSI 14998 (10), RUSI 15002 (3: 36-59), RUSI 15011 (11).
Tanzania: RUSI 14997 (8: 21-40), USNM 228219 (20 of 58: 52-79).
Kenya: RUSI 15009 (5), RUSI 15012 (6), UF 34643 (1: 40), USNM 228278
(1: 47), USNM 228282 (1: 63). Aden: USNM 228216 (4: 21-52). Saudi
Arabia, Red Sea: USNM 147584 (1: 26), USNM 147586 (3: 34-44). Sudan:
BMNH 1960.2.15.1589 (1), BPBM 19719 (14: 28-46), NMW 73225 (6).
Egypt: USNM 228185 (6: 49-59), USNM 228227 (2), USNM 228230 (5:
27-39). Israel: BPBM 18332 (9), BPBM 19803 (6), USNM 228186 (1 of 22:
20), USNM 228187 (1 of 16: 19), USNM 228i94 (1: 38), USNM 228195 (12),
USNM 228196 (21: 19-63), USNM 228198 (8: 19-42), USNM 228200 (11:
19-31), USNM 228204 (54 of 94: 19-58), USNM 228223 (1: 60), USNM 228229
(4). Madagascar: MNHN uncataloged (numerous specimens collected by A.
Mauge), USNM 228225 (2), USNM 228327 (1). Comoros Islands: CAS 32548

163

(1: 49), CAS 40376 (1), CAS 40378 (14), CAS 40382 (16), USNM 228173
(49: 24-64), USNM 228215 (2), USNM 228249 (8). Seychelles Islands,
Farquhar Group: USNM 228177 (29: 31, 59), USNM 228183 (19 of 20
examnined: 25-60). Seychelles Islands, Amirantes Group: ANSP 126861
(2: 51, 62), ANSP 126862 (2: 28, 64), ANSP 126983 (9: 27-59), ANSP
127003 (1: 33). Seychelles Islands, Cosmoledo Group: ANSP 147666 (2:
31, 71), ANSP 147668 (3:62-66), ANSP 147669 (1: 60), ANSP 147670 (2:
26, 32), BMNH 1908.3.23.277 (1), BMNH 1969.1.24.47-73 (27), RUSI 14993
(4), USNM 228164 (2), USNM 228167 (20), USNM 228168 (16), USNM 228169
(1), USNM 228170 (19), USNM 228174 (2), USNM 227175 (4), USNM 228188
(1). Agelaga Islands: USNM 228207 (3), USNM 228211 (1), USNM 228212
(21: 37-54), USNM 228242 (1), USNM 228250 (5). Cargados Carajos
Shoals: USNM 228244 (2 of 3 examined: 78, 82). Mauritius: BPBM 20206
(2), BPBM 21021 (1: 58), USNM 228179 (2: 38, 55). Reunion Island:
BPBM 20033 (2: 52-61). Chagos Archipelago: ROM 46601 (1: 48), ROM
46602 (1: 42), ROM 46603 (5: 26-63), ROM 46604 (1: 38), ROM 46605 (4:
40-64), ROM 46606 (4: 33-62), ROM 46607 (1: 36"), USNM 228176 (2), USNM
228180 (22: 36-77), USNM 228181 (3: 39-62), USNM 228184 (1: 47), USNM
228190 (6: 54-77), USNM 228214 (12), USNM 228218 (16), USNM 228243
(14). Cocos-Keeling Islands: ANSP 134750 (65 of 112 examined: 25-75),
ANSP 134751 (49: 25-65), ANSP 13^752 (57 of 75 examined: 23-59), ANSP
134753 (4: 32-59), ANSP 134754 (2: 34, 67), ANSP 134755 (14), ANSP
134756 (1: 37), ANSP 134757 (25: 23-57), ANSP 134758 (8: 39-70), ANSP
134760 (1: 35), ANSP 134761 (2: 27-35), ANSP 134762 (9: 23-40), ANSP
134763 (2: 30, 34), ANSP 134764 (5: 25-56). Christmas Island, Indian
Ocean: WAM P. 26110-033 (1: 38). Australia, Western Australia: AMS

164

1.21318-072 (3: 44-51), WAM P. 27667-032 (2: 45, 51), WAM P. 27659-011
(1: 61). India, Kerala State: ANSP 147657 (1: 29). Sri Lanka
(Ceylon): USNM 228228 (1: 21), USNM 228247 (1: 56). Thailand, Andaman
Sea: BPBM 22785 (1: 66), USNM 228221 (2: 40, 45). Vietnam: CAS
UNCAT. (26 of 51 examined: 45-83). China: CAS 38846 (5: 56-66).
Taiwan: USNM 228051 (1), USNM 228182 (1: 56), USNM 228224 (3: 31-69).
Japan: ANSP 113692 (2: 76, 78), BPBM 7252 (7: 58-81), FAKU 111456 (1:
65), FAKU 48108 (2: 68, 73), FAKU 48271 (1: 34), FAKU 48926 (1: 52),
FAKU 48947 (1: 25), FAKU 48965 (1: 25), FAKU 48973 (1: 31), FAKU 49173
(2: 47-61), FAKU 49175 (1: 66), FAKU 49176 (1: 71), FAKU 49177 (2: 71 .
71), FAKU 49178 (1: 70), FAKU 49179 (2: 57, 72), FAKU 49182 (2: 89,
92), FAKU 50401 (1: 52). Philippine Islands: LACM UNCAT. (1), LACM
4279-19 (2), USNM 224951 (2), USNM 227552 (2), USNM 227554 (1), USNM
228062 (2), USNM 228171 (1), USNM 228191 (2: 47, 58), USNM 228192 (3),
USNM 228193 (23: 31-55), USNM 228197 (6: 8-70), USNM 228199 (7), USNM
228202 (2: 77, 78), USNM 228208 (3), USNM 228210 (1), USNM 229252 (2),
USNM 228281 (1: 45). Indonesia: AMS T. 19875-091 (13: 44-52), RMNH
12639 (1), RMNH 20605 (2), USNM 209561 (3), USNM 228172 (11: 19-40),
USNM 228203 (2: 38, 45), USNM 228206 (3), USNM 228222 (3: 44-55), USNM
229246 (1), USNM 228279 (1: 75). Papua-New Guinea: AMS 1.17094-074
(4: 27-60), USNM 212136 (1), USNM 228201 (8: 22-55), USNM 228213 (1:
65), USNM 228240 (4). Australia, Queensland: AMS 1.15638-048 (1), AMS
1.18740-014 (1), AMS 1.18740-015 (1), AMS 1.19473-204 (24), AMS
1.19481-015 (2), AMS 1.20467-005 (1), AMS 1.20770-098 (8), AMS
1.20774-077 (1), AMS 1.20912-002 (2), AMS 1.21422-046 (3), AMS

165

1.15621-022 (1), AMS 1.15646-012 (1), AMS 1.17112-004 (1), AMS
1.17445-011 (2), AMS 1.17445-042 (3), AMS 1.19483-033 (35: 53-87), AMS
1.20756-083 (2: 43, 46), AN3P 109730 (3: 31-46), ANSP 147658 (1: 65),
USNM 228165 (5: 50-75), USNM 228205 (56), USNM 228217 (5), USNM 228220
(1), USNM 229245 (1). Lord Howe Island: AMS 1.17368-035 (1: 59).
Norfolk Island: AMS 1.20268-037 (1: 41). Solomon Islands: CAS UNCAT.
(1: 47), CAS UNCAT. (1: 42). Vanuatu (previously New Hebrides) : BPBM
UNCAT. (4), BPBM 5708 (1: 55). Loyalty Islands: USNM UNCAT. (1: 20;
OUT OF 228274), USNM 228166 (1: 71), USNM 228178 (1: 76). New
Caledonia: MNHN 1980.959 (2). Fiji Islands: BMNH 1877.4.26 ] (1),
BMNH 1877.12.10.63 (1), BMNH 1897.8.23.215-217 (3), BPBM 14629 (4),
USNM 259996 (3), USNM 227209 (1), USNM 228189 (32: 39-77), USNM 228241
(1), USNM 235726 (52), USNM 235729 (9), USNM 235730 (4), USNM 235733
(1), USNM 235734 (3). Tonga Islands: USNM 228248 (1: 56), USNM 228251
(1: 64). Caroline Islands: CAS UNCAT. (2: 40, 50), CAS UNCAT. (1:
46), CAS UNCAT. (6: 51-65), CAS 38841 (1: 38), CAS 38842 (1: 43), CAS
48894 (1), CAS 48907 (1: 40), CAS 48910 (4: 23-57), CAS 48925 (1), CAS
48927 (1: 60), CAS 48944 (2), CAS 48951 (2), CAS 48968 (2: 38, 44), CAS
48969 (1: 58), CAS 49901 (1).

cirripectes chelomatus Willams and Mauge

Cirripectes chelomatus Williams and Mauge, 1983:1140 (Lady Musgrave

Reef, Queensland, Australia).
Cirripectes sp. Russell, 1983:114 (Capricorn-Bunker Group of Islands,

Queensland, Australia).

166

Diagnosis « A species of Cirripectes with the following combination
of characters: incomplete lateral line, type II male genital papilla
(Figure 13), dorsal fin entire, 1,4 pelvic-fin rays, 15 segmented
dorsal-fin rays, 16 segmented anal-fin rays, and 30 caudal vertebrae.

Description. Dorsal fin XII-XIII (XII in 98.6% of specimens) , 14-16
(15 in 91.6%); anal fin 11,15-17 (16 in 89.9%); total procurrent
caudal-fin rays 10-14; pelvic fin 1,4; vertebrae 9-11 (10 in 97.8%) +
19-21 (20 in 94.8%) = 29-31 (30 in 96.4%); last pleural ribs on
vertebral centrum 11; last epipleural rib on vertebral centrum 15-18
(15-17 in 97.7%); anal pterygiophores 1-1-2, 1-2-1, or 2-1-1 (1-2-1 in
74.8%); nuchal cirri 22-45 (27-32 in 80.6%); supraorbital cirri 3-93
(6-9 in 82.1%; one specimen each with 23 and 93, all others with 12 or
fewer); nasal cirri 6-82 (6-15 in 83.5%; one specimen with 82, all
others with 25 or fewer); LL tubes 0-8 (1-5 in 89.6%); last LL tube or
end of LL canal (if no tubes) positioned at point between verticals
from dorsal-fin spine XII and dorsal-fin ray 10 (rays 3-7 in 89.0%; one
specimen with a widely disjunct tube beneath ray 15); no scalelike
flaps along LL; lower lip smooth mesially (plicate laterally); gill
rakers 20-28 (based on 85 specimens); pseudobranchial filaments on one
side 6-1C (based on 85 specimens); premaxillary teeth 200-231 (based on
18 specimens); dentary teeth 93-120 (based on 19 specimens); upper lip

167

crenulae approximately 29-43; nuchal cirri in four groups (some cirri
in dorsalmost groups sometimes not connected at their bases) with a
slightly expmded flap at bases of ventralmost cirri (type B; Figure
7); first dorsal-fin spine of adult males 2-19 mm longer than second,
first dorsal-fin spine of adult females 0-9 mm longer than second;
dorsal-fin membrane with very shallow notch above last dorsal-fin
spine; dorsal-fin membrane attached to caudal fin in adults; cephalic
pore system simple (less than 3 pores at most positions; number of
pores increases with increasing SL); mid-snout pores frequently absent
(Figure 17); extra interorbital pore position absent (Figure 17); two
pore positions behind nuchal flap (Figure 17); male genital papilla
with urogenital orifice located basally between two closely appressed
slender filaments (less than 1.0 mm long) on a fleshy swelling behind
anus (type II; Figure 13); testes bulbous, length equals width; maximum
SL about 94 mm; ophioblennius stage larvae of this species have not
been examined.

The smallest mature female (ova about 0.5 mm diameter) examined was
about 40 mm SL. Males mature at about 35 mm SL.

Color in alcohol. Adult males and females have similar color
patterns. Head brown with diagonal streak of tiny, sharply defined,
cieam-colored spots extending from postcrbital area to dorsal edge of
upper lip; nasal and supraorbital cirri brown or tan; nuchal cirri dark
brown or black. Body brown with cream-colored spots dispersed over
middle third of body, dorsalmost spots on basal third of dorsal fin,
ventralmost near anus and on membranes of lower third of anal fin,
spots gradually darken posteriorly. Dorsal fin with transluscent tips,

168

remainder dusky. Other fins dusky. Anal-fin spine rugosities of males
pale. Additional details given by Williams and Mauge (1983).

Color in life. As described by Williams and Mauge (1983), an adult
male from One Tree Island, Australia, with red spots on head; nasal and
supraorbital cirri yellowish; nuchal cirri black basally and at tips,
with yellow band around middle; iris red; purplish-red spots on middle
of body, spots gradually darken to dark brown posteriorly; pectoral fin
yellowish; dorsal-fin elements with orange-yellow tips, spots on basal
portion of fin purplish red; spots on anal fin purplish red; anal-spine
rugosities dirty yellow.

Comparisons. Cirripectes chelomatus , C. vanderbilti , and C.
f ilamentosus are the only Cirripectes species with a type II genital
papilla. Characters differentiating _C. chelomatus and C^. f ilamentosus
are discussed in the account of the latter. Cirripectes vanderbilti
only occurs in the Hawaiian Islands and at Johnston Island, and has a
type G nuchal cirri arrangement (Figure 7).

Cirripectes chelomatus (Figure 33) and C^. springeri (Figure 58)
have similar color patterns, but differ in that C_. chelomatus has a
type II male genital papilla (versus type I), anal-fin pterygiophores
typically 1-2-1 (versus 1-1-2), and 30 vertebrae (versus 31).

Distribution. Cirripectes chelomatus is known to occur on coral
reefs and rocky bottoms off eastern Australia from Lady Musgrave Reef
northward to Sir Charles Hardy Island; as far north as Basilaki Island,
Papua-New Guinea; as far south as Lord Howe Island; and eastward to the
Fiji and Tonga Islands (Figure 26). It is represented in a collection
of fishes made at depths of 0-16 m in the Tonga Islands, but most
specimens were collected in water shallower than 7 m.

169

Etymology. The specific epithet is derived from the Greek cheloma,
meaning notch, and refers to the shallow notch in the dorsal-fin
membrane above the last dorsal spine. The name is used as a noun in
apposition.

Comments. As discussed by Williams and Mauge (1983), geographic
variation occurs in color pattern. The few available Fiji specimens
have poorly defined spots on the body. Additional material needs to be
examined to determine the extent of this variation.

Material examined. A complete listing of localities for the
mauerial examined is given in Williams and Mauge (1983). AMS
1.21495-027 (male: 66 mm SL), holotype of Cirripectes chelomatus, Lady
Musgrave Reef, Queensland, Australia, 23 55' s, 152°24' E, 20 Feb.
1980.

The following specimens are paratypes. Australia, Queensland: AMS
1.15482-011 (2), AMS 1.15634-029 (1), AMS 1.17109-015 (1), AMS
1.17362-037 (1), AMS 1.17445-150 (1), AMS 1.19338-008 (4), AMS
1.19444-036 (1), AMS 1.19473-205 (13), AMS 1.20205-005 (3), AMS
1.20210-016 (1), AMS 1.20213-007 (1), AMS 1.20464-005 (2), AMS
1.20560-014 (1), AMS 1.20770-071 (4), AMS 1.21490-032 (1), ANSP 109717
(6), ANSP 147659 (1), BMNH 1982.11.3.1 (1), BPBM 14449 (2), BPBM 15024
(1), BPBM 28196 (1), BPBM 28197 (2), CAS 13832 (10), LACM 33732-20 (1),
ROM 40368 (2), UF 35398 (2), USNM 228298 (3), USNM 228299 (4), USNM
228300 (1), USNM 229301 (5), USNM 228302 (11), USNM 228303 (4), USNM
228305 (2), USNM 228306 (3), USNM 228308 (9), USNM 228309 (2), USNM
228310 (44), WAM P. 27754-001 (2). Lord Howe Island: AMS 1.17362-037
(1). New Caledonia: CAS 48957 (1), CAS 48958 (1), MNHN 1983-257 (1),

170

USNM 195783 (1). Loyalty Islands: USNM 228274 (3), USNM 228304 (3).
Tonga Islands: USNM 228291 (4). Vanuatu (=New Hebrides): CAS 48903
(1). Papua-New Guinea: USNM 228307 (1).

Other material examined. Fiji Islands: ROM 40207 (3), USNM 228277
(1), USNM 235727 (2), USNM 235731 (2), USNM 235735 (2).

Cirripectes filamentosus (Alleyne and Macleay)

Salarias filamentosus Alleyne and Macleay, 1877:337 (Cape York).
Salarias cruentipinnis Day, 1888:797 (Saddle Island, off Kyoukphoo in

Arracan) .
Cirripectes indrambaryae Smith, 1934:322 (Koh Samui , Gulf of Siam) .

Diagnosis . A species of Cirripectes with the following combination
of characters: uniformly brown body, small pale spots (red in life) on
cheeks and snout, last lateral-line tube usually positioned at point
between verticals from dorsal-fin ray 2-6, 2 pores behind nuchal flap,
and 30 total vertebrae.

Description. Dorsal fin XI -XIII (XII in 95.8% of specimens) , 13-1 6
(14 in 40.8%, 15 in 57.7%); anal fin 11,14-17 (15 in 39.0%, 16 in
60.1%); total procurrent caudal-fin rays 8-14 (10-12 in 95.7%); pelvic
fin 1,3-4 (geographic variation discussed in comments section);
vertebrae 10 (one specimen with 11) + 19-21 (20 in 91.1%) = 29-31 (30
in 91.0%); last pleural ribs on vertebral centrum 11; last epipleural
rib on vertebral centrum 13-17 (14-16 in 92.5%); anal pterygiophores
1-1-1, 1-1-2, 1-2-1, or 2-2-1 (1-2-1 or 2-1-1 in 87.2%); nuchal cirri

171

22-39 (25-31 in 82.6%); supraorbital cirri 4-13 (4-10 in 94.6%); nasal
cirri 4-34 (6-14 in 83.8%); LL tubes 0-8 (0-5 in 98.5%); last LL tube
or end of LL canal (if no tubes) positioned at point between verticals
from dorsal-fin spine XII and dorsal-fin ray 11 (rays 2-6 in 97.1%); no
scalelike flaps along LL; lower lip smooth mesially (plicate
laterally); gill rakers 21-27 (based on 140 specimens); pseudobranchial
filaments on one side 6-9 (based on 141 specimens); premaxillary teeth
151-189 (based on 17 specimens); dentary teeth 72-103 (based on 17
specimens); upper lip crenulae approximately 26-50; nuchal cirri in
four groups with cirri in dorsalmost groups sometimes not connected at
their bases, cirri in ventralmost groups borne on a slightly expanded
nuchal flap (type B; Figure 7); most dorsal-fin spines of adults
filamentous, the first dorsal-fin spine longer than second (1.0-9.6 mm
longer in males, 1.0-6.0 mm longer in females); dorsal-fin membrane
distinctly incised above last dorsal-fin spine; dorsal-fin membrane
attached to caudal fin in adults; cephalic pore system simple (less
than 3 pores at most positions; Figure 17); mid-snout pores present or
absent (varies geographically); extra interorbital pore position absent
(Figure 17); two pore positions behind nuchal flap (Figure 17); male
genital papilla with urogenital orifice located basally between two
closely-appressed , small, slender filaments (less than 1.0 mm long) on
a fleshy swelling behind anus (type II; Figure 13); testes bulbous,
length equals width; maximum SL about 70 mm; ophioblennius iarvae
examined nad no canines posteriorly on dentaries.

The smallest mature female (ova about 0.5 mm diameter) examined was
about 39 mm SL. Females 35-36 mm SL were not gravid but had developing
ova (0.1-0.2 mm diameter). Males mature by about 35 mm SL.

172

No sexual variation was found in any of the meristic characters
examined.

Color in alcohol. Ophioblennius stage larvae (to about 20 nm SL)
with head and body cream colored; no distinct blackish spots, but
several areas around lower half of orbit with slightly denser grouping
of small melanophores than surrounding areas; all cirri cream colored.

Some specimens about 25-35 mm SL with broad dark-brown stripe (its
width about the diameter of orbit) on dorsal half of body beginning
above pectoral-fin base and reaching almost to caudal-fin base;
background color pale brown; others with a uniformly dark-brown body;
frequently, a narrow pale streak, often broken into pale spots,
extending diagonally from behind eye onto upper lip.

Adult males and females (Figure 34) with dark-brown body. Some
specimens with faint indication of above-mentioned broad dark stripe
(stripe not contrasting with dark body); several pupil-sized pale-brown
spots frequently present above pectoral-fin base; head brown with pale
spots on cheeks and around eyes, often with pale streak extending from
postorbital margin to upper lip; two faint pale bars (width of each
about half pupil diameter) sometimes present under eye, one from
posteroventral margin of orbit to point on upper lip beneath middle of
orbit, the other from anteroventral margin of orbit onto upper lip near
symphysis .

Color in life. Adult male (based on a color jlide of a freshly
dead specimen from Dampier Archipelago, Western Australia) with head
and anterior fourth of body pale brown, posterior three- fourths of body
dark brown; head with small red spots and streaks; bars beneath eye

173

pale yellowish- brown; nasal cirri yellowish brown; orbital cirri pale
brown; nuchal cirri blackish; pectoral-fin rays yellowish; dorsal-fin
spines reddish, lower half of spinous-dorsal fin brown,
segmented-dorsal fin dark brown with tips of anterior rays reddish;
proximal half of caudal fin brown, distal half with upper rays yellow
and lower rays reddish; anal fin with tips of rays whitish, then
sequentially toward body a red stripe, brown stripe, red stripe, and
brown stripe, each becoming darker posteriorly; iris with yellow inner
ring and red outer ring; reddish pink rugosities on anal-fin spines.

A young female (based on a color slide of a Tioman Island, Malaysia
specimen) has coloration similar to the male described, except the
segmented-ray portion of the dorsal fin and the entire caudal fin are
yellowish, the lower pectoral-fin rays are orangish red, and the red
spots extend from the head onto the body above the pectoral-fin base.

Comparisons . Cirripectes f ilamentosus is most similar to C.
chelomatus. These species occur sympatrically in northeastern
Queensland and southeastern New Guinea, where they >.an be
differentiated by coloration and pelvic-fin ray counts. Cirripectes
chelomatus has small brown (purplish-red in life) spots covering the
body and 1,4 pelvic-fin rays. Cirripectes filamentosus lacks spots on
the body and has 1,3 pelvic-fin rays in the area of sympatry (some
populations in other geographic areas have 1,4 or both 1,3 and 1,4).

Male Cirripectes filamentosus are distinct from all sympatric
species (except C_. chelomatus ) in having a type II genital papilla
(Figure 13). Females and young are distinguished from sympatric
species by the following combination of characteristics: uniformly

174

brown body, small pale spots (red in life) on cheeks and snout, last
lateral-line tube usually positioned at point between verticals from
dorsal-fin ray 2-6, 2 pores behind nuchal flap, and 30 total vertebrae.

Distribution. Cirripectes f ilamentosus occurs in the western
Indian Ocean from northern Madagascar and Cargados Carajos Shoals
northward to the southern Red Sea and the Persian Gulf. Although known
from the Seychelles Islands, it has not been collected at Chagos
Archipelago or the Cocos-Keeling Islands. Based on material I have
examined, a disjunct population is known from the eastern Indian Ocean,
where it occurs from Western Australia to the Andaman Sea, throughout
the Indo-Australian Archipelago to the Solomon Islands, and as far
north as Taiwan, but not on the Pacific plate.

The disjunct distribution in the Central Indian Ocean (Figure 19)
is probably a collecting artifact. Jones and Kumaran (1980) reported
specimens identified as Cirripectes variolosus from the Laccadive
Islands, but, as this species does not occur in the Indian Ocean, the
specimens may be C. f ilamentosus . My attempts to borrow these
specimens for examination have been unsuccessful. If these specimens
are referable to C. f ilamentosus , they fil-1 part of the gap between the
eastern and western Indian Ocean populations.

Specimens of Cirripectes filamentosus seem to be better colonizers
or able to tolerate a wider range of environmental conditions than
other Cirripectes species. Cirripectes filamentosus is the only member
of the genus occurring in the Persian Gulf, Gulf of Thailand, and along
the coast of Northern Territory, Australia.

Cirripectes filamentosus is usually found on coral or rocky reefs
from shallow water to about 20 m.

175

Etymology. The specific epithet is derived from the Latin filum,
meaning thread, and presumably refers to the filamentous dorsal-fin
spines of adults.

Comments . Cirripectes f ilamentosus shows more variation in more
characters than any other Cirripectes species. It is the only species
that does not have a strong mode for dorsal- and anal-fin segmented
rays (i.e. in each population, almost half the specimens have 14 and
half 15 dorsal rays, and about half have 15 and half 16 anal rays).
All other Cirripectes species have a strong mode for a single count in
each fin. The variation in number of segmented pelvic-fin rays in C.
f ilamentosus is particularly noteworthy. For every other Cirripectes
species, this character is extremely constant. Cirripectes
f ilamentosus not only exhibits geographic variation in this count, but
can have both counts (1,3 and 1,4) common in specimens from a single
locality (e.g. of 37 specimens from the Philippines, 25 have 1,3 and 12
have 1,4; at Tioman Island 3 have 1,3 and 2 have 1,4; at each of these
localities, one additional specimen has 1,3 on one side and 1,4 on the
other). Specimens from most other localities have 1,3 pelvic-fin
elements (one specimen in the western Indian Ocean has 1,3 on one side
and 1,4 on the other), but specimens in the Gulf of Thailand and Viet
Nam (one specimen examined) above the equator, and Northern Territory
and Western Australia below the equator, all havo 1,4 (one Western
Australian specimen with 1,3 on one side and 1,4 on the other). One
other character, presence or absence of mid-snout pores, shows the same
pattern of geographic variation. In those populations (localities)
with both pelvic-fin ray formulae and those with only 1,4, mid-snout

176

pores may be present or absent. Those populations with 1,3 pelvic-fin
rays have mid-snout pores present.

Although the variation discussed above suggests a divergence of
certain populations from others, I do not believe these differences
warrant recognition of these populations at the specific or subspecific
level .

Another character showing a high degree of variation in Cirripectes
f ilamentosus is the length and number of filamentous dorsal spines.
The spines become filamentous with increasing SL, and are often best
developed in adult males. However, some groups of similar-sized males
and females may contain individuals of each sex with short filaments
and others with very long filaments. The first spine is usually long
and filamentous in adults of both sexes. Adult males usually have most
of the spines filamentous, whereas adult females can have anywhere from
none to almost all filamentous.

Nomenclatural discussion. Alleyne and Macleay (1877) described
Salarias f ilamentosus based on one specimen from Cape York, Australia.
They erroneously described the specimen as having XII, 20 dorsal-fin
elements, 11,20 anal-fin elements, and no canines. McCulloch and
McNeill (1918) corrected the counts of Alleyne and Macleay (1877) to
dorsal XII, 15 and anal 11,16, and found a canine posteriorly on each
dentary. My examination of the holotype (AMS 1.16408-001) confirms the
observations of McCulloch and McNeill (1918).

The description of Salarias cruentipinnis by Day (1888) was based
on a description and illustration in a Tickell manuscript. The
specimen on which the description was based is presumed lost. The

177

illustration and description generally fit Cirripectes f ilamentosus ,
but there are a few differences (based on my examination of a color
photograph (slide) of the description and illustration in the Tickell
manuscript). The illustration shows a continuous dorsal fin and a
distinct yellow patch behind the posterior edge of the maxillary. I
have not seen a Cirripectes specimen with similar yellow markings.
Several species have a continuous dorsal fin, and I have even seen C.
f ilamentosus specimens without the notch (the result of damage and
regeneration of the membrane, probably during early development).
Aside from the yellow patches, Salarias cruentipinnis generally
resembles C^. f ilamentosus and I consider it a junior synonym of C.
f ilamentosus . The type locality of Salarias cruentipinnis , Saddle
Island, is the only Burma locality from which a Cirripectes has been
recorded.

Cirripectes indrambaryae was described by Smith (1934), based on
one specimen from Koh Samui, Gulf of Thailand. I have not examined the
type, but, aside from the lack of canines in the lower jaw, the
description and the illustration of the type (the latter published by
Schultz, 1941) agree with C^. f ilamentosus . The missing canines could
have been broken off (not an uncommon occurrence) , or they may have
been present and overlooked. In addition, C. filamentosus is the only
Cirripectes species known to occur in the Gulf of Thailand.
Consequently, I consider C. indrambaryae to be a junior synonym of C.
filamentosus .

Material examined. Types: AMS 1.16408-001 (55 mm SL), male
holotype of Salarias filamentosus, Cape York, Queensland, Australia.

178

Other material examined. Kenya: RUSI UNCAT. (2: 54-46 ) ..
Ethiopia: HUJF 11241 (6: 34-53), HUJF 11242 (1: 26), USNM 204500 (4:
29-41), USNM 204512 (1: 38), USNM 204520 (9: 29-51), USNM 204521 (3:
31-37). Yemen: USNM 230382 (1: 28), USNM 230383 (1). Aden: USNM
228050 (1). Omman: BPBM 21378 (1: 48), BPBM 21464 (4: 39-56), ROM
UNCAT. (3: 46-54), ROM UNCAT. (1; SIMM 82-14), ROM UNCAT. (2; SIMM
18-04). Saudia Arabia, Persian Gulf: BPBM 30281 (1). Madagascar:
USNM 228057 (2: 40-46). Seychelles Islands, Farquhar Group: ANSP
114817 (3: 28-54), ANSP 126857 (1: 31), ANSP 126858 (1: 29), ANSP
126859 (3: 29-36), ANSP 126860 (3: 28-31), AnaP 126871 (3: 31-43), ANSP
126936 (2: 23, 44), ANSP 126937 (6: 32-57), ANSP 126984 (15: 24-55),
ANSP 126985 (18: 23-46), ANSP 126986 (51: 16-51), ANSP 126987 (28:
16-52) ANSP 126988 (114: 19-54), ANSP 127001 (3: 33-37), ANSP 127002
(2: 39, 66), ANSP 127004 (3: 32-38), ANSP 127005 (2: 55, 58), ANSP
127127 (1: 17), ANSP 127139 (10: 29-53), ANSP 127140 (12: 18-59), ANSP
127141 (36: 18-53), BPBM 21583 (22), BPBM 22968 (6). Cargados Carajos
Shoals: USNM 228054 (4), USNM 228055 (6), USNM 228056 (6), USNM 228058
(34), USNM 228059 (1), USNM 228060 (22), USNM 228061 (1), USNM 228092
(30 of 53 examined: 34-60), USNM 228100 (34), USNM 228104 (9), USNM
228156 (1: 51), USNM 229157 (1: 62). Australia, Western Australia:
AMS 1.19688-004 (2), BPBM 17427 (20: 18-65), WAM P. 22417-9 (1: 47), WAM
P. 27496-001 (2: 40-58). Nicobar Islands: SMF 17081 (1: 35).
Thailand, Similan Islands: BPBM 22798 (6: 35-51), USNM 228094 (1).
Thailand, Gulf of Thailand: CAS 48887 (2), CAS 48888 (8), CAS 48889
(1), CAS 48890 (2), CAS 48904 (7), CAS 48913 (17), CAS 48914 (15), CAS
48918 (3), CAS 48919 (2), CAS 48920 (13), CAS 48921 (1), CAS 48932

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(64), CAS 48933 (43: 40-64). Malaysia: BPBM 21891 (2: 40, 41), BPBM
21980 (8: 32-47). Viet Nam: CAS UNCAT. (1: 47). Taiwan: BPBM UNCAT.
(2: 49, 51), BPBM 23077 (2: 49, 64). Philippine Islands: CAS UNCAT.
(3: 26-49), CAS 45893 (2: 53, 54), CAS 46041 (2), CAS-SU 32274 (2),
LACM 37414-7 (1: 48), LACM 37423-4 (1: 43), LACM 42456-14 (3), LACM
42461-12 (3), LACM 42485-11 (7), LACM 42490-22 (3), LACM 42491-21 (2),
USNM 122456 (1), USNM 137860 (1), USNM 137861 (1), USNM 225120 (7),
USNM 225121 (2), USNM 225125 (5), USNM 225132 (3), USNM 225133 (3),
USNM 225142 (2), USNM 228046 (23), USNM 228047 (5), USNM 228048 (26),
USNM 228052 (5), USNM 228052 (5), USNM 229053 (86), USNM 228063 (2),
USNM 228064 (ll)r USNM 228065 (1), USNM 228066 (8: 54-63), USNM 228101
(16), USNM 228110 (4), USNM 228111 (1), USNM 228112 (1: 56), USNM
228295 (1: 58), USNM 228296 (2: 39, 51), USNM 228276 (1: 28).
Indonesia: RMNH 17950 (2), RMNH 20283 (1: 23), RMNH 20783 (1: 11),
USNM 228093 (10: 28-42), USNM 228095 (1), USNM 228096 (6: 16-38), USNM
228103 (1), USNM 228105 (1), USNM 228273 (17: 17-45), USNM 228275 (2:
23, 43). Australia, Western Australia: WAM P. 20292 (2), WAM P. 21291
(1), WAM P. 22568 (1), WAM P. 22626-33 (8), WAM P. 22766-8 (3), WAM
P. 23956-9 (4), WAM P. 24012-18 (7), WAM P. 24275-9 (8), WAM P. 24374-5
(2), WAM P. 24606 (3), WAM P. 25111-013 (14), WAM P. 25112-017 (11), WAM
P. 25368-030 (1), WAM P. 25813-025 (4), WAM P. 25824-008 (1), WAM
P. 25827-002 (2), WAM P. 26670-012 (7), WAM P. 26677-016 (1). Australia,
Northern Territory: AMS 1.21961-020 (2), NTM UNCAT. (19: 20-62), NTM
UNCAT. (15; HL 82-58), NTM UNCAT. (138; HL 82-71), NTM UNCAT. (3; HL
82-74). Australia, Queensland: AMS 1.20770-101 (1: 36), USNM 164966
(8: 36-69), USNM 164967 (26: 30-56), USNM 174345 (26: 37-75).

180

Papua-New Guinea: USNM UNCAT. (4: 17-21), USNM 212137 (1), USNM 212140
(1), USNM 227629 (1), USNM 228097 (2), USNM 228098 (3: 28-29), USNM
228102 (2), USNM 228107 (2: 30, 32), USNM 228108 (30 of 66 examined:
32-51), ZMB 15141 (1). Bismarck Archipelago: CAS 48892 (2), USNM
228099 (22: 35-56), USNM 228106 (3). Solomon Islands: AMS 1.17486-005
(3: 39-47), BPBM 16022 (6: 17-43), USNM 122988 (2).

Cirripectes fuscoguttatus Strasburg and Schultz

Cirripectus fuscoguttatus Si-tasburg and Schultz, 1953:130 (Rongerik
Atoll, Eniwetak Island).

Diagnosis . A species of Cirripectes with the following combination of
characters: broadly expanded nuchal flap bearing distinct cirri (type
C; Figure 7), 0-5 lateral line tubes, and males and females with
dark-brown spots on a pale-brown background.

Description. Dorsal fin XII, 13-15 (14 in 97.1% of specimens); anal
fin 11,14-16 (15 in 96.4%); total procurrent caudal-fin rays 11-14;
pelvic fin 1,4; vertebrae 10+20=30; last pleural ribs on vertebral
centrum 11-12 (11 in 99.3%); last epipleural rib on vertebral centrum
17-20 (17-19 in 97.8%); anal pterygiophores 1-1-2 or 1-2-1 (1-1-2 in
82.3%); nuchal cirri 47-66 (50-60 in 93.3%); supraorbital cirri 18-42
(20-37 in 89.6%); nasal cirri 7-32 (11-27 in 86.4%); LL tubes 0-5 (0-3
in 95.8%); last LL tube positioned at point between verticals from
dorsal-fin ray 13 and caudal-fin base (at caudal-fin base in 75.6%); no

181

scalelike flaps along LL; lower lip smooth mesially (plicate
laterally); gill rakers 22-32 (based on 46 specimens); pseudobranchial
filaments on one side 8-13 (based on 46 specimens); premaxillary teeth
248-310 (based on 11 specimens); dentary teeth 120-140 (based on 11
specimens); upper lip crenulae approximately 40-55; nuchal cirri in
four groups, two or more groups occasionally connected basally by a
slightly notched frenum, dorsalmost groups of cirri usually meet or
overlap at midpoint on nape, ventralmost group of cirri on each side
borne on expanded flap (type C; Figure 7); first dorsal-fin spine of
adults equal to or slightly longer than second (0-4.4 mm longer in
males, 0-2.9 mm longer in females); dorsal-fin membrane deeply incised
above last dorsal-fin spine; dorsal-fin membrane attached to caudal fin
in adults; cephalic pore system complex ( 3 or more pores at most
positions; number of pores increases with increasing SL); mid-snout
pores present (Figure 17); extra interorbital pore position present
(Figure 17); two pore positions behind nuchal flap (Figure 17); male
genital papilla with urogenital orifice located basally between two
widely separated slender filaments (less than 1.0 mm long) on a fleshy
swelling behind anus (type I; Figure 13); testes bulbous, length equals
width; maximum SL about 106 mm; ophioblennius larvae not known.

The smallest mature female (ova about 0.6 mm diameter) examined was
about 56 mm SL. Males mature by about 50 mm SL.

Color in alcohol. Small specimens (10-30 mm SL) have body and head
markings similar to young Cirripectes gilberti (see next species
account), except young C. fuscoguttatus have the broad white triangle
beneath the eye extending dorsally along posterior margin of orbit to

182

top of head (Figure 35). One 23 mm SL specimen from the Marshall
Islands has faint dark-brown spots on body instead of typical uniformly
brown pattern of juveniles.

As size of males and females increases, number of dark-brown spots
on head and body increases; background color of body behind spots
becomes blotched, forming about four broad irregular brown bars with
pale interspaces (Figure 36). More details of changes in color pattern
with size are discussed by Strasburg and Schultz (1953).

Color in life. Adult males (based on a color slide of a Marshall
Islands specimen) with dark-brown spots over head and body; head and
anterior half of body with yellowish background, becoming brown on
posterior half of body; anterior dorsal-fin spines yellowish, fin
otherwise with indistinct brown spots and bars, and pale stripe
extending entire length of basal fourth of fin; segmented-dorsal fin
otherwise with dark-brown rays and dusky membranes; tips of upper
caudal-fin rays orange, remainder of fin dark brown; anal fin dark
brown; anal-fin spine rugosities yellowish brown; pelvic fin yellowish;
pectoral fin with dark-brown spots on proximal half, distal half of
upper rays brown with pale interradial membranes, distal half of lower
rays yellowish brown; nuchal cirri black; supraorbital cirri yellowish
brown; nasal cirri brown; iris orangish red.

Distribution. Cirripectes fuscoguttatus is widely distributed on
the Pacific plate and occurs along the plate margin at Taiwan and
Niuatoputapu Island, Tonga Islands. It is not known to occur at
Johnston Island, the- Hawaiian Islands, Line Islands, or several other
groups (Figure 22). Typically, it is found on coral reefs in the surge
zone at depths of 0-8 m.

183

Comparisons. Cirvipectes fuscoguttatus differs from all
Cirripectes species occurring on the Pacific plate in having a broadly
expanded nuchal flap bearing distinct cirri (type C; Figure 7). In
Taiwan, where the geographic ranges of C_. fuscoguttatus and C. imitator
overlap, both have a large nuchal flap, but the latter usually has 7-14
lateral line tubes (versus 0-5). Cirripectes fuscoguttatus differs
from its Indian Ocean sister species, C. gilberti, only in color
pattern, as discussed in the account of the latter.

Etymology. The specific epithet is a combination of the Latin
fuscus, meaning dusky or dark, and guttatus , meaning spotted, in
reference to the dark brown spots on head and body.

Material examined. Types: USNM 113634 (1 female: 68 mm SL),
holotype of Cirripectes fuscoguttatus, Marshall Islands, Rongerik
Atoll, Eniwetak Islet, ocean reef; and the following paratypes of
Cirripectes fuscoguttatus: USNM 115497 (1: 75), Samoa Islands, Tutuila
Island; USNM 115498 (5: 75-90), Phoenix Islands, Enderbury Island reef;
USNM 142102 (10: 19-94), Marshall Islands, Bikini Atoll, Eman Islet;
USNM 142103 (16: 23-86) .Marshall Islands, Bikini Atoll, Airy Islet;
USNM 142104 (35: 23-97), USNM 142105 (1: 72), Marshall Islands,
Kwajalein Atoll, Ennylabegan Islet; USNM 142106 (11: 22-82), Marshall
Islands, Kwajalein Atoll, Ennylabegan Islet; USNM 164960 (2: 60-79),
Gilibert Islands, Onotoa Atoll.

Other material examined. Pacific Ocean (exact locality unknown):
USNM 198700 (3: 63-79). Taiwan: USNM 227869 (1: 106). Caroline
Islands: CAS 489422 (4: 39-82), CAS 48937 (13), CAS 48940 (7), CAS
48943 (15: 41-106). Mariana Islands: BPBM UNCAT. (2: 69-81), CAS

184

48915 (1: 27), GAS 48931 (5: 77-96). Marshall Islands: BPBM 8008
(10), BPBM 15517 (1), LACM UNCAT. (1; MARSHALL IS.), LACM 4067 (4:
50-79), LACM 6679-37 (3), USNM 200612 (3: 29-67), USNM 227864 (1: 88).
Phoenix Islands: USNM 201888 (1: 82), USNM 227865 (2: 26-28), USNM
227870 (1: 34). Tonga Islands: USNM 227868 (3: 54-86). Samoa
Islands: LACM 34356-11 (3: 85-94). Tuamoto Archipelago: BPBM UNCAT.
(4: 59-77), CAS 48928 (2), CAS 48929 (2), CAS 48954 (1), USNM 227866
(1: 93), USNM 227867 (4: 92-97).

Cirripectes gilberti new species

ft
Diagnosis . A species of Cirripectes with the following combination of

characters: type C nuchal cirri pattern (Figure 7), high number of

nuchal cirri (typically more than 45), 7-14 lateral-line tubes, adult

males with uniformly brown body, and females with reddish spots in life

(pale in alcohol) .

Description. Dorsal fin XII, 14; anal fin 11,15; total procurrent

caudal-fin rays 12-14; pelvic fin 1,4; vertebrae 10+20=30; last pleural

ribs on vertebral centrum 11; last epipleural rib on vertebral centrum

17-19; anal pterygiophores 1-1-2 or 1-2-1 (1-1-2 in 95.8% of

specimens); nuchal cirri 50-64 (53-59 in 82.6%); supraorbital cirri

17-48 (22-35 in 79.2%); nasal cirri 11-33 (11-23 in 95.8%); LL tubes

0-5 (0-3 in 95.8%); last LL tube positioned at point between verticals

from dorsal-fin ray 9 and caudal-fin base (on caudal-fin base in

76.2%); no scalelike flaps along LL; lower lip smooth mesially (plicate

laterally); gill rakers 24-30 (based on 23 specimens); pseudobranchial

185

filaments on one side 8-13 (based on 23 specimens); premaxillary teeth
203-270 (based on 16 specimens; number of teeth increases with
increasing SL; specimens greater than 60 mm SL have 240-270 teeth);
dentary teeth 100-141 (based on 17 specimens; specimens greater than 60
mm SL have more than 120 teeth); upper lip crenulae approximately
36-48; nuchal cirri in four groups, two or three groups occasionally
connected basally by a slightly notched frenum, dorsalmost groups of
cirri usually overlap at midpoint on nape, ventralmost group of cirri
on each side borne on expanded nuchal flaps (type C; Figure 7); first
dorsal-fin spine of adults slightly longer than second (0.1-2.6 mm
longer in males, 0.4-4.3 mm longer in females); dorsal-fin membrane
deeply incised above last dorsal-fin spine; dorsal-fin membrane
attached to caudal fin in adults; cephalic pore system complex ( 3 or
more pores at most positions; Figure 17; number of pores increases with
increasing SL); mid-snout pores present (Figure 17); extra interorbital
pore position present (Figure 17); two pore positions behind nuchal
flap (Figure 17); male genital papilla with urogenital orifice locaueJ
basally between two widely separated slender filaments (less than 1.0
mm long) on a fleshy swelling behind anus (type I; Figure 13); testes
bulbous, length equals width; maximum SL about 102 mm; ophioblennius
larvae not known.

The smallest mature female (ova about 0.6 mm diameter) examined was
about 76 mm SL (a 50 mm SL specimen was still immature). Males mature
by about 50-6U mm SL.

186

Color in alcohol. Color pattern changes ontogenetically and
differs sexually among adults (Figures 37 and 38). Body of specimens
less than 40 mm SL (Figure 39) uniformly brown, with faint dark-brown
spots beginning to appear posteriorly on specimens nearing 40 mm SL;
head with brown background, broad white triangular area extending from
point at mid-ventral margin of orbit ventrally over posteriormost half
(as measured from snout tip) of upper lip onto lower lip, narrow white
bar reaching from anterior edge of orbit over lip at snout tip where it
almost meets similar bar from other side forming a V on snout; dorsal
fin dusky with pale triangular area at tips of anterior spines; anal
fin dark brown; caudal fin dusky; pectoral-fin rays dusky; pelvic-fin
rays dusky; nuchal cirri black; supraorbital and nasal cirri dark
brown.

Between 40-65 mm SL, females have pupil-sized dark-brown spots over
body and slightly smaller ones on head; males have darker brown
background color and sometimes very faint spots or irregular pale-brown
bars on body; pale triangular wedge beneath eye present but darker in
both sexes; females with small brown spots scattered over wedge; pale
bars at snout tip faint or absent.

Females longer than 65 mm SL with head covered with 1-2 mm diameter
spots on dark-brown background, spots extending onto pectoral fin and
ventral halves of dorsal and anal fins; spots on fins, head, and
anterior half of body pale, becoming dark brown on posterior half of
body; uppermost caudal-fin rays pale, remainder dark brown.

Males greater than 65 ram SL with uniformly dark-brown head and
body; tips of dorsal-fin elements pale, remainder dark brown; anal fin

187

dark brown; tips of uppermost caudal-fin rays pale, remainder of fins
dark brown; anal-fin rugosities dark brown.

Color in life. Adult females (based on a color slide of a Chagos
Archipelago specimen) have background color of head and body mottled
with pale-olive and dark-brown blotches; stomach and throat white; head
and anterior half of body with reddish-orange spots becoming reddish
brown at mid-body and dark brown near caudal-fin base; orangish-brown
spots on dorsal, anal, proximal half of caudal, and pectoral fins;
ventralmost pectoral-fin rays with orange tips; dorsal fin with tips of
spines yellow and tips of rays orange; tips of dorsalmost caudal-fin
rays bright orange, remainder of fin dusky orange; iris red except for
yellow ring around pupil.

Life colors of males unknown.

Comparisons. Cirripectes gilberti is closely related to C.
fuscoguttatus , a Pacific plate endemic, and C. imitator, occurring from
Taiwan to Japan. All three have a type C nuchal cirri pattern (Figure
7), and high number of nuchal cirri (typically more than 45).
Cirripectes imitator differs from the other two in having 7-14
lateral-line tubes (versus 0-5). Cirripectes gilberti and C.
fuscoguttatus appear to differ only in color pattern. Adult males of
C_. gilberti do not have spots, and females have reddish spots in life
(pale in alcohol), whereas both sexes of C. fuscoguttatus have
dark-brown spots (in life and alcohol).

Of those Cirripectes species occurring in the Indian Ocean, C.
gilberti is the only one that has a type C nuchal cirri pattern.

188

Distribution. I have examined specimens of Cirripectes gilberti
from seven Indian Ocean localities: South Africa, Comoros Islands,
Agalega Island, Seychelles Islands, Chagos Archipelago, Cocos (Keeling)
Islands, and the northern tip of Sumatra. The male identified by Smith
(1959) as C_. fuscoguttatus from La Digue, Seychelles, is C_. gilberti.
Cirripectes gilberti occurs on rocky and coralline substrates at depths
ranging from near the surface to 8 m.

Etymology. This species is named for Dr. Carter R. Gilbert (FSM) ,
who provided assistance and encouragement during the course of this
study.

Comments . Although Cirripectes gilberti is similar to C.
fuscoguttatus , their strikingly different color patterns and
non-overlapping geographic distributions warrant their recognition as
separate species.

Material examined. Holotype: USNM 274749 (male: 82 ram SL),
Indonesia, Pulo Boenta, off Achen Head, Sumatra, 05° 33' 10" N,
095° 09' 30" E, surge channel in coral reef, G -4 m, 20 Nov. 1963, "Te
Vega" Cruise 2, station 93.

Paratypes: USNM 227872 (2: 71, 90), collected with the holotype;
ANSP 134747 (5: 34-45), Cocos-Keeling Islands, North Keeling Island,
11° 50' S, 096° 49' 30" E, 0-1 m, 6 Mar. 1974; ROM 46597 (6:
76-93), Chagos Archipelago, Salomons Group, Isle Boddam, ocean side at
southwest tip of island, 05° 21' 05" S, 072° 12' 12" E, 0-3 m, 18
Mar. 1979; RUSI 15299 (1: 102), Seychelles Islands, Farquhar Group, La
Digue, 12 Oct. 1954; USNM 227871 (3: 43-47), Agalega Island, North
Island, about one-half mile southwest of tip, dead coral channels, some

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live coral, 10° 19' s, 056° 35' E, 0-9 m, 17 April 1976; CAS 40379
(5: 34-102), Comoros Islands, Grande Comore Island, N'Gouni Reef, about
one-half km north of Iconi, surge channel at far end of small cove, 0-5
m, 1 Mar. 1975; RUSI UNCAT. (1: 49), South Africa, Boteler Point, 13
April 1979.

Cirripectes hutchinsi new species

Diagnosis. A species of Cirripectes with the following combination
of characters: complex cephalic sensory pore pattern, 1,4 pelvic-fin
rays, no extra interorbital pore position (Figure 17), 36-42 nuchal
cirri.

Description. Dorsal fin XII-XIII (XII in 94.7% of specimens) , 13-14
(14 in 89.5%); anal fin 11,15-16 (15 in 89.5%); total procurrent
caudal-fin rays 9-11; pelvic fin 1,4; vertebrae 10 + 20-21 (20 in
94.7%) = 30-31 (30 in 94.7%); last pleural ribs on vertebral centrum
11; last epipleural rib on vertebral centrum 16-20 (17-19 in 89.5%);
anal pterygiophores 1-1-2 or 1-2-1 (1-1-2 in 89.5%); nuchal cirri 35-42
(36-41 in 89.5%); supraorbital cirri 12-29 (17-29 in 94.7%); nasal
cirri 8-13 (12-26 in 89.5%); LL tubes 3-9; last LL tube positioned at
point between verticals from dorsal-fin ray 13 and caudal-fin base (on
caudal-fin base in 82.4%); no scalelike flaps along LL; lower lip
smooth mesially (plicate laterally); gill rakers 23-29 (based on 18
specimens); pseudobranchial filaments on one side 8-14 (based on 19
specimens); premaxillary teeth 192-218 (based on 10 specimens); dentary
teeth 97-114 (based on 10 specimens); upper lip crenulae approximately

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36-42; nuchal cirri in four groups with each ventralmost group of cirri
borne on a slightly expanded nuchal flap (type B; Figure 7); first
dorsal-fin spine of adults slightly longer than second (1.5-11.0 nm
longer in males, 0.7-4.9 mm longer in females); dorsal-fin membrane
deeply incised above last dorsal-fin spine; dorsal-fin membrane
attached to caudal fin in adults; cephalic pore system complex (more
than 3 pores at most positions; Figure 17; number of pores increases
with increasing SL); mid-snout pores present (Figure 17); extra
interorbital pore position absent (Figure 17); 2 pore positions behind
nuchal flap (Figure 17); male genital papilla with urogenital orifice
located basally between two widely separated slender filaments (less
than 1.0 mm long) on fleshy swelling behind anus (type I; Figure 13);
testes bulbous, length equals width; maximum SL about 105 mm;
ophioblennius larvae not known.

The smallest mature female (ova about 0.5 mm diameter) examined was
about 73 mm SL. Males mature by about 60-70 mm SL.

Color in alcohol. Young specimens (30-40 mm SL) have pale brown
areas on dorsal and ventral thirds of body with mid-lateral third
darker brown, section of body between pectoral-fin base and posterior
end of anal-fin base overlaid with dark-brown spots and narrow wavy
lines; pale-brown area on body at caudal-fin base; head brown with
small pale spots on snout and lower part of cheeks, 6-8 narrow pale
bars on upper lip; throat with brown bar across middle, flanked by pale
areas anteriorly and posteriorly; transluscent triangular area at tips
of anterior dorsal-fin spines and over upper and lower caudal rays;
tips of posterior dorsal-fin elements pale, remainder of fin dusky;

191

middle of caudal fin dusky; lower half of pectoral fin dusky, upper
half transluscent ; proximal half of pelvic fins dusky, distal half
transluscent ; nuchal cirri dark brown; nasal and supraorbital cirri
brown.

Adult females have a body color pattern that varies geographically
from north to south (Figures 40 and 41). The southern pattern consists
of small pupil-sized spots arranged over broad mid-lateral section of
body from behind head to posterior end of anal-fin base, and pale area
extending from posterior end of anal-fin base to caudal-fin base. In
the northern pattern, about five to nine slightly-irregular broad
dark-brown bars with pale interspaces extend from dorsum to about
two-thirds distance to anal fin base; anterior half of body has small
dark-brown spots overlying barred pattern. Amount of body covered by
spots variabe, with some specimens showing patterns intermediate
between the two patterns. All females with two to five vertical rows
of small dark-brown spots on proximal half of pectoral fin; head brown
with two or three diagonal dark-brown bars extending from nape
anteroventrally to middle of head where bars break up into small spots
that cover throat and ventral half of head; upper lip with 8-10 pale
bars; middle of spinous dorsal fin with line of brown spots on
interradial membranes; remainder of pattern same as for young
specimens .

Adult males have two color patterns (Figure 42), both unlike
females; both patterns may be found in the same geographic area. One
pattern consists of about six broad dark-brown bars with brown
interspaces. In the other pattern, the body is uniformly dark brown

192

without spots on the body. These patterns appear to be related to
size, as the largest males have uniformly brown bodies, and most of the
smaller males have the barred pattern. All males have a brown head
without dark spots; upper lip with 8-10 pale bars; no spots on pectoral
fins; other colors similar to those of females and young specimens.

Color in life. Females (based on color slides of specimens from
Rottnest Island, Western Australia) with background color of head and
body olive to brown; reddish-brown to dark-brown spots on head and
body; spinous-dorsal fin dusky to dark brown, remainder varying from
completely orange or red to dark brown with tip» of rays red; caudal
fin with dorsalmost and ventralmost rays red, middle rays brown;
posterior part of body at caudal-fin base reddish; anal fin dark brown
with brilliant blue tips; iris varies from yellow to orange.

Based on a color slide of a 57 nm SL specimen from Rottnest Island,
a male with the barred color pattern resembles color in alcohol
except: throat and edge of operculum yellowish; cheek brown; two
anteroventrally directed bars (becoming spots beneath eye) extend from
top of head onto upper lip, interspaces yellow to brown; pectoral-fin
base reddish brown; middle of spinous-dorsal fin with narrow
brownish-orange line, spines yellow with tips of posterior spines
becoming scarlet; segmented dorsal fin with diagonal
posterodorsally-directed brownish-orange line on basal half of each
interradial membrane, rays dusky yellow; anal fin with alternating
lengthwise stripes in sequence from base: blue, reddish brown, blue,
reddish brown; anal ray tips pale blue; pelvic fin reddish brown;
ventralmost 5-6 nuchal cirri yellowish orange, others dark brown; other

193

cirri brown; iris varies from completely orange to having inner yellow
ring and outer orangish-red ring with black area in between.

Based on a color slide of a Shark Bay, Western Australia,
specimen, a larger male resembles Rottnest Island male except for
dorsal fin, which has anterior 4-5 spines yellow and remainder of fin
scarlet; body is uniformly dark-brown.

Comparisons . Cirripectes f ilamentosus is the only Cirripectes
species known to occur within the geographic range of C_. hutchinsi.
Cirripectes f ilamentosus differs from C_. hutchinsi in having a simple
cephalic sensory pore pattern and males with a type II (Figure 13)
genital papilla (versus type I).

Cirripectes randalli and females of C_. hutchinsi , C.. perustus , and
C^. gilberti all occur in the Indian Ocean and have spots on the body.
Cirripectes hutchinsi and C. randalli are distinguished from the others
in the account of C_. randalli. Cirripectes hutchinsi and C_. randalli
differ from each other primarily in color pattern as discussed in the
account of C_. randalli.

Distribution. Cirripectes hutchinsi is known only from Western
Australia, where it occurs from North West Cape southward to Rottnest
Island, near Perth (Figure 22). It has been collected at depths
ranging from one to 22 m. Barry Hutchins has informed rae (in litt.)
that he has found this species in the surge zone in limestone holes
just below the intertidal range, and commonly in areas where
Pocillopora damicornis is present on the reefs.

Etymology. This species is named for Mr. Barry Hutchins of the
Western Australian Museum, who collected most of the known specimens,

194

provided information on the ecology of this speoies, and gave me color
slides of both sexes.

Material examined. Holotype: WAM P. 25744-003 (male: 89 mm SL),
Australia, Western Australia, Rottnest Island, Strickland Bay, 1 Mar.
1977.

Paratypes: AMS 1.20239-023 (2: 85-104), Australia, Western
Australia, Rottnest Island, Salmon Bay, 32° 01 ' S, 115° 27' E, 1-10
m, 10 April 1978; AMS 1.20243-004 (1: 82), Australia, Western
Australia, Rottnest Island, 32° 03* S, 115° 26' E, 20-22 m, 11
April 1978; USNM 273891 (2: 69, 79), Australia, Western Australia,
Northwest Cape, 22 May 1980; WAM UNCAT. (1: 53; OUT OF 25744-003),
collected with holotype; WAM P. 4647 (1: 73), Australia, Western
Australia, Point Quobba, Oct. 1959; WAM P. 4652 (1: 98), Australia,
Western Australia, Houtman Abrolhos, Wallaby Group, Pigeon Island, May
1959; WAM P. 25317-002 (2: 90-106), Australia, Western Australia,
Wallabi Group, Abrolhos Islands, Long Island, 21 May 1975; WAM
P. 25374-042 (1: 69), Australia, Western Australia, Northwest Cape,
lagoon off Tantabiddi Creek, 3-4 m, 2 July 1975; WAM P. 25758-010 (1:
73), Australia, Western Australia, Rottnest Island, Fish-Hook Bay, 8
Mar. 1977; WAM P. 26072-003 (2: 32-52), Australia, Western Australia,
Houtman Abrolhos, Beacon Island, outer reef near Seal Island, 28° 29'
S, 113° 47' E, 4 m, 10 April 1978; WAM P. 26626-001 (1: 76), same data
as USNM 273891; WAM P. 26657-009 (3: 34-70), Australia, Western
Australia, Shark Bay, Steep Point, at entrance to Sou^h Passage, 26°
08' S, 113° 08' E, 13-15 m, 9 April 1979.

195

Cirripectes imitatcr Williams

Cirripectes imitator Williams, 1985:533 (Ogasawara Islands, Chichi
Jima Island).

Diagnosis . A species of Cirripectes with the following combination
of characters: 45 or more nuchal cirri, enlarged nuchal flap on either
side of the head, 7-14 lateral line tubes, and color pattern consisting
of pale spots on a dark background.

Description. Dorsal fin XI -XIII (XII in 95.2% of specimens), 13-15
(14 in 95.2%); total dorsal-fin elements 26; anal fin 11,14-16 (15 in
95.2%); total procurrent caudal-fin rays 11-14; pelvic fin 1,3-4
(bilaterally 1,4 in 88%, bilaterally 1,3 in 6%, one side 1,3 and other
1,4 in 6%); vertebrae 10+20=30; last pleural ribs on vertebral centrum
11; last epipleural rib on vertebral centrum 18-21 (19-20 in 85.5%);
anal pterygiophores 1-1-1, 1-1-2, 1-2-1 (1-1-2 in 92.1%); nuchal cirri
40-59 (45-53 in 82.4%); supraorbital cirri 13-46 (15-35 in 82.7%);
nasal cirri 9-93 (9-33 in 84.6%); LL tubes 5-14 (8-13 in 94.6%); last
LL tube positioned at point between verticals from dorsal-fin ray 9 and
caudal-fin base (on caudal-fin base in 84.5%); no scalelike flaps along
LL; lower lip smooth mesially (plicate laterally); gill rakers 24-27
(based on 22 specimens); pseudobranchial filaments on one side 7-9
(based on 22 specimens); premaxillary teeth 192-230 (based on 11
specimens); dentary teeth 84-120 (based on 11 specimens); upper lip

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crenulae approximately 34-50; nuchal cirri in four groups (two on each
side) separated at dorsalmost point on nape and about halfway down
length of row on each side (gaps less than about 0.5 mm), two groups on
one side rarely connected by a low basal membrane, ventralmost group of
cirri on each side borne on a broad nuchal flap; adults of both sexes
with first dorsal-fin spine slightly longer than second (1-5 mm longer
in males, 1-2 mm longer in females); dorsal-fin membrane deeply incised
above last dorsal-fin spine; dorsal-fin membrane attached to caudal fin
in adults; cephalic pore system complex (numerous pores at most
positions; number of pores increases with increasing SL); mid-snout
pores present (Figure 17); extra interorbital pore position present
(Figure 17); pore positions behind nuchal cirri flap 2 (Figure 17);
male genital papilla with urogenital orifice located basally between
two widely separated slender filaments (less than 1.0 mm long) on a
fleshy swelling behind anus (Figure 13); testes bulbous, length equals
width; maximum SL about 100 mm.

The smallest mature female (ova about 0.5 mm diameter) examined was
55 mm SL, from the Ogasawara Islands. Some 40-50 mm SL females have
large ovaries, but they are granular in appearance and have no large
ova. Males mature by about 50 mm SL.

Color in alcohol. Color pattern highly variable, ranging from
alternating dark- and pale-brown bars to dark-brown reticulations
around pale-brown pupil-sized spots on body. Adult males (Figure 43)
tend to be darker overall, with spots coalescing into pale bars on
body. Females (Figure 44) generally with reticulated color pattern,
but both sexes can exhibit either pattern. Both sexes with cheeks,

197

snout, upper lip, and underside of head with pale-brown spots on
darker-brown background or the reverse; some specimens with spots on
underside of head fusing into 2 or 3 alternating dark and pale bars
across throat; dorsal fin with translucent triangular area in
anterodorsal part of spinous section, narrow pale stripe running
through middle of fin to last dorsal spine, remainder of spinous and
soft dorsal fin brown; upper part of caudal fin with translucent
triangular area, remainder of fin brown; anal fin brown, tips of rays
paler; pectoral and pelvic fins dusky; nuchal cirri black, other cirri
brown, ctugosities on anal-fin spines of males pale brown.

Color in life. Male (based on fig. 392-7a in Shen 1984, which he
referred to as Cirripectes sebae) with alternating brown and
bluish-white bars on head and body; those on head broken into irregular
pupil-sized spots; pale section of caudal and spinous-dorsal fins with
orange rays; red stripe running through middle of spinous dorsal; each
nuchal cirrus with pale-yellow band near base; iris with yellow ring
around pupil; other colors same as in alcohol. Fukao (1984) states
that the Ogasawara specimens have bright-yellow spots or blotches on
body in life.

Females (based on fig. 392-7b in Shen 1984; and plate 87-D in
Masuda et al. 1975) similar to male except spots on body not fused into
bars, spots becoming smaller posteriorly. There is some doubt about
the identification of the specimen in figure 392-7b (Shen 1984). I
tentatively identify it as Cirripectes imitator , but it could be a
specimen of C. castaneus , a species in which females have a very
similar color pattern.

198

Distribution. Cirripectes imitator is known to occur from Taiwan
northward to Shirahama, Japan, and in the Ogasawara Islands (Figure
22).

Comparisons . Cirripectes imitator belongs to the C^ fuscoguttatus
complex of species, with which it shares two derived characters: a
high number of nuchal cirri (usually 45 or more) and an enlarged nuchal
flap on either side of the head. A large nuchal flap is also present
in C^. auritus and C_. kuwamurai (Carlson 1981, Fukao 1984), but the
nuchal flaps in these species are proportionally larger, bearing poorly
developed cirri, and are probably independently derived. Cirripectes
imitator differs from C_. fuscoguttatus and _C. gilberti in having 7-14
(in 98.2% of specimens; 1 of 56 with 5) LL tubes, versus 0-4 (in 98.5%;
2 of 69 with 5). The color pattern of C_. imitator , with pale spots on
a dark background, is the reverse of C_. fuscoguttatus , which has dark
spots on a pale background.

Williams (1985) discussed the differences between Cirripectes
imitator and other sympatrically occurring congeneric species.

Etymology. The specific epithet is derived from the Latin imitor ,
meaning mimic, and refers to the similarity of the color pattern to
that of Cirripectes polyzona and C. castaneus.

Comments . No geographic variation was found for the meristic or
morphometric characters examined. Fukao (1984) noted that his
Cirripectes polyzona specimens from the Ogasawara Islands (=C_. imitator
at that locality) had bright-yellow spots or blotches in life. I
attribute this color variant to populational variation within the
species .

199

Material examined. Holotype: FAKU 43203 (male: 65.6 mm SL),
Ogasawara Islands, Chichi Jima Island (approximately 27°30'N,
142 30'E), Sakiaura; 0.5-5 m; 8 April 1974. Other material examined
is listed in Williams (1985) and is not repeated here.

Cirripectes jenningsi Schultz
Cirripectes jenningsi Schultz, 1943:274 (Swains Island).

Diagnosis . A species of Cirripectes with the following combination
of characters: uninterrupted row of nuchal cirri (type F; Figure 7),
dorsal fin attached to caudal fin in adults, and more than 36 nuchal
cirri.

Description. Dorsal fin XII-XIII (XII in 98.9% of specimens) , 15-16
(15 in 93.6%); anal fin 11,15-17 (16 in 95.7%); total procurrent
caudal-fin rays 10-14; pelvic fin 1,4; vertebrae 10 + 21-22 (21 in
92.6%) = 31-32 (31 in 92.6%); last pleural ribs on vertebral centrum
11-13 (12 in 97.9%; one each with 11 and 13); last epipleural rib on
vertebral centrum 20-23 (21-23 in 95.7%); anal pterygiophores 1-1-1,
1-1-2, or 1-2-1 (1-1-2 in 88.2%); nuchal cirri 34-44 (37-42 in 93.0%);
supraorbital cirri 2-4 (2-3 in 96.5%); nasal cirri 8-19 (9-12 in
94.3%); LL tubes 2-11 (5-9 in 93.9%); last LL tube positioned at point
between verticals from dorsal-fin ray 15 and caudal-fin base (on
caudal-fin base in 95.7%); no scalelike flaps along LL; lower lip
crenulate mesially (plicate laterally); gill rakers 19-24 (based on 25
specimens); pseudobranchial filaments on one side 9-11 (based on 25

200

soecimens); premaxillary teeth 244-269 (based on 3 specimens); dentary
teeth 112-119 (based on 3 specimens); upper lip crenulae approximately
41-47; nuchal cirri in one continuous row with cirri connected at their
bases by a low membranous ridge, nuchal flap absent (type F; Figure 7);
first dorsal-fin spine of adults equal in length or slightly longer
than second (0-3.3 mm longer in males, 0.9-2.7 mm longer in females);
dorsal-fin membrane deeply incised above last dorsal-fin spine;
dorsal-fin membrane attached to caudal fin in adults; cephalic pore
system complex ( 3 or more pores at most positions; Figure 17; number of
pores increases with increasing SL); mid-snout pores present (Figure
17); extra interorbital pore position present (Figure 17); pore
positions behind nuchal flap 2 (Figure 17); male genital papilla with
urogenital orifice located basally behind a single slender filament
(less than 1.0 mm long) on a fleshy swelling behind anus (type IV;
Figure 13); testes bulbous, length equals width; maximum SL about 76
mm; ophioblennius larvae with 2 canines posteriorly on each dentary.

The smallest mature female (ova about 0.6 mm diameter) examined was
about 42 mm SL. Males mature by about 45-50 mm SL.

Color in alcohol. Ophioblennius stage larvae (based on a 28.2 mm
SL Raroia specimen) with cream colored head, body, cirri, and fins;
small dark-brown spot (about half pupil diameter) located posteriorly
on lower lip.

Juveniles and adults of both sexes have same color pattern (Figure
45): head and anterior half of body pale with dark-brown pupil-sized
spots, frequently with two broad brown bars on body; posterior half of
body brown with pale pupil-sized spots; dorsal fin with transluscent

201

area at tips of anterior dorsal- fin spines, posterior spines with
dark-brown tips, basal third of segmented dorsal fin dark brown with
white spots, pale stripe extending through middle, dusky above stripe;
caudal fin brown with tips of dorsalmost rays pale; anal fin brown with
pale spots on basal half; dorsal half of pectoral fin pale, ventral
half brown; all cirri pale. Males have pale anal-fin spine rugosities.

Color in life. I have not seen life colors of this species, but
Schultz (1943) describes them for a specimen from Swains Island.

Comparisons . Cirripectes jenningsi is the only species in the
genus with an uninterrupted row of nuchal cirri (type F; Figure 7).
All other Cirripectes species have two or more groups of nuchal cirri
separated by small gaps. Cirripectes jenningsi is endemic to the
Pacific plate, where it is most similar to C_. quagga. Cirripectes
quagga differs from _C. jenningsi in having two groups of nuchal cirri
separated at midpoint of nape (type E; Figure 7), dorsal fin not
attached to caudal fin, and usually less than 34 (in 96.9% of
specimens) nuchal cirri (versus more than 36 in 95.8%).

Distribution. Cirripectes jenningsi is known to occur from the
Gilbert Islands to the Tuamotu Archipelago (Figure 19) on shallow coral
reefs. One female (USNM 228160) is recorded from Aldabra Atoll, having
been found together with a large series of C. quagga and C.
variolosus . This group of specimens was accessioned at the USNM along
with material collected at localities on the Pacific plate.
Cirripectes variolosus is otherwise known only from the Pacific plate
and C. quagga, although widespread geographically, is rarely collected
in the Indian Ocean and, when collected, is found in small numbers

202

relative to other species of the genus. As no other specimens of C_.
jenningsi are known from the Indian Ocean, I believe the data
associated with USNM 228160 are erroneous and do not consider Aldabra
as part of the geographic range of either C_. jenningsi or C.
variolosus . I know of one additional non-Pacific plate locality (New
Caledonia) where C. jenningsi (MNHN 1980.224) has supposedly been
collected, but these locality data are also questionable. A. Mauge
(pers. comm.) received the material from P. Fourmanoir, in New
Caledonia, and it was thought to be from that locality. However, as
Fourmanoir has also made collections in the Tuamotu Archipelago, he
could have collected the specimen there. Pending confirmation of the
presence of C_. jenningsi in New Caledonia by new collections, I
consider the distribution of this species to be restricted to the
Pacific plate.

Etymology. Schultz (1943) named this species for a Mr. Jennings of
Swains Island.

Comments . Schultz (1943) gave an anal-fin ray count of 18 for
Cirripectes jenningsi. This count includes both spines and rays,
whereas I separated the two types of rays in my formula. Schultz 's
count of 28 nuchal cirri on the holotype is lower than my lowest
recorded value. The nuchal cirri on the holotype had been damaged
prior to collection, therefore, I excluded this count.

Material examined. Types: USNM 115486 (male holotype: 63; female
allotype: 65 mm SL), Tokelau Islands, Swains Island, 3-9 May 1939; USNM
115487 (20: 35-66), paratypes, same data as holotype.

203

Other material examined. Pacific Ocean (exact locality unknown):
USNM 198714 (1: 61). Gilbert Islands: USNM 167332 (1: 73). Phoenix
Islands: USNM 216718 (1: 49). Line Islands: USNM 200615 (45:
30-76). Tuamotu Archipelago: BPBM 14006 (4: 32-69), CAS 48916 (53:
28-67), CAS 48935 (3), CAS 48941 (27), CAS 48953 (17), USNM 228159 (2:
53, 69).

The following two lots seem to have erroneous locality data: USNM
228160 (1: 40), cataloged as being from Aldabra Atoll, but is probably
from the Pacific Ocean (see earlier discussion); and MNHN 1980.224 (2),
cataloged as being from New Caledonia, but is probably from the Tuamotu
Archipelago according to A. Mauge.

Cirripectes kuwamurai Fukao

Cirripectes kuwamurai Fukao, 1984:106 (Shirahama, Japan).
Cirripectes sp. Masuda, Araga, and Yoshino, 1975, 1980:267 (Shirahama,
Japan) .

Diagnosis. A species of Cirripectes with the following combination
of characters: greatly expanded nuchal flap bearing ventralraost group
of cirri on either side of nape, narrow pale stripes (red in life) on
body.

Description. Dorsal fin XII, 16; anal fin 11,17; total procurrent
caudal-fin rays 10; pelvic fin 1,4; vertebrae 10+22=32; last pleural
ribs on vertebral centrum 11; last epipleural rib on vertebral centrum
19; anal pterygiophores 1-1-2; nuchal cirri 30; supraorbital cirri 13;

204

nasal cirri 10; LL tubes 5; last LL tube positioned at vertical from
dorsal-fin ray 7; no scalelike flaps along LL; lower lip smooth
mesially (plicate laterally); gill rakers 23; pseudobranchial filaments
on one side 8; premaxillary teeth 148; dentary teeth 76; upper lip
crenulae approximately 41; ventralmost nuchal cirri borne on greatly
enlarged nuchal flap, those cirri above flaps independent, no
membranous ridge connects their bases (type A; Figure 7); first
dorsal-fin spine about 0.5 mm shorter than second; dorsal-fin membrane
deeply incised above last dorsal-fin spine; dorsal-fin membrane
attached to caudal peduncle in advance of caudal fin; cephalic sensory
pore system simple (1-3 pores at most positions; Figure 17); mid-snout
pores present (Figure 17); extra interorbital pore position absent
(Figure 17); pore positions behind nuchal flap 2 (Figure 17).

Color in alcohol. Head and body (Figure 46) of holotype with brown
background color; head with pale bar laterally on cheeks (very faint,
slightly darker than background); body with five narrow stripes
(slightly darker than background color) from above and behind
pectoral-fin base to caudal-fin base; spinous dorsal fin dusky basally,
pale distally; segmented-rayed dorsal fin with two faint dusky stripes
in central part of fin; other fins dusky; enlarged nuchal flap black;
all cirri brown.

Color in life. Head of holotype (based on color photo in Masuda et
al., 1975, 1980) brown with scarlet reticulations; body brown with five
scarlet stripes, dorsalmost stripe irregular and wavy; narrow red bar
at base of pectoral-fin rays; dorsal fin with red spots in middle of
fin on membranes between spines, two narrow red stripes extending

205

through middle of anterior three-fourths of segmented dorsal fin,
entire dorsal fin with narrow red distal margin; basal part of
caudal-fin rays red, remainder of caudal-fin pale; anal fin ausky.

Comparisons. See Cirripectes auritus account for comparisons.

Distribution. Cirripectes kuwamurai is known only from the
holotype, which was collected on a rocky reef in water about 3 m deep
off the northern beach of the Seto Marine Biological Laboratory,
Shirahama, Wakayama Prefecture, Japan (Figure 20).

Etymology. This species is named for Dr. Tetsuo Kuwamura,
collector of the only known specimen.

Comments . My counts for the holotype agree generally with those of
Fukao (1984). The slight differences reflect counts that are difficult
to make and should be considered approximate.

Material examined. Holotype: FAKU 48479 (female: 55 mm SL),
Japan, Wakayama Prefecture, Shirahama, rocky reef on north shore of
Seto Biological Laboratory, 3 m, 4 May 1974.

Cirripectes obscurus (Borodin)

Exallias obscurus Borodin, 1927:1 (Oahu).

Diagnosis . A species of Cirripectes with the following combination
of characters: small scalelike flaps on the anterior part of the
lateral line, pupil-sized dark spots behind each eye, 0-8 lateral line
tubes, and last lateral line tube on caudal-fin base.

206

Description. Dorsal fin XI -XII (XII in 98.0% of specimens) , 15-17
(16 in 92.0%); anal fin 11,16-17 (17 in 95.5%); total procurrent
caudal-fin rays 10-14; pelvic fin 1,4; vertebrae 10 + 21-23 (22 in
95.7%) = 31-33 (32 in 95.7%); last pleural ribs on vertebral centrum
12; last epipleural rib on vertebral centrum 19-22 (19-21 in 97.9%);
anal pterygiophores 1-1-1, 1-1-2, or 1-2-1 (1-1-2 in 58.8%); nuchal
cirri 36-47 (38-44 in 86.4%); supraorbital cirri 10-26 (11-19 in
75.0%); nasal cirri 14-42 (15-42 in 96.0%); LL tubes 0-10 (0-8 in
94.2%); last LL tube on caudal-fin base; irregularly spaced scalelike
flaps along anterior part of LL; lower lip crenulate tnesially (plicate
laterally); gill rakers 26-30 (based on 25 specimens); pseudobranchial
filaments on one side 11-15 (based on 25 specimens); premaxillary teeth
284-315 (based on 11 specimens); dentary teeth 145-158 (based on 11
specimens); upper lip crenulae approximately 41-50; nuchal cirri in two
groups that sometimes overlap at midpoint on nape, no nuchal flaps
(type E; Figure 7); first dorsal-fin spine of adults slightly longer
than second (0.4-2.5 mm longer in males, 0.4-4.5 ran longer in females);
dorsal-fin membrane deeply incised above last dorsal-fin spine;
dorsal-fin membrane attached to caudal peduncle in advance of caudal
fin; cephalic pore system complex ( 6 or more pores at most positions;
Figure 17; number of pores increases with increasing SL); mid-snout
pores present (Figure 17); extra interorbital pore position present
(Figure 17); pore positions behind nuchal flap 2 (Figure 17); male
genital papilla with urogenital orifice located at distal tip of a
slender filament (less than 1.0 mm long) on a fleshy swelling behind
anus (type III; Figure 13); testes elongate, length equals two to three

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times width; maximum SL about 175 mm (based on Randall, 1981);
ophioblennius larvae have not been examined.

The smallest mature female (ova about 0.4 mm diameter) examined was
about 110 mm SL, but females have well-developed ovaries by about 85 mm
SL. Males mature by about 75 mm SL.

Color in alcohol. Adult males (Figure 47) with dark-brown
background color; tiny dark or pale spots over head and anterior half
of body, sometimes over entire body; pupil-sized black spot on each
side of head posterior to eye; all fins dark brown; pectoral fin with
elongate black area at base of upper 3-8 rays; all cirri dark brown to
black.

Adult females and subadults (Figure 48) usually with mottled brown
and pale pattern over head and body, body sometimes with about four to
eight irregular bars, background pattern overlaid with small pale
spots; other color characters as described for males.

Color in life. Similar to color in alcohol except as follows
(based on color slides of a male and female from Hawaii): female head
and body with tiny white spots becoming lavender posteriorly; underside
of head golden brown; dorsal-fin spines red, dorsalmost and ventralmost
caudal-fin rays dusky yellow, middle rays purplish red; anal fin
purplish black with two narrow reddish stripes near middle of fin and
running length of fin; tips of middle pectoral-fin rays dusky yellow,
others brown; nuchal cirri bluish black; nasal and supraorbital cirri
dark brown; iris yellowish. Male similar to female except spots not
present on caudal-fin base; underside of head reddish brown; anal-fin
stripes indistinct and brownish; tips of ventral pectoral-fin rays
reddish brown; iris orange; anal-fin spine rugosities black.

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Comparisons. Cirripectes obscurus and C. alboapicalis are the only
species of Cirripectes with small scalelike flaps on the anterior part
of the lateral line and pupil-sizsd dark spots behind each eye.
Characters differentiating these species are discussed in the account
of C_. alboapicalis .

Distribution. Cirripectes obscurus is known only from the Hawaiian
Islands (Figure 19), where it is usually found on rocky reefs at depths
less than 6 m.

Etymology. The specific epithet, obscurus , is Latin for dark, in
reference to the dark coloration of the holotype.

Nomenclatural discussion. Borodin (1927) based his description of
Exallias obscurus on a single specimen from Hawaii. Fowler (1927)
referred to a previous report (Fowler 1923) of a Hawaiian specimen
identified as Cirripectes alboapicalis and, believing these two species
to be the same, placed Exallias obscurus in the synonymy of C.
alboapicalis . Borodin (1928) indicated several characters that
differentiated the holotypes of the two species and recognized the
Hawaiian form as a distinct species of the genus Cirripectes . Fowler
(1928), without mentioning Borodin (1928), again placed _E. obscurus in
the synonymy of C_. alboapicalis . Schultz (1941) and Chapman (1951)
relegated both of the above names to the synonymy of C. variolosus . My
findings support the conclusion of Strasburg (1956), who recognized all
three of the above names as valid.

Material examined. Types: AMNH 9363 (female: 116 mm SL),
holotype, Hawaiian Islands, Hawaii.

209

Other material examined. Hawaiian Islands, Oahu: ANSP 83819 (1:

36), BPBM UNCAT. (4: 33-107; 19 MAR 1950), BPBM UNCAT. (24: 62-126; 6

OCT 1951), BPBM UNCAT. (15: 61-132; 10 SEP 1951), BPBM 4912 (1), BPBM

10035 (2: 54, 55), BPBM 19581 (12: 58-134), ROM UNCAT. (1), USNM 228158
(1: 86).

Cirripectes perustus Smith

Cirripectus perustus Smith, 1959:238 (Malindi).

Diagnosis. A species of Cirripectes with the dorsal fin entire and
1,3 pelvic-fin rays.

Description. Dorsal fin XI -XII (XII in 98.7% of specimens) , 14-15
(14 in 98.7%); anal fin 11,14-16 (15 in 96.2%); total procurrent
caudal-fin rays 10-12; pelvic fin 1,3; vertebrae 10 + 20-21 (20 in
97.4%) = 30-31 (30 in 97.3%); last pleural ribs on vertebral centrum
11-12 (11 in 98.7%); last epipleural rib on vertebral centrum 15-19
(15-18 in 97.4%); anal pterygiophores 1-1-1, 1-1-2, or 1-2-1 (1-1-2 in
91.0%); nuchal cirri 30-46 (34-42 in 90.6%); supraorbital cirri 6-23
(12-21 in 90.5%); nasal cirri 5-25 (8-17 in 90.5%); LL tubes 0-3 (0-2
in 93.3%); last LL tube positioned at point between verticals from
dorsal-fin ray 5-11 (6-8 in 89.8%); no scalelike flaps along LL; lower
lip smooth mesially (plicate laterally); gill rakers 23-28 (based on 14
specimens); pseudobranchial filaments on one side 8-11 (based on 14
specimens); premaxillary teeth 239-258 (based on 3 specimens); dentary
teeth 105-108 (based on 3 specimens); upper lip crenulae approximately

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36-48; nuchal cirri in 3-4 groups, 3-group condition results from
fusion of bases of dorsalmost groups of cirri at apex of nape, 4-group
condition frequently has dorsalmost groups meeting or overlapping at
apex of nape (type B or D; Figure 7); first dorsal-fin spine of adults
slightly or not longer than second (0-1.5 nm longer in males, 0-1.0 nm
longer in females); dorsal-fin membrane not incised above last
dorsal-fin spine; dorsal-fin membrane attached to caudal fin in adults;
cephalic pore system simple (1-2 pores at most positions; Figure 17);
mid-snout pores present (Figure 17); extra interorbital pore position
absent (Figure 17); two pore positions behind nuchal flap vFigure 17);
male genital papilla with urogenital orifice located basally between
two widely separated slender filaments (less than 1.0 nm long) on a
fleshy swelling behind anus (type I; Figure 13); testes bulbous, length
equals width; maximum SL about 82 mm; ophioblennius larvae have not
been examined.

The smallest mature female (ova about 0.4 mm diameter) examined was
about 45 mm SL. Males matare by about 35 mm SL.

Color in alcohol. Males (Figure 49) with uniformly chocolate-brown
head, body, dorsal fin, and anal fin; caudal fin with pale triangular
area posterodorsally, remainder of fin brown; pectoral and pelvic fins
dusky; rugosities on anal-fin spines creamy white; all cirri dark
brown.

Females (Figure 50) with dark-brown spots (about 1 mm diameter) on
a brown background on head and body; narrow, diagonal, pale bar
extending anteroventrally from nape, along posterior margin of orbit,
onto upper lip; dorsal fin dark brown, with pale basal stripe extending

211

longitudinally along fin; other colors as for males (where
appropriate) .

Color in life. Males (based on color slides of specimens from
Chagos Archipelago) with head and anterior half of body yellow;
posterior half of body reddish brown to brown; segmented dorsal fin,
anal fin, and all but tips (which are orange) of uppermost caudal rays
red; spinous dorsal fin yellow with tips of anterior spines orange;
pectoral fins yellow, tips of about five ventralmost rays red; basal
half of pelvic fins yellow, distal half red; rugosities on anal-fin
spines red; nuchal and nasal cirri reddish brown; supraorbital cirri
red; iris with yellow oval centered around pupil and oriented almost
vertically, remainder of iris silvery white.

Female (based on a color slide of a specimen from Chagos
Archipelago) similar to color in alcohol except: spots on body rusty
brown; tips of dorsal elements reddish orange; caudal-fin rays light
brown with reddish-orange cast; pectoral fin brown, tips of about five
ventralmost rays red; distal half of pelvic fin red; iris color same as
for males.

Comparisons. Cirripectes perustus, C. auritus, and C. chelomatus
are the only Cirripectes species without the dorsal-fin membrane
distinctly incised between spinous and segmented portions (it is
slightly notched in jC. chelomatus ) . Cirripectes perustus differs from
these species primarily in having 1,3 pelvic-fin elements (versus 1,4)
and in the life color pattern.

Distribution. Cirripectes perustus is a widely distributed,
although rarely collected, species occurring from Kenya and Madagascar

212

eastward to Kiribati (Gilbert Islands). It has been collected at
depths ranging from 0 to about 25 m.

Etymology. Smith (1959) did not provide the etymology for the
specific name, but it is probably a combination of the Latin per,
meaning very, and ustus , meaning burn. The name presumably refers to
the bright red and yellow color of the male holotype and paratype.

Comments. Although Cirripectes perustus is widely distributed, I
have found no geographic variation across its range, and very little
variation within populations, in the characters examined.

Randall (1955) reported four specimens identified by Strasburg as
Cirripectes sp. from Onotoa. It was noted that this form was probably
undescribed and was distinctive in lacking a notch between the spinous
and segmented dorsal-fin elements. Although Randall (1955) stated that
Strasburg was working on these specimens, Strasburg did not publish a
description and the species was subsequently described by Smith (1959).

Material examined. Types: RUSI 265 (male: 67 mm SL), holotype,
Malindi, Kenya, 1952; RUSI 517 (male: 70), paratype, Malindi, Kenya.

Other material examined. Kenya: LACM 30859-18 (1: 58).
Madagascar: MNHN (3 specimens collected by L. A. Mauge). Seychelles
Islands, Cosmoledo Group: AMSP 147667 (3: 29-71). Seychelles Islands,
Farquhar Group: MNHN 54-33 (1). Chagos Archipelago: ROM 46587 (1:
52), ROM 46588 (1: 57), ROM 46589 (14: 23-39), ROM 46590 (16: 21-35),
ROM 46591 (1: 47), ROM 46592 (2: 61, 62), ROM 46593 (1: 57), ROM 46594
(3: 57-60), ROM 46595 (2: 55, 61), ROM 46596 (1: 35). Nicobar
Islands: SMF 17079 (2: 32-44), SMF 17080 (1: 54). Philippine
Islands: USNM 228268 (2: 20, 30), USNM 228270 (1: 69), USNM 229270 (1:

213

59), USNM 228272 (2: 56, 62). Taiwan: NTUM 5791 (1: 82). Papua-New
Guinea: USNM 228271 (1: 34). Caroline Islands: CAS UNCAT. (1: 63;
GVF 1912), CAS UNCAT. (1: 47; KAYANGEL ATOLL, 26 AUG 1956), CAS UNCAT.
(2: 56-63; KAYANGEL ATOLL, 8 OCT 1956), CAS UNCAT. (1: 35; SOROL ATOLL,
GVF 993), CAS 38843 (3: 37-45), CAS 38847 (1: 47), CAS 48096 (2: 37,
39), CAS 48942 (1: 52), CAS 48946 (1: 64), CAS 48961 (2: 38, 58), CAS
48971 (3: 51-55). Gilbert Islands: BPBM UNCAT. (2: 61, 64), BPBM
UNCAT. (2: 29, 43).

Cirripectes polyzona (Bleeker)

Salarias (Cirripectes) polyzona Bleeker, 1868:278 (Amboina).
Blennius canescens Garman , 1903:236 (eastern entrance of Mbengha
Passage, Fiji Islands).

Diagnosis . A species of Cirripectes with a complex cephalic
seusory pore system, 1,3 pelvic fin rays, and one pore posterior to the
ventral edge of the ventralmost group of nuchal cirri.

Description. Dorsal fin XI -XIII (XII in 99.2% of specimens) , 13-15
(14 in 96.2%); anal fin 11,14-16 (15 in 97.0%); total procurrent
caudal-fin rays 9-12; pelvic fin 1,3; vertebrae 10 (1 with 9) + 19-20
(20 in 98.2%) - 29-31 (30 in 98.0%); last pleural ribs on vertebral
centrum 11; last epipleural rib on vertebral centrum 15-19 (16-18 in
96.9%); anal pterygiophores 1-1-1, 1-1-2, or 1-2-1 (1-1-2 in 75.4%);
nuchal cirri 32-44 (37-41 in 73.7%); supraorbital cirri 4-15 (6-11 in
85.9%); nasal cirri 5-24 (8-14 in 75.0%); LL tubes 2-9 (4-7 in 77.6%);

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last LL tube positioned at point between verticals from dorsal-fin ray
7 and caudal-fin base (8-13 in 86.7%); no scalelike flaps along LL;
lower lip smooth mesial ly (plicate laterally); gill rakers 18-25 (based
on 27 specimens); pseudobranchial filaments on one side 7-10 (based on
27 specimens); premaxillary teeth 170-191 (based on 8 specimens);
dentary teeth 79-100 (based on 8 specimens); upper lip crenulae
approximately 32-45; nuchal cirri in 4 groups with slightly expanded
nuchal flap (type B; Figure 7); first dorsal-fin spine of adults of
both sexes equal to or slightly (0-3.0 mn) longer than second;
dorsal-fin membrane deeply incised above last dorsal-fin spine;
dorsal-fin membrane attached to caudal fin in adults; cephalic pore
system complex (more than 3 pores at most positions; Figure 17; number
of pores increases with increasing SL); mid-snout pores present (Figure
17); extra interorbital pore position present (Figure 17); pore
positions behind nuchal flap 1 (Figure 17); male genital papilla with
urogenital orifice located basally between two widely separated slender
filaments (less than 1.0 mm long) on a fleshy swelling behind anus
(type I; Figure 13); testes bulbous, width equals length; maximum SL
about 100 ran; ophioblennius larvae with 2 canines posteriorly on each
dentary.

The smallest mature female (ova about 0.5 ran diameter) examined was
about 40 ran SL. Males mature by about 35 mm SL.

Color in alcohol. Ophioblennius stage larvae with body uniformly
pale brown; nasal, orbital, and nuchal cirri brown to dark brown;
blackish spot on each side of lower jaw above lower lip flap, another
spot in groove behind posteriormost end of each maxillary and in groove
above anterodorsal edge of maxillary.

215

Young (18-45 mm SL; Figure 51) have stripe (about one and one-half
pupil diameter in width) extending from above pectoral-fin base to end
of caudal-fin rays, stripe frequently broken, appearing as string of
beads with distinct, rounded spot above pectoral-fin base; area
generally paler above stripe than below.

In sub-adults and adults (25-45 mm SL), lateral body stripe breaks
into about 12 brown bars (each about 3/4 eye diameter); bar above
pectoral-fin base frequently appears as blackish spot; small
cream-colored spots on underside of head; upper lip with reticulated
pattern of pale Hues and spots on brown background; on upper half of
cheek, reticulations develop into barred pattern extending onto nape
(Figure 52).

Color in life. Striped phase (based on a specimen from Eniwetak
Atoll) with pale-yellow spots on underside of head and on operculum,
reddish-brown reticulations on snout, reddish-brown bars on upper cheek
and nape; ventralmost nuchal cirri with narrow yellow-orange band
basally; rest of cirri and their bases dark brown; spot above
pectoral-fin base reddish brown; reddish-brown stripe beginning behind
this spot and becoming black posteriorly; body tan above stripe and
white to lavender below; iris with inner yellow ring and outer red
ring; pectoral fin and upper caudal rays with yellowish tint.

Adults (based on color slides of a male from Eniwetak Atoll and
females from Enewetak, Tutuila, and Chagos Archipelago) similar to
striped phase except reddish-brown reticulations and bars on head more
pronounced; pectoral-fin base with two reddish-brown bars; spot above
pectoral-fin base and subsequent bars purplish black to dark brown;

216

Enewetak male with yellowish interspaces between first 5 bars and
yellow-tinted pectoral and pelvic fins. Females have pale-brown
interspaces between dark-brown bars on body and red-tinted pectoral and
pelvic fins.

Comparisons. Cirripectes polyzona can be differentiated from its
congeners, except C. perustus and C. f ilamentosus , in having three
pelvic-fin rays (versus 4). It is distinguished from _C. perustus and
C. f ilamentosus by its complex pore pattern (versus simple), dark bars
on body (versus uniformly brown or with dark spots), and one pore
position benind nuchal flap (versus two). Cirripectes polyzona is most
frequently confused with specimens of C_. castaneus because of their
similar color patterns, but the latter has 4 segmented pelvic-fin rays
and a simple cephalic pore pattern (Figure 17).

Distribution. Cirripectes polyzona is the most widely distributed
species in the genus (Figure 23). It occurs from South Africa to the
Gulf of Aden eastward to Johnston Atoll and the Line Islands, and from
southern Honshu Island, Japan to the Capricorn-Bunker Group of islands,
Great Barrier Reef, Australia.

Etymology. The specific epithet is derived from the Greek polys ,
meaning many, and the Latin zona, meaning belt. Presumably the name
refers to the barred color pattern of adults.

Comments . No geographic variation was noted for the characters
examined, but secondary sexual dichromatism was found. In life, an
Enewetak Atoll male had yellow-tinted pectoral and pelvic fins, versus
red tinted fins in females. Variation for this character is not known,
as I have not seen life colors for males from other geographic areas.

217

Nomenclatural discussion. Bleeker (1868) described Salarias
(Cirripectes) polyzona based on two specimens from Amboina. The
syntypic series (RMNH 4797) contains three specimens (two females and a
badly damaged male). All three specimens are conspecific, but Bleeker
(1868) appears to have excluded the damaged male from his description.
Chapman (1951) and Schultz and Chapman (1960) erroneously referred S.
(C_. ) polyzona to the synonymy of C_. sebae and gave the type locality of
the latter as East Indies (type locality is unknown for C. sebae) . The
types of these two species are easily distinguished in that C. polyzona
has 1,3 pelvic-fin elements (versus 1,4) and multiple pores at most
cephalic sensory pore positions (versus less than three). See the C.
castaneus account for a discussion of the nomenclatural status of S.
sebae. Schultz and Chapman (1960) were describing specimens of C.
polyzona from the Marshall Islands, not C_. sebae .

Garman (1903) described Blennius canescens based on an
ophioblennius stage larva from Fiji. As the holotype (MCZ 28294) is a
specimen of Cirripectes polyzona, Blennius canescens is referred to the
synonymy of C. polyzona.

Material examined. Types: RMNH 4797 (3 specimens, 43-45 mm SL)
syntypes of Salarias (Cirripectes) polyzona , East Indies, Aroe I.,
Amboina, collected by P. Bleeker; MCZ 28294 (1, 28) holotype of
Blennius canescens, Fiji Islands, Mbengha Passage.

Other material examined. South Africa: BPBM 21772 (1: 29), RUSI
9141 (2). Mozambique: RUSI UNCAT. (2: 45, 50). Tanzania: USNM
227563 (20: 26-52). Gulf of Aden: USNM 227560 (2: 27, 45). Comoros
Islands: CAS 33047 (4), CAS 40374 (1), CAS 40337 (2), CAS 40381 (6),

218

USNM 22766? (4: 33-45). Seychelles, Cosmoledo Group: USNM 227666 (1),
USNM 227684 (1). Seychelles, Amirante Isles: ANSP 126849 (2: 35-40),
ANSP 147660 (1: 38). Agalega Island: USNM 227564 (2 of 3 examined:
33, 36), USNM 227565 (1: 31). Chagos Archipelago: ROM 46598 (6), ROM
46599 (10), ROM 46600 (101), USNM 227562 (2: 48, 53), USNM 227569 (19:
31-57), USNM 227690 (5: 42-56), USNM 227667 (1), USNM 227673 (2), USNM
227683 (5). Maldive Islands: SMF 13590 (3: 40-46). Sri Lanka: USNM
227566 (1 of 2 examined: 46), USNM 227567 (2: 59, 65). Nicobar
Islands: SMF 17082 (1: 41), SMF 17083 (5: 29-47). Cocos (Keeling)
Islands: ANSP 147661 (2: 40, 43), ANSP 147662 (2: 34, 35), ANSP 147663
(2: 34, 44), ANSP 147664 (1: 23), ANSP 147665 (1: 50). Christmas
Island (Indian Ocean): WAM P. 21811 (1: 37), WAM P. 26088-049 (1: 20).
Viet Nam: CAS 48923 (9: 34-51). Taiwan: BPBM UNCAT. (4), USNM 227656
(1: 62), USNM 227664 (2: 51, 52), USNM 227670 (83: 23-69), USNM 227676
(6), USNM 227679 (7), USNM 227680 (15). Japan: FAKU 48270 (1: 20),
FAKU 48273 (1: 24), FAKU 4830 (1: 23), FAKU 49174 (2: 35, 60), FAKU
111457 (1: 19). Philippine Islands: LACM UNCAT. (1), LACM 42479-20
(1), USNM 224945 (2: 36-50), USNM 227620 (7: 30-56), USNM 227621 (1:
43), USNM 227622 (8: 32-42), USNM 227671 (2), USNM 227674 (15), USNM
227677 (28), USNM 227682 (25), USNM 227686 (1), USNM 227687 (2), USNM
227688 (12). Indonesia: AMS 1.19875-071 (90), BMNH 1858.4.21.83 (1),
RMNH 20226 (4: 23-34), USNM 227624 (15: 17-55), USNM 227662 (5:
17-24). Netherland Indies: USNM 227618 (4: 43-49). Papua-New
Guinea: USNM 227361 (2: 18, 19), USNM 227660 (13: 25-44), USNM 227665
(1: 19). Louisiade Archipelago: USNM 227661 (5: 41-48). Trobriand
Islands: AMS 1.17094-066 (15), BMNH 1974.5.25.3579-3582 (4), USNM

219

227C59 (150 +: 18-50). Solomon Islands: BPBM 5947 (1: 35), CAS 48966
(1). Australia, Queensland: AMS 1.19473-099 (1: 58), AMS 1.19483-014
(9: 26-54), AMS 1.20770-100 (1: 41), AMS 1.21422-145 (4: 32-51), USNM
227626 (6: 42-58), USNM 227689 (1). Mariana Islands: UF 31444 (1:
20). Caroline Islands: CAS 38822 (3), CAS 48898 (1), CAS 48909 (2),
CAS 48924 (2), CAS 48934 (8), CAS 48952 (14), USNM 223369 (4: 37-47),
USNM 227631 (13: 20-41). Marshall Islands: BPBM UNCAT. (17: 18-55),
BPBM UNCAT. (1), BPBM 8173 (6), BPBM 15522 (2), GCRL 3984 (6), LACM
6674-100 (1), LACM 6674-101 (3), LACM 6679-38 (23), LACM 6679-39 (23),
LACM 7279 (1: 51), LACM 7422 (2: 53, 63), USNM 227657 (6: 44-59), USNM
227568 (4: 46-58), USNM 227669 (1). Gilbert Islands: AMS 1.18045-23
(1), AMS I. 18052-022 (69), BPBM 10645 (11), BPBM 15320 (3), BPBM 15361
(12). Rotuma Island: USNM 227625 (1: 47). Fiji Islands: USNM UNCAT.
(2), USNM 227675 (1). Tonga Islands: USNM 227623 (29: 27-59). Samoa
Islands: BPBM 11311 (2), UF 31445 (10), UF 31449 (18), USNM 52294 (1:
37), USNM 126227 (2: 43, 46). Phoenix Islands: USNM 227627 (1: 46),
USNM 227658 (2: 19,19), USNM 227668 (1), USNM 227681 (3). Howland
Island: USNM 227678 (3). Baker Island: USNM 227672 (1). Line
Islands: ANSP 64316 (1: 41), ANSP 64321 (1: 38), BPBM UNCAT (6), BPBM
UNCAT. (3), BPBM 15372 (20), BPBM 25204 (14), CAS UNCAT. (16: 21-45),
USNM 227685 (5). Johnston Atoll: USNM 227551 (20: 26-54).

Cirripectes quagga (Fowler and Ball)

Rupiscartes quagga Fowler and Ball, 1924:273 (Wake Island).
Cirripectus lineopunctatus Strasburg, 1956:248 (Oahu, Hawaii).

220

Diagnosis . A species of Cirripectes with the following combination
of characters: lower lip crenulate mesially, last pleural ribs on
vertebral centrum 12, 15 segmented dorsal-fin rays, 16 segmented
anal-fin rays, 21 caudal vertebrae, and no scalelike flaps along
anterior portion of lateral line.

Description. Dorsal fin XI -XIII (XII in 98.9% of specimens), 14-16
(15 in 92.5%); anal fin 11,15-17 (16 in 90.0%); total procurrent
caudal-fin rays 10-15 (1 with 15); pelvic fin 1,4; vertebrae 10 + 20-22
(21 in 95.1%) = 30-32 (31 in 95.1%); last pleural ribs on vertebral
centrum 11-12 (12 in 91.5%); last epipleural rib on vertebral centrum
19-24 (20-23 in 99.1%); anal pterygiophores 1-1-1, 1-1-2, or 1-2-1
(1-1-2 in 84.8%); nuchal cirri 23-36 (26-23 in 95.6%); supraorbital
cirri 2-15 (2-12 in 96.9%); nasal cirri 6-16 (8-14 in 96.2%); LL tubes
7-18 (10-18 in 94.5%); last LL tube positioned at point between
verticals from dorsal-fin ray 7 and caudal-fin base (11 to caudal-fin
base in 94.8%); no scalelike flaps along LL; lower lip crenulate
mesially (plicate laterally); gill rakers 18-26 (based on 150
specimens); pseudobranchial filaments on one side 7-9 (based on 150
specimens); premaxillary teeth 152-190 (based on 26 specimens); dentary
teeth 72-97 (based on 26 specimens); upper lip crenulae approximately
32-46; nuchal cirri in two groups separated ac mid-point of nape, no
nuchal flap (type E; Figure 7); first dorsal-fin spine of adults longer
than second (0.3-9.2 mn longer in males, 0-5.8 nm lunger in females);
dotsal-fin membrane deeply incised above last dorsal-fin spine;
dorsal-fin membrane attached to caudla peduncle in advance of caudal
fin; cephalic pore system complex ( 3 or more pores at most positions;

221

Figure 17; number of pores increases with increasing SL); mid-snout
pores present (Figure 17); extra interorbital pore position present
(Figure 17); two pore positions behind nuchal flap (Figure 17); male
genital papilla with urogenital orifice located basally behind a single
slender filament (less than 1.0 mm long) on a fleshy swelling behind
anus (type IV; Figure 13); testes elongate, width equals about half
length; maximum SL about 74 mm; ophioblennius larvae with two canines
posteriorly on each dentary.

The smallest mature female (ova about 0.5 mm diameter) examined was
about 34 mm SL. Males mature by about 35 nm SL.

Color in alcohol. Ophioblennius stage larvae (about 25-35 mm SL)
with pale-brown head and body; head with several short, wavy, brown
spots on cheeks; about 3 brown bars between each orbit and upper lip;
pupil-sized dark-brown spot on posterior part of lower lip on each
side, and at symphyses of dentary bones and premaxillary bones,
premaxillary symphyseal spot extending into vomerine region inside
mouth; body with faint indications of brown bars; fins dusky; all cirri
brown.

Juveniles and adults of both sexes show extreme variability in body
color pattern, both within and among populations (Figures 53, 54, and
55). Head with pale- and dark-brown bars usually present, sometimes
broken into spots; ocellated spot occasionally present on opercle;
pattern on underside of head varying from uniformly brown to presence
of one to three dark-brown bars with pale interspaces; posterior edge
of branchiostegal membrane with pale margin, frequently preceded by a
brown bar extending between ventral margins of opercles; body

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pigmentation variable: some specimens with uniformly dark-brown body;
some with about 12-14 dark-brown bars with pale interspaces, each pale
interspace frequently reduced to vertical row of small pale spots
(about 1 mm diameter); others with pale area posteriorly on body from
beneath dorsal-fin ray 11-13 to caudal-fin base, bordered anteriorly by
one or two broad dark-brown bars on dorsal half of body; dorsal fin
with tips of anterior spines pale, remainder of fin brown; caudal fin
with distal half of upper (and sometimes lower) rays pale, remainder of
fin brown; anal fin dark brown; anal-fin spine rugosities pale to
brown; pectoral fin with dark-brown band on tips of ventralmost rays,
remainder dusky; pelvic fin dusky; nuchal cirri brown to black; nasal
and supraorbital cirri brown.

Color in life. Adult coloration (based on color slides of
specimens from Chagos Archipelago, Samoa, Marshall Islands, Hawaiian
Islands, Marquesas Islands, and Henderson Island) is similar to that in
alcohol except as follows: tips of anterior dorsal-fin spines and
caudal-fin rays yellow to orange; pale (unpigmented) area on caudal
peduncle of preserved specimens yellow or scarlet in life; Marquesan
specimens with red bar on chin and short red bar on branchiostegal
membranes immediately anterior to pelvic-fin bases; iris black with
irregularly shaped yellow inner ring; supraorbital cirri yellowish
brown; other cirri brown.

Comparisons. Cirripectes quagga , C. jenningsi , C_. obscurus , and _C.
alboapicalis differ from all other Cirripectes in having lower lip
crenulate mesially, and last pleural ribs on vertebral centrum 12.
Cirripectes quagga differs from C. obscurus and C. alboapicalis in

223

having 15 (versus 16) segmented dorsal-fin rays, 16 (versus 17)
segmented anal-fin rays, 21 (versus 22) caudal vertebrae, and no
scalelike flaps along anterior portion of lateral line (versus flaps
present). Cirripectes quagga and £. jenningsi are differentiated in
the account of C_. jenningsi ♦

Distribution. Cirripectes quagga is widely distributed throughout
the Indian and Pacific Oceans (Figure 24). In the Indian Ocean, it is
known from South Africa to Tanzania eastward to Cocos (Keeling) Islands
and northward to southern India and Sri Lanka. In the Pacific, it
occurs from China to the Great Barrier Reef eastward to Henderson
Island and the Hawaiian Islands. Although usually taken on reefs in
water less than 10 m deep, C_. quagga has been collected at depths as
great as 19 m in the Marquesas Islands.

Etymology. The specific epithet, quagga, is of Hottentot origin
and refers to an extinct species of Equus , related to zebra, sometimes
used to mean zebra (V. G. Springer, pers. comm) . Fowler and Ball
(1924) provided the following etymology: "Quagga, with reference to
the rather obscure cross lines or bands."

Comments . Cirripectes quagga exhibits geographic variation in
color pattern. The presence of a scarlet-colored caudal peduncle is
known to occur only on Henderson Island females. The yellow-peduncle
occurs on both males and females at numerous Pacific localities and Sri
Lanka. The barred and/or spoi_ted forms are the most frequently
collected morphs and occur sympatrically with the other morphs .
Although the barred and/or spotted versus colored-peduncle color morphs
appear strikingly different in life, specimens taken at the same

224

collecting station exhibit a broad range of color patterns intermediate
between the colored-peduncle morphs and the barred and/or spotted
morphs. As none of the o.:her characters I examined show any
differences correlated with a particular color morph, I believe the
morphs reflect individual variants of a single highly variable species,
C. quagga.

Nomenclatural discussion, Strasburg (1956) based his description
of Cirripectes lineopunctatus on a holotype, paratypes and non-types
from the Hawaiian Islands, and ten non-type specimens from Johnston
Island. He differentiated C_. lineopunctatus from C^ quagga op the
basis of several color-pattern characters including presence of spots
versus stripes, a minor tendency to have higher dorsal- and anal-ray
counts, and a lower mean number of nuchal cirri. I have found
specimens of C. quagga with the same color-pattern characters as the
Hawaiian specimens at numerous other localities. There are also many
specimens of C. quagga with color patterns intermediate between the
barred and spotted patterns. I found no differences in fin-ray or
nuchal-cirri counts between the Hawaiian specimens and those from other
localities. In the absence of any differences characteristic of the
Hawaiian Islands specimens, I place C. lineopunctatus in the synonymy
of C_. quagga.

Material examined. Types: ANSP 91013 (9 specimens: 33-47),
paratypes of Rupiscartes quagga, Wake Island; ANSP 91191 (10: 33-51),
paratypes of Rupiscartes quagga , same data as ANSP 91013; USNM 164198
(male: 58 mm SL) , holotype of Cirripectus lineopunctatus, Hawaiian
Islands, Oahu, Kaena Point; USNM 164199 (8: 28-69), paratypes of

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Cirripectus lineopunctatus, same data as holotype; USNM 164200 (6:
36-62), paratypes of Cirripectus lineopunctatus , Hawaiian Islands,
Oahu, Hanauma Bay; USNM 164201 (4 of 5 examined: 28-44), paratypes of
Cirripectus lineopunctatus, Hawaiian Islands, Oahu, Makapuu Point.

Other material examined. South Africa: RUSI UNCAT. (1: 26; OUT OF
RUSI 77-16), RUSI 77-20 (1: 45). Tanzania: USNM 227755 (1: 54).
Comoros Islands: CAS 33249 (1: 25), CAS 33427 (5: 31-56), CAS 33768
(2: 31, 34). Cargados Carajos Shoals: USNM 227749 (1: 55). Agalega
Islands: USNM 227752 (1: 38). Reunion Island: BPBM 20059 (3:
61-74). Chagos Archipelago: ROM 46608 (6), USNM 22/751 (1: 35), USNM
227756 (4: 36-49), USNM 227760 (1: 39), USNM 227761 (2: 35, 36), USNM
227767 (16: 34-63). India: ANSP 146113 (1: 24). Sri Lanka: USNM
227766 (1: 45). Cocos-Keeling Islands: ANSP 134746 (2: 25, 27), ANSP
134759 (5: 34-57). Indonesia: AMS 1.19875-093 (1: 44). China: CAS
48893 (1: 27). Taiwan: USNM 27754 (7: 45-57). Australia,
Queensland: AMS 1.5023 (1: 49). Fiji Islands: ROM UNCAT. (31; WE
83-67). Mariana Islands: CAS 38849 (10), CAS 38851 (1: 40), CAS 38852
(6), CAS 48911 (1). Caroline Islands: CAS UNCAT. (1: 40), CAS UNCAT.
(8: 34-43; GVF 76), CAS 48905 (22: 26-56), CAS 48938 (1: 49), CAS 48950
(1), CAS 48967 (16). Marshall Islands: BPBM 18413 (7 of 10: 36-54),
GCRL 4389 (3), LACM 4033 (1: 47), LACM 6674-102 (3: 37-51), LACM
6679-40 (31), UF 9935 (3), USNM 227559 (2: 42-45), USNM 227762 (2: 38,
42), USNM 22/763 (18: 36-64). Gilbert Islands: BPBM 15327 (2: 47,
53), USNM 167331 (4). Howland Island: USNM 227771 (291 34-71). Baker
Island: USNM 227759 (1: 42). Phoenix Islands: USNM UNCAT. (12 of
100+: 30-49; F-437), USNM 227632 (1: 54), USNM 227750 (2: 57, 60), USNM

226

227757 (19: 28-59), USNM 227768 (5: 28-31). Samoa Islands: OF UNCAT.
(7 of 62: 28-43; DICK WASS), UF 31448 (4). Tonga Islands: USNM 227753
(7: 30-53). Cook Islands: CAS UNCAT. (5: 40-62). Society Islands:
BPBM 10811 (1: 40), CAS UNCAT. (24: 28-55; GVF 21). Line Islands:
BPBM UNCAT. (1; 21 NOV 1953), USNM 227758 (1: 42), USNM 227765 (2 of 3:
38-57), USNM 227770 (24: 31-74), USNM 227772 (2: 36, 55). Tuamotu
Archipelago: BPBM UNCAT. (8: 38-55; 15 MARCH 1956), BPBM UNCAT. (27:
47-67;NO DATE), BPBM 14015 (8), CAS UNCAT. (2: 48, 49; 9 JULY 1952),
USNM UNCAT. (4; 15 MARCH 1956). Marquesas Islands: AMS 1.22017-016
(10), BPBM UNCAT. (10: 26-55; 19 APRIL 1971), BPBM UNCAT. (2: 30-53;17
JULY 1957), BPBM 12103 (1: 69), BPBM 12111 (15: 28-52), BPBM 12144 (15:
25-61), BPBM 12396 (28 of 29: 27-56), BPBM 12586 (8: 37-51), BPBM 12587
(2), BPBM 12654 (4). Henderson Island: BPBM 17070 (10: 29-46).
Marcus Island: BPBM 7156 (24). Wake Island: ANSP 65631-37 (7:
31-40), BPBM UNCAT. (28; JULY 1923), CAS 48970 (1). Johnston Island:
ANSP 65598-602 (5: 39-52), BPBM 4924 (14), USNM 142115 (7), USNM 227550
(13: 31-63). Hawaiian Islands: BPBM 19580 (3).

One lot of 24 specimens (USNM 227764), cataloged as being from
Aldabra Atoll, probably has erroneous collection data. These specimens
were mixed with specimens of Cirripectes jenningsi and C. variolosus ,
which are otherwise known only from the Pacific Plate.

Cirripectes randalli new species

Diagnosis . A species of Cirripectes with the following combination
of characters: complex cephalic sensory pore system, extra

227

interorbital pore postion present (Figure 17), 36-42 nuchal cirri, last
epipleural rib modally on vertebral centrum 19, body covered with small
brown spots.

Description. Dorsal fin XII, 14-15 (14 in 8 of 9 speicmens); anal
fin 11,15-16 (15 in 8 of 9); total procurrent caudal-fin rays 10-12;
pelvic fin 1,4; vertebrae 10+20=30; last pleural ribs on vertebral
centrum 11; last epipleural rib on vertebral centrum 18-20; anal
pterygiophores 1-1-1, 1-1-2, or 1-2-1 (1-1-2 in 8 of 9); nuchal cirri
36-42; supraorbital cirri 12-26; nasal cirri 10-18; LL tubes 1-7; last
LL tube on caudal-fin base; no scalelike flaps along LL; lower lip
smooth mesially (plicate laterally); gill rakers 26-27 (based on 7
specimens); pseudobranchial filaments on one side 7-11 (based on 8
specimens); premaxillary teeth 200-213 (based on 2 specimens); dentary
teeth 107-123 (based on 3 specimens); upper lip crenulae approximately
36-43; nuchal cirri in four groups with ventralmost group of cirri
borne on a slightly expanded nuchal flap (type B; Figure 7); adults
with first dorsal-fin spine slightly longer than second (4.6 mm longer
in males, 0.5-2.0 mm longer in females); dorsal-fin membrane deeply
incised above last dorsal-fin spine; dorsal-fin membrane attached to
caudal fin in adults; cephalic pore system complex (6 or more pores at
most positions; Figure 17; number of pores increases with increasing
SL); mid-snout pores present (Figure 17); extra interorbital pore
position absent (Figure 17); pore positions behind nuchal flap 2
(Figure 17); male genital papilla with urogenital orifice located
basally between two widely separated slender • filaments (less than 1.0
mm long) on a fleshy swelling behind anus (type I; Figure 13); testes

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bulbous, length equals width; maximum SL abort 107 nm; ophioblennius
larvae not known.

The smallest mature female (ova about 0.5 nm diameter) examined was
about 85 mm SL. Ovaries were granular in 47 and 77 nm SL females.

Color in alcohol. A young female (47.4 mm SL) from Mauritius has
pupil-sized dark-brown spots on a brown background over body; head with
small pale spots on cheeks and snout, about 8 narrow pale bars on upper
lip, background color brown; dorsal fin with pale triangular area
distally on anterior spines, two lines of faint brown spots extending
length of dorsal fin, one lir.c of spots at base, another along middle
of fin; caudal fin with pale triangular area distally on dorsalmost
rays, remainder of fin dusky; anal fin with dark-brown sub-marginal
line, remainder of fin dusky; pectoral and pelvic fins brown; nuchal
cirri black; supraorbital and nasal cirri dark brown.

Adult females (Figure 56) have dense covering of pupil-sized
dark-brown spots over body, overlaid on a background of about six to
eight slightly irregular, broad, brown bars and pale interspaces (about
half width of bars); spots extending onto basal half of all fins;
background color of head brown with faint brown diagonal bar extending
from nape to posterior part of upper lip; head and throat covered with
small dark-brown to pale spots (about half pupil diameter in width),
8-10 narrow bars (pale or dark brown) on upper lip; other colors as
described for young female.

Adult male (based on a specimen from Cargados oarajos Shoals;
Figure 57) similar to females except: body background color uniformly
dark brown, spots not as on females; head dark brown with few scattered

229

pale spots on cheeks and narrow pale bars on upper lip; body spots do
not continue onto dorsal, caudal, and anal fins.

Color in life. Adult female (based on a color slide of a freshly
dead Mauritius specimen) with reddish-brown spots on head; body spots
dark brown; dorsal-fin rays with orange tips; tips of dorsalmost
caudal-fin rays yellowish orange; supraorbital and nasal cirri
yellowish brown; color of iris orange, but appears to be faded; other
colors as described for females in alcohol.

Life colors of males unknown, but probably similar to those of the
female described above.

Comparisons. In the western Indian Ocean, the color pattern of
Cirripectes randalli resembles that of female C^ gilberti and female C_.
perustus. Cirripectes perustus differs from _C. gilberti and _C.
randalli in having pelvic-fin rays 1,3 and a simple cephalic sensory
pore system. Cirripectes randalli differs from _C. gilberti in lacking
an interorbital pore postion (present in C_. gilberti) and in having
36-42 nuchal cirri (versus 50-59). Cirripectes randalli is also
similar to the Western Australian _C. hutchinsi, but differs in that
male C. hutchinsi do not have spots covering the body and females have
spots restricted to the ventral half of the head and, usually,
midlateral region of body. There is also a modal difference in the
position of the last epipleural rib, on vertebral centrum 19 in C_,
randalli and 18 in C. hutchinsi , but the range of variation for this
character in the latter species includes thdt of the former. These two
species also have allopatric distributions, with C^. hutchinsi known
only from the southeastern Indian Ocean.

230

Distribution. Cirripecte? randalli is known only from Mauritius
and Cargados Carajos Shoals in the western Indian Ocean (Figure 22).
Of the nine known specimens of this species, the eight females were
collected at Mauritius and the male at Carados Carajos Shoals. It is
known to inhabit rocky shores at depths of 0-1 m at Mauritius and
depths as great as 7.5 m at Cargados Carajos Shoals.

Etymology. This species is named for Dr. John E. Randall in
recognition of his many contributions to tropical marine ichthyology.

Material examined. Holotype: USNM 227873 (male: 92 mm SL),
Cargados Carajos Shoal, 16° 26' S, 059° 36' E, coral patch in surge
channel about 100 yds. off Raphael on west side, fossil coral rock
patch with young corals, vertical undercut, many small caves - blind
surge channel, 0-25 ft. (0-7.6 m) .

Paratypes: RUSI 74-99 (1: 47), Mauritius, La Preneuse, surge
channel, 8 Mar. 1971; RUSI 22306 (1: 79), Mauritius, collection date
unknown; BPBM 20165 (6: 77-107), Mauritius, Trou d'Eau Douce and
Palmar, rocky shore, light surf, 0-1 m.

Cirripectes springeri new species

Diagnosis ♦ A species of Cirripectes with the following combination
of characters: no mid-snout pores, type I male genital papilla (Figure
13), 31 vertebrae, and small spots on the body.

Description. Dorsal fin XII-XIII (XII in 97.8% of specimens) , 14-16
(15 in 95.7%); anal fin 11,15-17 (16 in 93.6%); total procurrent
caudal-fin rays 10-12 (one specimen has 13); pelvic fin 1,4; vertebrae

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10-11 (10 in 97.8%) + 20-21 (21 in 93.3%) = 30-31 (31 in 95.6%); last
pleural ribs on vertebral centrum 11; last epipleural rib on vertebral
centrum 16-19 (17-18 in 90.9%); anal pterygiophores 1-1-1, 1-1-2, or
1-2-1 (1-1-2 in 84.4%); nuchal cirri 27-38 (29-36 in 93.3%);
supraorbital cirri 2-9 (5-7 in 84.7%); nasal cirri 5-23 (6-23 in
97.9%); LL tubes 0-5 (1-5 in 97.0%); last LL tube positioned at point
between verticals from dorsal-fin ray 2-8 (3-6 in 88.1%); no scalelike
flaps along LL; lower lip smooth mesially (plicate laterally); gill
rakers 23-30 (based on 46 specimens); pseudobranchial filaments on one
side 7 -8 (based on 46 specimens); premaxillary teeth 187-227 (based on
11 specimens); dentary teeth 91-122 (based on 11 specimens); upper lip
crenulae approximately 36-47; nuchal cirri in four groups with a small
nuchal flap bearing ventralmost cirri (type B; Figure 7); first
dorsal-fin spine of adults longer than second (4-20 mm longer in males,
2-7 mm longer in females); dorsal-fin membrane deeply incised above
last dorsal-fin spine; dorsal-fin membrane attached to caudal fin in
adults; cephalic pore system simple (1-2 pores at most positions;
Figure 17); mid-snout pores absent (Figure 17); extra interorbital pore
position absent (Figure 17); two pore positions behind nuchal flap
(Figure 17); male genital papilla with urogenital orifice located
basally between two widely separated slender filaments (less than 1.0
mm long) on a fleshy swelling behind anus (type I; Figure 13; one
aberrant specimen with 3 filaments); testes bulbous, length equals
width; maximum SL about 70 Uiin; ophioblennius larvae with two canines
posteriorly on each dentary.

232

The smallest mature female (ova about 0.4 mm diameter) examined was
about 40 nm SL. Males mature by about 40 mm SL.

Color in alcohol. Ophioblennius stage larvae (based on a 17.9 nm
SL larva from Great Banda Island) with uniformly brown head and body;
fins dusky; nuchal and supraorbital cirri dark brown; nasal cirri
brown.

Juveniles, subadults, and adults of both sexes with chocolate-brown
head and body covered with spots (0.5-1.0 nm diameter), spots on head
and anterior quarter of body pale, becoming dark brown posteriorly;
dorsal fin dark brown, all but posteriormost 4-6 rays with pale tips;
caudal fin dark brown with translucent triangular area distally on
dorsalmost 3-4 rays; anal and pelvic fins dark brown; pectoral fin dark
brown with small pale spots on basal quarter of fin (Figure 58).

Color in life. Adults (based on a color slide of a freshly dead
adult male from Sumilon Island, Philippines) with orangish-red spots on
anterior half of fish and basally on pectoral fin; tips of dorsal-fin
elements and upper caudal-fin rays orangish red; iris red; other colors
as in alcohol.

Comparisons. Cirripectes springeri , C_. chelomatus , and C^
f ilamentosus are the only Cirripectes species that do not have
mid-snout pores as adults. Cirripectes f ilamentosus and C. chelomatus
both differ from _C. springeri in having a type II male genital papilla
(versus type I), and 30 vertebrae (versus 31). Cirripectes springeri
and C. chelomatus have allopatric geographic distributions.
Cirripectes springeri also differs from the sympatric C. f ilamentosus
in having spots on the body (versus uniformly brown body, rarely with a
few pale spots or bare above pectoral-fin base).

233

Distribution. Cirripectes springeri is known to occur in the
Solomon Islands, Bismarck Archipelago, Ninigo Islands, Moluccas, and
Philippines (Figure 26). It has been collected at depths as great as
18 m in the Ninigo Islands, but most specimens were collected from
water shallower than 10 m.

Etymology. Cirripectes springeri is named after Victor G.
Springer, in recognition of his contributions to blennioid systematics.

Material examined. Ho lo type: BPBM 22121 (male: 54 ran SL),
Philippine Islands, Sumilon Island, west side, outer reef flat on live
coral, 2 m, 25 Aug. 1981.

Paratypes: AMS 1.18469-174 (1: 56), Indonesia, Ceram, Marsegoe
Bay, 03° 00' 30" S, 128° 03' 18" E, 0-8 m, 1 April 1975; CAS 48956
(2: 37, 49), Solomon Islands, New Georgia, outer reef of Wana-Wana
Island, Blackett St., 25 June 1944; USNM 210166 (1: 20), Molluccas
Islands, Ceram, Tandjun Liang, east shore, Piru Bay, 0-1 m, 10 Jan.
1973; USNM 227617 (1: 51), Netherlands Indies, collection date unknown;
USNM 228283 (1: 43), Bismarck Archipelago, New Britain, 04° 14' 05"
S, 152 10' 25" E, Dawapia Rocks (Beehives) near entrance to Simpson
Harbor, Rabaul , 27 Feb. 1965; USNM 228284 (2: 22, 39), Philippine
Islands, Southern Negros Oriental, Port Siyt , 09° 04' N, 123° 10'
48" E, 0-3.1 m, 28 April 1979; USNM 228285 (7: 18-60), Iloluccas, Banda
Island, Indonesia, 04° 32' 50" S, 129° 54* E, north shore of Great
Banda, island directly south of Naira Island, 0-10 ft (0-3 m) . 8 Mar.
1974; USNM 2?8286 (1: 42), Papua-New Guinea, Umboi Island, in lee of
Higgins Point, 06° 41' 54" S, 147°53' 06" E, 0-4.5 m, 18 June 1979;
USNM 228287 (8: 8), Phillipine Islands, Siquijor Island, near Tonga

234

Point, 09° 13' 30" N, 123° 28' E, 0-1.2 m, 15 Mar. 1979; USNM
228288 (1: 30), Phillipine Islands, west side of Solino (Selinog)
Island, Zamboanga del Norte, Mindanao, 08° 51' 24" N, 123° 24' 36"
E, 0-4.5 m, 3 May 1979; USNM 228289 (1: 32), Papua-New Guinea, Madang
Harbor, south end of Massas Island, 5-15 ft (1.5-4.5 m) , 1 June 1970;
USNM 228290 (2: 44, 53), Papua-New Guinea, Madang Harbor, off southern
edge of Massas Island, 10-45 ft (3-13.7 m) , 31 May 1970; USNM 228292
(6: 45-54), Papua-New Guinea, Madang Harbor, off southern edge of
Massas Island, 35-45 ft (10.7-13.7 a), 26 May 1970; USNM 228293 (1:
26), Papua-New Guinea, Kranket Island, lagoon on northwest side, 05°
11' 30" S, 145° 50' 42" E, 0-0.9 m, 7 Nov. 1978; USNM 228294 (10:
23-49), Papua-New Guinea, Madang Harbor, southern tip, 05° 10' 18" S,
145° 51' 24" E, 0-18.3 m, 6 Nov 1978; USNM 228297 (1: 57), Papua-New
Guinea, Ninigo Islands, southeast of Ami Island, 01 14' S, 144°
22' E, 0-6 m, 22 Oct. 1978.

Cirripectes stigmaticus Strasburg and Schultz

Cirripectes stigmaticus Strasburg and Schultz, 1953:132 (Rongerik

Atoll, Marshall Islands).
Cirripectes cruentus Smith, 1959:238 (Pinda) .

Diagnosis . A species of Cirripectes with the following combination
of characters: simple cephalic sensory pore system, no extra
interorbital pore position (Figure 17), 15 segmented dorsal-fin rays,
16 segmented anal-fin rays, 21 caudal vertebrae, and one pore behind
the vcr.tralmost group of nuchal cirri on each side.

235

Description. Dorsal fin XI -XIII (XII in 98.6% of specimens) , 14-16
(15 in 95.3%); anal fin 11,15-17 (16 in 96.2%); total procurrent
caudal-fin rays 10-14; pelvic fin 1,4; vertebrae 10 + 20-22 (21 in
94.6%) = 30-32 (31 in 94.6%); last pleural ribs on vertebral centrum
11; last epipleural rib on vertebral centrum 17-21 (18-19 in 87.0%);.
anal pterygiophores 1-1-1, 1-1-2, and 1-2-1 (1-1-2 in 86.1%); nuchal
cirri 34-47 (34-40 in 87.2%); supraorbital cirri 7-22 (7-14 in 81.4%);
nasal cirri 8-29 (10-21 in 76.7%); LL tubes 1-10 (3-8 in 89.7%); last
LL tube positioned at point between verticals from dorsal-fin ray 7 and
caudal-fin base (9-15 in 81.4%); no scalelike flaps along LL; lower lip
smooth mesially (plicate laterally); gill rakers 23-30 (based on 34
specimens); pseudobranchial filaments on one side 7-12 (based on 34
specimens); premaxillary teeth 221-248 (based on 3 specimens); dentary
teeth 114-123 (based on 3 specimens); upper lip crenulae approximately
35-52; nuchal cirri in four groups, ventralmost group of cirri on each
side borne on a slightly expanded nuchal flap (type B; Figure 7); first
dorsal-fin spine of adults slightly longer than second (0.2-12.0 mm
longer in males, 0-2.2 mm longer in females); dorsal-fin membrane
deeply incised above last dorsal-fin spine; dorsal-fin membrane
attached to caudal fin in adults; cephalic pore systeui simple (1-3
pores at most positions; Figure 17); mid-snout pores present (Figure
17); extra interorbital pore position absent (Figure 17); pore
positions behind nuchal flap 1 (Figure 17); male genital papilla with
urogenital orifice located basally between two widely separated slender
filaments (less than 1.0 mm long) on a fleshy swelling behind anus
(type I; Figure 13); testes bulbous, length equals width; maximum SL

236

about 100 mm; ophioblennius larvae with two canines posteriorly on each
dentary.

The smallest mature female (ova about C.5 mm diameter) examined was
about 45 mm SL. Males mature by about 35 mm SL.

Color in alcohol. Small ophioblennius stage larvae (based on an
18.8 mm SL specimen from the Gilbert Islands) with dark-brown pigment
spot on each side of lower lip above small lip flap; pale bar extending
from midventral margin of orbit to and over posterior fourth of upper
lip on each side; tip of snout densely covered with melanophores ;
remainder of head and body with uniformly distributed melanophores.

Large ophioblennius stage larvae (based on a 24.6 mm SL specimen
from Tanzania) with 3-4 faint brown bars on head and about 11-12 faint
brown bars on body (brown bars are narrower than cream-colored
interspaces); other colors same as smaller larva.

Juvenile and adult females (Figure 59) with a reticulated pattern
of pale spots enclosed by wavy brown lines over head and anterior half
of body; posterior half of body with dark-brown spots, sometimes fusing
into irregular bars, on a paler-brown background; pectoral-fin base and
proximal ends of rays with pale spots on a brown background;
transluscent triangular area distally on antetior dorsal-fin spines and
dorsalmost caudal-fin rays, otherwise, fins dusky; nasal and
supraorbital cirri dark brown; nuchal cirri black.

Juvenile and adult males (Figure 60) similar to females except as
follows: body from beneath middle of spinous-dorsal fin to end of
dorsal-fin base with small white spots (about 1.0 mm diameter) that
frequently fuse into irregular wavy bars; rugosities on anal-fin spines
dark brown.

237

Color in life. Females (based on color slides of living and
freshly dead specimens from Fiji and Queensland, Australia) with head
and anterior half of body with rust-colored reticulations enclosing
pale-olive spots; at about mid body, spots becoming larger and less
defined, and reticulations beginning to break apart; near caudal-fin
base, reticulations reduced to several brown spots and short wavy lines
on yellowish-brown background; tips of dorsal-fin spines and rays
yellowish orange, most elements with red line on basal third, remainder
of fin yellowish brown; caudal fin yellow basally with dorsalmost and
ventralmost rays orange and distal half of other rays yellowish orange;
anal fin dusky brown with two longitudinal red lines, one located
outward from fin base at distance of about one-third and other at about
two-thirds length of each element; nuchal cirri black with yellow bar
basally on each cirrus in ventralmost group; iris with narrow yellow
ring around pupil, irregular red ring around outer edge, and black area
between them; other colors as in alcohol.

Males (based on color slides of fr°shly dead specimens from
Queensland, Australia, New Caledonia, Fiji, Samoa, and the Gilbert
Islands) with dark-brown background color on head and body;
reddish-brown reticulations overlaid on head and anterior half of body;
posterior half of body with scarlet spots and wavy lines; tips of
anterior dorsal-fin spines yellowish orange; scarlet spots and lines of
body extending onto basal fourth of segmented-dorsal fin, above these,
rays scarlet, becoming into yellowish orange at tips, membranes brown;
tips of drosal and ventral caudal-fin rays yellow to orange, otherwise,
fin scarlet; anal fin with scarlet spots basally, orange line

238

submarginally , remainder brown; body reticulations extending onto basal
third of pectoral-fin rays, tips of lower rays orange, upper rays
yellow, membranes dusky ventrally and transluscent dorsally; pelvic
fins brown with scarlet line submarginally; anal-fin spine rugosities
brown; other colors as described for female.

The Gilbert Islands male differs from the other males as follows:
darker overall color; reticulations on head enclose pale spots; fins
tend to have brown lines and spots instead of scarlet; and iris is
almost entirely yellow.

Comparisons. On the Pacific plate, Cirripectes stigmatic'"- is
easily distinguished from other Cirripectes species by its color
pattern. It further differs from all plate species except C^. auritus
in having a simple cephalic sensory pore pattern, and lacking an
interorbital pore position (Figure 17). Cirripectes auritus has a
broadly expanded nuchal flap (type A; Figure 7) absent in other plate
species.

Of those Cirripectes species whose geographic distribution does not
include the Pacific plate, C_. stigmaticus differs from all except C_.
f ilamentosus , C. chelomatus , and C_. springeri in usually having 15
(versus 14) segmented dorsal-iin rays and 16 (versus 15) segmented
anal-fin rays. in addition, only C_. stigmaticus and _C. springeri
typically have 21 caudal vertebrae. Cirripectes stigmaticus differs
from C. springeri in having 1 pore (versus 2) behind each nuchal flap,
and mid-snout pores present (versus absent).

Distribution. Cirripectes stigmaticus is a widely distributed
species occurring from Mozambique to Kenya on the African coast,

239

throughout the Indian Ocean and western Central Pacific, to the
Marshall and Samoa Islands (Figure 25). It is typically found on rocky
and coralline structures, usually at depths less than 10-15 m, but
occasionally as deep as 20 m.

Etymology. The specific epithet is derived from the Greek stigma,
meaning spot or mark, and refers to the body markings.

Comments . Apart from sexual dichromatism and slight color
differences noted for the Gilbert Islands male, no geographic or sexual
variation was observed for the characters examined.

Nomenclatural discussion. Smith (1959) described Ci.rripectes
cruentus based on one specimen from Pinda, Mozambique. The only
comparison he made was that it "differs from other species in
markings." Smith was aware of the description of Cirripectes
stigmaticus by Strasburg and Schultz (1953), as he cited the paper on
the same page as his description of C. cruentus , but he did not comment
on the similarity of the markings on his specimen to those described
and figured for C. stigmaticus .

Material examined. Types: RUSI 246 (male: 63 mm SL), holotype of
Cirripectus cruentus, Baixo Pinda, Mozambique (radiograph, counts, and
measurements provided by P. C. Heemstra); USNM 164962 (male: 64),
holotype of Cirripectes stigmaticus, Marshall Islands, Rongerik Atoll,
Latoback Islet, lagoon reef; and the following paratypes of Cirripectes
stigmaticus: USNM 142129 (1: 84), Marshall Islands; USNM 154673 (2:
45, 57), Marshall Islands; USNM 154674 (3: 68-83), Marshall Islands;
USNM 164961 (16: 36-79), Gilbert Islands; USNM 164963 (2: 62, 67),
Marshall Islands; USNM 164964 (2: 89, 100), Marshall Islands; USNM
164965 (1: 67), Samoa Islands.

240

Other material examined. Mozambique: RUSI UNCAT. (1: 24).
Madagascar: MNHN (12 specimens collected by A. Mauge). Mauritius:
RUSI 74-309 '1), USNM 227701 (1: 78), USNM 227723 (3: 39-87), USNM
227725 (4: 66-87). Cargados Carajos Shoals (St. Brandons Shoals):
USNM 227711 (3: 22-83), USNM 227721 (1: 98), USNM 227713 (1: 69).
Comoros Islands: CAS 40380 (3), USNM 215213 (5), USNM 227714 (4:
50-84). Tanzania: RUSI UNCAT. (1: 24; OUT OF RUSI 14997). Kenya:
USNM 227874 (1: 78). Seychelles Islands: USNM 227727 (1: 43).
Maldive Islands: BPBM 18912 (1: 66). Sri Lanka: USNM 227701 (1:
70). Nicobar Islands: SMF 17085 (2: 42, 57). Similan Islands,
Thailand: BPBM 22784 (1: 66). Christmas Island, Indian Ocean: WAM
P. 26083-039 (2: 29, 43). Indonesia: AMS 1.18469-088 (3), AMS
1.19875-092 (8). Australia, Western Australia: AMS 1.21318-057 (1).
Australia, Queensland: AMS 1.19338-007 (1), AMS 1.19454-027 (1), AMS
1.19473-095 (14: 56-88), AMS 1.19481-014 (6), AMS 1.19483-016 (10), AMS
1.20547-010 (4), AMS 1.20755-035 (3), AMS 1.20756-041 (5), AMS
1.20757-006 (1). AMS 1.20770-099 (1), AMS 1.20774-077 (6), AMS
1.21422-048 (3), USNM 227698 (1: 72), USNM 227709 (1: 74). Philippine
Islands: USNM 227553 (1: 25), USNM 227697 (9: 48-82), USNM 227700 (1:
40), USNM 227702 (1: 48). Indonesia: USNM 195699 (2: 55, 62), USNM
209727 (1: 51), USNM 227616 (3: 36-55), QSNM 227706 (18: 19-54), USNM
227710 (13: 25-53), USNM 227731 (1: 58). Papua-New Guinea: USNM
227704 (1: 35), USNM 227705 (2: 61, 63), USNM 227707 (1: 29), USNM
227708 (1: 56), USNM 227720 (3: 46-53), USNM 227721 (15: 21-61), USNM
227724 (1: 20), USNM 227726 (13: 32-59), USNM 228280 (1: 54). Bismarck
Archipelago: USNM 227722 (4: 53-58). Solomon Islands: AMS

241

1.17486-029 (1), BPBM 5954 (1), BPBM 15611 (1), BPBM 16035 (1), CAS
48959 (2). Vanuatu (New Hebrides) : AMS 1.17473-027 (2), BPBM UNCAT.
(1: 73), CAS 48960 (2). Loyalty Islands: USNM 227699 (1: 79). New
Caledonia: BPBM 11417 (1: 84). Fiji Islands: BMNH 1877.4.26.2 (1),
BPBM 14633 (1), BPBM 20956 (3), USNM 227703 (2: 44-86), USNM 235728
(2), USNM 235732 (1), ZMB 9870 (1). Tonga Islands: USNM 227715 (1:
65). Caroline Islands: BPBM 7422 (1), BPBM 9230 (2), CAS 38810 (2),
CAS 38811 (1), CAS 38812 (1), CAS 38813 (1), CAS 38817 (1), CAS 38844
(1), CAS 38870 (20), CAS 38872 (30), CAS 48897 (3), CAS 48945 (1), CAS
48947 (1), USNM 223457 (24: 41-74), US^i 224387 (11: 27-54), USNM
227628 (1: 48), . Kapingamarangi Atoll: CAS 48936 (3). Marshall
Islands: BPBM 7998 (4), BPBM 18383 (2), LACM 4034 (1: 75). Gilbert
Islands: AMS 1.18047-012 (1), AMS 1.18051-018 (1), AMS 1.18052-047
(1), AMS 1.18052-079 (1). Samoa Islands: ANSP 51009 (1: 57), BPBM
11314 (1: 46), UF 31450 (2).

Cirripectes vanderbilti (Fowler)

Ophioblennius vanderbilti Fowler, 1938:242 (Diamond Head, Oahu).
Ophioblennius capillus Reid, 1943:381 (Honolulu, Diamond Head Light).

Diagnosis. A species of Cirripectes with the following combination
of characters: 14 segmented dorsal-fin rays, 15 segmented anal-fin
rays, smooth lower lip, white (red in life) spots and streaks on the
snout and cheeks, nuchal cirri in two groups with base slightly swollen
beneath ventralmost cirri on each side (Figure 7G), and male genital
papilla with two closely appressed filaments (Figure 13B) .

242

Description. Dorsal fin XII, 13-15 (14 in 9^.0% of specimens); anal
fin 11,15-16 (15 in 95.7%); total procurrent caudal-fin rays 10-12;
pelvic fin 1,4; vertebrae 10 + 20-21 (20 in 97.4%) = 30-31 (30 in
97.4%); last pleural ribs on vertebral centrum 11; last epipleural rib
on vertebral centrum 18-21 (19-20 in 93.0%); anal pterygiophores 1-1-2
or 1-2-1 (1-1-2 in 92.2%); nuchal cirri 31-42 (35-40 in 86.5%);
supraorbital cirri 9-22 (10-15 in 78.9%); nasal cirri 7-23 (8-15 in
91.7%); LL tubes 0-5; last LL tube or end of LL canal positioned at
point between verticals from dorsal-fin ray 7 and caudal-fin base (8-14
in 94.4%); no scalelike flaps -long LL; lower lip smooth mesially
(plicate laterally); gill rakers 23-30 (based on 21 specimens);
pseudobranchial filaments on one side 8-9 (based on 21 specimens);
premaxillary teeth 204-229 (based on 5 specimens); dentary teeth 86-108
(based on 5 specimens); upper lip crenulae approximately 42-54; nuchal
cirri in two groups with a small nuchal flap bearing ventralmost cirri
(type G; Figure 7); first dorsal-fin spine of adults slightly longer
than second (1-5 mm longer in males and females); dorsal-fin membrane
deeply incised above last dorsal-fin spine; dorsal-fin membrane
attached to caudal fin in adults; cephalic pore system complex ( 6 or
more pores at most positions; figure 17; number of pores increases with
increasing SL;); mid-snout pores present (Figure 17); extra
interorbital pore position present (Figure 17); two pore positions
behind nuchal flap (Figure 17); male genital papilla with urogenital
orifice located basally between two closely appressed slender filaments
(less than 1.0 mm long) on a fleshy swelling behind anus (type II;
Figure 13); testes bulbous, length equals width; maximum SL about 100
mm; ophioblennius larvae with two canines posteriorly on each dentary.

243

The smallest mature female (ova about 0.6 mm diameter) examined was
about 42 mm SL. Males mature by about 35 mm SL.

Color in alcohol. Ophioblennius stage larvae have uniformly
light-brown head and body, no distinct blackish spots, and all cirri
dark brown.

Juveniles, subaduts, and adults of both sexes (Figure 61) have
brown head and body; small (0.5-1.0 mm diameter) pale spots on head,
those on snout frequently joined to form narrow lines running from
margin of orbits onto upper lip; all cirri blackish; underside of head
uniformly brown; fins br^wn except for pale triangular area
anterodorsally on spinous-dorsal fin and pale area over upper
caudal-fin rays.

Color in life. Adults (based on color slide of living and
photograph of freshly dead Hawaiian specimens) have brown body; head
with small reddish-orange spots and streaks on brown background; all
cirri black; underside of head pale brown; spinous-dorsal fin with
spines red in translucent triangular area anterodorsally on fin, tips
of first few segmented dorsal-fin rays red; tips of upper caudal rays
red; anal-fin rays with whitish tips; otherwise, fins brown; iris black
with thin yellow ring around pupil and bright reddish-orange ring
around outer portion.

Comparisons. Of the three Cirripectes species occurring in the
Hawaiian Islands, C. vanderbilti typically has 14 segmented dorsal-fin
rays, whereas C^. quagga has 15 and _C. obscurus asually 16. Cirripectes
obscurus also has a pupil-sized black spot behind each eye, and usually
has small white spots covering the head and about two-thirds of the

244

body. Cirripectes quagga and C. obscurus both have a crenulate lower
lip (smooth mesially in C. vanderbilti) .

Cirripectes vanderbilti and _C. variolosus occuc sympatrically at
Johnston Island, where they are the only species with white (red in
life) spots and streaks on the snout and cheeks (see C. variolosus
account for differentiating characters).

Distribution. Cirripectes vanderbilti is restricted to the
Hawaiian Islands and Johnston Island (Figure 26). It is usually found
on coral reefs where it has been collected at depths ranging from near
the surface to 10 m.

Etymology. Fowler (1938) named this species after Mr. George
Vanderbilt.

Nomenclatural discussion. Fowler (1938) based the description of
Ophioblennius vanderbilti on 14 specimens, two from Oahu and 12 from
Christmas Island, Line Islands. All these specimens are ophioblennius
stage larvae of Cirripectes, but those from Christmas Island are C.
variolosus. Fowler (1938) designated the Christmas Island specimens
and one of the Oahu specimens paratypes, and the other Oahu specimen
"type." This clearly links the name with the Oahu specimen designated
"type." Fowler (1938) did not realize that his specimens were larvae
and, in the same publication, identifieu adults of this species as C.
variolosus. Nevertheless, Ophioblennuio vanderbilti is the first name
available for this Hawaiian Islands-Johnston Icland endemic species.

Reid (1943) described Ophioblennius capillus based on one specimen
from Diamond Head Light, Oahu. He stated that 0_. capillus "differs
from Ophioblennius vanderbilti Fowler in having only two canines in the

245

upper jaw, more rays in the pectoral fins, nasal and orbital
appendages, and a much deeper notch in the dorsal fin," Reid (1943)
did not realize that his specimen (as well as the others in the genus
Ophioblennius as he defined it) was a larva. The canines at the tips
of the jaws are gradually lost as the larvae metamorphose into the
juvenile stage of development. The deeper dorsal-fin notch may reflect
a torn membrane or a difference in methods of making the measurement.
The difference in color of nasal and orbital appendages (cirri) could
be an artifact of preservation. As for the difference in number of
pectoral-fin rays, neither Fowler (1938) nor Reid (1943) provide this
count for _0. vanderbilti , and I have found this character to have a
constant mode of 15 for all Cirripectes species. As the types of 0_.
capillus and 0. vanderbilti represent the same species, the older name,
0^. vanderbilti, is considered the valid name.

Material examined. Types: USNM 120032 (1 specimen: 21 mm SL),
holotype of Ophioblennius capillus, , Hawaiian Islands, Oahu, off
Diamond Head, surface; ANSP 68432 (1: 22), holotype of Ophioblennius
vanderbilti, Hawaiian Islands, Oahu, Diamond Head; ANSP 68433 (1: 22),
paratype of Ophioblennius vanderbilti, Hawaiian Islands, Oahu, Diamond
Head.

Other material examined. Hawaiian Islands: ANSP 10493 (1: 58),
USNM 78057 (1). Hawaiian Islands, Pearl and Hermes Reef: NMW 77809
(3: 31-37). Hawaiian Islands, Oahu: nNS? 83873 (3: 22-24), BPBM 4918
(1), BPBM 15212 (20), USNM 108846 (2: 23, 27), USNM 109320 (3: 37-62),
USNM 205336 (4: 31-54), USNM 228162 (16: 35-81), USNM 228163 (1: 66),
USNM 258323 (2), USNM 258324 (5). Hawaiian Islands, Molokai: ANSP

246

81990 (1: 34), BPBM 4917 (1). Hawaiian Islands, Maui: USNM 228161 (1:
54). Hawaiian Islands, Hawaii: USNM 160687 (7: 61-90). Johnston
Island: BPBM UNCAT. (2; JULY 1923), BPBM 11041 (3), BPBM 15103 (65),
BPBM 15360 (25), RUSI 74-23 (5), USNM 142114 (73: 35-61).

Cirripectes variolosus (Valenciennes)

Salarias variolosus Valenciennes in Cuvier and Valenciennes, 1836:317

(Guam) .
Salarias nigripes Seale, 1901:127 (Guam).
Ophioblennius vanderbilti Fowler, 1938:242 (in part, only paratypes

from Christmas Island, Line Islands).
Ophioblenniuus sp. indet. Clark, 1938:185 (Nukuhiva Island).
Ophioblennius clarki Reid, 1943:380 (Nukuhiva Island).

Diagnosis . A species of Cirripectes with the following combination
of characters: small white (red in life) spots and/or narrow lines on
snout and around eye, nuchal cirri type B (Figure 7B) , and male genital
papilla type I (Figure 13A).

Description. Dorsal fin XI -XIII (XII in 99.2% of specimens) , 13-15
(14 in 95.1%); anal fin 11,14-16 (15 in 95.5%); total procurrent
caudal-fin rays 10-14; pelvic fin 1,4; vertebrae 10 (1 with 9) + 19-21
(20 in 96.3%) = 29-31 (30 in 96.5%); last pleural ribs on vertebral
centrum 11; last epipleural rib on vertebral centrum 18-23 (19-21 in
93.3%); anal pterygiophores 1-1-1, 1-1-2, or 1-2-1 (1-1-2 in 89.3%);
nuchal cirri 27-38 (28-34 in 89.5%); supraorbital cirri 4-14 (6-11 in

247

89.7%); nasal cirri 4-19 (8-12 in 76.9%); LL tubes 1-11 (2-9 in 89.4%);
last LL tube positioned at point between verticals from dorsal-fin ray
7 and caudal-fin base (10 to caudal-fin base in 94.1%); no scalelike
flaps along LL; lower lip smooth mesially (plicate laterally); gill
rakers 23-29 (based on 47 specimens); pseudobranchial filaments on one
side 7-10 (based on 47 specimens); premaxillary teeth 176-230 (based on
7 specimens); dentary teeth 83-96 (based on 7 specimens); upper lip
crenulae approximately 37-51; nuchal cirri in four groups (dorsalmost
groups sometimes with cirri not connected at their bases) with bases of
ventralmost groups slightly expanded basally, rarely with two groups on
a side weakly connected basally (type B; Figure 7); first dorsal-fin
spine of adults of both sexes 1-4 mm longer than second; dorsal-fin
membrane deeply incised above last dorsal-fin spine; dorsal-fin
membrane attached to caudal fin in adults; cephalic pore system complex
(6 or more pores at most positions; Figure 17; number of pores
increases with increasing SL); mid-snout pores present (Figure 17);
extra interorbital pore position present (Figure 17); two pore
positions behind nuchal flap (Figure 17); male genital papilla with
urogenital orifice located basally between two widely separated slender
filaments (less than 1.0 mm long) on a fleshy swelling behind anus
(type I; Figure 13); testes bulbous, length equals width; maximum SL
about 85 mm; ophioblennius larvae with 2 canines posteriorly on each
dentary.

The smallest mature female (ova about 0.5 mm diameter) examined was
about 55 mm SL, but a 35.6 mm SL female from the Ogasawara Islands had
developing ova (about 0.2 mm diameter). Males mature by about 35 mm
SL.

248

Color in alcohol. Ophioblennius stage larvae (20-25 mm SL) are
uniformly pale brown, without blackish spots or other distinctive
pigmentation.

Metamorphosed young (25-30 mm SL) with melanophores uniformly
distributed over body, but slightly darker than ophioblennius stage.
Pale spots beginning to form on snout and under eye.

Subadults and adults of both sexes (Figure 62) with cream- to
brown-colored head and body (some females with pupil-sized dark-brown
spots on posterior half of body); anterior half of head covered with
white spots (0.5-1.0 mm diameter), spots irregular in cl.ape and
frequently forming narrow vertical lines on snout and upper lip;
underside of head uniformly pale brown.

Color in life. Adults (based on color slides of freshly dead
specimens from Enewetak Atoll, Abaiang, and Funafuti) with brown body
(Funafuti specimens with body pinkish posteriorly and pale yellowish
anteriorly); red spots and lines on head; nasal and supraorbital cirri
reddish orange; nuchal cirri brown to black; pectoral-fin color ranging
from pale brown to reddish; spinous-dorsal fin with reddish spines,
membranes brown below anterodorsal translucent-triangular area and red
streaks basally; segmented-dorsal fin with yellowish rays and red
streaks extending from each ray base to mid-height of membrane between
each pair of rays; upper caudal-fin rays yellowish, lower rays pale
brown to yellowish; anal fin with reddish streaks basally, becoming
brown in middle of fin, and tips of rays cream colored; iris color
silver in the Funafuti and Abaiang specimens, red with yellow ring
around pupil in the Enewetak specimen (iris color in the Enewetak

249

specimen is tentative as the iris color had faded somewhat before the
specimen was photographed).

A specimen collected at a depth of 30.5 m off Pitcairn Island
differs from those described above in having the nasal cirri,
supraorbital cirri, and dorsal half of head bright reddish orange; iris
and other body colors same as described above for Enewetak specimen.

Comparisons. Of those Cirripectes species occurring on the Pacific
plate, Cirripectes variolosus and _C. vanderbilti are the only ones with
small white (red in life) spots and/ or narrow lines on the snout and
around the eye. Gosline (1955:469) stated that iio "Hawaiian endemics"
occurred sympatrically with their "Central Pacific counterparts" at
Johnston Island. He failed to realize that his C. variolosus comprised
two species, C_. variolosus and C_. vanderbilti, which occur
sympatrically at Johnston Island. They can be identified based on
their nuchal cirri arrangement and the shape of the male genital
papilla. Cirripectes variolosus has nuchal cirri type B and male
genital papilla type I, whereas C. vanderbilti has types G and II,
respectively (Figures 7 and 13).

Distribution. Cirripectes variolosus is endemic to the Pacific
plate ( sensu Springer, 1982) where it is known from every major island
group except the Hawaiian Islands (Figure 26). It occurs as far west
as the Ogasawara, Mariana, and Caroline Islands, in the northernmost
Tonga Islands, and as far east as the Pitcairn Island group. Although
this species usually occurs on shallow reefs in water less than 5 m
depth, it has been taken at a depth of 30.5 m at Ducie and Pitcairn
Islands .

250

There is one collection of Cirripectes variolosus (USNM 227978)
that is supposedly from Aldabra Atoll, Indian Ocean. As this is the
only record of this species from an area other than the Pacific plate,
I believe the locality data for this lot are in error (see C_. jenningsi
account for further discussion). I do not consider this record as part
of the geographic range of C. variolosus .

Etymology. The specific epithet is derived from the late Latin
variola, meaning smallpox or spotted, and refers to the pattern of
spots on the head.

Comments. Sexual dichromatism was :*oted for some female specimens
from the Marshall Islands, Johnston Island, Phoenix Islands, and
Makatea. Some females have pupil-sized dark-brown spots on about the
posterior half of body (Figure 63), while other females in the same
populations have the unspotted bodies typical of both sexes in this
species. Neither of these patterns is size dependent, as both patterns
are present on young and adult females in the same collection. The
reason for the variability in female color pattern (dark-brown spots on
body or spots lacking) is unknown.

The specimens collected between 23 and 30.5 m depth in the Pitcairn
Island group are problematical. These specimens occur in deeper water
than any other known Cirripectes species. Other than the distinctive
reddish-orange head, the characteristics of these specimens conform to
aiy definition of C_. variolosus . It is probable that the reddish-orange
coloration of these specimens is an artifact of their depth of
occurrence. In the absence of any additional information substantiating
the color differences, I treat these specimens merely as color
variants .

251

Nomenclatural discussion. Seale (1901) described Salariae nigripes
based on 30 specimens from Guam (also the type locality of Cirripectes
variolosus). Although I have not examined the primary type material
(BPBM 271), I have examined 15 paratypes (ANSP 82128), and all are
referable to C. variolosus, Seale (1901) did not compare his Salarias
nigripes with any other species, but his description of the spots on
the snout clearly associate his specimens with C_. variolosus .

The type material used by Fowler (1938) in the description of
Ophioblennius vanderbilti comprises two species. The paratypes from
Christmas Island (ANSP 68434 t~ 68445 inclusive) are ophioblennius
stage larvae of Cirripectes variolosus. The specimens from Oahu are
the types of C_. vanderbilti.

The specimen referred to by Clark (1938) as Ophioblennius sp.
indet. was used by Reid (1943) as the type of his 0_. clarki. This
specimen from Nukuhiva Island is an ophioblennius stage larva of
Cirripectes variolosus .

Material examined. Types: MNHN 4411 (male: 38 mm SL), holotype of
Salarias variolosus, Guam, Mariana Islands; CAS 24686 (1: 24), holotype
of Ophioblennius clarki, Marquesas Islands, Nuku Hiva Island, Taiohae
Bay; ANSP 82128 (15: 25-46), paratypes of Salarias nigripes, Mariana
Islands, Guam, Agana ; ANSP 68434-46 (12: 19-21), paratypes of
Ophioblennirs vanderbilti, Christmas Island, Line Islands.

Other material examined. Ogasawara Islands (Bonin Islands): FAKU
48143 (1: 36), FAKU 48144 (1: 51), FAKU 48183 (2: 42, 48). Marcus
Island: BPBM 7157 (15), USNM 227949 (5: 36-61), USNM 227954 (7:
42-62). Wake Island: ANSP 65628-30 (3: 30-50), ANSP 65789-92 (4:

252

28-30), ANSP 65802 (2: 29, 29), BPBM 4925 (22), BPBM 15369 (2), CAS
38807 (22). Johnston Island: USNM 198731 (32: 32-67). Caroline
Islands: BPBM UNCAT. (1; 10 JUNE 1968), CAS UNCAT. (1; GVF 936), CAS
29246 (6: 45-63), CAS 38805 (1: 47), CAS 38880 (2), CAS 48895 (1), CAS
48896 (2: 39, 51), CAS 48899 (1: 24), CAS 48917 (3), CAS 48926 (1), CAS
48939 (8), CAS 48962 (2), CAS 48964 (1: 25), USNM 227633 (6: 39-50).
Mariana Islands: ANSP 82166 (1: 29), CAS 38798 (5), CAS 38879 (1), UF
31446 (3), UF 31447 (2). Marshall Islands: BPBM UNCAT. (1; 5 JULY
1975), BPBM 8249 (1), BPBM 15520 (5), LACM 3979 (4), USNM 142107 (17:
35-66), USNM 142108 (15: 30-75), USNM 142110 (7: 47-59), USNM 142112
(11: 36-83), USNM 142113 (26: 18-81), USNM 200614 (57 of 58: 31-62),
USNM 227947 (1: 52), USNM 228109 (2). Gilbert Islands: AMS
1.18047-016 (2), BPBM 15328 (1), USNM 167333 (1 of 2: 56). Phoenix
Islands: USNM 115493 (5: 34-38), USNM 115494 (48 of 49: 24-62), USNM
115496 (54 of 57: 23-62), USNM 227769 (1: 26), USNM 227951 (2: 26, 26),
USNM 227953 (3: 46-78), USNM 227956 (7: 26-53), USNM 227974 (2: 25,
26), USNM 227976 (2: 28, 44), USNM 227977 (10: 25-48). Tokelau
Islands: USNM 115495 (3: 49-52), USNM 227948 (1: 31). Samoa Islands:
UF 31451 (1), USNM 115491 (4: 21-26). Cook Islands: BPBM 5741 (11),
USNM 227955 (4: 26-43), USNM 227969 (20: 23-51). Tubuai Islands: AMNH
UNCAT. (1: 25). Tonga Islands: USNM 227952 (7: 27-89). Society
Islands: BPBM 8633 (1), BPBM 8642 (1), CAS 48963 (3), CAS 48974 (1),
USNM 227960 (2: 25-38), USNM 227961 (2: 38-45), USNM 227962 (1: 31),
USNM 227971 (1: 51), USNM 227972 (1: 38). Line Islands: ANSP 82159
(1: 39), BPBM 14060 (1: 52), BPBM 4919 (2), BPBM 4920 (1), BPBM 7557
(9), BPBM 15156 (25), CAS 48949 (1), USNM 195809 (1), USNM 227950 (1:

253

40), USNM 227959 (3: 39-62), USNM 227970 (6: 36-42), USNM 227975 (29:
23-57). Tuamotu Archipelago: BPBM UNCAT. (5), BPBM UNCAT. (8: 47-62;
15 MARCH 1956), BPBM 12270 (4: 28-61), BPBM 16928 (2: 42, 43), BPBM
16941 (2: 25, 53), BPBM 17009 (1), BPBM 17079 (4), CAS 48955 (9), CAS
48965 (1: 64), USNM 227973 (1: 45). Marquesas Islands: AMS UNCAT. (1;
OUT OF AMS 1.22017-016), AMS 1.21769-025 (3), BPBM UNCAT. (1: 55; 11
OCT 1951), BPBM UNCAT. (1:68; 10 JULY 1957), BPBM UNCAT. (2: 49-68),
BPBM 11675 (12), BPBM 11839 (2), BPBM 12113 (3), BPBM 12143 (5), BPBM
12803 (3).

As discussed earlier, the following lot appears to have incorrect
locality data: USNM 227978 (7: 27-59), Aldabra Atoll.

Scartichthys JORDAN AND EVERMANN

Scartes Jordan and Evermann, 1896:471 (type species: Salarias

rubropunctatus Valenciennes j^ Cuvier and Valenciennes, 1836, by
original designation; a junior homonym of Scartes Swainson, 1835,
Mammalia) .

Scartichthys Jordan and Evermann, 1898:2395 (type species: Salarias
rubiopunctatus Valenciennes Jji Cuvier and Valenciennes, 1836, by
original designation).

Diagnosis. Scartichthys are salariin blennies with the posterior
section of the lateral line comprising 18-21 short bi-pored tubes
(continuous and tube sections of lateral line not in disconnected
overlapping portions). Specimens of Scartichthys , with adults often
exceeding 180 mm SL (up to 222 mm SL) are the largest (referring to a
combination of length and weight) in the Blenniidae (the nemophin genus
Xiphasia reaches 550 mm SL, but has an extremely slender body).

Selected counts for the species of Scartichthys are provided in
Table 4.

Distribution. The genus Scartichthys is restricted to the eastern
Pacific Ocean, where it occurs from Panama to Chile (Figure 64).

254

Figure 64. Geographic distribution of Scartichthys . S_. crapulatus
(closed triangles), Scartichthys gigas (closed squares), S_. variolatus
(closed diamonds), and S. viridis (closed circles).

256

257

Table 4. Counts for selected characters of the species of
Scartichthys. Table headings: 1st - primary modal count, 2nd -
secondary modal count for bimodal characters, n - number of specimens,

Segmented Dorsal Fin Rays
Range 1st n
crapulatus 18 6

gigas 16-18 17 235

variolatus 17-18 18 68
viridis 17-19 18 28

Segmented Anal Tin Rays

Range 1st 2nd n

19-20 20 19 6

18-20 19 173

19-20 19 20 72

19-20 20 19 34

crapulatus
gigas

variolatus
viridis

Vertebral Centrum Bearing

Last Pleural Rib

Range 1st n

12 6

11-12 11 164

11 68

11-12 12 23

Caudal Vertebrae

Range 1st n

24 6

23-25 24 166

23-25 24 69

23-25 24 23

258
Table 4. Continued.

Vertbral Centrum Bearing

Last Epipleural Rib Left+Right Orbital Cirri

Range 1st 2nd n Range 1st 2nd n

crapulatus 15-19 19 17 6 18-28 22 6

gigas 15-20 17 18 156 19-53 29 39 15

variolatus 16-19 17 18 68 22-116 23

viridia 16-21 18 23 20-51 30 16

Left+Right Nasal Cirri Total Nuchal Cirri Bases

Range

1st

2nd

n

Range

1st

n

crapulatus

7-9

8

4

7-20

8

6

gigas

7-15

8

23

8-19

12

16

variolatus

8-31

13

30

20-95

47

21

viridis

6-15

9

8

18

6-60

22

16

259
Table 4. Continued.

Dentary Teeth

Range 1st 2nd

n

crapulatus 92-110 110 6

gigas 57-69 60 30

variolatus 74-93 87 88 31

viridis 106-131 120 22

260
Key to the Species of Scartichthys

la. Fewer than 94 dentary incisors; body coloration mottled with brown
and white, or with white (red in life) spots 2

lb. More than 94 dentary incisors; body uniformly brown, occasionally
with a pupil-sized dark-brown midlateral stripe, or with tiny
dark-brown spots on posterior half of body 3

2a. Dentary incisors 73-94; typically 18 segmented dorsal-fin rays;
pupil-sized black spot on first (sometimes on second also)
interspinal membrane of dorsal fin; pupil-sized white spots over
head and body; occurs on offshore islands of Chile variolatus

2b. Dentary incisors 57-69; typically 17 segmented dorsal-fin rays; no
pupil-sized black spot on first interspinal membrane of dorsal
fin; body mottled with brown and white; occurs from Panama to
northern Chile gigas

3a. Tiny dark-brown spots on posterior half of body; known only from

northern Chile and from the vicinity of Valparaiso crapulatus

3b. Body coloration uniformly brown, occasionally with a dark-brown
stripe (its width about equal to diameter of pupil); occurs from
vicinity of Valparaiso, Chile, to southern Peru viridis

Figure 65. Female Scartichthys crapulatus, holotype, Chile (USNM
276344: HOmmSL).

Figure 66. Female Scartichthys gigas, Peru (GCRL 12635: 140 mm
SL).

262

m

Figure 67. Female Scartichthys variolatus, Juan Fernandez Islands
(MNHNC P. 6. 227: 103 mm SL).

Figure 68. Female Scartichthys viridis, Chile (GCRL 12618: 121 mm
SL).

264

'

265

Scartichthys crapulatus new species

Diagnosis . A species of Scartichthys with more than 95 dentary
incisors and small dark-brown spots on posterior half of body.

Description. Dorsal fin XII, 18; anal fin 11,19-20 (20 in 6 of 9
specimens); total procurrent caudal-fin rays 14-15; pelvic fin 1,4;
vertebrae 10+24=34; last pleural ribs on vertebral centrum 12; last
epipleural rib on vertebral centrum 15-19 (17-19 in 5 of 6); anal
pterygiophores 2-1-1 or 1-2-1 (1-2-1 in 5 of 6); nuchal cirri 7-20
(6-12 in 5 of 6); supraorbital cirri 18-28; nasal cirri 7-9; LL tubes
21-22 (21 in 8 of 10); last LL tube at base of caudal fin; no scalelike
flaps along LL; lower lip smooth mesially (plicate laterally); gill
rakers 22-27 (based on 5 specimens); pseudobranchial filaments on one
side 10-11 (based on 6 specimens); premaxillary teeth 205-220 (based on
3 specimens); dentary teeth 78-110 (95-110 in 10 of 14; fewer than 95
only in specimens less than 50 mm SL); upper lip crenulae approximately
28-36; nuchal cirri in 2 groups widely separated across nape (Figure
7); first dorsal-fin spine of adults approximately equal in length to
second in both sexes; dorsal-fin membrane deeply incised above last
dorsal-fin spine; dorsal-fin membrane attached to caudal peduncle in
advance of caudal fin in adults; cephalic pore system relatively simple
(less than 3 pores at most positions; number of pores increases with
increasing SL); male genital papilla with urogenital orifice located
basally between two small protuberances on a fleshy swelling behind

266

anus (Figure 13); testes elongate, length equals about twice width;
maximum SL about 110 mm.

No mature females of this species have been examined, but the
female holotype (about 110 tun SL) has well-developed ovaries and
females less than 70 nm SL do not. No mature males have been examined.

Color in alcohol. Juveniles have brown pupil-sized stripe
midlaterally on body on pale background, nine to eleven saddlelike
blotches along dorsal profile, posterior half of body speckled with
tiny black spots; head brown with small black spot, its diameter equal
to about half diameter of pupil, behind posterior margin of eye;
anterior one to three interspinal membranes of dorsal fin with black
pupil-sized spot, remainder of fins dusky.

Adult female (Figure 65) with background color of head and body
brown, faint eye-sized dark-brown stripe midlaterally on body,
posterior half of body with small dark-brown spots; dorsal and anal
fins with narrow pale distal margins.

Color in life. Life colors not known.

Comparisons . Scartichthys crapulatus is the only member of the
genus with small dark-brown spots on the posterior half of the body.
It is most similar in meristics and other counts to S. viridis , but is
easily distinguished by color pattern (the latter has a uniformly brown
body) .

Distribution. Gcartichthys crapulatus is known only from the coast
in the vicinity of Valparaiso, Chile, and from a power plant trap in
the northern Chilean town of Barquito, where it was collected with
specimens of _S_. gigas (Figure 64).

267

Etymology. The specific epithet, the Latin crapulatus , meaning
drunk, refers to the purported drunken feeling experienced when the
flesh of Scartichthys is eaten.

Material examined. Holotype: USNM 276344 (female: 110 mm SL) ,
Montemar Biological Station, field number BBC 1155, collected by B. B.
Collette and R. H. Gibbs , Jr., 14 Feb. 1966.

Paratypes: ANSP UNCAT. (4 specimens: 42-64 mm SL), Chile,
Barquito, power plant trap, 28 April 1955; BMNH 1850.6.14:20 (1: 67),
South America (probably Chile), collected by Mr. Bridges; MNHNC P. 6. 411
(8: 37-78), Chile, El Quisco, 32° 23' S, 71° 42' If, 14 Sept. 1952.

Scartichthys gigas (Steindachner)

Salarias gigas Steindachner, 1876:220 (Callao, Peru; syntypes NMW

73438:1 and 73438:2).
Salarias eques Steindachner, 1898:307 ("Cavanchabai bei Iquique";

holotype ZMB 15658).
Ophioblennius xiphiodon Clark, 1938:183 (Callao, Peru; holotype CAS

5543).
Ophioblennius mazorkae Hildebrand, 1946:384 (Mazorka Island, Huaura

Group, Peru; holotype 128188).

Diagnosis . A species of Scartichthys with fewer than 74 dentary
incicors and a reticulated color pattern.

Description. Dorsal fin XI -XIII (XII in 96.6% of specimens) , 16-1 8
(17 in 91.9%); anal fin 11,18-20 (19 in 80.9%; 18-19 in 99.4%); total

268

procurrent caudal-fin rays 10-16; pelvic fin 1,4; vertebrae 10-11 (10
in 99.4%) + 23-25 (24 in 94.6%) = 33-35 (34 in 94.6%); last pleural
rios on vertebral centrum 11-12 (11 in 99.4%); last epipleural rib on
vertebral centrum 15-20 (17-19 in 92.9%); anal pterygiophores 2-1-1,
1-2-1, or 1-1-2 (1-2-1 in 75.6%); nuchal cirri 8-19; supraorbital cirri
19-53 (23-39 in 80.0%); nasal cirri 7-15 (7-11 in 95.7%); LL tubes
18-22 (19-21 in 87.5%); last LL tube on caudal-fin base; no scalelike
flaps along LL; lower lip smooth mesially (plicate laterally); gill
rakers 16-20 (based on 10 specimens); pseudobranchial filaments on one
side 9-13 (based on 12 specimens); premay'.llary teeth 108-146 (based on
10 specimens); dentary teeth 57-69 (based on 30 specimens); upper lip
crenulae approximately 24-31; nuchal cirri in two irregular groups on
either side of the nape, distance between them approximately equal to
diameter of eye; length of first dorsal-fin spine of adults about equal
to second in both sexes; dorsal-fin membrane deeply incised above last
dorsal-fin spine; dorsal-fin membrane attached to caudal peduncle in
advance of caudal fin in adults; cephalic pore system complex (4 or
more pores at most positions; number of pores increases with increasing
SL); mid-snout pores present (Figure 17); male genital papilla with
urogenital orifice located basally between two small protuberances on a
fleshy swelling behind anus (Figure 13); maximum SL about 222 mm;
ophioblennius larvae with 2-3 canines posteriorly on each dentary; no
spots on membrane between anterior dorsal-fin spines.

The smallest mature female (ova about 0.6 mm diameter) examined was
about 126 mm SL, but it is likely that in some populations, females
mature at somewhat smaller sizes. Males mature by about 90 mm SL.

269

Color in alcohol. Ophioblennius stage larvae Dale with 11 to 13
saddlelike blotches of pigment along dorsal aspect of body; distal half
of pectoral fin with numerous melanophores on rays and membranes;
melanophores at tips of spinous dorsal-fin rays; remainder of fins
pale; small pupil-sized cluster of melanophores behind midpoint of
posterior margin of eye.

Juveniles with about eight to ten irregular dark-brown bars with
pale interspaces along body; head irregularly covered with pale spots
and bars, and dark-brown bars, large black spot behind posterior margin
of orbit, size of spot about half lo three-quarters size of eye; dorsal
and anal fins dark brown with pale-tipped fin elements; other fins
dusky.

Adult color pattern (Figure 66) similar to that of juveniles except
the bars on the head and body break up into a reticulated pattern.

Color in life. A recently collected adult male in alcohol still
retained some orange color at the distal tips of the dorsal-fin
elements. Other colors are unknown.

Comparisons . Scartichthys gigas differs from all other
Scartichthys in having fewer than 70 dentary teeth (versus 74 or more)
and in having a vermiculated color pattern over head and body (all
others have spots or a uniformly pigmented body).

Distribution. Scartichthys gigas occurs from the Pacific coast of
Panama to Antofagasta, Chile (Figure 64). It is sympatric with S.
viridis in southern Peru and northern Chile, and with S. crapulatus in
northern Chile.

Etymology. The specific epithet is Latin for giant and refers to
the relatively large size of adults.

270

Nomenclatural discussion. Steindachner (1876) described Salarias
gigas based two specimens from Callao, Peru, but gave no catalog
numbers. The two syntypes of j^. gigas are cataloged as NMW 73438:1
(female) and 73438:2 (male), from Callao, Peru.

Salarias eques was described by Steindachner (1898) based on a
single specimen from "Cavanchabai bei Iquique." Steindachner treated
S_. gigas and _S. viridis on the pages following the description of S.
eques , but failed to recognize ^. eques as a sub-adult specimen of S_.
gigas . The holotype of S^. eques is cataloged as ZMB 15658 (female, 86
mm SL). Although the holct/pe is a sub-adult, it retains the striped
pigmentation pattern frequently found on much smaller specimens. The
low number of dentary teeth and the lack of a spot anteriorly in the
dorsal fin are characteristic of Scartichthys gigas . Salarias eques is
a junior synonym of S. gigas .

Clark (1938) described Ophioblennius xiphiodon based on
ophioblennius stage post-larval specimens from Peru and Chile. As I
discuss in the account of Scartichthys viridis , the paratypes from
Valparaiso, Chile, are referable to _S. viridis , and the other specimens
probably belong to _S. gigas . The Peruvian holotype was not available
for examination, but, as the Peruvian paratypes are post-larvae of _S.
gigas and the collection locality (Callao) of the holotype is the same
as that of the types of _S. gigas , I consider Ophioblennius xiphiodon to
be a junior synonym of S. gigas.

Ophioblennius mazorkae was described by Hildebrand (1946) based on
ophioblennius-stage post-larval specimens of Scartichthys gigas and,
thus, is a junior synonym of the latter.

271

Material examined. Types: NMW 73438:1 (female: 150 mm SL) and
73438:2 (male: 185), syntypes of Salarias gigas, Callao, Peru; ZMB
15658 (1: 84), holotype of Salarias eques, Iquiqui, Chile; CAS
5544-5550 (3 of 7 examined: 33-41), paratypes of Ophioblennius
xiphiodon, Peru, Callao; CAS 5553-5556 (2 of 4 examined: 31, 32), Peru,
Chinchas; USNM 128188 (1: 33), holotype of Ophioblennius mazorkae ,
Peru, Huauru Group, Mazorka Island; USNM 128189 (20 of 60+ examined:
30-36), paratypes of Ophioblennius mazorkae, Peru, Huauru Group,
Mazorka Island.

Other material examined. West Coast of South America (exact
locality unknown): BMNH 1908.12.5.32-3 (2: 54, 57). Panama: USNM
144797 (72: 30-58). Ecuador: USNM 88796 (3: 106-120). Peru: GCRL
12492 (1), GCRL 12513 (3:127-159), GCRL 12628 (9), GCRL 12633* (6), GCRL
12635 (25), NMW 20516 (1), NMW 22184 (1), NMW 73244 (2: 102, 103), NMW
73425 (2: 117-141), RMNH 11283 (1:193), RMNH 11462 (1: 167), SI0 65-602
(12), UF 21437 (1: 136), USNM UNCAT. (2: 135, 135; GCRL 1670); USNM
UNCAT. (4: 37-55; 6 JUNE 1966); USNM UNCAT. (5: 120-153; GCRL 1677);
USNM UNCAT. (4: 33-57; GCRL 1672); USNM UNCAT. (1: 63; LWK 66-84), USNM
102009 (1: 50), USNM 102010 (1: 65), USNM 128192 (2: 30, 52), USNM
128195 (1: 43), USNM 200396 (1: 45), USNM 227556 (57 of 100+ examnined:
47-108), USNM 227981 (100+) , ZMB 9058 (1: 220), ZMB 9107 (1), ZMB 13740
(4), ZMB 13741 (6). Chile (exact locality unknown): BMNH
1871.4.13.26-7 (2: 138-222). Chile: USNM 76389 (1: 71), USNM 122571
(7: 40-126), USNM 175368 (1: 78), ZMB 15659 (1), ZMB 15660 (3), ZMB
15662 (5).

272

Scartichthys variolatus (Valenciennes)

Salarias variolatus Valenciennes in Cuvier and Valenciennes, 1836:346

(Juan Fernandez Island; holotype MNHN 4410).
Salarias rubropunctatus Valenciennes in Cuvier and Valenciennes,

1836:346 (Juan Fernandez Island; syntypes MNHN A. 2038).
Ophioblennius f ernandezensis Clark, 1938:184 (San Juan Bautista

[Cumberland] Bay, Juan Fernandez Islands).

Diagnose s . A species of Scartichthys with the following
combination of characters: 73-94 dentary incisors, 18 segmented
dorsal-fin rays, pupil-sized black spot on first and somtimes second
interspinal membrane, and pupil-sized white spots on head and body.

Description. Dorsal fin XI -XII (XII in 98.6% of specimens) , 17-18
(18 in 91.2%); anal fin 11,19-20 (19 in 56.9%); total procurrent
caudal-fin rays 12-14 (1 specimen with 16); pelvic fin 1,4; vertebrae
10 + 23-25 (24 in 94.2%) = 33-35 (34 in 94.2%); last pleural ribs on
vertebral centrum 11; last epipleural rib on vertebral centrum 16-19
(17-18 in 91.2%); anal pterygiophores 2-1-1, 1-2-1, or 1-1-2 (1-1-2 in
76.8%); nuchal cirri 20-95 (20-77 in 95.2%); supraorbital cirri 22-116
(19-74 in 91.7%); nasal cirri 8-31 (10-23 in 90.0%); LL tubes 19-21
(20-21 in 90.0%); last LL tube on base of caudal fin; no scalelike
flaps along LL; lower lip entire mesially (plicate laterally); gill
rakers 21-28 (based on 16 specimens); pseudobranchial filaments on one
side 10-15 (based on 16 specimens); premaxillary teeth 200-223 (based
on 2 specimens); dentary teeth 80-93 (based on 30 specimens); upper lip

273

crenulae approximately 35-43; nuchal cirri in 2 widely separated
transverse rows on either side of nape; first dorsal-fin spine of
adults approximately equal to second in males and females; dorsal-fin
membrane deeply incised above last dorsal-fin spine; dorsal-fin
membrane attached to caudal peduncle in advance of caudal fin in
adults; cephalic pore system complex ( 3 or more pores at most
positions; number of pores increases with increasing SL); mid-snout
pores present (Figure 17); male genital papilla with urogenital orifice
located basally between two short protuberances on a fleshy swelling
behind anus (Figure 13); testes elongate, length more than twice width;
maximum SL about 150 mm; pupil-sized black spot on distal portion of
membrane between first and second dorsal-fin spines (93.5% of
specimens) and occasionally a second spot on membrane between second
and third spines (6.5%).

The smallest mature female (ova about 0.8 mm diameter) examined was
about 100 mm SL. Males mature by about 100 mm SL.

Color in alcohol. Subadults and adults of both sexes (Figure 67)
have a dark brown background coloration with pupil-sized pale spots
over head and body, and 7 to 9 broad, faint, dark-brown bars on body;
dorsal fin with pupil-sized black spot on first interspinal membrane,
remainder of fin dusky with small pale spots, dorsal and anal fins with
distal ends of elements pale tipped; caudal fin brown with small palp
spots; black spot about half diameter of pupil on head behind posterior
margin of eye.

Color in life. I have not seen the life colors of this species, but
Valenciennes in Cuvier and Valenciennes (1836) describes the spots on

274

the body as brownish red. An illustration in the Cuvier and
Valenciennes manuscript material in the library of the Museum National
d'Histoire Naturelle, Paris, clearly shows the brownish-red spots
described in their 1836 publication. Other colors are the same as
described for specimens in alcohol.

Comparisons. Scartichthys variolatus differs from other
Scartichthys in that adults have 74-93 dentary teeth. Scartichthys
variolatus also differs from _S. gigas in typically having 18 segmented
dorsal-fin rays (versus 17 modally). The distinctive color pattern of
Scartichthys variolatus comprising pale (brownish-red in life) spots on
a dark background will distinguish this form from all other
Scartichthys.

Distribution. Scartichthys variolatus is an island endemic known
only from San Felix and San Ambrosio islands, and Juan Fernandez
Islands (Figure 64).

Etymology. The specific epithet is derived from the late Latin
variola, meaning smallpox or spotted, and refers to the pattern of
spots on the head and body.

Nomenclatural discussion. Valenciennes in Cuvier and Valenciennes
(1836) described specimens belonging to Scartichthys variolatus under
two species names, Salarias variolatus and S. rubropunctatus . The
former description was based on an adult specimen and the latter on
five young specimens from the same island. The syntypic series of S.
rubropunctatus comprises four specimens belonging to Scartichthys
vario.latus , and one specimen with supraorbital and nuchal cirri
morphologies similar to S. viridis and number of dentary teeth in the

275

range for _S. variolatus . As no other specimens of S. viridis have been
collected from the Juan Fernandez Islands, I consider the last specimen
to be an aberrant specimen of _S. variolatus , although it is posrsible
that Valenciennes inadvertently mixed some of his mainland Chile and
Juan Fernandez Islands collections. To avoid future confusion, I
designate a 43 mm SL male (MNHN A. 2038) as lectotype of Salarias
rubropunctatus . The name _S. variolatus is the senior synonym, based on
page priority, and _S. rubropunctatus is a junior synonym.

Clark (1938) described Ophioblennius fernandezensis based on eight
specimens from the Juan Fernandez Islands. I have not examined the
holotype (CAS 5557), but my examination of 3 of the 7 paratypes, the
original description, and data taken from the holotype by V. G.
Springer clearly indicate that this species was described based on
ophioblennius larval stage specimens of Scartichthys variolatus. Thus,
Ophioblennius fernandezensis is a junior synonym of Scartichthys
variolatus.

Material examined. Types: MNHN 4410 (1 specimen: 133 mm SL),
holotype of Salarias variolatus, lie Juan Fernandez; MNHN A. 2038 (1:
43), lectotype of Salarias rubropunctatus, lie Juan Fernandez; MNHN
uncat. (4: 43-59), paralectotypes of Salarias rubropunctatus, lie Juan
Fernandez; CAS 5558 through 5564 (examined 3 of 7 specimens: 40-42),
paraytpes of Ophioblennius fernandezensis, Juan Bautista Bay, Juan
Fernandez Island.

Other material examined. Juan Fernandez Islands: BMNH
1935.9.10.19 (1: 117), NMW 73428 (1), MNHNC P. 6. 073 (4), MNHNC P. 6. 212
(1: 163), MNHNC P. 6. 230 (1), MNHNC P.6.AQ8 (1), SIO 65-638 (41), USNM

276

176540 (1: 60), USNM 176546 (11: 45-97), USNM [ (1: 67), ZMB 15661 (3),
ZMB 15663 (4). Isla San Felix: MNHNC P. 6. 406 (1), SIO 65-624 (65:
42-148). San Ambrosio Island: MNHNC P. 6. 166 (2), MNHNC P. 227 (20).

Scartichthys viridis (Valenciennes)

Salarias viridis Valenciennes _in Cuvier and Valenciennes, 1836: 344

(Valparaiso; holotype MNHN A-2128).
Salarias cuvieri Gunther, 1861:248 (Chile; syntypes BMNH 1850.6.14.19

and 1850.6.14.21).
Blennophis semif asciatus Kner and Steindachner , 1866:369 (near Iquique,

west coast of South America).
Salarias concolor Philippi, 1896:380 (Valparaiso; type specimen not

located) .
Salarias modestus Philippi, 1896:381 (not specified but presumably in

Chile; type specimen not located).
Salarias petersoni Fowler, 1940:189 (Antof agasta, Chile; holotype ANSP

69150).

Diagnosis . A species of Scartichthys with more than 94 dentary
incisors and a uniformly brown body, sometimes with a dark-brown
lateral stripe.

Description. Dorsal fin XII, 17-19 (18 in 78.6% ^f specimens); anal
fin 11,19-20; total procurrent caudal-fin rays 13-16; pelvic fin 1,4;
vertebrae 10 + 23-25 (24 in 82.6%) = 33-35 (34 in 82.6%); last pleural
ribs on vertebral centrum 11-12 (12 in 69.6%); last epipleural rib on

277

vertebral centrum 16-21; anal pterygiophores 1-1-2, 1-2-1, or 2-1-1
(1-2-1 in 65.2%); nuchal cirri 6-60 (6-40 in 88.9%); supraorbital cirri
20-51 (20-32 in 87.5%); nasal cirri 6-15 (6-12 in 88.9%); LL tubes
20-22 (21 in 63.6%); last LL tube on base of caudal fin; no scalelike
flaps along LL; lower lip smooth mesially (plicate laterally); gill
]akers 20-26 (based on 13 specimens); pseudobranchial filaments on one
side 9-14 (based on 14 specimens); premaxillary teeth 226-268 (based on
5 specimens); dentary teeth 106-131 (based on 26 specimens; 93 in a 47
mm SL specimen); upper lip crenulae approximately 30-42; nuchal cirri
in 2-4 groups of irregularly shaped cirri with broad separation across
nape (Figure 7); first dorsal-fin spine of adults approximately equal
to second in both sexes; dorsal-fin membrane deeply incised above last
dorsal-fin spine; dorsal-fin membrane attached to caudal peduncle in
advance of caudal fin in adults; cephalic pore system relatively simple
(less than 3 pores at most positions); mid-snout pores present (Figure
17); male genital papilla with urogenital orifice located basally
between two small protuberances on a fleshy swelling behind anus
(Figure 13); testes elongate, length more than twice width; maximum SL
about 200 mm; pupil-sized black spot on distal portion of membrane
between first and second dorsal-fin spines and usually a second spot on
membrane between second and third spines.

The smallest mature female (ova about 0.8 mm diameter) examined was
about 170 mm SL, but females have fully developed ovaries by about 100
mm SL. Males mature by about 100 mm SL.

Color in alcohol. Diffuse pupil-sized black spot behind middle of
posterior margin of eye at all sizes (often difficult to discern in

278

dark specimens). Ophioblennius stage larvae pale with 9 or 10 blotches
on dorsum, pectoral fin with distal half black and proximal half pale.
Adults of both sexes (Figure 68) uniformly dark brown dorsally,
becoming paler ventrally, and sometimes with midlateral dark-brown
stripe (width about equal to eye diameter); all fins dusky; dorsal fin
with pale area over distal tips of anterior three or four spines, other
spines pale tipped, black pupil-sized spot on each of first two or
three interspinal membranes, spots located ventral to pale area.

Color in life. Valenciennes in Cuvier and Valenciennes (1836)
describes the life colors as dark green on the back and somewhat paler
green on the stomach.

Comparisons. Scartichthys viridis is distinctive in having a
relatively uniformly pigmented body without spots. It is further
differentiated from J5. gigas and _S. variolatus in having a high number
of dentary teeth, 106-131 (versus 93 or fewer).

Distribution. Scartichthys viridis occurs from Valparaiso, Chile
northward to Independencia Bay, Peru (Figure 64). Specimens have been
collected from tidepools and rocky shore areas.

Etymology. The specific epithet, viridis , is Latin for green,
referring to the green color of the body in life.

Nomenclatural discussion. Valenciennes in Cuvier and Valenciennes
(1836) described Salarias viridis based on a single specimen (MNHN
A. 2128) from Valparaiso, Chile.

The description of _S_. cuvieri by Gunther (1861) is problematical in
that it appears to be based on two species. He cited data in
Valenciennes' description of S. variolatus , which he placed in the

279

synonymy of S. cuvieri, but based the description on two specimens
(BMNH 1850.6.14.19 and 1850.6.14.21). The specimens he listed as
material of S. cuvieri are referable to Scartichthys viridis.
Smith-Vaniz and Springer (1971) listed these specimens as primary types
of S. cuvieri. As there are type specimens for _S. cuvieri , I consider
the description to apply to these specimens. To avoid future
confusion, I designate one of these (BMNH 1850.6.14.19, 196 mm SL male)
as the lectotype of Salarias cuvieri , and consider it a junior synonym
of _S. viridis.

Kner and Steindachner (1866) described Blennophis semifasciatus
based on an ophioblennius stage larva. Although Smith-Vaniz and
Springer (1971) correctly placed it in the genus Scartichthys, the
characters given in the original description are not sufficient for
assigning the specimen to a particular species of Scartichthys , but the
figure of the type generally resembles ophioblennius larvae of
Scartichthys viridis. I searched the collection of fishes in Vienna,
Austria, where the type was originally deposited, but could not find
the specimen. In addition, the type specimen was not found by V. G.
Springer (pers. comm.) in the Hamburg Museum, where many other
Goddefroy types are located. To avoid future confusion, I have
selected a neotype (USNM 194480, an ophioblennius larva of S_. viridis
from northern Chile) for Blennophis semifasciatus and consider
Blennophis semifasciatus a junior synonym of S_. viridis .

The type specimens of Salarias concolor and S. ntodestus , described
by Philippi (1896), could not be located (may be lost) but appear to be
referable to Scartichthys viridis, based on Philippi's descriptions.

280

Salarias concolor was described by Philippi (1896) from Algarrobo and
Valparaiso. This distribution limits the number of species to which it
can belong and, combined vith Philippi1 s (1896) description, clearly
places this species with S. viridis. Philippi (1896) did not give the
geographic distribution of S^. modestus . He compared his specimens with
S. variolatus, but the color pattern he described clearly fits S_.
viridis. Thus, I place S. modestus in the synonymy of S_. viridis .

Clark (1938) described Ophioblennius xiphiodon based on a mixture
of specimens belonging to Scartichthys gigas and _S. viridis . Based on
the collection locality of the holotype, I place C^. xiphiodnr- in the
synonymy of S. gigas. The two paratypes from Valparaiso, Chile, are
referable to _S. viridis , but all other type specimens are from Peru and
presumably belong to _S. gigas .

Fowler (1940) described Salarias petersoni based on a
metamorphosing specimen from Antofagasta, Chile, that is referable to
Scartichthys viridis. The holotype (ANSP 69150) has lost the large
canines typical of ophioblennius stage larvae, but retains the larval
pigmentation pattern consisting of dark blotches along the dorsum.

Material examined. Types: MNHN A. 2128 (1 specimen: 197 mm SL),
holotype of Salarias viridis, Valparaiso; BMNH 1850.6.14.19 (1: 196),
lectotype of Salarias cuvieri, South America; BMNH 1850.6.14.21 (1:
142), paralectotype of Salarias cuvieri, South America; USNM 194480 (1:
45), neotype of Blenr.cphis semif asciatus , "Atlantis" Cruise 221, 24
54* S, 71° 26' W, dip netted under a night light by S. Bray, 10
December 1955; CAS 5552 (1: 40), paratype of Ophioblennius xiphiodon,
Vlaparaiso Harbor, Chile; ANSP 69150 (1: 46), holotype of Salarias
petersoni , Antofagasta, Chile.

281

Other material examined. Chile: NMW 73462 (1: 128), RMNH 1810 (2:
188, 193), ZMB 1964 (1: 134). Chile, Algarobbo: GCRL 12618 (1: 122),
GCRL 12619 (5: 154-167), USNM uncat. (2: 122, 158). Chile, Arica:
MNHNC uncat. (out of P. 6. 414; 1). Chile, Valparaiso and vicinity:
MNHNC P. 6. 067 (2: 118, 156), MNHNC P. 6. 405 (3: 47-167), MNHNC P. 6. 407
(4), USNM 258788 (14: 38-181), USNM UNCAT. (1: 35), USNM UNCAT. (3:
100-111). Peru: BMNH 1868.1.11.22-3 (2: 169, 179), CAS-SU 48836 (1:
126).

Exallias JORDAN AND EVERMANN

Exallias Jordan and Evermann, 1905:503 (type species Salarias brevis

Kner, 1868a and b, by original designation).
Gloriella Schultz, 1941:17 (type species Cirripectes caninus Herre ,

1936 = Salarias brevis Kner, 1868a and b, by original designation).
Leoblennius Reid, 1943:382 (type species Leoblennius schultzi Reid ,

1943 = Salarias brevis Kner, 1868a and b, by original designation).

Diagnosis. Distinguished from all other salariin blennies by a
unique transverse row of nuchal cirri, in which the lateral cirri
progressively increase in length toward the nape; a single fleshy flap
associated with each of the two anteriormost sensory pores in each
dentary series; and a relatively long and deep-bodied ophioblennius
larval stage.

Nomenclatural discussion. Jordan and Evermann (1905) felt that
Salarias brevis was sufficiently distinct from other blennies to
warrant generic recognition and described the genus Exallias as a
monotypic genus for the reception of £. brevis. Fowler (1928) did not
believe that the characters used by Jordan and Evermann (1905)
warranted generic distinction of the form and made Exallias a subgenus
of Cirripectes . The name Exallias was not used again until Strasburg
and Schultz (1953) reviewed the genus and provided characters to
distinguish it from Cirripectes.

282

283

Exallias brevis (Kner)

Salarias brevis Kner, 1868a:29, and 1868b:334 (Samoa).
Salarias leopardus Day, 1870:518 (Galle Harbor).
Cirripectes caninus Herre , 1936:284 (Ternate, Moluccas).
Ophioblennius phalacrus Clark, 1938:184 (Taiohae Bay, Nukuhiva I.,

Marquesas) .
Leoblennius schultzi Reid, 1943:382 (Honolulu, Hawaii).

Description. Dorsal fin XII, 12-13 (13 in 92.5% of specimens); anal
fin 11,13-14 (14 in 90.0%); total procurrent caudal-fin rays 11-14;
pelvic fin 1,4; vertebrae 10 + 19-21 (20 in 94.7%) = 29-31 (30 in
94.7%); last pleural ribs on vertebral centrum 12; last epipleural rib
on vertebral centrum 18-21 (19-21 in 97.4%); anal pterygiophores 1-1-1
or 1-1-2 (1-1-1 in 86.8%); nuchal cirri 28-39 (30-37 in 87.5%);
supraorbital cirri 11-34 (highly variable with no strong mode); nasal
cirri 8-26 (10-17 in 82.1%); LL tubes 0-6; last LL tube on caudal-fin
base (rarely, in advance of vertical from last dorsal-fin ray); no
scalelike flaps along LL; lower lip heavily folded; gill rakers 17-22
(based on 37 specimens); pseudobranchial filaments on one side 9-15
(based on 37 specimens); dentary teeth 40-71 (based on 40 specimens);
upper lip crenulae approximately 17-26; nuchal cirri in a continuous

284

row across nape, rarely with a slight notch at the dorsal midline, with
the length of individual cirri gradually increasing in length toward
the middle of nape (lateral cirri as little as one-fourth length of
those at nape); dorsal-fin membrane deeply incised above last
dorsal-fin spine; dorsal-fin membrane attached to caudal fin in adults;
cephalic pore system complex ( 3 or more pores at most positions; number
of pores increases with increasing SL); mid-snout pores present (Figure
17); extra interorbital pore position present (Figure 17); 2 pore
positions behind nuchal flap (Figure 17); male genital papilla with
urogenital orifice located basally behind a single slender filament
(less than 1.0 mm long) on a fleshy swelling behind anus (type IV;
Figure 13); testes elongate, length equals about twice width; maximum
SL about 100 nm.

The smallest mature female (ova about 0.5 mm diameter) examined was
about 65 mm SL. Males mature by about 60 mm SL.

Color in alcohol. Ophioblennius stage larvae have uniformly
pale-brown body with several brown blotches on nape, cheeks,
pectoral-fin base, and dorsal part of body beneath spinous-dorsal fin;
dorsal fin transluscent with 5-6 brown blotches on basal quarter of
spinous-dorsal fin; pale-brown blotches basally on segmented-dorsal
fin, blotches becoming fainter posteriorly; pectoral fin with several
brown blotches on basal half of fin and dark-brown marginal band
restricted to interradial membranes; otherwise, fins transluscent.

Juveniles have scattered brown spots, about half pupil diameter in
size, on pale background on head, body, and fins; about 5-6 bars on
body, each bar overlain with paired columns of spots.

285

As specimens increase in size, spots increase in number and
decrease in size. Adults (Figure 69) of both sexes with fairly dense
covering of spots arranged in clusters of 5-10 roughly hexagonal-shaped
spots separated from other clusters by narrow pale interspaces; overall
pattern on body consisting of about 5-6 broad bars (comprising clusters
of brown spots described above) with narrow pale interspaces; fleshy
rugosities on anal-fin spines of males black; iris pale with 4-5 black
spots equally spaced along outer margin; cirri mottled with brown and
white.

Color in life. Herre (1939) described the life colors of an
ophioblennius stage larva as "yellow, with large brown spots between
pectoral and dorsal, and small brown spots all over head and on
pectoral base; 10 blackish-brown spots or vertical bands on dorsal;
brown spots on pectoral, tips of rays black; other fins colorless."

Juveniles (Masuda et al., 1975) have a white head and body with
yellowish-brown spots. Spots on head behind eye are dark brown and
typically darker than other spots. All fins are yellow with small
brown spots.

Adult female coloration (Masuda et al., 1975; Randall, 1982b) is
similar to that of juveniles except the spots are brown, smaller, and
more densely spaced. Adult males (Masuda et al . , 1984; Randall, 1981)
are essentially bicolored, with about anterior third of body similar in
coloration to that of juveniles and females, and posterior portion of
body, including dorsal, caudal, and basal part of anal fins, almost
uniformly scarlet (most of the red color is concentrated in the
spots). Most spots have a small black center. Light parts of iris
vary in color from white to yellow.

286

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Figure 69. Male Exallias brevis, Chagos Archipelago (ROM uncat.:
71 mm SL).

287

Distribution. Exallias brevis is a widely distributed coral reef
inhabitant found throughout the tropical and subtropical Indo-Pacif ic .
It occurs from South Africa to the northern Red Sea eastward to the
Marquesas Islands (Figure 70).

Comments. Despite the extensive geographic range of Exallias
brevis , most characters examined show very little variation among
populations. It is possible that some geographic variation exists, but
there are too few specimens from the same localities in museum
collections on which to base any sound conclusions.

Nomenclatural discussion. Kner (1868a, b) described Salarias
brevis based on a single specimen taken at Savaii, Samoa. Day (1870)
described S. leopardus based on a single specimen "dredged up off Galle
Harbor," Ceylon (=Sri Lanka). Day's description of _S. leopardus
clearly fits the species described by Kner two years earlier and, thus,
is a junior synonym of _S_. brevis .

Schultz (1941) recognized both C_. leopardus and _C. brevis as valid
species. The specimens Schultz (1941) referred to as C_. brevis were
actually specimens of another species that was later described
(Strasburg and Schultz, 1953) as C_. fuscoguttatus . Chapman (1951)
followed Schultz (1941) in recognizing C. leopardus as a valid
species. Strasburg and Schultz (1953) and Strasburg (1956) recognized
Exallias as a distinct genus containing only S. brevis , and listed
Salarias leopardus as a junior synonym.

Three other species (Cirripectes caninus Herre, Ophioblennius
phalacrus Clark, and Leoblennius schultzi Reid) were each based on
ophioblennius larval stage individuals. Each of these species are
referable to Exallias brevis, and are junior synonyms of that species.

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Material examined. Types: NMW 75387 (female: 77 mm SL), holotype
of Salarias brevis , Savay, Samoa Islands, collected in 1868; CAS-SU
29082 (1: 23), holotype of Cirripectes caninus, Molluccas Islands,
Ternate Island, collection date unknown; CAS 5566 (1: 25), holotype of
Ophioblennius phalacrus, Marquesas Islands, Nuku Hiva, Taiohae Bay,
2-15 Oct. 1934; USNM 118037 (1: 25), holotype of Leoblennius schultzi,
Hawaiian Islands, off Honolulu, Diamond Head Light, 6 May 1902.

Other material examined. South Africa: RUSI 67-11 (1: 53), RUSI
7514 (1: 42), RUSI 9628 (1: 53). Cumoros Islands: USNM 201875 (1).
Tanzania: USNM 201873 (2). Kenya- USNM UNCAT. (1). Egypt: HUJF
7719 (2: 58, 59). Maldive Islands: SMF 13587 (1: 88). Cargados
Carajos Shoals: USNM UNCAT. (1). Chagos Archipelago: ROM 50266 (1:
71), ROM 50267 (6: 56-77). Galle, Sri Lanka: USNM UNCAT. (1).
Christmas Island, Indian Ocean: AMS 1.20446-012 (1: 74), WAM
P. 26083-014 (1: 76). Malacca Strait: USNM 199420 (1). Indonesia:
AMS 1.19875-013 (1: 68). Philippines: USNM 122280 (1). Papua-New
Guinea: USNM UNCAT. (1). Australia, Western Australia: WAM
P. 25368-010 (1: 58), WAM P. 25827-001 (1: 61). Australia, Queensland:
AMS 1.19481-031 (2: 78, 85). Vanuatu (New Hebrides): AMS 1.17473-040
(1: 74). Fiji Islands: ROM UNCAT. (2: 44, 83; WE 83-29), ROM UNCAT.
(1: 61; WE 83-46), ROM UNCAT. (4: 41-91; WE 83-57). Caroline Islands:
CAS 38831 (2 of 5 examined: 58, 87). Marshalls Islands: USNM 166786
(1). Hawaiian Islands: ZMB 6093 (1). Howland Island: USNM 198701
(1). Samoa: USNM 115703 (1). Vostok Island: USNM 200544 (1).
Tuamotu Archipelago: BPBM UNCAT. (1).

HISTORICAL ZOOGEOGRAPHY

Springer (1982) cited the importance of cladistic analyses of
organisms to what he termed vicariography (vicariance biogeography) .
Parenti (1981) referred to the combining of vicariance biogeography
with hypotheses of phylogenetic systematics as cladistic biogeography.
Rosen (1978), Platnick and Nelson (1978), and Nelson and Platnick
(1981) discussed a method for transforming a cladogram of phylogenetic
relationships into an area cladogram by replacing the terminal taxa
with their respective geographic distributions. If area cladograms for
several different taxa are congruent, a general distributional pattern,
a generalized track (Croizat et al . , 1974), is supported. Once
recognized, tracks can be used to search for geological or other
vicariance events in earth history that explain the observed patterns.
This was the approach taken by Springer (1982), but, as he pointed out,
there are very few cladistic studies of Indo-Pacific organisms. The
scarcity of cladistic studies also pertains to organisms in most other
oceans .

In view of the scarcity of cladistic analyses of organisms with
distributions similar to Cirripectes and its allies, I rely heavily on
the relationships among taxa presented in Figures 1 and 15 and their
corresponding area cladograms (Figures 71 and 72). To facilitate
comparison, the nodes of the area cladograms are numbered in the same

291

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order as the nodes on the taxonomic cladograms. Although my analysis
is restricted to blenniid taxa, it comprises several tracks that are
congruent with tracks described by Rosen (1976), Springer (1982), and
Vari (1978). I have not proposed vicariant events to explain the
tracks. Cladistic analyses of other taxa are needed to support the
tracks proposed herein.

I tentatively recognize the following eleven tracks: (1)
circumglobal tropical-to-temperate coastal marine — the entire family,
(2) circumglobal tropical and subtropical — Salariini, (3) eastern
Pacific to eastern Atlantic — Scartichthys and Qphioblennius (node VII
group), (4) western South American-Caribbean Plate track — a subunit of
number (3), (5) Indo-Pacific track — many salariin genera, (6) Pacific
Plate track of Springer (1982), (7) Indo-West Pacific track of Vari
(1978), (8) ant i tropical track — Cirripectes alboapicalis-C. obscurus
group in the Pacific and the disjunct distribution of Pereulixia in the
Indian Ocean, (9) eastern Indian Ocean-western Indian Ocean — C_.
randalli and C_. hutchinsi , (10) track C of Vari (1978) — C_. springeri ,
and (11) C. chelomatus-C. f ilamentosus track.

The present distribution of the Blenniidae describes a track
comprising circumglobal tropical to temperate marine coastlines. The
family track contains numerous less extensive tracks described by the
geographical distribution of component taxa of the Blenniidae.

The track of the Salariini resembles that of the family, but does
not include the Mediterranean Sea or temperate coastlines (with a few

297

exceptions). The majority of the salariin genera have an Indo-Pacif ic
distribution, with only one (Entomacrodus ) purportedly occurring from
the Indo-Pacif ic to the Caribbean and Atlantic (Springer, 1967), but
Entomacrodus may be polyphyletic (Springer, pers. comm.). Among the
Salariini, only Scartichthys is restricted to the eastern Pacific and
only Ophioblennius is distributed from the eastern Pacific to the
islands of the eastern Atlantic Ocean (the eastern Pacific-eastern
Atlantic track of Rosen, 1976). Each of these tracks (subunits of the
Salariini track) is discussed below.

Rosen (1976) described the eastern Pacific-eastern Atlantic track
as being the oldest transoceanic generalized track in this region of
the world. Among the Salariini, the combined geographic distribution
of Scartichthys and Ophioblennius is congruent with this track.

Scartichthys is distributed along the western coast of South
America from central Chile to Panama, with _S. variolatus restriced to
San Felix and San Ambrosio islands, and Juan Fernandez Islands, on the
Nazca Plate. The other three species are restricted to the western
margin of the South American Plate. Scartichthys gigas occurs from
Panama to northern Chile. Scartichthys viridis occurs from southern
Peru to the area around Valparaiso, Chile. These two species occur
sympatrically in northern Chile and southern Deru. Scartichthys
crapulatus , restricted to Chile, occurs sympatrically with S_. viridis .

Ophioblennius occurs sympatrically with Scartichthys from Peru to
Panama, but Ophioblennius has a more extensive geographic range that
extends northward to the Revillagigedos Islands and eastward to the
eastern Atlantic Ocean. Ophioblennius comprises two recognized

298

species, the eastern Pacific _0. steindachneri and the Caribbean-eastern
Atlantic 0. atlanticus , each with two subspecies (Springer, 1962;
Springer, pers. comm., now believes all the subrpecies should be
accorded species-level recognition).

The geographic distributions of the node VTI genera (Scartichthys
and Ophioblennius) have geological correlations. The phylogenetic
relationships between the node VTI genera suggest a historic connection
between western South America and the Caribbean. The split in the
ancestral distribution may have occurred along the boundary between the
South American and Caribbean plates. If this hypothesis is correct,
the present-day sympatric occurrence of the node VTI genera in
northwestern South America is evidence of dispersal of the two sister
genera.

The two species of Ophioblennius have an eastern Pacific-Caribbean
relationship. This relationship presumably represents the division of
a continuous ancestral population by the development of the Central
American land barrier.

The Indo-Pacific track is a generalized track comprising two widely
recognized tracks, the Pacific Plate track of Springer (1982) and the
Indo-West Pacific track of Vari (1978). The Indo-Pacific track is
approximated by the distributions of Cirripectes quagga , C_. auritus , C_.
perustus, C. polyzona, and C. s tigmaticus . The combined distributions
of the taxa at almost every node on the generic area cladogram, and
many nodes on the Cirripectes area cladogram, approximate this
generalized track.

299

Springer (1982) demonstrated the presence of a generalized Pacific
Plate track, and also discussed numerous distribution patterns that fit
the Indo-West Pacific track, the boundary between the two tracks being
the western margin of the Pacific lithospheric plate. Among the
species of Cirripectes, C_. fuscoguttatus is a Pacific Plate endemic
associated in a trichotomy (node XI group) with the Japan-Taiwan
endemic, C. imitator , and the Indian Ocean endemic, C_. gilberti .
Another trichotomous sister-group relationship (node XII group) exists
between the Pacific Plate endemic, C_. variolosus, the Hawaiian
Islands-Johnston Island endemic, C_. vanderliilti , and the primarily
Indo-West Pacific node XIII group. The geographic distribution of C_.
auritus, C. perustus, and the node XVI group is evidence of dispersal
onto the Pacific Plate, probably via the Caroline Islands conduit
described by Springer (1982).

The distributional track of the node VIII group comprises three
subunits, antitropical Pacific, Pacific Plate, and Indo-Pacific
components. The node IX sister group relationship between Cirripectes
obscurus, the Hawaiian Islands endemic, and C_. alboapicalis , which is
distributed south of 20° S latitude from eastern Australia to Isla de
Pascua (Easter Island), makes up the antitropical component. This
antitropical component generally fits the pattern discussed by Randall
(1982a) for Pacific taxa.

The Pacific Plate endemic, C. jenningsi , occurs in the intervening
area between the antitropically distributed species, where it is
distributed from the Gilbert Islands to the Tuamotu Archipelago.

300

The geographic distribution of the last member of the node VIII
group, C. quagga, encompasses the distributions of all other members of
the node VIII group and extends into the western Indian Ocean. The
geographic distribution of C_. quagga is evidence of dispersal, but its
sister group within the node VIII group has not been determined; thus,
the extent of its dispersal is as yet unknown.

Another subunit of the Indo-West Pacific track is an eastern Indian
Ocean-western Indian Ocean track. This track is weakly supported by
the node IV group and a trichotomy at node XIII. At node IV,
Pereulixia kosiensis is restricted to the western Indian Ocean, where
it appears to have an antitropical distribution. It occurs in South
Africa, Mozambique, and in Pakistan .(Hoda , 1980). As there has been
relatively little collecting effort expended along the eastern African
coast, the known distribution of Pereulixia may be a collecting
artifact. Other members of the node IV group are either widespread
Indo-Pacific taxa that are at least partially sympatric with
Pereulixia, or are restricted to the eastern Pacific and/or Caribbean
regions. Although node XIII is an unresolved trichotomy, two of the
taxa, the Cargados Carajos Shoals-Mauritius endemic, Cirripectes
randalli , and the western Australian endemic, C_. hutchinsi , exhibit the
eastern Indian Ocean-western Indian Ocean distribution pattern. In
addition, the occurrence of these two species south of 20 S latitude
(although C. randalli occurs at latitudes slightly lower than 20 S)
concurs with the southern end of the antitropical distribution track.

Within the node XVII group there are two tracks. The first track
is represented by the distribution of Cirripectes springeri , which

301

occurs from the Philippines and along the northern coast of New Guinea
to the Solomon Islands. This distributional pattern fits within track
C of Vari (1978). Geologically, the pattern follows the western
margins of the Philippine and Pacific Plates (essentially follows the
Melanisian borderlands, a geologically recognized tectonic unit,
Springer, pers. comm.). The sister group of C_. springeri is uncertain,
as the relationships within the node XVII group are unresolved. If C.
perustus is its sister species, then there is evidence of dispersal in
that their ranges overlap in the Philippines and the Bismarck
Archipelago. The distribution of C_. perustus is completely within that
of the more widely distributed _C. f ilamentosus , but the distribution of
C_. chelomatus overlaps only that of C_. f ilamentosus, and then only
slightly.

The combined distribution of C^. chelomatus and C. f ilamentosus
describes a second track consisting of a Coral Sea to Tonga Islands
component ( Cirripectes chelomatus ) and an Indo-West Pacific component
(_C. f ilamentosus) . Evidence of dispersal within this group is the
sympatry of the two species in the northern Coral Sea.

The validity of some of the tracks discussed is relatively certain
(i.e. Pacific Plate track, Indo-Pacific track, eastern Pacific-eastern
Atlantic track), but most of the other tracks I discussed have not been
corroborated. The area cladograms (Figures 71 and 72) predict that
these tiacks will be congruent with area cladograms for other taxa in
these geographic areas, but this prediction can only be tested by
phylogenetic analyses of additional taxa. I hope my hypotheses will
help to stimulate such studies.

APPENDIX

Table 5. Table of material used for osteological studies.

Family Tribe

Species

Catalog Numbers

Dactyloscopidae

Dactylagnus mundus USNM 270277 (1)

USNM 270365 (2)

USNM 200385 (2)

Dactyloscopus crossotus USNM 270360 (2)

Dactyloscopus tridigitatus USNM 269550 (2)

Tripterygiidae — Enneanectes altivelis UF 16179 (2)

Chaenopsidae

Hemiemblemaria simulus UF 19112 (1)
Acanthemblemaria aspera UF 11881 (2)
Emblemariopsis signifera UF uncat . (1)

Clinidae

Gibbonsia elegans erroli USNM 200386 (2)

Labrisomidae

Paraclinus nigripinnis UF uncat. (1)
Labrisomus nuchipinnis UF uncat. (1)

Blenniidae Blenniini Blennias normani

Blennius ocellaris

Salariini Alticus saliens

Alloblennius pictus

USNM 199533 (2)
USNM 48387 (1)
USNM 205157 (1)
USNM 227848 (2)
USNM 203766 (2)

303

Table 5. Continued.

304

Family

Tribe

Snecies

Catalog Numbers

Andamia reyi

Antennablennius bifilum
Atrosalarias fuscus
Cirripectes castaneus
Cirripectes chelomatus
Cirripectes f ilamentosus
Cirripectes fuscoguttatus

Cirripectes gilberti
Cirripectes imitator
Cirripectes jenningsi
Cirripectes obscurus
Cirripectes perustus
Cirripectes quagga

Cirripectes polyzona
Cirripectes randalli
Cirripectes springeri

Cirripectes stigmaticus

USNM 227797 (2)
USNM 200207 (2)
USNM 227555 (2)
USNM 228189 (2)
USNM 258751 (2)
USNM 228108 (2)
USNM 198700 (1)
USNM 200612 (1)
USNM 227867 (1)
ROM 46597 (1)
USNM 227980 (1)
USNM 200615 (5)
BPBM uncat. (2)
ROM 46594 (1)
USNM 111603 (4)
USNM 198751 (2)
USNM 200605 (2)
USNM 227688 (2)
BPBM 20165 (1)
USNM 228287 (1)
USNM 228294 (1)
USNM 223457 (2)

Table 5. Continued.

305

Family

Tribe

Species

Catalog Number

Cirripectes vanderbilti
Cirripectes variolosus
Crossosalarias macrospilus
Ecsenius bicolor
Ecsenius yaeyamaensis
Entomacrodus cymatobiotus
Entomacrodus epalzeochilus
Entomacrodus nigricans
Entomacrodus stellifer
Exallias brevis

Hirculops cornifer
Istiblennius gibbifrons
Istiblennius lineatus
Litobranchus fowleri
Mimcblennius atrocinctus

Nannosalarias nativitatus
Ophioblennius atlanticus

macclurei
Pereulixia kosiensis
Praealticus sp.

USNM 142114 (2)

USNM 200614 (3)

USNM 205711 (1)

USNM 211914 (2)

USNM 211924 (2)

USNM 198654 (2)

USNM 269464 (1)
UF 17048 (2)

USNM 132795 (1)

USNM 224383 (2)

USNM 200544 (1)

USNM 200030 (2)

USNM 228313 (2)
UF uncat. (1 )

USNM 227798 (1)

USNM 197980 (1)

USNM 216676 (2)

USNM 201369 (1)

UF 10746 (2)

USNM 197637 (1)

USNM 228318 (2)

Table 5. Continued.

306

Family

Tribe

Species

Catalog Number

Rhabdoblennius snowi

Scartichthys gigas

Stanulus seychellensis

USNM 228315 (2)

USNM 200396 (2)

USNM 227556 (2)

USNM 227981 (2)

USNM 228316 (2)

Nemophini Meiacanthus grammistes
Omobranchini Enchelyurus kraussi

Omobranchus punctatus
"Blenniini" Chasmodes bosquianus

bosquianus
Chasmodes bosquianus

longimaxilla
Chasmodes saburrae

Hypleurochilus geninatus
Hypsoblennius hentz
Parablennius marmoreus
Scartella cristata

USNM 201363 (1)
USNM 200609 (1)
USNM 174330 (1)

UF 28296 (1)

USA 6005 (3)
UF uncat. (1 )
UF uncat. (2)
UF 19621 (1)
UF 2584 (1)
UF 11021 (2)
UF 11020 (2)

LITERATURE CITED

Allen, G. R. , D. F. Hoese, J. R. Paxton, J. E. Randall, B. C. Russell,
W. A. Starck II, F. H. Talbot, and G. P. Whitley. 1976. Annotated
checklist of the fishes of Lord Howe Island. Records of the
Australian Museum 30:365-454.

Alleyne, H. G. , and W. Macleay. 1877. The ichthyology of the Chevert
Expedition. Proceedings of the Linnean Society of New South Wales
1:321-359.

Bath, H. 1977. Revision der Blenniini. Senckenbergiana Biologica
57:167-234.

Bleeker, P. 1868. Description de deux especes nouvelles de

blennioides de l'Inde Archipelagique . Verslagen en Mededeelingen
der Koninklikje Akademie van Wetenschappen, Letterkunde, en Schoone
Kunsten te Amsterdam, ser. 2, 2:278-280.

Bleeker, P. 1983. Atlas Ichthyologique . Smithsonian Institution
Press, Washington. Vol. 11:1-22, pis. 421-447.

Borodin, N. A. 1927. A new blenny from the Hawaiian Islands.
American Museum Novitates 281:1-2.

Borodin, N. A. 1928. Exallias obscurus Borodin vs. Cirripectes
alboapicalis (Ogilby) . Copeia 1927:53-54.

Carlson, B. A. 1981. A new Indo-Pacific fish of the genus Cirripectes
(Blenniidae, Salariini). Pacific Science 34:407-414.

Chapman, W. M. 1951. Family Blenniidae. Pages 242-355 _in L. E. de
Beaufort and W. M. Chapman. Fishes of the Indo-Australian
Archipelago. E. J. Brill, Leiden, Holland. Vol. 9.

Clark, H. W. 1938. The Templeton Crocker Expedition of 1934-35. No.
36. Additional new fishes. Proceedings of the California Academy
of Sciences, ser. 4, 22:179-185.

Cohen, D. M. 1956. Notes on the identity of several salariine

blennies of the genus Scartichthys from western South America.
Copeia 1956:246-248.

Croizat, L. , G. J. Nelson, and D. E. Rosen. 1974. Centers of Origin
and related concepts. Systematic Zoology 22:265-287.

Cuvier, G. F. L. C. D. , and A. Valenciennes. 1836. Histoire naturelle
des poissons. F. G. Levrault, Paris, France. Vol. 11:1-506.

307

308

Day, F. 1870. Remarks on some fishes in the Calcutta Museum. Part
1. Proceedings of the Scientific Meetings of the Zoological
Society of London for the year 1869:511-527.

Day, F. 1888. Supplement to the fishes of India. Williams and
Norgate Publishers, London, England. Pages 779-816.

Day, F. 1889. The fauna of British India, including Ceylon and Burma.
Fishes. Taylor and Francis, London, England. Vol. 2, 509 pp.

De Buen, F. 1963. Los peces de la Isla de Pascua. Boletin de la
Sociedad de Biologia de Concepcion, Chile, 1960-61, 35-36:3-80.

Dingerkus, G. , and L. D. Uhler. 1977. Enzyme clearing of alcian blue
stained whole small vertebrates for demonstration of cartilage.
Stain Technology 52:229-232.

Fowler, H. W. 1923. New or little-known Hawaiian fishes. Occasional
Papers of the Bernice P. Bishop Museum 8:373-392.

Fowler, H. W. 1927. Notes on Exallias obscurus Borodin. Copeia
1927:91-92.

Fowler, H. W. 1928. The fishes of Oceania. Memoir of the Bernice P.
Bishop Museum 10:1-540.

Fowler, H. W. 1938. The fishes of the George Vanderbilt South Pacific
Expedition. Academy of Natural Sciences of Philadelphia, Monograph
2:1-349.

Fowler, H. W. 1940. Fishes obtained in Chile by Mr. D. S. Bullock.
Proceedings of the Academy of Natural Sciences of Philadelphia
92:171-190.

Fowler, H. W. 1946. A collection of fishes obtained in the Riu Kiu
Islands by Captain Ernest R. Tinkham A. U. S. Proceedings of the
Academy of Natural Sciences of Philadelphia 98:123-218.

Fowler, H. W. , and S. C. Ball. 1924. Descriptions of new fishes

obtained by the Tanager Expedition of 1923 in the Pacific Islands
west of Hawaii. Proceedings of the Academy of Natural Sciences of
Philadelphia 76:269-274.

Fukao, R. 1984. Review of the Japanese fishes of the genus

Cirripectes (Blenniidae) with description of a new species.
Japanese Journal of Ichthyology 31:105-121.

Garman, S. 1903. Some fishes from Australasia. Bulletin of the
Museum of Comparative Zoology, Harvard 39:229-241.

309

George, A., and V. G. Springer. 1981. Revision of the clinid fish
tribe Ophiclinini, including five new species, and definition of
the family Clinidae. Smithsonian Contributions to Zoology
307:1-31.

Gosline, W. A. 1955. The inshore fish fauna of Johnston Island, a
Central Pacific Atoll. Pacific Science 9:442-480.

Gunther, A. C. L. G. 1861. Catalogue of the Acanthopterygian fishes
in the collection of the British Museum. N.P., London, England.
Vol. 3, 586 pp.

Gunther, A. C. L. G. 1877. Andrew Garrett's Fische der Sudsee. VI.
Journal des Museum Godeffroy 13:169-216, pis. 101-120.

Hennig , W. 1966. Phylogenetic systematics. University of Illinois
Press, Urbana, Illinois. 263 pp.

Herre, A. W. C. T. 1936. Fishes in the Zoological Museum of Stanford
University, III. New genera and species of gobies and blennies and
a new Myxus , from the Pelew Islands and Celebes. Philippine
Journal of Science 59:275-287.

Herre, A. W. C. T. 1939. The Philippine blennies. Philippine Journal
of Science 70:315-373.

Herre, A. W. C. T. 1953. Check list of Philippine fishes.
Department of the Interior, Research Report 20:1-977.

Hildebrand, S. F. 1946. A descriptive catalog of the shore fishes of
Peru. United States National Museum Bulletin 189:1-530.

Hoda, S. M. S. 1980. Blenniid fishes from the Karachi Coast.

Proceedings of the 1st Pakistani Congress of Zoology B:437-447.

Kner, R. 1868a. Uber neue fische aus dem Museum der Herren Johann
Casar Godeffroy & Sohn in Hamburg. Sitzungsberichte der
Kaiserlichen Akademie der Wissenschaf ten in Wien 58, part 1, 26-31.

Kner, R. 1868b. Uber neue fische aus dem Museum der Herren Johann
Casar Godeffroy & Sohn in Hamburg. Sitzungsberichte der
Kaiserlichen Akademie der Wissenschaf ten in Wien 58(part 7 ) : 334 .

Kner, R. , and F. Steindachner . 1866. Neue fische aus der Herren Joh.
C. Godeffroy & Sohn in Hamburg. Sitzungsberichte der Kaiserlichen
Akademie der Wissenschaf ten in Wien 54:356-395.

Jones, S., and M. Kumaran. 1980. Fishes of the Laccadive Archipelago.
Nature Conservation and Aquatic Sciences Service, Trivandrum,
India. 760 pp.

310

Jordan, D. S. , and B. W. Evermann. 1896. A check-list of the fishes

and fish-like vertebrates of North and Middle America. United

States Commission of Fish and Fisheries, Report of the Commissioner
for the Year Ending June 30. 1895(21 ): 209-584.

Jordan, D. S., and B. W. Evermann. 1898. The fishes of North and
Middle America. United States National Museum Bulletin 47(Part
3):2183-3136.

Jordan, D. S., and B. W. Evermann. 1905. The aquatic resources of the
Hawaiian Islands. Part I. The shore fishes. United States Bureau
of Fisheries, Bulletin (1903) 23:1-574.

Leis, J. M. , and D. M. Rennis. 1983. The larvae of Indo-Pacific coral
reef fishes. University of Hawaii Press, Honolulu, Hawaii. 269
pp. , 75 pis.

Leviton, A. E. , R. H. Gibbs , Jr., E. Heal, and C. E. Dawson. 1985.
Standards in herpetology and ichthyology: Part I. Standard
symbolic codes for institutional resource collections in
herpetology and ichthyology. Copeia 1985:802-832.

Lotan, R. 1970. Systematic remarks on fishes of the family Salariidae
in the Red Sea. Israel Journal of Zoology 18:363-378.

Maddison, W. P., M. J. Donoghue, and D. R. Maddison. 1984. Outgroup
analysis and parsimony. Systematic Zoology 33:83-103.

Masuda, H. , K. Amaoka , C. Araga, T. Uyeno , and T. Yoshino, editors.
1984. The fishes of the Japanese Archipelago. Tokai University
Press, Tokyo, Japan. 437 pp., 370 pis.

Masuda, H. , C. Araga, and T. Yoshino. 1975. Coastal fishes of

southern Japan. Tokai University Press, Tokyo, Japan. 382 pp.

Masuda, H. , C. Araga, and T. Yoshino. 1980. Coastal fishes of

southern Japan. Revised edition, Tokai University Press, Tokyo,
Japan. 382 pp.

McCulloch, A. P., and F. A. McNeill. 1918. Some Australian blennioid
fishes. Australian Museum Records 12:1-25, 4 pis.

Nelson, G. , and N. Platnick. 1981. Systematics and Biogeography

Cladistics and Vicariance. Columbia University Press, New York,
New York. 567 pp.

Norman, J. R. 1943. Notes on the blennioid fishes. I. A provisional
synopsis of the genera of the family Blenniidae. Annals & Magazine
of Natural History, Ser. 11, 10:793-812.

Ogilby, J. D. 1889. The reptiles and fishes of Lord Howe Island.
Memoirs of the Australian Museum 2:51-74.

311

Ogilby, J. D. 1899. Additions to the fauna of Lord Howe Island.

Proceedings of the Linnean Society of New South Wales 23:730-745.

Parenti, L. R. 1981. A phylogenetic and biogeographic analysis of
cyprinodontiform fishes (Teleostei, Atherinomorpha) . Bulletin of
the American Museum of Natural History 168:335-557.

Philippi, R. A. 1896. Peces nuevos de Chile. Anales de la
Universidad, Chile 93:375-390.

Platnick, N. , and G. J. Nelson. 1978. A method of analysis for
historical biogeography. Systematic Zoology 27:1-16.

Randall, J. E. 1955. Fishes of the Gilbert Islands. Atoll Research
Bulletin 47:1-243.

Randall, J. E. 1981. Underwater guide to Hawaiian Reef fishes.
Harrowood Books, Newtown Square, Pennsylvannia. 71 pp.

Randall, J. E. 1982a. Examples of antitropical and antiequatorial
distribution of Indo-West-Pacif ic fishes. Pacific Science
35:197-209.

Randall, J. E. 1982b. The divers guide to Red Sea Reef Fishes. Immel
Publishing, London, England. 2 pp. + 325 figs.

Rehder, H. A. 1981. The marine molluscs of Easter Island (Isla de
Pascua) and Sala y Gomez. Smithsonian Contributions to Zoology
289:1-167.

Reid, E. D. 1943. Review of the genera of blennioid fishes related to
Ophioblennius. Journal of the Washington Academy of Sciences
33:373-384.

Rosen, D. E. 1976. A vicariance model of Caribbean biogeography.
Systematic Zoology 24:431-464.

Rosen, D. E. 1978. Vicariant patterns and historical explanation of
biogeography. Systematic Zoology 27:159-188.

Russell, B. C. 1983. Annotated checklist of the coral reef fishes in
the Capricorn-Bunker Group, Great Barrier Reef, Australia. Great
Barrier Reef Marine Park Authority, Australia. 184 pp.

Schultz, L. P. 1941. The species of Cirripectes Swainson and a new
genus of blennioid fishes from the tropical Pacific. Copeia
1941:17-20.

Schultz, L. P. 1943. Fishes of the Phoenix and Samoan Islands
collected in 1939 during the Expedition of the U. S. S.
"Bushnell." United State's National Museum Bulletin 180:1-316.

312

Schultz, L. P., and W. M. Chapman. 1960. Fishes of the Marshall and
Marianas Islands. Subfamily Salariinae. United States National
Museum Bulletin 202:302-372.

Seale, A. 1901. Report of a mission to Guam. Part 2. Fishes.
Occasional Papers of the Bernice P. Bishop Muswum 1:61-128.

Shen, S.-C. 1984. Coastal fishes of Taiwan. Shih-chieh Shen, Taipei,
Taiwan. 190 pp.

Smith, H. M. 1934. The blenniid fishes of Siam, with descriptions of
new species. Journal of the Siam Society, Natural Histroy
Supplement 9:315-323.

Smith, J. L. B. 1947. New Species and new records of fishes from
South Africa. Annals & Magazine of Natural History, Series 11,
13:793-821.

Smith, J. L. B. 1959. Fishes of the families Blenniidae and
Salariidae of the western Indian "Ocean. Rhodes University,
Department of Ichthyology, Ichthyological Bulletin 14:229-252.

Smith, J. L. B., and M. M. Smith. 1963. The fishes of Seychelles.
Rhodes University, Grahamstown, South Africa. 215 pp.

Smith-Vaniz, W. F. 1976. The saber-toothed blennies, tribe Nemophini
(Pisces: Blenniidae). Academy of Natural Sciences of
Philadelphia, Monograph 19:1-196.

Smith-Vaniz, W. F. , and V. G. Springer. 1971. Synopsis of the tribe
Salariini, with description of five new genera and three new
species (Pisces: Blenniidae). Smithsonian Contributions to
Zoology 73:1-72.

Snyder, J. 0. 1908. Descriptions of eighteen new species and two new
genera of fishes from Japan and the Riu Kiu Islands. Proceedings
of the United States National Museum 35:93-111.

Springer, V. G. 1962. A review of the blenniid fishes of the genus
Ophioblennius Gill. Copeia 1962:426-433.

Springer, V. G. 1967. Revision of the circumtropical shorefish genus
Entomacrodus . Proceedings of the United States National Museum
122:1-150.

Springer, V. G. 1968a. The Indo-Pacific blenniid fish genus

Stanulus , with description of a new species from the Great Barrier
Reef (Blenniidae; Blenniinae; Salariini). Proceedings of the
Biological Society of Washington 81:111-121.

Springer, V. G. 1968b. Osteology and classification of the fishes of
the family Blenniidae. United States National Museum Bulletin
284:1-85.

313

Springer, V. G. 1970. The blennies. Tropical Fish Hobbyist 19(176,
no. 2):54-66.

Springer, V. G. 1971. Revision of the fish genus Ecsenius

(Blenniidae, Blenniinae, Salariini). Smithsonian Contributions to
Zoology 72: 1-74.

Springer, V. G. 1982. Pacific Plate biogeography , with special

reference to shorefishes. Smithsonian Contributions to Zoology
367:1-182.

Springer, V. G. , and W. F. Smith-Vaniz. 1972. A new tribe

(Phenablennini) and genus (Phenablennius) of blenniid fishes based
on Petroscirtes heyligeri Bleeker. Copeia 1972:64-71.

Steindachner , F. 1876. Ichthyologische Beitrage (V).

Sitzungsberichte der Kaiserlichen Akademie der Wissenschaf ten in
Wien 74:49-240.

Strasburg, D. W. 1956. Notes on the blennioid fishes of Hawaii with
descriptions of two new species. Pacific Science 10:241-267.

Strasburg, D. W. , and L. P. Schultz. 1953. The blenniid fish genera
Cirripectus and Exallias with description* of two new species from
the tropical Pacific. Journal of the Washington Academy of Sciences
43:128-135.

Swainson, W. 1839. The natural history and classification of fishes,
amphibians, and reptiles, or monocardian animals. Longman, Orme ,
Brown, and Longmans, London, England. Vol. 2. 452 pp.

Vari, R. P. 1978. The terapon perches (Percoidei, Teraponidae) : A
cladistic analysis and taxonomic revision. Bulletin of the
American Museum of Natural History 159:175-340.

Williams, J. T« 1985. Cirripectes imitator, a new species of western
Pacific blenniid fish. Proceedings of the Biological Society of
Washington 98:533-538.

Williams, J. T. , and L. A. Mauge . 1983. Cirripectes chelomatus, a new
species of salarine fish (Pisces, Blenniidae). Bulletin du Museum
National d'Histoire Naturelle, Paris, serie 4, 5(section
A):1139-1149.

BIOGRAPHICAL SKETCH

Jeffrey Taylor Williams, the son of Jesse G. and Betty Williams,
was born in Honolulu, Hawaii, in 1953. He graduated from Mountain
Brook High School in Birmingham, Alabama, in 1971. After spending one
year at the University of Mississippi, he went to Florida State
University where he became interested in ichthyology. He graduated in
1975 and went on to the University of South Alabama to begin a graduate
program in ichthyology. He was elected to Phi Kappa Phi and Sigma Xi
and received his master's degree in 1979. He then began a doctoral
program in the Department of Zoology at the University of Florida.
After completing his coursework, but before finishing his dissertation,
he left Florida in 1983 to take a job at the National Museum of Natural
History, Smithsonian Institution in Washington, D.C. He continued to
work on his dissertation and completed it in 1986. He is married to
Karen Anderson Williams.

314

I certify that I have read this study and that in my opinion it
conforms to acceptable standards of scholarly presentation and is fully
adequate, in scope and quality, as a dissertation for the degree of
Doctor of Philosophy.

(mJLlB

Carter R. Gilbert', Chairman
Associate Professor of Zoology

I certify that I have read this study and that in my opinion it
conforms to acceptable standards of scholarly presentation and is fully
adequate, in scope and quality, as a dissertation for the degree of
Doctor of Philosophy. ■/

Frank G. Nordlie
Professor of Zoology

I certify that I have read this study and that in my opinion it
conforms to acceptable standards of scholarly presentation and is fully
adequate, in scope and quality, as a dissertation for the degree of
Doctor of Philosophy.

l)A*\. d.

tAy(<XA(*sV1

William Seaman, Jr. [J

Associate Professor of Forest Resources

and Conservation

I certify that I have read this study and that in my opinion it
conforms to acceptable standards of scholarly presentation and is fully
adequate, in scope and quality, p.s a dissertation for the degree of
Doctor of Philosophy.

'/aaJ&<~z ',

Victor G. Springer i)

Curator of Ichthyology, Smithsonian Inst.

This dissertation was submitted to the Graduate Faculty of the
Department of Zoology in the College of Liberal Arts and Sciences and
to the Graduate School and was accepted as partial fulfillment of the
requirements for the degree of Doctor of Philosophy.

May 1986

Dean, Graduate School

UNIVERSITY OF FLORIDA

3 1262 08553 7412