number 5

/I j

JUL2

0 19ttl

FIELD MUSEUM llBRftBY

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North Carolina State Museum of Natural History

North Carolina Department of Agriculture
James A. Graham, Commissioner

CODN BRIMD 7
ISSN 0193-4406

The Blancan Carnivore Trigonictis (Mammalia:
Mustelidae) in the Eastern United States

Clayton E. Ray
Department of Paleobiology,

National Museum of Natural History, Smithsonian Institution,

Washington, D. C. 20560

Elaine Anderson

730 Magnolia Street, Denver, Colorado 80220

AND

S. David Webb

Department of Natural Sciences,

Florida State Museum, University of Florida,

Gainesville, Florida 3261 1

ABSTRACT. — Fossils of a large galictine mustelid from Florida, North
Carolina, and Maryland, represent Galera macrodon Cope 1868, here
assigned to Trigonictis Hibbard 1941 and regarded as a senior synonym
of T. idahoensis (Gazin) 1934. The smaller T. cookii (Gazin) 1934, is
tentatively identified from Florida on the basis of a single specimen.

INTRODUCTION

In 1868 Cope described a partial mandible from presumed “postplio-
cene” deposits in Charles County, Maryland, as the new species, Galera
macrodon, assigning it to the genus of the living neotropical tayra. Fir a
(= Galera) Barbara, in recognition of its galictine character. Leidy (l869)
added a P-, apparently from the same individual and thus part of the
holotype, although not indicated by Cope. In 1886 Nehring transferred
the species to Galictis, the genus of the living neotropical grison. No
additional material has ever been referred to Cope’s species.

Meanwhile, fairly abundant remains of galictine mustelids have been
reported from widespread occurrences of Blancan land mammal age in
the western states. Gazin (1934) described similar species from Idaho, a
larger, Lutravus{l) idahoensis, and a smaller, L.(?) cookii, and in 1937
assigned both tentatively to Canimartes. In 1941 Hibbard described the
new genus and species, Trigonictis kansasensis. In recent years larger
specimens have been assigned to Trigonictis idahoensis, including T. kan-
sasensis, and smaller specimens to T. cookii. In the eastern states Trigo-
nictis has been listed only in the Blancan assemblage from the Santa Fe
River, Florida (Webb 1974, 1976), but the material has not been de-
scribed. Interestingly, although the galictine affinities of both eastern and
western forms have been recognized consistently from the first, none of

Brimleyana No. 5:1-36. July 1981.

1

2 Clayton E. Ray, Elaine Anderson, S. David Webb

the authors who studied the western Trigonictis has restudied Galera
macrodon, and only Bjork (1970:28) has mentioned it. The specimen
could not be found at the time of Schreuder’s (1935) writing, and the
western species now assigned to Trigonictis had only just been described
(Gazin 1934) and were not considered by her. Reig (1957) regarded
Canimartes{l) cookii and Galictis macrodon as very close, probably
representing a new subgenus of Galictis, and C.(?) idahoensis as conge-
neric with Trigonictis kansasensis, and referred all of them to the Galicti-
nae. Apparently working only from the literature, he did not recognize
the extremely close relationship between T. idahoensis and T. cookii,
which has been substantiated further by consideration of new material
(Zakrzewski 1967; Bjork 1970; Galbreath 1972; Gustafson 1978).

In 1971 one of us (Anderson) found the holotype of Galera macrodon
in the collections of the Academy of Natural Sciences of Philadelphia,
recognized its general affinities, and subsequently concluded that it is
conspecific with Trigonictis idahoensis. This was expressed tentatively in
Kurten and Anderson (1980:155).

Recently Peter J. Harmatuk sent another one of us (Ray) a mustelid
mandible found by Mr. Donnie Bailey at Goldsboro, North Carolina.
Efforts to identify the specimen prompted a review of the literature and
critical examination of the excellent sample of Trigonictis from Idaho in
the National Museum of Natural History, of the Florida material in the
Florida State Museum, and of the holotype of Galera macrodon in the
Academy of Natural Sciences of Philadelphia. All of this led to the
conclusion that Trigonictis idahoensis is a junior synonym of Trigonictis
macrodon, to which all but one of the eastern specimens of Trigonictis,
all western specimens previously assigned to T. idahoensis, and at least
some previously assigned to T. cookii, should now be referred.

Our purposes here are to review and describe the material from the
eastern states, to present our conclusions regarding Galera macrodon, to
place all of these in the context of the more abundant, geochronologically
better known, western Trigonictis, and to comment briefly on its broader
relationships with Palearctic paleotaxa and with neotropical neotaxa.

Abbreviations

ANSP - Academy of Natural Sciences of Philadelphia
BMNH - British Museum (Natural History)

F:AM - Frick:American Mammals Collection, American

Museum of Natural History
KUVP - University of Kansas, Vertebrate Paleontology
UF/FSM - University of Florida, Florida State Museum
USGS - United States Geological Survey

Blancan Carnivore Trigonictis

3

USNM - National Museum of Natural History
UM - University of Michigan
UO - University of Oregon
UW - University of Washington
C - canine
P - premolar
M - molar

mybp - million years before present
OR - observed range

with superscript (upper) or subscript (lower)

Galictinae Reig 1957
Trigonictis Hibbard 1941

Type-species. — Trigonictis kansasensis Hibbard 1941.

Included species. — T. macrodon (Cope) 1868, T. cookii (Gazin) 1934.
Diagnosis. — see Hibbard 1941a:344; 1941b:273; Bjork 1970:22; and
below, under T. macrodon.

Distribution. — United States.

Age. — Blancan Land Mammal Age; also Irvingtonian(?) in Florida.

Trigonictis macrodon (Cope), 1868
Figs. 1, 2 (part), 3-6

“Carnivore the size of a fox,” Cope, 27 October 1867, letter to his
father, in Osborn 1931:148.

Galera, a new carnivore of the genus. Cope 1868a: 138. — Bjork
1970:28.

Galera macrodon Cope 1 868b: 1 55. — Leidy 1 869:369, 47 1 , pi. 30, figs.
1-3. — Coues 1877:17 (type description reprinted). — Roger 1887:135.
— Gillette and Colbert 1976:33.

Putorius macrodon, Wortman 1883:1001. — Cope and Wortman,
1884:5.

Galictis macrodon, Nehring 1886:151. — Roger 1896:60. — Trouessart
1897:264. — Nehring 1901:216. — Hay 1902:767. — Trouessart 1904:197.

— Reig 1957:41, 44 (possibly distinct subgenus).

Grison macrodon. Hay 1919:367. — Hay 1923:220, 347. — Hay
1930:531 (part, not Merrill 1907A). — Schreuder 1935:89.

LutravusG) idahoensis Gazin 1934:137-143, fig. 1, table 1.

Canimartesl idahoensis, Gazin 1937:363-364. — Hibbard 1941a:346-
347. — Hibbard 1941b:273-274. — Reig 1957:33, 45. — Repenning
1967:297.

Trigonictis kansasensis Hibbard 1941a (genotype):344-347, fig. 5a, b.

— Hibbard 1941 b:273-274. — McGrew 1944:53. — Reig 1957:45. —
Zakrzewski 1967:293-294.

4

Clayton E. Ray, Elaine Anderson, S. David Webb

Trigonictis kansasensis, “at least generically identical with Pannonictis
pliocaenica,'' Repenning 1967:296. — Thenius 1972:206.

Trigonictis idahoensis, Reig 1957:33, 45. — Zakrzewski 1967:293-297.

— Shotwell 1970:82, fig. 37M,N. — Bjork 1970:22-24, figs. 10 b,c,e, 12.

— Hibbard 1972a: 108-109. — Hibbard 1972b: 128. — Gustafson 1978:39-
41. — Kurte^n and Anderson 1980:155, fig. 2.2.

Trigonictis cookii, Hibbard 1972a: 109 (part, F:AM 49163).

Trigonictis cooki, Gustafson 1978:39, fig. 22.

Remarks. — It is seldom possible to determine exact dates of publica-
tion for the Proceedings of the Academy of Natural Sciences of Philadel-
phia during the period of concern here, which includes the papers that we
cite as Cope 1868a, 1868b (containing the type description of Galera
macrodon), and 1868c. They were presented orally at meetings of the
Academy on 10 December 1867, 31 December 1867, and 28 July 1868,
respectively. Nolan (1913:xiii), the standard source for establishing time
of Academy publications, is imprecise in these instances, but for the
critical paper, 1868b, evidence indicates that it was published between
1 January and 1 1 May 1868 (see Nolan 1913; Osborn 1930).

Holotype. — ANSP 11626, partial right mandibular ramus, lacking
anterior and posterior extremities; retaining Pj - Mj- well preserved, pos-
terior root of Pj, and with alveoli of canine (incomplete), Pj, and M^;
fragment of left maxilla with P- well preserved, posterior root of P-, and
partial alveoli of M-. The maxillary fragment was not mentioned by
Cope, but it bears the same old number 187 and the same catalog number
(ANSP 1 1626), as does the mandible, and its P- was included by Leidy
( 1 869:47 1 , pi. 30, figs. 2,3). Also, its preservation, size, and other charac-
teristics are compatible with those of the mandible.

Referred material. — From the western United States, all specimens,
including the holotypes, heretofore assigned to Trigonictis idahoensis or
T. kansasensis by Hibbard (1941a:344), Shotwell (1970:82), Bjork
(1970:22-23), Hibbard (1972a: 109), and others. Also partial mandibles,
previously assigned to T. cookii, F:AM 49163 from the Sand Draw local
fauna, Nebraska (Hibbard 1972a: 109), and UW 41527 from the White
Bluffs local fauna, Washington (Gustafson 1978:39).

From the eastern United States, the following specimens, not pre-
viously described:

Santa Fe River, locality VIH A, Gilchrist Co., Florida

UF/FSM 14256, right femur, and UF/FSM 16762, left femur,
both collected June 1968 by William Hunt; both tentatively
referred.

UF/FSM 18475, left tibia, collected February 1971 by Kent Ainslie
and William Hunt; tentatively referred.

UF/FSM 18912, complete left mandibular ramus with Pj - Mp

Blancan Carnivore Trigonictis

5

and associated incomplete right ramus with Pj and Pj, and
incomplete P^ and Mj-; all teeth on both sides heavily worn,
collected by Larry Roberts.

Smith Mill Run, near Goldsboro, Wayne Co., North Carolina
USNM 306507, left mandibular ramus lacking anterior extremity
and part of coronoid process, with Pj - Mj well preserved and
with part of canine alveolus, collected spring 1980 by Donnie
Bailey.

Type locality. — “collected by James T. Thomas near his residence in
Charles County, Maryland, not far from the Patuxent River” (Cope
1868b: 138). Cope described several taxa of fossil vertebrates, mostly
cetaceans, from the same source, but never published precise field data.
Efforts made through the years to determine the exact locality and
horizon in Charles County, and the identity of James T. Thomas, have
been inconclusive thus far (see Dryden and Overbeck 1948:57, 90; Kel-
logg 1955: 143, 1965:48, 1968: 105). Cope ( 1868a, b) referred to the deposit
as postpliocene in age based on the fauna, a “common peccary” (later
identified as Cynorca proterva Cope, a Miocene species; see Woodburne
1969), a “Manatus” (specimen has not been relocated, but sirenian
remains are fairly common in the Calvert Formation but have not been
substantiated from later beds in the area; see Kellogg 1966), and the
Galera. Beds of the marine Miocene Chesapeake Series are overlain in
the area by the Brandywine Formation, also termed “upland deposits,” a
thin (10-30 feet, 3-9 m) mantle of gravel, sand and loam, mostly fluviatile
in origin, deposited by the southwestwardly migrating channel of the
Potomac River, and variously regarded as late Miocene, Pliocene and/or
early Pleistocene in age, although lacking diagnostic fossils (Clark 1915;
Hack 1955; Schlee 1957; Glaser 1968; Owens and Denny 1979). Although
Cope’s other “postpliocene” fossils probably came from the Miocene
Calvert Formation, his Galera macrodon more likely came from the
overlying “upland deposits,” judging from its taxonomic affinities.

It should be noted in passing, especially in view of the more recent
recovery of referred material in Florida, that Reig (1957:44-45) mistak-
enly ascribed the original material of Trigonictis macrodon to Florida
rather than Maryland.

Distribution. — In addition to the type locality (Fig. 1, loc. 7) in
eastern Charles County, near the Patuxent River, Maryland, the material
here referred to Trigonictis macrodon is known from the following
localities:

White Bluffs, east side of Columbia River, Franklin Co., southcen-
tral Washington, some 10-30 mi. (16. 1-48.3 km) N of Richland (Fig. 1,
loc. 1). UW locality A3027. Ringold Formation; age very early Blan-

Clayton E. Ray, Elaine Anderson, S. David Webb

Fig. I. Distribution of galictine mustelids of Blancan land mammal age in North America, l.ocalities I - 9, Trii^onictis niacrocion\
localities 2, 3, 5, 10, T. cookii\ localities 3, 4, Sminthosinis ho\vleri\ locality II, Trigonicfis sp.; locality 12, Caniniartes cuniniinsii\
locality 13, mustelid of the subfamily Galictinae. See text, under Distribution, for details of localities.

Blancan Carnivore Trigonictis 1

can. (Gustafson 1978:39, 55, not plotted in his fig. 2; specimen identi-
fied as T. cooki).

Grand View, Jackass Butte locality, SW of Snake River, Owyhee
Co., southwestern Idaho, some 17 mi. (27.4 km) NW of Grand View
(Fig. 1, loc. 2). UO locality 2404. Upper part of the Glenns Ferry
Formation, age regarded as late Blancan, although Mammuthus has
recently been found at the locality. A K-Ar date of approximately 1.4
mybp from a lava above the Glenns Ferry Formation places a min-
imum limit on the age of the Grand View local fauna. (Shotwell
1970:7, 82, fig. 8; Neville et al. 1979:519).

Hagerman, west side of Snake River, Twin Falls Co., south-
central Idaho (Fig. 1, loc. 3), the type locality of Trigonictis idahoensis
and T. cookii. Various localities of UM, USGS, Dwight W. Taylor,
and USNM. (Bjork 1970:4, 22-23, map 1, chart). Trigonictis occurs in
the lower part of the Glenns Ferry Formation at elevations of approx-
imately 865 to 990 m in beds dated by K-Ar and magnetic stratigraphy
from older than 3.75 mybp to older than 3.2 mybp; thus, the Hager-
man fauna is early Blancan in age. (Neville et al. 1979:521-522, fig. 10).

Broadwater and Lisco, Morrill and Garden cos., western Nebraska
(Fig. 1, loc. 4). Exact locality not published. The Broadwater fauna in
the Broadwater Formation is late Blancan in age. (Schultz et al. 1951:
table 1; Hibbard 1972b:128, 131-134).

Sand Draw, Brown Co., central northern Nebraska (Fig. 1, loc. 5).
Frick Prospecting Localities 277, some 5.5 mi. (8.8 km) N of Ains-
worth, along Booth Draw, and 278, some 6.5 mi. (10.5 km) ENE of
Ainsworth, N of Magill Draw. This fauna in the Keim Formation is
late Blancan in age. (McGrew 1944:53; Skinner 1972:30-34; Hibbard
1972a: 109, specimen from 278 identified as T. cookii).

Deer Park, Meade Co., southwestern Kansas (Fig. 1, loc. 6). Uni-
versity of Kansas Meade County locality 1, some 10 mi. (16. 1 km) SW
of Meade, Meade County State Park; SE 1/4, sec. 15, T33S, R29W,
Lake Larrabee 7.5-min. quad., USGS. The Deer Park fauna, occur-
ring in the Ballard Formation which overlies the Rexroad Formation,
is late Blancan in age. (Taylor 1966:103; Hibbard 1972b: 128).

Rexroad locality 3, Meade Co. (Fig. 1, loc. 6; distinct from preced-
ing locality, but not distinguishable at scale of map). University of
Kansas Meade County locality 3, some 11 mi. (17.7 km) SW of
Meade; SW 1/4, sec. 22, T33S, R29W, Lake Larrabee 7.5-min. quad.
This is the type locality of Trigonictis kansasensis. The Rexroad local
fauna in the Rexroad Formation is early Blancan in age, perhaps
somewhat older than the Hagerman local fauna. (Hibbard 1941a:344;
1941b:273; 1972b:128; Taylor 1966:101).

Smith Mill Run, 2.5 mi. (4 km) N of center of Goldsboro, Wayne

8

Clayton E. Ray, Elaine Anderson, S. David Webb

Co., east-central North Carolina (Fig. 1, loc. 8); 35®25'15"N, 7/^59'35"
W, Goldsboro 15-minute quadrangle. The specimen was recovered by
wet screening of sands redeposited in the bed of Smith Mill Run. At
the same locality Mr. Bailey also has collected remains of Cretaceous
vertebrates, including a partial femur of a hadrosaur, and of Tertiary
vertebrates, including sharks, bony fishes, and marine mammals,
mostly as float. Probably all of the Tertiary marine vertebrates are

derived from the Pliocene

Formation, poorly exposed in

the creek banks, and probably assignable to the Rushmere Member,
which in Virginia has yielded a glauconite date of 4.4 ± 0.2 mybp
(Ward and Blackwelder 1980:D31). Although it is conceivable that the
jaw of Trigonictis could have come from the Yorktown Formation,
the most probable source is the undifferentiated post-Miocene de-
posit, consisting of gravels, sands, and clays, of mostly fluviatile
origin, that mantles much of the Goldsboro area to a depth of 30 feet
(9 m) (Pusey 1960: 16-17). In detailed studies of the surficial sediments
of the region, Daniels and Gamble (1974) identified, between the
Kenly and Surry Scarps, a mappable, medium-fine sand unit, well
sorted and with little clay, which would have been assigned to the
“Sunderland” Formation by earlier workers. It is tempting to suppose
that these sediments may be similar in genesis and age to the “Brandy-
wine” or “upland deposits” of Maryland, and that the similar speci-
mens of Trigonictis came from similar deposits in the two areas. Only
additional, stratigraphically controlled collections will resolve the
problem.

Sante Fe River VIII A, Gilchrist Co., northern Florida (Fig. 1, loc.
9), vertebrate fossil locality in the Santa Fe River about 8 mi. (12.9
km) E of its confluence with the Suwanee River, SW 1 /4, SE 1 / 4, sec.
18, T7S, R16E. Fauna closely resembles those from Santa Fe River
sites I A, I B, IV A. The fauna is late Blancan in age, and includes abundant
material of Nannippus phlegon (MacFadden and Waldrop 1980). The
citations of Trigonictis from Santa Fe River I B (Webb 1974: 17) and I
A (Webb 1976:226) were in error, based on specimens from Santa Fe
River VIII A.

Other North American Galictinae. — Trigonictis cookii (Gazin) is
known in Idaho from Grand View, Jackass Butte locality (Fig. 1, loc. 2),
and Hagerman, the type locality (Fig. 1, loc. 3); Sand Draw, Frick Pros-
pecting Locality 277, near Ainsworth, Nebraska (Fig. 1, loc. 5); and Haile
XVI A, Alachua Co., Florida (Fig. 1, loc. 10), reported herein (tentative
identification).

Kurte^n and Anderson (1980:156) noted the presence of T. cookii also
in the Pliocene of Texas and California.

Trigonictis sp. has been listed from Cita Canyon, some 15 miles (24.1

Blancan Carnivore Trigonictis

9

km) southeast of Canyon, Randall Co., Texas (Fig. 1, loc. 11); Schultz
(1977:126, 129). The Cita Canyon local fauna is thought to be slightly
older than the Blanco on the basis of magnetic stratigraphy (Lindsay et
al. 1975:1 16), but not on the basis of the faunas (Schultz 1977:123).

Sminthosinis bowleri Bjork, 1970, was described from Hagerman (Fig.
1, loc. 3), and Kurt^n and Anderson (1980:156) cited it from the Broad-
water fauna (Fig. 1, loc. 4). This small mustelid is closely related to
Trigonictis and may be only subgenerically distinct from it (Bjork 1970).

Canimartes cumminsii Cope, 1892, a possible galictine, known only
from a single specimen, was described from the Blanco fauna, northeast-
ern Crosby County, some 40 miles (64 km) east northeast of Lubbock,
northwestern Texas (Fig. 1, loc. 12); Schultz (1977: 105, 126, fig. 20). The
Blanco local fauna is between 1.4 and 2.4 mybp in age on the basis of
fission track dating and magnetic stratigraphy (Lindsay et al. 1975:1 14).

A galictine mustelid is recorded apparently from both the Arroyo Seco
and Vallecito Creek faunas, in the Palm Spring Formation, Anza Bor-
rego State Park, eastern San Diego County, southern California (Fig. 1,
loc. 13). These faunas are late Blancan in age, and the latter may extend
into the Irvingtonian (Opdyke et al. 1977:323, 325).

Geologic Age. — Trigonictis is thought to have reached North Amer-
ica as an immigrant from Eurasia in the early Blancan (Repenning
1967:296-297), or perhaps somewhat earlier. Tedford and Gustafson
(1977) suggested that dispersal from oriental temperate woodlands
resulted in the simultaneous appearance of Trigonictis in North Ameri-
ca and of closely related forms in Europe. However, Schultz et al. (1972)
believed that Trigonictis migrated from North America to Eurasia at this
time.

The biostratigraphic significance of Trigonictis is based entirely on its
western occurrences where it is found only in faunas of Blancan Land
Mammal Age. The western early to late Blancan local faunas including
Trigonictis may be arranged tentatively in order of decreasing age as
follows: White Bluffs, Rexroad, Hagerman, Broadwater-Sand Draw-
Deer Park-Cita Canyon-Arroyo Seco, Blanco, Grand View-Vallecito
Creek. Many uncertainties exist in such a sequence; for example. Shot-
well ( 1 970: 1 6) could see little faunal basis for a distinction in age between
the Hagerman and Grand View local faunas, and Schultz et al. (1978:60)
proposed a somewhat different sequence of faunas. Radiometric ages and
magnetic stratigraphy bracket the age of these faunas from somewhat less
than 4 mybp to somewhat more than 1.4 mybp.

In the east only the occurrence at Santa Fe VHI A in Florida is in
demonstrably Blancan association. The records from North Carolina and
Maryland are regarded as Blancan only by extrapolation, but they do
serve to suggest the possibility of correlation of nonmarine and nearshore

10

Clayton E. Ray, Elaine Anderson, S. David Webb

Fig. 2. Left upper carnassials (P-'^) of some fossil (A, B) and modern (C, D, E)
galictine mustelids, in occlusal aspect, whitened for photography. All figures
approximately 4X, scale in mm. A, ANSP 1 1626, Charles Co., Maryland, holo-
type of Trigonictis macrodon; B, USNM 23664, Hagerman, Idaho, T. macrodon\
C, USNM 155480, Grisonella cuja', D, USNM 180224, Galictis vittata\ E, USNM
281468, Eira barbara.

Blancan Carnivore Trigonictis

11

deposits in the east that have thus far proved intractable to dating. Voor-
hies (1974) demonstrated the feasibility of this approach by recovery of
two teeth of the Pliocene horse, Nannippus minor, from previously
barren upland gravels near the Fall Line in Georgia.

Revised Diagnosis. — A large galictine mustelid. Crowded upper and
lower premolars. P- single rooted; P- (Figs. 2A, B) triangular in occlusal
view with low, strong, conical protocone and well developed cingulum
that forms a shelf extending from protocone to posterolingual base of
metacone; small hypocone on cingulum; talon with shallow basin bor-
dered anterolingually by protocone, posterolingually by hypocone and
labially by anterior part of trigon; cingulum continuous around base of
crown. M- three-rooted with reduced cingular shelf labial to metacone;
tooth rectangular in occlusal outline with no distinct waist. Mandible
(Figs. 3F, 4A) relatively short, robust, ventral margin straight. Premolars
simple, lacking accessory cusps, cingulate, Pj double-rooted and set
obliquely. Mj- trigonid longer than talonid; strong metaconid appressed
to protoconid; talonid broad, basined; hypoconid moderately developed.
Dental formula | y 5 5. Separated from T. cookii by larger size (see
Measurements and Tables 1 and 2).

Description of eastern specimens. — In ANSP 11626, the type speci-
men from Charles County, Maryland, the P- is slightly wider and more
robust, with a broader talon and lesser anterior emargination between the
parastyle and protocone than is seen in other P-’s of Trigonictis. The P-
(KUVP 4604) from Rexroad 3 has an incipient cusp on the cingulum that
is absent in the other specimens. Examination of a large number of
Recent galictines shows variations of this type to be quite common, and
they are not regarded as significant. The inferior border of the mandibu-
lar ramus of the holotype is somewhat more curved in labial aspect than
is seen in the other specimens, which have a straighter profile (cf. Fig.
4A,B). The alveoli of Pj show that the tooth was double-rooted and set
obliquely in the jaw. Pj is rather small, and there is a space between it and
P4. The length of My (12.2 mm) falls near the lower end of the observed
range (OR 12.0-14.9, N=24) of Trigonictis macrodon. The talonid of My
is rather heavily worn; wear is also seen on the crests of the posterior
faces of the metaconid and protoconid and obscures the notch between
the protoconid and hypoconid.

The left ramus from Smith Mill Run, North Carolina, USNM 306507
(Figs. 3D, 5D) has all the postcanine teeth in place, little worn, and
mostly well preserved. Pj is small, double-rooted and set obliquely
between the canine and P3. P-3 is more typical for Trigonictis than is that
of the type of T. macrodon, as it is more robust and slightly overlaps the
adjacent teeth. All of the premolars have strong cingula, which com-
pletely encircle the crowns of Pj and P^. My is relatively large, elongate.

12

Clayton E. Ray, Elaine Anderson, S. David Webb

Fig. 3. Mandibles of Trigonictis macrodon in occlusal aspect, whitened for photography. A, USNM 25026, Hagerman Idaho; B,
USNM 12030, Hagerman, Idaho holotype of T. idahoensis; C, USNM 23560, Hagerman, Idaho; D, USNM 306507, Smith Mill Run,
North Carolina; E, UF/FSM 18912, Sante Fe River, Florida; F, ANSP 1 1626, Charles Co., Maryland, holotype of T. macrodon.

1 CM

Blancan Carnivore Trigonictis

13

Fig. 4. Mandibles of Trigonictis macrodon in labial aspect, whitened for photography. A, ANSP 1 1616, Charles Co., Maryland, holo-
type, reversed; B, UF/FSM 18912, Santa Fe River, Florida.

14

Clayton E. Ray, Elaine Anderson, S. David Webb

Fig. 5. Mandibles of Trigonictis macrodon in labial aspect, whitened for photography.
A, USNM 25026, Hagerman, Idaho; B, USNM 12030, Hagerman, Idaho, holotype
of T. idahoensis’, C, USNM 23560, Hagerman, Idaho; D, USNM 306507, Smith
Mill Run, North Carolina

Blancan Carnivore Trigonictis

15

and narrow with a distinct lingual indentation in its occlusal outline
between the paraconid and metaconid; complementary crests on the pos-
terior slope of the protoconid and the anterior slope of the hypoconid
meet at the notch separating the trigonid from the talonid (contrast the
worn condition of these crests in the holotype, Figs. 3D, F, 4A, 5D); the
labially placed hypoconid is the highest part of the talonid; the talonid
basin is bordered continuously posteriorly and lingually by a regular,
crenulated crest; the talonid basin is floored by the smoothly and gently
sloping internal wall of the hypoconid.

The left half of the mandible from Santa Fe River VIII A, UF/FSM
18912, is essentially complete and one of the best preserved specimens of
Trigonictis known (Fig. 4B). It is characterized by short, robust propor-
tions, relatively straight ventral profile, low articular process, erect,
broad coronoid process, deeply incised masseteric fossa terminating pos-
terior to the level of the M2 alveolus, and narrow symphyseal region with
crowded incisive alveoli. The strongly molded bony surface with some
rugosity and the heavily worn dentition indicate advanced individual age.
The left Pj was lost during life and its alveoli nearly obliterated. The teeth
in the associated incomplete right ramus show comparable wear. Oth-
erwise the characteristics of the postcanine teeth fit well within the varia-
tion of the sample of Trigonictis, and similar patterns of extreme wear
and dental anomalies were observed among modern galictines in the
USNM.

The three postcranial elements from Santa Fe VIII A are assigned only
tentatively to the genus and species. The left (UF/FSM 16762) and right
(UF/FSM 14256) femora are similar enough in all respects to represent a
single individual. Thus only the left was described, measured and illus-
trated (Fig. 6), along with the left tibia (UF/FSM 18475). The tibia seems
compatible with the femora in size, maturity, morphology, and preserva-
tion and could also represent the same individual. Unfortunately, in the
present state of knowledge, very little can usefully be done with these
dissociated elements beyond placing them on record for future reference.
There is only a single partial skeleton of Trigonictis known, UM V49819,
T. cookii, described and illustrated by Bjork (1970:25-26). He referred
several isolated postcranial elements to T. idahoensis, including a femur
and tibia, but did not describe (except for comments on the tibia), mea-
sure, or illustrate them. The femur of T. cookii illustrated by Bjork
(1970:fig. 14e) appears to be very similar to those from Florida, except
for its smaller size.

Among modern mustelids, the tibia is longer than the femur and is
curved in mustelines, is slightly shorter than the femur in galictines, and is
curved in Galictis and Grisonella. The tibia is nearly straight in Eira, but
both it and the femur are relatively slender. If the femora and tibia from

16

Clayton E. Ray, Elaine Anderson, S. David Webb

Fig. 6. Left femur and tibia, whitened for photography, of Trigonicfis macrocion,
Santa Fe River, Florida. All figures approximately IX; scale in mm. Femur,
UF/ FSM 16762, in cranial (A) and caudal (B) aspects; tibia, UF/ FSM 18475, in
cranial (C) and caudal (D) aspects.

Blancan Carnivore Trigonictis

17

Florida do in fact represent a single individual, or at least reflect the true
relative lengths of the elements, they are subequal in Trigonictis, as indi-
cated also by the associated skeleton of T. cookii (cf. Table 3). In relative
length, absolute size, proportions, and morphology, the Florida specimens
compare most favorably with those of Pannonictis pilgrimi from the
Villafranchian of Hungary described and illustrated by Mottl (1941), and
further compared and the illustrations reproduced by Ficcarelli and
Torre (1967).

Measurements. — See Tables 1-3 for measurements and statistics.
The distinction in size between Trigonictis macrodon and T. cookii is
not clear-cut, yet all authors, including us, agree that the range in size is
too great to be accommodated in a single species, or at least in a single
penecontemporaneous population. We have followed Bjork (1970) in
placement of the boundary, as reflected in his statistics presented in our
Table 2, modified slightly by the addition of new specimens. Incidentally,
there is an anomalous point for an Mj- assigned to T. cookii in Bjork’s
figure 13, plotted at approximately 12.2 mm length and 4.8 mm width;
this specimen does not appear in the statistics for either species.

Gustafson (1978) presented a case for a chronocline of increasing size
upward in the Hagerman beds. Presumably because the length of Mj-
(12.0 mm) of the single specimen from the older White Bluffs fauna fell in
the gap between the two species, he moved the boundary upward and
referred the specimen to T. cookii. However, in the other variates pre-
sented, the specimen falls within the observed range of T. macrodon, and
we have referred it to the larger species. Gustafson’s measurements for
UW 41527 include: length of P^, 6.5 mm; width of P^, 3.7; length of Mj-,
12.0; width of Mj-, 5.3; depth of jaw below Mj-, 12.7 (cf. our Table 2).
Bjork (1970) did not give depth of jaw below M^ for T. cookii, but two
specimens from Hagerman in USNM measure 10.6 and 10.8 mm. The
inferior border of the ramus is missing in the holotype (USNM 12606),
but its depth could scarcely have exceeded 1 1 mm.

Similarly, on the basis of size (length of Mj-, 12.5 mm), we regard
F:AM 49163 from the Sand Draw local fauna as T. macrodon rather
than T. cookii, as assigned by Hibbard (1972a: 109). His measurement of
12.6 for “greatest length P^ - Mj-” is in error, and should be 18. 1.

Based on our measurements from his figures, Shotwell’s (1970:82, fig.
37J-N) specimens from the Grand View local fauna are correctly
assigned, although the larger is in some dimensions slightly larger than
other published specimens of Trigonictis, for example in length of Mj-, 15
mm, and depth of jaw below Mj-, 17 mm. However, there is a fragment of
a jaw, USNM 25027, from Hagerman, almost certainly representing
Trigonictis, that would have been as large or even larger.

18

Clayton E. Ray, Elaine Anderson, S. David Webb

However, the separation in size is not absolute. For example, the holo-
type of T. macrodon falls within the observed range for T. cookii in width
of P3, but widths of anterior premolars have slight diagnostic value.
Development of lower premolars is highly variable in modern galictines.
We have noted variations in Eira barbara, for example, ranging from
several specimens with Pj absent or tiny and spicular, some with spaces
between the premolars, to others with extremely large, broad, overlap-
ping premolars.

Relationships. — The closest relative of Trigonictis macrodon is its
only congener, T. cookii, distinguished by slightly smaller size. Having
two carnivores so similar in morphology and size apparently coexisting
(in the Hagerman, Broadwater, Sand Draw, and Grand View local fau-
nas) has vexed everyone who has studied these animals. Gazin (1934)
considered and rejected the possibility of a single species with extraordi-
narily high sexual and/or individual variation, as did Zakrzewski (1967),
and Bjork (1970).

We applied Zakrzewski’s (1967:205-206) method of assessing sexual
dimorphism to a series of Eira barbara from Panama in the USNM and a
sample of Grisonella cuja from Argentina and Brazil in the BMNH, as
the tayra and the little grison show dimorphism in size and should offer a
more relevant guide to Trigonictis than would the more distantly related
mustelines used by Zakrzewski. His “sex size ratio” for a given variate is
obtained by dividing the mean value for males by that for females. Our
results are as follows:

Eira barbara

N

X

OR

Toothrow length
male

10

31.54

29.6-34.0

female

12

28.77

26.6-30.2

sex size ratio

1.10

Length of Mj
male

14

10.33

9.2-11.0

female

12

9.74

9.1-10.3

sex size ratio

1.06

Blancan Carnivore Trigonictis 19

Grisonella cuja

N

X

OR

Toothrow length

male

14

26.19

22.0-28.4

female

11

23.99

22.0-25.4

sex size ratio

1.09

Length of Mj-

male

14

7.75

6.4-8.6

female

11

6.89

6.3-7.8

sex size ratio

1.12

With the exception of the sex size ratio for toothrow length in Mustela
vison, our values are less in Eira barbara and Grisonella cuja than for
these variates in the four species of mustelines tested by Zakrzewski,
suggesting a weaker secondary sexual dimorphism in the tayra and little
grison.

Galbreath (1972) suggested the possibility of a chronocline of decreas-
ing size from T. idahoensis in the lower beds at Hagerman to T. cookii
and Sminthosinis bowleri in the higher beds, whereas Gustafson
(1978:39-40) suggested a chronocline of increasing size from T. cookii to
T. idahoensis based on the relatively small sample of suitable, stratigra-
phically placed mandibles. The trend shown by Gustafson for the Hag-
erman beds is suggestive, but far from conclusive, and the evidence from
other local faunas seems to weaken the case. For example, Gustafson
assigned his White Bluffs specimen, thought to be very early Blancan in
age, to T. cookii, but it seems to us to fall more comfortably within the
variation of the larger T. macrodon, based on his measurements. Also,
the specimens from the early Blancan Rexroad local fauna are large, and
the specimen from the Irvingtonian Haile XVI A fauna is small. T. cookii
and T. macrodon occur together in the late Blancan Broadwater, Sand
Draw, and Grand View local faunas. Thus, no clear trend of changing
size through time can be demonstrated on the basis of present collections
and correlations. In any case, the eastern specimens fall comfortably on
one side or the other of the indicated specific boundary and thus present
no problems of assignment. Should all Trigonictis ultimately prove to
belong to a single heterogeneous species with great individual, sexual,
temporal, and geographic variation, then T. macrodon would be the
senior name.

Beginning with Cope (1868) the fossils now assigned to Trigonictis
have always been compared appropriately to the modern neotropical
Galictinae. The complex nomenclatural history of this small group has
been confusing, and its systematic arrangement remains unresolved. We

20

Clayton E. Ray, Elaine Anderson, S. David Webb

Table 1. Measurements (mm) of P- in some specimens of Trigonictis and
Sminthosinis.

Length

Width

Trigonictis macrocion

ANSP 1 1626, holotype

KUVP 4604, from

1 1.1

7.6

Hibbard (1941a:347)

UM V49728 (cast, in USNM),

1 1.9

7.8

Hagerman local fauna

11.1

6.2

USNM 23664, Hagerman local fauna

11.4

7.2

USNM 23665, Hagerman local fauna

11.6

—

Trigonictis cookii

UM V49819, Hagerman local fauna.

from Bjork (1970:26)

9.6

5.7

Sminthosinis howler i

Hagerman local fauna, from

Bjork (1970:28)

UM V52868, holotype

8.01

5.35

UM V53344

7.70

5.08

UM V55214

7.93

5.00

UM V55952

7.93

5.15

follow Cabrera (1958:258-265), except that we accord Grisonella full
generic status, on the basis of absence of the metaconid in My, in agree-
ment with Bjork (1970:28), in recognizing the following taxa: Galictis
vittata for the gxhon.Grisonella cuja for the little grison, and Eira bar-
bara for the tayra. Available to us for this study were 16 specimens of
Galictis, 10 of Grisonella, and 49 of Eira at USNM, and 27 of Grisonella
and 62 of Eira at BMNH. Trigonictis certainly requires close comparison
to this group, but its precise affinities within it and with fossil galictines of
Eurasia, as well as their interrelationships, are less clear. There seems to
be merit in the opinion that the affinities of Eira could be musteline
rather than galictine (cf. Pocock 1921, and Ficcarelli and Torre 1967), but
we adhere to the more traditional arrangement, pending the necessary
comprehensive review of fossil and modern material.

In 1867 Cope probably had available at ANSP no specimens of Galic-
tis vittata, two skulls and jaws of Grisonella cuja, and four of Eira (=
Galera) barbara. Cope’s concept of Galictis, and assertion that it lacked
the metaconid in Mj- (1868b: 156, footnote), obviously were based on
Grisonella, then and now generally regarded as congeneric with Galictis
vittata. With the exception of the obscure Putorius ardeus Bravard whose
affinities were recognized only recently (see Viret 1954), none of the
European fossils was known at that time; hence. Cope’s (1868b: 155-156)

Blancan Carnivore Trigonictis

21

assignment of his new species to Galera was remarkably perceptive and
his brief discussion of neotropical affinities of the North American Pleis-
tocene fauna resoundingly modern. He indicated that his species differed
from the living tayra in having an apparently “more slender muzzle,”
relatively larger Mj-, and double-rooted Pj, among other characters.

Nehring (1886:151-152) pointed out that, unknown to Cope, the grison
has a metaconid in Mj-, and indicated that in relative size of this tooth and
form of masseteric fossa. Cope’s fossil jaw more closely resembles that of
the grison, and therefore transferred the species to Galictis. He later
reiterated this conclusion (1901:215-216), stating that the specific charac-
ters distinguishing Galictis macrodon from the living grison are the two-
rooted Pj, the space between Pj and P^, and the somewhat greater dimen-
sions of the teeth and jaw bone. Although Nehring was aware of Leidy’s
(1869) illustration of the P- of Galera macrodon, he obvously based his
reassignment to Galictis on Cope’s type description, based only on the
lower jaw, as reprinted by Coues (1877), and on Leidy’s illustration of the
lower jaw. Until now, only Schreuder (1935:89) has considered the P- of
Galera macrodon, but, as the specimen was not available at that time, she
was limited to Leidy’s illustration. She supported Nehring’s conclusions.
The P- of Galictis (and Grisonella), however, differs fundamentally from
that of Trigonictis macrodon in having a well developed basin in place of
the protocone, bordered posteriorly by a large hypocone, especially in
Galictis (Fig. 2C,D), a contrast noted by Zakrzewski (1967:294). Eira
barbara is more similar to Trigonictis in development of the protocone of
P-(Fig. 2E), but differs markedly in shape of the tooth through having the
protocone set off from the trigon by a narrow neck (as typically devel-
oped in mustelines and apparently as in Canimartes cumminsii).

The Mj- of Grisonella is significantly different from those of Trigonic-
tis, Galictis, and Eira in lacking the metaconid. Although Mj- shows
considerable variation in the modern series available for Galictis and
Eira, in Galictis it is relatively large, as in Trigonictis, but generally has a
narrower talonid on which the hypoconid is more prominent and cen-
trally placed and the basin absent or incompletely enclosed lingually; in
Eira the Mj- is relatively small, but otherwise resembles that of Trigonictis
in having a broad talonid with labially placed hypoconid and distinct
basin, though generally not as fully enclosed as in Trigonictis (USNM
104546 and many other specimens of Eira have essentially Trigonictis-
like talonids). Schreuder (1935:88-89) quantified the relative size of Mj- by
expressing its crown length as a multiple of that of P^ (length of My
/length of Py)^ We have used her technique to compare relative size of Mj-
in the series of modern galictines in USNM to that of Trigonictis, with
the following results:

22

Clayton E. Ray, Elaine Anderson, S. David Webb

N

X

OR

Eira barbara

43

1.34

1.23-1.53

Grisonella cuja

10

1.73

1.55-1.88

Galictis vittata

14

1.85

1.73-1.98

Trigonictis macrodon

ANSP 11626, holotype

1.67

USNM 306507, North Carolina

1.99

KUVP 4604, holotype of

T. kansasensis (from

Hibbard 1941a:346)

1.85

UW 41527, Washington (from

Gustafson 1978, table 14)

1.85

Hagerman sample in USNM

5

1.81

1.73-1.86

T. cookii

Hagerman sample (from Bjork

1970, table 8)

3

1.94

1.81-2.03

UF/FSM 27509

1.89

Thus Trigonictis clearly is similar to

Grisonella and Galictis in relative

length of Mj-, and unlike Eira, which

has a reduced

Mj-. However, as

noted above, in all features other than

relative

size, M

j- of Trigonictis is

more similar to that of Eira than to that of Grisonella or Galictis. The
overall profile of the mandible of Trigonictis macrodon as seen in labial
aspect in the specimen from Florida (Fig. 4B) is much more like that in
Eira than in Galictis, in that the ventral border is straight, not convex
ventrally, and the coronoid process is broad and blunt, not tapering and
pointed. On the other hand the ventral border is curved and the coronoid
pointed in the Florida specimen tentatively referred to T. cookii (Fig. 7B).
and the shape of the coronoid is reversed in specimens assigned to the two
species from Idaho (Shotwell 1970, Fig. 37J,N). Similarly, we have not
been able to identify consistent characters in the shape and extent of the
masseteric fossa. The “narrower muzzle” of Galera macrodon, as com-
pared to the tayra, noted by Cope, does seem to be reflected in Trigonictis
in its narrower symphyseal region with more crowded incisive alveoli, as
preserved in UF/FSM 18912. In summary, Trigonictis be about

as similar to (and as different from) the tayra, as to (and from) the grison.
The tendency of American authors to refer to Trigonictis as a grison, an
extinct grison, a grison ancestor, or as grison-like is not justifiable, and is
in fact misleading, as a case equally strong and probably equally errone-
ous can be made for the tayra. We are not able to follow Bjork’s
(1970:28) suggestion that T. cookii might be ancestral to Galictis vittata
(and Sminthosinis bowleri to Grisonella cuja), especially as there are
coeval fossil galictines in Eurasia much more like the modern Galictis.

Blancan Carnivore Trigonictis

23

The close relationship between some Neogene palearctic mustelids and
modern neotropical galictines, especially Galictis, has long been recog-
nized (for example. Major 1902:626). A comprehensive discussion of
these Old World forms is beyond the scope of this paper and is in any
event not feasible, as it must be based upon restudy of original materials
and resolution of a welter of morphological, taxonomic, and nomencla-
tural problems (Viret 1954, and Ficcarelli and Torre 1967, provide the best
introduction to the subject). However, a few comments are appropriate
here insofar as the Eurasian material may be instructive in resolution of
North American problems.

Synonymy of New" and Old World forms has been suggested, for
example as follows, '"Trigonictis kansasensis appears to be at least generi-
cally identical with Pannonictis pliocaenica" (Repenning 1967:296; fol-
lowed by Thenius 1972:206 and by Kurten and Anderson 1980:156). We
feel that this is at least premature if not wrong. Pannonictis pliocaenica
has a basined talon in P- similar to that in the grison (Kormos 1931:169;
Schreuder 1935:83). Pilgrim (1932:854-855) also called attention to the
importance of this feature, as follows, “The protocone of P- in Enhydric-
tis is backwardly expanded. . .but the pronounced cusp of Trochictis
retained in Tayra has been replaced by a cup-shaped protocone sur-
rounded by a rim, which is identical with that of Pannonictis and Mus-
telid gen. indet., sp. n., Zdansky and almost so with GrisonT Also
according to Pilgrim P^ is single-rooted in Enhydrictis, as in living
galictines, but not in Trigonictis. The P- of Trigonictis closely resembles
that of the geologically older Trochictis, which also retains a double-
rooted Pj. Trochictis is clearly more primitive than Trigonictis, but may
well have been ancestral, whereas Trigonictis is in turn less advanced than
Enhydrictis, Pannonictis, Galictis, and Grisonella .

Kormos (1934:131), concerned about the great variation in size of
specimens referred to Pannonictis pliocaenica, measured a series of lower
dentitions. He found that the length of Mj- fell into three groups, as
follows: 8 specimens with a range of 10.7-12.0 mm and a mean of 1 1.5
mm; 17, range 12.6-14.5, mean 13.5; 15, range 15.0-16.2, mean 15.6. He
concluded that the largest size group represented males of P. pliocaenica,
the middle group females, and the smallest a new species, P. pilgrimi.
However, after completing the manuscript he discovered a skull of the
new species which proved to be more like the skull of Enhydrictis than
like that of the type species, Pannonictis pliocaenica, in spite of its
Pannonictis-\\\it dentition. Transfer of pilgrimi to Enhydrictis, probably
as a junior synonym of E. ardea (cf. Viret 1954:83), however, is not to say
that Pannonictis is a synonym of Enhydrictis as some American authors
apparently have supposed. Discovery of skulls of Trigonictis macrodon,
T. cookii, and Sminthosinis howleri may prove to be similarly enlighten-

Table 2. Measurements of some jaws and lower dentitions of Trigonictis, compared with statistics for samples from the Hagerman
local fauna, from Bjork (1970) except toothrow length, distance from posterior margin of canine alveolus to posterior
margin of Mj alveolus, from Zakrzewski ( 1967). Measurements in brackets are minima, based on specimens with missing,
broken, or deeply worn teeth. The minimum length of M- for specimens assigned to T. macrodon is for UW 41527, from
Gustaf<ion (1978).

24

Clayton E. Ray, Elaine Anderson, S. David Webb

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fN

1

r'

f

r-

rd

o

1

ro

o

rd

—

id

1

m

iri

i^

1

X

ON

o

o

o

1

m

1

X

1

(N

o

rd

id

od

O

rd

Nd

ON

m

OO

m

m

“

~

m

oo

o

Tt rt sd O

o

1

1

1

o^

r^i

rd

1

■ '

' — '

rn

r-

oc

Tt"

rsi

r4

r-

o’

<N

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—

i— 1

•o

'c

'c

o

00

o

00

« ^

o

o

X

w

X

X
■<— >

•n

X
■*— •
00

•o

c

c

_o

<u

1 —

2

<N rsi rn rs|

■rf Tf" rsi vD

r- o

O vD

I I I I

I I I I

till

till

sO OO

Tt Tt sd

I I I

m fN

Tf fNi

•n- -rt

Tf rf

Tf m vO

m o

rd od

r- o

rn r-’

tn r>-i

rd

rs <N

id Tt \d

m r-

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X)

73

X

X

00

c

•a

<*-

o

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X

Irj

a.

2

o

•a

width of jaw below

Table 3. Measurements (mm) of femora and tibiae of some galictine mustelids; those of Pannonictis pilgrimi taken from the
illustrations in Mottl (1941:figs. 15, 21), those of Trigonictis cookii after Bjork (1970:table 8B).

26 Clayton E. Ray, Elaine Anderson, S. David Webb

13

JC

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oo

oo

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c/3

• ^4

Q

cd

u

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r4

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<— 1

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p

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<u

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c

rv

TD

cd

-S ^

14

0

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05

VJ

<3

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-C)

CN

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.c-» :!!!!_

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c2

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v.

P

Galictis vittata

USNM 395079, adult male 69.4 15.8 4.5 12.0

Blancan Carnivore Trigonictis

27

ing. Meanwhile, synonymizing any of the three is not justifiable. The
status and relationships of Canimartes cumminsii can be assessed only
after addition of new material.

For the present it seems best to regard the Galictinae as including at
least the genera Trigonictis and Sminthosinis in North America, Enhy-
drictis and Pannonictis in Eurasia, and Galictis, Grisonella, Eira, and
Lyncodon in South America. Of these, Trigonictis apparently is the most
primitive, standing closest to Trochictis, the probable ancestor to the
group.

Trigonictis cookii (Gazin), 1934
Fig. 7

Lutravus(?) cookii Gazin 1934:142-143, fig. 2, table 1.

Canimartes ? cookii, Gazin 1937:363-364.

Canimartes(?) coocki, Reig 1957:33.

Caminartes(?) cooki, Reig 1957:41.

Canimartes(?) cooki, Reig 1957:42,44.

Trigonictis cookii, Zakrzewski 1967:293-297. — Hibbard 1972a: 109
(part). — Kurten and Anderson 1980:156.

Trigonictis cooki, Shotwell 1970:82, fig. 37J-L. — Bjork 1970:24-26,
fig. 14. — Galbreath 1972:786. — Hibbard 1972a: 128, fig. 50. —
Gustafson 1978:39-41 (part).

Holotype. — USNM 12606, partial right mandibular ramus, lacking
anterior and posterior extremities and most of ventral margin; retaining
Pj - Mj- well preserved except part of metaconid missing from Mf, retain-
ing alveolus and partial root of Mj, partial alveoli of anterior and poste-
rior roots of Pj with part of posterior root, and posterior wall of alveolus
of canine.

Referred material. — From the western United States, the specimens
assigned to the species by Zakrzewski (1967), Shotwell (1970:82), and
Bjork (1970:24-25), and one specimen, F:AM 49160, assigned to the spe-
cies by Hibbard (1972a: 109, fig. 50); possibly as yet undescribed speci-
mens from Texas and California (Kurten and Anderson 1980:156); also
USNM 25128, incomplete left mandibular ramus with Pj, from Hager-
man, Idaho, collected by C. L. Gazin, 1934.

From the eastern United States, tentatively referred herein, UF/FSM
27509, well preserved right mandibular ramus lacking anterior extremity,
with Pj and M^; collected May 1973 by UF/FSM staff at Haile XVI A,
Alachua Co., Florida.

From the same locality in Florida, there is a complete right humerus,
UF/FSM 27510, of a mustelid, rather similar in its distal half to that of
T. cookii reported by Bjork (1970:26, fig. 14a), though slightly smaller
and lacking the entepicondylar foramen, characteristic only of the skunks

28

Clayton E. Ray, Elaine Anderson, S. David Webb

Fig. 7. Mandibles of Trigonictis cookii in labial (A-C) and occlusal (D-F) aspects, whitened for photography. Labial aspect: A, USNM
25138, Hagerman, Idaho; B, UF/FSM 27509, Haile XVI A, Florida; C, USNM 12606, Hagerman, Idaho, holotype. Occlusal
aspect: D, USNM 25138, Hagerman, Idaho; E, UF/FSM 27509, Haile XVI A, Florida; F, USNM 12606, Hagerman, Idaho, holotype.

Blancan Carnivore Trigonictis

29

among mustelids. The specimen cannot be assigned to Trigonictis, at
least until more is known of its postcranial osteology.

Type locality. — Hagerman (one mi. S of Plesippus quarry), west side
of Snake River, Twin Falls Co., south-central Idaho (Fig. 1, loc. 3).

Distribution. — In addition to the type locality (Fig. 1, loc. 3), in the
Hagerman fauna of early Blancan age, T. cookii is known from the
Jackass Butte locality, Owyhee County, Idaho (Fig. 1, loc. 2), in the
Grandview fauna, and from Frick Prospecting Locality 277, Booth
Draw, Brown County, Nebraska (Fig. 1, loc. 5) in the Sand Draw fauna,
both of late Blancan age. See Distribution under T. macrodon for addi-
tional details.

Haile XVI A, Alachua County, northern Florida (Fig. 1, loc. 10), lies
near the center of the Haile limestone mining district about 1 km north-
east of Haile XV A (Robertson 1976) at an elevation of about 26 m. The
fossil vertebrates occur in a large fissure carved from the late Eocene
Ocala limestone and filled with massive dark, gray-brown, silty clays. The
fissure was at least 8 m wide, and possibly of equal depth; unfortunately
the site was destroyed by mining operations before its dimensions could
be determined with accuracy. The sediments are high in dark organic
content and show no signs of oxidation, unlike most fissure-fill sites in
the Haile district.

The vertebrate fauna from Haile XVI A is currently under study by
Michael Frazier who generously permitted us to mention this local fauna.
Its age is Irvingtonian, probably older than the Coleman II A local fauna
of late Irvingtonian age (Martin 1974). The aquatic elements of the fauna
include Rana, urodeles, abundant kinosternid turtles, Deirochelys,
Chrvsemys, Alligator, and a natricine snake. The diverse terrestrial
fauna, in which Eremotherium and Crotalus are unusually abundant,
includes representatives of both mesic and xeric habitats.

Geologic age. — Blancan Land Mammal Age, with the exception of
the one record of Irvingtonian Land Mammal Age from Haile XVI A, if
the specific identification is correct. See Geologic age under T. macrodon

for additional details regarding western occurrences.

Diagnosis. — As for T. macrodon, but smaller.

Description of eastern specimen. — The right mandibular ramus from
Haile XVI A, Florida, UF/FSM 27509, is complete and well preserved
except for the anterior extremity, including the symphyseal region (Fig.
7B,E). The coronoid process is triangular in outline, with a rather acute
apex, in contrast to the lobate outline with rounded apex in UO 16352
(Shotwell 1970:fig. 37J,K). The incomplete alveoli of Pj reflect crowding
between canine and Pj, with the tooth oriented obliquely and the poste-
rior root situated medial to the anterior root of Pj. P^ is relatively broad,
with a marked posterior heel, completely cingulate, and with a slight

30 Clayton E. Ray, Elaine Anderson, S. David Webb

protuberance in the position of a metaconid, and an undulation on the
posterior crest of the principal cusp. A small pressure facet on the ante-
rior margin of the crown reflects contact with Pj in life, Mj- is robust, with
a strong, discrete metaconid and hypoconid; its deep, closed basin is
bordered posteriorly and lingually by a crenulated crest of uniform height.
A posterior pressure facet evidences contact with Mj, the alveolus of
which indicates a large tooth with a root of circular cross section, in
contrast to that in other specimens of T. cookii, with root cross section
antero-posteriorly enlongate and narrower posteriorly.

Measurements. — See Tables 1-3 for measurements and statistics of T.
cookii, and see Measurements under T. macrodon for discussion of dis-
tinction in size between the two species. Table 2 shows that UF/FSM
27509 falls within the observed range of virtually all available measure-
ments for the meager series of T. cookii, and below that for T. macrodon.
Nevertheless, the toothrow of the Florida specimen is crowded overall
and the teeth broad in comparison to specimens from Idaho (Fig. 7D-F).

Relationships. — For a discussion of the relationships of T. cookii see
this heading under T. macrodon. The relationships of the specimen from
Haile XVI A remain uncertain. Its morphological peculiarities, the possi-
ble pertinence of the humerus from the same deposit, and the Irvingto-
nian age of the fauna, suggest the possibility of a late, derived species.
However, the difficulty experienced by others in interpreting series of
fossil galictine mandibles in the absence of skulls recommends caution.
Therefore, we prefer to assign this isolated jaw to T. cookii pending
recovery of supplementary material.

ACKNOWLEDGMENTS. — Knowledge of the later Cenozoic terres-
trial mammalian fauna in the eastern United States is extremely limited
as compared with that in the western states. Since the opening of the vast
fossil fields of the west more than a century ago, professional paleo-
mammalogists understandably have devoted much less attention to the
relatively unproductive eastern states, where there are no vast exposures
of fossiliferous strata and where results of collecting are apt to be
meager. However, a modest renaissance is underway in the east, largely
as a result of the energetic and effective efforts of an increasingly sophis-
ticated and numerous cadre of dedicated amateurs. In North Carolina,
these hobbyists recently organized themselves as the North Carolina Fos-
sil Club; and in Florida they have formed the Florida Paleontological
Society. The present report provides an example of their already signifi-
cant accomplishments and an inkling of future prospects. Thus, we wish
to thank two members of the North Carolina Club: Donnie Bailey,
whose discovery and contribution of the specimen from North Carolina
stimulated the investigation leading to preparation of this paper, and
Peter J. Harmatuk, who as usual recognized the specimen as unusual and

Blancan Carnivore Trigonictis

31

brought it to the attention of one of us. Likewise, we are grateful to the
Florida amateurs, especially to William Hunt and Kent Ainslie for their
collecting at Santa Fe VIII and to Ben Waller, now President of the
Florida Paleontological Society, for pioneering underwater paleontology
on the Santa Fe River.

Gay Vostreys and Charles Smart made specimens available from the
collections of the Academy of Natural Sciences of Philadelphia, as did G.
B. Corbet from the British Museum (Natural History), and Michael Fraz-
ier from the Haile XVI A fauna. Victor Krantz made the photographs,
and Lawrence B. Isham prepared the figures. The manuscript was
reviewed critically by Jessica Harrison. Robert W. Purdy, Charlotte Hol-
ton, and Carol M. Spawn aided in efforts to learn more about the James
T. Thomas collection from Charles County, Maryland.

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. 1904. Primates, Prosimiae, Chiroptera, Insectivora, Carnivora, Pinni-
pedia. Fasciculus I. pp i-iv + 1-288 in Catalogus Mammalium tarn viventium
quam fossilium. Quinquennale supplementum, anno 1904. 1904-1905. R.
Friedlander and son, Berlin, iv + 929 + vii pp.

Viret, Jean. 1954. Le Loess a Bancs Durcis de Saint-Vallier (Drome) et sa Faune
de Mammiferes Villafranchiens. Nouv. Arch. Mus. Hist. Nat. Lyon 4. 200 pp.

Voorhies, Michael R. 1974. The Pliocene horse Nannippus minor in Georgia:
geologic implications. Tulane Stud. Geol. Paleontol. 7/(2): 109-1 14.

Ward, Lauck W., and B. W. Blackwelder. 1980. Stratigraphic revision of upper
Miocene and lower Pliocene beds of the Chesapeake Group, Middle Atlantic

Blancan Carnivore Trigonictis

35

Coastal Plain. U. S. Geol. Surv. Bull. 1482-D. iv + 61 pp.

Webb, S. David. 1974. Chronology of Florida Pleistocene mammals, pp. 5-31 in
Webb, S. David (ed.). Pleistocene mammals of Florida. Univ. Presses Fla.,
Gainesville, x + 270 pp.

. 1976. Mammalian faunal dynamics of the great American interchange.

Paleobiology 2(3):220-234.

Woodburne, Michael O. 1969. Systematics, biogeography, and evolution of
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271-356.

Wortman, Jacob L. 1883. [Remarks on Galera macrodon.] Am. Nat. 77(9): 1001.
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Accepted 18 March 1981
ADDENDUM

After this paper was submitted for publication, Richard H. Tedford
and Henry Galiano of the American Museum of Natural History very
kindly called to our attention the following unreported specimens of
Trigonictis:

F:AM 63107, partial left maxilla with P-, P-, and M-
lacking labial part of crown. We assign the specimen to T.
macrodon on the basis of size; length of P- 11.2, width 7.8. In
addition P- shows an interesting combination of features tending to
bridge the morphological gap between this tooth in the holotype
and in referred specimens from the west. The occlusal outline is
broadly triangular with a wide talon, as in the holotype, but the
anterior margin is indented more as in the Hagerman specimens.
The cuspation of the talon is reminiscent of that in the holotype of
T. kansasensis (Hibbard 1941a:fig. 5b) and is more complex than in
any other specimen seen, with a strong hypocone, without a domi-
nant protocone, having in its place a group of interconnected cus-
pules in part expressed as crenulations of the cingulum, of which
the anterior-most is strongest.

The specimen is from Matthew Wash, west of Safford,
Graham County, southeastern Arizona, and, though not strictly
referable to any of the published Blancan local faunas in the vicinity
of Safford, is clearly Blancan on the basis of associated fauna and
magnetostratigraphic studies in progress (Tedford, pers. comm.).

Also from the same area (southwest corner of Bear
Springs Flat, west of Safford) is a left mandibular ramus lacking
teeth, F:AM 63109, almost certainly referable to T. macrodon.

F:AM 62740, nearly complete left mandibular ramus with
canine, Pj, Pj, and Mj-. Measurements as in our Table 2: toothrow
length 32.1; Pj length 4.1, width 2.6; Pj length 5.3, width 3.6; Mj-

36

Clayton E. Ray, Elaine Anderson, S. David Webb

length 12.3, width 5.1, length of trigonid 8.4; depth of jaw below Mj-
13.0, width 6.8. In most of these dimensions the specimen lies near
or below the lower extreme of the OR in T. macrodon; Pj and Pj in
particular are smaller than in any other specimen. As pointed out,
however, these teeth are highly variable in size and are of low
diagnostic value. Although this specimen slightly extends the OR in
several variates, we assign it to T. macrodon.

The specimen is from Bevins Pit 2, near Channing, Old-
ham County, in the northwestern part of the Panhandle of Texas.
This unpublished locality is within the Rita Blanca Creek drainage
that includes the Blancan Red Corral local fauna (Schultz 1977:131,
fig. 5), and has produced a Blancan fauna (Tedford, pers. comm.).

Also in the collections of the American Museum of Natu-
ral History are casts of five mandibular rami of Trigonictis from the
University of Nebraska State Museum. Four of these are from the
Broadwater fauna, Morrill County, Nebraska, and clearly represent
T. cookii (length of Mp 10.7 or less), not T. macrodon. If the pub-
lished records (Schultz et al. 1951: table 1; Hibbard 1972b:128, 131-
134) for the larger species are correct, they must have been based on
other specimens. The fourth specimen, from Hooker County, west-
central Nebraska, represents T. macrodon (length of Mj- 13.4).

UF/FSM 18085, isolated right P-, length 9.9, width 6.6.
Its size does not serve to allocate the tooth unequivocally to either
T. macrodon or T. cookii, and we record the specimen only as
Trigonictis sp.

The specimen is from Inglis I A, Citrus County, Florida,
of early Irvingtonian age (Webb 1974:29, table 2.1, fig. 2.1). This
late occurrence and the size and robustness of the specimen are
compatible with the record for Haile XVI A, and reinforce the
suggestion that a derivative Trigonictis extended into the Irvingto-
nian of Florida.

Pseudanophthalmus from Appalachian Caves
(Coleoptera: Carabidae):

The Engelhardti Complex

Thomas C. B ARR, J R.

School of Biological Sciences,

University of Kentucky, Lexington, Kentucky 40506

ABSTRACT. — The engelhardti complex includes about 55 species of
the cave beetle genus Pseudanophthalmus , here arranged in 7 species
groups with the following new species described and illustrated. (1)
ENGELHARDTI group: deceptivus, VA; wallacei, TN; nortoni, TN;
fastigatus, GA; nickajackensis, TN / AL\ sequoyah, AL‘, steevesi, AL. (2)

TEN NESSEENSIS group: pusillus, TN; paynei, TN; unionis, TN. (3)
HIRSUTUS group: sericus, VA; paulus, TN; ventus, TN; assimilis,

AL. (4) HUBRICHTI group: sanctipauli, VA; paradoxus, TN. (5)
JONESl group: scutilus, TN\rogersae, seciusus, \ A\pallidus, TN;
longiceps, VA/TN; thomasi, VA; cordicollis, VA. (6) HYPOLITHOS
group: hypolithos, KY; scholasticus, KY; frigidus, KY; calcareus, KY;
praetermissus, VA. (7) ALABAMAE group: georgiae, GA. Other tax-
onomic changes are: P. delicatus Valentine, new status (full species),
and P. virginicus, new combination for Aphanotrechus virginicus Barr.

The species of the engelhardti complex occupy the Appalachian valley
from Giles Co., Virginia southwest through east Tennessee to northwest
Georgia and north Alabama, including karst “islands” near the eastern
Allegheny front — Pine Mountain (KY/TN), Grassy Cove (TN),
Sequatchie Valley (TN), Lookout Valley (TN/GA), and Wills Valley
(AL). The hypothesis is offered that a majority of species groups of
Pseudanophthalmus are descendants of lineages evolving in the Alle-
gheny plateau and surviving in an Allegheny refugium during the

(

Pleistocene.

The trechine cave carabids of eastern United States include 6 genera
(Barr 1972) of which Pseudanophthalmus Jeannel, with an estimated 200
species, is by far the largest and most widely distributed. The other 5
genera — Neaphaenops, Darlingtonea, Ameroduvalius, Nelsonites, and
Xenotrechus — encompass a total of only 10 or 11 additional species.
This is the first in a series of detailed papers in which I intend to mono-
graph Pseudanophthalmus . It deals with the species of the southern part
of the Appalachian Valley and Ridge Province (hereafter called simply
the “Appalachian Valley”) and of associated karst “islands” within but
near the eastern edge of the Allegheny Plateau.

About one-fourth of the genus (approximately 55 species) consists of
an array of apparently related species which may be called the "''engel-
hardti complex.” In this array presumed relationship among its compo-
nent species is suggested by two apomorphic characters: (I) the apical
recurrent groove of the elytron is elongate and bisinuate, and 2) the

Brimleyana No. 5:37-94. July 1981.

37

38

Thomas C. Barr, Jr.

transfer apparatus within the internal sac of the aedeagus consists of a
canoe-shaped right dorsal sclerite partly enfolding an elongate-triangular,
minutely spinulose, left ventral piece. The species of the engelhardti com-
plex are widely distributed in the Appalachian valley from Giles County,
Virginia, southwestward through eastern Tennessee, southeastern Ken-
tucky (Pine Mountain), and northwest Georgia, to DeKalb and Blount
counties, Alabama, then following the Tennessee River valley westward
across north Alabama, finally northward again to Decatur, Perry, and
Wayne counties in west-central Tennessee. (Seven trans-Allegheny spe-
cies belonging to the engelhardti group will be treated in a subsequent
paper.)

No classification of the genus into species groups and no attempt to
understand the internal phylogeny of Pseudanophthalmus is possible
without a reasonably clear picture of this large block of related species.
The classical conflict between the dual goals of taxonomy — organiza-
tion and retrieval of information versus expression of phylogenetic rela-
tionships — arises in any attempt to regroup the engelhardti complex. In
this paper I propose seven species groups, three of them previously sug-
gested by Valentine ( 1 932) or Jeannel ( 1 949), and four new groups. There
are eleven subsets of related species; four of these are placed in the
engelhardti group as defined here (species clustered around P. engel-
hardti, P. holsingeri, P.fulleri, and P. loedingi, respectively) and two in
the hubrichti group (species clustered around P. hubrichti and P.
egberti). However, I regard all seven groups as internally monophyletic.
A brief list of the five species groups of the northern Appalachian valley
(not in the engelhardti complex) is given at the end of this paper. Four-
teen other groups have been proposed for the numerous species west of
the Allegheny Plateau (see Jeannel 1949: Valentine 1932; Krekeler 1973).

Most of the caves cited in this paper have been described by Douglas
(1964) or Holsinger (1975) for Virginia, Barr (1961) or Matthews (1972)
for Tennessee, and Varnedoe (1973) for Alabama.

This paper is dedicated to the memory of my late friend and colleague.
Dr. Walter B. Jones, for many years State Geologist of Alabama and
founder and Director of the Alabama Museum of Natural History. In the
1940s and 1950s he explored many caves in Alabama, Kentucky, and
Tennessee with Dr. J. Manson Valentine, discovering many new taxa of
cave trechines. He would have delighted in the descriptions of the new
species in the present paper, especially those, I think, from Alabama. I
am particularly pleased that one of the most interesting of the new species
groups {jonesi group) bears his name. His zest for life, his generosity, and
his assistance to those of us who shared his never-ending curiosity about
the subterranean world earned him a major role in the development of
North American biospeleology.

Appalachian Pseudanophthalmus 39

Pseudanophthalmus Jeannel
ENGELHARDTI COMPLEX

Integuments generally pubescent, although dorsum of head and prono-
tum disc subglabrous in a few species. Elytral microsculpture always
more or less transverse, usually a little confused, often obsolescent on
central disc, rarely forming distinct meshes; elytra not pruinose. Anterior
discal puncture at or near level of 4th umbilicate puncture. Apical recur-
rent groove elongate, oblique or subparallel, usually bisinuate (except
alabamae group) and usually connected to apex of 3rd stria with or
without a crosier. Humeri setulose, rarely serrulate. Mentum tooth short,
usually emarginate. Mesosternum simply declivous. Profemur unmodi-
fied. Last abdominal sternite of males with apical margin entire. Transfer
apparatus consisting of an elongate, canoe-shaped right piece (sometimes
with dorsal keel) partly enfolding a smaller, usually shorter, elongate-
triangular, spinulose left piece.

Distribution: — The species of the engelhardti complex occur primar-
ily in the Appalachian Valley and Ridge Province from the New River
valley in Giles County, Virginia, southwest through east Tennessee,
northwest Georgia, and north Alabama, and also in the Tennessee River
valley in west-central Tennessee as far north as Decatur and Perry coun-
ties. They also inhabit karst “islands” near the eastern edge of the Alle-
gheny Plateau — Grassy Cove, Tennessee; Pine Mountain, Tennessee
and Kentucky; Lookout Valley, Tennessee and Georgia; Wills Valley,
Alabama; and Sequatchie Valley, Tennessee and Alabama. Southwest of
Tazewell County, Virginia, all known species of cave trechines in the
Appalachian valley or in karst islands at the edge of the Allegheny Pla-
teau belong to the engelhardti complex. Limited overlap (but not sympa-
try in the same caves) occurs with species of the petrunkevitchi group (all
species with circular, well-formed eye rudiment), which are known from
caves in Washington, Smyth, Wythe, Pulaski, Tazewell (Burkes Garden),
and Bland counties, Virginia. Ranges of engelhardti complex species {P.
quadratus, P. egberti) and pusio and gracilis group species in Giles
County are mutually exclusive (see Barr 1965).

Pleistocene Refugia

Cave species of Pseudanophthalmus are presumably descendants of
edaphobitic ancestors which became extinct outside of caves during
warmer, drier interglacials (Jeannel 1949; Barr 1967a). Jeannel (1949)
proposed a Unaka refugium hypothesis: ancestral beetle stocks spread
over the Appalachian valley and Interior Low Plateaus during glacial
maxima from an interglacial refugium in the higher mountains along the
Tennessee-North Carolina border. A pulse theory of cave colonization

40

Thomas C. Barr, Jr.

was thus implied, each “pulse” corresponding to colonizations at the
beginning of each interglacial. Polytypic Trechus hydropicus and T.
cumberlandus show present distribution patterns suggesting how a
Unaka-based stock might have spread west and north (Barr 1969, 1979a).

Study of the engelhardti complex, coupled with concurrent examina-
tion of cave trechines west of the Allegheny plateau (Barr, in prepara-
tion), suggests a different interpretation. 1) With the notable exception of
the engelhardti group, species groups of Pseudanophthalmus on opposite
sides of the Allegheny Plateau are quite distinct and mutually exclusive.
The small genera of eastern cave trechines — Neaphaenops (see Barr
1979b), Darlingtonea, Ameroduvalius, and Nelsonites (see Valentine
1952) — are limited to Kentucky and part of Tennessee west of the
Alleghenies; they have no counterpart in the Appalachian valley. 2) In
Appalachian valley caves the majority of Pseudanophthalmus species are
concentrated near the Allegheny front and become increasingly rare
toward the Unaka front. 3) No edaphobitic species of Pseudanophthal-
mus have been found in the Unaka region, despite considerable searching
during the past 20 years. In fact, the only edaphobitic, noncavernicolous
species of Pseudanophthalmus thus far known from eastern United
States is P. sylvaticus (Barr 1967b), from Pocahontas County, West Vir-
ginia, in the heart of the Allegheny Plateau. 4) The pattern of species
distribution in caves is not what one would expect from repeated expan-
sion and contraction of an ancestral stock from a Unaka source. Only the
engelhardti group shows this sort of pattern — a series of closely similar
species strung out as if on a chain of islands in an archipelago, with
representatives on both sides of the Alleghenies. All other species groups
in the genus differ substantially across the Allegheny Plateau. The caves
of two karst islands — Grassy Cove and Pine Mountain — are inhabited
by species of the jonesi and hypolithos groups, other species of which are
found in Appalachian valley caves to the east.

The significance of the Allegheny Plateau as an interglacial refugium
for Pseudanophthalmus ancestors has been neglected in favor of Jean-
nel’s Unaka refugium hypothesis. As an alternative view I offer the possi-
bility that the source of many, perhaps most, of the species groups of
Pseudanophthalmus was the upland forest of the Allegheny Plateau. The
diversity within the genus and the difficulty of relating species groups on
opposite sides of the Allegheny Plateau — only the gracilis group (east)
and inexpectatus group (west) seem clearly related (Krekeler 1973) —
suggest that considerable precave diversification may have taken place
within the plateau, and that only those groups near karst areas survived
the warm, dry, climatic regimes of four successive interglacial periods. In
fact, the level of intrageneric diversity opens up the possibility that
Pseudanophthalmus is much older than the Pleistocene. Jeannel (1949

Appalachian Pseudanophthalmus 41

and elsewhere) demonstrated a close relationship between the Eurasian
genus Trechoblemus (eyes and wings usually present) and Pseudanoph-
thalmus and Neaphaenops (I would add Nelsonites), postulating a Euro-
pean introduction ancestral to these cave beetles. In my judgment Lasio-
trechus discus, from eastern Canada and northeastern United States,
belongs within the same phyletic series. Trechoblemus was recently
reported from Oregon (Barr 1972).

The notion of a Unaka refugium should not be totally discarded: the
distribution of the engelhardti group (one of seven groups in the engel-
hardti complex) is compatible with the hypothesis of successive pulses
from a Unaka refugium, and the distribution of the petrunkevitchi group
(Virginia; not treated in detail in this paper) suggests an ancestral refu-
gium in the Blue Ridge. But new and more complete distributional data
for cave trechines in eastern United States, including Pseudanophthal-
mus, strongly support the hypothesis that the Allegheny Plateau played a
major role as a refugium during Pleistocene time and perhaps even ear-
lier. At least two other introductions must be postulated to account for a)
Darlingtonea and Ameroduvalius, of unknown affinities within the Tre-
chini; and b) Xenotrechus, whose two Missouri species are unquestiona-
bly very close to Chaetoduv alius, a genus of the Carpathians and Tran-
sylvanian Alps.

KEY TO SPECIES GROUPS OF THE ENGELHARDTI COMPLEX

1. Apex of aedeagus without constriction before apex (dorsal view) and

without hatchet shape or sharp ventral cusp (lateral view) 2

Apex of aedeagus arrow-shaped in dorsal view because of subapical
constriction and/or hatchet-shaped with sharp ventral cusp in lateral

view (Figs. 5-11) engelhardti group

2(1). Pronotum disc with 1-4 long setae each side in addition to normal

pubescence 3

Pronotum disc pubescent but without longer setae 5

3(2). Small, slender, usually depressed species (3. 1-4.5 mm) 4

Larger (4.4-6. 2 mm), slender, often convex species; aedeagal apex pro-

duced and slender or (Rye Cove, VA) button-shaped (Figs. 48-54)

jonesi group (new group)

4(3). Aedeagus with apex slender, moderately produced and attenuate, with

very finely truncate knob in lateral view (Figs. 12-15)

tennesseensis group (new group)

Aedeagus with apex feebly produced and bluntly rounded at tip, median
lobe weakly arcuate, basal bulb rather small, left copulatory piece very

small (Figs. 20-25) hirsutus group

5(2). Aedeagus with apex slender and considerably produced and attenuate . .6
Aedeagus with apex briefly produced, either bluntly rounded or finely

truncate, in some species also deflexed (Figs. 32-33)

hubrichti group (new group)

42

Thomas C. Barr, Jr.

6(5). Aedeagus with apex strongly deflexed, falciform, slightly knobbed (Fig.
39); apical groove of elytron subparallel to suture; northwest GA,

northeast AL alabamae group

Aedeagus with apex not knobbed, not or but slightly reflexed at tip
(Figs. 34-38); Pine Mountain, KY, and Scott Co. (Hunter Valley), VA
hypolithos group (new group)

Occasional specimens of P. alabamae and P. georgiae {alabamae
group) have 1-3 long setae on the pronotum, so specimens from
northwest Georgia or northeast Alabama should be checked against Fig.
39.

engelhardti group

Aedeagus more or less constricted before apex, which is arrow-shaped
in dorsal view. Length 3. 6-5.4 mm, mean lengths about 4.0-4. 5 mm in a
majority of species. In many species the aedeagal apex bears a sharp,
ventral cusp when examined in lateral view (Figs. 5, 7-1 1); in others the
apex is more or less attenuate and produced, with or without a terminal
knob (Fig. 6). Form subdepressed, pronotum more or less cordiform and
moderately to strongly transverse, pronotal disc without long setae in
addition to normal pubescence (except in west-central Tennessee). Type
species: P. engelhardti (Barber).

Distribution. — Lee Co., VA; Anderson, Campbell, Claiborne,
Decatur, Hamilton, Hancock, Marion, Perry, Rhea, Union cos., TN;
Blount, Colbert, Dekalb, Jackson, Lauderdale, Lawrence, Madison,
Marshall, Morgan cos., AL; Dade, Walker cos., GA. The group is appar-
ently bicentric in distribution with several species along the Virginia-
Tennessee border and the remainder in the lower Tennessee River valley,
from Chattanooga westward.

Pseudanophthalmus engelhardti (Barber)

Anophthalmus engelhardti Barber 1928:195.

Length 3.6-4. 1, mean 3.8 mm. Head rounded; pronotum subglabrous,
5/6 as long as wide, cordiform, greatest width in apical fifth just behind
anterior marginal setae, sides subparallel in basal fifth, hind angles large,
about right, sharp; elytra narrow, 1.7 times longer than wide, humeri not
sharply angular, stria 1-3 well impressed but intervals essentially flat,
apical groove elongate and bisinuate, joining apex of 3rd stria via crosier
at level of 7th umbilicate puncture, usually 2 irregular rows of short but
moderately dense pubescence each interval; aedeagus rather strongly
arcuate, apex rather narrow, sharp ventral cusp slightly reflexed, para-
meres slender with 3 apical setae.

This species is known only from English Cave, Claiborne County,
Tennessee (see Barr 1961 for location, description, and map), where it is

Appalachian Pseudanophthalmus

43

relatively abundant on wet, rotting wood of old bridges and walkways. It

is sympatric and syntopic with two more widely distributed species, P.
rotundatus {engelhardti group) and P.pallidus {jonesi group). At present
this is the only known case in the entire Appalachian valley of three-
species sympatry in the same cave. Normally (three earlier visits) P.
engelhardti is 15 to 20 times more abundant than P. rotundatus, but on
16 September 1979, at the end of an unusually wet summer, I took nine
beetles in English Cave, five of which were P. rotundatus and four P.
engelhardti. Pseudanophthalmus pallidus is known from small series in
the Cedar Fork area a few kilometers south of English Cave, but collec-
tions by at least five" different biospeleologists over the past fifty-two
years have produced only a single specimen of P. pallidus from English
Cave.

Although Valentine (1945) suggested some form of sympatric specia-
tion to explain coexistence of P. engelhardti and P. rotundatus, the more
extensive range of P. rotundatus indicates allopatric speciation with sub-
sequent dispersal and range overlap. The process of geographic specia-
tion outlined by Barr (1967a) still appears to be the best explanation for
species multiplication and divergence in Pseudanophthalmus . Invocation
of other modes of speciation (e.g. chromosomal mutations resulting in
aneuploid gametes in heterozygotes) is conceptually difficult and seems
unnecessary to explain known distributions of related, sympatric species
of anophthalmids.

Pseudanophthalmus deceptivus, new species

Fig. 5

Etymology. — Latin, deceptivus, “deceptive.”

Diagnosis. — Closely similar to P. engelhardti in habitus, pronotum
cordiform with approximately right hind angles, humeri somewhat
rounded, longitudinal striae rather feebly impressed, intervals weakly
convex; aedeagus much more arcuate than that of P. engelhardti, apical
blade deflexed and quite narrowly truncate in lateral view, much con-
stricted and broadly expanded in dorsal view.

Description. — Length of holotype and one paratype 4.0-4. 4 mm.
Form moderate, about as in P. engelhardti', rufotestaceous, shining,
pronotum disc with sparse micropubescence, elytral disc with dense but
rather short pubescence, elytral microsculpture finely transverse. Head
rounded or a little longer than wide (L/W 1.02-1.14), labrum singly
emarginate; last segment of maxillary palp 1.3- 1.4 as long as penultimate
segment; antenna 0.6 body length. Pronotum cordiform, 0.85 as long as
wide, anterior angles small and subdued, sides quite shallowly sinuate in
basal fifth, hind angles large and about right, basal angles small and

44

Thomas C. Barr, Jr.

Figs. 1-4: Pseudanophthalmus spp., engelhardti and tennesseensis groups. 1) P.
wallacei, n.sp. 2) P. nortoni, n.sp. 3) P. fastigatus, n.sp. 4) P.pusillus, n.sp. All
scales in mm.

Appalachian Pseudanophthalmus

45

Figs. 5-11: Aedeagi of Pseudanophthalmus spp., engelhardti group left lateral
view. 5) P. deceptivus, n.sp. 6) P. wallacei, n.sp., a-apex ventral view. 7) P.
nortoni, n.sp. 8) P. fastigatus, n.sp. 9) P. nickajackensis, n.sp. 10) P. sequoyah,
n.sp. 1 1) P. steevesi, n.sp.

rounded; widths at apex and base subequal, about 0.7 greatest width,
which occurs in apical fourth behind anterior marginal setae. Elytra
elongate-oval, 1.6 times longer than wide, disc subconvex; prehumeral
borders oblique, humeri rather prominent but rounded; inner 4 longitud-
inal striae finely but rather shallowly impressed, intervals weakly convex,
striae 5-8 progressively obsolescent; apical groove elongate, oblique, bi-
sinuate, joining apex of 3rd stria at level of 7th umbilicate puncture.
Aedeagus of paratype 0.55 mm long, strongly arcuate, basal bulb bent at
nearly right angle to median lobe, apex briefly produced and deflexed,
apical blade quite narrow in lateral view, conspicuously constricted and
very broad in dorsal view.

Type series. — Holotype female (American Museum of Natural His-
tory), Fisher Cave, near the top of Newmans Ridge, between Blackwater
and Kyles Ford, Fee Co., Virginia (Kyles Ford IV2 Quadrangle, 36°37'22"
X 83'^03'40", elevation 480 m), 17 July 1979, T. C. Barr, Jr., T. C. Barr,
III, and J. R. Holsinger. One male paratype (teneral), same cave, T. C.
Barr, Jr., 30 September 1979.

Measurements (mm). — Holotype, total length 4.37, head 0.84 long X
0.82 wide, pronotum 0.82 long X 0.98 wide, elytra 2.41 long X 1.49 wide,
antenna 2.69.

46

Thomas C. Barr, Jr.

Discussion. — This rare species coexists in Fisher Cave with P. longi-
ceps (jonesi group), which is much more abundant (19:2). On 17 July, six
beetles were collected, one of which was the female holotype of P. decep-
tivus. On 30 September, 14 beetles were collected, one of which was the
teneral male paratype, which was found under rocks at the bottom of the
steep talus slope just inside the entrance of the cave. Morphologically P .
deceptivus is very similar to P. engelhardti, which inhabits English Cave
45 km west of Fisher Cave. At present 10 pairs of Pseudanophthalmus
species are known to coexist in the same cave systems in the Appalachian
valley (excluding the ecologically and geologically very different Green-
brier valley of West Virginia), in addition to the unique case of three
species coexisting in English Cave.

Pseudanophthalmus wallacei, new species

Figs. 1,6

Etymology . — Patronymic honoring Mr. Richard L. Wallace, Knox-
ville, Tennessee, for his assistance in collecting this rare species.

Diagnosis. — Closely similar to P. engelhardti, differing in the sharp,
right (rather than obtuse) hind angles of the pronotum and broader elytra
(L/ W 1.6 vs. 1.7 in P. engelhardti)', aedeagal apex narrowly produced and
truncate, without ventral cusp.

Description. — Length 4. 3-4. 6, mean 4.5 mm (N = 4). With general
form, color, microsculpture, and pubescence of P. engelhardti. Head
rounded, labrum rather deeply and singly emarginate; antenna about 0.6
body length. Pronotum transverse-cordiform, 0.85 as long as wide, wid-
est in apical fifth at level of anterior marginal setae, anterior angles a little
more prominent than in P. engelhardti, hind angles large, sharp, about
right, base behind angles perpendicular to midline (rather than inclined
forward as in P. engelhardti) and distinctly though shallowly emarginate
between angles. Elytra 1.6 times longer than wide, broader and slightly
more convex than in P. engelhardti, margins a little more rounded; pre-
humeral borders oblique, humeri rounded but still rather prominent;
apical groove elongate, bisinuate, with crosier running to 3rd stria at or
slightly in advance of 7th umbilicate puncture. Aedeagus of paratype 0.59
mm, strongly arcuate, apex as in P. holsingeri.

Type series. — Holotype female (American Museum of Natural His-
tory) and one paratype female. Weaver Cave, 3.0 km N Clinton, Ander-
son Co., Tennessee on the southeast (left) side of Clinch River (Norris
71/2' Quadrangle, 36°08'19" X 84°06'55"), 3 February 1980, R. L. Wallace,
One female paratype, same cave, 19 April 1965, J. A. Payne; one female
paratype, same cave, 1 October 1980, R. L. Wallace; one male paratype,
same cave, 1 March 1981, R. L. Wallace.

Measurements (mm). — Holotype, total length 4.32, head 0.84 long X

Appalachian Pseudanophthalmus 47

0.76 wide, pronotum 0.76 long X 0.90 wide, elytra 2.30 long X 1.48 wide,
antenna 2.70 long.

Discussion. — This rare species is probably closest to P. holsingeri,
with which it shares the same aedeagal pattern. It is remarkable that
another species {P. paynei, tennesseensis group) exists in Moores Bridge
Cave only 1.3 km south of Weaver Cave, on the same side of Clinch
River, but P. paynei has not yet been encountered in Weaver Cave, nor
has P. wallacei been taken in Moores Bridge Cave; the two species are
potentially sympatric. From P. wallacei, P. paynei is distinguished by
several pronotal characters: the hind angles are obtuse, the sides are
convergent and not sinuate, and the disc bears two pairs of long setae.

Pseudanophthalmus rotundatus Valentine
Valentine 1932:271.

For many years a very rare species, P. rotundatus was originally de-
scribed from English Cave, also the type locality of P. engelhardti\ it is
more robust than P. engelhardti, with more angular humeri, the prehu-
meral borders perpendicular to the midline, deeper elytral striae, and a
broader apical blade on the aedeagus. Jeannel (1949) reported the species
from Parkeys Cave, Hancock County, Tennessee, farther up the Powell
River valley. J. R. Holsinger and T. C. Kane recently took P. rotundatus
and P. delicatus {hirsutus group) by trapping in Smith Cave, near Rose
Hill, Lee County, Virginia. In July 1979, J. R. Holsinger, T. C. Barr, HI,
and I collected 33 specimens of P. rotundatus in Subers Cave, 2.7 km
east-northeast of Hopewell (Coleman Gap IVi Quadrangle, 36°34'32" X
83‘^25'52"), Hancock County, Tennessee, in a locality intermediate
between English Cave and Smith Cave. The beetles occurred beside a
small stream, under rocks, sticks, and leaves. The range of this species
thus extends along the Powell River valley for approximately 30 km,
overlapping the range of P. delicatus at the northeast end and coexisting
in English Cave with P. engelhardti and P. pallidus.

Pseudanophthalmus sidus Barr

Barr 1965:64.

This rare species is known only from three specimens taken in Mere-
dith Cave, at Shanghai Boat Dock, Campbell County, Tennessee, about
45 km southwest of English Cave in the lower Powell River valley. It is
smaller (3.6-4. 1 mm) than either P. engelhardti or P. rotundatus, subpar-
allel, depressed, polished (microsculpture obsolescent at center of elytral
disc); prehumeral borders perpendicular to midline, humeri angular;
pronotum 0.8 as long as wide, hind angles very large and right. The
aedeagus is shorter (0.51-0.55 mm) and less arcuate than that of P. rotun-

48

Thomas C. Barr, Jr.

datus, with moderately large apical blade, the apex unusually narrow and
rather feebly arrow-shaped when seen from above. The holotype male,
originally in my collection, has been deposited in the American Museum
of Natural History. The species was described on a pair of specimens, and
only one additional male has been taken (September 1979, R. Wallace
and T. Barr).

Pseudanophthalmus holsingeri Barr

Barr 1965:63.

Length 4.2-5. 4, mean 4.8 ± SD 0.3 mm (N = 38). Head 1.2 times as long
as wide, labrum singly emarginate or (often) with low and wide median
lobe. Pronotum transverse-cordiform, greatest width in apical fourth
behind anterior marginal setae, hind angles large, more or less right (but
often slightly obtuse), secondary basal angles small but conspicuous.
Elytra 1.6 times longer than wide, prehumeral borders oblique, humeri
prominent though a little rounded; disc subconvex, flatter near middle, 3
longitudinal striae present and traces of outer striae, intervals flat to
weakly convex; apical groove elongate, bisinuate, running to 3rd stria
apex via crosier at level of 7th umbilicate; pubescence dense but rather
short.

This species is known only from the Young-Fugates Cave system near
Gibson Station, western Lee County, Virginia, where it is relatively
abundant. From the majority of species of ihQ engelhardti group it differs
in having the aedeagal apex deflexed and simply and finely truncate
(lateral view), but without a sharp ventral cusp.

Pseudanophthalmus nortoni, new species

Figs. 2, 7

Etymology. — Patronymic honoring Mr. Russell M. Norton, discov-
erer of this and many other species of cave beetles.

Diagnosis. — Similar to P.fulleri, differing in the perpendicular pre-
humeral borders of the elytra, deeply impressed elytral striae, and
strongly arcuate aedeagus.

Description. — Length of unique holotype 4.28 mm. Form robust and
subconvex. Head rounded, as wide as long; labrum strongly trilobed in
anterior margin; genae subglabrous; 3rd segment of maxillary palp 0.75
as long as 4th segment; antenna 0.6 body length. Pronotum transverse-
subquadrate, 0.9 as long as wide, anterior angles prominent, apex 0.9 as
wide as base, base 0.8 greatest width, which occurs in apical fourth
behind anterior marginal setae; sides subparallel in basal fifth, hind
angles slightly more than right, sharp and slightly produced, secondary
angles of base prominent; disc with one long seta each side, otherwise

Appalachian Pseudanophthalmus

49

with very sparse and short pubescence. Elytra 0.67 times longer than
wide, elongate-oval, prehumeral borders perpendicular to midline, humeri
serrate and setose; all longitudinal striae impressed, intervals subconvex,
with 1-4 rows of pubescence, apical recurrent groove bisinuate, conspicu-
ously oblique to suture, connected to 3rd stria by crosier; microsculpture
obsolete on center of disc. Aedeagus 0.57 mm long (holotype), strongly
arcuate, apex with ventral cusp.

Type series. — Unique holotype male (American Museum of Natural
History), Grassy Creek Cave, 0.7 km S Washington, Rhea Co., Tennes-
see, 3 July 1967, R. M. Norton.

Measurements (mm)." — Holotype, total length 4.28, head 0.80 long X
0.80 wide, pronotum 0.86 long X 0.95 wide, elytra 2.30 long X 1.38 wide,
antenna 2.63 long, aedeagus 0.57.

Discussion. — The type locality cave lies between the Allegheny front
(Waldens Ridge) and the west (right) bank of Tennessee River; it is
developed along a sinking section of Grassy Creek (Evensville IVi Quad-
rangle, 35^3 T40" X 84°54"44"). Judging from overall habitus and aedea-
gal morphology, P. nortoni is closer to P.fulleri, P. nickajackensis, and
other “southern” species of the group than to the more geographically
remote species along the Virginia-Tennessee border.

Pseudanophthalmus fulleri Valentine
Valentine 1932:272. Barr 1965:66.

Length 4.0-4. 5 mm; head rounded, labrum singly emarginate; prono-
tum transverse, almost subquadrate, with shallow lateral sinuation and
large, obtuse hind angles; elytra with angular humeri, widest at middle,
subconvex, striae very shallow, intervals flat to weakly convex, apical
groove elongate, oblique, bisinuate; apex of aedeagus hatchet-shaped,
with sharp ventral cusp, moderately arcuate.

In a previous paper (Barr 1965) I reported a 20 km range extension for
this species, from Tennessee Caverns, Hamilton County, Tennessee (type
locality), to Howards Waterfall Cave, 3.5 km southwest of Trenton,
Dade County, Georgia, predicting that future collecting in Dade County
caves “will eventually yield more P.fulleri and perhaps even the less well
known P. digitus. ...” In 1967 and subsequently, J. R. Holsinger, S. B.
Peck, and their associates collected P. fulleri in the following Dade
County caves, all of them in Lookout Valley on the west side of Lookout
Mountain: Byers Cave, 2.5 km SW Rising Fawn; Johnsons Crook Cave,
7.5 km NE Rising Fawn; Howards Waterfall Cave (additional speci-
mens); Morrison Cave, 3.5 km E Trenton; Sittons Cave, 3.5 km SE
Trenton; Deerhead Cove Cave, near Trenton (T. lies and A. Dobson,
•eg).

50

Thomas C. Barr, Jr.

In Tennessee Caverns, Byers Cave, and Johnsons Crook Cave P.fulleri
coexists with P. digitus {hirsutus group). Related vicar species occur in a
series of en echelon anticlinal valleys nearby: P.fastigatus in the valley of
West Chickamauga Creek to the east, P. sequoyah in Wills Valley to the
southwest, and P. nickajackensis still farther west in the Tennessee River
valley.

Pseudanophthalmus fulleri was the first of a series of closely similar,
allopatric species to be discovered in southeastern Tennessee, northwest
Georgia, north Alabama, and west-central Tennessee. This ^"fulleri series”
includes all species of the engelhardti group in this southern area except
the rather different P. loedingi. All species of the series possess a hatchet-
shaped aedeagal apex with sharp ventral cusp, resembling the northern
species P. engelhardti, P. rotundatus, P. sidus, and P. deceptivus in this
respect. The elytral humeri are minutely serrulate in iht fulleri series, and
occasional specimens have a single long seta on each side of the pronotal
disc. The aedeagal apex in P. loedingi, in contrast, is deflexed, produced,
attenuate, and finely but distinctly truncate; polytypic P. loedingi occu-
pies caves of the Cumberland plateau north of the Tennessee River.
South of the Tennessee River near and west of Guntersville, caves are
occupied by polytypic P. meridionalis Valentine, a member of the fulleri
series.

Pseudanophthalmus fastigatus, new species

Figs. 3, 8

Etymology. — Latin fastigatus, “sloping down, tapered.”

Diagnosis. — Resembles P.fulleri but more polished, humeri much
sharper, greatest width of elytra at apical third, elytral apexes elongate-
attenuate (not rounded), longitudinal striae deeper, intervals subconvex;
aedeagus smaller, apical blade larger, wider, and more deflexed.

Description. — Length 4.4-4. 5 mm (N = 3). Form moderately slender
and elongate, subconvex; rufotestaceous, very polished, pubescent; ely-
tral microsculpture finely and obsoletely transverse. Head 1.2 times longer
than wide, labrum singly emarginate; last 2 segments of maxillary palp
subequal; antenna two-thirds body length, segments rather thick. Prono-
tum transverse, more than 0.8 as long as wide, greatest width in apical
third behind level of anterior marginal setae (as in P.fulleri), width at
apex only seven-eighths width at base, which is about 0.85 greatest width;
anterior angles subdued, sides very shallowly sinuate in basal fifth, hind
angles large and slightly obtuse, secondary angles of base broad, low,
rounded. Elytra highly diagnostic: 1.6 times longer than wide, prehu-
meral borders perpendicular to midline, humeri sharply angular, greatest
elytral width in apical third (rather than at middle) with sides behind

Appalachian Pseudanophthalmus

51

gradually convergent, apexes attenuate; disc subconvex; short scutellar
stria present, longitudinal striae moderately deep, intervals subconvex,
inner 3 striae fairly regular, outer striae progressively obsolescent; apical
groove elongate, oblique, feebly bisinuate, with anterior crosier at level of
7th umbilicate puncture. Aedeagus of holotype 0.55 mm, similar to that
of P. fulleri but a little smaller, apical blade larger, wider, and more
deflexed.

Type series. — Holotype male (American Museum of Natural His-
tory), and one male paratype. Horseshoe Cave, 7 km SW Chickamauga,
Walker Co., Georgia, 10 June 1967, J. R. Holsinger, S. B. Peck, A. Fiske,
and R. Baroody. One paratype male, same cave, 21 June 1967, S. B. Peck
and A. Fiske.

Measurements (mm). — Holotype, total length 4.40, head 0.92 long X
0.76 wide, pronotum 0.83 long X 0.98 wide, elytra 2.36 long X 1.48 wide,
antenna 2.84, aedeagus 0.55.

Discussion. — This small, highly polished species with tapered elytra
was discovered in a cave in the valley of West Chickamauga Creek, on the
opposite (east) side of Lookout Mountain from caves occupied by P.
fulleri and P. digitus. It is probably closest to P. fulleri but is readily
distinguished by the characters cited in the diagnosis. Horseshoe Cave is
stratigraphically and structurally isolated from the caves of Lookout
Valley.

Pseudanophthalmus nickajackensis, new species

Fig. 9

Etymology. — Geographic place name.

Diagnosis. — A large species with cuspate aedeagal apex, moderately
transverse pronotum, oblique prehumeral borders, and 3 feebly impressed
elytral striae, the apical groove oblique and bisinuate, running to apex of
3rd stria; aedeagus strongly arcuate, apex produced, recurved ventral
cusp highly diagnostic.

Description. — Length 4. 1-5.0, mean 4.5 ± SD 0.6 mm (N = 40). Head
slightly longer than wide, dorsum subglabrous; anterior margin of
labrum with low median lobe; 3rd segment of maxillary palp 0.8 as long
as 4th segment. Pronotum 0.8 as long as wide, apex and base widths
subequal and 0.75 greatest width, which occurs in apical fourth; sides
sinuate in basal fifth, hind angles about right, base with prominent
secondary angles; disc subglabrous. Elytra two-thirds longer than wide,
elongate-oval, depressed, prehumeral borders oblique to midline, humeri
nevertheless rather prominent; 3 inner striae shallow, intervals flat, outer
striae obsolescent, 3-5 irregular rows of fine pubescence per interval,
apical recurrent groove elongate, oblique to suture, bisinuate, connected
to 3rd stria via crosier. Aedeagus 0.61-0.65 mm long, strongly arcuate.

52

Thomas C. Barr, Jr.

apex produced and cuspate ventrally, cusp sharply recurved.

Type series. — Holotype male (American Museum of Natural His-
tory), and 87 paratypes, Nickajack Cave, 1.0 km S Shellmound Station
near the mouth of Nickajack Cove, Marion Co., Tennessee, 2 July 1967,
S. B. Peck and A. Fiske; 10 paratypes, same cave, 29 July 1967, S. B.
Peck, A. Fiske, J. E. Cooper; 8 paratypes, same cave, 1 1 November 1967,
J. E. Cooper, J. R. Holsinger, M. Richmond.

Measurements (mm). — Holotype, total length 4.72, head 0.88 long X
0.84 wide, pronotum 0.88 long X 1.06 wide, elytra 2.65 long X 1.59 wide,
antenna 2.08, aedeagus 0.65.

Discussion. — Pseudanophthalmus nickajackensis is readily diagnosed
by the recurved cusp on the ventral side of the aedeagal apex. The species
is known only from the type locality, a large stream cavern which was
unfortunately flooded late in 1967 by the waters of Nickajack Reservoir
and is no longer accessible. The cave was described by Barr (1961:305),
and a map of the cave was published by Matthews (1971: 133). Nickajack
Cave is on the south (left) side of the Tennessee River; most of the cave
lies in Marion County, Tennessee, but a small part extends under Jack-
son County, Alabama.

Pseudanophthalmus sequoyah, new species

Fig. 10

Etymology. — Place name, noun in apposition.

Diagnosis. — Resembling P. fulleri, but differing in slightly longer
head, pronotum hind angles right, elytral humeri less angular and inter-
vals convex, aedeagus more arcuate with shorter copulatory pieces.

Description. — Length 4. 5-5.0, mean 4.7 ± SD 0.1 (N = 10). Moder-
ately robust, subconvex, pubescent, rufotestaceous; microsculpture of
head rather strongly isodiametric, satiny-smooth isodiametric at center
of pronotum apex and base but very finely transverse elsewhere on disc,
very fine and transverse without forming meshes on elytral disc. Head
one-eighth longer than wide, labrum singly emarginate, maxillary palp
with last segment a little longer than penultimate segment; antenna two-
thirds body length. Pronotum transverse-subquadrate, a little less than
0.9 as long as wide, width at apex and base subequal and about 0.75
greatest width, which occurs in apical fifth; anterior angles very promi-
nent, produced; sides subparallel in basal fourth, hind angles large, about
right, somewhat reflexed, and blunt; base with conspicuous secondary
angles; disc glabrous. Elytra almost subparallel, 1.6 times longer than
wide, prehumeral borders not quite perpendicular to midline, humeri
prominent though rounded, disc subconvex; very short scutellar stria
present, inner 3 longitudinal striae well impressed, outer striae progres-
sively feebler and irregular, intervals convex with 3-4 rows of pubescence;

Appalachian Pseudanophthalmus

53

apical groove very long and oblique, feebly bisinuate, running to 3rd stria
via crosier well in advance of 7th umbilicate puncture; elytral apexes
separately rounded. Aedeagus 0.57 mm long (paratype), closely similar to
that of P.fulleri but considerably more arcuate.

Type series. — Holotype male (American Museum of Natural History)
and 6 paratypes, Ellis (=Sequoyah) Cave (AL 333), 3.3 km SW Sulphur
Springs, T4S/R10E/S20, Dekalb Co., Alabama, 25 August 1965, S. B.
Peck. Three paratypes, same cave and collector, 9 August 1965.

Measurements (mm). — Holotype, total length 4.64, head 1.06 long X
0.94 wide, pronotum 0.94 long X 1. 10 wide, elytra 2.73 long X 1.67 wide,
antenna 3.08.

Discussion. — This species occupies a cave at the northwest end of
Wills Valley, west of the Wills anticline; it is thus geologically isolated
from most other Dekalb County caves, which are east of the anticline
axis and inhabited by P. alabamae. Pseudanophthalmus sequoyah coex-
ists with P. assimilis, a smaller and rarer species belonging to the hirsutus
group.

Alabama caves are assigned a sequential number as they are added to
the official list of caves in that state (Varnedoe 1973). For example, Ellis
Cave is AL 333, and nearby Kudzu Cave, discovered and explored much
later, is AL 734.

Pseudanophthalmus steevesi, new species

Fig. 1 1

Etymology . — Patronymic honoring Mr. Harrison R. Steeves, Jr.,
Birmingham, Alabama.

Diagnosis. — A member of the fulleri series, with subquadrate prono-
tum and very shallow elytral striae; aedeagus closely resembling that of P.
fulleri but more sharply recurved at apex.

Description. — Length 4. 2-4.6, mean 4.4 ± SD 0.2 mm (N = 7). Form
subparallel, depressed, pubescent, rufotestaceous; elytral microsculpture
obsolescent-transverse, shining. Head slightly wider than long but basi-
cally rounded; labrum with very low and wide median lobe; last 2 seg-
ments of maxillary palp subequal; antenna two-thirds body length.
Pronotum subquadrate, 0.8 as long as wide, widths at apex and base
subequal and about 0.7 greatest width, which occurs at apical fifth; sides
subparallel in basal sixth, anterior angles not prominent, hind angles
large and more or less right (in some specimens slightly produced and
very sharp), secondary basal angles prominent but rounded. Elytra sub-
parallel, rather depressed, prehumeral borders slightly oblique and
humeri less prominent than in other species of the fulleri series (especially
in specimens from the type locality cave); longitudinal striae very shal-

54

Thomas C. Barr, Jr.

low, 3 or 4 inner striae complete and outer striae obsolescent, intervals
flat; scutellar stria very short, vestigial; apical recurrent groove fairly
long, oblique, feebly bisinuate or not, joining 3rd stria behind level of 7th
umbilicate puncture. Aedeagus 0.55-0.59 mm long, about as in P.fulleri
but not quite as arcuate, median lobe more slender, apex with ventral
cusp more strongly recurved, parameres with 4 quite short apical setae.

Type series. — Holotype male (American Museum of Natural History)
and one paratype male, Randolph Cave, 1.7 km SW Blount Springs,
Blount Co., Alabama (AL 414, T13S/ R3W/S12), 15 June 1967, Harri-
son R. Steeves, Jr., and Thomas C. Barr, Jr. Female paratype, same cave,
12 December 1965, S B. Peck.

Measurements (mm). — Holotype, total length 4.25, head 0.73 long X
0.76 wide, pronotum 0.78 long X 0.98 wide, elytra 2.39 long X 1.45 wide,
antenna 2.84, aedeagus 0.59.

Discussion. — This species has also been collected in Rickwood Cav-
erns (AL 236; one male and one female, 24 November 1972, W. W.
Torode), Bryant Cave (AL 355; female, 19 March 1966, S. B. Peck), and
Horse Cave (AL 721; male, 11 April 1970, W. W. Torode). Rickwood
Caverns and Bryant Cave are both in T13S/R3W near Randolph Cave,
and Horse Cave is in T12S/R1W/S10, all three caves in Blount County.
A total of 7 specimens of this species was examined, including the type
series.

tennesseensis group (new group)

Aedeagus with apex not constricted before base, not arrow-shaped in
dorsal view; apex more or less finely truncate and slightly knobbed;
copulatory pieces as in engelhardti group, left piece large and spinulose.
Length 3. 6-4. 9 mm, mean lengths 3.8-4. 1 mm. The group includes four
depressed, pubescent species with 2 long setae each side of the pronotum
disc. The species occupy caves in Roane, Anderson, Knox, and Union
counties west and north of Knoxville, in the Appalachian valley of east
Tennessee. Type species: P. tennesseensis Valentine.

Distribution. — Roane, Anderson, Knox, Union cos., TN.

Discussion. — All known species of the group are closely similar,
reflecting relatively recent common ancestry, and they are best differen-
tiated by aedeagal structure. Barriers separating the species include both
structural/ stratigraphic ones and the Clinch and Powell rivers. From
other small species with discal setae on the pronotum the species of the
tennesseensis group are separated by the large left copulatory piece (very
small in hirsutus group) and produced, apically knobbed aedeagus
(bluntly rounded in hirsutus group and in P. pallidus, a small species of
the jonesi group).

Appalachian Pseudanophthalmus

55

Figs. 12-15: Aedeagi of Pseudanophthalmus spp. tennesseensis group, left lateral
view. 12) P. tennesseensis Valentine 13) P.pusillus, n.sp. 14) P.paynei, n.sp. 15)
P. unionis, n.sp.

Pseudanophthalmus tennesseensis Valentine

Fig. 12

Pseudanophthalmus tenesensis Valentine 1937:98 (emendation).

Length 3. 7-4. 2, mean 3.9 ± SD 0.2 mm (N = 12). Slender and
depressed, somewhat parallel, pubescent. Head rounded. Pronotum wid-
est in apical seventh, apex one-eighth wider than base, sides convergent
and shallowly sinuate before somewhat obtuse, sharp, and slightly
reflexed hind angles; base with prominent secondary angles; disc subgla-
brous except 2-3 long setae each side. Elytra with humeri prominent,
prehumeral borders perpendicular to midline, striae shallow, intervals
nearly flat, apical groove short, joining 3rd stria behind level of 7th
umbilicate puncture; pubescence of disc dense and not in rows. Aedeagus
0.61-0.65, mean 0.63 mm, moderately arcuate, apex with small button.

Pseudanophthalmus tennesseensis occupies caves in a long strike band
of the Knox group which lies south of the Copper Creek fault in Knox
and Roane counties, Tennessee. It is known from four caves: Grand
Caverns (type locality, also known as Atomic Caverns), George Light
Cave (1.7 km S Solway), and Rock Hill Cave (3.3 km S Heiskell), all in
Knox County; and Eblen Cave (1.7 km SE Bradbury), Roane County.
The known geographic range is approximately 40 km long. In all the
caves P. tennesseensis was collected from under rocks on damp silt, not
beside streams. Total length measurements given by Barr (1965:66) were
0. 1-0.2 mm too small; the aedeagal lengths I previously reported are
incorrect because of a typographical error.

56

Thomas C. Barr, Jr.

Pseudanophthalmus pusillus, new species

Figs. 4, 13

Etymology . — Latin pusillus, “very little.”

Diagnosis. — Closely similar to P. tennesseensis, differing in the much
less prominent anterior angles of the pronotum, less subparallel form of
the elytra, less dense pubescence, and smaller aedeagus.

Description. — Length 3. 7-3.9, mean 3.8 ± SD 0. 1 mm. Closely similar
to P. tennesseensis, differing as follows: Head a little longer than wide,
labrum margin without median lobe; pronotum with anterior angles
subdued, hind angles more sharply reflexed; elytra with less prominent
humeri, margins more arcuate (less subparallel), striae feebler, pubes-
cence less dense. Aedeagus smaller, 0.56-0.57 mm long, basal bulb much
less sharply reflexed, apex a little more attenuate and apical knob slightly
larger.

Type series. — Holotype male (American Museum of Natural History)
and one female paratype, Martin Cave, 7.2 km SW Clinton beside
Southern Railroad tracks, Anderson Co., Tennessee, 23 November 1963,
R. M. Norton; two male paratypes, same cave, 5 January 1966, R. M.
Norton.

Measurements (mm). — Holotype, total length 3.67, head 0.74 long X
0.67 wide, pronotum 0.74 long X 0.76 wide, elytra 2.06 long X 1.23 wide,
antenna 2.43, aedeagus 0.57.

Discussion. — P. pusillus is a vicar species of P. tennesseensis, from
which it is geographically separated by the Copper Creek fault. It occu-
pies caves in Ordovician limestones on the west (right) side of Clinch
River, and is known only from the type locality. This and the next two
species share a relatively recent ancestry with P. tennesseensis.

Pseudanophthalmus paynei, new species

Fig. 14

Etymology. — Patronymic honoring Dr. J. A. Payne, discoverer of
this species.

Diagnosis. — Closely similar to P. tennesseensis, differing in nonsinu-
ate, simply convergent sides of pronotum, less prominent humeri, and
more slender and more produced apex of median lobe of aedeagus with
less sharply defined terminal knob.

Description. — Length 3. 6-4. 9, mean 4. 1 ± SD 0.3 mm (N = 13). Head
about 1.15 longer than wide; labrum trilobed; antenna less than 0.6 body
length. Pronotum 0.85 as long as wide, greatest width at apical fourth
behind anterior marginal setae, sides convergent to obtuse hind angles,
secondary basal angles moderate, 2 long setae either side of disc. Elytra
1.6 times longer than wide, sides feebly rounded, humeri rather promi-

Appalachian Pseudanophthalmus

57

nent but not sharply angular (as in P. tennesseensis), prehumeral borders
slightly oblique, disc a little depressed; 5 or more shallowly impressed
longitudinal striae, intervals flat or feebly convex, apical groove rather
short, bisinuate, running to 3rd stria at level of 8th umbilicate puncture,
without crosier. Aedeagus of paratype 0.63 mm long, arcuate, apex grad-
ually attenuate and very finely truncate, median lobe more slender and
apical knob less pronounced than in P. tennesseensis. Apex thicker and
less abruptly attenuate and apical knob less pronounced than in P.pusil-
lus or P. unionis.

Type series. — Holotype male (American Museum of Natural His-
tory), 1 male, and 7 female paratypes, Moores Bridge Cave, 1.3 km N
Clinton on east (left) side of Clinch River, Anderson Co., Tennessee
(Norris IV2' Quadrangle, 36°0736" X 84°06'55"), 4 July 1967, R. M.
Norton; one male and 2 female paratypes same cave, 22 July 1965, J. A.
Payne.

Measurements (mm). — Holotype, total length 4.10, head 0.84 long X
0.73 wide, pronotum 0.75 long X 0.88 wide, elytra 2.08 long X 1.33 wide,
antenna 2.30 long.

Discussion. — The type locality cave lies a short distance upstream
from the old Moores Bridge across Clinch River, just north of Clinton on
the Norris road (Tennessee Route 61). A steep descent of 45 m opens into
a strike gallery 9 to 15 m wide and 180 m long, with high, irregular ceiling
and damp floor. Beetles occurred about “200 ft. from entrance under
rotten log and stones” (Payne) and near the foot of the entrance drop on
“damp . . . floor with rotting wood” (Norton). This species is quite close
to P. tennesseensis, differing primarily in the convergent sides of the
pronotum, slightly less angular humeri and more rounded sides of the
elytra, and the slightly more arcuate and apically less sharply knobbed
aedeagus. One specimen of this species was collected by R. M. Norton in
Flowstone Cave (Anderson County Park) and one specimen in Norris
Quarry Cave No. 2; both caves are near Norris, in Anderson County,
10-12 km northeast of Moores Bridge Cave.

Pseudanophthalmus unionis, new species

Fig. 15

Etymology . — Geographic place name, from Union County, Tennessee.

Diagnosis. — Closely similar to the preceding three species, differing in
the sparser pubescence of the elytral disc, oblique prehumeral borders,
less prominent anterior angles of pronotum, less subparallel elytra, and
shorter and thicker aedeagus.

Description. — Length 3. 7-4. 2, mean 4.0 mm (N = 3). Head one-sixth
longer than wide, sides feebly rounded; labrum with low median lobe in

58

Thomas C. Barr, Jr.

anterior margin. Pronotum a little transverse, 0.8 as long as wide, ante-
rior angles and secondary basal angles less prominent than in P. tennes-
seensis, margins feebly and briefly sinuate before small, obtuse, but sharp
and slightly reflexed hind angles. Elytra 1.6 times longer than wide; in
contrast to P. tennesseensis prehumeral borders slightly oblique to mid-
line, disc a little more convex, sides slightly rounded, pubescence sparser
and confined to rows on intervals; striae shallow, somewhat irregular,
only inner 4 complete. Aedeagus short and thick, 0.55 mm long in holo-
type, basal bulb bent at right angle to less arcuate median lobe, apex very
briefly produced and finely knobbed. Female unknown.

Type series. — Holotype male (American Museum of Natural His-
tory), Wright Cave, Union Co., Tennessee, 31 December 1963, R. M.
Norton; male paratype, same cave and collector, 6 January 1965; male
paratype. Wolf Cave, Union Co., Tennessee, 22 August 1972, J. R. Hol-
singer and D. C. Culver. Both caves were described and located by Barr
(1961).

Measurements (mm). — Holotype, total length 4.10, head 0.88 long X
0.71 wide, pronotum 0.71 long X 0.86 wide, elytra 2.31 long X 1.35 wide,
antenna 2.77 long, aedeagus 0.55 long.

Discussion. — The species is known only from two caves 2.3 km apart,
both on the north side of Clinch River in the “Peninsula” (the interfluve
between Clinch and Powell rivers). The principal barrier between the
ranges of P. unionis and P. paynei is apparently the Clinch River.
Although P. pusillus and P. unionis are on the same side of Clinch
River, they are separated by Powell River and are in different strike
bands of limestone.

hirsutus group

Aedeagus weakly arcuate, not constricted before apex, which is
bluntly rounded or very feebly knobbed; copulatory sclerites very small,
especially left piece. Length 3. 1-4.5 mm, mean lengths about 3. 7-4.2 mm.
Form slender and depressed, pronotum transverse-cordiform with 2-4
long setae each side of disc, elytra more or less subparallel. Type spe-
cies: P. hirsutus Valentine.

Distribution. — Lee and Scott cos., VA; Hamilton, Marion, and Mon-
roe cos., TN; Dade Co., GA; Dekalb Co., AL.

Pseudanophthalmus hirsutus Valentine

Fig. 20

Valentine 1931:252. Barr 1965:46 (in part).

Length 4.0-4.5, mean 4.2 ± SD 0.2mm (N = 6). Head longer than wide;
pronotum sides convergent to obtuse hind angles, anterior angles rather
prominent; disc with 3 long setae each side; elytra elongate-subparallel.

Appalachian Pseudanophthalmus

59

Figs. 16-19: Pseudanophthalmus spp., hirsutus group. 16) P. delicatus Valen-
tine 17) P. sericus, n.sp. 18) P. paulus, n.sp. 19) P. digitus Valentine

60

Thomas C. Barr, Jr.

striae very fine and regular, intervals flat, at least anterior to posterior
discal puncture (in 2 specimens striae deepen toward apex); apexes atten-
uate, not separately rounded. Aedeagus of a male from Saltpeter Cave
0.47 mm long, similar in general form to that of P. delicatus but a little
larger.

This species is known only from caves in the band of Newman (Missis-
sippian) limestone at the base of Cumberland Mountain (the Allegheny
front) in western Lee County, Virginia. J. F. Quinlan (pers. comm.) has
traced subterranean stream flow from a point near Ewing, Virginia, to
Cudjos Cave, the type locality for P. hirsutus, a distance of about 25 km.
In July, 1979, J. R. Holsinger and Virginia Tipton collected six specimens
of this species in Cumberland Mountain Saltpeter Cave, about 2.5 km
east of (and probably connected with) Cudjos Cave.

Pseudanophthalmus delicatus Valentine, new status

Figs. 16, 21

Pseudanophthalmus hirsutus delicatus Valentine 1932:270. Barr 1965:46
(in part).

Compared with P. hirsutus, smaller (P<0.02) 3. 1-4.2, mean 3.7 ±SD
0.3 mm (N = 31); pronotum a little more transverse with less prominent
anterior angles, sides slightly but distinctly sinuate before sharp right or
slightly acute hind angles; elytral striae deeper. Elongate, subparallel,
depressed, pubescent. Head a little longer than wide, labrum with low
median lobe, last segment of maxillary palp one-fourth longer than
penultimate segment; antenna rather short, 0.6 body length. Pronotum
0.75-0.80 as long as wide, widest about apical sixth behind anterior mar-
ginal setae, anterior angles fairly prominent (but less so than in hirsutus),
sides convergent but shallowly and barely perceptibly sinuate just before
more or less right hind angles (obtuse in hirsutus)', disc with 3 long setae
each side. Elytra 1.7 times longer than wide, apexes not separately
rounded, intervals weakly subconvex, apical groove elongate, bisinuate,
joining 3rd stria via crosier. Aedeagus 0.39-0.45, mean 0.40 ± SD 0.02
mm long (N = 8), slender and weakly arcuate, basal bulb not sharply set
off from median lobe, apex very briefly attenuate and bluntly rounded;
copulatory pieces about as in P. engelhardti but left piece quite small;
parameres with 3 apical setae.

In a previous study of Appalachian valley cave beetles (Barr 1965) I
misinterpreted a series of P. delicatus from Jones (=Ewing) Saltpeter
Cave as P. /2. hirsutus. Actually P. hirsutus is confined to the cave system
at the base of Cumberland Mountain, and P. delicatus inhabits a number
of caves in Ordovician limestones along the Powell River valley in central
Lee County, Virginia. Furthermore, there is a distinct geographic gap

Appalachian Pseudanophthalmus

61

between known ranges of the two species in addition to profound struc-
tural and stratigraphic barriers. Young-Fugate Cave, near Gibson Sta-
tion, lies between Cumberland Mountain Saltpeter Cave and Jones Salt-
peter Cave; more than 50 specimens of Pseudanophthalmus have been
collected in Young-Fugate Cave, but all of them are P. holsingeri (engel-
hardti group).

The ubiquity of this small species in the Powell River valley of Lee
County is surprising. From a point near Ewing northeast to Dryden
(both in Lee County) the range is approximately 45 km long and 8 to 9
km wide, lying north of Wallen Ridge and south of Cumberland and
Stone mountains. Caves from which the species is known include those
developed in middle Ordovician limestone exposed in broad belts along
the Powell Valley as well as caves in the Chepultepec member of the
Knox group. At the southwest corner of its range P. delicatus is sympat-
ric with P. rotundatus {engelhardti group). It is a species of pool and
stream margins or (more often) muddy areas with rotting wood. The
distribution as described is based on examination of 58 specimens from
13 Lee County caves: Gilley (type locality, 13 topotypes seen). Bowling,
Cattle, Gallohan No. 1, Garrett, Jones Saltpeter, Molly Wagle, Poor
Farm, Seal Pit, Smith, Spangler, Sweet Potato, and Unthanks caves. The
majority of these specimens were collected between 1962 and 1979 by J.
R. Holsinger, D. C. Culver, T. C. Kane, R. M. Norton, and T.C. Barr.
Most of the caves were located and described by Holsinger (1975).

Figs. 20-25: Aedeagi of Pseudanophthalmus spp., hirsutus group, left lateral
view. 20) P. hirsutus Valentine 21) P. delicatus Valentine 22) P. sericus, n.sp. 23)
P. digitus Valentine 24) P. ventus, n.sp. 25) P. assimilis, n.sp.

62

Thomas C. Barr, Jr.

Pseudanophthalmus sericus, new species

Fig. 17, 22

Etymology. — Latin sericus, “silken.”

Diagnosis. — Resembles P. delicatus in general form of body and
aedeagus and in weakly subconvex elytral intervals; differs in having
greatest pronotum width at apical 4th (instead of apical 6th), singly emar-
ginate labrum, and separately rounded elytral apexes.

Description. — Length 3.7-4. 1, mean 3.9 ± SD 0. 1 mm (N = 10). Form
slender, subparallel, depressed, pubescent; rufotestaceous; elytral micro-
sculpture obsoletely transverse, shining. Head 0.15 longer than wide;
labrum singly emarginate; maxillary palp with last 2 segments subequal
in length; antenna rather short, about 0.6 body length. Pronotum cordi-
form, 0.8 as long as wide, widest in apical fourth, apex subtruncate and
anterior angles subdued, sides barely perceptibly sinuate in basal fifth,
hind angles obtuse, secondary basal angles evanescent; disc with 2 long
setae each side. Elytra rather subparallel, depressed, prehumeral borders
oblique, humeri a little rounded; no scutellar stria; longitudinal striae
feebly impressed (about as in P. delicatus, i.e. deeper than P. hirsutus),
intervals weakly subconvex, inner 2 striae a little deeper and vaguely
punctulate, striae 3 and 4 shallower, outer striae obsolete; apexes sepa-
rately rounded; apical groove elongate, bisinuate, joining 3rd stria via
crosier slightly in advance of 7th umbilicate puncture; disc moderately
pubescent, 2 or 3 rows per interval. Aedeagus 0.42-0.44 mm long, similar
to that of P. delicatus, but apex somewhat less produced and conspicu-
ously deflexed; parameres with 3 setae.

Type series. — Holotype male (American Museum of Natural His-
tory), 4 male and 5 female paratypes. Lane Cave, in the valley of Moc-
casin Creek, Scott Co., Virginia (Gate City IVi Quadrangle, 36°39'48" x
82°36'46"), 7 October 1967, J. R. Holsinger and George Titcomb.

Measurements (mm). — Holotype, total length 4.10, head 0.84 long X
0.73 wide, pronotum 0.69 long X 0.82 wide, elytra 2.20 long X 1.29 wide,
antenna 2.53, aedeagus 0.44.

Discussion. — Lane Cave is developed in the same strike band of
limestone (Maryville limestone, Ordovician) as Blair-Collins and Coley
No. 2 caves, which lie a few kilometers northeast in Moccasin Creek
valley. However, the latter two caves are occupied by P. thomasi ijonesi
group), and only P. sericus has been collected in Lane Cave. Future
collecting may demonstrate these two species to be sympatric. There
seems little doubt, because of morphological similarity, that P. sericus, P.
hirsutus, and P. delicatus are allopatric vicar species descended from a
common ancestor.

Appalachian Pseudanophthalmus

63

Pseudanophthalmus paulus, new species

Fig. 18

Etymology. — paulus, “little, small.”

Diagnosis. — Related to P. hirsutus and P. digitus', pronotum only 0.7
as long as wide, hind angles right, greatest width in apical third behind
anterior marginal setae; elytral apexes individually rounded, only 2 com-
plete longitudinal striae, inner 3 intervals subconvex, medial umbilicate
punctures widely spaced: distance between 4th and 5th punctures about
1.2 times distance between 5th and 6th punctures.

Description. — Length 3. 7-3. 8 mm. Head 0.1 longer than wide; ante-
rior margin of labrum with low median lobe, 3rd segment of maxillary
palp 0.75 as long as 4th segment; antenna 0.6 total length. Pronotum 0.7
as long as wide, more transverse than in other species of hirsutus group,
apex about 0.1 wider than base and 0.7 greatest width, which occurs in
apical third behind anterior marginal seta, sides subparallel in basal fifth,
hind angles right, secondary angles of base obsolescent; disc with usual
sparse, short pubescence and 2 or 3 long setae each side, but these less
conspicuous than in other species of the group. Elytra 1.8 times longer
than wide, depressed, prehumeral borders nearly perpendicular but
humeri not unusually prominent, apexes individually rounded, with
slight subapical emargination; only inner 2 longitudinal striae complete,
but inner 3 intervals subconvex, each with 2-4 rows of fine pubescence;
apical recurrent groove elongate, bisinuate, slightly oblique, connected to
3rd stria by crosier. Male unknown.

Type series. — Holotype female (American Museum of Natural His-
tory) and one female paratype, Nobletts Cave, 4.8 km W Sweetwater on
the west side of Watson Ridge, Monroe Co., Tennessee, 4 January 1967,
Russell M. Norton.

Measurements (mm). — Holotype, total length 3.73, head 0.82 long X
0.73 wide, pronotum 0.67 long X 0.99 wide, elytra 1.99 long X 1.13 wide,
antenna 2. 19.

Discussion. — The cave in which P. paulus occurs is 0.8 km south of
Tennessee Highway 68 and only 0.5 km east of the McMinn County line
(Niota IVi Quadrangle, 35°35'33" X 84°31'02"). It is a small, muddy
Stream cave about 1 15 km northeast of the range of P. digitus and 215 km
southwest of that of P. hirsutus.

Pseudanophthalmus digitus Valentine
Figs. 19, 23

Valentine 1932:67.

Length 3.6-4. 1, mean 3.9 mm (N = 9). Slender, subparallel, depressed.

64

Thomas C. Barr, Jr.

Head about 1.15 times longer than wide, last segment of maxillary palp
one-third longer than penultimate segment. Pronotum almost as long as
wide, greatest width slightly behind anterior marginal setae, apex and
base widths subequal, sides shallowly sinuate in basal fourth, hind angles
acute, secondary angles of base prominent, disc with 2 long setae each
side. Elytra nearly 1.8 times longer than wide, subparallel, depressed,
humeri prominent even though prehumeral borders a little oblique, apex
rounded; disc densely pubescent, inner 4 striae feebly impressed, traces of
5th and 7th striae discernible, apical groove elongate, bisinuate, subparal-
lel to suture. Aedeagus 0.47-0.48 mm long, evenly arcuate, closely similar
to that of P. hirsutus, with simple apex.

Compared with P. hirsutus, the pronotum of P. digitus is longer with
acute (rather than obtuse) hind angles, and the elytral apexes are con-
spicuously more rounded. Neither Valentine (1932) nor Jeannel (1949)
was able to examine a male of this species, but they correctly surmised
that it is closely related to P. hirsutus. Examination of the aedeagus in
freshly collected material confirms this supposition. The species coexists
in caves of Lookout Valley, Hamilton County, Tennessee, and Dade
County, Georgia, with P.fulleri {engelhardti group). The type locality is
Tennessee Caverns, Hamilton County. J. R. Holsinger and S. B. Peck
collected a total of 9 specimens from Johnsons Crook and Byers caves,
near Trenton, Dade County.

Pseudanophthalmus ventus, new species

Fig. 24

Etymology. — Latin ventus, “wind.”

Diagnosis. — Resembles P. digitus in size, habitus, rounded apexes of
elytra, and aedeagal form; differs in longer head, shorter and wider pro-
notum with convergent (=nonsinuate) sides and right hind angles, and
more convex elytra.

Description. — Length 3. 8-4. 2, mean 4.0 ± SD 0.1 mm (N = 6). Head
1.3 times longer than wide, labrum with low median lobe, last segment of
maxillary palp one-third longer than penultimate segment; antenna 0.75
body length. Pronotum about 0.9 as long as wide, widest in apical sixth,
sides convergent, not sinuate or barely sinuate before hind angles, which
are right or slightly more than right; apex and base widths subequal and
0.75 maximum width, secondary basal angles subdued; disc with 2-3 long
setae each side in addition to sparse, short pubescence. Elytra 1.8 times
longer than wide, moderately convex, elongate-oval, prehumeral borders
slightly oblique to midline, humeri nevertheless prominent, apex rounded,
with slight subapical sinuation; longitudinal striae all discernible (outer
striae obsolescent in one specimen only), at least at base, intervals feebly

Appalachian Pseudanophthalmus

65

convex, with 2-3 rows of pubescence per interval; apical groove elongate,
bisinuate, oblique to suture, connected to 3rd stria by crosier. Aedeagus
0.49-0.53 mm long, evenly arcuate, apex simply rounded as in P. hirsutus
and P. digitus, slightly larger than in P. digitus.

Type series. — Holotype male (American Museum of Natural History)
and 5 paratypes. Blowing Cave, in town of Sequatchie, Marion Co.,
Tennessee (Sequatchie IVi Quadrangle, 35°07T4" x 85®35"39"), 29
August 1968, S. B. Peck.

Measurements (mm). — Holotype, total length 3.96, head 0.92 long X
0.70 wide, pronotum 0.73 long X 0.86 wide, elytra 2.23 long X 1.25 wide,
antenna 2.88.

Discussion. — This species is known only from the type locality, the
outlet of a subterranean stream on the west side of the Sequatchie Valley.
It is closely similar to P. digitus, which occurs about 25 km southeast in
another, parallel, anticlinal valley. The species is a little more densely
pubescent than P. digitus, and there is a slight subapical sinuation in the
elytral margin. More conspicuous character differences are cited in the
diagnosis.

Pseudanophthalmus assimilis, new species

Fig. 25

Etymology. — Latin assimilis, “similar.”

Diagnosis. — Similar to P. digitus, differing in less deeply sinuate
pronotum sides with obtuse hind angles, secondary basal angles less
prominent, outer longitudinal striae of elytra less regular, apical groove
more deeply impressed, and aedeagus less arcuate, middle part of median
lobe straighter.

Description. — Length 4. 2-4.4 mm (N = 4). Form slender, depressed,
pubescent; rufotestaceous, shining; elytral microsculpture very fine,
dense, transverse-obsolescent. Head about 1.15 times longer than wide,
labrum margin with prominent, broad, median lobe; maxillary palp with
penultimate segment 0.8 as long as last segment; antenna 0.7 body length.
Pronotum 0.9 as long as wide, cordiform, sides barely sinuate in basal
fifth, hind angles obtuse and sharp, secondary angles of base subdued;
greatest width in apical fifth, base width slightly greater than apex width
and about 0.7 maximum width; 2-4 long setae on each side of disc in
addition to sparse micropubescence. Elytra subparallel, depressed, 1.7
times longer than wide, prehumeral borders slightly oblique to midline,
humeri prominent though somewhat rounded; inner 3 longitudinal striae
well impressed, intervals subconvex, outer striae very irregular, 4th
vestigial; no scutellar stria; apical groove deeply impressed, bisinuate,
with crosier to 3rd stria or (1 of 4 specimens) running to 5th stria; discal

66

Thomas C. Barr, Jr.

pubescence rather long, 2-3 rows per interval. Aedeagus 0.47-0.49 mm
long, similar to that of P. digitus but middle portion of median lobe
straighter; apex finely attenuate.

Type series. — Holotype male (American Museum of Natural History)
and one paratype female, Ellis (=Sequoyah) Cave (AL 333), 3.3 km SW
Sulphur Springs in T4S/ RlOE/ S20, Dekalb Co., Alabama, 9 August
1965, S. B. Peck. One paratype male, same cave and collector, 25 August
1965.

Measurements (mm). — Holotype, total length 4.24, head 0.82 long X

0. 73 wide, pronotum 0.78 long X 0.84 wide, elytra 2.33 long X 1.35 wide,
antenna 2.86, aedeagus 0.49.

Discussion. — From P. sequoyah, which also occurs in Ellis Cave, P.
assimilis is easily distinguished by smaller size, cordiform pronotum with
2-4 discal setae each side, subdued anterior angles and sharper hind
angles, and shorter and more clearly bisinuate apical groove; the aedea-
gus is very different. A single female of this species was collected March

1, 1970, in Kudzu Cave (AL 734, T4S/R10E/S4), Dekalb County, by W.
W. Torode. The specimen agrees closely with the type series but was not
made a paratype. Ellis Cave lies on the west side of the Wills anticline in
Wills Valley; caves on the east side of the anticline are inhabited by P.
alabamae {alabamae group). Presumably P. assimilis is more closely
related to P. digitus than is P. ventus, judging from external characters,
but the less arcuate aedeagus of P. assimilis is distinctive.

hubrichti group (new group)

Aedeagal apex not arrow-shaped in dorsal view, but briefly attenuate
and finely truncate {hubrichti) or bluntly rounded (egberti) or bluntly
rounded and deflexed (vicarius). Mostly small species, 3. 4-4. 4 mm, but P.
paradoxus ranges between 4. 3-4. 9 mm. Pronotum subcordiform, disc
without long setae; form depressed, moderately slender. Type species: P.
hubrichti Valentine.

Distribution. — Giles, Russell, Scott cos., VA; Hawkins Co., TN.

Pseudanophthalmus hubrichti Valentine
Valentine 1948:13. Barr 1965:47 (in part).

Length 3. 8-4.0 mm. Form a little subparallel, depressed; head rounded,
labrum singly emarginate; pronotum transverse-cordiform, hind angles
obtuse, sides very shallowly sinuate before base, which is oblique behind
angles and shallowly emarginate between; elytra 1.6 times longer than
wide, prehumeral borders oblique and humeri rounded, striae shallow
and punctulate, intervals flat. Apical groove elongate, bisinuate, running
via crosier to 3rd stria in advance of 7th umbilicate puncture, 5th and 6th

Appalachian Pseudanophthalmus

67

\imbilicates widely separated; aedeagus 0.61-0.63 mm long, gently arcuate,
apex briefly produced and bluntly truncate at tip.

This species is known only from Dougherty Cave, 3.3 km northwest of
Lebanon, Russell County, Virginia, on the left bank of Cedar Creek. The
record of P. hubrichti from Banners Corner (=Big Spring) Cave in west-
ern Russell County (Barr 1965:48) applies to the next species.

Pseudanophthalmus sanctipauli, new species

Fig. 26, 32

Pseudanophthalmus hubrichti: Barr 1965:47, NOT Valentine 1948:13.

Etymology. — From town of Saint Paul, Virginia, near the type
locality.

Diagnosis. — Differs from P. hubrichti, to which it is closely similar, in
more slender and more subparallel elytra with perpendicular prehumeral
borders and deeper longitudinal striae; aedeagus longer, less arcuate,
apex more slender but similarly truncate at tip.

Description. — Length 3. 8-4.0, mean 3.9 mm (N = 5). Form and
microsculpture as in P. hubrichti except for more slender elytra and more
angular humeri. Head a little longer than wide, genae weakly convex;
labrum with quite low but distinct median lobe; last segment of maxillary
palp 1.3 times longer than penultimate segment; antenna two-thirds body
length. Pronotum seven-eighths as long as wide, transverse-cordiform,
apex and base widths subequal and each 0.8 greatest width, which occurs
in apical sixth at level of anterior marginal setae; sides sinuate in basal
sixth, hind angles obtuse, sharp, finely and minutely produced; base
emarginate in middle, oblique behind angles, secondary angles small,
sharp, slightly produced. Elytra narrow, 1.8 times longer than wide (1.6
in P. hubrichti), more nearly subparallel than in P. hubrichti, prehumeral
borders perpendicular to midline, humeri angular but a little rounded,
disc depressed; inner 4 longitudinal striae moderately impressed but a
little irregular, outer striae obsolete, intervals weakly convex, each with
about 3 rows of fine pubescence; apical groove elongate, bisinuate,
directed toward apex of 3rd stria but without crosier or actual connec-
tion; distance between 5th and 6th umbilicate punctures 1.2 times greater
than between 4th and 5th umbilicates. Aedeagus 0.59 long in holotype,
longer and less arcuate than in P. hubrichti, apex more slender and
produced, gradually attentuate, finely truncate at tip; parameres rela-
tively short and thick, each with 3 apical setae.

Type series. — Holotype male (American Museum of Natural His-
tory), 1 male and 1 female paratypes. Banners Corner Cave, near St. Paul,
Russell Co., Virginia (Moll Creek IV2 Quadrangle, 36‘^52T7" X
82^ir55"), 12 April 1962, T. C. Barr.

68

Thomas C. Barr, Jr.

Figs. 26-31: Pseudanophthalmus spp., hubrichti and hypolithos groups. 26) P.
sanctipauli, n.sp. 27) P. paradoxus, n.sp. 28) P. hypolithos, n.sp, 29) P.
scholasticus, n.sp., right elytral apex 30) P.frigidus, n.sp., right elytral apex 31)P.
calcareus n.sp., right elytral apex.

Appalachian Pseudanophthalmus

69

Measurements (mm). — Holotype, total length 3.84, head 0.83 long X
0.70 wide, pronotum 0.67 long X 0.80 wide, elytra 2.77 long X 1.54 wide,
antenna 2.56 long, aedeagus 0.59 long.

Discussion. — This species was erroneously determined as P. hubrichti
in an earlier paper (Barr 1965). The caves inhabited by the two species are
in different strike bands of limestone and are separated by major faults.
Head and pronotum are closely similar in the two species, but the nar-
rower elytra with more angular humeri and deeper and impunctate striae
offer useful diagnostic characters. The aedeagi of the two species are
rather different but suggest close relationship. J. R. Holsinger collected
two males from Greears Sweet Potato Cave, Scott County, Virginia (Fort
Blackmore IVi Quadrangle 36^49'03" X 82^3 IT 8"), which I have
assigned to this species but have not made paratypes; this small cave is
about 13 km southwest of Banners Corner Cave in the same band of
Maryville limestone.

Pseudanophthalmus egberti Barr

Barr 1965:49.

Length 3. 4-4.2, mean 4.0 ± SD 0.1 mm (N = 9). Slender, depressed,
shining. Head a little longer than wide, labrum singly emarginate. Prono-
tum strongly cordiform with deep antebasal sinuation, sides slightly di-
vergent at base, hind angles correspondingly large, sharp, and acute; apex
truncate, base rectilinear. Elytra slender, depressed, prehumeral borders
a little oblique yet humeri fairly prominent, striae deep, intervals convex,
only striae 1-3 complete but traces of 5-8 present; apical groove subparal-
lel, rather short, running to 3rd stria, clearly bisinuate in 6 of 10 speci-
mens examined. Aedeagus 0.61-0.65 mm long (greater lengths in the
original description are a typographical error), moderately arcuate with
well-formed basal bulb, apex briefly attenuate and slightly deflexed.

Pseudanophthalmus egberti is known only from two caves in the New
River valley of Giles County, Virginia: Starnes Cave (type locality) and
Giant Caverns (=Hopkins Cave).

Pseudanophthalmus quadratus Barr

Barr 1965:60.

Closely similar to P. egberti but a little less slender, hind angles right,
elytral striae shallow, intervals less convex, apical groove bisinuate;
aedeagal apex produced and bluntly rounded, not deflexed. Length 3.4-
3.7 mm, aedeagus 0.66-0.67 mm. This species was erroneously placed in
\hQ gracilis group (Barr 1965) but is much closer to P. egberti and belongs
here. It is known from three males taken in Straleys Cave in the valley of

70

Thomas C. Barr, Jr.

New River at Eggleston, Giles County, Virginia, and is the northernmost
representative of the engelhardti complex.

Pseudanophthalmus vicarius Barr

Barr 1965:48.

Length 3. 5-4.4, mean 3.9 mm. Similar to P. egberti but more robust
and more convex. Pronotum with apex truncate, hind angles large and
slightly acute, antebasal sinuation deep, basal angles weakly developed,
base slightly concave. Elytra broader, subconvex, intervals less convex, 4
complete inner striae, apical groove bisinuate, running to 3rd stria (no
crosier) at level of 7th umbilicate. Labrum margin somewhat variable,
often with low median lobe. Head more rounded than in P. egberti,
tenerals and late tenerals with small, lemon-shaped eye rudiment visible.
Aedeagus similar to that of P. egberti but apex more slender, briefly
produced, and deflexed.

This species occurs in caves of the Maiden Spring area, Tazewell
County, Virginia: Hugh Young Cave (type locality), Bowen Cave, Fallen
Rock Cave, Gully Cave, and Lost Mill Cave (see Douglas 1964 and
Holsinger 1975 for locations and descriptions).

Pseudanophthalmus paradoxus, new species

Figs. 27, 33

Etymology. — Latin paradoxus, “paradox.”

Diagnosis. — A large species with greatly reduced dorsal pubescence,
the aedeagal apex deflexed and bluntly rounded at the tip, as in P.
vicarius.

Description. — Length 4. 3-4.9, mean 4.7 ± SD 0.2 mm (N = 8). Form
rather robust and depressed; shining, microsculpture on elytral disc obso-
lescent and finely transverse; dorsally subglabrous, pubescence very short
on pronotum and elytral disc, denser internal to elytral margins. Head
longer than wide, a little depressed, sides moderately rounded, labrum
singly emarginate; last segment of maxillary palp one-sixth longer than
penultimate segment. Pronotum transverse-cordiform, 0.83-0.85 as long
as wide, widest in apical fourth, sides convergent to prominent antebasal
sinuation, apex wider than base and 0.75 maximum width; hind angles
large, sharp, nearly right, basal impressions short, deep, oblique. Elytra
1.7 times longer than wide, elongate-subparallel, depressed; humeri
moderate, finely serrulate, setose; inner 4 striae moderately impressed
and vaguely punctulate, intervals weakly convex; apical groove elongate,
bisinuate, connected to 3rd stria via crosier at level of 7th umbilicate
puncture. Aedeagus 0.95-1.00 mm long, basal bulb large and flexed at

Appalachian Pseudanophthalmus

71

less than right angle to median lobe, which is swollen near base of inter-
nal sac; apex briefly attenuate, deflexed, slightly knobbed, rounded at tip;
parameres rather broad, with 3 or 4 long apical setae.

Type series. — Holotype male (American Museum of Natural His-
tory), Sensabaugh Saltpeter Cave, about 8 km W Kingsport, Hawkins
Co., Tennessee (Church Hill IVi' Quadrangle, 36^33'57" X 82''38'05"),
May 1968, Sam Taylor and Dick Powers, leg. One paratype female, same
cave, 16 June 1963, L. G. Conrad. Six paratypes, same cave, 17 July
1979, T C. Barr, Jr., T. C. Barr, III, and J. R. Holsinger.

Measurements (mm). — Holotype, total length 4.92, head 0.94 long X

O. 88 wide, pronotum 0.85 long X 1.03 wide, elytra 2.73 long X 1.58 wide,
antenna 3.21, aedeagus 0.95.

Discussion. — The form of the aedeagus is strikingly similar to that of

P. vicarius. At present P. paradoxus is the only known Tennessee
Pseudanophthalmus species in the Holston Valley and the only known
species south of Clinch Mountain. The type locality cave opens near the
top of a wooded ridge in a subdivision of Kingsport; from the mouth a
steep, muddy slope drops about 40 m to a small stream. The specimens
collected in July 1979 were taken from under rocks and rotten wood near
a ceiling drip, and no specimens were encountered along the stream. The
microhabitat is thus similar to that of P. longiceps (jonesi group), another
species of rather large size which inhabits caves high on a ridge. Sensa-
baugh Saltpeter Cave is also known as Moffitt Saltpeter Cave or simply
“Saltpeter Cave;” another cave in the vicinity, described as Click Creek
Cave by Barr (1961), is sometimes locally called “Sensabaugh Cave”
because it is near the Sensabaugh (railroad)Tunnel.

jonesi group (new group)

Aedeagus with apex produced, long and slender, not arrow-shaped in
dorsal view, in lateral view tapering to a point (P. cordicollis), with a
terminal button {P. seclusus), or simply bluntly rounded. Most species
large to medium-large (4. 2-6. 2 mm), although one species {P. pallidus) is
3. 9-4. 3 mm. Form slender to very slender, convex, appendages elongate;
pronotum elongate-cordiform with sides shallowly sinuate before small
hind angles, disc with 1-4 long setae each side. Type species: P. jonesi
Valentine.

Distribution. — Lee, Scott, and Wise cos., VA; Harlan Co., KY;
Campbell, Claiborne, Cumberland, and Hancock cos., TN.

72

Thomas C. Barr, Jr.

Figs. 32-39: Aedeagi of Pseudanophthalmus spp., hubrichti, hypolithos, and
alabamae groups. 32) P. sanctipauli, n.sp. 33) P. paradoxus, n.sp. 34) P. hypo-
lithos, n.sp. 35) P. scholasticus, n.sp. 36) P. frigidus, n.sp. 37) P. calcareus,
n.sp. 38) P. praetermissus, n.sp. 39) P. georgiae, n.sp.

Pseudanophthalmus jonesi Valentine

Fig. 48

Valentine 1945:645. Barr 1965:62.

Length 4. 6-4. 8 mm. Form elongate, slender, moderately convex. Head
1.2 times longer than wide; labrum with distinct median lobe. Pronotum
0.9 as long as wide, cordiform, greatest width in apical fourth just behind
anterior marginal setae; base width and apex width subequal, about 0.7
greatest width; sides subparallel in basal fifth, hind angles large, approx-
imately right, sharp, secondary basal angles prominent; disc with 2 long
setae each side. Elytra 1.7 times longer than wide, widest behind middle,
rather convex, prehumeral borders oblique to midline but humeri angu-
lar and very prominent; microsculpture transverse-obsolescent on disc;
short scutellar stria present; inner two longitudinal striae finely impressed,
intervals subconvex, outer striae gradually obsolescent; apical groove
elongate, not clearly bisinuate, subparallel, running to 3rd stria or not.
Aedeagus 0.73-0.76 mm long, basal bulb large and set off from weakly
arcuate median lobe, apex gradually attenuate, finely and bluntly rounded
at tip; parameres with 4-5 apical setae.

Appalachian Pseudanophthdlmus

73

Pseudanophtahlmus jonesi is known from three caves in Grassy Cove,
a large polje along the plunging axis of the Sequatchie anticline in Cum-
berland County, Tennessee: Grassy Cove (=Brady) Saltpeter Cave, the
type locality; nearby Mill Cave; and Blowhole (=“The Gouffre”). Grassy
Cove is a karst island in the interior of the Cumberland Plateau; caves in
the Appalachian valley to the east are occupied by species of the engel-
hardti and hirsutus groups. In common with P. scutilus and P. rogersae,
which occur in another karst island. Pine Mountain, P. jonesi has the
elytra widest behind the middle and the apical groove is not distinctly
bisinuate. This is the only species of the group previously described.
Valentine (1945) quite rightly noted its unusually attenuate form and
speculated that it was a representative of a more widely distributed stock.

Pseudanophthalmus scutilus, new species
Figs. 40, 49

Etymology . — Latin scutilus, “very lean.”

Diagnosis. — Resembling P. jonesi in the indistinctly bisinuate apical
groove and slightly ventricose elytra, but head proportionately larger,
pronotum more cordiform, and elytral striae obsolete.

Description. — Length 4.3-5. 4, mean 4.8 ± SD 0.3 mm (N = 1 1). Form
elongate and slender, convex, with elongate appendages; color pale rufo-
testaceous, shining but a little dull; elytral microsculpture finely trans-
verse, a little confused. Head rather large, a fourth longer than wide,
maxillary palps with penultimate segment about 0.7 as long as fourth
segment, labrum with obsolete median lobe. Pronotum slender and cor-
diform, only slightly wider than long (L/W 0.94-0.96), greatest width in
apical fifth at level of anterior marginal setae, apex width slightly greater
than base width and about 0.8 greatest width; disc convex, with 1 or 2
long setae each side in addition to sparse micropubescence; anterior
angles subdued, sides shallowly sinuate in basal seventh, hind angles
sharp and a little more than right, secondary basal angles only suggested.
Elytra elongate-oval, 1.8 times longer than wide, convex, deplanate
around scutellum, prehumeral borders a little oblique to midline, humeri
somewhat rounded, finely setose but not serrulate; discal pubescence
short, fine, rather sparse; longitudinal striae obsolete, inner 3 striae
barely visible, intervals flat, outer striae absent, no scutellar stria; apical
groove rather short and deep, hardly bisinuate but with slight suggestion
of anterior flexure, ending blindly at level of anterior apical puncture.
Aedeagus 0.71-0.73 mm long, basal bulb not greatly enlarged, median lobe
slender, moderately and evenly arcuate, apex finely attenuate but without
knob, truncation, cusp, or other special modification; parameres short,
with 4 terminal setae.

74

Thomas C. Barr, Jr

Figs. 40-43: Pseudanophthalmus spp., 70^7^5/ group. 40) P. scutilus, n.sp. 41) P.
rogersae, n.sp. 42) P. seclusus, n.sp. 43) P. pallidus, n.sp.

Appalachian Pseudanophthalmus

75

Type series. — Holotype male (American Museum of Natural History)
and one female paratype, New Mammoth Cave, 1.5 km E Elk Valley on
the north side of Pine Mountain, Campbell Co., Tennessee (Ivydell IV2
Quadrangle, 36°29'03'' x 84°13'46"), 8 August 1979, T. C. Barr, Jr. Two
paratypes, same cave, 16 September 1979, T. C. Barr, Jr. Seven para-
types, same cave, 21 November 1979, T. C. Barr, Jr., and J. R. Holsinger.

Measurements (mm). — Holotype, total length 4.80, head 0.98 long X
0.78 wide, pronotum 0.84 long X 0.88 wide, elytra 2.67 long X 1.49 wide,
antenna 3.31, aedeagus 0.71.

Discussion. — This species, isolated within the Allegheny Plateau but
near its eastern front like P. jonesi, appears more closely related to P.
jonesi than to other species of the group. Grassy Cove and Elk Valley are
approximately 90 km apart. New Mammoth Cave has a large, rather dry
upper level several hundred meters long; small crevices through break-
down lead down to a lower stream passage at various points. The cave is
more extensive than indicated by the map reproduced in Barr (1961:92).
The beetles are very hygrophilous, all of them taken from very wet,
soggy, rotten wood at the edge of the stream. One small log, its end actually
immersed in the stream, yielded a beetle on each of three collecting visits
to the cave; a large colony of collembolans, Folsomia Candida, was found
just inside the outer layers of the log and was a probable food source for
the beetles.

Pseudanophthalmus rogersae, new species

Fig. 41

Etymology . — Patronymic honoring Mrs. Mary Rogers, Pine Moun-
tain Settlement School.

Diagnosis. — Resembles P. scutilus in the singly emarginate labrum,
indistinctly bisinuate apical groove, and slightly ventricose elytra, differ-
ing in cordiform pronotum with abrupt lateral sinuation and large hind
angles, regular and shallowly impressed elytral striae, and subconvex
intervals.

Description. — Length of unique holotype 4.65 mm. Form elongate,
slender, convex, appendages elongate; rufotestaceous, dull shining, pubescent;
elytral microsculpture confused, isodiametric in striae and weakly trans-
verse on intervals. Head a fourth longer than wide, labrum singly emar-
ginate, maxillary palp with fourth segment about 0.2 longer than penul-
timate segment; antenna 0.7 body length. Pronojum cordiform, 0.9 as
long as wide, widest in apical third behind anterior marginal setae, widths

76

Thomas C. Barr, Jr.

at apex and base subequal and 0.75 maximum width; sides rather
abruptly sinuate at basal 0.4, then convergent to large, obtuse hind angles,
base oblique behind angles, secondary angles small and inconspicuous;
disc rather convex, with 3 long setae each side and scattered pubescence.
Elytra 1.75 times longer than wide, widest behind the middle, prehumeral
borders oblique to midline, humeri somewhat rounded, antapical sinua-
tion shallow; disc convex, deplanate near scutellum, rather densely
pubescent; striae regular and shallow but deeper than usual for jonesi
group, intervals subconvex, apical groove elongate and subparallel to
suture, running into 3rd stria. Male unknown.

Type series. — Unique holotype female (American Museum of Natural
History), Sawmill Hollow Cave, 2.0 km NNW Nolansburg and 600 m
ESE Pine Mountain Settlement School on the northwest slope of Pine
Mountain, elevation 700 m (Nolansburg IVi Quadrangle, 36°56'50" x
83^10'31"), 23 August 1979, T. C. Barr, Jr., and T. C. Barr, HI.

Measurements (mm). — Holotype, total length 4.65, head 1.01 long X
0.80 wide, pronotum 0.83 long X 0.92 wide, elytra 2.63 long X 1.50 wide,
antenna 3.21.

Discussion. — Even though no male is available, the species is readily
differentiated on external characters alone. It is evidently related to P.
jonesi and P. scutilus, differing in the pronotal and elytral strial charac-
ters cited in the diagnosis. Sawmill Hollow Cave is a small cave (length
about 300 to 400 m) consisting of muddy crawlways on two or three
levels, with a small stream and a pool in the lowest level; the cave is in
Newman limestone dipping southeast at about 32^. The unique holotype
was collected at the lower end of a section of the cave called “The Emper-
or’s Palace”, a small stream channel intersected by a 10-m dome.

Pseudanophthalmus seclusus, new species

Figs. 42, 50

Etymology. — Latin seclusus, “remote, separated.”

Diagnosis. — Distinguished from other species of the group by the
following combination of characters: labrum with prominent median
lobe, elytra subconvex with subparallel sides and broadly rounded
apexes, head nearly 1.3 times longer than wide, elytral striae shallowly
impressed and inner intervals subconvex, aedeagus with apex briefly
reflexed and obliquely truncate.

Description. — Length 4.2-5. 0, mean 4.6 ± SD 0.2 mm (N = 40). Pale
rufotestaceous, form rather elongate and subconvex, pubescent. Head
1.25-1.28 times longer than wide, labrum with prominent median lobe in
anterior margin (doubly emarginate), antenna 0.6 times body length.
Pronotum 0.85 times as long as wide, greatest width in apical fourth

Appalachian Pseudanophthalmus

11

behind level of anterior marginal setae, widths at apex and base subequal
and 0.75 greatest width; sides feebly sinuate in basal fifth, anterior angles
subdued, hind angles large, acute, slightly produced and elevated, second-
ary angles of base prominent but broadly rounded; disc with 1-3 (usually
2) long setae each side in addition to sparse, rather long pubescence.
Elytra 1.7 times longer than wide, subparallel but rather broad, humeri
prominent but not sharp, prehumeral borders oblique to midline, apexes
broadly rounded; scutellar stria long, attaining suture at level of 4th
umbilicate puncture, striae 1-3 shallowly impressed, intervals subconvex
with 2-3 rows of pubescence, outer striae irregular and progressively
obsolescent, apical recurrent groove elongate and bisinuate, joining 3rd
stria via crosier in advance of anterior apical puncture. Aedeagus 0.67-
0.74, mean 0.69 ± 0.03 mm long (N = 8). moderately arcuate, basal bulb
large but not sharply set off from median lobe; apex of median lobe
slightly swollen, then briefly reflexed and obliquely truncate, buttonlike,
at tip; right copulatory piece canoe-shaped, partially enfolding elongate-
triangular, minutely spinulose, shorter left piece; internal sac weakly
armed with minute spines; parameres rather stout, with only 3 apical
setae.

Type series. — Holotype male (American Museum of Natural History)
and 45 paratypes, Flannery Cave, Scott Co., Virginia (Clinchport IVi
Quadrangle, 36°42'28" x 82°43'30"), 1 August 1964, S. B. Peck and J. R.
Holsinger.

Measurements, (mm) — Holotype, total length 4.64, head 1.02 long X
0.76 wide, pronotum 0.86 long X 0.92 wide, elytra 2.55 long X 1.45 wide,
antenna 2.96, aedeagus 0.71.

Discussion. — Pseudanophthalmus seclusus is known from a series of
caves in the Rye Cove karst near Clinchport, Scott County, Virginia,
including Flannery (type locality), McDavid (traversed by the Flannery
Cave stream). Alley No. 2, Cox Ram Pump, Pond, Hill, and Kerns No. 1
caves. Most of the caves are developed along the eastern flank of the Rye
Cove syncline and were described by Holsinger (1975). A total of 54
specimens was seen. The species is abundant on mud banks along the
stream in Flannery Cave. Four specimens were taken in McDavid Cave
and only one or two each in the other caves cited above. The form of the
aedeagus, with reflexed and obliquely truncate, buttonlike apex, is highly
diagnostic. Superficially P. seclusus is closest to P.pallidus, which occurs
along the Powell River in Claiborne County, Tennessee, but it is larger,
has a longer pronotum, and the elytral apexes are quite broadly rounded
rather than attenuate as in P. pallidus.

78

Thomas C. Barr, Jr.

Pseudanophthalmus pallidus, new species

Figs. 43, 51

Etymology. — Lsitin pallidus , “pale.”

Diagnosis. — A moderately depressed and slender species of small size
(3. 9-4.3 mm), the elytral striae obsolescent and the aedeagal apex simple.

Description. — Length 3. 9-4.3, mean 4.2 ± SD 0.2 mm (N = 8). Rather
pale testaceous, moderately slender and subconvex, dull shining, moder-
ately pubescent. Head 0.2 longer than wide; labrum with prominent
median lobe in anterior margin; antenna two-thirds body length. Prono-
tum 0.87 as long as wide, cordiform, apex 0.1 wider than base and 0.75
maximum width; anterior angles prominent, sides evanescently sinuate
and almost convergent from apical third to obtuse, sharp, slightly ele-
vated hind angles, base oblique behind angles, small secondary angles
broadly rounded; disc subconvex, 3 long setae each side. Elytra 0.75 longer
than wide, elongate-oval, prehumeral borders oblique to midline, humeri
rather prominent; 4 inner striae and trace of 5th vaguely discernible,
intervals flat, apical groove elongate and bisihuate, joining 3rd stria via
crosier. Aedeagus 0.52-0.53 mm long, smaller than in any other known
species of the jonesi group; apex simply and briefly attenuate.

Type series. — Holotype male (American Museum of Natural His-
tory), 1 male and 3 female paratypes, Chadwell Cave, 6 km NE Tazewell,
425 m S of Cedar Fork Road, and 1000 m N of Henderson Knob, in a
wooded sink at elevation 400 m (Tazewell IV2 ' Quadrangle, 36‘^29'46" x
83^3 r23"), 18 July 1979, T. C. Barr, Jr., T. C. Barr, III, and J. R.
Holsinger; one paratype male, same cave, 1 March 1964, S. B. Peck.

Measurements (mm). — Holotype, total length 4.34, head 0.89 long X
0.73 wide, pronotum 0.77 long X 0.89 wide, elytra 2.36 long X 1.35 wide,
antenna 2.88, aedeagus 0.53.

Discussion. — Chadwell Cave, developed in the Harrison Bridge and
Martin limestones (Ordovician), has approximately 600 m of readily tra-
versable passages. Most of the specimens of this species occurred on wet
silt under rocks near the stream. In addition to Chadwell Cave, P. palli-
dus has been taken in nearby Buis Saltpeter Cave (6.7 km northeast of
Tazewell, two females) and English Cave (Barr 1961:115), both in Clai-
borne County. The single female from English Cave, taken in July 1965
by J. Holsinger and C. Rippy, establishes the first known case of sympa-
try of three species of Pseudanophthalmus in the Appalachian valley.
Much more abundant in English Cave are P. engelhardti and P. rotunda-
tus, the former known only from English Cave and the latter extending
up the Powell River valley to small caves near Rose Hill, Lee County,
Virginia. A troglobitic milliped, Pseudotremia nodosa Loomis, and a
troglobitic pseudoscorpion, Kleptochthonius affinis Muchmore, are

Appalachian Pseudanophthalmus

79

found in English Cave as well as in the caves of the Cedar Fork area.
There is no obvious structural geologic barrier separating these caves.

Pseudanophthalmus longiceps, new species

Figs. 44, 52

Etymology. — Latin longiceps, “long head.”

Diagnosis. — Differs from other species of the group in the slender
form and unusually elongate head (1.5 times longer than wide), the small,
acute, pronotal hind angles, and the shallow elytral striae with subconvex
intervals.

Description. — Length 4. 6-6. 2, mean 5.3 ± SD 0.3 mm (N = 17). Form
elongate, head very narrow, pronotum small and rather convex, elytra
convex; rufotestaceous, sparsely pubescent, elytral microsculpture finely
transverse, obsolescent. Head nearly 1.5 times longer than wide, sides
subparallel, dorsum depressed; anterior margin of labrum with low but
sharp median lobe; frontal grooves feeble behind, barely extended onto
sides of head, subaphaenopsian. Pronotum cordiform, 0.9 as long as
wide, convex, disc with 4 long, somewhat irregular setae each side; widths
at apex and base subequal and 0.75 greatest width, which occurs in apical
sixth at placement of anterior marginal setae; anterior angles prominent,
a little produced, sides feebly and very shallowly sinuate in basal sixth,
hind angles small, sharp, a little less than right; basal impressions deep
and oblique, secondary basal angles subdued. Elytra broadly convex,
slightly ventricose, prehumeral borders oblique to midline, humeri prom-
inent but slightly rounded, setose and feebly serrulate; disc deplanate in
scutellar region, with longitudinal rows of rather sparse pubescence;
inner 4 striae feebly impressed, outer striae obsolescent, intervals subcon-
vex; apical recurrent groove elongate and bisinuate, joining 3rd stria at
level of 7th umbilicate puncture. Appendages all unusually slender and
elongate; antenna 0.8 times body length; last segment of maxillary palp
1.15 times longer than penultimate segment, Aedeagus 0.60-0.63 mm
long, gently arcuate in left lateral view, apex produced and very slightly
knobbed, transfer apparatus as in P. seclusus.

Type series. — Holotype male (American Museum of Natural His-
tory), Fisher Cave, near the top of Newmans Ridge, between Blackwater
and Kyles Ford, Lee Co., Virginia (Kyles Ford IVi Quadrangle, 36^37'22"
X 83^03'40", elev. 480 m), 15 August 1969, J. R. Holsinger; 5 paratypes,
same cave, 17 July 1979, T. C. Barr, Jr., T. C. Barr, III, and J. R.
Holsinger; 13 paratypes, same cave, 30 September 1979, T. C. Barr, Jr.

Measurements (mm). — Holotype, total length 4.78, head 1.13 long X
0.76 wide, pronotum 0.86 long X 0.95 wide, elytra 2.66 long X 1.59
wide, antenna 3.76, aedeagus 0.62.

80

Thomas C. Barr, Jr.

Discussion. — This remarkable species is unusually slender and elon-
gate, almost aphaenopsian in form. The frontal grooves are nearly obso-
lete at the sides of the head, the pronotum is small and convex, and the
elytra are convex with marked deplanation around the scutellum. At 6.2
mm, two members of the type series are the largest cave carabids known
from the Appalachian valley. The species was found under rocks and
rotting wood on crumbly soil, walking across a wet, sloping rock surface,
and under large flat stones near the bottom of the long talus slope extend-
ing down from the entrance, where it coexists with P. deceptivus (engel-
hardti group). In addition to the type locality cave (description in Holsin-
ger 1975:133), P. longiceps is also known from Panther Creek Cave,
Hancock County, Tennessee (description in Barr 1961:255), where J. R.
Holsinger collected six specimens on 20 November 1979. Both caves are
in Newman limestone high on Newmans Ridge, and both are damp with
no permanent stream.

Pseudanophthalmus thomasi, new species

Figs. 45, 53

Etymology . — Patronymic honoring Thomas C. Barr, III, who col-
lected the only two males known of this rare and unusual species.

Diagnosis. — Resembling P. longiceps in trilobed labrum margin, gen-
eral form, and aedeagal structure, differing in less slender head, larger
hind angles, and obsolescent elytral striae.

Description. — Length 4. 7-5. 2 mm (N = 4). Form elongate, slender,
subconvex, appendages elongate; color pale rufotestaceous, dull shining,
microsculpture of elytral disc very fine, transverse, obsolescent. Head 1.3
times longer than wide and nearly as wide as pronotum; labrum with
distinct, broad, median lobe in anterior margin; last segment of maxillary
palp 1.2 times longer than penultimate segment. Pronotum cordiform,
convex, as long as wide, greatest width in apical third, width at apex a
little more than base width and about 0.8 maximum width; sides deeply
sinuate in basal sixth, then subparallel or slightly divergent to prominent,
sharp, reflexed, slightly acute to right hind angles; base oblique or emar-
ginate behind angles, secondary angles of base conspicuous but rather
broadly rounded; anterior marginal setae at apical ninth, well forward of
maximum width, posterior marginals placed well forward of hind angles;
disc glabrous except for 4 long setae each side. Elytra subconvex,
elongate-oval, 1.8 times longer than wide; prehumeral borders oblique to
midline, humeri somewhat rounded, antapical sinuation very shallow;
apical recurrent groove elongate, deep, bisinuate, running into apex of
5th stria well in advance of anterior apical puncture; disc with rather

Appalachian Pseudanophthalmus

81

Figs. 44-47: Pseudanophthalmus sp^.Jonesi and alabamae groups. 44) P. longi-
ceps, n.sp. 45) P. thomasi, n.sp. 46) P. cordicollis, n.sp. Al)P. georgiae, n.sp.

82

Thomas C. Barr, Jr.

short and moderately dense pubescence. Aedeagus of holotype 0.74 mm
long, basal bulb not sharply set off from evenly arcuate median lobe,
which is gradually attenuate and rounded at apex.

Type series. — Holotype male (American Museum of Natural History)
and one male paratype, Blair-Collins Cave, Scott Co., Virginia (Gate
City 71/2' Quadrangle, 36''40'27" x 82°33"27", elevation 490 m), 17 July
1979, T. C. Barr, HI; one female paratype, same cave, 6 November 1966,
J. R. Holsinger; one female paratype from nearby Coley Cave No. 2,
Scott County, Virginia, 3 June 1967, J. R. Holsinger.

Measurements (mm). — Holotype, total length 4.97, head 1.04 long X
0.80 wide, pronotum 0.86 long X 0.86 wide, elytra 2.75 long X 1.53
wide, antenna 3.34, aedeagus 0.74.

Discussion. — This species is known only from the Blair-Collins Cave
system and from Coley Cave No. 2, which are developed in the Maryville
limestone (Ordovician) along Moccasin Creek near Gate City, Scott
County, Virginia (Holsinger 1975:267, 275). All four specimens in the
type series were taken on mud banks in stream passages. The two males
were collected in the lower stream passage of Blair-Collins Cave by
Thomas C. Barr, III, at age 12 already an accomplished and indefatigable
cave trechine collector, who reported that one of the beetles was observed
seizing a predatory mite just before it was caught.

Pseudanophthalmus cordicollis, new species

Figs. 46, 54

Etymology . — Latin cor, “heart”, + collum, “neck.”

Diagnosis. — A large, elongate species with slender appendages, elon-
gate head, small pronotum with convergent sides and obtuse hind angles,
obsolescent elytral striae, and aedeagal apex simply attenuate.

Description. — Length 4. 7-5.0, mean 4.8 mm (N = 4). Form slender
and elongate, subconvex, appendages elongate and slender; pale rufotes-
taceous, pubescent; elytral microsculpture finely transverse, shining.
Head 1. 1-1.3 times longer than wide, mandibles unusually large, long and
slender; labrum with prominent median lobe; maxillary palps with last
segment about 0.4 longer than penultimate segment; antenna 0.6 body
length. Pronotum cordiform, 0.9 as long as wide, widest in apical fifth;
apex subtruncate, anterior angles rounded, sides convergent without
sinuation, hind angles obtuse, secondary angles of base very small and
rounded; disc with 3 long setae each side, otherwise subglabrous. Elytra
subparallel, subconvex, 1.6 times longer than wide, widest at middle;
prehumeral borders slightly oblique, humeri rather prominent but not
angular, apexes attenuate; longitudinal striae feeble and irregular, inter-
vals very flat (feebly subconvex in 1 of 4 specimens), with 2 or 3 rows of
long pubescence per interval; apical groove elongate, subparallel, faintly

Appalachian Pseudanophthalmus

83

to strongly bisinuate, running directly into 3rd stria, no crosier; all fixed
setae hypertrophied, unusually long. Aedeagus of holotype 0.61 mm
long, moderately arcuate, apex finely and simply attenuate.

Type series. — Holotype male (American Museum of Natural History)
and 3 female paratypes. Little Kennedy Cave, Wise Co., Virginia (Appa-
lachia IVi' Quadrangle, 36°53'24' x 82''45'01'), 26 November 1970, J. R.
Holsinger, Roger Baroody, and R. M. Norton.

Measurements (mm). — Holotype, total length 4.88, head 0.88 long X
0.78 wide, pronotum 0.84 long X 0.90 wide, elytra 2.49 long X 1.57 wide,
antenna 3.00, aedeagus 0.61.

Discussion. — Together with P. longiceps and P. thomasi this species
forms a trio of rather large, unusually attenuate species with long append-
ages. Little Kennedy Cave, near the edge of the Allegheny front in
Newman limestone (Mississippian), was described by Holsinger (1975:
402). The cave is about 40 km north of the type locality of P. thomasi (to
which P. cordicollis is most closely similar) and 65 km northeast of the
type locality of P. longiceps.

hypolithos group (new group)

Aedeagus with apex long and slender, not arrow-shaped in dorsal view,
bluntly rounded or slightly falciform at tip. Size small (3. 7-4. 3 mm, most
species means about 4 mm), form moderately slender and depressed;
pronotum transverse-cordiform, sides shallowly sinuate before hind
angles, disc without long setae. Type species: P. hypolithos, new species.

Distribution. — Pike, Harlan, Bell, and Whitley cos., KY (Pine Moun-
tain); Scott Co., VA.

Discussion. — Four of the small species of this group occupy different
caves in Pine Mountain, Kentucky, a large fault block in which the
Newman (Mississippian) limestone is exposed on the northwest face. The
fifth species {P. praetermissus) occurs in a cave in Hunter Valley, Scott
County, Virginia, near the base of the Allegheny front but in the edge of
the Appalachian valley.

Pseudanophthalmus hypolithos, new species

Figs. 28, 34

Etymology. — Greek hypo-, “under,” + lithos, “rock.”

Diagnosis. — Distinguished from other members of the group by the
rather deep and complete elytral striation, convex intervals, reduced
pubescence, and falciform aedeagal apex.

Description. — Length 3.9-4. 3, mean 4.0 mm (N = 4). Form elongate,
rather slender, depressed; rufotestaceous, shining, head and pronotum
subglabrous, elytra with short and sparse pubescence, limited to 1 or 2

84

Thomas C. Barr, Jr.

rows per interval; elytral microsculpture transverse-obsolescent, forming
meshes. Head rounded, as long as wide; labrum singly emarginate; last
segment of maxillary palp about 0.2 longer than penultimate segment;
antenna rather short, 0.6 body length. Pronotum transverse-cordiform,
0.8 as long as wide, width at base and apex subequal and 0.75 greatest
width, which occurs in apical fourth behind anterior marginal setae;
anterior angles prominent, sides shallowly sinuate, subparallel or conver-
gent in basal fifth, hind angles large and sharp, right or slightly obtuse;
secondary angles of base prominent but rounded. Elytra elongate-oval,
1.8 times longer than wide, subconvex; prehumeral borders a little
oblique, humeri prominent but slightly rounded, apexes bluntly rounded;
short scutellar stria present, longitudinal striae deep, inner 3-4 complete
with clear traces of 5,6,7, and 8, intervals convex, apical groove elongate,
bisinuate, running to 3rd stria without crosier at level of 7th umbilicate
puncture. Aedeagus of paratype 0.55 mm long, moderately arcuate, apex
slender and produced, slightly falciform; parameres with 4-5 apical setae.

Type series. — Holotype male (American Museum of Natural His-
tory), 1 male and 2 female paratypes. Old Quarry Cave, 1.8 km SSE
Ashcamp, Pike Co., Kentucky (Hellier IVi Quadrangle, 37^15'09" X
82°25'29''), 2 August 1979, T. C. Barr,

Measurements (mm). — Holotype, total length 3.92, head 0.72 long X
0.70 wide, pronotum 0.69 long X 0.84 wide, elytra 2.23 long X 1.22 wide,
antenna 2.42.

Discussion. — This species, near the northeast end of Pine Mountain,
is immediately differentiated by the unusually deep elytral striation and
reduced pubescence. Old Quarry Cave is situated 100 m east of an old,
abandoned limestone quarry at an elevation of 620 m. The beetles were
taken from under rocks at the back of the entrance room and in the lower
of two subparallel crawlways, all within 20-60 m of the entrance. Abun-
dant cave rat debris was present.

Pseudanophthalmus hypolithos and the next three species are re-
stricted to caves in Pine Mountain, a huge fault block 125 km long,
extending from Elk Gap, Campbell County, Tennessee, to Breaks Inter-
state Park near Elkhorn City, Kentucky. The Newman limestone (Missis-
sippian) crops out on the northwest face of Pine Mountain, dipping to
the southeast at about 25-35°. Caves of Pine Mountain are of the Appala-
chian pattern, with major passages along the strike and passages connect-
ing different levels along the dip.

Pseudanophthalmus scholasticus, new species

Figs. 29, 35

Etymology. — Latin scholasticus, “scholastic.”

Appalachian Pseudanophthalmus

85

Diagnosis. — Differs from other species of the group in the attenuate
elytral apexes, deflexed aedeagal apex, and somewhat more robust form.

Description. — Length 3.9 mm (in 2 specimens of the type series).
Form as in P. hypolithos but more robust; pubescence moderate on
genae and pronotum disc, dense on elytra, longer than in P. hypolithos,
2-3 rows per interval. Head rounded; labrum singly emarginate; last seg-
ment of maxillary palp 0.3 longer than penultimate segment; antenna 0.6
body length. Pronotum 0.8 as long as wide, apex and base widths sub-
equal and about 0.7 greatest width, which occurs in apical fourth; sides
conspicuously sinuate and subparallel in basal fifth, anterior angles
prominent, hind angles large, sharp, slightly obtuse, secondary angles of
base low, broad, rounded. Elytra elongate-oval, prehumeral borders a
little oblique, humeri prominent though somewhat rounded, apexes
attenuate; no separate scutellar stria, longitudinal striae finely impressed,
intervals weakly subconvex, inner 4 striae present, outer striae obsolete;
apical groove elongate and bisinuate, running to 3rd stria via short cro-
sier. Aedeagus of holotype 0.55 mm long, apex produced, slender, and
conspicuously deflexed, finely and bluntly rounded at tip.

Type series. — Holotype male (American Museum of Natural History)
and one female paratype. Sawmill Hollow Cave, 2 km NNW Nolansburg
and 600 m ESE Pine Mountain Settlement School on the northwest side
of Pine Mountain, Harlan Co., Kentucky (Nolansburg IVi Quadrangle,
36°56'50" X 83°I0'31"), 23 August 1979, T. C. Barr, Jr., and T. C. Barr,
III.

Measurements (mm). — Holotype, total length 3.95, head 0.69 long X
0.70 wide, pronotum 0.73 long X 0.87 wide, elytra 2.33 long X 1.29 wide,
antenna 2.25, aedeagus 0.55.

Discussion. — This species coexists with P. rogersae (jonesi group) in
Sawmill Hollow Cave, the only known case of sympatry in Pine Moun-
tain caves. While P. scholasticus occurs in the upper level near the
entrance, P. rogersae was collected in the lower level beside a small
stream. A similar microhabitat segregation was observed in the same cave
between a troglophilic (upper level) and a troglobitic species of Pseudo-
tremia millipeds. The elytral apexes in P. scholasticus are more attenuate
than in the other species of the group, and the deflexed aedeagal apex is
also diagnostic.

Pseudanophthalmus calcar eus, new species

Figs. 31, 37

Etymology. — Latin calcareus, “pertaining to limestone.”

Diagnosis. — Distinguished from other group species by the elongate
head, narrower pronotum, and wider elytra with rounded apexes and

86

Thomas C. Barr, Jr.

only 2-3 clearly impressed inner striae; apical recurrent groove ending
blindly, not connected to 3rd stria.

Description. — Length 4.0-4. 1 mm (N = 3). Form about as in
hypolithos but head and pronotum narrower and elytra wider, pubes-
cence rather dense. Head 1.15-1.25 longer than wide; labrum with sug-
gested very low and wide median lobe; last segment of maxillary palp 0.3
longer than penultimate segment; antenna 0.6 body length. Pronotum
0.85-0.87 as long as wide, anterior angles somewhat rounded, hind angles
acute (2 of 3 specimens) or obtuse (1 specimen), large and sharp, basal
angles as in P. hypolithos', apex width slightly more than base width and
0.75 greatest width, which occurs in apical fifth at level of anterior margi-
nal setae; disc irregularly with 1 long seta each side. Elytra short, 1.6
times longer than wide, elongate-oval, prehumeral borders oblique,
humeri slightly rounded, apexes much rounded; inner 2 striae more
deeply impressed than 3rd stria, but all very fine, intervals essentially flat,
outer striae obsolete; apical groove elongate, bisinuate, ending blindly at
level of 7th umbilicate puncture. Aedeagus 0.63 mm long in paratype,
median lobe less arcuate, apex produced, slightly sinuate in lateral view,
narrowly and bluntly rounded at tip.

Type series. — Holotype male (American Museum of Natural History)
and two male paratypes. Limestone Cave, on the northwest slope of Pine
Mountain, 2.5 km NNW of the common corner of Whitley Co., Ken-
tucky, and Campbell and Claiborne cos., Tennessee, in Whitley Co.,
Kentucky (Jellico East IVi Quadrangle, 36‘^36'38" X 84°01'10", elev. 420
m), 8 August 1979, T. C. Barr, Jr.

Measurements (mm). — Holotype, total length 3.95, head 0.81 long X
0.73 wide, pronotum 0.72 long X 0.84 wide, elytra 2.14 long X 1.32 wide,
antenna 2.57.

Discussion. — Pseudanophthalmus calcareus is readily distinguished
by the slender head and pronotum and relatively short, broad elytra
which are widest just behind the middle; the widest part of the pronotum
is at the level of the anterior marginal setae. The three specimens of the
type series were collected in the entrance room of Limestone Cave under

rocks on damp silt in areas rich in organic debris (cave rat nest debris,
rotting wood, etc.). This seems to be a pattern for species of this group
— close to food sources near entrances, at least in summer. J. R. Hol-
singer and I carefully searched the entire cave in November 1979, finding
no beetles; apparently cold, dry air moving into the cave from the exte-
rior rendered accessible microhabitats in the entrance room unsuitable.

Pseudanophthalmus frigidus, new species

Figs. 30, 36

Etymology . — Latin frigidus, “cold.”

Appalachian Pseudanophthalmus

87

Diagnosis. — Resembles P. calcareus in rounded elytral apexes and
flat intervals, differing in wider head and pronotum, greatest width of
elytra near middle, and aedeagal apex not as slender nor as greatly
produced.

Description. — Length 3. 7-4.3 mm(N = 2). Head rounded, only slightly
longer than wide; labrum singly emarginate; last two segments of
maxillary palp subequal; antenna two-thirds body length. Pronotum
about as in P. scholasticus, 0.8 as long as wide, widths at apex and base
subequal and about 0.75 greatest width, which occurs in apical fourth
behind anterior marginal setae; sides subparallel in basal fifth, anterior
angles prominent, hind angles sharp and about right, basal angles small
and rounded. Elytra 1.65 times longer than wide, apexes rounded,
prehumeral borders a little oblique, humeri slightly rounded, greatest
width near middle; scutellar stria present; striae 1-3 finely and regularly
impressed, intervals flat, outer striae obsolescent, apical groove elongate,
bisinuate, oblique, running to 3rd stria via anterior crosier at level of 7th
umbilicate puncture. Aedeagus 0.64 in holotype, compared with P.
calcareus basal bulb more sharply deflexed and apex less slender and less
produced; parameres shorter, with 3 apical setae.

Type series. — Holotype male (American Museum of Natural History),
Icebox Cave, 25 m above L & N railroad tracks on north side of
Cumberland River in the town of Pineville, 1.0 km SE of the courthouse.
Bell Co., Kentucky, 26 October 1963, S. B. Peck. One female paratype,
same cave, 22 August 1979, T. C. Barr, Jr. and T. C. Barr, HI.

Measurements (mm). — Holotype, total length 4.34, head 0.86 long X
0.80 wide, pronotum 0.80 long X 0.98 wide, elytra 2.48 long X 1.50 wide,
antenna 2.91, aedeagus 0.64.

Discussion. — The type locality is a small but very well known cave; a
small entrance leads into an antechamber from which a low, rocky
crawlway extends 8 m to a muddy strike gallery 75 m long. The
holotype was found at the edge of a temporary pool (S. B. Peck, pers.
comm.) and the paratype under a rock among wet stalactities.

Pseudanophthalmus praetermissus, new species

Fig. 38

Etymology. — Ediim praetermissus, “overlooked.”

Diagnosis. — A robust species closest to P. scholasticus, differing in
more rounded elytral apexes, presence of a short scutellar stria, no crosier
connecting apical groove to 3rd stria; size slightly larger; aedeagus similar
with deflexed apex, but a little larger.

Description. — Length 4.0-4. 3, mean 4.1 mm (N = 4). Form moder-
ately robust and depressed; rufotestaceous, dorsum of head and prono-

88

Thomas C. Barr, Jr.

turn subglabrous, elytral disc densely pubescent; elytral microsculpture
rather coarse, vaguely transverse, no meshes, dull-shining. Head as long
as wide; labrum singly emarginate; last segment of maxillary palp elon-
gate, 1.5 times as long as penultimate segment; antenna 0.6 body length.
Pronotum transverse-cordiform, 0.8 as long as wide, apex and base sub-
equal and 0.7 greatest width, which occurs in apical fifth; anterior angles
prominent, sides subparallel to slightly divergent in basal sixth, hind
angles slightly produced, acute, secondary basal angles effaced. Elytra
elongate-oval, 1.6 times longer than wide, prehumeral borders slightly
oblique, humeri somewhat rounded, disc depressed and heavily pubes-
cent; short scutellar stria present, striae 1 and 2 very shallow though
regular, intervals nearly flat, striae 3-5 shallower; apical groove elongate,
a little oblique, bisinuate, connected medially to 3rd stria but without
crosier. Aedeagus 0.61-0.63 mm, broadly arcuate, apex slender, pro-
duced, deflexed, finely and bluntly rounded at tip.

Type series. — Holotype male (American Museum of Natural History)
and one paratype male, Kern’s Cave No. 1, Scott Co., Virginia (East
Stone Gap IVi Quadrangle, 36°47'20" X 82°39''33"), 26 July 1969, J. R.
Holsinger and James Beck. Two male paratypes, same cave, J. R. Hol-
singer, 6 October 1979.

Measurements (mm). — Holotype, total length 3.98, head 0.92 long X

O. 92 wide, pronotum 0.94 long X 1. 14 wide, elytra 2. 17 long X 1.35 wide,
antenna 2.54.

Discussion. — This is the only species of the hypolithos group known
outside Pine Mountain, Kentucky, but it inhabits a cave near the base of
the Allegheny front. On each of two visits to Kern’s Cave No. 1, J. R.
Holsinger collected three beetles: one P. seclusus (jonesi group) and two

P. praetermissus. Externally the two species are closely similar and in the
same general size range (4.0-4. 3 mm for P. praetermissus and 4. 2-5.0 mm
for P. seclusus). The aedeagi are quite different and highly diagnostic; in
addition, the labrum in P. seclusus bears a low but distinct median lobe,
there are usually two or three long setae on each side of the pronotal disc,
and the elytra are slightly longer and more subparallel.

alabamae group

Aedeagus with apex slender, produced, distinctly and briefly deflexed
at tip, apex not arrow-shaped in dorsal view. Medium-sized species, 4.0-
4.8 mm, mean lengths 4.4 and 4.5 mm, respectively for the two known
species. Pronotum a little transverse and strongly cordiform; apical recur-
rent groove highly diagnostic: subparallel to suture (not bisinuate), ante-
rior end directed toward apexes of 4th and 5th striae, sometimes joining
(no crosier), sometimes ending blindly. Type species: P. alabamae
Valentine.

Appalachian Pseudanophthalmus 89

Distribution. — Dekalb Co., AL; Chattooga and Walker cos., GA.

Pseudanophthalmus alabamae Valentine
Valentine 1932:273. Barr 1965:67.

This distinctive species is known from eight caves in Little Wills Valley,
Dekalb County, Alabama, all on the east side of the Wills anticline:
Bartlett (AL 251, T9S/ R7E/ S13); Cherokee (AL 806, T6S/R9E/S26);
Kelly Girls (AL 252, T9S/R7E/S13); Lykes (AL 239, T9S/R8E/S13);
Manitou (type locality, - AL 13), in Fort Payne: Talley (AL 443,
T5S/R10E/S32); Stanley-Carden (AL 730, T6S/ R9E/S13); and Section
26 (AL 804, T4S/ RlOE/ S26). I have examined 54 specimens including 16
topotypes; the length of this series is 4.0-4.8, mean 4.4 ± SD 0.4 mm. In
P. alabamae the humeri are less sharply angular and the tip of the
deflexed aedeagal apex is falciform rather than knobbed as in the only
other known species of the group, described below. Aedeagi of four
topotypes measured 0.57-0.63, mean 0.60 mm long. Some individuals
have 1 or 2 long setae on each side of the pronotum disc.

Figs. 48-54: Aedeagi of Pseudanophthalmus spp., jonesi group. 48) P. jonesi
Valentine 49) P. scutilus, n.sp. 50) P. seclusus, n.sp. 51) P. pallidus, n.sp. 52) P.
longiceps, n.sp. 53) P. thomasi, n.sp. 54) P. cordicollis, n.sp.

90

Thomas C. Barr, Jr.

Pseudanophthalmus georgiae^ new species

Figs. 39, 47

Etymology. — Geographic name.

Diagnosis. — Resembles P. alabamae in the short, subparallel apical
groove and slender, attenuate, deflexed aedeagal apex; differs in the more
angular humeri and more slender, less arcuate aedeagus with finely
knobbed apex.

Description. — Length 4. 1-4.8, mean 4.5 ± SD 0.1 mm (N = 13). Form
slender and moderately elongate, subconvex, pubescent, rufotestaceous;
elytral microsculpture transverse, not forming meshes. Head a little
longer than wide; labrum with broad, prominent, median lobe; mandibles
unusually long and slender, terebral teeth large and very conspicuous;
last segment of maxillary palp one-third longer than penultimate seg-
ment; antenna two-thirds body length. Pronotum transverse, strongly
cordiform, 0.85-0.89 as long as wide, convex, disc glabrous (very sparse
micropubescence only), a few individuals with 1-3 discal setae; width at
base slightly greater or equal to width at apex and about 0.8 greatest
width, which occurs in apical fourth behind level of anterior marginal
setae; anterior angles moderate, sides arcuate, very shallowly (or not)
sinuate at basal fifth, hind angles sharp, usually a little less than right,
secondary basal angles small but conspicuous. Elytra elongate-oval, 1.6
times longer than wide, prehumeral borders slightly oblique, humeri
prominent and angular, apexes attenuate, disc moderately convex with
slight deplanation around scutellum; striae fairly deep, intervals convex,
inner 3 striae deeper but striae 4-7 still discernible; apical groove subpar-
allel to suture, hardly bisinuate at all, joining or directed toward juncture
of 4th and 5th striae at level of anterior apical puncture without anterior
crosier. Aedeagus 0.60-0.65 mm long, less arcuate than that of P. alaba-
mae, angle between basal bulb and median lobe greater, apex more
slender, slightly knobbed or finely truncate and deflexed; 5-6 setae at
apexes of paramers.

Type series. — Holotype male (American Museum of Natural His-
tory), 1 male and 8 female paratypes, Blowing Spring Cave, 4 km NE
Cloudland and 1.6 km NW Chelsea at the east base of Lookout Moun-
tain, Chattooga Co., Georgia (Dougherty Gap IVi Quadrangle), 21 June
1967, S. B. Peek and A. Fiske.

Measurements (mm). — Holotype, total length 4.59, head 0.83 long X
0.77 wide, pronotum 0.80 long X 0.92 wide, elytra 2.45 long X 1.53 wide,
antenna 3.00, aedeagus 0.63.

Discussion. — This species obviously shares a relatively recent common
ancestry with P. alabamae, which occurs in several caves on the east side
of the Wills anticline in Little Wills Valley, Alabama. The subparallel

Appalachian Pseudanophthalmus

91

apical groove, occasional 1-3 long setae on each side of the pronotal disc,
and slender, nonconstricted aedeagal apex suggest a more remote rela-
tionship to the Grassy Cove and Pine Mountain species of the jonesi
group (P. jonesi, P. scutilus, P. rogersae). The known range of P. geor-
giae includes three Georgia caves: Blowing Spring Cave, the type local-
ity; Pettijohn Cave, 8 km southwest of Lafayette and 2.3 km northwest
Bronco and a similar distance south-southeast of Atwood Point on
Pigeon Mountain ( an east spur of Lookout Mountain) (Estelle IVi
Quadrangle); and Mt. Cove Farm Cave, 2.5 km east of Lookout near the
head of McLemore Cove, 0.9 km north-northwest of Dougherty Gap
(Dougherty Gap IVi Quadrangle). The latter two caves are in Walker
County.

Other Appalachian Valley Species Groups

Although northern Appalachian Pseudanophthalmus species will be
treated in detail in a subsequent paper, availability of much fresh material
has substantially altered my views on the relationships between the
approximately 35 known species in the region. Five rather well defined
species groups exist, and the distributions of four of them are in accord
with an Allegheny refugium hypothesis. With respect to my earlier paper
(Barr 1965) on Appalachian valley Pseudanophthalmus, the following
classificatory changes are now indicated. Subspecies citations have been
omitted, but some of the Greenbrier valley species of the grandis group
are polytypic.

grandis group

grandis Valentine 1931:254 (WV)
fuscus Valentine 1931:254 (WV)
sylvaticus Barr 1967b: 167 (WV)
montanus Barr 1965:52 (WV)
krekeleri Barr 1965:52 (WV)
hypertrichosis Valentine 1932:266 (WV)

virginicus (Barr 1960:66 (NEW COMBINATION for Aphanotrechus

virginicus Barr)

Collection of a male of P. virginicus by J. R. Holsinger and R. M.
Norton made possible the determination that virginicus is only an aber-
rant species of iht grandis group near P. hypertrichosis. It is known only
from Hugh Young Cave, in the Maiden Spring area, Tazewell County,
Virginia.

hubbardi group

Same as hubbardi group of Valentine (1945) and Jeannel (1949); equiv-
alent to hubbardi subgroup of Barr (1965).

92

Thomas C. Barr, Jr.
pusio group

Same as pusio group of Valentine (1932), Jeannel (1949), and Barr
(1965), readily identified by the elongate, cylindrical median lobe of the
aedeagus. I differ with Jeannel (1949) in including P. higginbothami
Valentine (WV) in the pusio group and placing P. fuscus in the grandis
group.

gracilis group (new group)

Small species in which the males have an apical emargination in the
last abdominal sternite; aedeagus long and slender, copulatory pieces
subequal and rather short. The group is closely related to the inexpecta-
tus group of central Kentucky (Krekeler 1973).

gracilis Valentine 1931:253 (VA)
hadenoecus Barr 1965:53 (WV)

petrunkevitchi group (new group)

Small species with a distinct, circular eye rudiment (as opposed to
irregular, lunate scars in P. vicarius and some species of the grandis
group); aedeagal apex slender and produced, transfer apparatus of two
elongate pieces fused into a cylinder at the base of the internal sac.

petrunkevitchi Valentine 1945:652 (VA)
hoffmani Barr 1965:58 (VA)
hortulanus Barr 1965:60 (VA)

Four of these species groups {grandis, hubbardi, pusio, gracilis) have
species in karst islands in the eastern part of the Allegheny Plateau as well
as in the Appalachian valley proper. These distributions are consonant
with the hypothesis that they are relics of ancient lineages which were
edaphobitic in a Pleistocene (or earlier?) refugium within the Allegheny
Plateau. In the grandis group, P. sylvaticus remains an edaphobite living
in the forest floor of mountains above the Greenbrier valley caves where
P. fuscus, its closest known relative, occurs.

The petrunkevitchi group includes species at the eastern edge of the
Appalachian valley and no species are known from the Allegheny karst
islands. Although this group could have dispersed eastward from an
Allegheny source, a Blue Ridge refugium is equally likely, or perhaps
more likely in view of distribution of its known component species.

ACKNOWLEDGMENTS. — Many persons have contributed spec-
imens, given advice, or assisted me in the field over the years, and this
paper would not have been possible without their help. I single out for

Appalachian Pseudanophthalmus 93

special thanks T. C. Barr, III, J. E. Cooper, J. R. Holsinger, the late W.
B. Jones, C. H. Krekeler, J. A. Payne, S. B. Peck, R. M. Norton, W. W.
Torode, J. M. Valentine, and R. L. Wallace. Some of the beetles de-
scribed in this paper were collected with the assistance of grants from the
National Science Foundation (G-18765 and GB-5521) and the Kentucky
Nature Preserves Commission.

LITERATURE CITED

Barber, Henry S. 1928. Two new cave beetles related to Anophthalmus pusio
Horn. J. Wash. Acad. Sci. 75:195-196.

Barr, Thomas C., Jr. 1960. A new genus of cave beetle (CarabidaeiTrechini) from
southwestern Virginia, with a key to the genera of Trechini of North America
north of Mexico. Coleopt. Bull. 74:65-70.

1961. Caves of Tennessee. Tenn. Div. Geol. Bull. 64, Nashville. 567 pp.

1965. The Pseudanophthalmus of the Appalachian valley (Coleoptera:

Carabidae). Am. Midi. Nat. 75:41-72.

1967a. Observations on the ecology of caves. Am. Nat. 707:475-492.

1967b. A new Pseudanophthalmus from an epigean environment in West

Virginia (Coleoptera:Carabidae). Psyche 74:166-174.

1969. Evolution of the Carabidae (Coleoptera) in the southern Appala-
chians. pp. 67-92 in P. C. Holt (ed.). The distributional history of the biota of
the southern Appalachians, Part I: Invertebrates. Res. Div. Monogr. 1, Va.
Polytech. Inst., Blacksburg. 295 pp.

1972. Trechoblemus in North America, with a key to North American

genera of Trechinae (Coleoptera:Carabidae). Psyche 75:140-149.

1979a. Revision of Appalachian Trechus (Coleoptera:Carabidae). Brim-

leyana. 2:29-75.

1979b. The taxonomy, distribution, and affinities of Neaphaenops, with

notes on associated species of Pseudanophthalmus (Coleoptera:Carabidae).
Am. Mus. Novit. No. 2861:1-20.

Douglas, Henry H. 1964. Caves of Virginia. Va. Cave Survey, Falls Church.
761 pp.

Holsinger, John R. 1975. Descriptions of Virginia Caves. Va. Div. Mineral
Resour. Bull. 85. 450 pp.

Horn, George H. 1868. Catalogue of Coleoptera from south-west Virginia. Trans.
Am. Entomol. Soc. 2:123-128.

Jeannel, Rene. 1949. Les coleopteres cavernicoles de la region des Appalaches.
Etude systematique. Notes Biospeol. 4 (Publ. Mus. Nat. Hist. Nat., Paris, no.
12):37-104.

Krekeler, Carl H. 1973. Cave beetles of the genus Pseudanophthalmus (Coleop-
tera:Carabidae) from the Kentucky Bluegrass and vicinity. Fieldiana (Zool.)
(52:35-83.

Matthews, Larry E. 1971. Descriptions of Tennessee caves. Tenn. Div. Geol. Bull.
69. Nashville. 150 pp.

94

Thomas C. Barr, Jr.

Valentine, J. Manson.1931. New cavernicole Carabidae of the subfamily Trechinae
Jeannel. J. Elisha Mitchell Sci. Soc. 4(5:247-258.

1932. A classification of the genus Pseudanophthalmus Jeannel (fam.

Carabidae) with descriptions of new species and notes on distribution. J. Elisha
Mitchell Sci. Soc. 4<^:261-280.

1937. Anophthalmid beetles (fam. Carabidae) from Tennessee caves. J.

Elisha Mitchell Sci. Soc. 53:93-100.

1945. Speciation and raciation in Pseudanophthalmus (cavernicolous

Carabidae) Trans. Conn. Acad. Arts Sci. 3(5:631-672

1948. New anophthalmid beetles from the Appalachian region. Geol.

Surv. Ala. Mus. Pap. 27:1-20.

1952. New genera of anophthalmid beetles from Cumberland caves (Cara-
bidae, Trechinae). Geol. Surv. Ala. Mus. Pap. 34:1-41.

Varnedoe, William W., Jr. 1973. Alabama caves and caverns. Alabama Cave
Survey, Huntsville.

Accepted 12 December 1980

Records of Leatherback Turtles, Dermochelys
coriacea (Linnaeus), and Other Marine Turtles in

North Carolina Waters

Davids. Lee and William M. Palmer

North Carolina State Museum of Natural History,

P.O. Box 27647, Raleigh, North Carolina 2761 1

ABSTRACT. — New information is presented on the occurrence of five
species of marine turtles in North Carolina waters. Dermochelys coria-
cea and Caretta carettd, the two most commonly occurring species, are
emphasized. Thirty-three unpublished records of Dermochelys for
North Carolina, and information from other sources, indicate that in
North Carolina at least, this turtle typically occurs throughout the
warmer months in relatively shallow shelf waters. It may not be an
open-ocean wanderer.

Information on seasonal distributions of marine turtles in North Caro-
lina’s offshore waters is fragmentary. Since 1975, one of us (DSL) has
been regularly surveying seabirds in this area (Lee and Booth 1979) and
making incidental observations of marine turtles. These records, com-
bined with others in the files of the North Carolina State Museum of
Natural History (NCSM), contribute considerably to our knowledge of
sea turtle occurrences off the coast of the state. All five species known
from the Atlantic have been encountered.

Nearly all of the 85 offshore trips departed either from Oregon Inlet or
Hatteras Inlet, Dare County, North Carolina. Each daylong outing (ca.
10-1 1 hours) typically followed predesignated transects of 20 to 50 miles
(32 to 80 km) from the point of departure and into the Gulf Stream. Data
accompanying sightings are, unfortunately, not uniform because of (1)
lack of LORAN equipment on some charter boats, (2) abbreviated record
keeping necessitated by conditions at sea, and (3) concentration of pri-
mary field effort on seabirds, which sometimes made it impossible to
record maximum data on turtles. Furthermore, surveys of marine turtles
from boats are difficult, since surface conditions and angle of view nor-
mally provide a narrow corridor of visibility. Variability of surface condi-
tions from one trip to the next makes comparisons of trip-by-trip
numbers observed meaningless. The difference in numbers of turtles seen
from boats and numbers observed in aerial surveys, to be discussed later,
is striking.

Information from NCSM files was compiled from numerous inde-
pendent records accumulated during the past 20 years. Units of meas-
urements used here are, for the most part, expressed as originally
reported to us; few have been converted to metric units.

Brimleyana No. 5:95-106. July 1981.

95

96

David S. Lee and William M. Palmer

Dermochelys coriacea coriacea (Linnaeus). Atlantic Leatherback

Ernst and Gilroy (1979) summarized the 25 known occurrences of
Dermochelys from the central Atlantic states (VA-4 records, MD-4, DE-
3, NJ-14) and concluded that, although these reptiles were generally
believed to make long, open ocean journeys and are rare along the middle
Atlantic coast, many remain close to shore during migrations and are
seasonally common along the central Atlantic states. Lazell (1980) docu-
mented regular occurrences in New England waters. Schwartz (1977)
noted that in North Carolina this species is known from only seven
adults, and juveniles from one presumed nesting at Cape Lookout, Car-
teret County, reported to him in June 1966. There apparently are only
three published records for the species in South Carolina waters (De Sola
and Abrams 1933; Schwartz 1954; Pritchard 1976). Our 33 additional
records (Table 1) seem significant when compared to the total number of
leatherbacks reported from New Jersey south to South Carolina, and
especially when compared to the modest number of loggerheads observed
from boats offshore during the same survey period. Also, many of the 36
previous New Jersey to South Carolina records represent animals found
dead on beaches or possibly unhealthy individuals, and may not reflect
normal seasonal movements for the western North Atlantic Dermochelys
“population.” Therefore, our observations may be of importance in even-
tually understanding such movements.

Four live individuals observed by DSL were floating just below the
surface with only their heads protruding. When breathing, the entire head
was exposed for 5 to 10 seconds. The animals were not as easily fright-
ened as were most of the loggerheads observed, and we were able to keep
the boat within 10 to 15 m of them for several minutes. Even then, turtles
could not be seen until we were extremely close to them. Sightings were
made only on days when the water surface was calm. Consequently, even
on relatively calm days, leatherbacks would be much more difficult to
census from a boat than would loggerheads, which float with part of the
carapace above the surface. Several Oregon Inlet boat captains and mates
insisted that leatherbacks were as common or more common offshore
than loggerheads, but they could be seen only on calm days. Captain
John Booth saw five in one day during the summer of 1976.

At sea, observations and trawler catches of leatherbacks are from the
relatively shallow waters over the continental shelf (>100 fathoms). Even
though most of Lee’s observation time was spent along the edge of the
continental shelf at or near the inner edge of the Gulf Stream, leather-
backs were not seen there. Boat captains confirmed that turtles they saw
were well inshore (10-30 miles) of the edge of the shelf. Atlantic trawler
fishing also takes place in shallow (normally 20 to 30 m) shelf water. The

North Carolina Marine Turtles

97

Fig. 1. Locations of Dermochelys sightings off North Carolina’s Outer Banks,
1976-1980. Dots indicate specific sightings. Dashed line encloses approximately
8+ sightings made from charter boats not equipped with LORAN instrumenta-
tion. X indicates turtles found dead on beach. Contour lines are in fathoms.

South Carolina specimen reported by Schwartz (1954) was trawled from
water 25 to 30 feet deep, as were a significant number of the North
Carolina turtles. In the 1979 aerial surveys of the North Carolina Wildlife
Resources Commission, only two leatherbacks were sighted. During 225
hours of flight time, the spotters seldom ventured more than two to four

98

David S. Lee and William M. Palmer

miles from the beach (see Caretta discussion). We conclude that, with few
exceptions, leatherbacks confine their activities to the shallow waters
over the continental shelf but normally remain well away from the beach,
although long range migrants may travel more direct open-water routes.
LazelPs (1980) records were all from well inside the 183 m contour, but he
considered this to be a result of the distribution of food organisms {Cya-
nea). Pritchard (1976) noted, however, that although his recapture
localities made this species appear to be a coastal form, individuals cap-
tured had ventured atypically close to shore. He also noted that the
integument of the leatherback is so delicate that prolonged or preferred
residence in shallow water is improbable, since even occasional contact
with rocks or coral would likely cause extensive damage to the animals.
Our limited data indicate that Dermochelys, at this latitude, tends to
remain inshore over the continental shelf and not to venture regularly
into water over 500 fathoms deep (see Figure 1 and Table 1). We have,
though, only limited experience past the 1000 fathom contour. Since this
turtle is assumed to be a surface feeder, water depth would appear to be
inconsequential.

In further support of our belief that the leatherback normally frequents
shallow shelf waters rather than those of the open sea, we provide the
following records from Bermuda waters, kindly supplied by David B.
Wingate, Conservation Officer for Bermuda: 14 July 1835 (7 ft. long,
estimated weight 1200 lb.); 8 August 1967 (81/2 ft. long from head to tip of
tail, estimated weight 1 100 lb.; tangled in a fishing net and drifting help-
lessly); 9 December 1972 ( 4 ft. 9 in. from tip of head to tip of tail,
estimated weight 400 lb.; length of carapace 3 ft. V/z in.; width of shell
around curvature at widest point 2 ft. 9 in.; span of forelimbs tip to tip 6
ft.; washed ashore dead on Coopers Point, Bermuda). Wingate noted that
other individuals are occasionally sighted by fishermen, but no dates have
been recorded. In view of the long involvement the citizens of Bermuda
have had with the sea in general and sea turtles in particular, the limited
number of records of Dermochelys from Bermuda indicates that it infre-
quently occurs in open sea areas there.

Additionally, Ralph W. Harvard and Howard E. Inspahr (Sula Pelagic
Expeditions), and Charles D. Duncan, University of Alabama, Bir-
mingham, reported to us records of 14 live and 3 dead leatherbacks in the
Northern Gulf of Mexico (Daulphin Island, Alabama, area). Two of the
three dead individuals were believed by them to have drowned in shrimp
nets. Period of occurrence ranged from May to September (1975-80).
“All sightings were in shallow green water (20-150 ft.) and always near a
tide line. The food seems to be large jellyfish.” David Rupke, Louisiana
State University, reported three individuals from 500 m off Horn Island,
Mississippi, on 23 June 1980. They were in approximately 4 m of water.

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102

David S. Lee and William M. Palmer

and water temperature was 30^ C. This information, combined with the
fact there are few records from Bermuda, further suggests that this
turtle is regularly associated with the shallow shelf waters and not those
of the open sea.

With two exceptions, all North Carolina records are from mid-April
through mid-October, when offshore water temperatures normally range
from ca. 20^ to 27^ C. We assume that an individual caught by a trawler
off Ocracoke Island on 6 January 1976 was healthy, but the occurrence of
one in the Neuse River on 16 November 1975 seems atypical and may
represent a sick or injured animal. Charter boat captains consider this
turtle a summer resident and do not normally encounter it at other times,
even though much of their spring and fall fishing for migratory commercial
fishes occurs in inshore waters.

Three of four leatherbacks encountered by Lee were small (ca. 1.25 m
carapace length), but boat captains insist that larger ones are common.
Available photos of NC trawler-caught specimens show large animals.
Schwartz (1977) provided weights for the seven specimens he listed, but
did not indicate how they were determined. The label with a mounted
1897 specimen at NCSM gives the weight as “800 lb.”, but this is
believed to be an estimate. A weight of “427 lb.” accompanies a news-
paper photo of a leatherback caught by a trawler on 24 May 1955.
Because it is conservative and precise. We assume this figure is not an
estimate. This individual appears to be as large as others in news articles
reported to weigh “1000 lb.”, and perhaps as large as the “800 lb.”
NCSM specimen. A beached animal found on 27 November 1979, which
was struck by the propeller of a ship, measured 203 cm carapace
length and apparently is the largest specimen recorded from the Central
Atlantic, although few accurate measurements are available. Ernst and
Gilroy (1979) provided carapace lengths for 10, and weights or weight
estimates for 12, of the 25 records they summarized. These ranged from
136 to 180 cm and 193+ to 500 kg. A 1952 South Carolina specimen
examined by Schwartz (1954) was 61 in. carapace length and weighed 680
lb.

Lazell (1980) and others have suggested that the “Arctic” jellyfish,
Cyanea capillata, is a major food of this turtle. Although Cyanea occurs
in North Carolina waters, we are not aware that it ever reaches the
concentrations recorded from cooler waters, and have never seen it in the
course of our offshore surveys. Normally it occurs inshore, and there may
be heavy local concentrations in May.

Although the data are fragmentary, it appears that adult and subadult
leatherbacks occur off the North Carolina coast from mid-April to mid-
October and that in summer they may be relatively common offshore
residents. Surprisingly, no peak periods of observed occurrence in spring

North Carolina Marine Turtles

103

or fall indicate extensive migratory movements (Fig. 2). All known North
Carolina records are presented in Table 1, and seasons of occurrence for
all live individuals reported from New Jersey to South Carolina, includ-
ing Bermuda, are provided in Figure 2.

JAN FEB MAR APR MAY JUN JUL SUMMER AUG SEP OCT NOV DEC

Fig. 2. Sightings by month for live Dermochelys recorded from NJ, DE, MD,
VA, NC, SC, and Bermuda (1835-1980). Multiple sources.

Eretmochelys imbricata imbricata (Linnaeus). Atlantic Hawksbill

One adult of this species was sighted ca. 20 miles (32.3 km) east of
Oregon Inlet on 22 June 1977 by Ray E. Ashton, Jr. (NCSM). Only four
previous records were known for North Carolina waters: 3 July 1970, 31
July 1973, and 14 October and 10 November 1975 (Schwartz 1977).
Ashton’s sighting is the earliest known date of occurrence for this area.

Chelonia mydas mydas (Linnaeus). Atlantic Green Turtle

One medium-sized adult was seen sunning on the surface 12 to 18 miles
(19 to 29 km) east-northeast of Oregon Inlet on 25 May 1977. Water
depth was 50 fathoms, and water temperature was 20^ C. Schwartz
(1977) stated that individuals over 13.5 kg (30 lb.) are rare in North

104

David S. Lee and William M. Palmer

Carolina waters, but this one was considerably larger than that. The date
seems early for a tropical or subtropical species to be in this area, particu-
larly since the turtle was not in the warmer (24^ C) waters of the Gulf
Stream.

Lepidochelys kempi (Garman). Atlantic Ridley

On 7 November 1977, an adult male was observed swimming at the
surface, 4 to 5 miles (6.5 to 8 km) south of “the Point” (35^25',74^55').
The animal was close enough that five barnacles could be counted on its
carapace, and their diameters estimated at about 50 mm. Schwartz (1977)
stated that this species once was common at Beaufort, Carteret County,
but in recent years is known only from eight specimens captured between
July 1970 and August 1974 in Core Sound and North River, Carteret
County. Our record is the first known offshore occurrence and the only
fall sighting of this turtle for North Carolina. Surface water temperature
recorded when the turtle was sighted was 19® C. Although this reading is
above the 13.0® C at which Schwartz (1978) reported the species to
exhibit sluggish floating behavior, this individual appeared somewhat
sluggish. However, Lazell (1980) reported that November is a major
activity period in New England, when water temperatures are 7® to 10® C.

Additional North Carolina records not included by Schwartz (1977)
are: NCSM 15116 — dead on beach. Pea Island, Dare County, 20 April
1975; 215 mm carapace length; left front flipper missing and parts of shell
badly scarred. NCSM 16721 — apparently drowned in gill net. Cape Fear
River at Zeke’s Island, 2.25 mi. (3.6 km) southwest of Fort Fisher,
Brunswick County, 2 June 1976; 383 mm carapace length.

Caretta caretta caretta (Linnaeus). Atlantic Loggerhead

In warmer months loggerheads tend to stay within a mile or two of
shore, and they probably also occur throughout North Carolina’s exten-
sive sounds. Although individuals were occasionally encountered far off-
shore, including in the Gulf Stream, most of our June-September sight-
ings were made within a few miles of the beach. Between 1 June 1979 and
1 December 1979, 1440 individuals were sighted from planes by personnel
of the N.C. Wildlife Resources Commission during 225-250 hours of
flight time over the Atlantic between the Virginia and South Carolina
state lines. Some individuals may have been incorrectly identified from
the air, but we have no doubt that the vast majority were Caretta. In this
same area and time period, 324 nests were recorded on North Carolina
beaches (multiple sources). Guy Oliver of Avon, North Carolina, also

North Carolina Marine Turtles

105

censused marine turtles from the air in 1979 and recorded large numbers
of Caretta within a few miles of the North Carolina shore. Although

many of these aerial sightings were certainly duplicative, there obviously
were large numbers of marine turtles in the flight study area at that time.
All were sighted within two to four miles of shore. Furthermore, the area
of major turtle activity did not appear to correlate with main nesting
areas, sc we assume that most of the individuals observed were probably
foraging (or migrating) and not approaching nest beaches. Oliver saw as
many as 46 individuals in a single 1.5-hour period. Most of the animals
were adults, concentrated around inlets and submerged sandbar shelves
approximately two miles offshore. The majority of observations occurred
between 1200 and 1500 hours when individuals were most frequently
basking at the surface.

Fig. 3. Dermochelys photographed at sea (35° 3r,73°56'), 18 April 1980; ca
1.80+ m CL. Photo S. P. Platania.

The few winter offshore trips made by DSL indicated that loggerheads
are not found inshore from late November through early April, but they
were observed in or adjacent to the Gulf Stream in that time: 17 April
1978 (3 turtles), water temperature 19.7° C; 9 November 1979 (1) 23.5° C;
14 November 1978 (2) 17.5° C; 5 December 1978 (1), 16.8° C; 29
December 1977 (2); 30 December 1978 (9), 23° C. Only three of these
turtles were of adult size; the rest had carapace lengths of ca. 45 to 60 cm.
Additionally, one dead subadult was found on 5 December 1978. It thus
appears that the “summering” adults do not simply migrate to the Gulf

106

David S. Lee and William M. Palmer

Stream in colder months. We do not know whether the small individuals
encountered are migrants, waifs, or a wintering “population”. By mid-
April, modest numbers of adult and subadult loggerheads appear in
inshore waters (5 to 30 miles from shore). At these times shelf water
temperature is 15^ to 18^ C. On six April trips, we encountered Caret ta
on only two occasions: 18 April 1980 (2) and 19 April 1980 (10). All were
adult-size turtles, inshore of the Gulf Stream.

Since there are few records of yearling sea turtles, a single ca. 200 mm
CL individual sighted in 45 to 50 fathoms of water on 29 July 1980 off
Oregon Inlet, Dare County, seems noteworthy. It was swimming at the
surface and was not associated with sargassum or other floating debris.

ACKNOWLEDGMENTS. — We thank those persons mentioned in
the text for the information they supplied. Steven P. Platania assisted in
most of the sea trips and prepared Figures 1 and 2, and John E. Cooper
helped on two trips and provided helpful criticisms of the manuscript.
This study was financed in part by U. S. Army Corps of Engineers
(Wilmington District) contract DACW54-80-F-1 177 with NCSM.

LITERATURE CITED

Ernst, Carl H., and M. J. Gilroy. 1979. Are leatherback turtles, Dermochelys
coriacea, common along the middle Atlantic Coast? Bull. Md. Herpetol. Soc.
75(1):16-19.

DeSola, C. Ralph, and F. Abrams. 1933. Testudinata from southeastern Georgia,
including the Okefinokee Swamp. Copeia 1933(1): 10-12.

Lazell, James D., Jr. 1980. New England Waters. Critical habitat for marine
turtles. Copeia 1980(2):290-295.

Lee, David S., and J. Booth, 1979. Seasonal distribution of offshore and pelagic
birds in North Carolina waters. Am. Birds JJ(5):715-721.

, and G. Oliver. 1980. Report on possible impact of Manteo Bay Project

on marine mammals and turtles. On file, U. S. Army Corps of Engineers,
Wilmington (NC) District, DACW54-80-F-1 177. 14 pp. + 5 tables.

Pritchard, Peter C. H. 1976. Post-nesting movements of marine turtles (Cheloni-
idae and Dermochelidae) tagged in the Guianas. Copeia 1976(4):749-754.
Schwartz, Albert. 1954. A record of the Atlantic Leatherback Turtle {Dermo-
chelys c. coriacea) in South Carolina. Herpetologica 10{\)\1.

Schwartz, Frank J. 1977. Cheloniidae. pp. 303-308 in J. E. Cooper, S. S.
Robinson and J. B. Funderburg (Eds.). Endangered and Threatened Plants
and Animals of North Carolina. N. C. State Mus. Nat. Hist., Raleigh, 444 pp.

1978. Behavioral and tolerance responses to cold water temperatures by

three species of sea turtles (Reptilia, Cheloniidae) in North Carolina. Proc. Fla.
Interregional Conf. Sea Turtles, Fla. Mar. Res. Publ. 33:16-18.

Accepted 11 December 1980

Ecological Life History of Ptilostomis postica (Walker)
(Trichoptera: Phryganeidae) in
Greenbottom Swamp, Cabell
County, West Virginia

Mary Beth Roush and Donald C. Tarter
Department of Biological Sciences,

Marshall University, Huntington, West Virginia 25701

ABSTRACT. — The ecological life history of Ptilostomis postica
(Walker) from Greenbottom Swamp, Cabell County, West Virginia was
investigated from December 1977 to December 1978. Length-frequency
histograms indicate the life cycle is univoltine. Larvae achieved their
greatest growth (75%), and case length showed its greatest increase
(70.3%), from fall to winter. There was high correlation between case
length and body length in fall (r = 0.72) and winter (r = 0.87), but low
correlation (r = 0.37) in spring. The diet of the larvae changed from
carnivorous in fall and winter to omnivorous in spring. Pupation began
at the end of April and lasted approximately three weeks. Adult emer-
gence began on 12 May, peaked on 20 May, and lasted two weeks.
Chi-square tests for pupae and adults showed no deviation from a 1:1
sex ratio at the 0.05 level. Adults are nocturnal and live less than one
month.

INTRODUCTION

Several investigators, including Sibley (1926), Fankhauser and Reik
(1935), Wiggins (1960a,b; 1961), Merrill (1969) and Hill et al. (1978),
reported studies on the genus Ptilostomis. The objective of this investiga-
tion was to study the ecological life history of the caddisfly Ptilostomis
postica (Walker) in Greenbottom Swamp, Cabell County, West Virginia.

Ptilostomis postica has been recorded from 14 eastern states, Washing-
ton, D. C. and Quebec (Betten 1934; Ross 1944; O. S. Flint, Jr., pers.
comm.). The authors collected it from Berkeley and Cabell counties.
West Virginia. The larvae have been taken in both lentic and lotic waters,
ranging from cool streams to lakes and temporary vernal pools (Wiggins
1977).

MATERIALS AND METHODS

Greenbottom Swamp lies in the northwestern corner of Cabell County,
West Virginia, 8050 m east of Homestead on State Route 2. The study
area, rectangular in shape, is located 550 m from the Ohio River’s south
edge. The swamp proper is 1450 m long and has a contiguous marsh on
the north end which continues another 2100 m, forming about 14 ha of
swamp forest. The mean water depth varies from 0.5 m during dry peri-
ods to 1.2 m during wettest periods. Elevation of the area is 168 m above
sea level. In the permanently inundated areas, the only tree which

Brimleyana No. 5:107-1 16. July 1981. 107

108

Mary Beth Roush and Donald C. Tarter

remains alive is black willow, Salix nigra Marsh. Button-bush saplings,
Cephalanthus occidentalis L., have the greatest density of any woody
plant seedling in the swamp.

This study was initiated in December 1977 and completed in December
1978. Larval collections were made on a monthly basis during the study
period. However, due to the lack of specimens in certain months, we
decided to select one month as a representative of each season and report
all calculations on a seasonal basis.

Water quality tests were performed at the collection site with a Hach
chemical kit. Model AL-36B, and pH was measured colorimetrically.
Dissolved oxygen, carbonate alkalinity, and total hardness were meas-
ured and recorded in mg/ 1. Water temperature was taken with a Taylor
maximum-minimum thermometer placed 0.3 m below the water surface.

Larvae were collected from mud and leaf debris using a long-handled
dredge with a mesh size of 60 threads/ inch, and preserved in 70 percent
ethanol. Total length of larvae was measured to the nearest 0.5 mm using
a centimeter rule. Size classes were determined by length-frequency his-
tograms arranged in 2 mm length groups. Head width, measured to the
nearest 0.01 mm with an ocular micrometer, was used to assess growth.
Differences in larval head width were used to calculate the mean, range,
standard deviation, and standard error of the mean. Percent growth from
one season to the next was calculated using the mean head width value.
Larval instar designations were determined by using head width
measurements.

Seventy-four larval foreguts were examined to determine food habits.
The head was removed with microdissecting scissors and the abdomen
split dorsally to remove the foregut. Contents of the foregut were
removed for a complete scan with dissecting binocular microscope, then
transferred to a compound microscope for identifications. The entire
slide was quickly scanned for large remains, and a running tally of major
taxa was kept on a composite sheet. The number of foreguts containing
one of these taxa was recorded, the mean determined, and the data
analyzed by percent frequency of occurrence. A grid method was used to
determine the amount of detritus and diatoms. Using a Whipple eyepiece
consisting of 100 grid squares, each foregut was examined in three differ-
ent fields (300 grid squares) and a record made of presence or absence of
detritus or diatoms in each square. A mean was determined for each
foregut and the data were analyzed by percent frequency of occurrence
per 100 squares.

Larval case length measurements were made to the nearest 0.5 mm
with a centimeter rule. The number of rings in each case was recorded
and each ring length measured to the nearest 0.5 mm. Using a dial Vern-
ier caliper, the diameters of the anterior and posterior openings of each

Caddisfly Life History

109

case were measured to the nearest 0.05 mm. The mean, range, standard
deviation, and standard error of the mean were calculated for these
values. The regression analysis of case length on total length of larvae was
calculated and a coefficient of correlation determined.

In order to find the pupal stage, the swamp bottom was scraped for
mud and debris with a long-handled dredge net of mesh size 60 threads/
inch. Submerged logs were examined by pulling away rotting bark and
loose pieces of vegetation to uncover pupal cases embedded in soft wood.
Cases were preserved in 70 percent ethanol. Adults were collected with a
Ward’s ultraviolet light trap (8 watts) and with a fluorescent tube light
placed on a sheet, then preserved in 70 percent ethanol.

RESULTS AND DISCUSSION

Water quality. — The pH ranged from 6.0 in February to 7.7 in March;
x= 6.7. Dissolved oxygen concentration ranged from 2.0 to 12.0 mg/ 1 in
July and January, respectively. Carbonate alkalinity values ranged from
17.1 mg/1 in January and February to 85.5 mg/ 1 in May, June and
September; x = 57.0 mg/l. Total hardness ranged from 51.3 to 205.2
mg/ 1 in February and July, respectively; x = 107 mg/l. Mean annual
temperature for the study period was 9.8° C, with extremes of 0° C from
December through February and 30° C in September.

Larval stage. — Length-frequency histograms indicated that this popu-
lation contained one size class (Fig. 1). The earliest and smallest larvae
were collected in November 1978 (x length = 13.3 mm, R= 9.0-20.0 mm).
The last and largest larvae were collected in March 1978 (x length = 30.7
mm, R= 27.0-34.5 mm).

Head width was used to show seasonal variation in growth (Fig. 2).
Larvae grew most rapidly from fall (November) to winter (December) (x
head width in fall = 1.2 mm, R = 0.96-1.65 mm; x head width in winter =
2.06 mm, R= 1.39-2.44 mm). They increased their mean head width by 75
percent over the two-month period. The largest mean head width, 2.38
mm, was in the spring (R = 2.18-2.57 mm). Larvae increased their mean
head width by 14 percent from winter to spring. Growth was retarded
during winter, when water temperatures were at their lowest and the
swamp was frozen over.

We tried to determine the number of larval instars by using head width
measurements (Fig. 3). The graph shows a definite grouping of head
widths, indicating three different instars. However, no larvae were found
from July to October. This could eliminate one or two instars from the
calculations.

Siltala (1907) and Wesenberg-Lund (1911, 1913) stated that the larvae
of European phryganeids grow rapidly during summer and early fall, and
reach the last larval stage in October. In this stage they pass the winter

110

Mary Beth Roush and Donald C. Tarter

40

30

20

10

0

>-

u

z

10 20 30 40

BODY LENGTH mm

Fig. 1. Length-frequency histograms at seasonal intervals of P. postica larvae
from Greenbottom Swamp. M = March, D = December, N = November, and
number = sample size.

months. Wiggins (1973) reported living, first-instar, phryganeid larvae (of
unknown genus), still within a gelatinous matrix, beneath wet leaves in a
pool basin in Algonquin Park, Ontario in October 1960. Wiggins (1977)
reported final instars of P. ocellifera in a littoral region of a British
Columbia lake from November to June.

Larval case length also showed seasonal variation (Fig. 4): fall
(November) x = 23 mm, R = 18-33 mm; winter (December) x = 39.3 mm,
R = 22-55 mm; spring (March) x = 50.0 mm, R = 33-69 mm. The correla-
tion between case length and body length was high in fall (Y = 11.65 +
0.86X, r= 0.72) and winter (Y = -10.61 + 2.25X, r= 0.87) (Fig. 5), but low
in spring (Y = 27 + 0.74X, r = 0.37). In these equations, Y = case length
(mm) and X = total body length (mm). These data indicate that body
length and case length are closely related in fall and winter, but in spring
case construction continues as larval growth slows down.

Once the larva of P. postica has begun to add a new ring at the anterior
end of the case, it completes this addition rather rapidly, often with
segments of the same leaf. The larva may pause for several days, or even

SPRING M
43

Caddisfly Life History

111

2.8-

2.6-

2.4-

2.2-

E

E

1.8-

1.6-

1.4-

1.2-

1.0-

75%

rh

IV.-V*

14%

FALL WINTER SPRING

N D M

20 11 43

Fig. 2. Seasonal variation of head width in P. postica larvae. Horizontal lines =
means; vertical lines = ranges; open rectangles = one standard deviation; shaded
rectangles = standard error of the mean; letter = month; number = sample size;
and % = growth rate.

weeks, however, before adding another anterior ring (Fankhauser and
Reik 1935).

The larvae in our study were largely carnivorous early in their life
cycle, shifting to a more omnivorous diet in later stages (Table 1). The
diet of larvae collected in the fall consisted primarily of the copepod,
Cyclops sp. (x= 4.82 per foregut, 85 percent frequency of occurrence (%
FO) ). Ostracods (x = 2.1 per foregut, 50% FO), diatoms (x = 0.42 per
foregut, 20% FO), and detritus (x = 11.55 per foregut, 100% FO) were
also found. In winter, the larval diet consisted primarily of Cyclops sp.
and ostracods (x = 4.33 and 2.33 per foregut, respectively, 55% FO for
each). Diatoms (x = 1.19 per foregut, 73% FO) and detritus (x = 18.39 per
foregut, 100% FO) were also found in winter. The larval diet shifted
in spring and consisted primarily of ostracods and midge larvae (x =
4.5 and 2.0 per foregut, respectively, 20% FO for each). Detritus (x =
27. 12 per foregut, 100% FO) and diatoms (x = 0.90 per foregut, 62% FO)
were also found during this season.

112

Mary Beth Roush and Donald C. Tarter

Instar Head width ranges mm

I

II

III 0.96-1.07

IV 1.38 - 1.73

V 2.16 -2.66

Fig. 3. Head width of all P. postica larvae versus number of larvae.

Wiggins (1977) stated that phryganeid larvae generally are omni-
vorous, with a few predaceous for at least part of their life cycle.
Merritt and Cummins (1978) classified Ptilostomis larvae into two func-
tional feeding groups: (1) shredders and detritivores, and (2) engulfers.
Shapas and Hilsenhoff (1976) reported Ptilostomis spp. from the Mecan
River in Wisconsin that were exclusively carnivorous. Wiggins (1977)
reported that late instars of P. ocellifera from a British Columbia lake
were largely predaceous.

Pupal stage. — Fifty-two pupae were collected in April and May, the
first on 23 April and the last on 16 May. Most were found embedded in
logs. April measurements were: x length = 21.84 mm, R = 17-27.5 mm; x
head width = 2.77 mm, R= 2.4-3 mm. May measurements were: x length
= 22.23 mm, R = 18-23 mm; x head width = 2.62 mm, R = 2. 3-2. 7 mm.

Adult stage. — The first adult was collected on 12 May and the last on
27 May; 31 were collected after dusk. In one hour, 1, 12, 14 and 4 adults
were collected on May 12, 17, 20 and 27, respectively. Twenty females
and 1 1 males were collected. A chi-square test showed no significant
deviation from a 1:1 sex ratio at the 0.05 confidence level.

No eggs were observed in adult females or in the field. According to
Wiggins (1973), O. S. Flint Jr. reported that adult Ptilostomis in Michi-
gan deposited eggs in August, 10 to 20 cm above the water surface of
streams. Gelatinous masses of eggs were attached to the underside of a
log and an overhanging bank.

Caddisfly Life History

113

70-

60-

50-

E

^ 40-

O)

1 30-

0)

«/)

o

^ 20-

10-

0-1

20

FALL WINTER SPRING
N D M

Fig. 4. Seasonal variation of case length in P. postica larvae. Horizontal lines =
means; vertical lines = ranges; open rectangles = one standard deviation; shaded
rectangles = standard error of the mean; letter = month; and number = sample
size.

ACKNOWLEDGMENTS. — We would like to express our thanks to
Miss Vickie Crager for typing the manuscript. Also, we thank the follow-
ing gradutate students for assisting in the field work: Kerry Bledsoe, Bill
Cremeans, Pam Dolin, Paul Hill, Steve Lawton and Joan Schramm.

114

Mary Beth Roush and Donald C. Tarter

Table 1. Seasonal foregut analysis of Ptilostomis postica krvae from Green-
bottom Swamp, Cabell County, West Virginia. X = mean, %FO =
percent frequency of occurrence. N = November (20 larvae), D =
December (1 1 larvae), M = March (43 larvae).

Fall

Category

Taxa

X

%FO

(N)

Copepods

Cyclops sp.

4.82

85

Ostracods

2.1

50

Cladocerans

1.0

15

Midge larvae

Chironomus sp.

1.0

5

Rotifers

1.0

5

Filamentous algae

1.0

20

Unidentified

1.0

30

Grid

Detritus

11.55

100

method:

Diatoms

0.42

20

Winter

(D)

Copepods

Cyclops sp.

4.33

55

Ostracods

2.33

55

Cladocerans

1.75

36

Midge larvae

Chironomus sp.

1.0

9

Rotifers

11.0

9

Dipterans

1.0

9

Filamentous algae

Microspora

1.0

9

Unidentified

1.0

18

Grid

Detritus

18.39

100

method:

Diatoms

1.19

73

Spring

(M)

Ostracods

4.5

20

Midge larvae

Chironomus sp.

2.0

20

Rotifers

9.0

5

Filamentous algae

1.0

5

Unidentified

Odonata

1.0

5

Grid

Detritus

27.12

100

method:

Diatoms

0.90

62

Caddisfly Life History

115

Total length Total length

mm mm

Fig. 5. Regression analysis of body length and case length for P. postica larvae.
Number in parentheses = sample size in fall and winter.

LITERATURE CITED

Betten, Cornelius. 1934. The caddis flies or Trichoptera of New York state. N. Y.
State Mus. Bull. 292. 576 pp.

Fankhauser, Gerhard, and L. E. Reik. 1935. Experiments on the case-building of
the caddisfly larva, Neuronia postica Walker. Physiol. Zool. (^(3):337-359.

Hill, Paul L., D. C. Tarter, B. Cremeans and M. B. Roush. 1978. State records of
family Phryganeidae in West Virginia (Insecta; Trichoptera). Proc. W. Va.
Acad. Sci. 50(1):24.

Merrill, Dorothy. 1969. The distribution of case recognition behavior in ten
families of caddis larvae (Trichoptera). Anim. Behav. /7(3):486-493.

Merritt, Richard W., and K. W. Cummins. 1978. An introduction to the aquatic
insects of North America. Kendall/ Hunt Publ. Co., Dubuque, Iowa. 441 pp.
Ross, Herbert H. 1944. The Caddis Flies, or Trichoptera, of Illinois. 111. Nat.
Hist. Surv. Bull. 23. 326 pp.

Shapas, Theodore J., and W. L. Hilsenhoff. 1976. Feeding habits of Wisconsin’s
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Sibley, Charles K. 1926. Trichoptera. pp. 102-108, 185-221 in A preliminary
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Siltala, Antti J. 1907. Trichopterologische Untersuchungen. Zool. Jahr. Abt.
Syst. Oekol. Geogr. Tiere. (Suppl. 1) 9:309-626.

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Mary Beth Roush and Donald C. Tarter

Wesenberg-Lund, Care. 191 1. Uber die biologie der Phryganea grandis und uber
die Mechanik ihres Gehausebaues. Int. Rev. Gesamten Hydrobiol. 4.65-90.

1913. Wohnungen und Gehausebau der Susswasserinsekten. Fortschr.

Naturw. Forsch. 9:55-132.

Wiggins, Glenn B. 1960a. A preliminary systematic study of the North American
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1960b. The unusual pupal mandibles in the caddisfly family Phryganei-
dae (Trichoptera). Can. Entomol. 92(6):449-457.

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some additional records of caddisflies from Newfoundland (Trichoptera). Can.
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Univ. Toronto Press, Toronto. 401 pp.

Accepted 4 February 1981

Reproduction of the Eastern Cottonmouth Agkistrodon
piscivorus piscivorus (Serpentes: Viperidae) at the
Northern Edge of its Range

Chari.es R. Beem
Department of Biology,

Virginia Commonwealth University, Academic Divison,
Richmond, Virginia 23284

ABSTRACT. — Eastern cottonmouths, Agkistrodon piscivorus pisci-
vorus, were studied at the apparent northeastern edge of the species’
range (Hopewell, Virginia). Although biennial reproduction is generally
typical of viperid snakes, with approximately 50% of the females pro-
ducing young in any given year, 83% of the females collected at the
Hopewell site were gravid. Mean litter size (7.7) does not appear to
differ from that of populations in other parts of the range. Young
cottonmouths at the Hopewell site appear to be smaller than those from
other areas and survival is much reduced in years having cold winters.
Average snout-vent length of adult females at Hopewell currently is
greater and less variable than at locations to the southeast and within
the main range of the species. Production of offspring is a function of
female size; larger females produce more calories of young and larger
offspring. Reproduction in kcal may be accurately predicted from the
weight of the female (g) using the equation: kcal = 0.61 weight - 41.20.

INTRODUCTION

The Eastern Cottonmouth, Agkistrodon piscivorus piscivorus, is one
of the more widespread and abundant poisonous snakes in the Southeast.
It is generally a lowland species (e.g. Kofron 1978), although in the deep
South it may be found in a variety of habitats (Burkett 1966, Mount
1975). In the northern part of its range the cottonmouth becomes more
selective in its choice of habitat, and in Virginia it is known only from
wetlands in the Coastal Plain. The northeastern extreme of the species’
range apparently is represented by an isolated population at the conflu-
ence of the Appomattox and James rivers near Hopewell, Virginia (Fig.
1). At this locality the species occurs in the lower reaches of Swift Creek,
Chesterfield County, and along both west and east banks of the Appo-
mattox River. No cottonmouths have been collected on the James River
in this region. The vegetation of the area, a mosaic of tidal swamps, tidal
marshes, and upland forests, will be described elsewhere (Blem and
Gutzke, in preparation). This population is at least 60 km from the
nearest known locality in the main part of the range, and repeated efforts
to find the species in apparently excellent habitat at other sites near
Hopewell have been fruitless.

Little information is available regarding reproduction of snakes at the
northern limits of their distributions and no studies of reproduction of A.
p. piscivorus have been published. Studies by Wharton (1966, 1969) in

Brimleyana No. 5:1 17-128. July 1981. 117

118

Charles R. Blem

North Carolina

Fig. I. Localities from which the eastern cottonmouth has been taken in Virginia
and northeastern North Carolina. Hollow circle represents the Hopewell site.

Florida were of the subspecies A.p. conanti and those by Burkett (1966)
and Kofron (1979) involved the western subspecies A. p. leucostoma.
Also, there is practically nothing in the literature about the ecology of the
cottonmouth in Virginia. In fact, Wood (1954), in a survey of the distri-
bution of the snake in Virginia, did not mention the Hopewell site and
maintained that cottonmouths did not occur west of the Appomattox
River.

In this paper I also examine briefly some hypotheses regarding animals
at the northern edges of their ranges. For example, environmental condi-
tions in such peripheral areas usually are severe relative to the tolerance
of a species. Mortality of adults and/or young is expected to be high and
occasionally catastrophic; reproduction rates should be adjusted corre-
spondingly. A less variable population may be produced through stabiliz-
ing or normalizing selection, or, in time, the species may be eliminated
entirely. Additionally, the size of young might be adjusted through natural
selection in ways that promote survivorship early in life.

Eastern Cottonmouth Reproduction

119

METHODS

Cottonmouths were observed and collected by hand in more than 500
hrs of field work during April through October 1977-1979. Newly cap-
tured snakes were sacrificed, weighed to the nearest 0.1 g, and body
measurements (total, snout-vent, and tail lengths; head width and length)
were determined to the nearest mm. Each snake was dissected and the
ova of the females were counted and their lengths measured to the nearest
mm. Fat bodies were carefully removed to exclude obvious connective
tissue, weighed to 0. 1 g, and freeze-dried to constant weight. Lipids were
extracted from the fat bodies in Soxhlet refluxers in 5:1 petroleum
ether:chloroform solution. Loss of weight of the dried sample after
extraction represents the amount of extractable lipid. Some obviously
gravid female cottonmouths captured in late July and August of each
year were kept in captivity until the young were born. Shortly after birth,
measurements of young were made as described above. Caloric equiva-
lents of lipid, young snakes, and unfertilized eggs were determined by
means of a Parr nonadiabatic bomb calorimeter.

Scales were counted according to criteria of Burkett (1966), which
essentially include Dowling’s (1951) technique for counting ventrals. For
comparative purposes ventral melanism was quantified by counting all
ventrals from the anal scale anteriad to (but not including) the first three
consecutive scales with less than half of their total area covered by black
pigment.

RESULTS

A total of 68 male and 38 female cottonmouths was collected from the
study area. Chi-square tests (with Yates continuity correction) indicate
that the maleifemale ratio differs significantly from 50:50 (X^=7.93). The
difference may be due to intersexual variation in activity, but since most
snakes were collected at rest near the entrance of “summer dens” I believe
the sexual bias is real. Mainly two types of females were found: those
possessing large, yolked follicles (45-50 mm), and those with small, yolk-
less ova (8-1 1 mm diameter). This is similar to Rahn’s (1942) findings in a
study of Crotalus viridis and those of Tinkle (1962) in an investigation of
Crotalus atrox. Apparently, ovarian eggs ripen rapidly and yolk deposi-
tion of the set may require only a few weeks at most. Two females
captured 13 April 1977 and 13 April 1978 possessed ovarian eggs 16-20
mm long; earliest gravid females were found 31 May 1977.

In order to determine the relative occurrence of reproductive activity in
mature females within the breeding season, I eliminated from the analysis
all those smaller than 700 mm total length (the smallest gravid female was
732 mm), all captured earlier than the first gravid one (3 1 May), and all
captured after September 30 (no gravid animals were captured after this

120

Charles R. Blem

date; all known birth dates are earlier than this). Only 5 of the remaining
29 were not gravid; the rest contained uterine eggs or produced young in
the laboratory. This ratio (24:5=83% gravid) deviates significantly from
the 50:50 ratio predicted from published studies (see below, X =11.18).
(Note: during research of fat cycles and energetics of cottonmouths in
1980, we collected 5 adult females; all were gravid.)

Based on the number of yolked, oviductal eggs or actual number of
young born, mean litter size for the 24 gravid females is 7.68 ± 1.77. The
mean caloric value of yolked cottonmouth eggs is 6.136 ± 0.067 kcal/g
dry weight (N=3); newborn young contain a mean of 5.5 10 ± 0.055 kcal/ g
dry weight (N=3). After correcting for water content of young and eggs, I
computed the total caloric content of the offspring of 1 1 female cotton-
mouths that gave birth in the laboratory. Three of these females pro-
duced single infertile eggs along with viable litters. The eggs are counted
as part of the litter, and the caloric content computed separately and
added to the calories invested in living young. The total represents total
caloric output (but not expenditure) in reproduction. All the females in
this part of the study were held for relatively short periods (45 days or
less) and all births occurred without mortality. The caloric content of the
litter is a significant function of the weight of the female shortly after
giving birth (Fig. 2): kcal = 0.61 weight (g) - 41.20, r = 0.93

Cottonmouth fat bodies are composed of 26.8% water and the remain-
ing dry material is 94.5% lipid. Using the caloric content of lipids
extracted from the fat bodies (x=9.227 ± 0.030 kcal/g, N=4), the mean
caloric reserves of the fat bodies of female cottonmouths were computed.
Assuming that the caloric content of the smallest litter (104.9 kcal)
represents a threshold minimum, no cottonmouth possessing fat bodies
weighing less than 16.5 g (=105.3 kcal) could be expected to reproduce,
especially those collected in early spring or summer. A distinct cycle of
lipid deposition is discernible in female cottonmouths at Hopewell, in
which reserves are generally low in spring and increase in autumn (Blem,
unpublished). In early spring, before the first gravid female was collected,
3 of 6 nongravid females did not possess lipid in excess of this threshold.
During the period 31 May - 30 September, 3 of 5 nongravid females had
fat bodies below threshold levels, and after 30 September all females (3)
had less fat than the amount apparently necessary for reproduction.
Seven female cottonmouths collected during mid-September in extreme
southeastern Virginia likewise possessed insufficient reserves (fat bodies
weighed from 1.5 to 11.0 g) for reproduction. Overall, nonreproductive
females possessed slightly more fat than those containing eggs or produc-
ing young (“reproductive females”), although the difference is not statis-
tically significant (Table 1). Male cottonmouths possessed significantly
greater amounts of fat than females in either category, but the difference

Eastern Cottonmouth Reproduction

121

Fig. 2. Total energy content (kcal) of offspring as a function of female body
weight (g). The equation for the relationship is: kcal offspring = 0.61 weight of
female (g) - 41.20; r = 0.93. Eleven different females are included in the analysis.

in relative fatness, expressed as a percentage, is not statistically significant.

Larger females gave birth to correspondingly larger young (Table 2).
Length and weight of young cottonmouths at Hopewell are distinctly
smaller than those of newborn cottonmouths at Florida sites (Allen and
Swindell 1948, Wharton 1966), but sufficient data are lacking at present
for proper analyses of geographic trends. The “heritability” of size of
young cottonmouths at the present study location is statistically signifi-
cant, but comparative data from other study sites are unavailable. Also,
heritability of size is expected to be statistically great when only the
female parent is known (Falconer 1960). The physiological/ ecological
basis for the relationship between the size of female snakes and their

122

Charles R. Blem

young remains to be shown, but it probably is related to aspects of energy
mobilization and amount of lipid reserve in larger snakes.

Other than the correlations between female size and size of young, the
present studies indicate no significant correlation between head length
and width, between number of subcaudals and ventrals, or with degrees
of melanism. Head lengths and widths and subcaudal counts are sexually
dimorphic, and the scatter introduced into a mixed litter of male and
female young probably obscures correlations between scale counts of the
parent and young. Melanism apparently increases with age, as adult
females generally score higher than their young (see Table 2). Lack of a
significant correlation between ventral counts of parents and young may
be due to low overall variation in ventrals.

Table 1. Weight of fat bodies and body weight in adult eastern cottonmouths at

Hopewell, Virginia (± 1 standard error).

Reproductive

females

Nonreproductive

females

Males

Mean body weight (g)

430.8 ± 30.4

402.6 ± 28.7

857.2 ± 60.6

Mean fat weight (g)

12.3 ± 2.1

15.4 ± 2.2

33.7 ±4.3

Percentage fat

2.9

3.8

3.9

N

24

14

68

Table 2. Relationship of morphometries of young cottonmouths to female parents.
Values are means, r = correlation coefficient, Y = measurement of

young, F

== measurement of

female.

Females

Young

r

Equation

N

10

80

—

—

Body weight (g)

363.5

17.3

0.70*

Y = 0.018 FT 10.168

Snout-vent length

(mm) 747.2

211.3

0.58*

Y± 0.061 FT 11.039

Melanism

38.1

17.3

0.40

Ventrals

133.2

132.9

0.40

Subcaudals

41.5

44.6

0.22

Head length (mm)

44.3

20.5

0.34

Head width (mm)

34.9

13.2

0.42

*P<0.05

Eastern Cottoiimouth Reproduction

123

DISCUSSION

It is obvious that the limits of a species’ range are reached where
mortality regularly exceeds reproductivity. At the Hopewell site we have
established that survival of young cottonmouths is quite poor in years in
which the winter is unusually cold (Blem and Gutzke, in preparation).
The success of females giving birth in the lab indicates that reproduction
regularly occurs without undue mortality. In the field, several litters of
newborn cottonmouths have also been observed in September. No small
cottonmouths (i.e less than 403 mm snout-vent length) have been col-
lected at Hopewell in spring or summer, although we regularly collect
individuals of 200-500 mm in extreme southeastern Virginia. I believe this
is related to the extremely cold winters of 1976-1977 (the coldest January
since 1940) and 1977-1978 (the second coldest January of the period
1971-1979). No other environmental variable would seem to account for
the disappearance of young overwinter. The more abundant size classes
over 600 mm appear to represent greater survivorship over mild winters
before 1976.

A variety of forces may contribute to death in cottonmouths. Man is
probably the major cause of mortality at most sites (Burkett 1966), but
starvation during mild winters (Wharton 1969), disease and parasitism
(Burkett 1966), and a wide variety of predators (Allen and Swindell 1948,
Barbour 1956, Burkett 1966) all take their toll. Mortality from cold seems
to be absent in the main range, as tolerance of low temperatures seems
well developed in cottonmouths (Wharton 1969). Perhaps only at the
northern edge of the range does freezing occur so intensively or for such
long periods that survival in the hibernacula becomes difficult.

The ability of a species to maintain its distributional limits or expand
them depends upon behavioral, physiological, and morphological adap-
tations that balance the birth-death ratio. Among the reproductive
adjustments that a reptile might demonstrate are: 1) increased litter size,
2) more frequent ovulation, 3) earlier sexual maturation, 4) early ovula-
tion or more rapid development of young, 5) production of young that
are better adjusted for survival of the environment at the distributional
extreme, and 6) niche selection that maximizes the accumulation of
energy for reproduction.

Few data are available with which to compare litter size at the Hope-
well site. Litter sizes in cottonmouths collected in the Everglades (x=6.6 ±
2.5, N=31: Allen and Swindell 1948) do not differ significantly from the
data in my study. Mean litter size of females from the Cedar Keys, Florida
(5.5 ± 1.5, N=24; Wharton 1966) is significantly smaller (t=4.8, df=46)
than that of the Hopewell site. I conclude that there is little evidence at
present that indicates any adjustment of the number of young in litters at
the northern extreme of the range.

124

Charles R. Blem

Reproduction by individual females within many species of snakes
apparently is not an annual phenomenon. Evidence indicates that many
viperid species produce young at two-year or longer intervals (St. Girons
1957, Tinkle 1962, Fitch 1970, Aldridge 1979). Burkett (1966) and Whar-
ton (1966) reported a biennial cycle in A. piscivorus, but an annual cycle
has been found in some populations of Louisiana cottonmouths (see
Kofron 1979). It is generally believed that snakes at northern latitudes
often are not able to accumulate sufficient energy to produce and mature
a set of eggs annually (Rahn 1942, Klauber 1972, Tinkle 1957, St. Girons
1957), but my data contradict this generalization. If reproduction is bien-
nial or less frequent, 50% or less of the mature females collected should
possess ripe eggs in the uterus (as did Florida cottonmouths; see Wharton
1966). However, at Hopewell during 1977-1979, 83% of the females that
could have possessed uterine eggs were, in fact, gravid. This ratio is
significantly different from 50:50 and indicates that Hopewell cotton-
mouths breed more regularly than expected.

Frequency of reproduction of viviparous snakes is believed to be a
function of fat storage (Tinkle 1962, Wharton 1969, Aldridge 1979).
Assuming this is true, the Hopewell population during 1977-1979 seemed
to be well prepared for reproduction. Lipid reserves were sufficient for
most mature females to produce full litters. Hopewell cottonmouths also
exceeded the lipid levels found in all reproductive classes (reproductive
and non-reproductive females, males) in Wharton’s (1966) Florida study.
A low population density at Hopewell may have reduced competition for
food and provided for more productive foraging. At present there are no
data with which to assess this hypothesis, but a subjective evaluation
indicates that cottonmouths are more abundant in the main part of the
range (e.g. extreme southeastern Virginia). The high rate of reproduction
found in my study may also be related to winter extremes. Mild winters
may cause decreases in fat reserves because of elevated metabolism
(Wharton 1966), and conversely, very cold winters may encourage repro-
duction through conservation of fat stores. As stated above, the winters
during my study were among the coldest of the decade.

Few data are available regarding size of female cottonmouths at first
reproductive effort. Arny (in Wharton 1966) found that female A. p.
leucostoma may mature at a total length of 594 mm. Wharton (1966)
noted that 800 mm was the minimum total length of mature females in
the Cedar Keys of Florida. At least three Hopewell cottonmouths less
than 800 mm total length (732, 770, and 791 mm; =619, 654, and 684 mm
snout-vent length) contained oviductal eggs, and two females (707 and
756 mm total length) collected in September had ovarian eggs of 10-11
mm. I conclude that early maturation at the Hopewell site is a viable
hypothesis that requires further study.

Eastern Cottonmouth Reproduction

125

Although sufficient data are not available for rigorous testing, time of
ovulation apparently varies little from one site to the next. Wharton
(1966) estimated that Florida cottonmouths ovulated in the period 20
May-8 June, and Burkett’s (1966) data indicate similar timing, as do my
data. I have no measurements of growth of young because smaller speci-
mens were absent throughout this study.

Weight of young at birth could be a fundamental indication of the
fitness of offspring. Young cottonmouths at Hopewell are born in Sep-
tember (usually around the middle of the month, the mean date = 18
September, range = 5 September-23 September, N=13). They therefore
have little opportunity to forage (and accumulate energy stores) before
finding a hibernaculum for the winter. In addition, increased body mass
may conserve heat and enhance survival at low ambient temperature in
the hibernaculum. Cooling rates of large snakes should be slower, allow-
ing them to survive short periods of extreme cold or to move to deeper
parts of the hibernaculum before cooling to fatal temperatures. Snout-
vent lengths and weights of young from other parts of the range largely
reflect size of the parental race (see Wright and Wright 1957) and it
appears that Hopewell cottonmouths do not produce particularly large
young (Table 2). Weights and total lengths of young Florida cotton-
mouths (324-343 mm; 28.0-33.7 g) are distinctly greater than those of the
Hopewell population (Allen and Swindell 1948, Wharton 1966). Reduced
size of young cottonmouths at Hopewell could be interpreted as an evolu-
tionary compromise that maintains litter sizes while reducing the expen-
diture of energy per litter. This would be advantageous where fitness of
small young is high and availability of energy is low. Neither seemed to be
the case at Hopewell in 1977-1979, and the significance of small offspring
there remains to be shown.

Size of mature females at the Hopewell site varies less than in popula-
tions in southeastern Virginia or northeastern North Carolina, and mean
snout-vent lengths of Hopewell snakes (excluding newborn young) aver-
age significantly longer than those in the main part of the range to the
southeast (Blem and Gutzke, in preparation). Moreover, within the total
range of size, reproductive output is a linear function of weight of the
female. Larger females are apparently able to mobilize greater amounts
of energy in reproduction, and we have found that, in general, larger
individuals have larger fat reserves. The so-called “biennial reproduc-
tion”, with 40-60% of females breeding in any given year, may only be an
artifact of the collective reproductive rates of a population of females of
diverse sizes. Large females reproduce more frequently than small (Bur-
kett 1966), and generally have larger lipid reserves; at Hopewell: g lipid =
0.05 snout-vent length (mm) - 19.65, r=0.55. It is therefore likely that
larger individuals are capable of collecting and mobilizing larger energy

126

Charles R. Blem

reserves and have a greater statistical probability of reproducing in any
single year. It appears from this that descriptions of reproductive fre-
quency at specific sites are of little value without a description of the
sizes of the females involved. The percentage of gravid females in popula-
tions composed predominantly of large individuals generally should
exceed that of populations containing significant numbers of smaller (but
mature) females.

The size of young cottonmouths is at least partly determined by the size
of the female parent, and as shown, the correlation between female size
and that of offspring is fairly large. While selection for large body size in
female cottonmouths at Hopewell may be only a phenomenon related to
periodic mortality of small snakes, the present situation probably reduces
the amplitude of population oscillations at least partly as a result of the
relationship between female size and reproductive output. Increase in
reproductive output appears to be related to number of mature ova pro-
duced and size of offspring (Burkett 1966, and the present study). Elimi-
nation of small individuals in extreme years should decrease competition
for food among females and might further insure their successful contact
with males. Production of young with a relatively high degree of fitness
could occur, with most females producing young in breeding seasons
following severe winters. Mild winters should enhance subsequent survi-
val of young, and decreased lipid reserves and increased competition
would result in decreases in the number of females producing offspring.

The bias toward large size is even more striking in males (Table 1). No
males less than 640 mm total length were captured in 1977-1979 and 18
males were collected that exceeded 1000 mm and 1000 g (the largest was
1345 mm and 2008.5 g). Since Wharton (1966) considered males above
650 mm to be sexually mature, it is likely that the male segments of the
1977-1979 populations were almost entirely mature. It appears that males
generally exceed females in size; Wharton (1966) obtained a similar result
in his Florida studies.

The cottonmouth at Hopewell is much more habitat-specific than in
some other parts of its range. For example. Mount (1975) described the
cottonmouth in Alabama as “occurring in almost every type of perma-
nently aquatic habitat”. At Hopewell it is found very locally and only at
sites where tidal marshes and nearby upland provide feeding and hiber-
nating sites, respectively. The apparent failure of the species to colonize a
number of nearby sites that seem superficially suitable is evidence that
relatively inconspicuous factors may be influential in determining habitat
suitability for the cottonmouth at the northern edge of its range. Precise
habitat selection may be an important factor in enabling female cotton-
mouths to obtain sufficient energy for reproduciton.

It is obvious that with the present survival rate of young the future of

Eastern Cottonmouth Reproduction

127

this population is in jeopardy. Even though small cottonmouths (other
than newborn individuals seen in autumn) have begun to appear in 1980,
the population structure is skewed heavily toward longer and older indi-
viduals. Local people kill many of these adults each year, along with
many brown water snakes, Nerodia taxispilota, mistaken for cotton-
mouths. I predict the species will become very rare at this site in the
future.

ACKNOWLEDGMENTS. — I am grateful to Leann Blem, Claire
Filemyr, Mike Miller, Cheryl Roeding, and Tom Thorp for assistance in
the field. William Gutzke made the project possible through his extensive
assistance in the field and laboratory and asked questions that stimulated
me to find answers. Val Combs assisted in preparation of the manuscript
and John W. Steiner and C. C. Steirly provided important suggestions or
observations. Figure 1 is based on specimens loaned to me from the
Carnegie Museum of Natural History, National Museum of Natural His-
tory, and North Carolina State Museum of Natural History. 1 am
indebted to the curators of these collections. Virginia Commonwealth
University Computer Center provided computational facilities. Grants
from the Virginia Academy of Science and the Virginia Commonwealth
University faculty grant-in-aid program provided support for this
research.

LITERATURE CITED

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Barbour, Roger W. 1956. A study of the cottonmouth, Ancistrodon piscivorus
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Burkett, Ray D. 1966. Natural history of cottonmouth moccasin, Agkistrodon
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, 1979. Reproduction of aquatic snakes in south-central Louisiana. Her-

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Mount, Robert H. 1975. The reptiles and amphibians of Alabama. Auburn Univ.
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Rahn, H. 1942. The reproductive cycle of the prairie rattlers. Copeia 1942(4);
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Tinkle, Donald W. 1957. Ecology, maturation and reproduction of Thamnophis
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. 1962. Reproductive potential and cycles in female Crotalus atrox from

northwestern Texas. Copeia 1962(2):306-313.

Wharton, Charles H. 1966. Reproduction and growth in the cottonmouths,
Agkistrodon piscivorus Lacepede, of Cedar Keys, Florida. Copeia 1966(2):
149-161.

. 1969. Cottonmouth moccasin on Sea Horse Key, Florida. Bull. Fla.

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Accepted 8 October 1980

Habitat Use and Relative Abundance of the
Small Mammals of a South Carolina Barrier Island

John B. Andre^

Cape Romain National Wildlife Refuge,

Route 1, Box 191, Awendaw, South Carolina 29429

ABSTRACT. — Species composition, habitat use, and relative abun-
dance of the small mammal fauna of Bulls Island, Charleston County,
South Carolina were determined by snap trapping on 17 days between
December 1978 and February 1979. Ninety-five mammals of four spe-
cies were captured in 2909 trap nights, for an overall trapping success of
3.3%. Oryzomys palustris was found in all habitats and was the only
species in the dunes, salt spray forest, and freshwater marsh habitats.
Sigmodon hispidus was numerically dominant in the old-field, while
Peromyscus gossypinus and Mus musculus were most abundant in the
residential area.

INTRODUCTION

Barrier islands of the southeastern coast of the United States are inter-
esting areas for biological studies due to their isolation from, yet close
proximity to, the mainland (Gibbons and Coker 1978). Species diversity
and composition vary between neighboring islands and between islands
and the mainland (Dueser et al. 1979). Patterns of colonization and
interisland variability in species characteristics, e.g. habitat preference in
association with different species on different islands, may emerge as
more data on animals inhabiting different islands are made available for
comparisons.

Terrestrial vertebrate studies have been conducted on some of the
islands of Virginia (Dueser et al. 1979), North Carolina (Engels 1942,
1952), South Carolina (Pelton 1975) and Georgia (Hillestad et al. 1975;
Johnson et al. 1974; Teal 1962). However, published information on the
vertebrates of many barrier islands is lacking.

This paper describes the previously unreported small mammal fauna of
a South Carolina barrier island. The objectives of the study were to (1)
determine the species composition and relative abundance of the small
mammals on Bulls Island and (2) obtain specific information on the
presence of a species in specific habitats.

THE STUDY AREA AND METHODS

The study was conducted on Bulls Island, Charleston County, South
Carolina, a 2024 ha barrier island in Cape Romain National Wildlife
Refuge. The island is approximately 9.6 km long and 3.2 km wide. Salt

Present address; U.S. Fish and Wildlife Service, P.O. Box 87, Kilauea, Kauai,

Hawaii 96754

Brimleyana No. 5:129-134. July 1981. 129

130

John B. Andre

marsh, tidal creeks, and the intracoastal waterway separate the island
from the mainland by a distance of about 3 km.

Stalter (1974; manuscript) listed the plant species of Bulls Island and
described three major and two minor plant communities. Hosier’s (1975)
descriptions of the plant communities of Kiawah Island, Charleston
County, although more detailed than Stalter’s Bulls Island studies,
showed that the two islands are similar in vegetation. I followed Hosier’s
classification to delineate the habitats on Bulls Island, recognizing the
following: fore and rear sand dune; salt spray forest; maritime live oak
forest; freshwater marsh; salt marsh; and old-field. A residential area
consisting of one house and a workshop made up a seventh small mam-
mal habitat surveyed.

The dominant vegetation of each habitat (excluding the residential
area) follows: (1) sand dune. — sea oats, Uniola paniculata; croton,
Croton punctatus\ sea elder, Iva imbricata; and panic grass, Panicum
amarum. (2) salt spray forest. — live oak, Quercus virginiana\ red bay,
Persea borbonia; wax myrtle, Myrica cerifera; and yaupon. Ilex vomi-
toria. (3) live oak forest. — live oak; loblolly pine, Pinus taeda; Darling-
ton oak, Quercus laurifolia\ and magnolia. Magnolia grandiflora. (4)
freshwater marsh. — cattail, Typha sp.\ rush, Scirpus sp.; wax myrtle;
cabbage palmetto, Sabal palmetto; and willow, Salix caroliniana. (5) salt
marsh. — smooth cordgrass, Spartina alterniflora. (6) old-field —
broomsedge, Andropogon sp.; and other grasses and herbaceous plants.

Small mammals, i.e. those capturable in mouse and rat snap traps,
were collected during 17 days of trapping between 18 December 1978 and
10 February 1979. Trapping was conducted from 18 to 20 December, 9 to
12 and 23 to 26 January, and 7 to 10 February. Trapping effort was not
equal in all habitats (see Table 1) due to time and material constraints.

Six trapping transects, one per habitat (excluding the residential area),
were established. Each had 12 trapping sites, placed at 5 m intervals, and
each site included one rat and three mouse snap traps situated 4 m apart
along a line perpendicular to the transect. Thus, each transect contained
48 traps and was 12 m wide and 55 m long.

Transect width was reduced in the freshwater and salt marsh habitat
edges to minimize the chance of trapping animals from adjacent habitats.
Twenty-eight mouse and eleven rat traps were selectively placed in and
around the residential area to determine small mammal occurrence and
the results are included in Table 1. Eight rat traps were placed on trees in
the maritime live oak forest to investigate the presence of flying squirrels,
Glaucomys volans, but none was captured during the study.

All traps were Victor brand, baited with a paste of rolled oats and
peanut butter that was replenished as needed. Specimens obtained in this
study were donated to the Charleston Museum.

Barrier Island Small Mammals

131

Table 1. Summary of small mammal trapping on Bulls Island, December 1978
to February 1979.

Habitat

Number
of days
trapped

Number
of trap
nights

Number and
genera of mam-
mals captured

Relative
abundance
value (RAV)"'

Fore and rear

sand dunes

13

560

9 Oryzomys

1.6

Salt spray

forest

13

578

17 Oryzomys

2.9

Maritime live

oak forest

13

616

3 Oryzomys

0.5

2 Peromyscus

0.3

Freshwater

marsh

4

186

5 Oryzomys

2.7

Salt marsh

10

381

36 Oryzomys

9.4

1 Sigmodon

0.2

Old-field

9

432

1 1 Sigmodon

2.5

3 Oryzomys

0.7

Residential

area

4

156

4 Peromyscus

2.6

3 Mus

1.9

1 Oryzomys

0.6

All Habitats

17

2909

74 Oryzomys

12 Sigmodon

• • • •

6 Peromyscus
3 Mus

''The percent trapping success for each species in each habitat.

132

John B. Andre

Differences in abundance of small mammals among habitats were
compared by Chi-square test. Equal probability of capture in each habi-
tat was assumed. For each species, expected frequency (E) in each habitat
was calculated by dividing the number of trap nights executed in habitat
A by the total number of trap nights executed in habitats A and B, then
multiplying by the number of individuals captured in habitats A and B.

RESULTS AND DISCUSSION

Trapping results, habitat use, and relative abundance of the four spe-
cies of small mammals found on Bulls Island are shown in Table 1. The
percent trapping success for each species in each habitat is the relative
abundance value (RAV). Comparisons of the RAVs of different species
within a habitat, and of the same species among habitats, reflects the
degree of a species’ use of a habitat.

The rice rat, Oryzomys palustris, was the only species captured in the
sand dune, freshwater marsh, and salt spray forest habitats. It was
equally abundant in the freshwater marsh (2.9 RAV) and salt spray forest
(2.7 RAV) habitats, and less abundant in the sand dunes (1.6 RAV). The
differences were not significant(X^=2.22, 1 df, p>0. 10). The freshwater
marsh and salt spray forest habitats are structurally complex, with
patches of grass and dense, tangled stands of small trees and shrubs. By
contrast, the vegetation of the sand dunes was sparse and structurally
simple with only scattered, dense stands of sea oats. Oryzomys prefers
habitats with a dense cover of grasses or sedges (Golley 1962). On Bulls
Island vegetation of this type was found only in small patches in the
dunes, providing little habitat for Oryzomys,

The maritime live oak forest produced the fewest mammals of all
habitats despite the greater number of trap nights. Oryzomys and the
cotton mouse, Peromyscus gossypinus, yielded RAVs of 0.5 and 0.3,
respectively. The maritime live oak forest of Kiawah Island was also
sparsely inhabited by small mammals, presumably because the forest
canopy reduces light penetration to the forest floor, reducing productiv-
ity and resulting in little food and cover (Pelton 1975). The three Oryzo-
mys I captured in the live oak forest were subadults, as judged by body
size. Grant (1971) reported that subadult Microtus pennsylvanicus were
more likely to inhabit suboptimal habitat than were adults. A more
detailed study is needed to determine whether the same is true of Oryzo-
mys on Bulls Island.

Trapping in the salt marsh produced 36 O. palustris and 1 hispid
cotton rat, Sigmodon hispidus. Oryzomys was significantly more -abun-
dant there (9.4 RAV) than in any other habitat during winter (X^= 17.48, 1

Barrier Island Small Mammals

133

df, p<0.005). It feeds on grasses, sedges, insects, crabs, fish, and the eggs
and young of birds (Golley 1966; Sharp 1967). Although bird eggs and
nestlings are not available in winter, the probable abundance of other
food items in the salt marsh could explain why Oryzomys is able to
exploit this habitat so successfully. Oryzomys was also common in the
salt marshes of Kiawah Island (Pelton 1975) and was the most widely
distributed mammal in the Virginia barrier island complex (Dueser et al.
1979).

Sigmodon and Oryzomys are sympatric in the salt marsh and old-field
habitats, indicating some similarity in habitat requirements, i.e. dense
grass and weed cover. Oryzomys prefers stream edges, freshwater
marshes, and salt marshes, while Sigmodon prefers drier grass fields and
thickets (Golley 1966). Although Oryzomys was found in all habitats on
Bulls Island it was most abundant in the salt marsh (9.4 RAV), salt spray
forest (2.9 RAV), freshwater marsh (2.7 RAV), and sand dunes (1.6
RAV), while Sigmodon was common only in the old-field habitat (2.5
RAV). Significantly more Oryzomys were captured in the salt marsh than
Sigmodon (p<0.005), while more Sigmodon were captured in the old-
field habitat than Oryzomys (p<0.05), demonstrating that Sigmodon is
found mostly in old-fields.

Of the three species captured in the residential area, Peromyscus was
most abundant (2.6 RAV), followed by the house mouse, Mus musculus
(1.9 RAV), and Oryzomys (0.6 RAV). The difference was not significant
(X^=1.8, 1 df, p>0.1) between Peromyscus and Oryzomys. Pelton (1975)
found that Peromyscus invaded homes on Kiawah Island, as it has on
Bulls Island, and also reported that it was the most abundant small
mammal of Kiawah Island. On Bulls Island Peromyscus is less abundant
than Oryzomys and Sigmodon. It is interesting to note that Mus (an
exotic species) was captured only in the residential area of Bulls Island.
Pelton (1975) found no Mus in or around the residential areas of Kiawah
Island. He reported, however, capturing Mus in abundance in the sand
dune habitat. Dueser et al. (1979) captured Mus on four Virginia barrier
islands and found that its distribution was not limited to the vicinity of
cabins on three of the islands.

Representatives of the small mammal fauna of Bulls Island used all
habitats sampled. Mus was found only in the residential area. Peromys-
cus inhabited the maritime live oak forest and probably colonized the
residential area with migrants from that habitat. Oryzomys captured in
the residential area probably also represented migrants from surrounding
habitats. In old-fields Sigmodon is numerically dominant to other spe-
cies. Oryzomys is a habitat generalist on Bulls Island, but it is most
abundant in the salt marsh.

134

John B. Andre

ACKNOWLEDGMENTS. — Support for field work was provided by
the U.S. Fish and Wildlife Service, Cape Romain National Wildlife
Refuge. I thank James A. MacMahon for reviewing an earlier draft of the
manuscript, and three anonymous reviewers and Raymond D. Dueser for
their helpful comments.

LITERATURE CITED

Deuser, R.D., W.C. Brown, G.S. Hogue, C. McCaffrey, S.A. McCuskey and G.J.
Hennessey. 1979. Mammals on the Virginia barrier islands. J. Mammal.
(50:425-429.

Engels, W.L. 1942. Vertebrate fauna of North Carolina coastal islands. Am.
Midi. Nat. 25:273-304.

1952. Vertebrate fauna of North Carolina coastal islands. II: Shackle-
ford Banks. Am. Midi. Nat. ^7:701-742.

Gibbons, J.W., and J.W. Coker. 1978. Herpetofaunal colonization patterns of
Atlantic coast barrier islands. Am. Midi. Nat. 99:219-233.

Golley, Frank B. 1962. Mammals of Georgia: A study of their distribution and
functional role in the ecosystem. Univ. Georgia Press, Athens. 218 pp.

Grant, P.R. 1971. The habitat preference of Micro tus pennsylvanicus, and its
relevance to the distribution of this species on islands. J. Mammal. 52:351-361.
Hillestad, H.O., J.R. Bozeman, A.S. Johnson, C.W. Berisford and J.I.
Richardson. 1975. The ecology of Cumberland Island National Seashore,

Camden County, Georgia. Ga. Mar. Sci. Cen. Univ. Ga. Tech. Rep. Ser. No.
75-5, Skidaway Island. 219 pp. + 4 maps.

Hosier, Paul E. 1975. Dunes and marsh vegetation, pp. Dl-D96m Environmental
inventory of Kiawah Island. (W.D. Chamberlain, project coordinator.)
Environ. Res. Cen., Inc., Columbia.

Johnson, A.S., H.O. Hillestad, S.F. Shanholtzer and G.F. Shanholtzer. 1974.
An ecological survey of the coastal region of Georgia. Nat. Park Serv. Sci.
Monogr. Ser. No. 3:1-233.

Pelton, Michael R. 1975. The mammals of Kiawah Island, pp. M1-M45 in
Environmental inventory of Kiawah Island. (W.D. Chamberlain, project
coordinator.) Environ. Res. Cen., Inc., Columbia.

Sharp, Homer F., Jr. 1967. Food ecology of the rice rat, Oryzomys palustris
(Harlan), in a Georgia salt marsh. J. Mammal. 45:557-563.

Stalter, Richard. 1974. A floristic study of South Carolina barrier islands. ASB
Bull. 27:86. Abstract.

Manuscript. The flora of Bulls Island, Charleston County, South

Carolina. Unpubl.

Teal, J.M. 1962. Energy flow in the salt marsh ecosystem of Georgia. Ecology
45:614-624.

Accepted 23 February 1981

On the Taxonomic Status, Distribution and Subspecies
of the Milliped Pseudotremia fracta (Chamberlin)
(Chordeumatida: Cleidogonidae)

Richard L. Hoffman
Department of Biology,

Radford University, Radford, Virginia 24142

A BSTRACT. — Examination of the female holotype of Pseudotremia
fracta Chamberlin (1951) shows beyond much doubt that this name is
senior to P. cottus (Shear (1972). This widely distributed species is
herein considered to contain four subspecies, easily distinguished by
form of the median process of the gonopod syntelopodite: P.f. fracta in
the Great Smokies; P.f. paynei n. subsp. along the Clinch River, Ten-
nessee; P.f. ingens n. subsp. from the Cumberland Mountains in Scott
County, Tennessee; and P.f. nantahala n. subsp. in the Nantahala River
gorge. North Carolina. The proposal by Shear (1972) to unite fracta,
cocytus, and scrutorum in a subgeneric group is reaffirmed. The last-
named taxon may in time be shown to be subspecifically related to
fracta.

Because of the normally restricted ranges of most species of Pseudo-
tremia, it is a matter of interest when one is found to occur over a
relatively large geographic area that embraces a variety of physiographic
provinces and a resultant diversity of biotopes. Such an organism is
Pseudotremia fracta (Chamberlin 1951), which appears to be not
uncommon in central eastern Tennessee in both epigean and subterra-
nean habitats.

Since the original description was based upon a female specimen,
which was subsequently misplaced and unavailable for study, the status
of this nominal species could not be addressed with confidence by the
recent monographer of the genus (Shear 1972). With evident perspicuity,
however. Dr. Shear suspected (1972:158) that the name fracta was based
on an immature specimen of the species that was named Pseudotremia
cottus in his revision.

During the course of a general renovation of the Chamberlin collection
(now on deposit at the Smithsonian Institution), the type oi fracta —
among many other misplaced specimens — was recovered but was not
closely examined until the recent receipt from Dr. Thomas C. Barr, Jr. of
unidentified material showing some degree of affinity with Shear’s P.
cottus. With the motivation of having to provide a name for this popula-
tion, I essayed an investigation de novo, the results of which are set forth
in the following pages.

Brimleyana No. 5:135-144. July 1981.

135

136

Richard L. Hoffman

As might be expected of a milliped that occurs in leaf litter in the
spruce-fir forest of the Great Smoky Mountains as well as in limestone
caves along the Clinch River 50 miles distant and 4000 feet lower, there is
evident geographic variation in structure of the gonopods. This circum-
stance was perceived and accounted by Shear (1972:184, Figs. 103, 104),
although he did not go so far as to nomenclatorially formalize subspecific
differentiation.

Since the already manifested differences between the populations of
the Tennessee Valley and the Great Smokies have now been further
substantiated by the discovery of two new forms of fracta in the Cumber-
latid Mountains and in the Nantahala Gorge, I think it desirable to
introduce trinomial designations for these four isolates, and to confirm
Dr. Shear’s suspicion that cottus might be a junior synonym of fracta.

In connection with the citation of material in the following accounts,
the standard acronymic abbreviations are used to indicate the location of
specimens, thus:

MC2 — Museum of Comparative Zoology
NCSM — North Carolina State Museum
RLH — Personal collection of the author
USNM — National Museum of Natural History

Pseudotremia Cope 1869:179. Shear 1971:162-193 (monograph).

The general structure of the gonopods in Pseudotremia has been
adequately described and figured by Shear. I wish here only to express an
opinion about one anatomical feature and to suggest a slight refinement
in nomenclature.

As shown in his Figure 1 (of Pseudotremia hobbsi), the dominant
elements of the gonopods (8th pair of legs) are the apparent coxal deriva-
tives for which the term colpocoxite (Ribaut 1920) seems applicable.
Immediately posterior to the pair of colpocoxites, and attached to them
only by connective tissue (no direct musculature has been demonstrated)
is a sclerotized, almost medially diastemmate structure (the “bifid lami-
nae” of earlier workers) that Shear considers to represent the fused telop-
odites of the gonopods. If this interpretation is correct, and I have no
better alternative to suggest, perhaps the term “syntelopodite” might be
employed in this genus (in the related taxon Cleidogona, the two struc-
tures remain discrete or minimally attached at their bases). When the
appendages of the genitalic complex are held in a resting position, the
syntelopodite is tightly embraced basally by large coxal lobes of the
posterior gonopods (9th pair of legs).

The anterior (ventral) surface of the syntelopodite is generally modified
in Pseudotremia by the development of a central basal structure, referred

Milliped Taxonomy and Distribution

137

to by Shear as the “telopodite process” and by him quite properly exploit-
ed as a taxonomic character of considerable importance. A wide spec-
trum of form is evident, from a low median convexity to enormously
elongated and apically bifid blades projecting conspicuously between the
colpocoxites.

In a small group of apparently related species native to eastern Tennes-
see, the syntelopodite process is somewhat enlarged distally, and apically
produced into several projections of variable form and length. These
species are P. cocytus Shear, P. cottus Shear, P. scrutorum Shear, and P.
minos Shear, and the ensemble was referred to by Shear as the Cottus
Group. I think he was quite correct in considering it “. . . one of the more
coherent species assemblages in the genus Pseudotremia.'' With the pres-
ent reinstatement of P.fracta as a senior synonym of cottus, it will be
appropriate to likewise alter the group designation.

Both geographically and anatomically, P. minos is somewhat disjunct
from the others (known from northern Alabama, troglobitic rather than
trogophilic, and with the syntelopodite process four- instead of three-
pronged) and perhaps warrants assignment to a group of its own. Of the
remainder, cocytus occurs in Anderson County, Tennessee, apparently
sympatric with fracta but not yet collected at the same locality with it;
scrutorum is known only from the type locality in Scott County, Tennes-
see; and fracta occurs widely from the crest of the Great Smokies to caves
and bluffs along the Clinch River.

Pseudotremia fracta Chamberlin

The original description of this taxon was based upon a single female
from Gatlinburg, Tennessee, and mentioned in four brief sentences color-
ation, size, number of ocelli, and form of the metatergal surface sculp-
ture. Although the specimen was subsequently misplaced in the collection
of the describer, and despite the brevity of the account, it was possible for
Dr. Shear to suspect that the name fracta applied to an immature indi-
vidual of the species that he (1972:1) named Pseudotremia cottus. Subse-
quent to the demise of Dr. Chamberlin in 1968 his myriapod collection
was transferred to the National Museum of Natural History and in 1977
the diplopod material was placed in my hands for reorganization. Event-
ually the type oi fracta was discovered and Shear’s prophesy fulfilled; it is
indeed a female lacking one moult of maturity yet externally identical
with specimens identified by Shear as P. cottus (which is, moreover, the
only member of the genus so far known from the western slopes of the
Great Smokies).

The present decision to recognize taxonomically nameworthy popula-

138

Richard L. Hoffman

tions within the original concept of cottus engenders the question of their
relative status, both to each other and to the closely allied P. scrutorum.
Although no decisive answer can be advanced at the present, the point
nonetheless merits consideration if for no other reason than the edifica-
tion of possible future students of the group.

On the basis of differences in dorsal ornamentation (30-40 small, well-
defined metatergal tubercles in scrutorum, 4-16 longitudinal rugosities in
fracta) and in gonopod structure (median branch of colpocoxite with an
acute subapical projection in scrutorum, lacking in fracta), it is probable
that these two taxa can be distinguished as two distinct species. Differ-
ences in gonopod structure (e.g., lateral colpocoxite branches not caudo-
dorsally deflexed in cocytus, prominently decurved in fracta) as well as
the apparent sympatry of these taxa, suggest that they, too, differ at the
level of species.

On the other hand, the general external similarity of the several popu-
lations to be recognized within fracta, overall concordance in gonopod
structure, and apparent allopatry, suggest that, for the present, subspe-
cific status best expresses the degree of relationship. This estimation
requires future confirmation by field work in the region south and east of
Knoxville to establish whether the present distributional hiatus is real or
illusory. If the former be true, a good case might be made for full specific
status on the grounds of effectual geographic reproductive isolation of
the components.

The distributional pattern shown by fracta (i.e., northwest to southeast
trend across the Tennessee Valley) is paralleled in a number of other
groups. Amongst trechine carabids, which seem to have ecological con-
straints like those of pseudotremias, Barr (1969, 1979) demonstrated sim-
ilar disjunctions in the case of Trechus tennesseensis Barr, the nominate
subspecies of which occurs in a cave in Roane County, Tennessee, and T.
t. tauricus in a cave near the Great Smokies in Blount County. In the
Trechus schwarzi group, T. schwarzi (several subspecies) is restricted to
the southern Blue Ridge, and the closely related vicar, T. cumberlandus,
to the Cumberland Plateau in Tennessee and Kentucky. Barr postulated
that such patterns developed during the Wisconsin glacial period, when
cool or subarctic environments must have been prevalent in the southern
Appalachian region generally.

Pseudotremia fracta fracta Chamberlin, new status

Figs. 1, 5

Pseudotremia fracta Chamberlin 1951:25. Chamerlin & Hoffman 1958:94.
Inmature female holotype (USNM) labeled “Gatlinburg Tenn /
Cove hardwoods / B/ 6-24-47”; a second label has the notation

Milliped Taxonomy and Distribution

139

“SM-145” No collector is given, but the original description states
that material was taken by Hugh Hanson, Arizona State College.
Pseudotremia cottus Shear (in part) 1972:183, figs. 101-109. Male holo-
type (MCZ) from “The Sinks” of Little River, on Tenn. Hy. 73 at
the Blount-Sevier County Line, Tennessee; Leslie Hubricht leg. 25
May 1962. New Synonymy!

Syntelopodite process of gonopods massive (Fig. 5), lateral apices
widely separated, distally curved mesad, extending forward between
medial and lateral branches of colpocoxite; median apex relatively long
and acute. Lateral branch of coxal region notably broad beyond point of
flexure, its outer subterminal divison (x) much larger than inner (y) (Fig.
1). Distal extremities of syntelopodite larger, and curve further anteriad,
than in the other three races of fracta.

The original description of fracta stated the type locality to be “Gatlin-
burg Cove”, obviously a misinterpretation of the collector’s label by
Chamberlin, who was probably unaware of the term “cove hardwoods”
and so transposed some of the words. The specimen apparently came
from the immediate vicinity of Gatlinburg itself. Furthermore, by some
inexplicable error during transcribing of original collector’s field data,
the name “Cades Cove” was added to the permanent label with the holo-
type of P. cottus and was included in citation of the type locality of this
species. Actually The Sinks is about 9 miles northeast of Cades Cove.

Although P.f. fracta is so far unknown from North Carolina it cer-
tainly occurs on the southern slopes of the Great Smokies, since the
specimen that I found at Indian Gap was taken less than 100 meters from
the state line on the Tennessee side. Aside from the type localities of the
two names applied to this race, I have examined the following material
(all at present in my collection):

TENNESSEE: Blount County. — Big Poplar Trail, Cades Cove, 23
May 1962, L. Hubricht; near Gregory’s Cave, Cades Cove, 25 May 1962,
Hubricht. Sevier County. — west side of Indian Gap, 4 August 1958,
R.L. Hoffman; between Gatlinburg and Newfound Gap, 25 May 1962,
Hubricht.

Pseudotremia fracta paynei, new subspecies

Figs. 2, 6

Holotype (5, paratype $ and 2 (RLH) from Norris Quarry Cave No. 1,
1 mi. N of Andersonville, Anderson Co., Tennessee; Jerry A. Payne leg.
29 May 1965. 2$ paratypes (NCSM A2599) From Foster’s Cave No. 1, 2

140

Richard L. Hoffman

Figs. 1-4. Left colpocoxites, anterior aspect, of four subspecies of Pseudotremia
fracta: 1. P.f. fracta Chamberlin, specimen from Cade’s Cove, Tennessee. 2. P.
/. paynei, n. subsp., from holotype. 3. P.f. ingens, n. subsp., from holotype. 4.
P. f. nantahala, n. subsp., from holotype. All drawings made to same scale.
Abbreviations: X, outer division or process of lateral colpocoxite branch; Y,
inner division of same.

Milliped Taxonomy and Distribution 141

mi. N of Clinton, Anderson Co., Tennessee; J. A. Payne leg. 18 July
1965.

Lateral projections of syntelopodite process nearly straight, only a
little longer than the median (Fig. 2); all three extend cephalad between
median branches of colpocoxites, latter similar to those of fracta but the
outer branch distinctly more slender distally and drawn out into a long
narrow blade. (Fig. 6).

Body size slightly less than in fracta and ingens, length of adult males
about 25 mm. Dorsal surface of metaterga nearly smooth, dorsolateral
knobs of segments 3-5 not tilted upward. Ocelli of holotype 19 in four
rows. Coloration grayish-purple, with lighter areolation as in the other
subspecies.

As shown by open circles on the map (Fig. 9), this milliped appears to
be confined to caves and epigean sites along the Clinch River, west and
northwest of Knoxville. Material has been examined from the following
localities (all collections from Anderson County by Jerry A. Payne, for
whom the subspecies is named; all material at present in my personal
collection):

TENNESSEE: Anderson County. — Moore’s Bridge Cave, 2 mi. N
of Clinton, 22 July 1965; Melton Hill Cave No. 1, 5 mi. S of Oak Ridge,
19 May 1965; Bee Hole Cave, 4 mi. N of Clinton, 30 May 1965; Marie’s
Cave, 1 mi. N of Andersonville, 29 May 1965; Wright’s Cave, ca. 2 mi. N
of Clinton, 31 May 1965 and 2 August 1965; Wallace’s Cave, ca. 5 mi. N
of Clinton, 4 April 1965; Markli’s Cave, 4 mi. S of Clinton, 31 May 1965.
Knox County. — Rock Hill Cave, 2 mi. S of Heiskell, 12 June 1965, E.
F. Menhinick. Roane County. — Eblen’s Cave near Kingston, 1 August
1955, S. I. Auerbach; Obed River bluff opposite Harriman, 21 May 1961,
Leslie Hubricht; wooded hillside 1.3 mi. S of Pine Grove, 30 May 1963,
Hubricht.

Pseudotremia fracta ingens, new subspecies

Figs. 3, 7

Holotype $ and paratype $ (RLH) from New Mammoth Cave, ca. 1 1
mi. NW of LaFolette, Campbell County, Tennessee; T. C. Barr leg. 16
September 1979. 2$ and 1$ paratypes (NCSM A3646) from same local-
ity, T. C. Barr and J. R. Holsinger leg. 21 November 1979.

Lateral arms of syntelopodite process long and apically divergent,
median projection rudimentary (Fig. 7); outer branch (solenomerite) of
colpocoxite more slender than in fracta and paynei, its outer subterminal
process (x) much smaller than inner (y); undivided basal region of coxa
smaller than in the other three races owing to a deeper diastemma

142

Richard L. Hoffman

between mesal and ectal branches (Fig. 3).

Holotype about 28 mm long (broken); dorsally grayish-purple, meta-
terga with large pale oval spot on each side; prozona and legs lighter,
nearly white; front of head light brown with four pairs of irregularly-
shaped aerolated spots. Ocelli pigmented, 20 in five rows.

Metazona of anterior segments with prominent lateral knobs formed
by two enlarged ridges, the dorsolateral of which has a seta at front end
and is subtended by a larger oblique ridge with seta at posterior end; on
segments 3-5 the lateral knobs project upward slightly above level of
middorsum, on following segments knobs become progressively smaller
and are not present on segments 25-29. Ornamentation of metaterga
greatly reduced, middorsal region smooth, a few indistinct elongated
tubercles occur near base of dorsolateral ridge.

Figs. 5-8. Syntelopodite process of four subspecies of Pseudotremia fracta,
ventral aspect, with lateral lobes of syntelopodite also shown: 5. P.f. fracta
Chamberlin, specimen from Cade’s Cove, Tennessee. 6. P.f. paynei, n. subsp.,
from holotype. 7. P.f. ingens, n. subsp., from holotype. 8. P.f. nantahala, n.
subsp., from holotype. All drawings made to same scale.

Milliped Taxonomy and Distribution

143

This subspecies is known so far only from the type locality, to which
the name alludes. Collections from the region between this cave and the
type locality of P. scrutorum (northern Scott County, Tennessee) would
be of considerable interest in providing information on the taxonomic
status of these two taxa vis-a-vis each other.

Fig. 9. Eastern Tennessee and extreme western North Carolina, showing known
localities for several taxa of Pseudotremia: inverted triangle, P. scrutorum
Shear; dot with star, P.f. ingens, n. subsp.; open circles, P.f. paynei, n. subsp.;
solid dots, P.f. fracta Chamberlin; circle with dot, P.f. nantahala, n. subsp.
Eastern and western boundaries of the Ridge and Valley Physiographic Province
are indicated by the two broken lines.

Pseudotremia fracta nantahala, new subspecies

Figs. 4, 8

Holotype $ (NCSM A2528) from Blowing Springs Cave near
Nantahala, Swain Co., North Carolina; S. Platania, P. Hertl, and C. O.
Holler leg. 18 March 1979.

Mesal and ectal branches of colpocoxites separated by a distinctly
U-shaped diastemma, subterminal projection of ectal branch relatively
small (Fig. 4); syntelopodite process with stout pedicel, lateral projections

144

Richard L. Hoffman

straight, subparallel, extending between branches of colpocoxites, median
projection short, broad, apically truncate (Fig. 8).

Holotype about 27 mm long (broken), coloration as described for P.f.
ingens, ocelli pigmented, 21 in five rows. Dorsolateral knobs of anterior
segments less prominent than in the other three races, and not elevated.
Metaterga of most segments with two low but distinct convexities
between median suture and dorsolaterial ridges, surface of these areas
distinctly coriaceous in contrast to the nearly smooth metaterga of other
subspecies.

Aside from the holotype, I have examined a female (NCSM A2598)
from Cliff Ridge near Blowing Springs, 3.3 mi. NE of Nantahala, Swain
County, North Carolina; L. Hubricht leg. 16 May 1961. This specimen
had been identified by Dr. Shear as P. cottus but was not cited in his
monograph (possibly because of the usual uncertainty in the identifica-
tion of single females). It is probably from the immediate vicinity of the
type locality.

ACKNOWLEDGMENTS. — My sincerest thanks are expressed to
Dr. Thomas C. Barr, Jr., Dr. Jerry A. Payne, and Mr. Leslie Hubricht
for presenting me with most of the material upon which this paper is
based. Dr. Rowland M. Shelley kindly loaned the specimens of P. /.
nantahala and allowed me to describe it. Dr. Shelley and Dr. J. E.
Cooper performed much-appreciated service in removing numerous
rough places from the manuscript.

LITERATURE CITED

Barr, Thomas C., Jr. 1969. Evolution of the Carabidae (Coleoptera) in the
southern Appalachians, pp. 67-92 m P. C. Holt (ed.). The distributional history
lof the biota of the southern Appalachians, Part 1: Invertebrates. Res. Div.
Monogr, 1, Va. Polytech. Inst., Blacksburg. 295 pp.

. 1979. Revision of Appalachian Trechus (ColeopteraiCarabidae).

Brimleyana 2:29-75.

Chamberlin, Ralph V. 1951. On eight new southern millipeds. Great Basin Nat.
77:19-26.

^ and Richard L. Hoffman. 1958. Checklist of the millipeds of North

America. Bull. U. S. Natl. Mus 272:1-236.

Cope, Edward D. 1869. Synopsis of the extinct Mammalia of the cave formations
in the United States, with observations on some Myriapoda found in and near
the same, and on some extinct mammals of the caves of Anguilla, W. I., and
other localities. Proc. Amer. Philos. Soc. 77:171-192.

Ribaut, Henri. 1920. Notes sur les Chordeumoides de France. Bull. Soc. Hist,
nat. Toulouse 45:18-34.

Shear, William A. 1972. Studies in the milliped order Chordeumida (Diplo-
poda): A revision of the family Cleidogonidae and a reclassification of the
order Chordeumida in the New World. Bull. Mus. Comp. Zool. 744:151-352.

Accepted 16 March 1981

Reptiles and Amphibians of
Kiawah and Capers Islands, South Carolina

J. Whitfield Gibbons
Savannah River Ecology Laboratory,

Drawer E, Aiken, South Carolina 29801

AND

Julian R. Harrison, III
Department of Biology,

College of Charleston, Charleston, South Carolina 29401

ABSTRACT. — We obtained information on abundance, species com-
position, distribution among habitats, and general ecology of the rep-
tiles and amphibians of two South Carolina barrier islands, Kiawah and
Capers. The herpetofauna of the islands is greatly reduced compared
with that of the adjacent mainland. Kiawah Island has 16% of the
mainland’s amphibian species and 43% of the reptile species; Capers
Island has only 10% of the amphibian species and 21% of the reptiles.
All herpetofaunal species found on Capers occur on Kiawah. The rela-
tionship between island size and species numbers on each island is sim-
ilar to that reported for other Atlantic Coast barrier islands. Recom-
mendations are given for minimizing the environmental impacts on
reptiles and amphibians in future recreational development of these or
any barrier islands.

INTRODUCTION

Many coastal islands of the Carolinas and Georgia are being developed
for recreational and other purposes. The potential environmental impact
of such endeavors is great and has generated concern for how these
activities affect certain elements of the fauna and flora. The objective of
our studies was to obtain information on abundance, distribution, species
composition, and general ecology of the reptiles and amphibians of two
barrier islands along the South Carolina coast. Our purpose was to reveal
the environmental alterations that must be considered if the impact of
development on the herpetofaunal populations is to be minimized.

Field studies were conducted on Kiawah and Capers islands during
spring and summer of 1978 and 1979. These studies complemented earlier
herpetological research on Capers Island during summer and fall of 1975
and on Kiawah Island from spring of 1974 through fall of 1975 (Gibbons
and Coker 1978).

Barrier Islands

Barrier islands occur along 10 to 13 percent of the coastlines of the
world (Cromwell 1971). In the United States they margin the entire
Atlantic coast from Florida to Canada, and the northern Gulf of Mexico.

Brimleyana No. 5:145-162. July 1981.

145

146

J. Whitfield Gibbons and Julian R. Harrison III

They are generally of low elevation and parallel the mainland, from
which they are separated by salt marsh or, in some instances, by open
water. Sand or gravel is the predominant soil texture. Most geologists
consider the Atlantic barrier islands of the United States to be Holocene
in origin, probably formed within the last 6,000 years.

Several theories have been proposed to explain the origin of barrier
islands. Among these, the emergence of offshore bars (Leont’yev and
Nikiforov 1965; Otvos 1970), the submergence of coastal ridges (Hoyt
1967, 1968), and the isolation of sandspits (Fisher 1968), have been the
most prominent. The most appealing theory is that of Schwartz (1971)
who compromised by suggesting that a combination and interaction of
all three processes was the most suitable overall explanation. However,
he indicated that one mode of development or another might be more
prevalent in a particular situation or locality.

On the southeastern Atlantic coast, those barrier islands with ocean-
facing beaches and large enough to support terrestrial vertebrates have
certain characteristics in common. Among these are a sand dune complex
beginning above the high tide mark. The dune system is frequently mar-
gined by a hardwood thicket of shrubs and trees stunted by continual salt
spray. Plant communities of the island interiors are generally a combina-
tion of hardwoods, palmettos and pines although the composition of a
particular forest is the consequence of soil, climate, and recent historical
events. One apparent characteristic of the southern barrier islands is that
most woody species are evergreen. Fresh water may be abundant on some
islands, absent on others. Even the largest freshwater lakes, however,
have the potential of completely drying up during long periods of
drought. Extensive salt marshes frequently make up the landward
borders of the islands, which are then further separated from the main-
land by brackish or salt water. This may take the form of tidal creeks or,
in some cases, a major sound.

A common threat to the ecological integrity of all barrier islands of the
United States is the impact of development and other human activities
(Dolan et al. 1973). Nonetheless, thorough studies of the flora and fauna
of these unique habitats have lagged far behind those of other natural
environments. The limited knowledge available about the reptiles and
amphibians of the barrier islands of the Gulf and Atlantic coasts was
compiled by Gibbons and Coker (1978). Despite the great abundance and
diversity of reptiles and amphibians in the Southeast (Conant 1975; Mar-
tof et al. 1980), a clear need exists for documentation of the ecology of
these animals in the fast-disappearing natural habitats of barrier islands.

The Study Areas

The islands are located 19 km south (Kiawah) and 22 km north (Cap-
ers) of Charleston (80‘^02'W, 32°54'N), Charleston County, South

Barrier Island Herpetofauna

147

Carolina. Kiawah Island consists of approximately 3200 ha, half of which

«

is an extensive salt marsh. Major habitats besides the salt marsh include a
12 km ocean-facing beach and dune system, and maritime thickets and
forests that form most of the island’s interior. The maritime thickets are
characterized by closely spaced vegetation, predominantly stunted live
oaks, Quercus virginiana; yaupon holly. Ilex vomitoria\ and wax myrtle,
Myrica cerifera. The interior forests are combinations of pines, Pinus sp.;
oaks, Quercus sp.; magnolia. Magnolia grandiflora; and palmettos, Sabal
sp..

About a dozen brackish and freshwater lakes that are not under tidal
influence occur on Kiawah. They range in salinity from 0 ppt to about 17
ppt depending upon their location on the island and upon recent rainfall.
These lakes total approximately 80 ha and in most cases represent
impounded salt marshes. In addition, many low-lying areas become
flooded during wet parts of the year, creating small, shallow freshwater
habitats throughout much of the forested parts of the island. Of major
influence on Kiawah Island is the recreational development complex and
resort located at the southwest end. This system of cottages, golf courses,
and blacktop roads composed more than 10% of the island by 1979.

Capers Island consists of about 900 ha, of which approximately 47% is
salt marsh. Beach frontage on Capers is 5.3 km, much of which is com-
posed of a short, ocean-facing beach with standing dead trees exposed
only at low tide. Erosion of the beach and marsh margins has increased in
recent years and has altered the size and configuration of impoundment
areas. The island vegetation is generally similar to that of Kiawah Island,
although the maritime thicket community is greatly reduced in extent.
Only one small, freshwater pond, Greene Pond, is believed to have con-
tained water continually throughout the study period. This pond, located
at the south end of the island, is less than 0. 1 ha in area. An extensive
brackish-water impoundment system is also present on the south end of
the island. One arm of this impoundment, a large, isolated freshwater
pond in earlier years, has been breached by surf erosion. Numerous
ditches and low-lying areas throughout the island contain water during
early spring and midsummer wet periods.

The climate of both Kiawah and Capers Islands is classed as subtropi-
cal. Temperatures fall below freezing on fewer than 20 days during the
winter (Kjerfve 1974). Mean summer (July) temperatures are 21.5° C min-
imum and 31.5° C maximum. Mean winter (January) temperatures are
2.8° C minimum and 15.5° C maximum. Both islands receive approxi-
mately 125 cm of rain a year.

METHODS

Field collecting techniques were diversified, since our objective was to

148

J. Whitfield Gibbons and Julian R. Harrison III

document the presence and abundance of as many species of reptiles and
amphibians as possible. Baited hoop nets, drift fences with pitfall traps
(Gibbons and Bennett 1974), seining, road collecting, muddling in aqua-
tic areas, and general collecting were the most extensively used methods.
Visual counts were made of alligators. Alligator mississippiensis, on the
various lakes during both day and night. Records were kept of road-
killed amphibians and reptiles on Kiawah, and of those reported or
brought in by residents or workers on either island. Quantitative data
were collected in four ways: 1) 50-foot drift fences, with perpendicular
fencing at each end, and pitfall traps; 2) visual counts of alligators; 3)
equal-effort visual censuses along transects, corresponding to vegeta-
tional analysis transects used by Gaddy (in preparation); each transect
was walked by a single investigator who noted all reptiles or amphibians
seen or heard during a one hour period; and 4) mark-release-recapture
sampling of turtles in Greene Pond. Each of these methods and their
results will be discussed separately below.

RESULTS AND DISCUSSION

A total of 31 species of reptiles (24) and amphibians (7) are known to
occur on Kiawah and Capers islands (Tables 1 and 2). These represent 20

Table 1. Cumulative summary of reptiles and amphibians from Kiawah and
Capers Islands compared to mainland occurrences; excludes Caretta
and Malaclemys. Species names are given in Table 2.

Mainland Only

Kiawah

Capers

Reptiles

Families

1

9

8

Genera

17

20

11

Species

32

24

11

Amphibians

Families

5

6

3

Genera

13

6

3

Species

36

7

4

All Herps

Families

6

15

11

Genera

30

26

14

Species

68

31

15

Barrier Island Herpetofauna

149

Table 2. Reptiles and amphibians documented from Kiawah and Capers Island,
South Carolina. Species names used are those given by Conant (1975).

Species Both Kiawah

Islands Only

Amphibia

Anura

Bufonidae

Bufo terrestris. Southern Toad X

Hylidae

Hyla cinerea. Green Tree Frog X

Hyla squirella. Squirrel Tree Frog X

Microhylidae

Gastrophryne carolinensis. Narrow-mouthed Toad X

Pelobatidae

Scaphiopus holbrooki, Spadefoot Toad X

Ranidae

Rana utricularia

(= pipiens or sphenocephala). Leopard Frog X

Caudata

Plethodontidae

Plethodon glutinosus , Slimy Salamander X

Reptilia

Chelonia

Emydidae

Malaclemys terrapin. Diamond-back Terrapin

Pseudemys scripta. Yellow-bellied Turtle X

Terrapene Carolina, Box Turtle X

Kinosternidae

Kinosternon subrubrum. Mud Turtle X

Cheloniidae

Caretta caretta. Loggerhead Sea Turtle *

Lacertilia

Anguidae

Ophisaurus ventralis. Common Glass Lizard X

Iguanidae

Anolis carolinensis, Carolina Anole X

Scincidae

Scincella laterale. Ground Skink X

Eumeces laticeps. Broad-headed Skink **

Eumeces inexpectatus. Southeastern Five-lined Skink X
Teiidae

Cnemidophorus sexlineatus. Six-lined Racerunner X

150

J. Whitfield Gibbons and Julian R. Harrison III

Species Both Kiawah

Islands Only

Serpentes

Colubridae

Natrix fasciata. Banded Water Snake X

Thamnophis sauritus. Ribbon Snake X

Thamnophis sirtalis. Garter Snake X

Coluber constrictor. Black Racer X

Masticophis flagellum, Coachwhip X

Lampropeltis getulus. Chain Kingsnake X

Opheodrys aestivus. Rough Green Snake X

Elaphe obsoleta. Rat Snake, Chicken Snake X

Elaphe guttata. Corn Snake X

Tantilla coronata. Crowned Snake X

Cemophora coccinea. Scarlet Snake X

Viperidae

Agkistrodon contortrix. Copperhead X

Agkistrodon piscivorus, Cottonmouth X

Crotalus horridus, Canebrake Rattlesnake X

Crocodilia

Crocodilidae

Alligator mississippiensis , American Alligator X

*Marine or estuarine species known or suspected to nest on both islands.

**Eumeces laticeps occurs on Kiawah; some of the skinks observed but not
captured on Capers may have been this species.

genera and 9 families of reptiles and 6 genera and 6 families of amphibi-
ans (Table 2). With the possible exception of Chelydra serpentina, all
species found on Capers (11 reptiles, 4 amphibians) have also been
reported on Kiawah. (A specimen of C. serpentina was reported on the
south end of Capers Island by David Chamberlain and L. L. Gaddy, but
has not been seen by the authors.)

Barrier islands of the Atlantic (Lewis 1946; Engels 1942, 1952; Quay
1959; Martof 1963; Parnell and Adams 1970; Lee 1972; Johnson et al.
1974; Hillestad et al. 1975) and Gulf (Jackson and Jackson 1970; Blaney
1971) coasts generally have a greatly reduced herpetofauna compared
with that of the adjacent mainland (Gibbons and Coker 1978). Kiawah
has 16% and Capers 10% of the mainland’s amphibian species. Mainland
reptiles are better represented than amphibians on both islands, with
Kiawah having 43% and Capers 21%. The abundance of reptiles and
amphibians on the islands is in accord with what would be predicted from
the amount of woodland area available for habitation by these groups of

Barrier Island Herpetofauna

151

animals (Gibbons and Coker 1978). For example, the data points show-
ing the relationship between woodland area and number of species on the
two islands fall along the same regression lines generated by similar data
from eight other islands (Fig. 1).

Fig. 1. Relationship between woodland area (based on standard topographic
maps) habitable by reptiles and amphibians and actual number of species
present. Linear regression equations based on nine Atlantic Coast barrier
islands, including Kiawah, are highly significant as reported in Gibbons and
Coker (1978). Capers Island data points fall near predicted regression lines.

152

J. Whitfield Gibbons and Julian R. Harrison III

Because of its smaller land area, Capers Island would be expected to
have fewer species of reptiles and amphibians than Kiawah (MacArthur
and Wilson 1967). In addition, Capers has significantly more open water
and salt marsh (~2 km; approximately twice the distance for Kiawah)
between the island and the mainland. Greater distances from the main-
land tend to result in lower numbers of species for oceanic islands
(MacArthur and Wilson 1967); however, the factor of distance from the
mainland has not yet been evaluated in assessing faunal composition of
barrier islands. No endemic species of reptile or amphibian has been
reported for any North American barrier island (Gibbons and Coker
1978).

The variety of methods used to collect reptiles and amphibians necessi-
tates separate consideration of results obtained. The most meaningful
approach is to compare results on the two islands by each method.

Drift Fences

Collections from the four drift fence and pitfall trap areas on the two
islands revealed certain characteristics about the herpetofauna, primarily
in regard to the occurrence of anurans (Table 3). Speculations about
relative abundance of the species should be conservative at this time
because of the high variability in trapping success between dates and
locations.

Gastrophryne carolinensis appears to be a consistent forest floor
inhabitant on both islands and is active throughout the summer. Rana
utricularia also ventures into the terrestrial environments on occasion, as
seen by the sporadic captures, primarily of subadults. Scaphiopus hol-
brooki juveniles were the most abundant anurans in the pitfall traps in
every month sampled. The absence of S. holbrooki and Bufo terrestris
from the Capers Island traps strongly supports our conviction that these
species occur only on Kiawah. The absence of Hyla in the traps, although
two species occur on both islands, is a consequence of sampling bias;
pitfall traps are not effective in capturing tree frogs (Gibbons and Bennett
1974). The Capers Island pitfall traps caught the only Kinosternon sub-
rubrum confirmed from this island.

Transects

Three transects established as part of an interdisciplinary study which
included the two islands were used in the herpetofaunal studies. Walking
trips were taken along each transect, and all reptiles and amphibians seen
or heard were noted (Table 4). No new species were recorded as a result
of this method, but a comparison could be made of the animals between
islands and among locations on an island.

The lowest numbers of reptiles and amphibians on Kiawah were

Table 3. Drift fence captures of anurans on Kiawah and Capers Islands during summer 1979 (June 23-September 30). Transect
numbers refer to those used by L. L, Gaddy (in prep.) in vegetational analyses on Capers Islands. Y refers to fence at
Yellowlegs Marsh on Kiawah Island. Number in parentheses indicates number of trap checks during month. Other
numbers indicate individuals of species caught on consecutive trap checks during month indicated.

Barrier Island Herpetofauna

153

Dd

W

PQ

U

H

CU

u

c/3

H

c/3

D

O

D

<

m o

o o

O

00 o

00

<N O

T3

T3

T3

<U

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c/3

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o

o

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u

U

(U

lU

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o

o

o

c

c

c

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<u

<u

Uh

pH

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oo o o

o o

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>-

P

oo es

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<N O ^

« mo

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mm

1-M 1-^

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oo

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1-H

-*->

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cd

U

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c

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W

u-i \D

fN

>0

O

o o

o

VO

r-

m

4;

V) o

Z

P

VO

oo

IT)

H

U

P

c/3

Z

<

Od

73

73

73

^ ^

- o

^ ^

- ^ ^

^ o

^

H

H

H

H

H

H

U-l

ccj

c/3

l->

-C

03

c/3

Ih

J3

cd

c/3

Ui

<

cd

(U

Cu

cd

(U

O,

cd

(U

O,

p

cd

cd

cd

c/3

U

U

U

x:

cd

cd

03

P

Oh

03

>3

03

c

c

o

*3

<3

-2

3

3

Qd

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o

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"o

03

03

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03

Capers None caught Fence Closed

154

J. Whitfield Gibbons and Julian R. Harrison III

Table 4. Numbers of reptiles and amphibians seen or heard during timed trips
along established transects (see text).

TRANSECT

TOTAL

TOTAL EXCLUDING
TURTLES AND ALLIGATORS

Species

Individuals

Species

Individuals

No.

No./ Hr.

No.

No./ Hr.

KIAWAH

1

(Develop-
ed Area)

10

16

2.3

7

8

1.2

2

10

75

11.5

10

75

11.5

3

13

>200

>25

12

>200

>25

CAPERS

1

6

123

22.4

4

19

3.5

2

7

23

6.6

7

23

6.6

3

8

>50

>10

7

>50

>10

observed in the developed section (Table 4). Although the number of
species noted was not appreciably different from that along the other
transects, the reduction in relative abundance of individuals was signifi-
cant. Ten to twenty times as many individuals of terrestrial species (aquat-
ic turtles and alligators excluded) were seen in an equivalent collecting
time in the forested parts of the island compared with the developed area.

The contrast among different areas on Capers Island is less than that
on Kiawah. However, fewer species and individuals were present along
the two forested transects than on the transect that crossed the major dike
complex on the south end of Caper’s Island. The diversity of habitats
crossed by this transect presumably accounts for the increase in numbers
of species and individuals.

The forested areas of Kiawah Island clearly have a higher species diver-
sity and relative density of individuals on the basis of these comparisons
than do the woodlands of Capers Island. However, even the poorest
transect on Capers Island yielded higher numbers of animals observed
per hour than did the developed part of Kiawah.

Alligator Counts

Daytime and nighttime visual counts were made of alligators on both
islands (Table 5). Alligators occur in high densities in most freshwater
and some brackish habitats on both Kiawah and Capers islands. Except
for the presumed absence of large alligators in Sparrow Pond, now part

Barrier Island Herpetofauna

155

Table 5. Alligator counts on
night observations.

Kiawah and Capers Islands;

combined day and

Aquatic Habitat

KIAWAH ISLAND

Minimum Number Known Present

1974-75

1979

Sparrow Pond

2 adults

2 juveniles

Canals in developed areas

no canals present

2

Bufflehead Pond

15

6

Pintail Pond

21

0

Egret Pond

2

-

Blue Heron Pond

14 juveniles

1

Canvasback Pond

-

15

Miscellaneous, unnamed

~20

~10

aquatic habitats

TOTAL

~64*

~36*

Greene Pond

CAPERS ISLAND

1 adult.

Caper’s Lake

6 juveniles

15 adults

South Lagoon

0

Salt Marsh

1

TOTAL (minimal estimate)

23

♦The reduced number observed in 1979 should not be construed as indicative of
overall reduction in number of alligators, since 1974-75 counts were based on
maximum observations accumulated over 2 years

of the Inn-Hotel complex on Kiawah Island, no difference in abundance
was apparent between observations in 1975 and 1979. Bara (1976)
reported sighting 12 alligators on Capers Island during a nighttime count
in August, 1975.

Freshwater Turtle Studies

A unique situation permitted a mark-release-recapture study of the
Pseudemys scripta population occurring in Greene Pond at the south end
of Capers Island. Because the freshwater habitat is restricted, the turtles

156

J. Whitfield Gibbons and Julian R. Harrison III

could be collected by hand, marked, and measured on subsequent trips.
This permitted an estimate of the population size and was an indication
of the demography of P. scripta on Capers Island (Gibbons et al. 1979).
Captures of marked P. scripta during six different months from May
1978 to June 1980 resulted in fairly consistent Lincoln index estimates of
54 to 73 (x=60.7, S.E.=3.05) adult animals. No juveniles were captured.

Mark-rlease-recapture studies were also conducted on Kiawah Island
in 1974-75 (Gibbons and Coker 1978) and in 1978-79. However, few
recaptures were made due to the difficulty of collecting large samples.
This was partly because the many freshwater habitats gave greater oppor-
tunity for dispersal on Kiawah.

Pseudemys scripta from the two islands are characteristically large,
show rapid juvenile growth rates, and have populations primarily made
up of adults (Gibbons and Coker 1978; Gibbons et al. 1979). Turtle
populations on the barrier islands warrant further investigation in an
attempt to understand the ecological and evolutionary significance of
their uniqueness.

Important Species

Although several species of reptiles and amphibians encountered on
Kiawah or Capers Islands were common, certain ones emerged as the
most abundant and apparent forms during the periods of study.

Alligator. — The American Alligator is unquestionably the dominant
reptile on both Kiawah and Capers Islands. Both adult and young indi-
viduals were observed at one time or another in almost every freshwater
habitat on both islands. Nests or recent hatchlings also were observed,
indicating that populations on the islands are reproductively active and
self-perpetuating.

Turtles. — Only one species of freshwater turtle, P. scripta, was
abundant on either island. This species was restricted to aquatic habitats
and was not observed in waters of high salinity. Kinosternon subrubrum
may be present on both islands in greater numbers than our observations
suggest. Some of the few specimens were associated with brackish
marshes, a habitat not intensively sampled during the study period since
on the mainland it is not normally frequented by Kinosternon in this
region of the country.

Lizards. — Of the several species of lizards found on the two islands,
those in the family Scincidae are invariably the most abundant and
apparent in areas having forest litter of any sort. Scincella laterale is
dominant on both islands, especially in forested areas where pine needles
are an important component of the forest floor. However, in ubiquity
and relative abundance, Anolis carolinensis is the dominant arboreal
species. Despite the apparent availability of suitable habitats throughout

Barrier Island Herpetofauna

157

Kiawah Island^ Cnemidophorus sexlineatus was surprisingly scarce. This
lizard is abundant on some barrier islands along the southeastern
Atlantic Coast.

Snakes. — The most apparent snake on Kiawah Island was Thamno-
phis sauritus. On Capers Island, Agkistrodon piscivorus and Coluber
constrictor were the most frequently encountered species. The difficulty
of assessing abundance and population levels of snakes is well known to
herpetologists. Hence other, more secretive, species may be more com-
mon than is apparent.

Salamanders. — Only Plethodon glutinosus was found on Kiawah
Island. It occupies mesic habitats and is locally abundant in certain for-
ested areas. No salamanders were collected on Capers Island although
suitable habitat exists there for P. glutinosus. Salamanders are absent on
many barrier islands, or are represented by only a few species. On the
mainland, salamander activity is greatest during late fall, winter, and
early spring; sampling efforts, which were not made on Capers during
these seasons, might confirm the presence of P. glutinosus .

Frogs and toads. — Almost all of the anuran species on the islands
were very abundant, particularly during periods of heavy rainfall. An
assessment of relative population levels of the different anuran species is
difficult to make due to the large numbers observed of almost every
species at one time or another.

Hyla squirella occupies diverse habitats and is very abundant, as
attested by the very large breeding choruses that develop after heavy
spring or summer rains. It is clearly the most widespread terrestrial spe-
cies on Capers and Kiawah islands. Two species of toads appear to differ
sharply in abundance on Kiawah Island. Scaphiopus holbrooki was
common to abundant, especially in mesic, mixed forests as indicated, for
example, by the drift fence data from transect 3 (Table 4). In contrast,
Bufo terrestris, a common toad on the mainland, occupies similar habi-
tats but was less abundant than S. holbrooki. Since most of the S. hol-
brooki captured were juveniles, a demographically realistic comparison
of abundance is not possible. A third terrestrial anuran, Gastrophryne
carolinensis, is common to abundant in diverse habitats on both islands.
Rana utricularia is the most apparent anuran species in the more stable
aquatic sites; adults are more or less restricted to freshwater marshes and
ponds. Very large breeding choruses of this species develop after heavy
winter and spring rains. Although individuals sometimes occur in
smaller, less stable aquatic sites (ditches, rain-filled depressions, etc.)
throughout both islands, these are often postmetamorphic juveniles or
subadults that may not survive. Rana utricularia shares the larger fresh-
water marshes and ponds with Hyla cinerea, especially those ponds con-
taining cattails or other emergent vegetation. Hyla cinerea is somewhat

158

J. Whitfield Gibbons and Julian R. Harrison III

less terrestrial than H. squirella. Although relatively large breeding cho-
ruses develop on both islands after heavy spring or summer rains, H.
cinerea appears to be much less abundant than H. squirella, especially on
Capers Island and in the developed parts of Kiawah.

Kiawah Island — Before And After

Development of Kiawah Island as a resort community has led to cer-
tain changes in the herpetofauna of the modified areas. Many species
persist in these areas, but their population densities appear to be consid-
erably reduced. Sparrow Pond and associated habitats in the vicinity of
the present hotel complex previously harbored a rich herpetofauna
represented by virtually all of the species known to occur on the island.
With development, the pond was enlarged and deepened and most of the
emergent vegetation removed, either deliberately or as a result of envir-
onmental manipulations. In addition. Sparrow Pond was stocked with
largemouth bass, Micropterus salmoides, and sunfish, Lepomis sp.,
which do not occur naturally on the island. Surrounding habitats were
modified chiefly by clearing understory vegetation, removing surface lit-
ter and some trees, and constructing buildings and roads.

One apparent consequence of these activities is loss of breeding popu-
lations of frogs and toads. While a few species still frequent this area
(Table 4), population densities are extremely low and may represent
recruitment by dispersal from other parts of the island. Often only two or
three individuals are heard calling during or after heavy rains (such as
Hurricane David in September 1979) whereas prior to development such
meteorological conditions triggered choruses involving hundreds of frogs.
Large choruses are still heard in some undeveloped parts of the island.
We found no evidence (e.g. eggs and/or larvae) that any anuran is now
reproducing in the Sparrow Pond area. Failure of reproduction is due at
least in part to the presence of introduced predatory fish. Absence of eggs
may also be attributed to use of insecticides in the general area; the entire
island is treated weekly during the summer months. Insecticides may
affect eggs, larvae, or adults directly, or they may limit population sizes
by reducing available food sources (Hall 1980).

The palmetto forest that previously bordered the northern perimeter of
Sparrow Pond had a large population of P. glutinosus. It is doubtful that
a population persists in the area today, as no individuals were observed
during the recent study period. Removal of organic litter, warmer ground
temperatures resulting from increased insolation, and perhaps use of
insecticides, may explain this species’ absence. Similar considerations
may account for the absence of scincid lizards; none was observed during
the recent study period although three species were abundant earlier.

Thamnophis sauritus and Agkistrodon piscivorus were previously

Barrier Island Herpetofauna

159

common in the grassy areas bordering Sparrow Pond. We saw no T.
sauritus and only one A. piscivorus around Sparrow Pond in 1979.
Absence of T. sauritus may reflect in part the dearth of suitable habitat
and prey, chiefly frogs. Scarcity of A. piscivorus is due in part to selective
removal of this venomous species from the area. Several road-killed
snakes were encountered during the recent study period; prior to the
existence of paved roads and heavier traffic loads such instances were
rare. As development proceeds, the incidence of road-kills will almost
certainly increase, at least until population sizes are appreciably reduced.

Residual turtle and alligator populations remain in Sparrow Pond, but
population densities appear to be low. Drainage operations in the pond
prior to its modification revealed the presence of 50 P. scripta (Tony
Niemeyer, pers. comm.). Small alligators are still present, but larger ones
are removed and translocated to ponds in undeveloped areas.

At least two other ponds on Kiawah Island have been enlarged, deep-
ened, cleared of emergent vegetation, and stocked with freshwater fish.
Both ponds are on the otherwise undeveloped part of the island. Removal
of cattails and other emergent plants from these ponds probably accounts
in part for the apparent reduction in population size of H. cinerea. This
species is often abundant in cattail marshes; its apparent scarcity on
Capers Island may reflect the relative dearth of such habitat on that
island.

Considerations for Recreational Development of Barrier Islands

The greatest potential human disruptions to the herpetofauna of Cap-
ers Island and the undeveloped parts of Kiawah would occur as a result
of major alteration of forests and freshwater ponds. Freshwater habitats
support dense populations of many species. Changes in water level and
salinity, and removal of vegetation and litter, will change the herpeto-
faunal character of the areas.

Drainage of shallow aquatic sites for mosquito control or other pur-
poses would have a severe impact on reproductive efforts of frogs and
toads. Most species of frogs reported from the islands have relatively
short larval periods (90 days or less) and deposit their eggs in small,
rain-filled depressions or in larger, often temporary ponds that lack pred-
atory fishes. Only the mosquitofish, Gambusia affinis, has been
reported to occur naturally in strictly freshwater habitats on Kiawah
Island, and even this species is absent from Capers. Creating permanent
ponds may provide opportunities for establishment of frog species with
longer larval periods and different breeding strategies; however, intro-
duction of freshwater game fishes would create a serious predator impact
on all anurans. Recreational development of ponds inhabited by P.
scripta would probably not directly alter their survival, but population
features such as rapid growth rates and large individuals might be

160

J. Whitfield Gibbons and Julian R. Harrison III

affected.

The most severe impact to terrestrial reptiles and amphibians could
come from removal of essential organic litter and ground cover in the
forest systems. Land clearing or large scale removal of ground cover
could eliminate some species and would completely alter the natural
systems as they now exist. Removal of trees and other forest vegetation
would also make the habitats less desirable for many species. However,
some type of recreational development such as conservative trail con-
struction or small picnic areas and campgrounds, should have minimal
impact on these species. Plethodon glutinosus is a possible exception,
since it is most common in the more elevated mesic forests, areas that are
also the most suitable for picnic areas, campgrounds, and roads. Con-
struction of paved roads will lead to an increase in the incidence of
road-killed vertebrates.

Because of the minimal presence of most species in the open beach, salt
marsh, and dune habitats, changes in these areas will not have a major
effect on the herpetofauna as a whole. However, particular species, such
as Caretta caretta on the beach and Malaclemys terrapin in the marsh,
could suffer unless ecological awareness prevails among those fostering
development of these islands.

ACKNOWLEDGMENTS. — We are indebted to several individuals
who assisted in various phases of field work, including installation of
drift fences. In particular we thank Joe Schubauer, Judy Greene, Garfield
Keaton, Dr. Jan Caldwell, Gary Moran, Brad Gammon, Dr. Bob Ald-
ridge, Steve Bennett, Kent Brown, Lou Ann Brown, Dr. Rebecca Sharitz,
Dave Bennett, Joe McAuliffe, Bob Parmenter, Ray Semlitsch, Vince
DeMarco, Mike McMillan, Linda Whittlesy, Charles Haddock, and
Albert Sanders for their contributions. We thank Robert Jeter and the
Youth Conservation Corps group for providing transportation to Capers
Island and other assistance; and Michael McKenzie and Robert Dunlap
of the S. C. Wildlife and Marine Resources Department for maps and
other information concerning Capers Island, and for use of facilities on
that island. Tony Niemeyer permitted access and provided information
about Kiawah Island. Ray Semlitsch, Rebecca Sharitz and Stephen H.
Bennett critically read the original manuscript, which was also greatly
improved by the comments of two anonymous reviewers.

Support for parts of the research was provided by Contract DE-AC09-
76SR00819 between the U. S. Department of Energy and the University
of Georgia, by the South Carolina Wildlife and Marine Resources
Department, and by a National Science Foundation Grant (DEB-
7904758) to J. W. Gibbons.

Barrier Island Herpetofauna

161

LITERATURE CITED

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Blaney, Richard M. 1971. An annotated check list and biogeographic analysis of
the insular herpetofauna of the Apalachicola region, Florida. Herpetologica,
27:406-430.

Conant, Roger. 1975. A field guide to reptiles and amphibians of eastern and
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Vol., Second Natl. Coastal Shallow Water Res. Conf. 50 pp.

Dolan, Robert, P. J. Godfrey and W. E. Odum. 1973. Man’s impact on the
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Engels, William L. 1942. Vertebrate fauna of North Carolina coastal islands. Am.
Midi. Nat. 25:273-304.

1952. Vertebrate fauna of North Carolina coastal islands. II.

Shackleford Banks. Am. Midi. Nat. 47:702-742.

Fisher, John J. 1968. Barrier island formation: Discussion. Geol. Soc. Am. Bull.
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Gaddy, L. L. 1979. In preparation. Vegetation studies of Kiawah and Capers
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Conservation, and Recreation Service prepared by S. C. Wildl. Mar. Resour.
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Gibbons, J. Whitfield, and D. H. Bennett. 1974. Determination of anuran
terrestrial activity patterns by a drift fence method. Copeia 1974(l):236-243.

, and J. W. Coker. 1978. Herpetofaunal colonization patterns on

Atlantic Coast barrier islands. Am. Midi. Nat. 99:213-233.

, G. H. Keaton, J. P. Schubauer, J. L. Greene, D. H. Bennett, J. R.

McAuliffe and R. R. Sharitz. . 1979. Unusual population size structure in
freshwater turtles on barrier islands. Ga. J. Sci. 57:155-159.

Hall, Russell J., and D. Swineford. 1980. Toxic effects of endrin and toxophene
on the southern leopard frog, Rana sphenocephala. Env. Pollut. Ser. A.
23:53-65.

Hillestad, Hilburn O., J. R. Bozeman, A. S. Johnson, C. W. Berisford and J. I.
Richardson. 1975. The ecology of the Cumberland Island National Seashore,
Camden County, Georgia. Tech. Rep. Ser. No. 75-5 Ga. Mar. Sci. Center. 299

pp.

Hoyt,, James H. 1967. Barrier island formation. Geol. Soc. Am. Bull. 75:1125-
1136.

Hoyt, James H. 1968. Barrier island formation: Reply. Geol. Soc. Am. Bull.
79:947.

Jackson, Crawford G., Jr., and M. M. Jackson. 1970. Herpetofauna of Dauphin.

Island, Alabama. Q. J. Fla. Acad. Sci. 55:281-287.

Johnson, A. Sydney, H. O. Hillestad, S. F. Shanholtzer and G. F. Shanholtzer.
1974. An ecological survey of the coastal region of Georgia. Natl. Park Ser. Sci.
Monogr. Ser. 51-233.

Kjerfve, B. 1974. Climatology. Section C. pp. 1-34 m A preliminary report on the
environmental inventory of Kiawah Island, S. C. Environmental Research
Center, Inc., Columbia.

Lee, David S. 1972. List of the amphibians and reptiles of Assateague Island.
Bull. Md. Herpetol. Soc. 5:90-95

162

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Leont’yev, Oleg K., and L. G. Nikiforov. 1965. Reasons for the world-wide
occurrence of barrier beaches. Oceanology 5:61-67.

Lewis, Thomas H. 1946. Reptiles and amphibians of Smith Island, North
Carolina. Am. Midi. Nat. 56:682-684.

MacArthur, Robert H., and E. O. Wilson. 1967. The theory of island
biogeography. Princeton Univ. Press, Princeton. 203 pp.

Martof, Bernard S. 1963. Some observations on the herpetofauna of Sapelo
Island, Georgia. Herpetologica 79:70-72.

, W. M. Palmer, J. R. Bailey and J. R. Harrison, III. 1980. Amphibians

and reptiles of the Carolinas and Virginia. Univ. North Carolina Press, Chapel
Hill. 264 pp.

McKenzie, Michael. 1975. A conceptual “Use Plan” for Capers Island, Charleston
County, South Carolina. Spec. Rep. No. 1. S. C. Wildl. Mar. Resour. Dep.

Otvos, Ervin G., Jr. 1970. Development and migration of barrier islands.
Northern Gulf of Mexico. Geol. Soc. Am. Bull. 57:241-246.

Parnell, James F., and D. A. Adams. 1970. Smith Island — a resource capability
study — interim report. Wilmington, N.C. 83 pp.

Quay, Thomas L. 1959. The birds, mammals, reptiles and amphibians of Cape
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79:91-94.

Accepted 16 January 1981

163

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Museum’s H. H. Brimley Memorial Library.

Address all subscriptions and requests for information on purchase and
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each.

DATE OF MAILING

Brimleyana No. 4 was mailed on 13 January 1981.

ERRATUM

The following error appeared in Brimleyana No. 4:

Page 162, running head should read: George A. Feldhamer and Joseph A.
Chapman, not Richard F. Collins.

164

TABLE OF CONTENTS
1980

Number 3

Barr, Thomas C., Jr. New species groups of Pseudanophthalmus from the

Central Basin of Tennessee (Coleoptera;Carabidae:Trechinae) 85

Biernbaum, Charles K. Occurrence of the “tramp” terrestrial amphipods
Talitroides alluadi (Chevreux) and T. topitotum (Burt) (Amphipoda: •

Talitridae) in South Carolina 107

Braswell, Alvin L. (see Palmer, William M.) 49

Brown, E. E. Some historical data bearing on the Pine Barrens Treefrog,

Hyla andersoni, in South Carolina 113

Burr, Brooks M. A distributional checklist of the fishes of Kentucky 53

Hedges, S. Blair (see Mitchell, Joseph C.) 119

Laerm, Joshua (see Roth, Janet A.) 1

Lee, David S. (see Robinson, Sarah S.) 43

McMillan, Michael A. (see Semlitsch, Raymond D.) 97

Mitchell, Joseph C. and S. Blair Hedges, Ambystoma mabeei Bishop
(Caudata: Ambystomatidae); an addition to the salamander fauna of

Virginia 119

Maurakis, Eugene G. (see Burkhead, Noel M.) 75

Meyers, Joseph M. (see Laerm, Joshua) 47

Nagel, Jerry W. Life History of the Mottled sculpin, Cottus bairdi, in

northeastern Tennessee (Osteichthyes:Cottidae) 115

Redmond, William H. Notes on the distribution and ecology of the
Black Mountain Dusky Salamander Desmognathus welteri Barbour

(Amphibia: Plethodontidae) in Tennessee 123

Robison, Henry W. (see Williams, James D.) 149

Rossman, Douglas A. and Robert L. Erwin. Geographic variation in the
snake Storeria occipitomaculata (Storer) (Serpentes:Colubridae) in

southeastern United States 95

Shelley, Rowland M. (see Filka, Marianne E.) 1

Vitt, Laurie J. (see Laerm, Joshua) 47

Williams, James D. and Henry W. Robison, Ozarka, a new subgenus of

Etheostoma (Pisces: Percidae) 149

Wiseman, Jeffrey S. (see Gooch, James L.) 133

Palmer, William M. and Alvin L. Braswell. Additional records of albinistic

amphibians and reptiles from North Carolina 49

Robinson, Sarah S. and David S. Lee. Recent range expansion of the
Groundhog, Marmota monax, in the Southeast (Mammalia:

Rodentia) 43

Roth, Janet A. and Joshua Laerm. A late Pleistocene vertebrate assemblage

165

from Edisto Island, South Carolina 1

Semlitsch, Raymond D. and Michael A. McMillan. Breeding migrations,
population size structure, and reproduction of the Dwarf Salamander,

Eurycea quadridigitata, in South Carolina 97

Shelley, Rowland M. The status of Cleoptoria shelfordi Loomis, with the
proposal of a new genus in the milliped family Xystodesmidae
(Polydesmida) 31

Number 4

Ashton, Ray E., Jr., Alvin L. Braswell and Sheldon I. Guttman. Electro-
phoretic analysis of three species of Necturus (Amphibia: Proteidae), and

the taxonomic status of Necturus lewisi (Brimley) 43

Braswell, Alvin L. (see Ashton, Ray E., Jr.) 43

Burkhead, Noel M., Robert E. Jenkins and Eugene G. Maurakis. New
records, distribution and diagnostic characters of Virginia ictalurid

catfishes with an adnexed adipose fin 75

Chapman, Joseph A. (see Feldhamer, George A.) 161

Collins, Richard F. Stomach contents of some snakes from eastern and

central North Carolina 157

Culver, David C. and Timothy J. Ehlinger. Effects of microhabitat size

and competitor size on two cave isopods 103

Ehlinger, Timothy J. (see Culver, David C.) 103

Erwin, Robert L. (see Rossman, Douglas A.) 95

Feldhamer, George A. and Joseph A. Chapman. Mandibular dental

anomaly in Whitetailed deer 161

Filka, Marianne E. and Rowland M. Shelley. The milliped fauna of the

Kings Mountain region of North Carolina (ArthropodaiDiplopoda) 1

Freeman, B. J. (see Laerm, Joshua) 47

Gooch, James L. and Jeffrey S. Wiseman. Morphological and habitat

variability in Gammarus minus Say (AmphipodaiGammaridae) 133

Guttman, Sheldon I. (see Ashton, Ray E., Jr.) 43

Jenkins, Robert E. (see Burkhead, Noel M.) 75

Laerm, Joshua, B. J. Freeman, Laurie J. Vitt, Joseph M. Meyers and

Lloyd Logan. Vertebrates of the Okefenokee Swamp 47

Logan, Lloyd (see Laerm, Joshua) 47

166

INDEX TO SCIENTIFIC NAMES

(New names in italics)

Numbers 3: and 4: (1980)

New Names

Brevigonus shelfordi 3:31-42 Pseudanophthalmus inquisitor 3:94-95

(Ozarka) [Etheostoma] 4:149-156 Pseudanopthalmus productus 3:91-92

Pseudanopthalmus fowlerae 3:88-89 Pseudanopthalmus simplex 3:86-88

Abacion magnum 4:6,9,20,21,32,33,
34,35,36,37

Acantharcus pomotis 4:52
Accipiter
cooperii 4:61
striatus 4:61
Acer rubrum 3:121;4:48
Acipenser fulvescens 3:57
Acris gryllus dorsalis 4:54
Actitis macularia 4:61
Agelaius phoeniceus 4:65
Agkistrodon
contortrix 4:157,158
contortrix 4: 158
piscivorus 4: 159
conanti 4:57
leucostoma 4:157
piscivorus 4:157,158,159
Aimophila aestivalis 4:65
Aix sponsa 4:60
Ajaia ajaja 4:60
Alligator 3:1 1,22,23

mississippiensis 3:5,8, 10;4:56,71
Alosa

alabamae 3:55,61
chrysochloris 3:61
Ambloplites rupestris 3:73
Amblyopsis spelaea 3:71
Ambystoma
cingulatum 4:55
mabeei 3:1 19-121
maculatum 3:44

opacum 4:55
talpoideum 3:50,101;4:55
tigrinum 3:1 13;4:55

Amia calva 3:58;4:51
Ammocrypta 4:149
asprella 3:55,74
Clara 3:55,75
pellucida 3:75
vivax 3:55,75
Ammodramus
henslowii 4:65
savannarum 4:65
Ammospiza leconteii 4:65
Amphiuma means 3:49;4:55
Anas

acuta 4:60
americana 4:60
clypeata 4:60
crecca 4:60
discors 4:60
penelope 4:60
platyrhynchos 4:60
rubripes 4:60
strepera 4:60

Andrognathus corticarius 4:6,8,10,11,
33,34,35,36,37
Andropogon virginicus 4:48
Anguilla rostrata 3:61;4:51
Aniulus orientalis 4:13
Anhinga anhinga 4:59
Anolis carolinensis 4:56
Anthus spinoletta 4:64

167

Apheloria tigana 4:37
Aphredoderus sayanus 3:71;4:52
Aplodinotus grunniens 3:80
Aquila chrysaetos 4:61
Aramus guarauna 4:61

Archilochus colubris 4:62
Arcitalitrus sylvaticus 3:109
Ardea herodias 4:60
Armadillium sp. 3:108
Arundinaria spp. 3:121
Auturus

erythropygos 4:8,9,25-26,27,32,33,

34.35.36.37
georgianus 4:26

Aytha
affinis 4:60
americana 4:60
collaris 4:60
marila 4:60
valisineria 4:60

Bipalium sp. 3:108
Bison 3:23

antiquus 3:6,8,20,21,24
bison 3:21

Blarina carolinensis 4:68
Bombycilla cedrorum 4:64
Boraria stricta 4:8,9,26,27-28,32,33,

34,35,36,37,39,40
Boreostracon floridanus 3:12
Brachyiulus lusitanus 4:7,8,12,32,33,

35.36.37
pusillus 4: 12

Branneria carinata 4:38
Branta canadensis 4:60
Brevigonus 3:31-42
shelfordi 3:32-42
Botaurus lentiginosus 4:60
Bubo virginianus 4:62
Bubulcus ibis 4:60
Bucephala
albeola 4:60
clangula 4:60

Bufo

quericus 4:54
terrestris 4:54

woodhousei fowleri 3;50;4:158
Buteo

jamaicensis 4:61
lagopus 4:61
lineatus 4:61
platypterus 4:61
Butorides striatus 4:60

Caecidotea
cannulus 4:103-1 13
holsingeri 4:103-1 13
Caiman sclerops 4:56
Calidris
alba 4:62
alpina 4:62
mauri 4:62
pusillus 4:62
Callitriche 4:153

Cambala annulata 4:6,9,21,22,32,33,

34,35,36,37

Camellia japonica 3:108
Campephilus principalis 4:63,71
Campostoma
anomalum 3:62
oligolepis 3:80
Canis 3:23
dims 3:6,8,14,15,24
lupus 3: 15
rufus niger 4:67,70
Capella gallinago 4:61
Capreolus capreolus 4:162
Caprimulgus
carolinensis 4:62
vociferus 3:44;4:62
Carassius auratus 3:62
Cardinalis cardinalis 4:65
Carduelis
pinus 4:65
tristis 4:65
Carex 4:48

168

Carphophis amoenus amoenus 3:51
Carpiodes
carpio 3:68
cyprinus 3:68
velifer 3:68

Carpodacus purpureus 4:65
Carya

illinoensis 3:108
sp. 3:108

Casmerodius albus 4:60
Castor 3:22

canadensis 3:5,8, 14;4:67
carolinensis 4:69
Castoroides 3:22,23
ohioensis 3:5,8,13,14
Cathartes aura 4:60
Catharus
fuscescens 4:64
guttata 4:64
minima 4:64
ustulata 4:64

Catoptrophorus semipalmatus 4:61
Catostomus commersoni 3:68
Cemophora
coccinea 3:49,1 13
copei 4:56

Centrarchus macropterus 3:73;4:52
Certhia familiaris 4:63
Chaetura pelagica 4:62
Charadrius
semipalmatus 4:61
vociferus 4:61
Chelydra 3:22
serpentina 3:4,7,8;4:158
serpentina 3:50;4:57
Chen caerulescens 4:60
Chlamytherium 3:23
Chlidonias niger 4:62
Chologaster agassizi 3:71
Chordeiles minor 4:62
Chondestes grammacus 4:65
Chrysemys 3:22
concinna 3:7,8

floridana 3:5,7,8
nelsoni 4:57

scripta petrolei 3:5,7,8,24
Circus cyaneus 4:61
Cistothorus
palustris 4:63
platensis 4:63
Cleidogona
caesioannulata 4:38
medialis 4:6,8,14-15,33,34,35,36,
37,39
Cleptoria
abbotti 3:39
shelfordi 3:31-42
Clethra alnifolia 4:48
Clinostomus
elongatus 3:55,62
funduloides 3:63

Cnemidophorus sexlineatus sexlin
eatus 4:56
Coccyzus
americanus 4:62
erythropthalmus 4:62
Colaptes auratus 4:62
Colinus virginianus 4:61
Coluber

constrictor priapus 4:56
sp. 3:5,8,10

Columbina passerina 4:62
Condylura
cristata 4:67
cristata 4:68
Contopus virens 4:63
Coragyps atratus 4:60
Corvus

brachyrhynchos 4:63
ossifragus 4:63
Cottus

bairdi 3:72;4:1 15-121
bairdi 4:120
kumleini 4:120
carolinae 3:72

Coturnicops noveboracensis 4:61

169

Crangonyx antennatus 4: 1 1 1 , 1 33, 1 45
Croatania catawba 4:7,9,26,28,29,30,33,

34.35.36.38.39
Crocodylus acutus 3:11
Crotalus

adamanteus 4:57
horridus 3:49
atricaudatus 4:57
Cryptotis
parva 4:67
parva 4:68

Ctenopharyngodon idella 3:63
Cyanocitta cristata 4:63

Cycleptus elongatus 3:68
Cylindroiulus truncorum 4:37
Cyprinus carpio 3:63
Cyrilla racemiflora 4:48

Dasypus 3:23
bellus 3:5,8, 1 1,12,24
novemcinctus 3:12;4:68
mexicanus 4:69

Deirochelys reticularia reticularia 4:57
Delophon
carolinum 4:20

georgianum 4:6,9,20-21,32,33,35,36,

37.38.39

Deltotaria lea 4:7,9,29,30,32,33,34,
35,36,38,39,40
Dendroica
caerulescens 4:64
cerulea 4:64
coronata 4:64
discolor 4:64
dominica 4:64
fusca 4:64
magnolia 4:64
palmarum 4:64
pensylvanica 4:64
petechia 4:64
pinus 4:64
striata 4:64
tigrina 4:64

virens 4:64
Desmognathus

fuscus 4:123,1 25, 1 26, 1 27, 1 28, 1 29, 1 30
auriculatus 4:55
monticola 4: 1 23, 1 25, 1 26, 1 27,
129,130

ochrophaeus 4:125,129
welteri 4:123-131
Diadophis

punctatus punctatus 4:56
ssp. 3:51
Diathera 4:153

Didelphis virginiana pigra 4:68
Dolichonyx oryzivorits 4:65
Dorosoma
cepedianum 3:61
petenense 3:61

Drymarchon corais couperi 4:56,71
Dryocopus pileatus 4:62
Dumetella carolinensis 4:63

Egretta thula 4:60
Elanoides forficatus 4:61
Elaphe
guttata 3:49
guttata 4:56
obsoleta 3:49;4:157
obsoleta 3:52;4:157,158
quadrivittata 4:56,158
spiloides 4:56
sp. 3:5,8,10
Elassoma

evergladei 4:51,52
okefenokee 4:51,52
zonatum 3:73
Empidonax virescens 4:63
Enneacanthus
chaetodon 4:52
gloriosus 4:52
obesus 4:52

Eptesicus fuscus fuscus 4:67,69
Equus 3:23
caballus 3:17

170

sp. 3:6,8,17
Eremotherium 3:23
mirabile 3:5,8,13
Ericymba buccata 3:63
Erimyzon
oblongus 3:68
sucetta 3:68;4:51
Eriobotrya japonica 3:108
Esox

americanus 3:62;4:51
lucius 3:62
masquinongy 3:62
niger 3:62;4:51
Etheostoma 4:149-156
(Ozarka) 4:149-156
asprigene 3:75
atripinne 3:75
barbouri 3:75
boschungi 4:149-156
bellum 3:75
blennioides 3:75
caeruleum 3:75
camurum 3:75
chlorosomum 3:75
cinereum 3:75
cragini 4:149-156
flabellare 3:76
fusiforme 3:76;4:52
gracile 3:76
histrio 3:76
kennicotti 3:76
maculatum 3:76
microlepidum 3:76
microperca 3:55,76
neopterum 3:76
nigrum 3:76
obeyense 3:77
pallididorsum 4:149-156
parvipinne 3:77
proeliare 3:77
punctulatum 4:149-156
rufilineatum 3:77
sagitta 3:77

smithi 3:77
sp. 3:78
spectabile 3:77
squamiceps 3:77
stigmaeum 3:77
swaini 3:77
tippecanoe 3:77
trisella 4:149-156
variatum 3:78
virgatum 3:78
zonale 3:78
Eudocimus albus 4:60
Eumeces

egregius similis 4:56
fasciatus 4:56
inexpectatus 4:56
laticeps 4:56
Eupatorium sp. 3:98
Euphagus
carolinus 4:65
cyanocephalus 4:65
Eurycea

bislineata bislineata 3:44
cirrigera 3:50;4:55
quadridigitata 3:97-105,1 13;4:55

Falco

columbarius 4:61
peregrinus 4:61,71
sparverius 4:61
Farancia 3:1 15
abacura 3:49,1 13
abacura 3:51;4:56
erytrogramma 4:56
Felis 3:23

concolor coryi 4:67,70,71
onca augusta 3:6,8,16
Florida caerulea 4:60
Fulica americana 4:61
Fundulus
catenatus 3:71
chrysotus 3:71;4:51,52
cingulatus 4:51,52

171

dispar 3:55
lineolatus 4:51,52
notatus 3:71,72
notti 3:55,72
olivaceus 3:72

Gallinula chloropus 4:61
Gambusia affinis 3:72;4:52
Gammarus
bousfieldi 4:133,145
minus 4:107,109,112,133-147
oceanicus 4:133
pulex 4:133

Gastrophryne carolinensis 4:55
Gavia immer 4:59
Gavialosuchus 3:22,24
sp. 3:5,8,10,1 1
Geochelone 3:23,25
sp. 3:5,8,10
Geomys
pinetis 4:68
floridanus 4:67
pinetis 4:69

Geothlypis trichas 4:65
Glaucomys volans querceti 4:69
Glossotherium harlani 3:5,8,13
Glyptotherium 3:22,23,25
floridanum 3:5,8,12,24
Gopherus 3:23
polyphemus 4:57
sp. 3:5,8,10

Gordonia lasianthus 4:48
Grus

canadensis 4:61
pratensis 4:58,71
Guiraca caerulea 4:65

Hadropterus 4:149
Haliaeetus leucocephalus 4:61,71
Halichoerus 3:22,23
grypus 3:6,8,16
Helmintheros vermivorus 4:64
Hemitremia flammea 3:55,63

Heterandria formosa 4:51,52
Heterodon
platyrhinos 4:56
simus 4:56
Hiodon
alosoides 3:61
tergisus 3:61
Hirundo rustica 4:63
Holmesina septentrionalis 3:5,8,12
Hybognathus
hayi 3:63
nuchalis 3:63
placitus 3:63
Hybopsis
aestivalis 3:63
amblops 3:63
dissimilis 3:64
gelida 3:64
gracilis 3:64
insignis 3:64
meeki 3:64
storeriana 3:64
x-punctata 3:55,64
Hydranassa tricolor 4:60
Hydrodchoerus pinckneyi 3:14
Hyla

andersoni 3:1 13-1 17
chrysoscelis 4:54
cinerea cinerea 4:55
crucifer bartramiana 4:55
femoralis 4:55
gratiosa 4:55
squirella 4:55
Hylocichla mustelina 4:63
Hypentelium nigricans 3:68

Ichthyomyzon
bdellium 3:57
castaneus 3:57
fossor 3:57
gagei 3:57
greeleyi 3:57
unicuspis 3:57

172

Ictalurus 4:75-93

brunneus 4:75,76,77,79-81,82,83,84,

85,86,87,90

catus 3:69;4:75,76,79,81,82,86,87,89
furcatus 3:69;4;75, 76,79,8 1-82,

84.86.89

melas 3:69;4:75,76,77,78,80,81,82-83

85.87.90

natalis 3:69;4:52,76,78,83,85,87,90
nebulosus 3:69;4:52,75, 76,78,82,83,

85.87.90

platycephalus 4:76,77,79,80,83-84,85,

86.87.90

punctatus 3:70;4:52,76,79,8 1,82,84,

86.89.90

serracanthus 4:76,85
sp. 4:158

Icteria virens 4:65
Icterus
galbula 4:65
spurius 4:65
Ictiobus

bubalus 3:68
cyprinellus 3:68
niger 3:68
Ilex

cassine 4:48
glabra 4:49

Iridoprocne bicolor 4:63
Itea virginica 4:48
Ixobrychus exilis 4:60

Junco hyemalis 4:65

Kinosternon 3:22
bauri palmarum 4:57
sp. 3:5, 7,8

subrubrum subrubrum 4:57

Labidesthes sicculus 3:73;4:52
Lachnanthes caroliniana 4:48
Lagochila lacera 3:55,69
Lampetra

aepyptera 3:57
lamottei 3:57
Lampropeltis

calligaster rhombomaculata 4:56
getulus getulus 4:56
getulus X floridana 4:56
triangulum elapsoides 4:56
Lanius ludovicianus 4:64
Larus

argentatus 4:62
atricilla 4:62
Lasiurus

borealis borealis 4:69
cinereus cinereus 4:69
intermedius floridanus 4:69
seminolus 4:68,69
Lepisosteus
oculatus 3:58
osseus 3:58
platostomus 3:58
platyrhincus 4:51
spatula 3:58
Lepomis
auritus 3:73
cyanellus 3:73
gibbosus 3:73
gulosus 3:73;4:52
humilis 3:73
macrochirus 3:74;4:52
marginatus 3:74;4:52
megalotis 3:74
microlophus 3:74
punctatus 3:74;4:52
symmetricus 3:74
Leptolucania ommata 4:51,52
Lespedeza sp. 3:98
Leucothoe racemosa 4:48
Ligustrum sp. 3:108
Limnodromus sp. 4:62
Limnothlypis swainsonii 4:64
Liquidambar styraciflua 3:108,121
Lontra canadensis vaga 4:70
Lophodytes cucullatus 4:60

173

Lota lota 3:55,71
Lynx
rufus 4:68
floridanus 4:70
Lyonia lucida 4:48

Macroclemys temmincki 4:57
Magnolia
grandiflora 3:108
virginiana 4:48
Mammut 3:23
americanum 3:6,8,17
Mammuthus 3:23
columbi 3:6,8,16
imperator 3:16
Marmota monax 3:43-48
Martes pennanti 3:25
Masticophis
flagellum flagellum 4:56
sp. 3:5,8,10

Megaceryle alcyon 4:62
Megalonyx 3:23
jeffersonii 3:5,8,12
Melanerpes
carolinus 4:63
erythrocephalus 4:63
Meleagris gallopavo 4:61
Melospiza
georgiana 4:65
melodia 4:66
Menidia
audens 3:55,72
beryllina 3:55

Mephitis mephitis elongata 4:70
Mergus

merganser 4:60
serrator 4:60

Microtus pinetorum parvulus 4:70
Micropterus
coosae 3:74
dolomieui 3:74
punctulatus 3:74
salmoides 3:74;4:52

sp. 4:158

Micrurus fulvius fulvius 4:57
Mimus polyglottos 4:63
Minytrema melanops 3:69;4:51
Mniotilta varia 4:64
Molothrus ater 4:65
Morone
chrysops 3:72
mississippiensis 3:73
saxatilis 3:73
Moxostoma
anisurum 3:69
atripinne 3:69
carinatum 3:69
erythrurum 3:69
macrolepidotum 3:69
Mus

musculus 4:67
musculus 4:70
Mustela

frenata olivacea 4:70
vison mink 4:70
Mycteria americana 4:60,71
Myiarchus crinitus 4:63
Mylohyus 3:23,25
fossilis 3:6,8,18,19
nasutus 3:19
Myotis

austroriparius 4:67
austroriparius 4:69
Myrica cerifera 3:98
Myrophyllum 4:153

Narceus 4:37

americanus 4:6,9,15,16-19,32,33,
34,35,36,37
annularis 4:17-19,37
Nasturtium officinale 4:153
Necturus 4:43-46
lewisi 4:43-46
maculosus 4:43-46
punctatus 4:43-46
Neochoerus 3:22,23,25
pinckneyi 3:5,8,14,24

174

Neofiber
alleni 4:67,68
exoristus 4;70

Neotoma floridana floridana 4:70
Nerodia 4:157,159
cyclopion floridana 4:56
erythrogaster erythrogaster 4:56,158
transversa 4:159

fasciata fasciata 3:51;4:56,158,159
pictiventris 4:56
sipedon sipedon 4:158
spp. 4:157

taxispilota 3:5I;4:56,158
Nocomis

biguttatus 3:64
effusus 3:64
micropogon 3:64

Nopoiulus minutus 4:7,8,11,33,34,35,
36,37

Notemigonus crysoleucas 3:64
Notophthalmus
perstriatus 4:55
viridescens 4:158
louisianensis 4:55
viridescens 3:44
Notropis
amnis 3:55,65
ardens 3:65
ariommus 3:65
atherinoides 3:65
blennius 3:65
boops 3:65,81
buchanani 3:65
camurus 3:65
chalybaeus 4:50
chrysocephalus 3:55,65
chrysoleucas 4:50
coccogenis 3:80
cornutus 3:55
emiliae 3:65
fumeus 3:65
galacturus 3:65
heterolepis 3:81

hubbsi 3:81
hudsonius 3:66
leuciodus 3:66
lutrensis 3:66;4:83
maculatus 3:66
petersoni 4:50
photogenis 3:66
procne 3:67
rubellus 3:66
shumardi 3:66
sp. 3:67

spectrunculus 3:67
spilopterus 3:66
stramineus 3:66
telescopus 3:66
umbratilis 3:66
venustus 3:66
volucellus 3:66
whipplei 3:67
Noturus
elegans 3:70
eleutherus 3:70
exilis 3:70
flavus 3:70
gyrinus 3:70;4:52
hildebrandi 3:70
leptacanthus 4:51,52
miurus 3:70
nocturnus 3:70
phaeus 3:70
stigmosus 3:70
Numenius phaeopus 4:61
Nuphar luteum 4:48
Nyctanassa violacea 4:60
Nyticeius

humeralis 4:67
humeralis 4:69
Nycticorax nycticorax 4:60
Nymphaea odorata 4:48
Nymphoides aquaticum 4:48
Nyssa sylvatica var. biflora 4:48

Obolaria virginica 3:39

175

Ochrotomys nuttalli aureolus 4:70
Odobenus 3:22,23
rosmarus 3:6,8,16
Odocoileus 3:23
hemionus 4:161

virginianus 3:6,8, 20;4:67,68, 161-163
virginianus 4:70
Olor columbianus 4:60
Oniscus sp. 3:108
Onychiurus 3:93
Opheodrys aestivus 4:56
Ophisaurus

attenuatus longicaudus 4:56
compressus 4:56
ventralis 4:56
Ophyiulus pilosus 4:37
Oporornis
agilis 4:65
formosus 4:65
Orconectes incomptus 3:86
Orontium aquaticum 4:48
Oryzomys palustris palustris 4:69
Osmerus mordax 3:62
Otus asio 4:62

Oxidus gracilis 4:7,9,22,32,33,34,35,
36,37

(02flr/:a) [Etheostoma] 4:149-156
Oxyura jamaicensis 4:60

Pachydesmus 4:38
crassicutis incursus 4:7,9,29-31,32,
33,34,35,36,38,39
Palaeolama 3:23,25
mirifica 3:6,8,19
Pandion haliaetus 4:61
Panicum 4:48
Paramylodon 3:23
Parula americana 4:64
Parus

bicolor 4:63
carolinensis 4:63
Passer domesticus 4:65
Passerculus sandwichensis 4:65

Passerella iliaca 4:65
Passerina
ciris 4:65
cyanea 4:65

Pelecanus erythrorhynchos 4:59
Perea flavescens 3:78
Percina 4:149
burtoni 3:55,78
caprodes 3:78,79;4:82
copelandi 3:79
cymatotaenia 3:80
evides 3:79
macrocephala 3:79
maculata 3:79
nigrofasciata 4:51,52
ouachitae 3:55,79
oxyrhyncha 3:79
phoxocephala 3:79
sciera 3:79,80
shumardi 3:79
squamata 3:80
sp. 3:80

uranidea 3:55,79

Percopsis omiscomaycus 3:71;4:82
Peromyscus
gossypinus 4:68
gossypinus 4:69
polionotus polionotus 4:69
Persea borbonia 4:48
Phalacrocorax auritus 4:59
Phenacobius
mirabilis 3:67
uranops 3:67
Phengodes sp. 4:157
Pheucticus ludovicianus 4:65
Philohela minor 4:61
Phoxinus

cumberlandensis 3:67
erythrogaster 3:67
Physeter 3:22
sp. 3:6,8,14
Picoides

borealis 4:63,71

176

pubescens 4:63
villosus 4:63
Pimephales
notatus 3:67
promelas 3:67;4:83
vigilax 3:67
Pinus

echinata 4:5
elliotii 3:98;4:48
palustris 4:48
strobus 4:20

taeda 3:44,98,109, 121;4:48
virginiana 4:5

Pipilo erythrophthalmus 4:65
Pipistrellus
subflavus 4:68
subflavus 4:69
Piranga

olivacea 3:44;4:65
rubra 4:65

Pituophis melanoleucus mugitus 4:56
Plecotus rafinesquii 4:67,69
Plegadis falcinellus 4:60
Plethodon glutinosus glutinosus 4:55
Pleuroloma
flavipes 4:38
sp. 4:38

Podiceps auritus 4:59
Podilymbus podiceps 4:59
Poecilichthys punctulatus 4:150
Polioptila caerulea 4:64
Polyodon spathula 3:58
Polyxenus fasciculatus 4:6,8,9,32,33,34,
35,36,37
Polyzonium
rosalbum 4:38

strictum 4:6,8,10,1 1,33,34,35,36,37
Pomoxis
annularis 3:74
nigromaculatus 3:74;4:52
Pontederia cordata 4:48
Pooecetes gramineus 4:65
Porphyrula martinica 4:61

Porzana Carolina 4:61
Potamogeton 4:153
Procyon 3:23
lotor 3:6,8,15
elucus 4:67,70
Progne subis 4:63
Protonotaria citrea 4:64
Prunus sp. 3:108
Pseudacris
nigrita nigrita 4:55
ornata 4:55

Pseudanophthalmus 3:85-96
acherontis 3:93
bendermani 3:94
catherinae 3:92

cumberlandus 3:85,86,90,91,92
farrelli 3:92

fowlerae 3:87,88-89,90,95
Hesperus 3:90,93
inquisitor 3:89,90,94-95
loedingi humeralis 3:90
occidentalis 3:93
productus 3:88,90,91-92,94
robustus 3:92
simplex 3:86-88,89,90,92
tiresias 3:90,92
tullahoma 3:93
valentine! 3:92
Pseudemys

floridana floridana 4:57
scripta scripta 4:57
elegans 4:57

Pseudobranchus striatus spp. 4:55
Pseudopolydesmus
branneri 4:8,9,23-25,32,33,34,35,
36,37

collinus 4:22,25
serratus 4:22,38
Pseudotriton
montanus floridanus 4:55
ruber ruber 3:44
Ptyoiulus 4:20,34,35,37
ectenes 4:7,8, 10, 12-13,32,33,34,35,

177

36.37.39

impressus 4:7,8, 10, 1 3,33,34,35,36,

37.39

sp. 4:32,33

Polydictis olivaris 3:70;4:76,81,84,
86,89

Pyrocephalus rubinus 4:63

Quercus
falcata 3:109
laurifolia 3:108,109
niger 4:49
spp. 3:121
virginiana 4:49
Quiscalus
major 4:65
quiscula 4:65

Radicula 4:153
Rallus
elegans 4:61
limicola 4:61
longirostris 4:61
Rana

areolata aesopus 4:55
catesbeiana 4:55,157,158,159
clamitans clamitans 4:55
grylio 3:1 16;4:55
heckscheri 4:55
palustris 4:158
utricularia 4:55
virgatipes 4:55
Ranunculus 4: 153
Rattus
rattus 4:67
alexandrinus 4:70
rattus 4:70
Regina
alleni 4:56
rigida rigida 4:56
Regulus
calendula 4:64
satrapa 4:64

Reithrodontomys humilus humilus 4:69
Rhadinaea flavilata 4:57
Rhinichthys

atratulus 3:67
cataractae 3:81

Rhynchospora 4:48
Rubus sp. 3:98

Salmo

fontinalis 3:61
gairdneri 3:61
trutta 3:61

Sayornis phoebe 4:63
Scalopus aquaticus australis 4:68
Scaphiopus
holbrooki 3:1 13
holbrooki 4:55
Scaphirhynchus
albus 3:58
platorynchus 3:58
Sceloporus
undulatus 3:49
undulatus 4:56
Scincella laterale 4:56
Sciurus

carolinensis 4:68
carolinensis 4:69
niger niger 4:67,69

Scytonotus granulatus 4:8,9,24,25,33,
34,35,36,37
Seiurus

aurocapillus 4:64
motacilla 4:64
noveboracensis 4:64
Seminatrix pygaea pygaea 4:57
carolinensis 4:63
pusilla 4:63
Sphagnum 4:48
Sphyrapicus varius 4:63
Spizella
arborea 4:65
passerina 4:65
pusilla 4:65

178

Stereochilus marginatus 4:55
Sterna
forsteri 4:62
paradisaea 4:62
Sternotherus
minor minor 4:57
odoratus 4:57
Stizostedion
canadense 3:80
vitreum 3:80
Storeria

dekayi victa 4:57
occipitomaculata 4:95-102
hidalgoensis 4:98
obscura 4:57,95,97,102
occipitomaculata 4:97,98,102
Striaria 4:37
causeyi 4:16

sp. 4:6,8,15,16,32,33,35,36
zygoleuca 4:16
Strix varia 4:62
Sturnella magna 4:65
Semotilus atromaculatus 3:68
Serenoa repens 4:49
Setophaga ruticilla 4:65
Sialia sialis 4:64

Sigmodon hispidus hispidus 4:70
Sigmoria

latior 4:7,9,30,31-32,33,34,35,36,37,39
latior X hoffmani 4:31
Siren

intermedia intermedia 3:50;4:55
lacertina 4:55

Sistrurus miliarius barbouri 4:57
Sitta

canadensis 4:63
pacificus 3:1 10
topetotum 3:107-1 1 1
Talitrus sylvaticus 3:110
Tapirus 3:23,25
sp. 3:6,8,18

Taxodium ascendens 4:48
Teniulus 4:39

parvior 4:13
setosior 4:13

sp. 4:7,8,10,13-14,33,34,35,36,
37,39

Terrapene 3:23
Carolina bauri 4:57
Carolina 4:57
putnami 3:5,7,8
Thamnophis

sauritus sackeni 4:57
sirtalis sirtalis 4:57
Thryomanes bewickii 4:63
Thryothorus lucovicianus 4:63
Tilia caroliniana 3:108
Toxostoma rufus 4:63
Trechus

aduncus coweensis 3:123
howellae 3:123
toxawayi 3:123

Tremarctos floridanus 3:6,8,15
Trichechus 3:22
sp. 3:6,8,17
Sturnus vulgaris 4:64
Sus scrofa 4:70
Sylvilagus 3:23
floridanus mallurus 4:69
palustris 4:68
palustris 4:69
sp. 3:5,8,13
transitionalis 3:25

Tadarida
brasiliensis 4:67
cynocephala 4:69
Talitroides
alluaudi 3: 107-11 1
decoratus 3:110
Typhlichthys subterraneus 3:71
Tyrannus
dominicensis 4:63
tyrannus 4:63
verticalis 4:63
Tyto alba 4:62

179

Umbra
limi 3:62
pygmaea 4:51
Urocyon 3:23
cinereoargenteus 3:6,8,15
floridanus 4:70
Ursus

americanus 4:68
floridanus 4:67,70,71
Utricularia spp. 4:48

Vaccinium stamineum 3:39
Viburnum prunifolium 3:39
Vireo

flavifrons 4:64
griseus 4:64
olivaceous 4:64
solitarius 4:64
Virginia

striatula 3:51;4:57
valeriae valeriae 4:57
Trichopetalum dux 4:6,8,16,32,33,35,
36,37
Tringa

flavipes 4:62
melanoleucus 4:62

solitaria 4:61
Trionyx
ferox 3:57
sp. 3:5
Troglodytes
aedon 4:63
troglodytes 4:63
Tsuga canadensis 4:20
Turdus migratorius 4:63
Tursiops 3:22
truncatus 3:6,8,14
Vermivora
bachmanii 4:64,71
celata 4:64
chrysoptera 4:64
pinus 4:64

Wilsonia
canadensis 4:65
citrina 4:65

Woodwardia virginica 4:48

Xyris smalliana 4:48

Zenaida macroura 4:62
Zinaria brunnea 4:38
Zonotrichia albicollis 4:65

180

NEW BOOKS FROM NCSM

ATLAS OF NORTH AMERICAN FRESHWATER FISHES

by

D. S. Lee, C. R. Gilbert, C. H. Hocutt, R. E. Jenkins,

D. E. McAllister, J. R. Stauffer, Jr., and many collaborators

This timely book provides accounts for all 777 species of fish known to
occur in fresh waters in the United States and Canada. Each account
gives a distribution map and illustration of the species, along with
information on systematics, distribution, habitat, abundance, size, and
general biology.

“. . . represents the most important contribution to freshwater fishes of
this continent since Jordan and Evermann’s 'Fishes of North and Middle
America' over 80 years ago.” — Southeastern Fishes Council Pro-
ceedings.

1980 825 pages ISBN 0-917134-03-6

Price: $25. North Carolina residents add 4% sales tax. Please make checks
payable in U. S. currency to NCDA Museum Extension Fund.

Send to FISH ATLAS, N. C. State Museum of Natural History, P. O. Box 27647,
Raleigh, NC 27611.

SEACOAST LIFE
by

Judith M. Spitsbergen

Ecology of natural seashore communities of the Middle Atlantic States,
with emphasis on North Carolina, is the subject of this field study guide.
It also can be used as a classroom text and overall resource book. A
general discussion of coastal habitats and their occupants is followed by
sections on communities of the Ocean Beach, Sand Dune, Salt Marsh,
Tidal Flat, and Rock Jetty and Piling. Each section includes a description
of the habitat and its special features, plant and animal adaptations, the
community, and typical organisms. The sections are profusely illustrated.
Includes glossary and indexes to scientific and common names.

1980 114 pages Price $5.95, plus $1.00 postage and handling ($6.95).

North Carolina residents add 4% sales tax. Make checks payable to NCDA
Museum Extension Fund. Send to SEACOAST LIFE, N. C. State Museum of
Natural History, P. O. Box 27647, Raleigh, NC 27611.

INFORMATION FOR CONTRIBUTORS

Submit original and two copies of manuscripts to Editor, Brimleyana, North Carolina State
Museum of Natural History, P. O. Box 27647, Raleigh, NC 27611. In the case of multiple
authorship, indicate correspondent. Manuscripts submitted for publication in this journal
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Preparation of manuscript. Adhere generally to the Council of Biology Editors Style
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inch margin on all sides. Double space all typewritten material.

The first page will be separate and contain the title and the author’s name and address.
Where appropriate, the title will indicate at least two higher categories to which taxa
belong. Example: Studies of the genus Hobbseus Fitzpatrick and Payne (Decapoda: Cam-
baridae).

A brief informative abstract on a separate sheet follows the title page, preceding the text. In-
dicative abstracts are not^ acceptable. Footnotes will be used only where absolutely
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Woodall, W. Robert, Jr., and J. B. Wallace. 1972. The benthic fauna in four small southern
Appalachian streams. Am. Midi. Nat. ^5(2):393-407.

Crocker, Denton W. and D. W. Barr. 1968. Handbook of the Crayfishes of Ontario. Univ.
Ontario Press, Toronto. 158 pp.

Authors, not the editor, are responsible for verifying references.

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numbers optional, following a colon; for more than two authors use et al. (not italicized).

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Changes in proofs other than type corrections will be charged to the author.

CONTENTS

The Blancan Carnivore Trigonictis (Mammalia: Mustelidae) in the
Eastern United States. Clayton E. Ray, Elaine Anderson and S. David

Webb 1

Pseudanophthalmus from Appalachian Caves (Coleoptera: Carabidae):

The Engelhardti Complex. Thomas C. Barr, Jr 37

Records of Leatherback Turtles, Dermochelys coriacea (Linnaeus), and
Other Marine Turtles in North Carolina Waters. David S. Lee and
William M. Palmer 95

Ecological Life History of Ptilostomis postica (Walker) (Trichoptera:
Phryganeidae) in Greenbottom Swamp, Cabell County, West Virginia.
Mary Beth Roush and Donald C. Tarter 107

Reproduction of the Eastern Cottonmouth Agkistrodon piscivorus
piscivorus (Serpentes: Viperidae) at the Northern Edge of its Range.
Charles R. Blem 117

Habitat Use and Relative Abundance of the Small Mammals of a South
Carolina Barrier Island. John B. Andre 129

On the Taxonomic Status, Distribution and Subspecies of the Milliped
Pseudotremia fracta (Chamberlin) (Chordeumatida: Cleidogonidae).
Richard L. Hoffman 135

Reptiles and Amphibians of Kiawah and Capers Islands, South Carolina.

J. Whitfield Gibbons and Julian R. Harrison, HI 145

Errata and Miscellany 163

Table of Contents, Nos. 3 and 4 (1980) 164

Index of Scientific Names, Nos. 3 and 4 (1980) 166

JUL 131981