Virginia Museum of NATURAL HISTORY PUBLICATIONS JEFFERSONIANA Contributions from the Virginia Museum of Natural History Number 24 22 October 2010 A middle Miocene beaked whale tooth (Cetacea: Ziphiidae) from the Carmel Church Quarry, Virginia, and implications for the evolution of sexual dimorphism in ziphiids Alton C. Dooley, Jr. ISSN 1061-1878 Virginia Museum of Natural History Scientific Publications Series The Virginia Museum of Natural History produces five scientific publication series, with each issue published as suitable material becomes available and each numbered consecutively within its series. Topics consist of original research conducted by museum staff or affiliated investigators based on the museum’s collections or on subjects relevant to the museum’s areas of interest. All are distributed to other museums and libraries through our exchange program and are available for purchase by individual consumers. Memoirs are typically larger productions: individual monographs on a single subject such as a regional survey or comprehensive treatment of an entire group. The standardized format is an 8.5 x 11 inch page with two columns. Jeffersoniana is an outlet for relatively short studies treating a single subject, allowing for expeditious publication. Issues are published electronically and are open-access. Guidebooks are publications, often semi-popular, designed to assist readers on a particular subject in a particular region. They may be produced to accompany members of an excursion or may serve as a field guide for a specific geographic area. Special Publications consist of unique contributions, usually book length, either single -subject or the proceedings of a symposium or multi-disciplinary project in which the papers reflect a common theme. Appearance and format are customized to accommodate specific needs; page size and layout varies accordingly. The Insects of Virginia is a series of bulletins emphasizing identification, distribution, and biology of individual taxa (usually a family) of insects as represented in the Virginia fauna. Originally produced at VPI & SU in a 6 X 9 inch page size, the series was adopted by VMNH in 1993 and issued in a redesigned 8.5 x 11 inch, double column format. Copyright 2010 by the Virginia Museum of Natural History Printed in the United States of America ISSN I06I-I878 Jeffersoniana, Number 24, pp. 1-11 Virginia Museum of Natural History A middle Miocene beaked whale tooth (Cetacea: Ziphiidae) from the Carmel Church Quarry, Virginia, and implications for the evolution of sexual dimorphism in ziphiids Alton C. Dooley, Jr.^ ABSTRACT An apparent right apical mandibular tooth from a beaked whale (Family Ziphiidae) was collected at the Carmel Church Quarry, Caroline County, Virginia in August 2009. The occurrence of this specimen in Bed 15 of the Calvert Formation marks only the second repon of a ziphiid from the Calvert Formation. Moreover, this specimen represents, along with the Peruvian Naicacetus and Messapicetus, the earliest known occurrence of an enlarged mandibular tooth m a ziphiid. The complete closure of the pulp cavity indicates that this tooth derived from a fully mature animal, while the lack of wear on the crown indicates that the tooth had not erupted from the gums, suggesting that the animal was a female. The presence of unerupted mandibular teeth in a fully mature female suggests that, even by the middle Miocene, ziphiids had already evolved modern behavioral patterns m which enlarged mandibular teeth are used exclusively for intraspecific combat between competing males. INTRODUCTION While there is a perception that beaked whales (Family Ziphiidae) are not especially common as fossils, numerous remains have been described worldwide. Ziphiid crania and rostra have been collected from the North Sea Basin for more than 1 50 years (Lambert 2005), with new taxa still being identified (e. g. Lambert 2005; Lambert and Louwye 2006). A number of specimens have been reported from the late Miocene and Pliocene of Italy, including Tusciziphius and Messapicetus (Bianucci 1997; Bianucci et al. 1992). The description of ten new taxa based on remains frawled off tlie coast of South Africa greatly increased the known fossil ziphiid diversity (Bianucci et al. 2007, 2008). Ziphiids are less common in the Americas. From Peru, Muizon (1983, 1984) described the Pliocene Ninoziphius, and Lambert et al. (2009) named the Miocene Nazcacetus\ both of these taxa are based on taiiiy extensive and well-preserved remains. Lambert, Bianucci, and Post (2010) and Bianucci et al. (2010) reported the remarkable discoveiy of eight specimens of Messapicetus from the middle to late Miocene of Peru. The only other reported ziphiid fossils from South America are undescribed remains from the Miocene of Argentina (Cozzuol 1996) and fragments from the Miocene of Ecuador (Bianucci et al. 2005). The majority of ziphiid remains from North America have been reported from South Carolina. Cope (1869a,b) and Leidy (1877) described several ziphiids of uncertain age from South Carolina (Oligocene to Pliocene sediments are known from the area). Post et al. (2008) suggested that most or all of these taxa should be considered nomina nuda, while noting possible similarities between Tusciziphius, Caviziphius, and Eboroziphius. True (1907) and Muizon (1984) discussed Anoplonassa Cope 1869a, which was based on a partial mandible. Post et al. (2008) reported a cranium of Tusciziphius from South Carolina, probably from Pliocene deposits. Whitmore 1. Virginia Museum of Natural History, 21 Starling Avenue, Martinsville, Virginia 24112 2 Jeffersoniana and Kaltenbach (2008) reported 15 ziphiid specimens from early Pliocene deposits at the Lee Creek Mine in North Carolina, which they referred to Ninoziphins, Mesoplodon, and Ziphius. Several ziphiid specimens have been reported from the early Pliocene of Florida by Morgan (1994), including rostral fragments refeiTcd to Mesoplodon and partial dentaries referred to Ninoziphius. While the specimens mentioned above are demonstrably or likely from tlie Pliocene, a few specimens fi'om the southeastern United States are thought to derive from Miocene sediments. Whitmore et al. (1986) reported a rostmm recovered by dredging in tlie Atlantic off the coast of Florida, which they refeiTcd to Mesoplodon. Morgan (1994) reported that this specimen was likely middle Miocene in age based on associated microfossils. Morgan (1994) also reported a single ziphiid periotic from the late Miocene of Florida. Whitmore and Kaltenbach (2008) reported two ziphiids from the late early Miocene Pungo River Fomiation at the Lee Creek Mine, a rostral fragment they refeiTcd to Choneziphius, and a mandible fragment they referred to Anoplonassa. Ziphiids ai'e particulai*ly I’ai'e in the otheiwise cetacean-rich deposits of the Oligocene-Pliocene Chesapeake Group in Maiyland, Delawai*e, and Virginia. Pelycorhamphus pertortus Cope, 1895 includes a paitial premaxilla for which exact locality is unknown, but which is thought to derive from tire Chesapeake Group. Post et al. (2008) considered tliis taxon a nomen nudum. Specimens from the Chesapeake Group reported by Gottfined et al. (1994) as ziphiid were reinterpreted by Gerholdt and Godfre>’ (2010) as patliological rostra that are not demonstrably from ziphiids. Whitmore and Kaltenbach (2008) mentioned but did not figui'e two specimens (a mandibular fragment, and an associated rostraFmandibular fragment) tliat they refeired to Ninoziphius, from Westmoreland County, Virginia. Sediments in tliis ai'ea range from middle Miocene to late Pliocene in age (Ward and Andrews 2008). Fuller and Godfrey (2007) reported a rostral Imgment of Messapicetus from the late Miocene St. Marys Fonnation in Mary land. Lambert, Godh^ey, and Fuller (2010) reported a paitial ziphiid cranium from Maiytand that has been the only reported zipliiid demonstrably from the irdddle Miocene Calvert Fonnation. One of the remarkable features of the Ziphiidae is the enlargement of one or two pairs of mandibular teeth. These teeth are sexually dimorphic, and while present in both sexes they typically only erupt in males (True 1910; Moore 1968; Mead 1989a, 1989b, 1989c). Except in some species of Mesoplodon, the enlarged teeth ai*e apical ly located (Dalebout et al. 2003). Among living genera, Berardius has two pairs of enlarged mandibular teeth (one of which is apical), while all other taxa have a single pair (Moore 1968). Almost all modern ziphiids exhibit reduction (and typically complete loss) of all other maxillary and mandibular teeth, although reduced teeth that are embedded in the gums (and occasionally protrude from the gums) occur with some frequency (Boschma, 1951). The exception among modem ziphiids is Tasmacetus, which retains a fully functional post-apical dentition (Oliver 1937; Moore 1968). Given the nature of the ziphiid fossil record, with the most common remains being isolated rostra and partial crania often found out of context, reports of ziphiid teeth are exceptionally rare. Typically the presence of either enlarged mandibular apical teeth, or enlarged alveoli to accommodate such teeth, is used as a definitive character to refer mandibular remains to the Ziphiidae. The type mandible of Anoplonassa includes alveoli for two pafrs of enlai'ged teeth, ineluding an apical pair (Tme 1907; Muizon 1984). Two pairs of Dooley: Carmel Church Beaked Whale 3 enlarged mandibular alveoli are also present m a fragmentaiy mandible from Belgium (IRSNB 3854-M.538, placed in Ziphidae incertae sedis by Lambert 2005). A mandibular fragment recovered fi'om the seafloor off the coast of New Zealand, probably late Miocene in age, has enlai'ged apical alveoli (Fordyce and Cullen 1979). Bianucci (1997) figui'ed casts of a right dentaiy fragment with an in situ tooth from the Pliocene of Italy, which he referred to Mesoplodon sp. This does not appear to represent an apical tooth, but rather is located more proximally, which is consistent with some modem species of Mesoplodon. A pair of enlai'ged apical mandibular alveoli is present in Ninoziphius (Muizon 1983, 1984). According to Morgan (1994:257) one of the Pliocene specimens from Florida that he referred to Ninoziphius included 'Two large, rounded, anteriorly directed teeth,” but unfoitunately tliis specimen was not figured. One of the Pliocene specimens refeiTed io Ninoziphius by Whitmore and Kaltenbach (2008) included large, circular, anterolaterally-oriented alveoli. Whitmore and Kaltenbach (2008) also reported two teeth (one in situ in a mandible fragment) from the Pliocene at Lee Creek Mine that they referred to Ziphius. These teeth have bulbous roots with small enamel crowns. Whitmore and Kaltenbach (2008) noted that, in addition to their similarity to Ziphius, these teeth also resembled the anterior teeth of Tasmacetus. The earliest known occurrences of enlarged mandibular teeth are in the middle Miocene Nazcacetus from Pern (Lambert et al. 2009), for which only the alveoli ai'e known, and several specimens of Messapicetus, also from the middle Miocene of Peru (Lambert, Bianucci, and Post 2010; Bianucci et al. 2010). The Messapicetus sample includes at least six specimens with dentaries, including two with in situ apical teeth. The new specimen reported here represents only the second record of a ziphiid from the Calvert Formation and, with the Peruvian specimens of Nazcacetus and perhaps Messapicetus, is the oldest record of an enlai'ged mandibular tooth in a ziphiid. Institutional Abbreviations: IRSNB, Institut royal des Sciences naturelles de Belgique, Brussels; MUSM, Museo de Historia Natural, Universidad Nacional Mayor de San Marco, Lima, Peru; USNM, United States National Museum of Natural History, Washington, DC; VMNH, Virginia Museum of Natural Histoiy, Martinsville, Virginia. SYSTEMATIC PALEONTOLOGY CETACEA Brisson, 1762 ODONTOCETI Flower, 1867 ZIPHIID AE (Gray, 1850) Gray, 1865 Gen. et sp. indet. (Fig. 1) Referred specimen — VMNH 120025, right apical mandibular tooth. Horizon and Locality — ^VMNH 120025 was collected in situ at the Cai*mel Church Quarry, Caroline County, Vii'ginia, during August 2009. The specimen was removed along with large numbers of chondrichthyan teetli and osteichthyan bones during the excavation of a mysticete skeleton, and was not noticed until January 20 1 0 during cleaning of this sample. 4 Jeffersoniana Ongoing excavations of the marine bonebed at Cannel Church since 1991 have yielded several thousand vertebrate fossils representing a minimum of approximately 50 taxa. The fauna is dominated by chondrichtliyans and cetaceans (Dooley et al. 2004; Beatty and Dooley 2009) but other marine mammals, osteichthyans, and ten*esti*ial mammals (Dooley 2007) ai'e also present. Diatoms present at the site (Trochim and Dooley 2010) indicate that tlie bone bed is located in Bed 15 of the Plum Point Member of the Calvert Fomiation (Ward and Andrews 2008) (East Coast Diatom Zone 6 of Andrews 1988). This is consistent with biosti'atigi'aphic coirelation based on terrestiial mammals (Dooley 2007). Tliis yields an age of approximately 13.4-14.4 Ma (Ward and Andrews 2008). Fig. 1. Ziphiid right apical tooth, VMNH 120025. A, lingual view; B, anterior view; C, buccal view; D, closeup of crown showing details of enamel, and possible bite mark. Scale bar for A-C equals 1 cm. DESCRIPTION The tooth has a large, rectilinear base with a moderately curved crown witli atotal height of 33.7 mm. Tlie crown has an approxbnately circulate cross section at tlie apex, but becomes more fransversely compressed proximally. In anterior view the lingual edge is sti'aiglit to sliglitly convex but tlie buccal edge is somewhat sigmoidal, with the buccal side at the apex angled medially (Fig. IB). The heiglit of the crown is 15 mm. The distal 2 mm of the crown is covered with relatively smooth enamel, ornamented with slight ridges on the proximal half. The remainder of the crown is enamel-free. There is a slight indentation at the base of the enamel. At the base of the crown the tootli is covered with a thick cementum sheath, marked by a slight lengthening of the tooth anteroposteriorly and a more rugose surface texture. The tooth becomes more bulbous and laterally compressed fi'om this point proximally, until at the base of the root the anteroposterior length of tire tooth (19.3 mm) is almost twice as large as the transverse width (10.5 mm ). The basal 5 mm of the tooth is heavily rugose. There are two large grooves running rtansversely across the base of the root. The pulp cavity is completely closed. Dooley: Carmel Chureh Beaked Whale 5 There are no obvious signs of wear on the enamel. Just proximal to the base of the enamel, the crown is somewhat rugose on the buccal surface, with a series of short grooves. It is possible that this wear is postmortem; an irregular, 5 mm long groove, interpreted here as a vertebrate bite mark, runs transversely across the posterior surface of the crown immediately adjacent to the rugose area (Fig. ID). DISCUSSION The location of Carmel Church on the extreme western edge of the Atlantic Coastal Plain and the abundance of benthic diatoms in the deposit indicate that this was a shallow water setting, with a water depth of less than 20 m (Trochim and Dooley 2010). The presence of a ziphiid at this locality is somewhat surprising, given the shallow water depths associated with the site. The general shallow nature of Chesapeake Group deposits has been invoked as a possible explanation for the scarcity of ziphiids in these deposits (Gottfried et al. 1994; Fuller and Godfrey 2007; Lambert, Godfrey, and Fuller 2010). The overall shape of a small conical crown with a large, laterally compressed root is consistent with apical teeth of many modern and fossil ziphiids. There is, however, considerable variation in tooth morphology among different taxa, in addition to intraspecific variation due to sexual dimorphism (True 1910; McCann 1962; Moore 1968; Lambert, Bianucci, and Post 2010). The overall shape of VMNH 120025 matches fahly closely the apical teeth from an adult female specimen of Indopacetiis pacificus, figured by Dalebout et al. (2003:450), as well as Juvenile teeth from the same species (Dalebout et al. 2003:440), but Indopacetiis teeth are smaller and much less laterally compressed than the Camiel Church tooth. The Indopacetiis tooth also has an open pulp cavity, even though it was recovered from an adult animal, while VMNH 120025 has a closed pulp cavity. VMNH 120025 also shows some similarity to female Mesoplodon minis teeth figured by Moore (1968:241) (USNM 175019), although the M, minis teeth are smaller and have a shorter crown, and also have an open pulp cavity. The overall shape of VMNH 120025 is somewhat similai* to Juvenile teeth from Hyperoodon ampullatus figured by Moore (1968:234), particulaidy with respect to the rugose base of the tooth. As with the adult Indopacetiis specimen, and in contrast with VMNH 120025, the Hyperoodon specimens all retained open pulp cavities. While ziphiid teeth typically lack enamel, there are a number of exceptions. Tasmacetus shepherdi, the only extant ziphiid with an extensive dentition, has enamel crowns on all the teeth (Oliver 1937). Non-apical teeth associated with Nazcacetiis urbinai appear to have small enamel crowns (Lambert et al. 2009); while this taxon had enlarged apical alveoli, no apical teeth were recovered with the type specimen. True (1910) mentioned a female specimen of Ziphius ccnnrostris with 2 mm of enamel at the tip of the crowns, but this does not appear to be typical for this taxon (True 1910; Moore 1968). Both teeth referred to Ziphius by Whitmore and Kaltenbach (2008) (USNM 392132 and USNM 182918) retained fairly large enamel crowns that comprise approximately one- fourth of the entire height of the tooth. Apical teeth from the Peruvian Messapicetus sample (MUSM 1037) appear to laek enamel, although the state of preservation of these 6 Jeffersoniana specimens makes this uncertain (Lambert, Bianucci, and Post, 2010), but post-apical teeth associated with these specimens all have small enamel crowns (Bianucci et al. 2010). With a maximum root length of 19.3 mm, the size of VMNH 120025 compares favorably with the alveoli of some otlier fossil ziphiids. In the type mandible of Anoplonassa the apical alveolus has a length of 23 mm (True 1907), The holotype specimen of the middle Miocene Nazcacetus has apical alveoli that are 20 mm in length (Lambert et al. 2009). VMNH 120025 is rather smaller than the alveoli of IRSNB 3854-M.538 from the late Miocene or Pliocene of Belgium, in which the anterior alveoli have a length of 28 mm according to Lambert (2005), Specimens of Messapicetiis gregarius recently described from Peru have a significant size range, with apical alveoli lengths ranging from 23 to 35 mm (Lambert, Bianucci, and Post 2010). Ratios between the minimum and maximum alveolar diameters in M gregarius range from 0.52 to 0.68 (Bianucci et al. 2010), compai'ed to 0.54 for the root of VMNH 120025. These ratios indicate that the apical teeth are rather more strongly compressed than is typical for ziphiids. The adult female specimen of Indopacetus figured by Dalebout et al. (2003:450) has a ratio of approximately 0.72, while teefli from a female Mesoplodon mirus (USNM 175019) figured by Moore (1968:241) have ratios of 0.64 and 0.57. Anoplonassa has an alveolar ratio of 0.70 (True, 1907). However, while the degree of transverse compression of the roots is similar in VMNH 120025 and M. gregarius, the morphology of preserved apical teeth is quite different, with an apparently much shorter crown on a larger tooth in MUSM 1037 (Lambert, Bianucci, and Post 2010). Several post-apical teeth are also known from M gregarius, although it is unclear if these are derived from the maxilla or the dentary. These teeth show a great range of size and shape, although all have roots that are more strongly transversely compressed than in A/, gregarius apical teeth or VMNH 120025, with minunum to maximum diameter ratios of 0.3 to 0.5 (Bianucci et al. 2010). These specimens have medially curved enamel crowns, and all but the smallest specimens show apical wear (Bianucci et al. 2010). While the presence of these specimens raises the possibility that VMNH 120025 could represent a post-apical tooth, the proportions and morphology are more consistent with an apical tooth. The completely closed pulp cavity in VMNH 120025 suggests that this animal was an adult at the time of death. It seems that the pulp cavity remains open well into adulthood in many modem ziphiids (Tme 1910; Moore 1968), so, assuming gi'owth patterns ai*e comparable in fossil species, it is unlikely tliat VMNH 120025 represents a subadult or young adult individual. The lack of any obvious wear on a tooth from an apparently fully mature ziphiid is also of some interest. The apical teeth are sexually dimorphic in all extant ziphiids (Tme 1910; Moore 1968; Mead 1989a, 1989b, 1989c). Even though there is at least one report of wear on the apical teeth from females of Berardius bairdi (Omiira et al. 1955), the typical condition for ziphiids is that apical teeth only erupt and become functional in adult males. Enlarged mandibular teeth do develop in females but normally remain covered by soft tissue throughout the life of the animal. This is tme even in Tasmacetiis, in which both males and females have an empted, functional dentition, yet the larger apical teeth are only emergent in males (Oliver 1937; Mead and Payne 1975; Dooley: Carmel Chureh Beaked Whale 7 Mead 1989a). Moreover, the emergent teeth in adult male beaked whales almost always show significant apical wear (True 1910; Moore, 1968). Given the lack of wear on VMNH 120025, combined with the closed pulp cavity indicating a fully mature adult, it seems highly unlikely that this tooth was emergent, and thus it most likely represents a female. Tills has miportant implications for the evolution of sexual dimorphism in Ziphiidae. In modern ziphiids the dimorphism of mandibular teeth is not simply a sexual display feature, but rather has behavioral significance. In most modem taxa, male ziphiids use the mandibular teeth in intraspecific combat, raking the teeth across the bodies of competing males (McCann 1974; Mead et al. 1982; Heyning 1984; McLeod 1998). While the functional significance of apical mandibular teeth for intraspecific combat in male ziphiids has been well established for modem ziphiids, it has been difficult to extend this to fossil ziphiids due to the paucit}' of mandibular remains, Lambert et al. (2009) noted that the presence of enlarged apical alveolae in Nazcacetiis suggested the possibility that sexually dimorphic mandibular teeth extended back to at least the middle Miocene. With the availability of a large sample of Messapicetiis, also from the middle Miocene, Lambert, Bianucci, and Post (2010) were able to establish a range of mandibular morphologies and apical alveolar sizes indicative of sexual dimorphism. One of the Messapicetus morphotypes includes a more robust mandible witli lai'ger apical teeth; Lambert, Bianucci, and Post (2010) interpreted this as the male moiphotype, suggesting that males were engaging in intraspecific combat. Given the fact that mandibular teeth are present but non-functional in most modern adult female ziphiids, it is plausible that these teeth may have served different or additional functions in both sexes in early ziphiids, with their use only later being restricted to male- male combat. Lambert, Bianucci, and Post (2010) did not report the recovery of any mandibular teeth in the Messapicetus female morphotype, so there is no direet evidence of the function (or non-function) of mandibular teeth in Miocene female ziphiids. The presence of an unworn, adult tooth at Carmel Church suggests that, even in the middle Miocene, apical teeth in some ziphiids were non-emergent and non-functional in females and that the function of apical teeth was restricted to their use in male-male combat. ACKNOWLEDGMENTS I would like to thank B. L. Beatty for helpful diseussions about this specimen. Reviews by S. J. Godfrey and O. Lambert greatly improved the manuscript. A. Dodd located the specimen among the material recovered from Carmel Church. The manuscript was proofread by B. S. Dooley, J. Davenport, and M, C. Santoro, who also provided assistance in locating references. J. Winston guided the manuscript tlirough the submission process. Access to the Cannel Church Quany was provided by Martin Marietta Materials, without which this research would not be possible. 8 Jeffersoniana LITERATURE CITED Andrews, G. W., 1988. A revised marine diatom zonation for Miocene strata of the southeastern United States. U. S. Geological Survey Professional Paper 1481,29 pp. Beatty, B. L. and A. C. Dooley, Jr. 2009. Injuries in a mysticete skeleton from the Miocene of Virginia, with a discussion of boLiyancy and the primitive feeding mode in the Chaeomysticeti. Jeffersoniana 20:1-28. Bianucci, G. 1997, The Odontoceti (Mammalia Cetacea) from Italian Pliocene. The Ziphiidae. Palaeontographica Italica 84:163-192. Bianucci, G., O. Lambert, and K. Post. 2007. A high diversity of beaked whales (Mammalia, Odontoceti, Ziphiidae) recovered by trawling from the sea floor off South Africa. Geodiversitas 29:561-618. Bianucci, G., O. Lambert, and K. Post. 2010. 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Jeffersoniana 23:1-18. True, F. W, 1907, Observations on the type specimen of the fossil cetacean Anoplonassa forcipata Cope. Bulletin of the Museum of Comparative Zoology 51:97-106, pis. 1-3. True, F. W. 1910. An account of the beaked whales of the Family Ziphiidae in the collection of the United States National Museum^ with remarks on some specimens in other American museums. United States National Museum Bulletin 73:1-89. Ward, L. W. and G. W. Andrews, 2008. Stratigraphy of the Calvert, Choptanlc, and St. Maiys Fonnations (Miocene) in the Chesapeake Bay area, Maryland and Dooley: Carmel Chureh Beaked Whale 11 Virginia. Virginia Museum of Natural History Memoir 9:1-169. Whitmore, F. C. Jr. and J. A. Kaltenbaeh. 2008. Neogene Cetaeea of the Lee Creek Phosphate Mine, North Carolina; pp. 181-269 in C. E. Ray, D. J. Bohaska, I. A. Koretsky, L. W. Ward, and L. G. Barnes (eds.). Geology and Paleontology of the Lee Creek Mine, North Carolina, IV. Virginia Museum of Natural History Speeial Publieation 14. Whitmore, F. C. Jr., G. V. Morejohn, and H. T. Mullins. 1986. Fossil beaked whales — Mesoplodon longirostris dredged from the oeean bottom. National Geographie Researeh 2:47-56. Parts published to date 1. On the taxonomy of the milliped genera Pseudojulus Bollman, 1887, and GeorgiuJus, gen. nov., of southeastern United States. Richard L. Hoffman. Pp. 1-19, figs. 1-22. 1992. $2.00 2. A striking new genus and species of bryocorine plant bug (Heteroptera: Miridae) from eastern North America. Thomas J. Henry. Pp. 1-9, figs. 1-9. 1993. $1.00. 3. The American species of Escmyus, a genus of Holarctic centipeds (Geophilo-morpha; Schendylidae). Luis A. Pereira & Richard L. Hoffman. Pp. 1-72, figs. 1-154, maps 1-3. 1993. $7.00 4. A new species of Puto and a preliminary analysis of the phylogenetic position of the Piito Group within the Coccoidea (Homoptera: Pseudococcidae). Douglass R. Miller & Gary L. Miller. Pp. 1-35, figs. 1-7. 1993. $4.00. 5. Cambanis (Camharus) angularis, a new crayfish (Decapoda: Cambaridae) from the Tennessee River Basin of northeastern Tennessee and Virginia. Horton H. Hobbs, Jr., & Raymond W. Bouchard. Pp. 1-13, figs, la-ln. 1994. $2.00. 6. Three unusual new epigaean species of Kleptochthonius (Pseudoscorpionida: Chthoniidae). William B. Muchmore. Pp. 1-13, figs. 1-9. 1994. $1.50. 7. A new dinosauromorph ichnogenus from the Triassic of Virginia. Nicholas C. Fraser & Paul E. Olsen. Pp. 1-17, figs. 1-3. 1996. $2.00. 8. “Double-headed” ribs in a Miocene whale. Alton C. Dooley, Jr. Pp. 1-8, figs. 1-5. 2000. $1.00. 9. An outline of the pre-Clovis Archeology of SV-2, Saltville, Virginia, with special attention to a bone tool dated 14,510 yr BP. Jeriy N. McDonald. Pp. 1-60, figs. 1-19. 2000. $3.00. 10. First confirmed New World record of Apocy cl ops dengizicus (Lepishkin), with a key to the species of Apocyclops in North America and the Caribbean region (Crustacea: Copepoda: Cyclopidae). Janet W. Reid, Robert Hamilton, & Richard M. Duffield. Pp. 1-23, figs. 1-3. 2002. $2.50 11. A review of the eastern North American Squalodontidae (Mammalia:Cetacea). Alton C. Dooley, Jr. Pp. 1-26, figs. 1-6. 2003. $2.50. 12. New records and new species of the genus Diacyclops (Crustacea: Copepoda) from subterranean habitats in southern Indiana, U.S.A. Janet W. Reid. Pp. 1-65, figs. 1-22. 2004. $6.50. 13. Acroneuria yiichi (Plecoptera: Perlidae), a new stonefly from Virginia, U.S.A. Bill P. Stark & B. C. Kondratieff Pp. 1-6, figs. 1-6. 2004. $0.60. 14. A new species of woodland salamander of the Plethodon cinereus Group from the Blue Ridge Mountains of Virginia. Richard Highton. Pp. 1-22. 2005. $2.50. 15. Additional drepanosaur elements from the Triassic infills of Cromhall Quarry, England. Nicholas C. Fraser & S. Renesto. Pp. 1-16, figs. 1-9. 2005. $1.50. 16. A Miocene cetacean vertebra showing partially healed compression fracture, the result of convulsions or failed predation by the giant white shark, Carcharodon megalodon. Stephen J. Godfrey & Jeremy Altmann. Pp. 1-12. 2005. $1.50. 17. A new Crataegus-foodmg plant bug of the genus Neolygiis from the eastern United States (Hemiptera: Heteroptera: Miridae). Thomas J. Henry. Pp. 1-10. !8. Barstovian (middle Miocene) Eand Mammals from the Carmel Church Quarry, Caroline Co., Virginia. Alton C. Dooley, Jr. Pp. 1-17. 19. Unusual Cambrian Thrombolites from the Boxley Blue Ridge Quarry, Bedford County, Virginia. Alton C. Dooley, Jr. Pp 1-12, figs. 1-8, 2009. 20. Injuries in a Mysticete Skeleton from the Miocene of Virginia, With a Discussion of Buoyancy and the Primitive Feeding Mode in the Chaeomysticeti. Brian E. Beatt>^ & Alton C. Dooley, Jr., Pp. 1-28, 2009. 21. Morphometric and Allozymic Variation in the Southeastern Shrew {Sores longirostris). Wm. David Webster, Nancy D. Moncrief, Becl