05_Kovalchuk.indd UDC 567.41:551.762.23(477.46) LEPISOSTEIFORM FISH (HOLOSTEI) GANOID SCALES FROM THE MIDDLE JURASSIC DEPOSITS OF UKRAINE О. М. Kovalchuk1, G.V. Anfi mova2 National Museum of Natural History NAS of Ukraine, B. Khmelnytsky st., 15, Kyiv, 01030 Ukraine E-mail: 1biologiest@ukr.net, 2anfi mova77@ukr.net Lepisosteiform Fish (Holostei) Ganoid Scales from the Middle Jurassic Deposits of Ukraine. Kovalchuk, О.  М., Anfi mova, G.  V. — Gars (Lepisosteiformes) fl ourished in epicontinental seas throughout the world during the second half of Mesozoic and early Cenozoic. Cretaceous and Paleogene remains of these fi shes are common in Europe while their Jurassic fossils are still relatively scarce. Here we re-describe in detail a series of ganoid scales from the latest Middle Jurassic (Callovian) deposits of Pekari (Cherkasy Region, Ukraine). Th ese fossils were identifi ed by  Professor O.  S.  Rogovich in 1861 as those that belong to Lepidotus mantellii and L.  fi ttoni. Th e referral of these scales to a certain species should be considered with caution because the described material lacks characters suffi cient for identifi cation it even to the genus or family. We consider to identify these fossils as Lepisosteiformes gen. et sp. indet. An overview of currently known Jurassic occurrences of lepisosteiform fi shes is also presented in the paper. K e y w o r d s : Lepisosteiformes, museum collection, morphology, Callovian, Europe. Introduction Order Lepisosteiformes is a small group of primitive neopterygian fi shes comprising two families — Lepi- sosteidae with seven genera (only two of which — Atractosteus and Lepisosteus — remain extant), and †Obaich- thyidae including two genera (Grande, 2010). In addition, seven extinct genera of lepisosteiform fi shes (†Arari- lepidotes, †Isanichthys, †Lepidotes, †Pliodetes, †Th aiichthys, and †Scheenstia) are indicated by incertae familiae (López-Arbarello, 2012). Th e current distribution of gars is restricted to North America, Central America and the Caribbean islands (Nelson et al., 2016). However, it was much wider during Mesozoic and early Cenozoic as evidenced by the presence of their fossils throughout the world (e. g. in South America, Africa, Europe and Asia; see Grande, 2010). Lepisosteiform fi shes appeared in the fossil record in the Early Jurassic and became diverse during the Late Jurassic and Early Cretaceous (López-Arbarello, 2012). However, little is  known about the taxonomic composition and diversity of the Jurassic lepisosteiforms. Th eir remains in  Europe are relatively scarce, but even if present, they are mostly unknown due to  being “buried” in  old natural history collections without a detailed description (Tretyak & Chervonenko, 2016). Zoodiversity, 54(1):35–42, 2020 DOI 10.15407/zoo2020.01.035 36 О. М. Kovalchuk, G.V. Anfi mova One of such fi nds is a series of ganoid scales briefl y described by Rogovich (1861) from the Middle Jurassic deposits of Girchin quarry near Pekari, Cherkasy region, Ukraine (fi g. 1). Rogovich (1861) assigned these scales to “Lepidotus Mantellii” and “Lepidotus Fittoni” based on their general similarity to scales of those species, which were previously described by Agassiz (1833–1844). Th e scales are “thin and thick, angular or completely rhomboidal in shape (depending on its position on the fi sh body)”, and their outer surface is “smooth or yields folds and dashes” (Rogovich, 1861: 67–68). Th e aim of our study is to describe in detail the morphology of ganoid scales from Pekari, re-interpret this fi nding in terms of current stratigraphy and place it into a broad biogeographical context. G e o l o g i c a l s e t t i n g , a d d i t i o n a l f a u n a a n d a g e e s t i m a t i o n Th e section from which the studied scales and numerous shark teeth were collected consists of “diluvium, Eocene green-grey sand and conglomerate, Cretaceous green sandstone, clayey-lignite intercalations, and Jurassic clay exposed at the base” (Rogovich, 1861: 7). Middle Jurassic deposits in the Kaniv dislocation area are represented by a series of light-brown and dark-grey clay referring to the ammonite zone Cadoceras (Paracadoceras) elatmae, formerly defi ned as Macrocephalites macrocephalus zone (Kiselev & Ippolitov, 2011). A calcareous nannoplankton assemblage from these sediments was described by Matlaj (2016): Biscutum dubium, Lotharingius contractus, L. crucicentralis, Stephanolithon speciosum, Watznaueria barnesae, W. britannica, W. fossacincta, and W. manivitiae. Th ese taxa represent the nannoplankton zone NJ12a/Ansulasphaera helvetica indicating the Early Callovian age (Matlaj, Fig. 1. Location of the Pekari fossil site on the map of Ukraine, the portrait of Professor O. S. Rogovich with the original (above) and additional labels (below) of the described material. 37Lepisosteiform Fish (Holostei) Ganoid Scales from the Middle Jurassic Deposits of Ukraine 2016). Based on this study, marine conditions within the Kaniv  dislocation area already existed in the Early Callovian. Th e ammonite assemblage of the studied region is represented by Cadoceras (Paracadoceras) elatmae, Macrocephalites cf. verus, M. multicostatus/M. prosekensis, M. pavlowi, M. (Pleurocephalites) cf. terebratus, and Pseudocadoceras (Costacadoceras) mundum (Kiselev & Ippolitov, 2011). Th is species list was supplemented by Gulyaev (2015) due to re-identifi cation of some specimens from old museum collections and description of Bullatimorphites (Kheiraceras) bullatus. Th is taxon is common for the Paracadoceras elatmae biohorizon (Gulyaev, 2015), which is equal to the Cadoceras suevicum horizon in Germany (Mönnig, 2014). Gulyaev & Ippolitov (2013) reported about the fi ndings of numerous Early Callovian belemnite remains from Kaniv district, namely of Cylindroteuthis s. str., “Cylindroteuthis” kowalewi, Pachyteuthis s. str., and Communicobelus represented by diff erent mophs. Material and methods Th e examined series of scales is stored in the Department of Geology of the National Museum of Natural History, National Academy of Sciences of Ukraine, Kyiv, Ukraine. Th e scales were identifi ed using diagnostic features based on comparisons with extinct and modern taxa (deposited in Virginia Institute of Marine Science, USA, Hungarian Natural History Museum, Budapest, Hungary, and Babeş-Bolyai University Cluj-Napoca, Romania) as well as on data from the literature (Agassiz, 1833–1844; Grande, 2010; López-Arbarello, 2012; Alvarado-Ortega et al., 2014; Sweetman et al., 2014; Pouech et al., 2015). Th e taxonomic hierarchy follows López-Arbarello (2012), and Nelson et al. (2016). Morphological description is presented here according to Grande (2010), with reference to other publications (e.g., Kerr, 1952; Th ompson & McCune, 1984; Kumar et al., 2005; Alvarado-Ortega et al., 2014; Garbelli & Tintori, 2015; Kyselevych & Kovalchuk, 2019). Th e scales were measured by an electronic caliper, and photographed using a Leica M168C camera in Schmalhausen Institute of Zoology, National Academy of Sciences of Ukraine. Systematic paleontology Class ACTINOPTERYGII Cope, 1887 sensu Rosen et al., 1981 Subclass NEOPTERYGII Regan, 1923 sensu Nelson et al., 2016 Infraclass HOLOSTEI Müller, 1844 sensu Grande, 2010 Subdivision GINGLYMODI Cope, 1872 sensu Grande, 2010 Order LEPISOSTEIFORMES Hay, 1929 sensu López-Arbarello, 2012 Lepisosteiformes gen. et sp. indet. Lepidotus mantellii Ag.: Rogovich, 1861, pp. 67–68; table IX, fi gs 27–34. Lepidotus fi ttoni Ag.: Rogovich, 1861, p. 68; table IX, fi gs 35–39. M a t e r i a l . Seven ganoid scales, Nos. 391/107a-d, 391/108-10. L o c a l i t y a n d a g e . Pekari (49°42´ N, 31°33´ E), Cherkasy Region, Ukraine; Middle Jurassic, Early Callovian (J2kl1), ca. 166–165 Ma. D e s c r i p t i o n . Ganoid scales are represented by three morphotypes. Morphotype 1 (specimen No. 391/109; fi g. 2, A1-A2). Th e scale plate is elongated, smooth and narrow, irregularly rectangular in shape; its total length is 15.0 mm, width — 8.0 mm. Th e thin ganoine layer covers the entire outer surface of the scale. Edges of the scale are smooth and rounded (posterodorsal angle is 103°, while the posteroventral angle equals 84°). Th e scale is the thickest along the ridge which is parallel to both its anterior and posterior edges. Th ere is a weak serration (four small denticles with blunt tips) forming a shallow ridge on the dorsal edge, between the dorsal peg (dp) and posterior margin of the scale. Th e anterodorsally oriented dorsal anterior process (dap) is strong, stout and sharp while the ventral anterior process (vap) is totally reduced. Th e space between the anterior processes is fi lled with a thin plate. Th e dorsal peg is shift ed toward the dap base. Posterior edge of the scale is narrow; the ventral edge forms a long shallow ridge. Morphotype 2 (specimens No. 391/107a, fi g. 2, B1-B2; No. 391/107b, fi g.  2, C1-C2; No. 391/110, fi g. 2, D1-D2). Th e scales are narrow and elongated, their length varies in the range of 12.0–13.0 mm, width of the scale plate — 4.0–5.0 mm. Th ere is a very strong dorsal 38 О. М. Kovalchuk, G.V. Anfi mova anterior process (5.0–8.0 mm in length) with a widened base and pointed tip. Th e ventral anterior process is absent as well, and the dorsal peg is comparatively reduced. Th e latter is located just near the dap base. All the scales are covered with a thin ganoine layer, however the specimen No. 391/107a (fi g. 2, B1-B2) partially lacks this cover (due to postmortem redeposition), and therefore its basal plate is uncovered. Th e scales are the thickest on the vertical of the  dp. Th ere are two shallow ridges along the margins of the dap, as well as one longitudinal ridge on its outer surface. Th e posterodorsal edge of all scales is rounded. Th ere is a concave groove starting from the proximal third of the dap up to the posterior half of the dp in specimen No. 391/110 (fi g. 2, D1-D2). Morphotype 3 (specimen No. 391/107c, fi g. 2, G1-G2). Th e small scale (total length 8.5 mm, width 6.0 mm) is clearly rhomboidal in shape. Its outer surface is smooth and slightly convex. As other scales in the described series, this specimen is narrower toward the non-serrated edges being the thickest in its central part. Th e anterior processes are not expressed, and the dp is absent. Two other scales (No. 391/108, fi g. 2, E1-E2; No. 391/107c, fi g. 2, F1-F2) are represented by small rounded and slightly concave fragments with concentric rings on the smooth outer surface, weakly expressed dap and the dp. C o m p a r i s o n . Th e ganoid scales from Pekari resemble those in representatives of the order Lepisosteiformes in overall morphology, including the presence of two processes forming a rostro-caudal or longitudinal articulation (Cavin et al., 2009) and the reduction of the ventral anterior process diagnostic of the suborder Lepisosteoidei (López-Arbarello, 2012). However, these characters diff er from those in the lepisosteiform crown taxa, whose scales have the peg-and-socket vertical articulation reduced or absent in the superfamily Lepisosteoidea and a strong posteriorly directed spine in the suborder Lepisosteoidei (López-Arbarello, 2012; Alvarado-Ortega et al., 2014). Th e general shape of some scales from Pekari (morphotypes 2 and 3) is similar to the scales of ?Scheenstia sp. described by Sweetman et al. (2014: fi g. 13, E-F, p. 891) from the Fig. 2. Ganoid scales of Lepisosteiformes gen. et sp. indet. from Pekari: A1-A2 — No. 391/109; B1-B2  — No. 391/107a; C1-C2 — No. 391/107b; D1-D2 — No. 391/110; E1-E2 — No. 391/108; F1-F2 — No. 391/107d; G1- G2 — No. 391/107c. Outer view in A1, B1, C1, D1, E1, F1, G1, inner view in A2, B2, C2, D2, E2, F2, G2. Abbreviations: bp, basal plate; dap, dorsal anterior process; dp, dorsal peg; gl, ganoin layer; gr, ganoin ridges. 39Lepisosteiform Fish (Holostei) Ganoid Scales from the Middle Jurassic Deposits of Ukraine Lower Cretaceous deposits of England. Both of them are equal in size and share the same type of articulation. However, the specimens Nos. 391/109, 391/107a, and 391/107b are more elongated and have a stronger dorsal anterior process. Besides, the dorsal edge of the scales in ?Scheenstia sp. is non-serrated, and the scale plate seems to be deeper. A scale fragment of Scheenstia mantelli from the Late Jurassic of Cherves-de-Cognac in France (Pouech et al., 2015: Fig. 3O) resembles No. 391/107d (fi g. 2, F1-F2). Other known scale specimens of Scheenstia (Murray, 2000: Fig. 6B, p. 127; Pouech et al., 2015: Fig. 3R, p. 36; Haddoumi et al., 2016: Fig. 10A, p. 298; Kyselevych & Kovalchuk, 2019: fi g. 2, etc.) share the same morphology and similar ganoin ridges at the outer surface, but have two well-developed anterior processes as well as shorter and deeper scale plate. We can say the same about the scales of Lepidotus fi gured by  Agassiz (1833–1844) and described in detail by Woodward (1919). It should be noted that the morphological diff erences between Lepidotes and Scheenstia are not completely resolved because not all the known Lepidotes species were considered in the study of López-Arbarello (2012). Th e scales of lepisosteiform fi shes show signifi cant diff erences along the trunk of the same individual (see Grande, 2010; López-Arbarello, 2012; Alvarado-Ortega et al., 2014). Th e attribution of isolated ganoid scales with a certain species (as it was presented by Rogovich, 1861) should be considered with caution because such material oft en lacks suffi cient diagnostic characters. In our case, it is not possible to make an accurate identifi cation and decide whether these scales represent one or two species. We  decide to assign the specimens from Pekari as Lepisosteiformes gen. et sp. indet. Discussion Th e oldest reliable lepisosteiform remains are known from the Lower Toarcian de- posits (182 Ma) of Grimmen in Germany (Böhme & Ilg, 2003). Th e fi nding of Lepiso- steiformes gen. et sp. indet. in Pekari is the sole Callovian record of this group in East- ern Europe and one of its few occurrences currently known for this age. Another one is Isanichthys latifrons (Woodward, 1893) from the Middle Callovian of Oxford Clay Pit in England (Woodward, 1893), as well as the scales identifi ed as Scheenstia sp. from the Middle Jurassic of Guelb el Ahmar, Morocco (Haddoumi et al., 2016). Th ere is a short report of Callovian fi sh remains found in Sarykamyshkai 1 (Kyrgyzstan) and assigned to Lepisosteus? sp. (Böhme & Ilg, 2003), however this record is  doubtful (Grande, 2010), and Lepisosteiformes are regarded to be absent in the general faunal list from this locality (Averianov et al., 2005). As for other Jurassic (but non-Callovian) lepisosteiform occurrences, most of them are known from Europe (Böhme & Ilg, 2003). Th ose are remains of Scheenstia laevis (Agas- siz, 1833–1844) from the Kimmeridgian/Tithonian of Cerin, Ain and Scheenstia maximus (Wagner, 1863) from Lot-et-Garonne, both in France (Agassiz, 1833–1844; Sauvage, 1902). Swiss record of Jurassic lepisosteiform fossils is represented by teeth and scales of Scheen- stia sp. from the Kimmeridgian of Bois de Sylleux and Tchâfoué (López-Arbarello & Sferco, 2011; López-Arbarello, 2012). Lepisosteiform fossils, mostly represented by the genus Scheenstia López-Arbarello & Sferco, 2011, are quite common in lithographic limestones of the Solnhofen and Mörn- sheim formations (Late Jurassic) in Germany. Scheenstia maximus (Wagner, 1863) was reported from Eichstätt, Kellheim (Wagner, 1863), and Langenaltheimer Haardt (Böhme & Ilg, 2003). López-Arbarello & Sferco (2011) described Scheenstia zappi from the Kim- meridgian of Schamhaupten. Scheenstia decoratus (Wagner, 1863) is known from the Lower Tithonian beds of Solnhofen (López-Arbarello, 2012). Other species of the genus Scheenstia (S. degenhardti (Branco, 1885), S. hauchecornei (Branco, 1887)) were reported from the Upper Berriasian lagoon deposits of Obernkirchen near Bückeburg (Böhme & Ilg, 2003). 40 О. М. Kovalchuk, G.V. Anfi mova Th ere are a few Jurassic localities yielding the lepisosteiform remains outside of Eu- rope: Qijiang in China (Tithonian/Kimmeridgian: Beiduyu quijiangensis Murray et al., 2015), Phu Nam Jun in Th ailand (Tithonian: Isanichthys palustris Cavin & Suteethorn, 2006; Th aiichthys buddhabutrensis (Cavin et al., 2003)), and Yosobé near Tlaxiaco in Mexico (Kimmeridgian: Nhanulepisosteus mexicanus Brito, Alvarado-Ortega & Meuni- er, 2017). Every new fi nd of lepisosteiform fossils (even described in open nomenclature) is im- portant for precise reconstruction of the biogeographical history of this group. Th e revision of old natural history collections is of great interest because it allows re-discovering some valuable but unknown specimens, and describing them in  more detail using the newest methodology. We are thankful to M. Szabó (Hungarian Natural History Museum), E. Hilton (Virginia Institute of Ma- rine Science, College of William & Mary, USA), and V. Codrea (Babeş-Bolyai University Cluj-Napoca, Roma- nia) for kindly presenting images of lepisosteiform fi sh scales, reviewing the manuscript and useful suggestions. We express our sincere thanks to Z. Barkaszi (National Museum of Natural History NAS of Ukraine) for proof- reading the manuscript, as well as to L. Popova for her comments of stratigraphy. References Agassiz, L. 1833–1844. Recherches sur les Poissons Fossiles. Tome II. Neuchâtel et Soleure, Petitpierre, vi–xii + 1–336. Alvarado-Ortega, J., Barrientos-Lara, J. I., Espinosa-Arrubarena, L., Melgarejo-Damian, M. del Pilar. 2014. Late Jurassic marine vertebrates from Tlaxiaco, Oaxaca State, southern Mexico. Palaeontologia Electronica, 17.1.24a, 1–25. Averianov, A. O., Martin, T., Bakirov, A. A. 2005. Pterosaur and dinosaur remains from the Middle Jurassic Balabansai Svita in the northern Fergana Depression, Kyrgyzstan (Central Asia). Palaeontology, 48 (1), 135–155. Böhme, M., Ilg, A. 2003. fosFARbase, www.wahre-staerke.com. 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