Eremiasaurus

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Amirani1746/sandbox
Temporal range: Late Cretaceous, Maastrichtian, 70.6–66 Ma
 
Life restoration
Scientific classification  
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Reptilia
Order: Squamata
Clade: Mosasauria
Family: Mosasauridae
Tribe: Mosasaurini
Genus: Eremiasaurus
LeBlanc et al., 2012
Type species
Eremiasaurus heterodontus
LeBlanc et al., 2012

Eremiasaurus ("desert lizard") is a genus of mosasaurs, an extinct group of marine reptiles. It lived during the Maastrichtian stage of the Late Cretaceous in what is now North Africa. Only one species is known, E. heterodontus, described in 2012 from two remarkably complete fossil specimens discovered in the Ouled Abdoun Basin, Morocco. This site is known to have delivered a significant number of other related mosasaurs.

Eremiasaurus is a medium-sized representative for mosasaurs, estimated to be around 5 metres (16 ft) long based on observations made on the syntype specimens. The skull of Eremiasaurus is robustly built and is characterized by its highly differentiated heterodonty (hence its specific name). The anatomy of the caudal vertebrae of Eremiasaurus suggests that it would have been a predator capable of swimming at high speed.

Eremiasaurus lived in the southern margin of the Mediterranean Tethys. This paleo-ocean had a significant diversity of aquatic vertebrates and had a temperate and warm oceanic climate. The fossil record also shows that there would have been niche partitioning between Eremiasaurus and the various other mosasaur species identified within the Ouled Abdoun Basin.

Research history

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Map of the Ouled Abdoun basin and other major phosphate basins of Morocco shown in yellow. The Upper Couche III, the area from which the syntypes of Eremiasaurus were discovered, is illustrated by the black star at the top right of the table opposite

In 2012, paleontologists Aaron R. H. LeBlanc, Michael W. Caldwell and Nathalie Bardet officially described Eremiasaurus heterodontus on the basis of two specimens discovered within the phosphate deposits of the Ouled Abdoun Basin in Morocco, and more precisely in the area of Sidi Daoui, located near the town of Oued Zem. The syntypes, cataloged UALVP 51744 and OCP DEK/GE 112 respectively, are two more or less complete specimens representing almost the entire known skeleton of the genus. The rationale for using syntypes rather than a single holotype comes from the fact that UALVP 51744, the most complete specimen, is derived from the commercial field without precise locality data. However, OCP DEK/GE 112 was exhumed by one of the describers, Nathalie Bardet, allowing its detailed geographic and stratigraphic position to be recorded. The precise zone concerning this discovery is located at the level of Upper Couche III, dating from the Upper Maastrichtian of the Late Cretaceous,[1][2] an area where other mosasaurids have been found, including Mosasaurus beaugei[2] and Thalassotitan atrox.[3] Referred specimens of Eremiasaurus have been also discovered in geological formations of Brazil and Israel, at the same latitude and time period as those in the Ouled Abdoun Basin.[4][2]

The genus name Eremiasaurus comes from the Ancient Greek ἐρημία (eremia, "desert") and σαῦρος (saûros, "lizard"), a portmanteau literally meaning "desert lizard", in reference to the arid climate of present-day Morocco where the marine reptile was discovered. The specific epithet heterodontus also comes from the Ancient Greek ἕτερος (heteros, "different") and ὀδόντος (odóntos, "tooth"), the two together meaning "different teeth", referring to the drastic change in the shape of the teeth at various points of the jaws.[1]

Description

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Size

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The syntypes of Eremiasaurus indicate a rather average size for a mosasaurid. The most complete specimen, UALVP 51744, is 4.5 m (15 ft) long, with the skull measuring 63.5 cm (25.0 in), but the absence of several dorsal vertebrae suggests that the actual body length would have been closer to 5 m (16 ft). The second specimen, OCP DEK/GE 112, was first estimated to reach 6 m (20 ft) in length, based on observation of the larger skull, measuring 70 cm (28 in).[1] However, a review of mosasaurids from Morocco conducted by Bardet and colleagues in 2015 reduced the proposed size for this specimen to 5 m (16 ft).[2]

Skull

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Annotated schematic of a Mosasaurus skull, a close relative of Eremiasaurus

The skull of Eremiasaurus has a robust build, but to the extreme seen in the related genus Prognathodon.[2] The premaxillary rostrum is short and conical in dorsal view and extends forward less than the length of an alveolar space. The outline of the dorsal surface of the premaxilla is narrow and pointed forward, similar to Mosasaurus and Plesiotylosaurus. The maxilla is long and thin. Feeder foramina line the lateral surface of the maxilla and enlarge posteriorly. These foramina are located about 2 cm (0.79 in) behind the row of teeth of the maxillae.[1] The preorbital part is slightly larger than half the total length of the skull and the frontal region is enlarged.[2] The lateral surface of the prefrontal is concave and has a broad, flat dorsal surface for contact with the overlapping frontal and maxilla. Posterior to the end of the premaxillary-maxillary suture, the internarial bar (the long part of the premaxilla extending behind the teeth of this bone) is laterally constricted and has a prominent median dorsal keel extending along the posterior half. A large supraorbital, rounded triangular process extends from the postero-dorsal surface of the prefrontal, similar to other mosasaurines. The infrastapedial and suprastapedial processes of the quadrate are fused, possessing a very large and rounded stapedial fossa, the latter being one of the autapomorphies of the species.[1]

The lower jaw is thin compared to the size of the teeth lodged along the dentary. The dorsal margin of the dentary is slightly convex in lateral view. This convexity is not as pronounced as in most Prognathodon species and rather resembles that in Mosasaurus and P. kianda. The coronoid bears a large posterior process oriented vertically, which gives the dorsal margin of the bone an angle of nearly 90° between the horizontal anterior end and the vertical hind wing. The articular bones form broad rectangular extensions of the lower jaws behind the glenoid fossae. An exceptional case among mosasaurs, Eremiasaurus seems to have a hyoid bone, an element rarely found in the fossils of representatives of this group. This bone is slightly widened in its posterior part.[1]

Teeth

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Eremiasaurus is characterized by its marked heterodonty, the teeth differing in many points in the jaws by their shape and size.[1][2] The premaxillary teeth would have been pointed straight rather than projecting forward based on observations of a small anterior pit in the first tooth of the dentary bones, as well as the position of the first premaxillary socket.[1]

Thirteen tooth positions can be counted in the left and right maxillae in Eremiasaurus.[a] The three anterior teeth of UALVP 51744 resemble those of the premaxilla and are long, straight, and conical, teardrop-shaped to round in cross-section. These teeth possess only serrated anterior carinae (ridges). When closing the jaw, its premaxillary and dentary teeth lodge in small pits between the teeth. This type of contact is also found along the dental margin of the maxilla. The crowns are blade-shaped, bicarinate (two-keeled), and are much longer from front to back than in the anterior dentition. The enamel surfaces are smooth with faint traces of facets on the dental crowns. In addition, the anteroposterior expansion of the dental crown leaves little space between the adjacent teeth, and at the seventh tooth of the maxilla, the interdental pits are absent. From this precise point, the teeth of the maxillae and dentaries no longer interdigitate, but shear against each other so that the teeth of the maxillae hide the lower teeth in lateral view when the jaws are closed. The fourth to ninth maxillary teeth become progressively more laterally compressed and slightly curved. The tenth to thirteenth teeth of the maxillae are also bicarinate, but show much less lateral compression and are also asymmetrical and widened anteriorly. As a result, the anterior surfaces of these teeth are convex in lateral view. These crowns are also flared at their bases and have smooth enamel surfaces.[1]

The dental bones have fifteen teeth on each side. The pattern of heterodonty in the lower dentition mirrors that of the premaxilla and maxillae. The first five teeth are straight and conical and each has only one dentate tooth and an anterior keel. The sixth through ninth teeth are more laterally compressed and blade-like, and each has a serrated carina on the anterior and posterior edges. These dental crowns are also more convex along their lingual surfaces (the side facing the tongue) than along their labial sides (the side facing outwards). The tenth to fifteenth teeth are more bulbous and curved, and still have two carinae with an intercarinal angle of 180°. There are small depressions along the tooth margin between the adjacent teeth, which disappear posteriorly from the eighth position of the teeth of the dental bones.[1]

A row from a pterygoid bone consists of five teeth and one isolated but associated tooth. The isolated tooth belongs to the same row of teeth of the pterygoids, on the basis of an identical curvature of the crowns. The teeth of the pterygoids are long, approaching the sizes of the posterior marginal teeth, but are significantly smaller than the medial marginal crowns. The two front teeth are thin, straight and tapered, while the last three become progressively smaller and more curved. The isolated tooth is smaller than the marginal dentition and has an enlarged base of the crown. The marked degree of heterodonty in the dentition of the pterygoid bones reflects similar changes in the marginal teeth, where the crowns become smaller, more bulbous, and curved further back. Furthermore, the cross-section of the areas of the bases of the pterygoid teeth in Eremiasaurus do not enlarge forward, contrary to what one would expect for all species tentatively classified within the genus Prognathodon.[1]

Postcranial skeleton

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The exact number of vertebrae in Eremiasaurus is unknown. The most complete specimen, UALVP 51744, lacks many of the dorsal and caudal vertebrae but preserves the cervical column. But excluding this, some vertebrae and other postcranial parts of the animal are well preserved and allow to visualize it as a whole. The ribs get smaller posteriorly, with the ribs numerous and wide on the first and second dorsals before becoming short and thin. Several large thoracic ribs hide the dorsal margin of the scapular blade in lateral view, obscuring the arch formed by the dorsal edge of the scapula.[1]

Eremiasaurus' caudal vertebrae are most similar to Plotosaurus. Among the most notable features are the presence of a ventral deviation of the tail, a fanning of the caudal neural spines, and an unusually long series of pygal (modified sacral) vertebrae. The large number of pygal vertebrae, accompanied by a reduced number of intermediate caudals is unique to Eremiasaurus. The presence of a ventral tail deflection, as in Plotosaurus, and a wide range of neural spines in the same region of the caudal vertebral series suggest a similar development of an incipient dorsal fin lobe in Eremiasaurus, though less developed. These changes in proportions, such as an increase in the number of pygal vertebrae, suggest a high-speed pursuit predator, converging with the vertebral proportions of Plotosaurus.[1]

The scapula and coracoid appear to be sutured tightly anterior to the glenoid fossa. This same pit is also slightly domed, another distinctive feature of the taxon. Posterior to this fossa the posterior edge of the scapula extends dorsally before extending to form the posterior margin of the scapular blade, similar to Clidastes. The lateral aspect of the scapula is wide, smooth and flat. The humerus is subequal in height and width, unlike Mosasaurus and Plotosaurus, where they are wider than they are tall. Like all mosasaurids, the iliac crest is reduced to a forward-leaning cylindrical process. The distal end of the ilium is enlarged and bears facets for articulation with the pubis and ischium. The tibia is a rectangular element, longer proximally than anteroposteriorly. The fibula is bell-shaped, with the distal end being much wider than the proximal end, unlike Mosasaurus and Plotosaurus, where both ends of the fibula are of less width. This bone is also about three-quarters the length of the tibia,[1] unlike Tylosaurus and Platecarpus, in which the fibula is the same length as the tibia.[5] The largest of the known elements of the tarsus is interpreted to be an astragalus. This bone is kidney-shaped, with a pedunculated fibular facet on the dorsal side. The phalanges are elongated spindle-shaped with moderately enlarged epiphyses, different from the stout, block-like proportions seen in Mosasaurus and Plotosaurus.[1]

Classification

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Eremiasaurus is a mosasaurid which is placed in the tribe Mosasaurini, alongside the genera Mosasaurus (shown above, depicted with the contemporaneous species M. beaugei) and Plotosaurus (below)

In one of the several cladograms present in the formal description of the taxon conducted by LeBlanc and colleagues in 2012, Eremiasaurus was placed as a sister group to the tribe Plotosaurini.[1] Plotosaurini is a taxon that was first erected in 1967 by Dale Russell in his scientific work entitled Systematics and morphology of American mosasaurs, from which he revised most North American mosasaurids.[5] The validity of this tribe begins to be questioned from 1997, the year from which the phylogenetic revision of the Mosasauroidea led by Gorden L. Bell Jr. was officially published, considering it polyphyletic and therefore obsolete.[6] The study by LeBlanc et al. (2012) argued that, although not necessarily invalid, dropping Mosasaurini would not follow the general principle of type genus carried over to all ranks in a classification hierarchy, and that the original diagnoses of Plotosaurini are now obsolete. The authors therefore proposed to synonymize the taxon Plotosaurini to Mosasaurini, and place Eremiasaurus in a clade containing Mosasaurus and Plotosaurus based on various cranial characteristics. Characteristics justifying this classification include the presence of a keel in the internarial bar, the exclusion of the prefrontals from the narial borders, narials sunk into the frontal, and the presence of a groove in the quadrate bone.[b][1] The validity of Mosasaurini will be immediately accepted, and the placement of Eremiasaurus as proposed by LeBlanc and colleagues in 2012 will be maintained in various subsequent studies.[7][8][9][10]

A 2017 phylogenetic analysis of the mosasauroids used several analyses to find the most valid classifications, as if a grouping was consistently recorded it was likely a true one.[11] Most phylogenetic trees found Eremaisaurus to be within Mosasaurini,[12] even after refinements were made by a later study.[11] Below is the cladogram from the most recent major phylogenetic analysis of the Mosasaurinae subfamily by Madzia & Cau (2017),[11] which was self-described as a refinement of a larger study by Simões et al. (2017):[12]

Mosasaurinae

Paleoecology

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Life restoration of the marine fauna in the Ouled Abdoun basin during the Upper Cretaceous

The deposits of the Ouled Abdoun Basin in Morocco constituted during the Maastrichtian a large part of what was once the southern margin of the Mediterranean Tethys.[2] Located along the equator, between 20°N and 20°S, the temperate climates were warmer than the northern margin of the paleo-ocean, which was located between 3040°N.[4] This place is represented by a great diversity of aquatic vertebrates, including various bony fishes like Enchodus and Stratodus to cartilaginous fishes like Cretalamna, Squalicorax and Rhombodus.[3] The precise locality from which Eremiasaurus was discovered was already known to have a high number of other mosasaurs, with more than ten genera identified within the Ouled Abdoun Basin. The highly differentiated dental anatomy within the taxa suggests that niche partitioning occurred, in which predators occupied different niches to avoid competition with each other. For example, some mosasaurs identified within this area, such as Globidens and Carinodens, have blunt teeth for crushing shellfish, while mosasaurs such as Mosasaurus, Thalassotitan, and Prognathodon have specialized dentitions for hunting larger prey.[2][3] Although the particular diet of Eremiasaurus is uncertain, its divergence from other stout-toothed mosasaurines would suggest that it specialized in food sources not exploited by its larger Moroccan contemporaries.[1][2] Other marine squamates are known there, including the sea monitor Pachyvaranus and possibly the sea snake Palaeophis. Many sea turtles of the Bothremydidae family have been identified. Plesiosaurs, with the exception of Zarafasaura, are rarely present within the locality.[4]

Notes

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  1. ^ In the specimen OCP DEK/GE 112, twelve teeth can be counted on each side of the skull, but a possible thirteenth may also be present posteriorly, as matrix and bone fragments obscure this area.[1]
  2. ^ The study by LeBlanc et al. (2012) describes this groove as the ala groove.[1]

References

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  1. ^ a b c d e f g h i j k l m n o p q r s t Aaron R. H. Leblanc; Michael W. Caldwell; Nathalie Bardet (2012). "A new mosasaurine from the Maastrichtian (Upper Cretaceous) phosphates of Morocco and its implications for mosasaurine systematics". Journal of Vertebrate Paleontology. 32 (1): 82–104. Bibcode:2012JVPal..32...82L. doi:10.1080/02724634.2012.624145. JSTOR 41407709. S2CID 130559113.
  2. ^ a b c d e f g h i j Nathalie Bardet; Alexandra Houssaye; Peggy Vincent; Xabier Pereda Suberbiola; M'barek Amaghzaz; Essaid Jourani; Saïd Meslouh (2015). "Mosasaurids (Squamata) from the Maastrichtian Phosphates of Morocco: Biodiversity, palaeobiogeography and palaeoecology based on tooth morphoguilds". Gondwana Research. 27 (3): 1068–1078. Bibcode:2015GondR..27.1068B. doi:10.1016/j.gr.2014.08.014. S2CID 140596842.
  3. ^ a b c Nicholas R. Longrich; Nour-Eddine Jalil; Fatima Khaldoune; Oussama Khadiri Yazami; Xabier Pereda-Suberbiola; Nathalie Bardet (2022). "Thalassotitan atrox, a giant predatory mosasaurid (Squamata) from the Upper Maastrichtian Phosphates of Morocco". Cretaceous Research. 140: 105315. Bibcode:2022CrRes.14005315L. doi:10.1016/j.cretres.2022.105315. ISSN 0195-6671. S2CID 251821884.
  4. ^ a b c Nathalie Bardet (2012). "Maastrichtian marine reptiles of the Mediterranean Tethys: a palaeobiogeographical approach". Bulletin de la Société Géologique de France. 183 (6): 573–596. doi:10.2113/gssgfbull.183.6.573. S2CID 140553167.
  5. ^ a b Dale A. Russell (1967). Systematics and morphology of American mosasaurs. Vol. 23. New Haven: Bulletin of the Peabody Museum of Natural History. p. 240. OCLC 205385.
  6. ^ Gorden L. Bell Jr. (1997). "A Phylogenetic Revision of North American and Adriatic Mosasauroidea". Ancient Marine Reptiles. Academic Press. pp. 293–332. doi:10.1016/b978-012155210-7/50017-x. ISBN 978-0-12-155210-7.
  7. ^ Dimitry V. Grigoriev (2013). "Redescription of Prognathodon lutugini (Squamata, Mosasauridae)" (PDF). Proceedings of the Zoological Institute RAS. 317 (3): 246–261. doi:10.31610/trudyzin/2013.317.3.246. S2CID 189800203.
  8. ^ Alessandro Palci; Michael W. Caldwell; Cesare A. Papazzoni (2013). "A new genus and subfamily of mosasaurs from the Upper Cretaceous of northern Italy". Journal of Vertebrate Paleontology. 33 (3): 599–612. Bibcode:2013JVPal..33..599P. doi:10.1080/02724634.2013.731024. JSTOR 42568543. S2CID 86646993.
  9. ^ Fedrico Fanti; Andrea Cau; Alessandra Negri (2014). "A giant mosasaur (Reptilia, Squamata) with an unusually twisted dentition from the Argille Scagliose Complex (late Campanian) of Northern Italy" (PDF). Cretaceous Research. 49 (2014): 91–104. Bibcode:2014CrRes..49...91F. doi:10.1016/j.cretres.2014.01.003. S2CID 129797507.
  10. ^ Paulina Jimenez-Huidobro; Michael W. Caldwell (2016). "Reassessment and reassignment of the early Maastrichtian mosasaur Hainosaurus bernardi Dollo, 1885, to Tylosaurus Marsh, 1872". Journal of Vertebrate Paleontology. 36 (3): e1096275. Bibcode:2016JVPal..36E6275J. doi:10.1080/02724634.2016.1096275. JSTOR 24740320. S2CID 87315531.
  11. ^ a b c Daniel Madzia; Andrea Cau (2017). "Inferring 'weak spots' in phylogenetic trees: application to mosasauroid nomenclature". PeerJ. 5: e3782. doi:10.7717/peerj.3782. PMC 5602675. PMID 28929018.{{cite journal}}: CS1 maint: unflagged free DOI (link)
  12. ^ a b Tiago R. Simões; Oksana Vernygora; Ilaria Paparella; Paulina Jimenez-Huidobro; Michael W. Caldwell (2017). "Mosasauroid phylogeny under multiple phylogenetic methods provides new insights on the evolution of aquatic adaptations in the group". PLOS ONE. 12 (5): e0176773. Bibcode:2017PLoSO..1276773S. doi:10.1371/journal.pone.0176773. PMC 5415187. PMID 28467456.

Further reading

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Nochnitsa

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Amirani1746/sandbox
Temporal range: Permian, 265–252 Ma
 
Holotype block, containing skull and partial skeleton
Scientific classification  
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Clade: Synapsida
Clade: Therapsida
Clade: Gorgonopsia
Genus: Nochnitsa
Kammerer and Masyutin, 2018
Type species
Nochnitsa geminidens
Kammerer and Masyutin, 2018

Nochnitsa is an extinct genus of gorgonopsian therapsids who lived during an uncertain stage of the Permian in what is now European Russia. Only one species is known, N. geminidens, described in 2018 from a single specimen including a complete skull and some postcranial remains, discovered in the red beds of Kotelnich, Kirov Oblast. The genus is named in reference to Nocnitsa, a nocturnal creature from Slavic mythology. The only known specimen of Nochnitsa is one of the smallest gorgonopsians identified to date, with a skull measuring close to 8 cm (3.1 in) in length. The rare postcranial elements indicate that the animal's skeleton should be particularly slender.

Phylogenetic analyzes published since its official description consider it as the most basal gorgonopsian known, due to several anatomical characteristics wo are not present in more or less derived genera. The Vanyushonki Member, the exact site from which Nochnitsa was discovered, would have been a moist, well-vegetated landscape, which would have been periodically flooded. The site contains numerous taxa of contemporary tetrapods, including other various therapsids. The presence of large therocephalians and the smaller size of Nochnitsa and its close relative Viatkogorgon indicate that the latter occupied comparatively small predatory roles.

Discovery and naming

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Map showing the Kotelnich locality in Russia where Nochnitsa was found (lower middle left box, magnified in inset box at upper right)

The only known specimen of Nochnitsa, cataloged KPM 310, was discovered in 1994 by the Russian paleontologist Albert J. Khlyupin in the Red Beds of Kotelnich, located along the Vyatka River in Kirov Oblast, European Russia. This specimen was found more precisely in the Vanyushonki Member, a site already known for the discovery of other contemporary therapsids, including the gorgonopsian Viatkogorgon. The datation of this site is not clear, but it seems to date to the latest Guadalupian or early Lopingian epochs. After this discovery, the specimen was subsequently prepared in the Paleontological Museum of Vyatka [ru] by Olga Masyutina.[1]

In 2018, paleontologists Christian F. Kammerer and Vladimir Masyutin named new genera of gorgonopsians and therocephalians discovered at Kotelnitch in two articles in the scientific journal PeerJ.[1][2] In their paper focusing on gorgonopsians, the specimen KPM 310 is identified as the holotype of a new genus and species, which they name Nochnitsa geminidens.[1]

Nochnitsa is named after the Nocnitsa, a nocturnal hag-like creature from Slavic mythology. Its name was intended as a parallel to the Gorgons, similarly hag-like creatures from Greek mythology, which are the namesake of many genera within Gorgonopsia and the clade as a whole. The name also reflects the nocturnal habits inferred for the genus. The type species name, geminidens, means "twin tooth" and refers to one of the autapomorphies of the species, postcanine teeth arranged in pairs.[1]

Description

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Skull

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Nochnitsa is small for a gorgonopsian, with a skull only 82 millimetres (3.2 in) long. It had a relatively long snout with five incisors, a canine, and six postcanine teeth on each side. The postcanine teeth are autapomorphic for the genus in being arranged in three pairs of closely placed teeth separated by longer diastemata. In each pair, the posterior tooth is larger. The mandible is relatively slender and lacks a strong "chin", unlike other gorgonopsians.[1]

Postcranial skeleton

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Right side of the block containing the holotype specimen, showing in more detail the rare postcranial elements known of the animal

Although incompletely known, the holotype specimen of Nochnitsa contains part of the postcranial elements with the skull, including the cervical vertebrae, some dorsal vertebrae, and associated ribs. The right forelimb is also preserved and partially articulated.[1]

In the cervical vertebrae, the axial spine is broadly rounded and similar in morphology to that of other gorgonopsians. The dorsal vertebrae are preserved as central and transverse process fragments interspersed by the ribs. The ribs are also simple and elongated. The scapula is elongated, narrow and weakly curved, comparable to that of other gorgonopsians of similar size like Cyonosaurus, but different from the anteroposteriorly broadened scapular spines of Inostrancevia.[1]

The humerus is relatively slender, having a short, poorly developed delto-pectoral ridge, where the muscles attach to the upper arm. The radius and ulna, have a distinct distal curvature, and the distal tip of the radius forms a discrete differentiated rim of the shaft. No olecranon process is visible on the ulna, but it is possible that this is the result of a lesion.[a] The preserved proximal carpal elements consist of the radial, the ulnar and two smaller, irregular elements that would probably represent the centralia. The ulnar is the longest carpus on the proximodistal side and is widened at its proximal and distal ends. The radial is a shorter and more rounded element. The possible centralia, although poorly preserved, appear to be weakly curved. The concave surface of the centralia would presumably have been articulated with the radial, based on the conditions of other gorgonopsians.[b] Several small irregular bones between the proximal carpals and the metacarpals probably represent distal carpals, but these elements are too poorly preserved to be further identified. Based on their great length relative to the other manual elements, the two best preserved elements probably represent the third and fourth metacarpals, which are the longest of all other gorgonopsians for which the manus are known. A shorter but still elongated element may represent the fifth metacarpal. A semi-articulated set of poorly preserved bones appear to represent fingers, one potentially ending in the ungual. Based on the size of the phalanx-like elements, these probably correspond to the third and fourth fingers, disarticulated from the third and fourth metacarpals. These elements are too poor for a definitive count of the phalanges, and there is no clear evidence of the reduced disc-shaped phalanges commonly present in gorgonopsians.[1]

Classification

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Skulls of Viatkogorgon and Nochnitsa (reversed for comparison)

Nochnitsa is currently the most basal gorgonopsian known, and its position is justified by several plesiomorphic criteria, such as the lowered mandibular symphysis, the low and inclined front of the dentary bone (similar to those of therocephalians), as well as a surface and a row of elongated teeth. These mentioned features are not present in derived genera.[1] The 2018 analysis by Kammerer and Masyutin, although derived from a previous analysis conducted by one of the two authors,[3] is a major revision of the phylogeny of the gorgonopsians, discovering that the derived representatives are divided into two groups, of Russian and African origin.[1] The basal position of Nochnitsa in phylogenetic analysis of gorgonopsians is still recognized in later published studies.[4][5]

The following cladogram showing the position of Nochnitsa within Gorgonopsia follows Kammerer and Rubidge (2022):[5]

Paleoecology

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Paleoenvironment

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Life restoration of N. geminidens

Nochnitsa is known from the Kotelnich locality, which consists of a series of Permian red bed exposures along the banks of the Vyatka River in Russia. It is specifically from the Vanyushonki Member, which is the oldest rock unit in the Kotelnich succession, consisting of pale or brown mudstones (clay and silts, with some fine-grained sand) as well as gray mudstone, and dark red mudstone at the base of this exposure. These mudstones were possibly deposited from suspension in standing water bodies on floodplains or shallow ephemeral lakes, that remained flooded for short periods of time, but the exact environment has not yet been determined, due to the lack of a primary structure of the sediments. The presence of rootlets, roots and tree stumps would show that the landscape represented by the member of Vanyushonki would be relatively humid and well vegetated. Although the age of the Kotelnitch faunal complex is uncertain, it may date to the same age as those found in South Africa, which date from either the Late Middle Permian or the Early Late Permian.[1][6]

The Vanyushonki Member contains abundant fossils of tetrapods contemporary to Nochnitsa, most including numerous fossils often consisting of articulated and complete skeletons. Apart from its close relative Viatkogorgon, other therapsids from the locality include the anomodont Suminia and the therocephalians Chlynovia, Gorynychus, Karenites, Perplexisaurus, Scalopodon, Scalopodontes, and Viatkosuchus. The pareiasaur Deltavjatia is particularly abundant there, and the parareptile Emeroleter is present.[1][2][7] Fossil ostracods have also been found.[6]

Ecological niche

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As the fossil record shows, the fauna of Kotelnitch was mainly dominated by the large therocephalians, and more specifically by Gorynychus and Viatkosuchus. These two taxa being much larger than Nochnitsa and Viatkogorgon, this indicates that the gorgonopsians occupied smaller predatory roles than the large therocephalians. This is further confirmed by the fact that several gorgonopsians having appeared after the extinction of the end of the Guadalupian reach considerably larger sizes than the two previously mentioned genera.[2][4] This type of ecological niche is also similar to that seen in the Pristerognathus Assemblage Zone in the Karoo Basin, South Africa, prior to the main round of gorgonopsian diversification there.[2] However, he noted that some Guadalupian gorgonopsians, notably Phorcys, are already larger in size, indicating that not all genera shared similar roles.[5]

See also

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  • Viatkogorgon, another gorgonopsian from the Vanyushonki Member.

Notes

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  1. ^ The proximal end of this feature is not complete and was partially replaced by mudstone during the fossilization of the holotype specimen.[1]
  2. ^ A clear intermediate is not visible, as this element is generally small in gorgonopsians and may be absent or still buried in the fossil block containing the holotype specimen.[1]

References

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  1. ^ a b c d e f g h i j k l m n Christian F. Kammerer; Vladimir Masyutin (2018). "Gorgonopsian therapsids (Nochnitsa gen. nov. and Viatkogorgon) from the Permian Kotelnich locality of Russia". PeerJ. 6: e4954. doi:10.7717/peerj.4954. PMC 5995105. PMID 29900078.
  2. ^ a b c d Christian F. Kammerer; Vladimir Masyutin (2018). "A new therocephalian (Gorynychus masyutinae gen. et sp. nov.) from the Permian Kotelnich locality, Kirov Region, Russia". PeerJ. 6: e4933. doi:10.7717/peerj.4933. PMC 5995100. PMID 29900076.
  3. ^ Christian F. Kammerer (2016). "Systematics of the Rubidgeinae (Therapsida: Gorgonopsia)". PeerJ. 4: e1608. doi:10.7717/peerj.1608. PMC 4730894. PMID 26823998.
  4. ^ a b Eva-Maria Bendel; Christian F. Kammerer; Nikolay Kardjilov; Vincent Fernandez; Jörg Fröbisch (2018). "Cranial anatomy of the gorgonopsian Cynariops robustus based on CT-reconstruction". PLOS ONE. 13 (11): e0207367. doi:10.1371/journal.pone.0207367. PMC 6261584. PMID 30485338.
  5. ^ a b c Christian F. Kammerer; Bruce S. Rubidge (2022). "The earliest gorgonopsians from the Karoo Basin of South Africa". Journal of African Earth Sciences. 194: 104631. Bibcode:2022JAfES.19404631K. doi:10.1016/j.jafrearsci.2022.104631. S2CID 249977414.
  6. ^ a b Michael J. Benton; Andrew J. Newell; Al'bert Y. Khlyupin; Il'ya S. Shumov; Gregory D. Price; Andrey A. Kurkin (2012). "Preservation of exceptional vertebrate assemblages in Middle Permian fluviolacustrine mudstones of Kotel'nich, Russia: stratigraphy, sedimentology, and taphonomy". Palaeogeography, Palaeoclimatology, Palaeoecology. 319–320: 58–83. Bibcode:2012PPP...319...58B. doi:10.1016/j.palaeo.2012.01.005.
  7. ^ Elena G. Kordikova; Albert J. Khlyupin (2001). "First evidence of a neonate dentition in pareiasaurs from the Upper Permian of Russia". Acta Palaeontologica Polonica. 46 (4): 589–594. Archived from the original on 27 January 2022. Retrieved 27 January 2022.
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Hyneria

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Amirani1746/sandbox
Temporal range: Late Famennian
 
Block containing holotype specimen of H. uldezinye
Scientific classification  
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Clade: Sarcopterygii
Clade: Tetrapodomorpha
Clade: Eotetrapodiformes
Family: Tristichopteridae
Genus: Hyneria
Thomson, 1968
Type species
H. lindae
Other species

Hyneria is a extinct genus of large predatory lobe-finned fish that lived during the Late Devonian (Famennian). It belongs to the family Tristichopteridae, an extinct lineage of carnivorous fishes, closely related to the ancestors of tetrapods. Two species are known, H. lindae and H. udlezinye, known respectively from the fossil record of present-day North America and South Africa.

With a size generally fixed between 2.5–3 m (8 ft 2 in – 9 ft 10 in) long, all accompanied by a very specialized dentition, Hyneria was undoubtedly a large predator which would not have hesitated to attack prey with large measurements.

Research history

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H. lindae

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The first known fossils of Hyneria lindae were discovered in 1952 by S. R. Ebright in a large road cut on the north side of Pennsylvania Route 120, between the villages of North Bend and Hyner in Clinton County, located in Pennsylvania, USA. The precise place of this find is the site of Red Hill, a locality dating from the upper stage of the Famennian (Upper Devonian).[1] The holotype (MCZ 9284) consists of a disarticulated skull in three blocks. This specimen is soon mentioned in a 1967 article by Keith Stewart Thomson,[2] before being formally described and named the following year by the same author. The genus name Hyneria refers to the village of Hyner in Pennsylvania, close to the site of the discovery of the first fossil individual. The specific epithet lindae comes from the first name of Thomson's wife, the paleontologist who described the animal.[3]

The holotype and paratype specimens were considered as the only viable fossils belonging to the taxon until 1993, when a new collecting effort began to uncover abundant new material within Red Hill,[4] to the point of becoming one of the most abundant vertebrates in terms of presence within the Catskill Formation.[1] Some other fossils of H. lindae have been temporarily described as belonging to other tristichopterid taxa. For example, in 1956, Alfred Romer and a team from Harvard University collected a remarkably complete specimen, which they identified as coming from Eusthenodon wängsjöi. This specimen, cataloged MCZ 8825, was reclassified as H. lindae in the genus rediagnosis conducted by Edward B. Daeschler and Jason P. Downs in 2018.[1]

H. uldezinye

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The specimens referred to the second species H. uldezinye were discovered near the town of Grahamstown in South Africa, and more precisely in the lagerstätte of Waterloo Farm, a geological site dating from the Upper Famennian, i.e. exactly the same age as the Catskill Formation. Several fossils were prepared and subsequently moved to the Albany Museum. The holotype specimen is preserved in two blocks, cataloged AM6540 and AM6528, which additionally contain bones of the stem-tetrapod Umzantsia and the placoderm Groenlandaspis.[5] The presence of the genus Hyneria within this locality was mentioned as early as 2008,[6] in particular on the basis of the comparison with other tristichopterids.[7] The naming and anatomical descriptions are done by Robert W. Gess and Per E. Ahlberg and are officially published in an article in the scientific journal PLOS ONE in February 2023. The specific epithet uldezinye comes from isiXhosa and means "he who eats the others", referring to the inferred predatory lifestyle of the species. The IsiXhosa is the widely spoken native language of southeastern South Africa, where the original fossil locality of the finds is.[5]

Description

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Size

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Hyneria is a bony fish of fairly large proportions, typically ranging in size from 2.5–3 m (98–118 in) in length for H. lindae.[3][4][1][5] The size of the second known species, H. uldezinye, was once estimated to be between 2.5–4 m (98–157 in) long based on fossil analyzes before being described.[7] However, the official description of the taxon shows that the largest known specimens belonging to the species measure at least 2.7 m (110 in).[5]

Other fossil specimens attributed to the genus Hyneria seem to indicate that some representatives could have reached larger measurements, but the weak identifications of the fossil material make these assertions uncertain and require re-evaluations.[8] While the largest known jaw of H. lindae (ANSP 21432), is 38 m (1,500 in) long,[4] another specimen (ANSP 21434), containing the mandibular symphysis and jaw fragments, may have come from a mandible approaching twice that length. However, there are also rhizodontids in the Red Hill fauna, and therefore the specimen might not even belong to the genus, as the dental characteristics observed are present in the latter.[8] Unpublished specimens suggest that Hyneria could have been larger, potentially measuring up to 3.5 m (140 in) in length,[9] but the estimates are based on the dubious fossils previously mentioned[8] and those of the related genus Eusthenopteron.[9]

Skull

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Restoration of the skull of H. udlezinye

The skull roof of Hyneria suggests a broad head with a rounded snout similar to that described for Cabonnichthys and Eusthenodon, but different from the narrow head and "very pointed" snout of Mandageria or the more torpedo-shaped head of Eusthenopteron.[1] As in other tristichopterids, the postorbital bone is triangular in shape and elongated, with a posterior margin that ends in a postero-dorsal process. The maxilla is almost parallel in shape. The maxilla of H. lindae is even more extreme than that of H. udlezinye, in that the contact margin of the squamosal is concave rather than convex.[1][5]

Hyneria's mandible is long yet slender, possessing three coronoids on both sides, two pairs of fangs on the third, and an articulated quadratojugal composed of two longitudinal pits. The fangs of the dentary bones are compressed on the lingual side and have sharp keels on both sides,[1] beings besides very robust and being able to reach more than 5 cm (2.0 in).[4] The row of teeth present in the mandible is aligned and extends to the mandibular symphysis. The general dentition of Hyneria suggests a predator specializing in hunting large preys, although no such interactions are known in the fossil record.[1]

Postcranial skeleton

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Classification

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Paleobiology

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Paleoecology

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North America

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South Africa

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See also

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References

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  1. ^ a b c d e f g h Edward B. Daeschler; Jason P. Downs (2018). "New description and diagnosis of Hyneria lindae (Sarcopterygii, Tristichopteridae) from the Upper Devonian Catskill Formation in Pennsylvania, U.S.A." Journal of Vertebrate Paleontology. 38 (3): e1448834. doi:10.1080/02724634.2018.1448834. S2CID 89661336.
  2. ^ Keith S. Thomson (1967). "Mechanisms of intracranial kinetics in fossil rhipidistian fishes (Crossopterygii) and their relatives". Zoological Journal of the Linnean Society. 46 (310): 223–253. doi:10.1111/j.1096-3642.1967.tb00505.x. S2CID 85884646.
  3. ^ a b Keith S. Thomson (1968). "A new Devonian fish (Crossopterygii: Rhipidistia) considered in relation to the origin of the Amphibia". Postilla. 124: 1–13.
  4. ^ a b c d Edward B. Daeschler; Neil H. Shubin (2007). "New data on Hyneria lindae (Sarcopterygii, Tristichopteridae) from the Late Devonian of Pennsylvania, USA". Journal of Vertebrate Paleontology. 27 (S3). doi:10.1080/02724634.2007.10010458.
  5. ^ a b c d e Robert W. Gess; Per E. Ahlberg (2023). "A high latitude Gondwanan species of the Late Devonian tristichopterid Hyneria (Osteichthyes: Sarcopterygii)". PLOS ONE. 18 (2): e0281333. doi:10.1371/journal.pone.0281333. PMC 9946258. PMID 36812170.
  6. ^ Robert W. Gess; Michael I. Coates (2008). "Vertebrate diversity of the Late Devonian (Famennian) deposit near Grahamstown, South Africa". Journal of Vertebrate Paleontology. 28 (3): 83.
  7. ^ a b Robert W. Gess; Alan K. Whitfield (2020). "Estuarine fish and tetrapod evolution: insights from a Late Devonian (Famennian) Gondwanan estuarine lake and a southern African Holocene equivalent". Biological Reviews. 95 (4): 865–888. doi:10.1111/brv.12590. PMID 32059074. S2CID 211122587.
  8. ^ a b c Ben Young; Robert L. Dunstone; Timothy J. Senden; Gavin C. Young (2013). "A Gigantic Sarcopterygian (Tetrapodomorph Lobe-Finned Fish) from the Upper Devonian of Gondwana (Eden, New South Wales, Australia)". PLOS ONE. 8 (3): e53871. Bibcode:2013PLoSO...853871Y. doi:10.1371/journal.pone.0053871. PMC 3590215. PMID 23483884.
  9. ^ a b Russell K. Engelman (2023). "A Devonian Fish Tale: A New Method of Body Length Estimation Suggests Much Smaller Sizes for Dunkleosteus terrelli (Placodermi: Arthrodira)". Diversity. 15 (3): 318. doi:10.3390/d15030318. S2CID 257131934.
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