删除或更新信息,请邮件至freekaoyan#163.com(#换成@)

新疆迟滞鳄类新材料

本站小编 Free考研考试/2022-01-03

刘俊,1,2,31 中国科学院古脊椎动物与古人类研究所,中国科学院脊椎动物演化与人类起源重点实验室 北京 100044
2 中国科学院生物演化与环境卓越创新中心 北京 100044
3 中国科学院大学地球与行星科学学院 北京 100049

New chroniosuchian materials from Xinjiang, China

LIU Jun,1,2,31 Key Laboratory of Vertebrate Evolution and Human Origins of Chinese Academy of Sciences, Institute of Vertebrate Paleontology and Paleoanthropology, Chinese Academy of Sciences Beijing 100044
2 CAS Center for Excellence in Life and Paleoenvironment Beijing 100044
3 College of Earth and Planetary Sciences, University of Chinese Academy of Sciences Beijing 100049

通讯作者: liujun@ivpp.ac.cn

收稿日期:2020-01-10网络出版日期:2020-10-20
基金资助:中国科学院战略性先导科技专项(B类).XDB26000000
国家自然科学基金.41572019
国家自然科学基金.41661134047
美国国家自然科学基金.NSF EAR 1714749


Corresponding authors: liujun@ivpp.ac.cn
Received:2020-01-10Online:2020-10-20


摘要
迟滞鳄类最早的化石记录来自甘肃玉门的大山口动物群,但是中国此类动物的化石记录相对俄罗斯来说少了许多,尤其是三叠纪的。新疆已知唯一的一件标本出自锅底坑组上部。报道了产自不同层位的3件迟滞鳄类新材料,分别出自泉子街组、锅底坑组底部以及韭菜园组。这些新发现丰富了中国迟滞鳄类的多样性以及时代延限。来自锅底坑组及韭菜园组的毕氏螈科(Bystrowianidae)材料表明这类动物在二叠纪末期大灭绝中在新疆生存了下来。
关键词: 新疆;二叠系;三叠系;泉子街组;锅底坑组;韭菜园组;毕氏螈科;迟滞鳄类

Abstract
Chroniosuchians have the earliest representatives in Gansu, China, but the Chinese records were scarcer compared to Russia, especially the Triassic one. In Xinjiang, there was only one specimen reported from the upper part of the Guodikeng Formation. Here three new chroniosuchian specimens are reported from three new stratigraphic horizons: the Quanzijie Formation (middle Permian), the base of the Guodikeng Formation (upper Permian), and the Jiucaiyuan Formation (Lower Triassic). The osteoderm from the Jiucaiyuan Formation represents the first definite Triassic chroniosuchian from China. The new findings increase the chroniosuchian diversity and their time range in China. The bystrowianid chroniosuchian specimens from the Guodikeng and Jiucaiyuan formations demonstrated that this group survived in the end-Permian mass extinction in Xinjiang, China.
Keywords:Xinjiang, China;Permian;Triassic;Quanzijie Formation;Guodikeng Formation;Jiucaiyuan Formation;Bystrowianidae;chroniosuchians


PDF (2246KB)元数据多维度评价相关文章导出EndNote|Ris|Bibtex收藏本文
本文引用格式
刘俊. 新疆迟滞鳄类新材料. 古脊椎动物学报[J], 2020, 58(4): 283-292 DOI:10.19615/j.cnki.1000-3118.200415
LIU Jun. New chroniosuchian materials from Xinjiang, China. Vertebrata Palasiatica[J], 2020, 58(4): 283-292 DOI:10.19615/j.cnki.1000-3118.200415


1 Introduction

The chroniosuchians were an enigmatic clade of non-amniotic tetrapods with uncertain phylogenetic position (Clack and Klembara, 2009; Schoch et al., 2010; Buchwitz et al., 2012; Witzmann and Schoch, 2018; Marjanovic? and Laurin, 2019). This group can be divided into two families, Bystrowianidae and Chroniosuchidae (Ivakhnenko and Tverdokhlebova, 1980; Novikov et al., 2000; Witzmann et al., 2019). The earliest representatives of both families are known from the middle Permian Dashankou fauna, Gansu, China (Li and Cheng, 1999; Jiang et al., 2017). The latest representative of Chroniosuchidae is known only from a single Triassic taxon, Madygenerpeton pustulatus, from the Ladinian or Carnian of Kyrgyzstan (Schoch et al., 2010); while those of Bystrowianidae are known from Middle Triassic of Russia and Germany (Novikov and Shishkin, 2000; Witzmann et al., 2008; Witzmann and Schoch, 2018).

This group was first reported from the late Permian Jiyuan fauna in China, i.e., Bystrowiana sinica (Young, 1979); later, two more species were named and referred to Bystrowianidae for this fauna (Jiyuanitectum flatum and Dromotectum largum) (Liu et al., 2014). Some postcranial bones were identified as bystrowianid from the Permo-Triassic Guodikeng Formation of Jimusar, Xinjiang, China (Liu and Abdala, 2017), but no definite Triassic chroniosuchian is known from China up to now. Our recent fieldwork showed that chroniosuchians were a diverse and persistent group in Xinjiang: they survived from the late Permian to at least the Early Triassic here. In this paper we reported three new chroniosuchian specimens from Xinjiang (Fig. 1), including the first definite Triassic one from the Jiucaiyuan Formation.

Fig. 1

新窗口打开|下载原图ZIP|生成PPT
Fig. 1Permian to Triassic stratigraphic sequence within Turpan-Hami Basin, Xinjiang, showing the horizons of studying specimens



Abbreviations IVPP, Institute of Verte-brate Paleontology and Paleoanthropology, Chinese Academy of Sciences; SMNS, Staatliches Museum für Naturkunde Stuttgart, Germany.

2 Systematic paleontology



Material IVPP V 26539, a left femur (Fig. 2).

Fig. 2

新窗口打开|下载原图ZIP|生成PPT
Fig. 2Chroniosuchian left femur (IVPP V 26539) from the Quanzijie Formation in Jimusar, Xinjiang in extensor (A), anterior (B), flexor (C), proximal (D), and distal (E) views

Abbreviations: ab. adductor blade; ac. anterior (tibial) condyle; adc. adductor crest; ff. fibula fossa;
icg. intercondylar groove; it. internal trochanter; itf. intertrochanteric fossa; pa. popliteal area;
pc. posterior (fibular) condyle


Locality and horizon Dalongkou section, Santai, Jimusar, Xinjiang, China; upper part of Quanzijie Formation (middle Permian).

Description The femur is slightly dorsoventrally compressed, and is not so curved as the femur of IVPP V 23295 (Liu and Abdala, 2017). It is slender and waisted as other chroniosuchians (Clack and Klembara, 2009; Liu and Abdala, 2017). The anterior margin is more concave than the posterior margin. The length of the bone is 40 mm, and the width is 13, 15 mm respectively for the proximal and distal ends. Both expanded ends are incompletely ossified. The unfinished proximal articular surface is convex in outline dorsally and slightly concave ventrally when viewed mesially (Fig. 2D). It extends anteroventrally, forms a continuous surface with the unfinished internal trochanter. The proximal articular surface decreases in dorsoventral height backwards and forms a pointed angle posteriorly.

The dorsal surface of the femur bears striations on the proximal side (Fig. 2A). The dorsal surface of the distal end of the femur is divided by a relatively broad intercondylar groove (Fig. 2E). The anterior condyle extends slightly wider than the posterior one. Due to the incomplete ossification, the anterior condyle projects distally similar to the posterior condyle. The anterodorsal surface of the anterior condyle, near the middle, bears distinct longitudinal ridges for ligaments.

The adductor blade is low, directed posteroventrally, forming the anterior margin of the large intertrochanteric fossa (Fig. 2B). The anterior surface of the adductor blade is rugose. Distal to the adductor blade, a low but distinct adductor crest is slightly curved, runs distally near the posterior margin of the shaft on the ventral surface, and ends by a crack (Fig. 2C). Distal to the crest, there is a low ridge to a point close to the triangular popliteal area. However, it is likely separated from the adductor crest. Posterior to it, another crest runs on the posterior side of the shaft ending on the distal posterior corner. Two crests frame the small fibula fossa on the posteroventral corner of the distal end.

Discussion The shape of this femur is primitive among tetrapods. However, it is slender, similar to that of temnospondyls like Trimerorhachis (Pawley, 2007) or chroniosuchians (Clack and Klembara, 2009; Liu and Abdala, 2017; Witzmann and Schoch, 2018), rather than robust as in many other basal tetrapod groups (Witzmann and Schoch, 2018; Bazzana et al., 2020). As in IVPP V 23295 and Bystrowiella schumanni, the adductor crest follows a diagonal course, ending distally close to the posterior margin of the shaft (Liu and Abdala, 2017; Witzmann and Schoch, 2018). In most Permian tetrapods, adductor crest generally runs towards, not posterior to the popliteal area (Fox and Bowman, 1966; Klembara and Bartík, 2000; Pawley, 2007). This could be a diagnostic character of chroniosuchians.

IVPP V 26539 also shares the following features with other chroniosuchian femurs (V 23295 and SMNS 96948): the adductor blade is directed posteroventrally, and the posterior end of the proximal articular surface is pointed. So this specimen can be referred to Chroniosuchia.

This specimen has unfinished ends, as in the much longer femur of SMNS 96948, may indicated juvenile state of both specimens. Meanwhile, a medium sized femur of V 23295 is well-ossified, indicated that species has a smaller adult size.



Material IVPP V 26540, four vertebrae, one rib, and several scutes (Fig. 3).

Fig. 3

新窗口打开|下载原图ZIP|生成PPT
Fig. 3Bystrowianid specimen (IVPP V 26540) from the Guodikeng Formation in Turpan, Xinjiang

A-B. four continuous vertebrae in ventral (A) and right lateral (B) views;
C-D. isolated vertebra in anterior (C) and posterior (D) views; E. an incomplete rib;
F-G. the impression of dorsal surface of three osteoderms (F) and two osteoderms (G)
Abbreviations: dp. diapophysis; ic. intercentrum; ns. neural spine; pc. pleurocentrum; pnc. paraneural canal; poz. postzygapophysis; pp. parapophysis; prz. prezygapophysis; tp. transverse process;
vp. ventral process of osteoderm; vr. ventral ridge


Locality and horizon Taoshuyuan (Taoxigou) section, Turpan, Xinjiang; base of the Guodikeng Formation (upper Permian).

Description There are four articulated and one isolated vertebrae, two of them are nearly complete (Fig. 3). They are identified as the vertebrae around sacral region. The vertebrae have a basic shape of Bystrowianidae (Liu et al., 2014; Liu and Abdala, 2017; Witzmann and Schoch, 2018).

Intercentra Only two articulated intercentra are exposed (Fig. 3A, B). The anterior one shows smooth periosteal bone on ventral and lateral surfaces. Its lateral surface bears part of the parapophyses for articulation with the capitulum near the posterior margin, and ventral surface has no haemal arch. In lateral view, its length relative to the pleurocentrum is similar to IVPP V 23295, much narrower than in Chroniosaurus dongusensis (Clack and Klembara, 2009).

Pleurocentra The lengths of the pleurocentra are approximately 10 mm, while the heights are about 9 mm (Fig. 3A, B). The pleurocentra are massive with a round cross-section, and they are not perforated by the notochord (Fig. 3C, D). The ventral surface is relatively flat (slightly convex on the anterior one, slightly concave on the posterior one) with faint ventral ridges on three articulated larger pleurocentra. Two longitudinally aligned, low ridges are clear on the narrow ventral face of the smaller pleurocentrum of the isolated vertebra. This feature was proposed as a bystrowianid characteristic (Witzmann and Schoch, 2018). The neural arches are fused to the pleurocentra, but their suture is clear; so this specimen looks like in a younger stage than V 23295, in which the suture is absent. This suture runs across the diapophysis in three articulated vertebrae, indicating the pleurocentrum participates in formation of the diapophysis. On two posterior pleurocentra, the anterior half of the ventrolateral surface participates in formation of the parapophysis, which is separated from the diapophysis by a narrow groove. So they are identified as the sacral and the first caudal vertebrae, as in Kotlassia (Bystrow, 1944) and Proterogyrinus (Holmes, 1984).

Neural arches The prezygapophyses are oriented dorsomedially and slightly anteriorly, and the postzygapophyses are oriented ventrolaterally and posteriorly (Fig. 3B-D). The paired openings of the paraneural canals are visible between and ventral to the zygapophyses on anterior and posterior surface in the better prepared isolated vertebra as in other bystrowianids (Tatarinov, 1972; Novikov and Shishkin, 2000; Witzmann et al., 2008; Liu et al., 2014; Liu and Abdala, 2017; Witzmann and Schoch, 2018). The openings are large as in Axitectum (Novikov and Shishkin, 2000), Bystrowiana (Liu et al., 2014) and V 23295 (Liu and Abdala, 2017), much bigger than those of Synesuchus (Novikov and Shishkin, 2000) and Bystrowiella (Witzmann et al., 2008; Witzmann and Schoch, 2018).

The transverse processes are very short and massive, directed ventrolaterally. The facets of the diapophyses are strongly enlarged in the sacral and first caudal. In the isolated vertebra, the transverse processes are completely formed by the neural arch. It is probably derived from the anterior tail region.

The neural spines are only nearly complete in the sacral vertebra and one isolated caudal vertebra. The neural spines are anteroposteriorly slightly shorter than the pleurocentrum. In the sacral, its anterior and posterior margins are nearly parallel. Its height is less than twice the height of the pleurocentrum. Its dorsal tip is connected with the osteoderm by interdigitating sutures. In the isolated caudal, the neural spine widens dorsally near the tip then narrows. Its dorsal tip does not carry an osteoderm.

Rib A curved incomplete rib measures more than 5 cm in original length (Fig. 3E). The proximal side is not preserved.

Osteoderms There are two pieces of impression of the dermal surface of the osteoderms, one with three osteoderms, and the other with two osteoderms (Fig. 3F, G). Neither of the osteoderms is complete, so it is unsure on the width of the osteoderms. The distinct dermal sculpturing is composed of ridges and depressions. A mid-ridge is preserved. The pits have different sizes on two sides of the ridge, and they likely arrange in posterolaterally radiated line. No prominent parasagittal ridge is observed.

Discussion This specimen is diagnosed as a bystrowianid chroniosuchian for the presence of the sculptured dorsal osteoderms which are sutured with the neural spine, paired deep paraneural canals on anterior and posterior surfaces of the neural arch. It cannot be further diagnosed for the poor preservation of the osteoderms.



Material IVPP V 26541, an incomplete dorsal osteoderm (Fig. 4).

Fig. 4

新窗口打开|下载原图ZIP|生成PPT
Fig. 4Bystrowianid osteoderm (IVPP V 26541) from the Jiucaiyuan Formation in Jimusar, Xinjiang in dorsal (A), ventral (B), and posterior (C) views

Abbreviations: am. area marginalis; ap. accessory process; aw. anterior wing; cl. lateral crista;
cm. medial crista; co. crista obliqua; df. dorsal facet; dv. ventral depression; fa. facies alaris;
pv. ventral process; sa. sulcus articularis


Locality and horizon 18J15 (N43°56′6.8″, E88°54′19.5″) (4 km east to the Dalongkou section), Santai, Jimusar, Xinjiang; Jiucaiyuan Formation (Lower Triassic).

Description The single osteoderm is slightly convex dorsally. Most of the margins are broken other than right anterolateral margin (Fig. 4). The complete width should be approximately 3 cm.

The dermal sculpture is not symmetric, and it is dominated by different-sized polygonal pits formed mainly by longitudinally oriented and oblique ridges. Transversely elongated sculptural depressions are only present near the posterior area. The sculpture has no axial crest or any parasagittal ridge, as in Synesuchus muravjevi or Dromotectum spinosum (Novikov and Shishkin, 2000). The right anterior wing is preserved its posterior portion, with a smooth dorsal facet for the facies alaris (ventral facets) of the preceding osteoderm. The right accessory process is also partially preserved. The maximum width of one anterior wing is estimated as 9 mm, slightly smaller than the width of accessory processes.

The incomplete median articular plate measures 10 mm in width. It lies posteriorly and slightly ventral to the sculptured dorsal plate. The median crista decreases in width backwards and is triangular in shape in dorsal view. The broad lateral cristae are longer than and located at the same level as the median crista. Most parts of these cristae are formed by tapered extensions of the posterior margin of the sculptured dorsal plate. As most bystrowianids, two deep longitudinal grooves (sulci articulares) lies between the median and lateral crests, for accommodation of the accessory processes and associated ligaments of the successive osteoderm (Novikov and Shishkin, 2000; Shishkin et al., 2014). The area marginalis (marginal zone) is incompletely preserved on the right side. It extends anteriorly ventral to the dorsal plate as in Bystrowiana and Jiyuanitectum (Novikov and Shishkin, 2000; Liu et al., 2014).

On the ventral surface, the shallow median depression, between the anterior wings back to the base of the ventral process, is preserved for most of the right side and nearly posterior half of the left side. The ridge extends from the right accessory process is distinct. The sulcus medius (median groove) should be narrow. A broad, low but distinct crista obliqua (oblique crest) extends along the ventral surface of the osteoderm posteromedially from the anterior wings toward the region of the ventral process, and continuous to the margin zone of the median articular plate. Lateral to the ventral margin, a shallow depression on the posterior part of the ventral surface is the ventral facet that overlapped the dorsal facet of the anterior wing of the succeeding osteoderm.

The base of the ventral process is located in the posterior half of the osteoderm, and its posterior margin extends posteriorly beyond the boundary of the sculptured surface of the osteoderm. The process is ovate in transverse section and lacks anterior and posterior extensions.

Discussion IVPP V 26541 can be referred to Bystrowianidae based on the unpaired posterior articular plate and weakly expanded plate bearing broadly separated anterior facets. This specimen is coded for the osteoderm characters of Witzmann et al. (2019) (Appendix 1), and the coding of character 1 of Dromotectum is changed to 1&2 because the ratio is greater than 1.5 in D. abditum (Shishkin et al., 2014). A single most parsimonious tree (length=33) is recovered and nearly identical to figure 5 of Witzmann et al. (2019) other than IVPP V 26541 forming the sister-group of Dromotectum. However, no synapomorphy supports this clade. IVPP V 26541 shares one synapomorphy with the clade (Vyushkoviana + (Dromotectum + Axitectum)): the absence of parallel to subparallel transversal bars present in the dorsal ornamentation (3). It also shares two of four synapomorphies with the clade (Dromotectum + Axitectum): axial process of posterior articular plate is positioned at the same level as the lateral processes (13) and posterior part of the base of the ventral process positioned posterior to the boundary of the ornamented region (21). However, it is different from them by the osteoderm plate with an angle between neural spine and osteoderm plate greater than 70° (19). IVPP V 26541 represents a new taxon closely related to Dromotectum. However, it is not named here and should be named on more complete material. Its close relationship with Dromotectum is not surprise, because Dromotectum existed in the upper Permian of Henan, China (Liu et al., 2014).

3 Discussion and conclusion

The new specimens described here increase the diversity of Permo-Triassic tetrapods. Previously, only one tetrapod species, Kunpania scopulusa, was reported from the top of the Quanzijie Formation (Sun, 1978). Also, only one chroniosuchian specimen was reported from the Guodikeng Formation (Liu and Abdala, 2017). Although chroniosuchian should have existed from middle Permian in Xinjiang based on their known distributions, this is the first evidence which confirmed its existence from the Quanzijie Formation. The bystrowianian chroniosuchian specimens from the base and the top of the Guodikeng Formation and the Jiucaiyuan Formation demonstrated that this group survived in the end-Permian mass extinction here in Xinjiang, together with Lystrosaurus.

Acknowledgements

Thanks to field crew to Xinjiang in 2018 and 2019, especially Liu Yu-Dong and Wang Ming-Li who discovered two of the studied specimens. FU Hua-Lin and Lan Li-Li prepared the specimens. Jozef Klembara and Igor V. Novikov kindly reviewed the paper. This work is supported by Strategic Priority Research Program of Chinese Academy of Sciences (XDB26000000), National Natural Science Foundation of China (41572019, 41661134047), and National Natural Science Foundation of USA (NSF EAR 1714749).

Appendix 1 Coding of IVPP V 26541 for the osteoderm characters of Witzmann et al. (2019)

11111 101?? 11011 01001 11

参考文献 原文顺序
文献年度倒序
文中引用次数倒序
被引期刊影响因子

Bazzana K D, Gee B M, Bevitt J J et al., 2020. Postcranial anatomy and histology of Seymouria, and the terrestriality of seymouriamorphs
PeerJ, 8:e8698

URLPMID [本文引用: 1]

Buchwitz M, Foth C, Kogan I et al., 2012. On the use of osteoderm features in a phylogenetic approach on the internal relationships of the Chroniosuchia (Tetrapoda: Reptiliomorpha)
Palaeontology, 55(3):623-640

[本文引用: 1]

Bystrow A P, 1944. Kotlassia prima Amalitzky
Geol Soc Am Bull, 55(4):379-416

[本文引用: 1]

Clack J A, Klembara J, 2009. An articulated specimen of Chroniosaurus dongusensis and the morphology and relationships of the chroniosuchids
Spec Pap Palaeontol, 81:15-42

[本文引用: 4]

Fox R C, Bowman M, 1966. Osteology and relationships of Captorhinus aguti (Cope) (Reptilia: Captorhinomorpha)
Univ Kansas Paleontol Contrib Vertebr, 11:1-79

[本文引用: 1]

Holmes R, 1984. The Carboniferous Amphibian Proterogyrinus scheelei Romer, and the early evolution of tetrapods
Philos Trans R Soc B: Biol Sci, 306:431-524

[本文引用: 1]

Ivakhnenko M F, Tverdokhlebova G I, 1980. Systematics, Morphology, and Stratigraphic Significance of the Upper Permian Chroniosuchians from the East of the European Part of the USSR
Saratov: Izdatel’stvo Saratovskogo Universiteta. 1-69

[本文引用: 1]

Jiang S, Ji S A, Mo J Y, 2017. First record of bystrowianid chroniosuchians (Amphibia: Anthracosauromorpha) from the Middle Permian of China
Acta Geol Sin-Engl Ed, 91(5):1523-1529

[本文引用: 1]

Klembara J, Bartík I, 1999. The postcranial skeleton of Discosauriscus Kuhn, a seymouriamorph tetrapod from the Lower Permian of the Boskovice Furrow (Czech Republic)
Trans R Soc Edinb-Earth Sci, 90(4):287-316

[本文引用: 1]

Li J L, Cheng Z W, 1999. New anthracosaur and temnospondyl amphibians from Gansu, China - the fifth report on Late Permian Dashankou lower tetrapod fauna
Vert PalAsiat, 37(3):234-247

[本文引用: 1]

Liu J, Abdala F, 2017. Therocephalian (Therapsida) and chroniosuchian (Reptiliomorpha) from the Permo-Triassic transitional Guodikeng Formation of the Dalongkou Section, Jimusar, Xinjiang, China
Vert PalAsiat, 55(1):24-40

[本文引用: 9]

Liu J, Xu L, Jia S H et al., 2014. The Jiyuan tetrapod fauna of the Upper Permian of China - 2. stratigraphy, taxonomical review, and correlation with other assemblages
Vert PalAsiat, 52(3):328-339

[本文引用: 6]

Marjanovic? D, Laurin M, 2019. Phylogeny of Paleozoic limbed vertebrates reassessed through revision and expansion of the largest published relevant data matrix
PeerJ, 6:e5565

DOIURLPMID [本文引用: 1]
The largest published phylogenetic analysis of early limbed vertebrates (Ruta M, Coates MI. 2007. Journal of Systematic Palaeontology 5:69-122) recovered, for example, Seymouriamorpha, Diadectomorpha and (in some trees) Caudata as paraphyletic and found the

Novikov I V, Shishkin M A, 2000. Triassic chroniosuchians (Amphibia, Anthracosauromorpha) and the evolution of trunk dermal scutes in bystrowianids
Paleontol J, 34(S2):165-178

[本文引用: 8]

Novikov I V, Shishkin M A, Golubev V K, 2000. Permian and Triassic anthracosaurs from eastern Europe
In: Benton M J, Shishkin M A, Unwin D M et al. eds. The Age of Dinosaurs in Russia and Mongolia. Cambridge: Cambridge University Press. 60-70



Pawley K A T, 2007. The postcranial skeleton of Trimerorhachis insignis cope, 1878 (Temnospondyli: Trimerorhachidae): a plesiomorphic temnospondyl from the Lower Permian of North America
J Paleontol, 81(5):873-894

[本文引用: 2]

Schoch R R, Voigt S, Buchwitz M, 2010. A chroniosuchid from the Triassic of Kyrgyzstan and analysis of chroniosuchian relationships
Zool J Linn Soc, 160(3):515-530

[本文引用: 2]

Shishkin M A, Novikov I V, Fortuny J, 2014. New bystrowianid chroniosuchians (Amphibia, Anthracosauromorpha) from the Triassic of Russia and diversification of Bystrowianidae
Paleontol J, 48(5):512-522

[本文引用: 2]

Sun A L, 1978. Two new genera of Dicynodontidae
Mem Inst Vert Paleont Paleoanthrop, Acad Sin, 13:19-25

[本文引用: 1]

Tatarinov L P, 1972. Seymouriamorphen aus der Fauna der USSR
In: Kuhn O ed. Handbuch der Pal?oherpetologie, Part 5B. Stuttgart: Gustav Fischer Verlag. 70-80

[本文引用: 1]

Vjuschkov B P, 1957. New unusual animals from the Tatarian deposits of the European part of the USSR
Dokl Akad Nauk SSSR, 113:183-186



Witzmann F, Schoch R R, 2018. Skull and postcranium of the bystrowianid Bystrowiella schumanni from the Middle Triassic of Germany, and the position of chroniosuchians within Tetrapoda
J Syst Palaeont, 16(9):711-739

[本文引用: 9]

Witzmann F, Schoch R R, Maisch M W, 2008. A relict basal tetrapod from Germany: first evidence of a Triassic chroniosuchian outside Russia
Naturwissenschaften, 95:67-72

DOIURLPMID [本文引用: 3]
Chroniosuchians are basal tetrapods nesting within the paraphyletic anthracosaurs and were so far only well known from the Permian and Triassic of Russia. In this study, we present evidence for their existence in the upper Middle Triassic of Germany, based on diagnostic osteoderms and vertebrae from the Kupferzell and Vellberg localities in southern Germany. The finds are most similar to Synesuchus, a Middle Triassic bystrowianid chroniosuchian from the Northern Ural Pechora region. They demonstrate that by Middle Triassic time, chroniosuchians were much more widespread than previously thought.

Witzmann F, Sues H-D, Kammerer C F et al., 2019. A new bystrowianid from the late Permian of Germany: first record of a Permian chroniosuchian (Tetrapoda) outside Russia and China
J Vert Paleontol, e1667366

[本文引用: 4]

Young C C, 1979. A late Permian fauna from Jiyuan, Henan
Vert PalAsiat, 17(2):99-113

[本文引用: 1]

相关话题/中国科学院 新疆 北京 动物 本文