Hostname: page-component-78c5997874-j824f Total loading time: 0 Render date: 2024-11-19T05:50:49.178Z Has data issue: false hasContentIssue false

Micromammals from the late early Miocene of Çapak (western Anatolia) herald a time of change

Published online by Cambridge University Press:  19 April 2021

Melike Bilgin
Affiliation:
Comenius University, Department of Geology and Palaeontology, SK-84215, Bratislava, Slovakia , Naturalis Biodiversity Center, Darwinweg 2, 2333 CR Leiden, The Netherlands
Peter Joniak
Affiliation:
Comenius University, Department of Geology and Palaeontology, SK-84215, Bratislava, Slovakia ,
Serdar Mayda
Affiliation:
Ege University, Faculty of Science, Biology Department, Bornova, Izmir, Turkey
Fikret Göktaş
Affiliation:
MTA Geology Department, Ankara, Turkey
Pablo Peláez-Campomanes
Affiliation:
Museo Nacional de Ciencias Naturales, MNCN-CSIC, C/ José Gutiérrez Abascal, 2, 28006, Madrid, Spain
Lars W. van den Hoek Ostende
Affiliation:
Naturalis Biodiversity Center, Darwinweg 2, 2333 CR Leiden, The Netherlands

Abstract

The new fossil micromammal assemblage of Çapak represents a mixture of both Anatolian and European faunal elements. The locality is very important for understanding faunal evolution in the less well-known time interval at the end of the early Miocene of western Anatolia. In Çapak, nine species of rodents and one species of ochotonid were encountered: the hamsters Democricetodon gracilis, Megacricetodon primitivus, Eumyarion aff. E. montanus, Cricetodon cf. C. aliveriensis, Cricetodon sp., and Karydomys cf. K. strati, the mole-rat Debruijnia sp., the squirrel Aliveria luteyni, the dormouse Myomimus tanjuae n. sp., and the pika Albertona balkanica. The assemblage is referable to Anatolian local zone E or MN unit 4. The relative abundance of the various genera is markedly different from that of the older early Miocene assemblages, suggesting that the environment in Anatolia became drier and had a more open landscape.

UUID: http://zoobank.org/75f3276c-dcd8-4090-b2f6-d8fc8d3c3f7c

Type
Articles
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press on behalf of The Paleontological Society

Introduction

The late early Miocene was a period of major changes in the eastern Mediterranean. The collision of the African plate with Eurasia altered both the topography of the region and its climates, offering new migration routes (Rögl, Reference Rögl1999). Anatolia lies right at the center of these events that strongly influenced the distribution of mammals both within the region as well as in other parts of western Eurasia.

The early Miocene of Anatolia shows a high degree of endemicity in taxa of the rodent assemblages between local zones B to D (correlated with MN1-3). While European assemblages are dominated by Eomyidae and Gliridae, Anatolian assemblages are dominated by Muridae. At the beginning of MN4, there was a conspicuous faunal turnover in Europe. After a prolonged absence, known as the cricetid vacuum (Daams and Freudenthal, Reference Daams and Freudenthal1981), muroid rodents entered and immediately took the dominant position they still hold today (De Bruijn et al., Reference De Bruijn, Daams, Daxner-Höck, Fahlbusch, Ginsburg, Mein and Morales1992). This entrance of the hamsters traditionally marks the transition between the mammal units MN3 and MN4. Notably, earlier research showed that the hamster genera entering Europe at the end of the early Miocene were already present throughout that period in Anatolia (e.g., De Bruijn and Saraç, Reference De Bruijn and Saraç1991; Theocharopoulos, Reference Theocharopoulos2000; De Bruijn et al., Reference De Bruijn, Mayda, Van den Hoek Ostende, Kaya and Saraç2006; Wessels, Reference Wessels2009). However, while there are well-studied faunas from the region between zones B–D (correlated with MN1–3), such as Kargı, Kılçak, Harami, Gökler, Gördes, Sabuncubeli, Keseköy (e.g., Van den Hoek Ostende, Reference Van den Hoek Ostende1992, Reference Van den Hoek Ostende1995, Reference Van den Hoek Ostende1997, Reference Van den Hoek Ostende2001; Ünay, Reference Ünay1994; Joniak et al., Reference Joniak, Peláez-Campomanes, Van den Hoek Ostende and Rojay2017, Reference Joniak, Peláez-Campomanes, Mayda, Bilgin, Halaçlar, Van den Hoek Ostende, Van den Hoek Ostende, Mayda and Kaya2019; Peláez-Campomanes et al., Reference Peláez-Campomanes, Göktaş, Kaya, Joniak, Bilgin, Mayda, Van den Hoek Ostende, Van den Hoek Ostende, Mayda and Kaya2019), the younger assemblages are little known, published only as faunal lists or abstracts, such as in the localities of Söke, Dededağ, Belenyenice, Kaplangı, and Horlak (e.g., Sümengen et al., Reference Sümengen, Ünay, de Bruijn, Terlemez, Gürbüz, Lindsay, Fahlbusch and Mein1990; Ünay and Göktaş Reference Ünay and Göktaş1999; Kaya et al., Reference Kaya, Ünay, Göktaş and Saraç2007). As a result, it is not known how the faunas of Anatolia developed at the time major changes took place in the European faunas.

Here, we present the micromammal fauna from the new Anatolian locality of Çapak, which shows a significantly different composition from other early Miocene faunas. The locality was discovered within the framework of the National Geographic Expedition “Palaeogeography of Mammals Following the Collision of the African and Eurasian Plates” in 2015. The locality is situated near the village of Çapak in the northern part of the Torbalı district in the Province of Izmir (Figure 1). Because the rich assemblage of the new site represents a less-known time interval, it provides important information about the evolutionary lineages and migration paths of the Anatolian micromammals in that period. In addition, the presence of some species otherwise known from Europe makes it an important comparison point for interregional correlations. The assemblage shows the first evidence of open woodlands of Anatolia in the early to middle Miocene transition. In this paper, we describe the rodents and the lagomorph from the locality; the small insectivore assemblage will be published elsewhere.

Figure 1. (1) Regional geological location of the Kocaçay Neogene basin. (2) Simplified geological map of the Kocaçay Neogene basin. (3) Early-middle Miocene sequence that crops out around Çapak village: (1) pre-Neogene basement, (2) fan-delta deposits, (3) lacustrine paper-shale deposits, (4) lacustrine limestone, (5) fluvial deposits, (6) Holocene alluvium (modified from Göktaş, Reference Göktaş2012). (4) Outcrop view of Çapak. (5) The fossiliferous layer of Çapak.

Geological setting

The Neogene Kocaçay Basin (Sözbilir et al., Reference Sözbilir, Sarι, Uzel, Sümer and Akkiraz2011) is one of the NE-SW trending Miocene basins of western Anatolia (Figure 1.1). Early middle Miocene basin-filling starts with fan delta sediments, continues with lacustrine sediments and ends with fluvial sediments. The late Miocene sequence, which overlies this sequence with an angular unconformity, consists of alluvial fan deposits (Figure 1.2). The lacustrine sequence consists of laminated shales and ends with limestone that includes mudstone, rhyolitic tuff, sandstone and marshy sediments. The Çapak small-mammal fauna was found in the coaly marsh deposits in the lacustrine section that crops out north of the village of Çapak (Figure 1.3)

Materials and methods

Collection

Approximately 2500 kg of sediment were collected during two fieldwork campaigns (2015 and 2018) and screen-washed with a mesh of 0.5 mm following the method of Daams and Freudenthal (Reference Daams and Freudenthal1988b). All concentrate was sorted under the microscope.

Measurements

Upper cheek teeth are indicated by uppercase and lower cheek teeth by lowercase. Where distinction between first and second molars is questionable, these are indicated as m1/2 or M1/2, respectively. Tooth measurements (maximum length and width) are given in mm and were taken using a Leica MZ16A stereomicroscope and associated software. Terminology used for dental morphology follows Daams and Freudenthal (Reference Daams and Freudenthal1988a) and Oliver and Peláez-Campomanes (Reference Oliver and Peláez-Campomanes2013) for Cricetidae, García-Paredes et al. (Reference García-Paredes, Peláez-Campomanes and Alvarez-Sierra2010) for Gliridae, Cuenca Bescós (Reference Cuenca Bescós1988) for Sciuridae, Sarıca and Sen (Reference Sarıca, Sen, Fortelius, Kappelman and Bernor2003) for Spalacidae and López Martínez (Reference López Martínez1986) for Ochotonidae. SEM photographs were taken at the Slovak Academy of Science in Bratislava. All dental elements have been figured as being left. The letters of inverted photographs have been underlined on the figures.

Repository and institutional abbreviation

The specimens examined in this study are deposited in the following institution: Ege University Natural History Application and Research Centre (EUNHM), Izmir, Turkey.

Systematic paleontology

Class Mammalia Linnaeus, Reference Linnaeus1758
Order Rodentia Bowdich, Reference Bowdich1821
Family Gliridae Muirhead, Reference Muirhead and Brewster1819
Genus Myomimus Ognev, Reference Ognev1924

Type species

Myomimus personatus Ognev, Reference Ognev1924.

Myomimus tanjuae new species
Figure 2

Figure 2. Myomimus tanjuae n. sp. (1) D4 sin (PV13091), (2) M1/2 sin (PV13097; holotype), (3) M1/2 sin (PV13094), (4) M1/2 sin (PV13093), (5) M3 sin (PV13105), (6) M3 sin (PV13106), (7) p4 sin (PV13134), (8) p4 sin (PV13111), (9) m1 dex (PV13120), (10) m1 dex (PV13124), (11) m2 dex (PV13119), (12) m2 sin (PV13116), (13) m3 sin (PV13129), (14) m3 sin (PV13130), (15) m3 dex (PV13125).

Holotype

Right M1; PV13097 (length 0.93, width 1.07), Figure 2.2.

Diagnosis

Small-sized Myomimus with an anterior extra ridge in M1 and M2. The ridge pattern in the central valley of the upper molars can be slightly complex. Lower molars are simple, only showing a posterior extra ridge. The m1 and m2 have two roots, while the m3 has three roots.

Differential diagnosis

Because the genus Peridyromys is sometimes considered a subjective junior synonym of Myomimus (see remarks), we include a comparison with the species of Peridyromys. Myomimus tanjuae n. sp. is smaller than M. roachi (Bate, Reference Bate, Garrod and Bate1937), M. qafzensis Haas, Reference Haas1973, M. maritsensis De Bruijn, Dawson, and Mein, Reference De Bruijn, Dawson and Mein1970; M. multicristatus (De Bruijn, Reference De Bruijn1966), Peridyromys lavocati Peláez-Campomanes and Daams, Reference Peláez-Campomanes and Daams2002, P. brailloni (Thaler, Reference Thaler1966), P. prosper (Thaler, Reference Thaler1966), P. sondaari Daams, Reference Daams, Reumer and De Vos1999, P. darocensis Daams, Reference Daams, Reumer and De Vos1999, P. jaegeri Aguilar, Reference Aguilar1974, and P. rex García-Moreno in Alvarez-Sierra and García-Moreno, Reference Álvarez-Sierra and García-Moreno1986.

Myomimus dehmi (De Bruijn, Reference De Bruijn1966) has a similar size to Myomimus tanjuae n. sp., but differs by having simpler dental pattern in the upper molars and having three roots in m1–m2.

Peridyromys aquatilis (De Bruijn and Moltzer, Reference De Bruijn and Moltzer1974) and P. obtusangulus (von Meyer, Reference Von Meyer1859) have a similar size to Myomimus tanjuae n. sp., but differ by the anterior extra ridge on the lower molars.

Myomimus sumbalenwalicus Munthe, Reference Munthe1980 has a similar size to Myomimus tanjuae n. sp., but differs by having three roots in m1–m2 and an absence of connection between posterior centroloph and metacone of M1–M2.

Peridyromys murinus (Pomel, Reference Pomel1853) is slightly smaller than Myomimus tanjuae n. sp. and differs from it by having no extra ridge on the upper molars.

Peridyromys turbatus Álvarez Sierra et al., Reference Álvarez Sierra, Daams, Lacomba, López Martínez, van der Meulen, Sesé and De Visser1991 is slightly larger than Myomimus tanjuae n. sp. and differs from it by having more complicated lower and upper molar dental patterns.

Occurrence

Çapak, Izmir, Turkey, late early Miocene, local zone E (MN4).

Description

D4

The outline of the molar is triangular and concave from the labial side (Fig. 2.1). Four main ridges are present (anteroloph, protoloph, metaloph, and posteroloph). The protoloph is higher than the other lophs. The anterior and posterior centrolophs are isolated. The posterior centroloph is longer than the anterior centroloph.

P4

The protoloph and the metaloph are present, but the molar is broken from the lingual side, which prevents seeing the connections. The specimen is too worn to show any additional features.

M1/2

The occlusal surfaces of the molars are concave. Four main ridges are present. The protocone is situated on the posterolingual corner, forming a V-shaped trigone. The metaloph and protoloph are connected. The anteroloph is isolated lingually. Both the anterior and posterior centrolophs are present. The central valley ridges have complex patterns in five specimens (Figure 2.3). The anterior centroloph is always longer than the posterior one. The anterior and posterior centrolophs are connected to the paracone and the metacone. There are no extra ridges in two of 12 specimens, while the other 10 specimens have a short anterior extra ridge. The molar has three roots.

M3

The occlusal surface of the molar is concave. The dental pattern consists of four main ridges accompanied by the anterior and posterior centrolophs. The posterior centroloph is longer than the anterior centroloph. The posterior extra ridge is present in one specimen. The molar has three roots.

p4

The premolar has a simple pattern and is slightly concave lingually. The posterior part is wider than the anterior part. The anterolophid and the metalophid are not connected to the mesolophid. The posterolophid and mesolophid are connected at the lingual side and end very close to each other at the labial side. The premolar has one root.

m1 and m2

The m1 and m2 only differ in the outline of the molars. The occlusal surface is slightly concave. The dental pattern consists of four main ridges (anterolophid, metalophid, mesolophid, posterolophid) and centrolophid. The vestigial anterior extra ridge is present in two of 14 specimens. The anterolophid and the metalophid are connected labially in seven of 14 specimens. The lingual connection of the metalophid is variable. It ends free in eight molars and connects to the metaconid in six molars, but it is always directed anteriorly. The posterior extra ridge is present in all specimens; it is connected to the entoconid in three specimens. The molar has two roots.

m3

The occlusal surface is slightly concave. The anterior part of the molar is wider than the posterior part. The dental pattern consists of four main ridges and centrolophid. The posterior extra ridge is present in all specimens. The molar has three roots.

Etymology

The species is named in honor of Prof. Dr. Tanju Kaya, in recognition of her work on the fossil mammals of Turkey and her continuous support of micromammal research in the region.

Material

2 D4 (PV13090, 13091), 1 P4 (PV13112), 13 M1/2 (PV13092–13104), 3 M3 (PV13105, 13106, 13141), 3 p4 (PV13110, 13111, 13134), 8 m1 (PV13118–13120, 13123, 13124, 13132, 13133, 13140), 6 m2 (PV13114–13117, 13121, 13122), 7 m3 (PV13125–13131).

Measurements

Measurements of isolated cheek teeth are in Table 1.

Table 1. Measurements of Myomimus tanjuae n. sp. from Çapak.

Remarks

The genus Myomimus is known from several Anatolian localities. The locality Keseköy yielded Myomimus sp. (Ünay, Reference Ünay1994), Çandır provided Myomimus n. sp. (De Bruijn et al., Reference De Bruijn, Van den Hoek Ostende, Kristkoiz-Boon, Theocharapoulos and Ünay2003), the Tuğlu and Sinap localities recorded M. dehmi (Sen, Reference Sen1990; Joniak and De Bruijn, Reference Joniak and de Bruijn2015; The NOW Community, 2020), and the locality of Hayranlı yielded M. maritsensis (Kaya and Kaymakçı, Reference Kaya and Kaymakçi2013). The genus Peridyromys is only recorded from three Anatolia localities. The localities of Hancılı 2 and Sofça yielded Peridyromys indet. (The NOW Community, 2020) and the locality of Paşalar provided P. lavocati Peláez-Campomanes and Daams, Reference Peláez-Campomanes and Daams2002.

The relationship between the genera Peridyromys and Myomimus has been cause of debate. De Bruijn et al. (Reference De Bruijn, Dawson and Mein1970) synonymized these two genera because of the similarity of the dental patterns. According to them, the only difference is the size of lower p4, which is relatively large in Peridyromys and small in Myomimus. By contrast, Daams (Reference Daams1981) preferred to keep both genera, based on the different number of the roots. Species of Myomimus have three roots while Peridyromys has two roots for lower m1, m2 and m3, with some exceptions (Daams, Reference Daams1981). In addition, a major argument was the time gap between their respective stratigraphic ranges—Peridyromys being recorded up to MN4 and Myomimus appearing in Europe from MN9 onwards. Therefore, there was no Peridyromys/Myomimus record from MN4 to MN9. This situation changed when De Bruijn et al. (Reference De Bruijn, Van den Hoek Ostende, Kristkoiz-Boon, Theocharapoulos and Ünay2003) published a new species of Myomimus from the middle Miocene hominoid site of Çandır in Turkey. They considered this species unique because of the number of roots (the m1 and m2 have two roots, the m3 has three roots). Because the age of the locality is considered MN5/6, this would close the gap in the record of Myomimus/Peridyromys. A full revision of the two genera is needed to clarify the proposed synonymy, which is outside the scope of the current paper. We do note that, as yet, there do not seem to be clear differences between Myomimus and Peridyromys.

Myomimus from Çapak falls metrically in the lower range of Myomimus n. sp. from Çandır (Figure 3) and is very similar morphologically. Moreover, both Myomimus tanjuae n. sp. and the Çandır Myomimus are characterized by having two roots in m1–m2 and three roots in m3. However, we have not studied the Myomimus material from Çandır, therefore we do not deem it opportune to change its current classification.

Figure 3. Scatter diagram of the upper and lower molars of Myomimus and Peridyromys from Anatolia and Europ (data after Daams, Reference Daams1981; Peláez-Campomanes and Daams, Reference Peláez-Campomanes and Daams2002; De Bruijn et al., Reference De Bruijn, Van den Hoek Ostende, Kristkoiz-Boon, Theocharapoulos and Ünay2003).

Family Muridae Illiger, Reference Illiger1811
Genus Democricetodon Fahlbusch, Reference Fahlbusch1964

Type species

Democricetodon crassus Freudenthal in Freudenthal and Fahlbusch, Reference Freudenthal and Fahlbusch1969 (=Cricetodon minor Lartet, Reference Lartet1851 sensu Fahlbusch Reference Fahlbusch1964).

Democricetodon gracilis Fahlbusch, Reference Fahlbusch1964
Figure 4

Holotype

Right M1 (BSPG 1959 II 247), Sandelzhausen, Germany. The specimen is stored in Bayerische Staatssammlung für Paläontologie und Geologie, Munich.

Figure 4. Democricetodon gracilis Fahlbusch, Reference Fahlbusch1964. (1) M1 sin (PV13001), (2) M1 dex (PV13008), (3) M2 dex (PV13015), (4) M2 sin (PV13011), (5) M3 sin (PV13026), (6) M3 dex (PV13028), (7) m1 sin (PV13037), (8) m1 dex (PV13032), (9) m1 dex (PV13030), (10) m2 dex (PV13045), (11) m2 sin (PV13048), (12) m3 sin (PV13054), (13) m3 sin (PV13057).

Description

M1

The anterocone is simple. The lingual anteroloph is comma-shaped and connected to the base of the protocone. The labial anteroloph is connected to the base of the paracone. It is transverse in seven and curved in three molars. The anterolophule is strong and connected to the protocone. The labial spur of the anterolophule is weak and only present in three out of 10 specimens. The protolophule is double in four and only the posterior one is present in the remaining five molars (one of the 10 M1 specimens is missing the posterior part). The posterior paracone spur is absent. The mesoloph is of medium length in eight and short in one specimen. The metalophule is directed posteriorly; it is connected to the posteroloph in seven and fused to the posteroloph in two molars. A weak mesostyle is present in two specimens. The lingual mesocingulum is, at most, weakly developed. The sinus is transverse. The molar has three roots.

M2

The lingual anteroloph is short and connected to the base of the protocone. The labial anteroloph is long and connected to the base of the paracone. The protolophule is double in 12 (only the anterior protolophule is present in one specimen), it is not visible in three specimens due to wear. The posterior paracone spur is absent. The metalophule is transverse in four specimens and directed anteriorly in 11 specimens. The mesoloph is always long and connected to the labial border in five molars. The mesostyle is present in seven out of 15 specimens. The lingual mesocingulum is present. The sinus is transverse. The molar has three roots.

M3

The lingual anteroloph is connected to the base of the protocone in two, absent in two molars. The labial anteroloph is connected to the paracone. The metacone is developed only in one specimen. The metacone and the hypocone are connected by the posteroloph and the metalophule. The ridge between the paracone and metalophule is incomplete. The mesoloph is present in one specimen. The sinus is very shallow and narrow. The molar has three roots.

m1

The anteroconid is elliptical. The labial anterolophid is longer than the lingual anterolophid. The labial anterolophid is connected to the base of the protoconid; the lingual anterolophid is connected to the base of the metaconid. The metalophulid is anterior in 12, weak and short in four specimens, absent in one specimen. The hypolophulid is anterior in all specimens. The posterolophid is strong and long, connected to the base of the entoconid. A weak labial posterolophid is present in two molars. A posterior sulcus is present in five m1. The mesolophid is short in two, of medium length in four, long and connected to the lingual border in four m1. The ectostylid is present in two and the mesostylid is present in one specimen. The labial mesocingulid is weak or absent. The sinus is wide and directed anteriorly. The molar has two roots.

m2

The lingual anterolophid is weakly present in four molars. The labial anterolophid is connected to the base of the protoconid. It is short in five, long in four specimens. The metalophid is present in four, fused to the lingual anterolophid in five m2. The hypolophulid is always directed anteriorly. The mesolophid is of medium length in two, long and reaching to the lingual side of the molar in four, and reaching to the metaconid in three specimens. The posterolophid is long, connected to the base of the entoconid. A weak posterior sulcus is present. The ectostylid is present in one molar. The labial mesocingulid is present. The sinusid is transverse. The molar has two roots.

m3

The lingual anterolophid is very short. The labial anterolophid is connected to the base of the protoconid. It is strong in five and weak in four specimens. The metalophulid is present in five, absent in one, and fused to the lingual anterolophid in three molars. The mesolophid is connected to the labial ridge. The posterior arm of the protoconid is long. The posterolophid is long and connected to the reduced entoconid. The sinusid is transverse. The molar has two roots.

Material

10 M1 (PV-13000–13009), 15 M2 (PV-13010–13024), 4 M3 (PV-13025–13028), 15 m1 (PV-13030–13044), 9 m2 (PV-13045–13053), 9 m3 (PV-13054–13062).

Measurements

Measurements of cheek teeth are given in Table 2.

Table 2. Measurements of Democricetodon gracilis from Çapak.

Remarks

Democricetodon first appeared in Anatolia in the early part of the early Miocene, in the Kılçak section (local zone B), much earlier than its first occurrence in Europe (Theocharopoulos, Reference Theocharopoulos2000). Democricetodon developed in Anatolia before it dispersed throughout Europe at the beginning of MN4 (e.g., Fahlbusch, Reference Fahlbusch1964; Aguilar, Reference Aguilar1982; Klein Hofmeijer and De Bruijn, Reference Klein Hofmeijer and de Bruijn1988).

In the early Miocene of Anatolia, the genus Democricetodon is represented by various species: Democricetodon anatolicus Theocharopoulos, Reference Theocharopoulos2000 from Harami 3, D. haltmari Theocharopoulos, Reference Theocharopoulos2000 from Gökler and D. doukasi Joniak et al., Reference Joniak, Peláez-Campomanes, Van den Hoek Ostende and Rojay2017 from Keseköy (Theocharopoulos, Reference Theocharopoulos2000; Joniak et al., Reference Joniak, Peláez-Campomanes, Van den Hoek Ostende and Rojay2017). The specimens from Çapak are bigger than those of D. haltmari and D. anatolicus, and fall in the same size range as D. doukasi (Figure 5). However, Democricetodon from Çapak differs from D. doukasi in having higher crowned molars, a posteriorly directed metalophule in the M1 and the absence of a posterior paracone spur in M1–M2.

Figure 5. Scatter diagram of the upper and lower first molars of small sized Democricetodon from Anatolia and adjacent area (data are after Klein Hofmeijer and De Bruijn, Reference Klein Hofmeijer and de Bruijn1988; Theocharopoulos, Reference Theocharopoulos2000; Wessels and Reumer, Reference Wessels and Reumer2009).

During the middle Miocene of Anatolia, Democricetodon is represented by European forms only. Democricetodon aff. D. gaillardi (Schaub, Reference Schaub1925) is known from the locality of Çandır (De Bruijn et al., Reference De Bruijn, Van den Hoek Ostende, Kristkoiz-Boon, Theocharapoulos and Ünay2003) and Democricetodon brevis (Schaub, Reference Schaub1925) is known from the locality of Paşalar (Peláez-Campomanes and Daams, Reference Peláez-Campomanes and Daams2002). Both species are larger than the Democricetodon from Çapak.

Democricetodon gracilis is a very common species in the MN4 to MN6 assemblages from central Europe (e.g., Fahlbusch, Reference Fahlbusch1964; Daxner-Höck, Reference Daxner-Höck1998; Wessels and Reumer, Reference Wessels and Reumer2009). It rarely occurs in the Iberian Peninsula but is known in late MN4/early MN5 sites in the Ebro Basin (Suárez Hernando, Reference Suárez Hernando2017) and the Vallès-Penedès Basin (Agustí, Reference Agustí1981; Jovells-Vaqué and Casanovas-Vilar, Reference Jovells-Vaqué and Casanovas-Vilar2018) as well. It is also known from the eastern Mediterranean localities of Aliveri (MN4), Karydia (MN4) and Thymiana A (MN5) (Theocharopoulos, Reference Theocharopoulos2000; Koufos, Reference Koufos2006). The species is also tentatively listed from two Anatolian localities, Yeniliman and Belenyenice (Saraç, Reference Saraç2003). The Çapak specimens fall metrically and morphologically within the variation of the type material of D. gracilis from Sandelzhausen (MN5) (Wessels and Reumer, Reference Wessels and Reumer2009) (Figure 5). However, the bottom of the sinuses is situated higher above the enamel-dentine junction in the Sandelzhausen specimens. In this respect, the molars from Çapak are more similar to those of D. gracilis from Forsthart (MN4) (Ziegler and Fahlbusch, Reference Ziegler and Fahlbusch1986) in having a lower crown. As yet, it is unclear whether this is part of an overall trend within the species or if it is a feature that is an ecophenotypical variation.

Genus Megacricetodon Fahlbusch, Reference Fahlbusch1964

Type species

Cricetodon gregarius Schaub, Reference Schaub1925.

Megacricetodon primitivus (Freudenthal, Reference Freudenthal1963)
Figure 6

Holotype

Ramus with m1–m3 56-142, Valtorres, Calatayud-Montalbán Basin, Spain. The specimen is stored in Institut Català de Paleontologia Miquel Crusafont, Barcelona.

Figure 6. Megacricetodon primitivus (Freudenthal, Reference Freudenthal1963). (1) M1 sin (PV13237), (2) M1 dex (PV13238), (3) M1 dex (PV13239), (4) M2 sin (PV13264), (5) M2 sin (PV13266), (6) M2 sin (PV13269), (7) M3 sin (PV13281), (8) M3 sin (PV13282), (9) m1 sin (PV13301), (10) m1 dex (PV13312), (11) m2 sin (PV13324), (12) m2 dex (PV13335), (13) m2 dex (PV13333), (14) m3 sin (PV13341), (15) m3 sin (PV13339).

Description

M1

The anterocone is slightly divided in three and deeply split in 19 specimens. There is a cingulum in front of the anterior furrow of the anterocone in all of the specimens. The labial cusp of the anterocone is larger than the lingual cusp. The anterolophule is connected to the lingual anterocone in 12 specimens, it is connected between the two cones in two, in which it is divaricated into two lophules, and it is connected to the labial and the lingual anterocone in two M1. The labial spur of the anterolophule is present in three specimens. The protolophule is directed posteriorly in all specimens. An indistinct posterior paracone spur is present in three specimens. The lingual mesocingulum is generally strong and it is barely visible or absent in worn specimens. The mesoloph is long (it is connected to the labial edge) in 19 and of medium length in three specimens. The metalophule is transverse in four and directed posteriorly in 17 molars. The sinus is transverse. The molar has three roots.

M2

The labial anteroloph is longer than the lingual anteroloph. The labial anteroloph is connected to the paracone and the lingual anteroloph continues to the cingulum; it is not connected to the protocone. The lingual mesocingulum is present in all specimens except for one molar. The protolophule is directed anteriorly in 17, transverse in seven, double in four, and directed posteriorly in one specimen. The protolophule II is incomplete in two out of four specimens. The entoloph is angular. The posterior arm of the protocone is longer than the anterior arm of the hypocone in a high proportion of the M2. The ectoloph is present in 11 M2. The development of the mesoloph is variable—it is short in one, of middle length in 10, long in nine and long and connected with the labial border in eight specimens. The ectoloph is connected with the mesoloph in seven of the M2. The metalophule is directed anteriorly in 15, transverse in 11, and directed posteriorly in one specimen. The molar has three roots.

M3

The labial anteroloph is connected to the paracone. The lingual anteroloph is present in four molars; it is connected to the base of the protocone in two specimens. The protolophule is transverse. The metalophule is connected to the anterior arm of the reduced hypocone. The neo-entoloph is present only in two M3. The weak metacone is present in three molars. The hypocone is present in four specimens. The molar has three roots.

m1

The anteroconid is rounded. The anterolophulid is long. The metalophulid is always single, short and directed anteriorly. The mesolophid is absent in seven specimens, of medium length in 24 specimens. The ectomesolophid is only present in one specimen. The hypolophulid is directed anteriorly. The sinusid is directed slightly anteriorly. The lingual and labial mesocingulid are present. The cusps are slender. The molar has two roots.

m2

The labial anterolophulid is longer than the lingual anterolophulid and is connected to the protoconid. The labial anterolophid continues to the mesocingulid and is not connected to the protoconid in one specimen. The lingual mesocingulid is connected with the entoconid in 11, free in five and absent in five molars. The labial mesocingulid is always connected to the hypoconid; it is well developed in five specimens. The mesolophid is generally short, but long in one and absent in one molar. The hypolophulid is directed anteriorly. The cusps are slender. The molar has two roots.

m3

The lingual anterolophulid is short, and the labial anterolophid is long and connected with the protoconid in ten specimens. The labial mesocingulid is well developed in five and weak in nine molars. The mesolophid is of medium length and present only in one m3. The cusps are slender. The molar has two roots.

Material

22 M1 (PV13230–13250, 13318), 30 M2 (PV13252–13280, 13319), 10 M3 (PV13281–13289, 13084), 31 m1 (PV13290–13317, 13080, 13081, 13083), 19 m2 (PV13320–13337, 13082), 14 m3 (PV13338–133449, 13086, 13087).

Measurements

Measurements of cheek teeth are given in Table 3.

Table 3. Measurements of Megacricetodon primitivus from Çapak.

Remarks

The story of Megacricetodon is not as well known as that of the other hamsters in the early Miocene of Anatolia. The earliest records are from the local zone D localities of Keseköy and Kınık 1 and are assigned to Megacricetodon sp. and M. cf. M. primitivus, respectively (Ünay and Göktaş, Reference Ünay and Göktaş2000; Wessels et al., Reference Wessels, Theocharopoulos, de Bruijn and Ünay2001). The records from Söke and Dededağ (local zone E) are assigned M. cf. M. primitivus and M. primitivus (Ünay and Göktaş, Reference Ünay and Göktaş1999), but as a preliminary list with a short description only. Kaya et al. (Reference Kaya, Ünay, Göktaş and Saraç2007) also indicated several Megacricetodon from early Miocene assemblages, but only in faunal lists.

Megacricetodon first appears in Europe in MN4, with occurrences such as M. hellenicus Oliver and Peláez-Campomanes, Reference Oliver and Peláez-Campomanes2016 from Aliveri (Greece), M. aff. M. collongensis (Mein, Reference Mein1958) from Langenau 1 (Germany), M. primitivus from Artesilla (Spain) and M. bezianensis Bulot, Reference Bulot1980 from Bézian (France) (Bulot, Reference Bulot1980; Sach and Heizmann, Reference Sach and Heizmann2001; Oliver and Peláez-Campomanes, Reference Oliver and Peláez-Campomanes2014, Reference Oliver and Peláez-Campomanes2016). It then continues as a very common element in the European faunas with an array of different species until MN10.

Somewhat surprisingly, Megacricetodon primitivus is known from southwestern and southeastern Europe, but was never encountered in central Europe. The Megacricetodon assemblage from the Greek locality Antonios (MN5) was assigned to M. primitivus by Vasileiadou and Koufos (Reference Vasileiadou and Koufos2005). However, Oliver and Peláez-Campomanes (Reference Oliver and Peláez-Campomanes2014) argued against this designation, based on the stronger cingulum in front of the anterocone and the presence of an ectoloph in M1 and short or absent mesolophid in m1. Notably, all these character states seem to apply to the Çapak material as well. Nevertheless, all the individual characters fall within the variation of M. primitivus from Spain (Oliver, Reference Oliver2015). The mean value of M. primitivus from Çapak is among the lower values of M. primitivus from Artesilla and Valtorres (Figure 7).

Figure 7. Scatter diagram of the upper and lower first molars of small and medium-sized Megacricetodon from Anatolia, Europe, and Asia (data are after Mein, Reference Mein1958; Freudenthal, Reference Freudenthal1963; Wessels et al., Reference Wessels, Theocharopoulos, de Bruijn and Ünay2001; Peláez-Campomanes and Daams, Reference Peláez-Campomanes and Daams2002; Lazzari and Aguilar, Reference Lazzari and Aguilar2007; Bi et al., Reference Bi, Meng and Wu2008; Oliver Pérez et al., Reference Oliver Pérez, López Guerrero and Peláez-Campomanes2008; Oliver and Peláez-Campomanes; Reference Oliver and Peláez-Campomanes2014, Reference Oliver and Peláez-Campomanes2016; Oliver, Reference Oliver2015).

A comprehensive study of all early Miocene Megacricetodon material from Asia minor and southeastern Europe is needed to clarify the relation with the assemblages from the Spanish localities. Until that time, the Çapak material is best assigned to M. primitivus.

Genus Eumyarion Thaler, Reference Thaler1966

Type species

Cricetodon medius Lartet, Reference Lartet1851 (=Cricetodon helveticus Schaub, Reference Schaub1925).

Eumyarion aff. E. montanus De Bruijn and Saraç, Reference De Bruijn and Saraç1991
 Figure 8.18.4

Description

M2

The labial anteroloph is well developed. The lingual anteroloph is vestigial. The protolophule is slightly directed anteriorly and connected to the posterior arm of the protocone. The posterior paracone spur is well developed and connects to the long mesoloph. The metalophule is parallel with the protolophule and connected to the entoloph just in front of the hypocone. The sinus is narrow and directed anteriorly. The roots are not preserved.

Figure 8. Eumyarion aff. E. montanus De Bruijn and Saraç, Reference De Bruijn and Saraç1991. (1) M2 dex (PV13210), (2) M3 dex (PV13211), (3) m1 sin (PV13212), (4) m3 sin (PV13215). Cricetodon sp. (5) M1 dex (PV13203), (6) M3 sin (PV13204). Cricetodon cf. C. aliveriensis Klein Hofmeijer and De Bruijn, Reference Klein Hofmeijer and de Bruijn1988. (7) M1 sin (PV13201), (8) m2 dex (PV13200). Karydomys cf. K. strati López-Antoñanzas et al., Reference López-Antoñanzas, Peláez-Campomanes, Prieto and Knoll.2018. (9) M2 sin (PV13216). Debruijnia sp. (10) M3 dex (PV13220). Aliveria luteyni De Bruijn, Van der Meulen, and Katsikatsos, Reference De Bruijn, van der Meulen and Katsikatsos1980. (11) M3 sin (PV13217). Albertona balkanica López Martínez, Reference López Martínez1986. (12) p3 dex (PV13223), (13) p3 sin (PV13224).

M3

The labial anteroloph is connected to the base of the paracone. The lingual anteroloph is very weak. The paracone spur is absent. The protolophule is very short. A short mesoloph starts at the middle of the longitudinal crest connecting the protolophule and metalophule. The posterior part of the molar is broken. The roots are not preserved.

m1

The outline of the molar is very narrow. The cusps are slender. The labial and lingual anterolophids are comma-shaped and connected to the base of the protoconid and to the metaconid, respectively. The labial anterolophid is longer than the lingual anterolophid. The anterolophulid is low and relatively short. The metalophid is connected to the anterior arm of the protoconid. The postero-lingual crest is very distinctive and connects to the base of the entoconid. The mesolophid is of medium length and directed anteriorly. The ectomesolophid is absent. The posterior arm of the hypoconid is strong and is not connected to the posterolophid. The sinusid is wide. The roots are not preserved.

m3

The lingual anterolophid is connected to the base of the metaconid. The labial anterolophid is short and descends to the base of protoconid. A narrow protosinus is present. The metalophid is short and connects to the anterior arm of the protoconid. The mesolophid is of medium length and directed posteriorly. The hypolophulid is connected to the ectolophid, just in front of the hypoconid. The roots are not preserved.

Material and measurements

1 M2 (PV13210, 1.47 x 1.38), 1 M3 (PV13211, — x 1.20), 1 m1 (PV13212, 1.94 x 1.04), 2 m3 (PV13214, 1.29 x 0.91; PV13215, 1.31 x 1.06).

Remarks

The genus Eumyarion is dominant in the early Miocene of Anatolia with a large number of species (E. intercentralis De Bruijn and Saraç, Reference De Bruijn and Saraç1991, E. microps De Bruijn and Saraç, Reference De Bruijn and Saraç1991, E. carbonicus De Bruijn and Saraç, Reference De Bruijn and Saraç1991, E. montanus, E. orhani De Bruijn et al., Reference De Bruijn, Mayda, Van den Hoek Ostende, Kaya and Saraç2006, E. gordesensis Peláez-Campomanes et al., Reference Peláez-Campomanes, Göktaş, Kaya, Joniak, Bilgin, Mayda, Van den Hoek Ostende, Van den Hoek Ostende, Mayda and Kaya2019 and E. lukasi Peláez-Campomanes et al., 2017) and up to three species may occur together in a single assemblage (De Bruijn and Saraç, Reference De Bruijn and Saraç1991; De Bruijn et al., Reference De Bruijn, Mayda, Van den Hoek Ostende, Kaya and Saraç2006; Joniak et al., Reference Joniak, Peláez-Campomanes, Van den Hoek Ostende and Rojay2017; Peláez-Campomanes et al., Reference Peláez-Campomanes, Göktaş, Kaya, Joniak, Bilgin, Mayda, Van den Hoek Ostende, Van den Hoek Ostende, Mayda and Kaya2019). By contrast, the Eumyarion from Çapak is one of the least common taxa in the fauna.

The m1 from Çapak is metrically almost in the same range, but narrower than Eumyarion aff. E. carbonicus from Harami 3 and E. montanus from its type locality Keseköy and from Sabuncubeli (De Bruijn and Saraç, Reference De Bruijn and Saraç1991; De Bruijn et al., Reference De Bruijn, Mayda, Van den Hoek Ostende, Kaya and Saraç2006). In morphology, Çapak specimens are closest to E. montanus, but there are some notable differences. The lingual anteroloph is present in the M3 from Çapak, but it never occurs in E. montanus. The metalophulid is single and the ectomesolophid is absent in the m1 from Çapak, but the metalophulid is double and ectomesolophid is present in E. montanus. We classify the Çapak material therefore as E. aff. E. montanus, indicating that the scarcity of the material does not allow a formal species definition, even though it is clearly different than any Eumyarion known so far.

Genus Cricetodon Lartet, Reference Lartet1851

Type species

Cricetodon sansaniensis Lartet, Reference Lartet1851.

Cricetodon sp.
Figure 8.58.6

Description

M1

The labial outline of the molar is sinuous. The cusps are robust and the enamel is thick. The molar is worn. The anterocone is slightly divided. The labial cusp of the anterocone is partly damaged. The lingual anteroloph is connected to the protocone. The anterior ectoloph is slender and reaches the paracone. The posterior ectoloph is well developed and complete, connected to the metacone. The protolophule is short and directed posteriorly. The metalophule is fused to the posteroloph. The mesoloph is short and directed posteriorly. The sinus is narrow and transverse. The roots are not preserved.

M3

The outline of the molar is rounded. The lingual anteroloph is short, connected to the protocone, enclosing a narrow protosinus. The labial anteroloph is long and strong and does not reach the paracone. The anterolophule is well developed and there is a small lingual spur. The posterior ectoloph is complete and connected to the metacone. The mesoloph is absent. The neo-entoloph is absent. The metacone is fused with the posteroloph. The metalophule is absent. The sinus is deep, narrow, and directed posteriorly. The roots are not preserved.

Material and measurements

1 M1 (PV13203, 2.93 x 2.00), 1 M3 (PV13204, 1.70 x 1.56).

Remarks

The genus Cricetodon is represented in Anatolia by several species during the early and middle Miocene (Tobien, Reference Tobien1978; Sen and Ünay, Reference Sen and Ünay1979; Ünay, Reference Ünay1990; De Bruijn et al., Reference De Bruijn, Fahlbusch, Saraç and Ünay1993; Çınar Durgut and Ünay, 2016; Joniak et. al., 2019). The Çapak assemblage comprises two different species of Cricetodon; the larger Cricetodon sp. and the smaller Cricetodon cf. C. aliveriensis.

The M1 of Cricetodon sp. from Çapak is morphologically very similar to the M1 of Cricetodon candirensis from its type locality Çandır described by Tobien (Reference Tobien1978). The size also is among the upper range of C. candirensis (Figure 9). However, M3 from Çapak is morphologically more similar to C. pasalarensis (Tobien, Reference Tobien1978) because of the incomplete anterior ectoloph, complete posterior ectoloph and single protolophule. Cricetodon candirensis typically has an elongated M3, whereas C. pasalarensis and the Cricetodon from Çapak have rounded M3. However, there are also some other differences: the M3 of C. pasalarensis has a mesoloph in 86% of the specimens, but the M3 from Çapak has no mesoloph. While the sinus is directed posteriorly in Çapak specimen, it is directed forward in C. pasalarensis. In that respect, and because of the limited material, we prefer to leave the large Çapak Cricetodon in open nomenclature.

Figure 9. Scatter diagram of the upper first molar of medium and large sized Cricetodon from Anatolia and adjacent area (data after Klein Hofmeijer and De Bruijn, Reference Klein Hofmeijer and de Bruijn1988; Ünay, Reference Ünay1990; De Bruijn et al., Reference De Bruijn, Fahlbusch, Saraç and Ünay1993, Reference De Bruijn, Van den Hoek Ostende, Kristkoiz-Boon, Theocharapoulos and Ünay2003; Vasileiadou and Koufos, Reference Vasileiadou and Koufos2005; Çınar Durgut and Ünay, Reference Çınar Durgut and Ünay2016; Skandalos, Reference Skandalos2017).

Cricetodon cf. C. aliveriensis Klein Hofmeijer and De Bruijn, Reference Klein Hofmeijer and de Bruijn1988
Figure 8.7, 8.8

Holotype

M1 sin, no. 542, Aliveri, Greece. The specimen is stored at Utrecht University, Department of Earth Sciences, Utrecht, The Netherlands.

Description

M1

The anterocone is slightly divided into two equal cusps. The lingual spur of the anterolophule joins to the base of the protocone. The labial anteroloph connects to the base of the paracone. The anterolophule is connected to the lingual cusp of the anterocone. The protolophule is very short and directed posteriorly. The mesoloph is short and directed posteriorly. The metalophule is strong, posteriorly oriented and connects to the weak posteroloph. The molar has no ectolophs. The sinus is narrow and directed anteriorly. The molar has four roots.

m2

The labial anterolophid is strong and connects to the base of the protoconid. The lingual anterolophid is almost absent. The metalophulid is short and connected to the anterolophule. The mesolophid is short and directed anteriorly. The hypolophulid is short, directed anteriorly and connects to the ectolophid. The posterolophid is strong and joins to the base of the entoconid. The sinusid is wide and transverse. Inside the sinusid there is a short, low, but distinctive crest originating from the anterior wall of the hypoconid towards the labial mesocingulid. The roots are not preserved.

Material and measurements

1 M1 (PV13201, 2.52 × 1.79), 1 m2 (PV13200, 2.04 × 1.56).

Remarks

The M1 falls metrically within the variation of the type material of Cricetodon tobieni from Horlak and is just outside the range of the small collection of the type material of Cricetodon kasapligili from Keseköy (De Bruijn et al., Reference De Bruijn, Fahlbusch, Saraç and Ünay1993). However, Cricetodon tobieni De Bruijn et al., Reference De Bruijn, Fahlbusch, Saraç and Ünay1993 and C. kasapligili De Bruijn et al., Reference De Bruijn, Fahlbusch, Saraç and Ünay1993 differ from the Cricetodon from Çapak by having slender cusps and three roots in M1. In addition, C. tobieni has a paracone spur that is absent in the Çapak specimen.

The Çapak material resembles C. aliveriensis in many respects. However, the size of M1 is outside the range of the type locality of C. aliveriensis (Aliveri), although it is similar in size to the larger specimens from Karydia (Skandalos, Reference Skandalos2017). Cricetodon cf. C. aliveriensis is also known from the Anatolia locality of Hacibekirli (Akgün et al., Reference Akgün, Kayseri-Özer, Tekin, Varol, Sen, Herece, Gündoğan, Sözeri and Us2021). However, the limited material from Hacibekirli does not allow comparison with the Çapak material. Morphologically, the Çapak material fits well with C. aliveriensis, but since we have only two specimens, which, moreover, are larger than those from the type locality, we prefer to classify it as C. cf. C. aliveriensis.

Genus Karydomys Theocharopoulos, Reference Theocharopoulos2000

Type species

Karydomys symeonidisi Theocharopoulos, Reference Theocharopoulos2000.

Holotype

UM Thy 0-30, a left M2, Thymiana, Chios, Greece. The specimen is stored at the paleontological collections of the University of Montpellier, France.

Description

M2

The anterolingual part of the molar is broken. The labial anteroloph is long. The protolophule is double. Protolophule II is somewhat stronger than protolophule I. The posterior paracone spur is well developed and connects to the long mesoloph at the labial border of the molar. The metalophules are double, but weak and situated lower than the protolophules. The sinus is directed slightly anteriorly. The posterolingual part is damaged, but a small postero-sinus is present. The roots are not preserved.

Material and measurements

1 M2 (PV13216, 1.82 × 1.41).

Remarks

The rare hamster Karydomys is represented by six different species between MN3 and MN6 in central Europe, the eastern Mediterranean, Kazakhstan, and China (Mein and Freudenthal, Reference Mein and Freudenthal1981; Theocharopoulos, Reference Theocharopoulos2000; Kordikova and De Bruijn, Reference Kordikova and de Bruijn2001; Mörs and Kalthoff, Reference Mörs and Kalthoff2004; Maridet et al., Reference Maridet, Wu, Ye, Bi, Ni and Meng2011; López-Antoñanzas et al., Reference López-Antoñanzas, Peláez-Campomanes, Prieto and Knoll.2018). In Karydia 1, from which the genus was originally described, it is represented by Karydomys symeonidisi Theocharopoulos, Reference Theocharopoulos2000, which is morphologically and metrically similar to our specimen. However, K. symeonidisi has a stronger metaloph and it is not double. Karydomys strati López-Antoñanzas et al., Reference López-Antoñanzas, Peláez-Campomanes, Prieto and Knoll.2018 from the Island of Chios resembles our specimen in having double protolophules and metalophules, a long mesoloph, and in the connections with the posterior paracone spur. It also falls within the size range of the Chios species. However, our specimen is partly broken and does not preserve the lingual anteroloph. In that respect, we prefer to classify it as Karydomys cf. K. strati.

Family Spalacidae Gray, Reference Gray1821
Genus Debruijnia Ünay, Reference Ünay, Bernor, Falbusch and Mittmann1996

Type species

Debruijnia arpati Ünay, Reference Ünay, Bernor, Falbusch and Mittmann1996.

Debruijnia sp.
Figure 8.10

Description

M3

The outline of the M3 is semicircular. The occlusal pattern consists of five lophs. The labial anteroloph is connected to the paracone. The lingual anteroloph is absent. The protolophule reaches the paracone area, but a true paracone is not defined. The mesoloph is strong and isolated by two valleys on the labial side; it does not reach the endoloph. The posterosinus is enclosed by the posteroloph and the metalophule. The sinus is deep and very narrow.

Material and measurements

1 M3 (PV13220, 2.25 x 2.35).

Remarks

The Çapak specimen metrically only fits with Debruijnia kostakii De Bruijn, Reference De Bruijn2017 from Karydia 2. A morphological comparison with this and other species, however, is hampered by the ontogenetic stage of our specimen. It represents a very young individual with only a little wear on the anterior part of the tooth. This makes it difficult to compare with other specimens because they generally represent more advanced stages of wear. Therefore, we prefer to leave its classification in open nomenclature.

Family Sciuridae Fischer, Reference Fischer1817
Genus Aliveria De Bruijn, van der Meulen, and Katsikatsos, Reference De Bruijn, van der Meulen and Katsikatsos1980

Type species

Aliveria brinkerinki De Bruijn, van der Meulen, and Katsikatsos, Reference De Bruijn, van der Meulen and Katsikatsos1980.

Aliveria luteyni De Bruijn, van der Meulen, and Katsikatsos, Reference De Bruijn, van der Meulen and Katsikatsos1980
Figure 8.11

Holotype

M1 dext. no. 171. Aliveri, Greece. The specimen is stored at Utrecht University, Department of Earth Sciences, Utrecht, The Netherlands.

Description

M3

The anteroconule is weak. The protoloph is transverse with an irregular course and bears a small protoconule. The paracone and protocone are well developed. The remnant of the metaloph is low and incomplete. The metacone is fused with the posteroloph. The hypocone is absent, but there is a small notch. The surface of the posterior valley is slightly crenulated.

Material and measurements

M3 (PV13217, 2.12 x 2.14).

Remarks

The flying squirrel, Aliveria luteyni, is known from the Greek localities of Aliveri and Karydia and the Turkish localities of Kaplangi 1 and Kaplangi 2 (de Bruijn et al., Reference De Bruijn, van der Meulen and Katsikatsos1980; Koufos, Reference Koufos2006; Bosma et al., Reference Bosma, De Bruijn and Wessels2018). The Aliveria specimen from Çapak is morphologically identical to the type material from Aliveri and metrically it is among the upper values of the measurements of the type material.

Order Lagomorpha Brandt, Reference Brandt1855
Family Ochotonidae Thomas, Reference Thomas1897
Genus Albertona López Martínez, Reference López Martínez1986

Type species

Albertona balkanica López Martínez, Reference López Martínez1986.

Albertona balkanica López Martínez, Reference López Martínez1986
Figure 8.12, 8.13s

Holotype

Left lower jaw with p3–4 and m2, no. 1. Aliveri, Greece. The specimen is stored at Utrecht University, Department of Earth Sciences, Utrecht, The Netherlands.

Description

p3

The talonid is separated by two flexids: the labial hypoflexid and the lingual metaflexid. The metaflexid is well developed. The hypoflexid is longer than the metaflexid. The anterostylid is well developed and does not connect to the metaconid. The protoconid is triangular in one specimen and rounded in the other. The metaconid is well developed. The anterior part of the centroflexid is directed lingually. The protoflexid is present as a shallow sulcus.

Material and measurements

2 p3 (PV13223, 1.48 x 1.23; PV13224, 1.47 x 1.56).

Remarks

Albertona comprises only two species: A. balkanica from Aliveri (López Martínez, Reference López Martínez1986) and A. aegeensis Ünay and Göktaş, Reference Ünay and Göktaş1999 from Söke, in addition to Albertona cf. A. aegeensis from Dededağ (Ünay and Göktaş, Reference Ünay and Göktaş1999). Albertona balkanica is otherwise known from Snegotin (MN4) in Serbia (Marković, Reference Marković2010). The Çapak specimens are metrically among the upper values of A. balkanica from Aliveri and identical morphologically. Our material is also close metrically and morphologically to A. cf. A. aegeensis from Dededağ as described by Ünay and Göktaş (Reference Ünay and Göktaş1999). Based on the measurements and illustrations in Ünay and Göktaş (Reference Ünay and Göktaş1999), the Dededağ material shows strong similarities with A. balkanica as well.

Discussion

The composition of the assemblage and paleoenvironmental considerations

The rodent assemblage of Çapak consists of 244 molars representing nine species belonging to four different families (Table 4). The hamsters are the most dominant group in the assemblage (81.6% of all specimens and 84.4% of M1 + M2 + m1 + m2). They are represented by six species belonging to five genera. The fauna is strongly dominated by Megacricetodon primitivus, which comprises more than half of the assemblage. Democricetodon gracilis is the second most dominant species in the assemblage with ~25.6%, signifying one of the first occurrences of this well-known species from the early and middle Miocene of Europe. The genus Cricetodon is represented by two species with two molars of each: the small species Cricetodon cf. C. aliveriensis and the larger Cricetodon sp. The presence of two species of Cricetodon in one assemblage is uncommon during the early and middle Miocene in Anatolia, known previously only from the localities of Kınık and Yapıntı (Çınar Durgut and Ünay, 2016). Eumyarion is one of the most common hamsters of the early Miocene in Anatolia. However, Eumyarion aff. E. montanus is represented by just five molars in the Çapak assemblage, which is a~2% of the rodents. The rare genus Karydomys completes the range of hamsters in the assemblage, with Karydomys cf. K. strati being represented by a single molar. Gliridae is the second most dominant family in the assemblage and is represented by a new species Myomimus tanjuae n. sp., comprising 17.6% of all rodent specimens. Representatives of the Spalacidae (Debruijnia sp.) and Sciuridae (Aliveria luteyni) are the rarest taxa in the assemblage. They are each represented by just one molar.

Table 4. The rodent composition of the Çapak assemblage. The entry “0(1)” is used in those instances in which the last molars and, for some taxa, premolars are excluded from the count because these elements are generally small and may have been lost while processing (which would give a bias towards larger species). If a species is only represented by premolars or M3s, it is counted as 1, because otherwise the data would falsely suggest an absence of that species.

The majority of the assemblage consists of only three species (Megacricetodon primitivus, Democricetodon gracilis, and Myomimus tanjuae n. sp.). The general composition of the assemblage is very different from known early and middle Miocene assemblages of Anatolia. Megacricetodon prefers a relatively dry and warm environment, but it can rarely be present in wet conditions (Daams and Freudenthal, Reference Daams and Freudenthal1988a). Its abundance in the Çapak assemblage, therefore, suggests a change towards a drier environment. Myomimus tanjuae n. sp. from Çapak is the third most abundant species and the only glirid in the fauna. Following the morphotype classification of van der Meulen and De Bruijn (Reference Van der Meulen and de Bruijn1982), Myomimus from Çapak is classified as part of the asymmetrical molar group (i.e., ground dwellers that prefer an open country biotope). The flying squirrel Aliveria is rare, but surprisingly present in the assemblage and, as an arboreal animal, suggests that part of the environment was woodland. During the early Miocene of Anatolia, Eumyarion was one of the most diverse and dominant genera and is considered to have preferred humid conditions, such as those inferred for the localities of Keseköy, Sabuncubeli, Harami, and Gördes (e.g., De Bruijn and Saraç, Reference De Bruijn and Saraç1991; De Bruijn et al., Reference De Bruijn, Mayda, Van den Hoek Ostende, Kaya and Saraç2006; Bilgin et al., Reference Bilgin, Joniak, Mayda, Göktaş, Kaya, Peláez-Campomanes and Van den Hoek Ostende2019; Joniak et al., Reference Joniak, Peláez-Campomanes, Mayda, Bilgin, Halaçlar, Van den Hoek Ostende, Van den Hoek Ostende, Mayda and Kaya2019; Peláez-Campomanes et al., Reference Peláez-Campomanes, Göktaş, Kaya, Joniak, Bilgin, Mayda, Van den Hoek Ostende, Van den Hoek Ostende, Mayda and Kaya2019). By contrast, Çapak has a very limited presence of Eumyarion, while Megacricetodon and Democricetodon become the most dominant genera at that time. These changes are clearly seen when comparing faunal compositions and appear to be the result of a transition from a moist and close environment in the early Miocene to a dry and more open environment in the middle Miocene in Anatolia.

The age of the assemblage

The Çapak assemblage yielded an interesting mixture of Anatolian and European species that is unlike any other rodent assemblage in Anatolia. Its elements occur between local zone D–G or MN3–MN6 (Figure 10). Unfortunately, some rarer elements could not be identified at the species level, but the overall distribution of fauna provides sufficient clues to the age of the locality.

Figure 10. The biochronological ranges of the taxa from Çapak assemblage based on the Anatolian local zones and MN units.

The most abundant species, Megacricetodon primitivus, is very well known and characteristic for MN4–5 of Spain. It is also known from the Greek locality of Antonios (MN5) (Vasileiadou and Koufos, Reference Vasileiadou and Koufos2005) and was listed from several Turkish localities (Saraç, Reference Saraç2003). Surprisingly, M. primitivus is not known from central Europe, and therefore seems to have a disjunct distribution. Even though this may cast some doubts on the relationship between Iberian populations and those from the eastern Mediterranean, there are no clear differences between the Spanish and the Çapak material.

Democricetodon gracilis shows similar characters with D. gracilis from Forsthart (MN4) and the type locality of Sandelzhausen (MN5), being more like the former in having a somewhat lower crown. Democricetodon gracilis was mentioned as one of the typical taxa for local zone E by Ünay et al. (Reference Ünay, de Bruijn and Saraç2003), a zone that the authors correlated to Unit MN4.

Eumyarion is the most abundant genus in Anatolian faunas from the local zones C and D (MN2–MN3) (e.g., De Bruijn et al., Reference De Bruijn, Fahlbusch, Saraç and Ünay1993; Joniak et al., Reference Joniak, Peláez-Campomanes, Mayda, Bilgin, Halaçlar, Van den Hoek Ostende, Van den Hoek Ostende, Mayda and Kaya2019) Eumyarion is only represented in Anatolia by very limited material from local zone E (MN4) (e.g., Ünay et al., Reference Ünay, Atabey and Saraç2001) and from the local zones E–H, there is no record of Eumyarion at all. However, in local zone H (MN7–8), a single specimen was reported from Sarıçay (Rummel, Reference Rummel1998). Eumyarion from Çapak is represented by just a few elements, and these are clearly different from any other species known so far, being most similar to E. montanus from Keseköy (local zone D, MN3), but with more advanced characteristics.

Cricetodon sp. shares several characters with C. pasalarensis from Paşalar (local zone F/G, MN5/6) and with C. candirensis from Çandır (local zone G, MN6), but the limited material does not allow its assignation to either species. The second Cricetodon shares similarities with C. aliveriensis from Karydia (MN4).

The rare taxon Karydomys ranges from MN3 to MN6 (e.g., Mörs and Kalthoff, Reference Mörs and Kalthoff2004; Maridet et al., Reference Maridet, Wu, Ye, Bi, Ni and Meng2011). The single specimen from Çapak is metrically and morphologically very close to K. strati from the island of Chios (MN5) (López-Antoñanzas et al., Reference López-Antoñanzas, Peláez-Campomanes, Prieto and Knoll.2018).

The first occurrence of Debruijnia is from local zone D (MN3), from the localities of Keseköy and Sabuncubeli, and the genus has its last occurrence in MN4 from the locality of Karydia (De Bruijn, Reference De Bruijn2017). Debruijnia sp. from Çapak is metrically within the range D. kostakii from Karydia, but the morphological comparison is hampered by it being unworn.

The flying squirrel, Aliveria luteyni, is known from the localities of Aliveri and Karydia in Greece and Kaplangı 1 and Kaplangı 2 in Turkey. All these localities are correlated to MN4.

The Ochotonidae Albertona is very characteristic for the late early Miocene lagomorphs from the eastern Mediterranean and Serbia (López Martínez, Reference López Martínez1986; Ünay and Göktaş, Reference Ünay and Göktaş1999; Marković, Reference Marković2010). The specimens from Çapak fall metrically and morphologically within the variation of the type material of Albertona balkanica from Aliveri.

The Çapak assemblage shares similarities with the locality of Aliveri in many respects. Cricetodon aliveriensis, Democricetodon gracilis, Aliveria luteyni, and Albertona balkanica are known from both localities, but the stage of evolution of Cricetodon cf. C. aliveriensis from Çapak seems more advanced than C. aliveriensis from Aliveri and closer to the assemblage from Karydia. Even though the localities of Çapak and Aliveri share some species, they clearly represent different environments. Because both faunas were collected from lignitic lacustrine deposits, we assume this represents a different ecosystem in the surrounding landscape. The locality of Aliveri shows a large diversity of rodents and the presence of the eomyids Pseudotheridomys and Ligerimys, as well as three species of flying squirrel, points to a forested environment. However, the locality of Çapak has less diversity than Aliveri, and the dominance of Megacricetodon primitivus (52%) followed by 17.6% for Myomimus tanjuae n. sp. indicates a dry and open environment.

Based on our current state of knowledge, the Çapak assemblage seems to be best placed in the uppermost part of zone E, younger than Aliveri and correlated with late MN4.

Biogeographic implications

Because of the diachronicity of the MN-system (van der Meulen et al., Reference Van der Meulen, García-Paredes, Angeles Alvarez-Sierra, Van den Hoek Ostende, Hordijk, Oliver, López Guerrero, Hernández-Ballarín and Peláez-Campomanes2011, Reference Van der Meulen, García-Paredes, Alvarez-Sierra, Van den Hoek Ostende, Hordijk, Oliver and Peláez-Campomanes2012), the exact temporal relation of Çapak to the central European MN4 localities remains unclear. Generally, this diachronicity implies that localities in the east can be older than those from the same zone in the west. This is clear for the locality of Aliveri, which, as an MN4 locality, contains the eomyid Pseudotheridomys, a taxon that is mainly known from MN3 sites in the rest of Europe. Van den Hoek Ostende et al. (Reference Van den Hoek Ostende, Mayda, Oliver, Madern, Hernández-Ballarín, Peláez-Campomanes, Van den Hoek Ostende, Peláez-Campomanes and Wessels2015) followed Koufos (Reference Koufos2006) in estimating the age of Aliveri between 18.0–17.5 Ma, stressing, however, that this is just an estimate. In the Daroca-Calamocha area in Spain, the lower boundary of MN4 is placed at 17.0 Ma (van der Meulen et al., Reference Van der Meulen, García-Paredes, Alvarez-Sierra, Van den Hoek Ostende, Hordijk, Oliver and Peláez-Campomanes2012).

Van den Hoek Ostende et al. (Reference Van den Hoek Ostende, Mayda, Oliver, Madern, Hernández-Ballarín, Peláez-Campomanes, Van den Hoek Ostende, Peláez-Campomanes and Wessels2015) suggested that a drying trend from the east may have been the cause behind the migrations of Megacricetodon, Democricetodon, and Eumyarion from Anatolia to Europe. However, it is unlikely that such a trend affected the migration of Eumyarion because this genus favors humid circumstances. Nevertheless, it is clear that the genus must have migrated into Europe before it was extirpated in Anatolia and, as we now know, Çapak represents the last Anatolian occurrence before that extirpation. Megacricetodon and Democricetodon, on the other hand, seem to have favored the dryer condition at Çapak, and may well have expanded their distribution as drier conditions also developed in Europe. As we noted, the chronology is still unclear and finding a point of comparison for dating the changes heralded by the Çapak fauna remains an important challenge for the future.

Conclusions

Çapak is an exciting location having both European and Anatolian elements in its faunal assemblage. This provides us with a view of the evolution of micromammals from a little-known period in western Anatolia. The assemblage yielded nine rodents and one lagomorph species: Myomimus tanjuae n. sp., Democricetodon gracilis, Megacricetodon primitivus, Eumyarion aff. E. montanus, Cricetodon sp., Cricetodon cf. C. aliveriensis, Karydomys cf. K. strati, Debruijnia sp., Aliveria luteyni, and Albertona balkanica. Judged on the basis of a faunal comparison, the locality of Çapak would seem to be younger than Aliveri and close to that of Karydia, best located in the uppermost part of local zone E, which is correlated with MN4. The dominance of Megacricetodon primitivus and Myomimus tanjuae n. sp. and the presence of a small number of Aliveria luteyni and Eumyarion aff. E. montanus indicate a transition from a humid and forest environment in the early Miocene to an open and dry environment in the middle Miocene.

Acknowledgments

We are thankful to T. Kaya, who provided us the opportunities of Ege University and who has lent her unwavering support to all our scientific endeavors in Anatolia. The staff of the Natural History Museum of Ege University made us feel at home during our campaigns and we are grateful for all the support of H. Akgün, A. Tekin, Y. Koç, Ö. Binici, and E. Çakır. P. Skandalos and F. Cailleux helped us during the fieldwork campaign and their work and warm companionship are gratefully acknowledged. We are thankful to A. Blair-Gould for her linguistic emendations. The authors also thank the reviewers I. Casanovas-Vilar, Ş. Şen, and an anonymous reviewer.

This work was funded by National Geographic grant “Palaeogeography of Mammals Following the Collision of the African and Eurasian Plates” (GEFNE 140-15). This study was supported by Ege University (TTM/001/2016) and (TTM/002/2016) to SM and MB. This study was also supported by grants UK/123/2019, UK/145/2020; Scientific Grant Agency of the Ministry of Education, Science, Research and Sport of the Slovak Republic VEGA 1/0164/19, 1/0533/21, and by the Slovak Research and Development Agency under contract Nos. APVV-15-0575 and APVV-16-0121. This work was partially supported by project PGC2018-094122-B-I00 funded by FEDER/ Ministerio de Ciencia e Innovación-Agencia Estatal de Investigación.

References

Aguilar, J.P., 1974, Les rongeurs du Miocène inférieur en Bas-Languedoc et les corrélations entre échelles stratigraphiques marine et continentale: Géobios, v. 7, p. 345398.CrossRefGoogle Scholar
Aguilar, J.P., 1982, Biozonation du Miocène d'Europe occidentale à l'aide des rongeurs et corrélations avec l’échelle stratigraphique marine: Comptes Rendus de l'Académie des Sciences, Paris, série II, v. 294, p. 4954.Google Scholar
Agustí, J., 1981, Roedores Miomorfos del Neógeno de Cataluña [Ph.D. thesis]: Barcelona, Universitat de Barecelona, 288 p.Google Scholar
Akgün, F., Kayseri-Özer, M.S., Tekin, E., Varol, B., Sen, S., Herece, E., Gündoğan, İ., Sözeri, K., and Us, S.M., 2021, Late Eocene to late Miocene palaeoecological and palaeoenvironmental dynamics of the Ereğli-Ulukışla Basin (Southern Central Anatolia): Geological Journal, v. 56, p. 673703. https://doi.org/10.1002/gj.4021.CrossRefGoogle Scholar
Álvarez-Sierra, M.A., and García-Moreno, E., 1986, New Gliridae and Cricetidae from the middle and upper Miocene of the Duero Basin, Spain: Studia Geologica Salmanticensia, v. 22, p. 145189.Google Scholar
Álvarez Sierra, M.A., Daams, R., Lacomba, J.I., López Martínez, N., van der Meulen, A.J., Sesé, C., and De Visser, J., 1991, Paleontology and biostratigraphy (micromammals) of the continental Oligocene–Miocene deposits of the north-central Ebro Basin (Huesca, Spain): Scripta Geologica, v. 94, p. 177.Google Scholar
Bate, D.M.A., 1937, Palaeontology: the fossil fauna of the Wady el Mughara caves, in Garrod, D.A.E., and Bate, D.M.A., eds., The Stone Age of Mount Carmel, part 2: Oxford, Clarendon Press, p. 137240.Google Scholar
Bi, S., Meng, J., and Wu, W., 2008, A new species of Megacricetodon (Cricetidae, Rodentia, Mammalia) from the middle Miocene of northern Junggar Basin, China: American Museum Novitates, n. 3602, p. 123.CrossRefGoogle Scholar
Bilgin, M., Joniak, P., Mayda, S., Göktaş, F., Kaya, T., Peláez-Campomanes, P., and Van den Hoek Ostende, L., 2019, Sabuncubeli too, Bornova, a second micromammal assemblage from the Sabuncubeli section (early Miocene, western Anatolia), in Van den Hoek Ostende, L.W., Mayda, S., and Kaya, T., eds., Taking the Orient Express? The Role of Anatolia in Mediterranean Neogene Palaeobiogeography: Palaeobiodiversity and Palaeoenvironments, v. 99, p. 655671.CrossRefGoogle Scholar
Bosma, A.A., De Bruijn, H., and Wessels, W., 2018, Early and middle Miocene Sciuridae (Mammalia, Rodentia) from Anatolia, Turkey: Journal of Vertebrate Paleontology, v. 38, no. 6, e1537281. https://doi.org/10.1080/02724634.2018.1537281.CrossRefGoogle Scholar
Bowdich, T.E., 1821, An Analysis of the Natural Classifications of Mammalia for the Use of Students and Travellers. Paris, J. Smith, 115 p.Google Scholar
Brandt, J.F., 1855, Untersuchungen über die craniologischen Entwicklungsstufen und Classification der Nager der Jetztwelt: Mémoires de l'Académie Impériale des Sciences de St. Pétersbourg, Serie 6, v. 9, p. 1365.Google Scholar
Bulot, C., 1980, Nouvelle description de deux espèces du genre Megacricetodon (Cricetidae, Rodentia) du Miocene de Bezian (Zone de La Romieu): Bulletin du Muséum National d'Histoire Naturelle Section C Sciences de la Terre Paléontologie Géologie Minéralogie, v. 2, p. 316.Google Scholar
Cuenca Bescós, G., 1988, Revisión de los Sciuridae del Aragoniense y del Rambliense en la fosa de Calatayud-Montalbán: Scripta Geologica, v. 87, p. 1127.Google Scholar
Çınar Durgut, N., and Ünay, E., 2016, Cricetodontini from the early Miocene of Anatolia: Bulletin of the Mineral Research and Exploration, v. 152, p. 85119.Google Scholar
Daams, R., 1981, The dental pattern of the Dormice Dryomys, Myomimus, Microdyromys and Peridyromys: Utrecht Micropaleontological Bulletins, Special Publication, v. 3, p. 1113.Google Scholar
Daams, R., 1999, Peridyromys darocensis and Peridyromys sondaari, two new species of Gliridae (Rodentia, Mammalia) from the lower Miocene (MN3–5) of the Calatayud-Daroca Basin, Zaragoza, Spain, in Reumer, J.W.F., and De Vos, J., eds., Elephants Have a Snorkel!: Deinsea, v. 7, p. 8390.Google Scholar
Daams, R., and Freudenthal, M., 1981, Aragonian: the Stage concept versus Neogene Mammal Zones: Scripta Geologica, v. 62, p. 117.Google Scholar
Daams, R., and Freudenthal, M., 1988a, Cricetidae (Rodentia) from the type-Aragonian; the genus Megacricetodon: Scripta Geologica, Special Issue, v. 1, p. 39132.Google Scholar
Daams, R., and Freudenthal, M., 1988b, Synopsis of the Dutch Spanish collaboration program in the Aragonian type area. 1975–1986: Scripta Geologica, Special Issue, v. 1, p. 318.Google Scholar
Daxner-Höck, G., 1998, Säugetiere (Mammalia) aus dem Karpat des Korneuburger Beckens. 3. Rodentia und Carnivora: Beiträge zur Paläontologie, v. 23, p. 367407.Google Scholar
De Bruijn, H., 1966, On the mammalian fauna of the Hipparion-beds in the Calatayud-Teruel Basin (Prov. Zaragoza, Spain). Part II—Gliridae: Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen Serie B, v. 69, p. 367387.Google Scholar
De Bruijn, H., 2017, A new stage in the evolution of the mole rats (Rodentia, Spalacinae) from the Early Miocene of northern Greece: Historical Biology, v. 29, no. 5, p. 571575.CrossRefGoogle Scholar
De Bruijn, H., and Moltzer, J.C., 1974, The rodents from Rubielos de Mora: the first evidence of the existence of different biotopes in the early Miocene of Eastern Spain: Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen, Serie B, v. 77, p. 129145.Google Scholar
De Bruijn, H., and Saraç, G., 1991, Early Miocene rodent faunas from the eastern Mediterranean area. Part I. The genus Eumyarion: Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen, Serie B, v. 94, p. 136.Google Scholar
De Bruijn, H., Dawson, M.R., and Mein, P., 1970, Upper Pliocene Rodentia, Lagomorpha and Insectivora (Mammalia) from the Isle of Rhodes (Greece): Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen, Serie B, v. 73, p. 535584.Google Scholar
De Bruijn, H., van der Meulen, A.J., and Katsikatsos, G., 1980, The mammals from the lower Miocene of Aliveri (Island of Evia, Greece) 1. The Sciuridae: Proceedings of the Koninklijke Nederlandse Akademie Van Wetenschappen, Serie B, v. 83, p. 241261.Google Scholar
De Bruijn, H., Daams, R., Daxner-Höck, G., Fahlbusch, V., Ginsburg, L., Mein, P., and Morales, J., 1992, Report of the RCMNS working group on fossil mammals, Reisensburg 1990: Newsletters on Stratigraphy, v. 26, p. 65118.CrossRefGoogle Scholar
De Bruijn, H., Fahlbusch, V., Saraç, G., and Ünay, E., 1993, Early Miocene rodent faunas from the eastern Mediterranean area. 3. The genera Deperetomys and Cricetodon with a discussion of the evolutionary history of the Cricetodontini: Proceedings of the Koninklijke Nederlandse Akademie Van Wetenschappen, Serie B, v. 96, p. 151216.Google Scholar
De Bruijn, H., Van den Hoek Ostende, L., Kristkoiz-Boon, M.R., Theocharapoulos, K., and Ünay, E., 2003, Rodents, lagomorphs and insectivores, from the middle Miocene hominoid locality of Çandir (Turkey): Courier Forschungsinstitut Senckenberg, v. 240, p. 5187.Google Scholar
De Bruijn, H., Mayda, S., Van den Hoek Ostende, L.W., Kaya, T., and Saraç, G., 2006, Small mammals from the early Miocene of Sabuncubeli (Manisa, S.W. Anatolia, Turkey): Beiträge zur Paläontologie, v. 30, p. 5787.Google Scholar
Fahlbusch, V., 1964, Die Cricetiden (Mammalia) der Oberen Süsswasser-Molasse Bayerns: Abhandlungen der Bayerischen Akademie der Wissenschaften. Mathematisch-naturwissenschaftliche Klasse, v. 118, p. 1135.Google Scholar
Fischer, G., 1817, Adversaria zoological: Société Impériale des Sciences Naturelles, Moscow, v. 5, p. 368428.Google Scholar
Freudenthal, M., 1963, Entwicklungsstufen der miozänen Cricetodontinae (Mammalia, Rodentia) Mittelspaniens und ihre stratigraphische Bedeutung: Beaufortia, v. 10, p. 51157.Google Scholar
Freudenthal, M., and Fahlbusch, V., 1969, Cricetodon minus Lartet, 1851, (Mammalia, Rodentia): request for a decision on interpretation. Z.N. (S.) 1854: Bulletin of Zoological Nomenclature, v. 25, p. 178183.CrossRefGoogle Scholar
García-Paredes, I., Peláez-Campomanes, P., and Alvarez-Sierra, M.A., 2010, Microdyromys remmerti, sp. nov., a new Gliridae (Rodentia, Mammalia) from the Aragonian type area (Miocene, Calatayud Montalban Basin, Spain): Journal of Vertebrate Paleontology, v. 30, p. 15941609.CrossRefGoogle Scholar
Göktaş, F., 2012, Kemalpaşa-Torbalı (İzmir) havzası ve yakın çevresindeki Neojen-Kuvaterner tortullaşması ile magmatizmasının jeolojik etüdü: Maden Tetkik ve Arama Genel Müdürlüğü Rapor No: 11575.Google Scholar
Gray, J.E., 1821, On the natural arrangement of vertebrose animals: London Medical Repository, v. 15, p. 296310.Google Scholar
Haas, G., 1973, The Pleistocene glirids of Israel: Verhandlungen der Naturforschhenden Gesellschaft, v. 83, p. 76110.Google Scholar
Illiger, C., 1811, Prodromus systematis mammalium et avium additis terminis zoographicis utriudque classis: Berlin, C. Salfeld, 301 p.CrossRefGoogle Scholar
Joniak, P., and de Bruijn, H., 2015, Rodents from the upper Miocene Tuğlu Formation (Çankırı Basin, Central Anatolia, Turkey): Paläontologische Zeitschrift, v. 89, p. 10391056.CrossRefGoogle Scholar
Joniak, P., Peláez-Campomanes, P., Van den Hoek Ostende, L.W., and Rojay, B., 2017, Early Miocene rodents of Gökler (Kazan Basin, Central Anatolia, Turkey): Historical Biology, v. 31, p. 9821007.CrossRefGoogle Scholar
Joniak, P., Peláez-Campomanes, P., Mayda, S., Bilgin, M., Halaçlar, K., and Van den Hoek Ostende, L.W., 2019, New faunas of small mammals from old Harami mine (early Miocene, Anatolia, Turkey), in Van den Hoek Ostende, L.W., Mayda, S., and Kaya, T., eds., Taking the Orient Express? The Role of Anatolia in Mediterranean Neogene Palaeobiogeography: Palaeobiodiversity and Palaeoenvironments, v. 99, p. 673700.Google Scholar
Jovells-Vaqué, S., and Casanovas-Vilar, I., 2018, Early Miocene Megacricetodon and Democricetodon (Cricetidae, Rodentia) from the Vallès-Penedès Basin (Catalonia): Fossilia, v. 2018, p. 1922.Google Scholar
Kaya, F., and Kaymakçi, N., 2013, Systematics and dental microwear of the late Miocene Gliridae (Rodentia, Mammalia) from Hayranli, Anatolia: implications for paleoecology and palaeobiodiversity: Palaeontologia Electronica, v. 16, no. 3, 16.3.21A, 22 p. https://doi.org/10.26879/385.Google Scholar
Kaya, O., Ünay, E., Göktaş, F., and Saraç, G., 2007, Early Miocene stratigraphy of central west Anatolia, Turkey: implications for the tectonic evolution of the eastern Aegean area: Geological Journal, v. 42, p. 85109.Google Scholar
Klein Hofmeijer, G., and de Bruijn, H., 1988, The mammals from the lower Miocene of Aliveri (Island of Evia, Greece) Part 8: The Cricetidae: Proceedings of the Koninklijke Nederlandse Akademie Van Wetenschappen, Serie B, v. 91, p. 185204.Google Scholar
Kordikova, E.G. and de Bruijn, H., 2001, Early Miocene rodents from the Aktau Mountains (south-eastern Kazakhstan): Senckenbergiana Lethaea, v. 81, p. 391405.CrossRefGoogle Scholar
Koufos, G.D., 2006, The Neogene mammal localities of Greece: faunas, chronology and biostratigraphy: Hellenic Journal of Geosciences, v. 41, p. 183214.Google Scholar
Lartet, Ε., 1851, Notice sur la colline de Sansan, sivre d'une récapitulation des diverses espèces d'animaux vertebrés fossiles trouvés soit a Sansan, soit dans d'autres gisements du terrain tertiare Miocene dans le bassin sous-Pyreneen, avec une liste des coquilles terrestres, lacustres et fluviatiles fossiles du même terrain: Auch, France, J. A. Portes, 47 p.Google Scholar
Lazzari, V., and Aguilar, J., 2007, Middle Miocene Megacricetodon species from the karstic locality of Blanquatere 1 (Pyrenees-Orientales, southern France): new species, biochronological and phylogenetical implications: Geobios, v. 40, p. 91111.CrossRefGoogle Scholar
Linnaeus, C., 1758, Systema Naturae per Regna Tria Naturae, Secundum Classes, Ordines, Genera, Species, cum Characteribus, Differentiis, Synonymis, Locis: Edition 10, reformata: Stockholm, Laurentii Salvii, 824 p.Google Scholar
López-Antoñanzas, R., Peláez-Campomanes, P., Prieto, J., and Knoll., F., 2018, New species of Karydomys (Rodentia) from the Miocene of Chios Island (Greece) and phylogenetic relationships of this rare democricetodontine genus: Papers in Palaeontology, v. 5, p. 3345.CrossRefGoogle Scholar
López Martínez, N., 1986, The mammals from the lower Miocene of Aliveri (Island of Evia, Greece). VI. The ochotonid lagomorph Albertona balkanika n. gen. n. sp. and its relationships: Proceedings of the Koninkllijke Nederlandse Akademie van Wettenshappen, Serie B, v. 89, p. 177194.Google Scholar
Maridet, O., Wu, W.Y., Ye, J., Bi, S.D., Ni, X.J., and Meng, J., 2011, Early Miocene cricetids (Rodentia) from the Junggar Basin (Xinjiang, China) and their biochronological implications: Geobios, v. 44, p. 445459.CrossRefGoogle Scholar
Marković, Z., 2010, Albertona balkanica from early Miocene of Snegotin (Serbia): implications for the distribution and evolution of Miocene Ochotonidae: Annales de Paléontologie, v. 96, p. 2532.CrossRefGoogle Scholar
Mein, P., 1958, Les mammifères de la faune sidérolithique du Vieux-Collonges: Nouvelles Archives du Muséum d'Histoire Naturelle de Lyon, v. 5, p. 1122.Google Scholar
Mein, P., and Freudenthal, M., 1981, Les Cricetidae (Mammalia, Rodentia) du Neogene Moyen de Vieux-Collonges. 2. Cricetodontinae incertae sedis, Melissiodontinae, Platacanthomyinae, et Anomalomyidae: Scripta Geologica, v. 60, p. 111.Google Scholar
Mörs, T., and Kalthoff, D.C., 2004, A new species of Karydomys (Rodentia, Mammalia) and a systematic re-evaluation of this rare Eurasian Miocene hamster: Palaeontology, v. 47, p. 13871405.CrossRefGoogle Scholar
Muirhead, L., 1819, Mazology, in Brewster, D., ed., The Edinburgh Encyclopedia, Fourth edition: v. 13, p. 393486.Google Scholar
Munthe, J., 1980, Rodents of the Miocene Daud Khel Local Fauna, Mianwali district, Pakistan. Part 1. Sciuridae, Gliridae, Ctenodactylidae, and Rhizomyidae: Contributions in Biology and Geology, Milwaukee Public Museum, v. 34, p. 136.Google Scholar
Ognev, S.I., 1924. Rodents of the Northern Caucasus: Rostov-na-Donu, Russia, Gos Izdt, 61 p. [in Russian].Google Scholar
Oliver, A., 2015, Evolution of Megacricetodon from the Aragonian and Vallesian (Miocene) of the Iberian Peninsula [Ph.D. dissertation]: Madrid, Universidad Complutense de Madrid, 318 p.Google Scholar
Oliver, A., and Peláez-Campomanes, P., 2013, Megacricetodon vandermeuleni sp. nov. (Rodentia, Mammalia), from the Spanish Miocene: a new evolutionary framework for Megacricetodon: Journal of Vertebrate Paleontology, v. 33, p. 943955.CrossRefGoogle Scholar
Oliver, A., and Peláez-Campomanes, P., 2014, Evolutionary patterns of early and middle Aragonian (Miocene) of Megacricetodon (Rodentia, Mammalia) from Spain: Palaeontographica Abteilung A, v. 303, no. 4–6, p. 85135.CrossRefGoogle Scholar
Oliver, A., and Peláez-Campomanes, P., 2016, Early Miocene evolution of the rodent Megacricetodon in Europe and its palaeobiogeographical implications: Acta Palaeontologica Polonica, v. 61, p. 211219.Google Scholar
Oliver Pérez, A., López Guerrero, P., Peláez-Campomanes, P., 2008, Primer representante del género Megacricetodon de la Cuenca de Calatayud-Daroca (Zaragoza, España): Palaeontologica Nova, v. 8, p. 317329.Google Scholar
Peláez-Campomanes, P., and Daams, R., 2002, Middle Miocene rodents from Paşalar, Anatolia, Turkey: Acta Palaeontologica Polonica, v. 47, p. 125132.Google Scholar
Peláez-Campomanes, P., Göktaş, F., Kaya, T., Joniak, P., Bilgin, M., Mayda, S., and Van den Hoek Ostende, L.W., 2019, Gördes, a new early Miocene micromammal assemblage from western Anatolia, in Van den Hoek Ostende, L.W., Mayda, S., and Kaya, T., eds., Taking the Orient Express? The Role of Anatolia in Mediterranean Neogene Palaeobiogeography: Palaeobiodiversity and Palaeoenvironments, v. 99, p. 639653.Google Scholar
Pomel, N.A., 1853, Catalogue méthodique et descriptif des vertébrés fossiles découverts dans le bassin hydrographique supérieur de la Loire, et surtout dans la vallée de son affluent principal l'Allier. Catalogue des vertébrés fossiles (suite et fin): Annales Scientifiques, Littéraires et Industrielles de l'Auvergne, v. 24, p. 81229.Google Scholar
Rögl, F., 1999, Mediterranean and Paratethys. Facts and hypotheses of an Oligocene to Miocene paleogeography: Geologica Carpathica, v. 50, p. 339349.Google Scholar
Rummel, M., 1998, Die Cricetiden aus dem Mittel-und Obermiozän der Türkei: Documenta Naturae, v. 123, 300 p.Google Scholar
Sach, V.J., and Heizmann, E.P.J., 2001, Stratigraphy and mammal faunas of the Brackwassermolasse in the surroundings of Ulm (Southwest Germany): Stuttgarter Beiträge zur Naturkunde, Serie B, v. 310, p. 195.Google Scholar
Saraç, G., 2003, Türkiye Omurgalı Fosil Yatakları (Mammalian Fossils Localities in Turkey). Rapor Yazısı: Maden Tetkik Arama Genel Müdürlüğü (Mineral Research and Exploration Institute [MTA] of Turkey Report), No: 10609, 218 p.Google Scholar
Sarıca, N., and Sen, S., 2003, Spalacidae, in Fortelius, M., Kappelman, J., and Bernor, R.L., eds., Geology and Paleontology of the Miocene Sinap Formation, Turkey: New York, Columbia University Press, p. 141163.Google Scholar
Schaub, S., 1925, Die hamsterartigen Nagetiere des Tertiärs und ihre lebende Verwandten: Abhandlungen der Schweizerischen Paläontologischen Gesellschaft, v. 14, p. 1111.Google Scholar
Sen, S., 1990, Stratigraphie, faunes de mammifères et magnétostratigraphie du Néogène de Sinap Tepe, Province d'Ankara, Turquie: Bulletin de la Museum National d'Histoire Naturelle, Série 4e, v. 12, p. 243277.Google Scholar
Sen, S., and Ünay, E., 1979, Sur quelques Cricetodontini (Rod.) du Miocène moyen d'Anatolie: Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen, Series B, v. 82, p. 293301.Google Scholar
Skandalos, P., 2017, Study of Cricetodon (Rodentia, Mammalia) from the early Miocene locality of Karydia (Rhodope, North Greece) [M.Sc. thesis]: Athens, National and Kapodistrian University of Athens, Greece Faculty of Geology and Geoenvironment Department of Historical Geology and Palaeontology, 121 p.Google Scholar
Sözbilir, H., Sarι, B., Uzel, B., Sümer, Ö. and Akkiraz, S., 2011, Tectonic implications of transtensional supradetachment basin development in an extension-parallel transfer zone: the Kocaçay Basin, western Anatolia, Turkey: Basin Research, v. 23, p. 423448.CrossRefGoogle Scholar
Suárez Hernando, O., 2017, Magnetobiocronología y Paleoecología del Mioceno inferior-medio en las Bardenas Reales de Navarra (Cuenca del Ebro) [Ph.D. Thesis]: Bilbao, Universidad del País Vasco/Euskal Herriko Unibertsitatea, 315 p.Google Scholar
Sümengen, M., Ünay, E., de Bruijn, H., Terlemez, I. and Gürbüz, M. 1990, New Neogene rodent assemblages from Anatolia (Turkey), in Lindsay, E.H., Fahlbusch, V., and Mein, P., eds., European Mammal Chronology: New York, Plenum Press, p. 6172.CrossRefGoogle Scholar
Thaler, L., 1966, Les Rongeurs fossiles du Bas-Languedoc dans leurs rapports avec l'histoire des faunes et la stratigraphie du Tertiaire d'Europe: Mémoires du Museum National d'Histoire Naturelle, sér. C, v. 17, p. 1295.Google Scholar
The NOW Community, 2020, New and Old Worlds Database of Fossil Mammals (NOW). Licensed under CC BY 4.0. Retrieved [09.08.2020] from https://nowdatabase.org/now/database/. http://doi.org/10.5281/zenodo.4268068.CrossRefGoogle Scholar
Theocharopoulos, C., 2000, Late Oligocene–middle Miocene Democricetodon, Spanocricetodon and Karydomys n. gen. from the eastern Mediterranean area: Gaia, v. 8, p. 192.Google Scholar
Thomas, O., 1897, On the genera of rodents: an attempt to bring up to date the current arrangement of the order: Proceedings of the Zoological Society of London, v. 1897, p. 10121028.Google Scholar
Tobien, H., 1978, New species of Cricetodontini (Rodentia, Mammalia) from the Miocene of Turkey: Mainzer Geowissenschaftliche Mitteilungen, v. 6, p. 209219.Google Scholar
Ünay, E., 1990, Turkomys pasalarensis Tobien, its range of variation in the type locality at Paşalar, Turkey: Journal of Human Evolution, v. 19, p. 437443.CrossRefGoogle Scholar
Ünay, E., 1994, Early Miocene rodent faunas from the eastern Mediterranean area. Part IV. The Gliridae: Proceedings Koninklijke Nederlandse Akademie van Wetenschappen, Serie B, v. 97, p. 445490.Google Scholar
Ünay, E., 1996, On fossil Spalacidae (Rodentia), in Bernor, R.L., Falbusch, V., and Mittmann, H.W., eds., The Evolution of Western Eurasian Neogene Mammal Faunas: New York, Columbia University Press, p. 246252.Google Scholar
Ünay, E., and Göktaş, F., 1999, Late early Miocene and Quaternary small mammals in the surroundings of Söke (Aydin): preliminary results: Geological Bulletin of Turkey, v. 42, p. 99113.Google Scholar
Ünay, E., and Göktaş, F., 2000, Small mammal biochronology of the early Miocene lignitiferous sediments around Kınık (Gördes): preliminary results: Geological Bulletin of Turkey, v. 43, p. 15.Google Scholar
Ünay, E., Atabey, E., and Saraç, G., 2001, Small mammals and foraminifera from the Anatolian (Central Taurus) early Miocene: Annals of Carnegie Museum, v. 70, p. 247256.Google Scholar
Ünay, E., de Bruijn, H., and Saraç, G., 2003, A preliminary zonation of the continental Neogene of Anatolia based on rodents: Deinsea, v. 10, p. 539548.Google Scholar
Van den Hoek Ostende, L.W., 1992, Insectivore faunas from the lower Miocene of Anatolia. part 1. Erinaceidae: Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen, Serie B, v. 95, p. 437467.Google Scholar
Van den Hoek Ostende, L.W., 1995, Insectivore faunas from the lower Miocene of Anatolia. Part 3: Dimylidae: Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen, Serie B, v. 98, p. 1938.Google Scholar
Van den Hoek Ostende, L.W., 1997, Insectivores from the lower Miocene of Anatolia. Part 4: the genus Desmanodon (Talpidae) with the description of a new species from the lower Miocene of Spain: Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen, v. 100, p. 2765.Google Scholar
Van den Hoek Ostende, L.W., 2001, Insectivore faunas from the lower Miocene of Anatolia. Part 8: Stratigraphy, palaeoecology, palaeobiogeography: Scripta Geologica, v. 122, p. 101122.Google Scholar
Van den Hoek Ostende, L.W., Mayda, S., Oliver, A., Madern, A., Hernández-Ballarín, V., and Peláez-Campomanes, P., 2015, Aliveri revisited, a biogeographical appraisal of the early Miocene mammals from the eastern Mediterranean, in Van den Hoek Ostende, L.W., Peláez-Campomanes, P., and Wessels, W., eds., Old Worlds, New Ideas. A tribute to Albert van der Meulen: Palaeobiodiversity and Palaeoenvironments, v. 95, p. 271284.Google Scholar
Van der Meulen, A.J., and de Bruijn, H., 1982, The Mammals from the lower Miocene of Aliveri (Island of Evia, Greece). Part 2. The Gliridae: Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen, ser. B, v. 85, p. 485524.Google Scholar
Van der Meulen, A.J., García-Paredes, I., Angeles Alvarez-Sierra, M., Van den Hoek Ostende, L.W., Hordijk, K., Oliver, A., López Guerrero, P., Hernández-Ballarín, V., Peláez-Campomanes, P., 2011, Biostratigraphy or biochronology? Lessons from the early and middle Miocene small mammal events in Europe: Geobios, v. 44, p. 309321.CrossRefGoogle Scholar
Van der Meulen, A.J., García-Paredes, I., Alvarez-Sierra, M.A., Van den Hoek Ostende, L.W., Hordijk, K., Oliver, A., and Peláez-Campomanes, P., 2012, Updated Aragonian biostratigraphy: small mammal distribution and its implications for the Miocene European chronology: Geologica Acta, v. 10, p. 159179.Google Scholar
Vasileiadou, K., and Koufos, G.D., 2005, The micromammals from the early/middle Miocene locality of Antonios, Chalkidiki, Greece: Annales de Paléontologie, v. 91, p. 197225.CrossRefGoogle Scholar
Von Meyer, H., 1859, Mittheilungen an Professor Bronn: Neues Jahrbuch für Mineralogie, Geologie und Paläontologie, Stuttgart, p. 172177.Google Scholar
Wessels, W., 2009, Miocene rodent evolution and migration: Muroidea from Pakistan, Turkey and northern Africa: Geologica Ultraiectina, v. 307, p. 1290.Google Scholar
Wessels, W., and Reumer, B.M., 2009, Democricetodon and Megacricetodon (Mammalia, Cricetidae) from the Miocene of Sandelzhausen, southern Germany: Paläontologische Zeitschrift, v. 83, p. 187205.CrossRefGoogle Scholar
Wessels, W., Theocharopoulos, K.D., de Bruijn, H., and Ünay, E., 2001, Myocricetodontinae and Megacricetodontini from the lower Miocene of NW Anatolia: Lynx, v. 32, p. 371388.Google Scholar
Ziegler, R., and Fahlbusch, V., 1986, Kleinsäuger-Faunen aus der basalen Oberen Süßwasser-Molasse Niederbayerns: Zitteliana, v. 14, p. 380.Google Scholar
Figure 0

Figure 1. (1) Regional geological location of the Kocaçay Neogene basin. (2) Simplified geological map of the Kocaçay Neogene basin. (3) Early-middle Miocene sequence that crops out around Çapak village: (1) pre-Neogene basement, (2) fan-delta deposits, (3) lacustrine paper-shale deposits, (4) lacustrine limestone, (5) fluvial deposits, (6) Holocene alluvium (modified from Göktaş, 2012). (4) Outcrop view of Çapak. (5) The fossiliferous layer of Çapak.

Figure 1

Figure 2. Myomimus tanjuae n. sp. (1) D4 sin (PV13091), (2) M1/2 sin (PV13097; holotype), (3) M1/2 sin (PV13094), (4) M1/2 sin (PV13093), (5) M3 sin (PV13105), (6) M3 sin (PV13106), (7) p4 sin (PV13134), (8) p4 sin (PV13111), (9) m1 dex (PV13120), (10) m1 dex (PV13124), (11) m2 dex (PV13119), (12) m2 sin (PV13116), (13) m3 sin (PV13129), (14) m3 sin (PV13130), (15) m3 dex (PV13125).

Figure 2

Table 1. Measurements of Myomimus tanjuae n. sp. from Çapak.

Figure 3

Figure 3. Scatter diagram of the upper and lower molars of Myomimus and Peridyromys from Anatolia and Europ (data after Daams, 1981; Peláez-Campomanes and Daams, 2002; De Bruijn et al., 2003).

Figure 4

Figure 4. Democricetodon gracilis Fahlbusch, 1964. (1) M1 sin (PV13001), (2) M1 dex (PV13008), (3) M2 dex (PV13015), (4) M2 sin (PV13011), (5) M3 sin (PV13026), (6) M3 dex (PV13028), (7) m1 sin (PV13037), (8) m1 dex (PV13032), (9) m1 dex (PV13030), (10) m2 dex (PV13045), (11) m2 sin (PV13048), (12) m3 sin (PV13054), (13) m3 sin (PV13057).

Figure 5

Table 2. Measurements of Democricetodon gracilis from Çapak.

Figure 6

Figure 5. Scatter diagram of the upper and lower first molars of small sized Democricetodon from Anatolia and adjacent area (data are after Klein Hofmeijer and De Bruijn, 1988; Theocharopoulos, 2000; Wessels and Reumer, 2009).

Figure 7

Figure 6. Megacricetodon primitivus (Freudenthal, 1963). (1) M1 sin (PV13237), (2) M1 dex (PV13238), (3) M1 dex (PV13239), (4) M2 sin (PV13264), (5) M2 sin (PV13266), (6) M2 sin (PV13269), (7) M3 sin (PV13281), (8) M3 sin (PV13282), (9) m1 sin (PV13301), (10) m1 dex (PV13312), (11) m2 sin (PV13324), (12) m2 dex (PV13335), (13) m2 dex (PV13333), (14) m3 sin (PV13341), (15) m3 sin (PV13339).

Figure 8

Table 3. Measurements of Megacricetodon primitivus from Çapak.

Figure 9

Figure 7. Scatter diagram of the upper and lower first molars of small and medium-sized Megacricetodon from Anatolia, Europe, and Asia (data are after Mein, 1958; Freudenthal, 1963; Wessels et al., 2001; Peláez-Campomanes and Daams, 2002; Lazzari and Aguilar, 2007; Bi et al., 2008; Oliver Pérez et al., 2008; Oliver and Peláez-Campomanes; 2014, 2016; Oliver, 2015).

Figure 10

Figure 8. Eumyarion aff. E. montanus De Bruijn and Saraç, 1991. (1) M2 dex (PV13210), (2) M3 dex (PV13211), (3) m1 sin (PV13212), (4) m3 sin (PV13215). Cricetodon sp. (5) M1 dex (PV13203), (6) M3 sin (PV13204). Cricetodon cf. C. aliveriensis Klein Hofmeijer and De Bruijn, 1988. (7) M1 sin (PV13201), (8) m2 dex (PV13200). Karydomys cf. K. strati López-Antoñanzas et al., 2018. (9) M2 sin (PV13216). Debruijnia sp. (10) M3 dex (PV13220). Aliveria luteyni De Bruijn, Van der Meulen, and Katsikatsos, 1980. (11) M3 sin (PV13217). Albertona balkanica López Martínez, 1986. (12) p3 dex (PV13223), (13) p3 sin (PV13224).

Figure 11

Figure 9. Scatter diagram of the upper first molar of medium and large sized Cricetodon from Anatolia and adjacent area (data after Klein Hofmeijer and De Bruijn, 1988; Ünay, 1990; De Bruijn et al., 1993, 2003; Vasileiadou and Koufos, 2005; Çınar Durgut and Ünay, 2016; Skandalos, 2017).

Figure 12

Table 4. The rodent composition of the Çapak assemblage. The entry “0(1)” is used in those instances in which the last molars and, for some taxa, premolars are excluded from the count because these elements are generally small and may have been lost while processing (which would give a bias towards larger species). If a species is only represented by premolars or M3s, it is counted as 1, because otherwise the data would falsely suggest an absence of that species.

Figure 13

Figure 10. The biochronological ranges of the taxa from Çapak assemblage based on the Anatolian local zones and MN units.