Does the geometric and linear morphometry of the brain reflect the divergence in the "guentheri" group (Arvicolinae, Sumeriomys)?
Zorenko T., Kagainis U., Barashkova L.
P. 45-57
The purpose of this work is to investigate the divergence of the brain size and shape of three voles taxa of "guentheri" group using geometric and linear morphometric analysis. The obtained data show that the sex factor does not affect the brains linear parameters and shape of the studied taxa that indicates a weak effect of the sexual selection on morphological adaptation and variability of the brain structure. The linear measurements of the investigated taxa differ significantly by all signs (24 parameters). The obtained data indicate that the divergence of Microtus guentheri and M. hartingi is the most significant (92%) that obviously is associated with ancient isolation of this species by Anatolian Diagonal. The differences between the two subspecies (M. hartingi hartingi and M. h. lydius) are much smaller — 63%. It should be noted that the vole of the Strandzha Mountain — M. h. strandzensis differs from the M .h. hartingi and M. h. lydius significantly more — 82 and 75%, respectively. These differences may reflect the history of the investigation of voles from Anatolia to Europe. Geometric deformities of the brain of all taxa are found. Analysis of canonical variations showed that all three taxa differ significantly, both laterally and dorsally. Comparison of taxa lateral views showed that M. h. lydius brain is more flatten than M. h. hartingi, but M. guentheri has a broader brain and a smoother outer olfactory tract as well as smaller olfactory bulbs. By dorsal view, deformation of M. guentheri brain at the attachment sites of the cerebellum hemisphere to the cerebral hemisphere is observed, while the cerebellum worm of M. h. lydius is more flattened. The factors affecting the diversity of brain complexity could include allometry, phylogeny and natural selection. The accelerated morphological evolution of the "guentheri" group can be explained by the fragmentation of the range and habitats.DOI: 10.15298/rusjtheriol.19.1.04
- Andreeva N.G. & Obukhov D.K. 1999. [Evolutionary morphology of vertebrate nervous system]. Saint-Petersburg: Lana. 384 p. [in Russian].
- Barčiovà L. 2009. Advances in insectivore and rodent systematics due to geometric morphometrics // Mammal Review. Vol.39. No.2. P.80–91.
- Belenkov N.Yu. & Goreva O.A. 1969. [The role of the hillocks of the tubercles of corpora guadrigemina in the exercise of the orienting reflex] // Zhurnal Vysshei Nervnoi Deyatelnosti. Vol.19. No.3. P.453–461 [in Russian].
- Boyagina O.D., Kostilenko Ju.P., Mangov A.V. & Inyutochkina I.A. 2016. [Linear metric parameters of individual variability of the corpus callosum sexual dimorphism of middle-aged people according to MRI scans] // Visnik Problem Biologii i Meditsini. Vol.1 (128). No.2. P.253–359 [in Russian, with English summary].
- Bruner E. 2004. Geometric morphometrics and paleoneurology: brain shape evolution in the genus Homo // Journal of Human Evolution. Vol.47. P.279–303.
- Bruner E., de la Cuétara J.M., Colom R. & Martin-Loeches M. 2012. Gender-based differences in the shape of the human corpus callosum are associated with allometric variations // Journal of Anatomy. Vol.220. P.417–421.
- Bruner E., de Lazaro G.R., de la Cuétara J.M., Martin-Loeches M., Colom R. & Jacobs H.I. 2014. Midsagittal brain variation and MRI shape analysis of the precuneus in adult individuals // Journal of Anatomy. Vol.224. P.367–376.
- Çağatay M.N, Görür N., Algan O., Eastoe C., Tchapalyga A., Ongan D., Kuhn T. & Kuşçu I. 2000. Late Glacial-Holocene palaeoceanography of the Sea of Marmara: Timing of connections with the Mediterranean and the Black Seas // Marine Geology. Vol.167. P.191–206.
- Çetintürk D. 2018. Mitochondrial DNA variations in Turkish Microtus hartingi (Barret-Hamilton 1903) and Microtus lydius (Blackler 1916) // Journal of Entomology and Zoology Studies. Vol.6. No.2. P.76–78.
- Dayan T. & Simberloff D. 1998. Size patterns among competitors: Ecological character displacement and character release in mammals, with special reference to island populations // Mammal Review. Vol.28. P.99–124.
- Ellerman J.R. 1941. The Families and Genera of Living Rodents. Vol.2. London: British Museum (Natural History). 690 p.
- Golenishchev F.N., Sablina O.V., Borodin P.M. & Gerasimov S. 2002. Taxonomy of voles of the subgenus Sumeriomys Argyropulo, 1993 (Rodentia, Arvicolinae, Microtus) // Russian Journal of Theriology. Vol.1. No.1. P.43–55.
- Goren-Inbar N., Feibel C.S., Verosub K.L., Melamed Y., Kislev M.E., Tchernov E. & Saragusti I. 2000. Pleistocene milestones on the out-of-Africa corridor at Gesher Benot Yaaqov, Israel // Science. Vol.289. No.5481. P.944–947.
- Gorodilova Ju.V. & Vasilyeva I.A. 2014. [Geometric morphometrics of the low jaw of chromosomal dews of forehead mouse (Sylvaemus uralensis Pallas, 1881): taxonomical and ecological aspects] // Uspehi Sovremennogo Estestvoznaniya. No.11. P.19–24 [in Russian].
- Gromov I.M. & Erbayeva M.A. 1995. [The Mammals of Russia and Adjacent Territories. Lagomorphs and Rodents]. Saint-Petersburg: Zoologicheskii Institut RAN. 520 p. [in Russian].
- Gromov I.M. & Polykov I.Ya. 1977.[ Voles (Microtinae). Fauna of the USSR, Mammals]. Vol.111. No.8. Leningrad: Nauka. 504 p. [in Russian].
- Guthrie R.D. 2003. Rapid body size decline in Alaskan Pleistocene horses before extinction // Nature. Vol.426. P.169–171.
- Kamilari M., Tryfonopolus G., Fraquedakis-Tsolis S. & Chondropolus B. 2013. Geometric morphometrics on Greek house mouse populations (Mus musculus domesticus) with Robertsonian and all-acrocentric chromosomal arrangements // Mammalian Biology. Vol.78. P.241–250.
- Kaya A., Gharakhloo M.M. & Coşkun Y. 2018. Geographic variation in the skull morphology of Ellobius lutescens Thomas, 1897 (Mammalia: Rodentia) by geometric morphometric analyses // Vertebrate Zoology. Vol.68. No.2. P.157–164.
- Kerey I.E., Meriç E., Tunoğlu C., Kelling G., Brenner R.L. & Doğan A. U. 2004. Black Sea–Marmara Sea Quaternary connections: new data from the Bosphorus, İstanbul, Turkey// Palaeogeography, Palaeoclimatology, Palaeoecology. Vol.204. No.3–4. P.277–295.
- Khrustaleva I.V., Mikhailov N.V., Schneiberg I.I., Zherebtsov N.A., Slesarenko N.A. & Krishtoforova B.V. 1994. [Anatomy of Domestic Animals]. Moscow: Kolos. 703 p. [in Russian].
- Klingenberg C.P. 2011. MorphoJ: an integrated software package for geometric morphometrics // Molecular Ecology Resources. Vol.11. P.353–357.
- Kryštufek B. & Vohrálik V. 2005. Mammals of Turkey and Cyprus. Rodentia I: Sciuridae, Dipodidae, Gliridae, Arvicolinae. Ljubljana: Univerza na Primorskem, Znanstveno-raziskovalno središče Koper, Založba Annales, Zgodovinsko društvo za južno Primorsko. 292 p.
- Kryštufek B., Vohrálik V., Zareie R. & Özkan B. 2009. Mitochondrial cytochrome b sequences into the speciation of social voles in southwest Asia // Biological Journal of Linnaean Society. Vol.98. No.1. P.121–128.
- Kryštufek B., Zorenko T., Bontzorlos V., Mahmoudi A., Atanasov N. & Ivajnšič D. 2018. Incipient road to extinction of a keystone herbivore in south-eastern Europe: Hartings vole (Microtus hartingi) under climate change // Climatic Change. Vol.149. No.3–4. P.443–456.
- Marder O., Malinsky-Buller A., Shahack-Gross R., Ackermann O., Ayalon A., Bar-Matthews M., Goldsmith Y., Inbar M., Rabinovich R. & Hovers E. 2011. Archaeological horizons and fluvial processes at the Lower Palaeolithic open-air site at Revadim (Israel) // Journal of Human Evolution. Vol.60. No.4. P.508–522.
- Markov G., Yiğit N., Çolak E., Kocheva1 M. & Gospodinova M. 2014. Epigenetic diversity and similarity of the voles of “guentheri” group (Mammalia: Rodentia) in Anatolian Peninsula and southeastern part of the Balkan Peninsula // Acta Zoologica Bulgarica. Vol.66. P.159–164.
- McHugh C.M.G., Gurung D., Giosan L., Ryan W.B.F., Mart Y., Sancar U., Buckles L. & Çagatay M.N. 2008. The last reconnection of the Marmara Sea (Turkey) to the World Ocean: A paleoceanographic and paleoclimatic perspective // Marine Geology. Vol.255. No.1–2. P.64–82.
- Millien V. 2006. Morphological evolution is accelerated among island mammals // PLoS Biology. Vol.4. No.10. e-321. P.1863–1868.
- Millien V. 2011. Mammals evolve faster on smaller islands // Evolution. Vol.6. P.1935–1944.
- Musser G.G. & Carleton M.D. 2005. Superfamily Muroidea // Wilson D.E. & Reeder D.M. (eds.). Mammal Species of the World. Baltimore: Johns Hopkins University Press. Vol.2. P.894–1531.
- Orbach D.N., Hedrick B., Würsig B., Mesnick S.L & Brennan P.L.R. 2017. The evolution of genital shape variation in female cetaceans // Evolution. Vol.72. P.261–273.
- Pavlinov L.Ya. & Mikeshina N.G. 2002. [Principles and methods of geometric morphometrics] // Zhurnal Obshchei Biologii. Vol.63. No.6. P.473–493 [in Russian].
- Rohlf F.J. 2016. Morphometrics at Suny Stony Brook. Available at https://life.bio.sunysb.edu/morph/index.html.
- Schmidt N.M. & Jensen P.M. 2003. Changes in mammalian body length over 175 years —Adaptations to a fragmented landscape? // Conservation Ecology. Vol.72. P.1–7.
- Thanou E., Tryfonopoulos G., Chondropoulos B. & Fraguedakis–Tsolis Et.S. 2012. Comparative phylogeography of the live Greek vole species infers the existence of multiple South Balkan subrefugia // Italian Journal of Zoology. Vol.79. No.3. P.363–376.
- Voino M.S. 1994. [Brain] // Sokolov V.E. & Bashenina N.V. (eds.). [Common Vole: Sibling-species Microtus arvalis and M. rossiameridionalis]. Moscow: Nauka. P.52–71 [in Russian].
- Voyta L.L., Omelko V.E. & Petrova E.A. 2013. [Analysis of the morphometrics variability and intraspecific structure of Sorex minutisimus Zimmerman, 1780 (Lipotyphla: Soricidae) in Russia] // Proceedings of the Zoological Institute RAS. Vol.317. No.3. P.332–351 [in Russian, with English summary].
- Wilczyński J., Tomek T., Nadachowski A., Miękina B., Rzebik-Kowalska B., Pereswiet-Soltan A., Stworzewicz E., Szyndlar Z., Marciszak A. & Lõugas L. 2016. Faunal record and environmental changes during Holocene and Pleistocene // Kaczanowska M., Kozłowski J. & Sampson A. (eds.). The Sarkenos Cave at Akraephnion, Boeotia, Greece. Vol.2. The Early Neolithic, the Mesolithic and the final Palaeolithic. Krákow: Polish Academy of Arts and Sciences. P.63–150.
- Yaltırak C., Sakinç M. & Oktay F.Y. 2000. Westward propagation of North Anatolian fault into the northern Aegean: timing and kinematics. Comment and reply // Geology. Vol.28. P.187–188.
- Yaskin V.A. & Lenec L.I. 1996. Specific features of the brain structure of the common vole sibling species // Zoologicheskii Zhurnal. Vol.75. No.11. P.1715–1720 [in Russian, with English summary].
- Yiğit N. & Çolak E. 2002. On the distribution and taxonomic status of Microtus guentheri Danford and Alston, 1880 and Microtus lydius Blackler, 1916 (Mammalia: Rodentia) in Turkey // Turkish Journal of Zoology. Vol.26. P.197–204.
- Yiğit N., Çetintürk D. & Çolak E. 2017. Phylogenetic assessment of voles of the Guentheri Group (Mammalia: Microtus) in Turkish Thrace and Western Anatolia // European Zoological Journal. Vol.84. No.1. P.252–260.
- Yiğit N., Markov G., Çolak E., Kocheva M., Saygılı F., Yüce D. & Çam P. 2012. Phenotypic features of the guentheri group vole (Mammalia: Rodentia) in Turkey and southeast Bulgaria: evidence for its taxonomic detachment // Acta Zoologica Bulgarica. Vol.64. No.1. P.23–32.
- Zima J., Arslan A., Benda P., Macholàn M. & Kryštufek B. 2013. Chromosomal variation in social voles: a Robertsonian fusion in Günters vole // Acta Theriologica. Vol.58. P.255–265.
- Zorenko T. & Golenishchev G. 2015. The spermatozoa structure peculiarities of the subgenus Sumeriomys (Rodentia, Arvicolinae, Microtus) // Russian Journal of Theriology. Vol.14. No.1. P.105–111.
- Zorenko T.A. 2013. [Social Voles of the Subgenus Sumeriomys: Systematics, Biology and Behavior]. Saarbrücken: Palmariun Academic Publishing. 541 p. [in Russian].
- Zorenko Z., Atanasov N. & Golenishchev F. 2016. Behavior and partial reproductive isolation between the European and Asian forms of Harting vole Microtus hartingi (Rodentia, Arvicolinae) // Russian Journal of Theriology. Vol.15. No.2. P.133–150.