Myodes smithii Thomas 1905
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https://doi.org/10.5281/zenodo.7316535 |
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https://doi.org/10.5281/zenodo.11357047 |
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https://treatment.plazi.org/id/9DB0933B-93B1-1263-61A4-6065DF2EF70B |
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treatment provided by |
Guido (2022-12-13 04:19:03, last updated 2024-11-29 04:44:57) |
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scientific name |
Myodes smithii Thomas 1905 |
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Myodes smithii Thomas 1905 View in CoL
Myodes smithii Thomas 1905 View in CoL , Ann. Mag. Nat. Hist., ser. 7, 15: 493.
Type Locality: Japan, Honshu, Hyogo Prefecture, Kobe.
Vernacular Names: Smith's Red-backed Vole.
Synonyms: Myodes kageus (Imaizumi 1957) ; Myodes okiensis (Tokuda 1932) .
Distribution: Japanese islands of Dogo, Honshu, Shikoku, and Kyushu ( Kaneko, 1992 b, 1994).
Conservation: IUCN – Lower Risk (lc) as Phaulomys smithii .
Discussion: Type species of Phaulomys Thomas (1905 b) , diagnosed as a subgenus of Evotomys . Imaizumi (1949) transferred Phaulomys to Eothenomys , an action largely ignored (e.g., Ellerman and Morrison-Scott, 1951) until adopted by Corbet (1978 c) and Aimi (1980). Phaulomys was reinstated as a genus, containing andersoni and smithii , by Kawamura (1988), who thought the two extant species with rootless molars (a key trait of Eothenomys ) were derived from the middle Pleistocene japonicus, which has rooted molars. Molar and external traits also led Tanaka (1971) to recognize Phaulomys as a genus distinct from Eothenomys , primarily because smithii combined characteristics of both Myodes and Eothenomys . Chromosomal analyses of smithii suggest that Myodes and Phaulomys are derived from a common ancestor ( Ando et al., 1988).
We (1993:532) previously recognized Phaulomys because "The removal of Japanese Phaulomys from Eothenomys , whose species-diversity centers in the mountains of China, and its proposed association with Clethrionomys [= Myodes ] is zoogeographically plausible and outlines a precise hypothesis that can be tested by analyses of other data sets." In just such a taxonomically and geographically broad study, using mitochondrial and nuclear ribosomal DNA, Suzuki et al. (1999 b) demonstrated: 1) that andersoni , imaizumii , and smithii are closely related to Japanese and Asian M. rufocanus and to Korean M. regulus ; 2) that this clade is phyletically remote from M. rutilus and Eothenomys melanogaster ; and 3) that no monophyletic group corresponding to Phaulomys as a separate genus is supported. They concluded (1999 b:520) that the allocations of Japanese red-backed voles to Myodes , Eothenomys , or Phaulomys should be reevaluated. The incorporation of smithii into Myodes had earlier been urged by Yoshida et al. (1989), based on chromosomal and allozymic data, and was so arranged by Pavlinov et al. (1995 a). The molecular relationships reported by Suzuki et al. imply that the evergrowing molars in andersoni and smithii are independently derived from a rooted Myodes ancestor endemic to Japan, as earlier hypothesized by Kawamura (1988).
Species revised, as Eothenomys , and many name combinations traced by Aimi (1980). Morphology, altitudinal and geographic distribution, taxonomic comparisons, and nomenclatural history meticulously investigated by Kaneko (1992 b, 1994, 1996 a). Synonymy of kageus demonstrated by Aimi (1980), Kaneko (1985) and Ando et al. (1988); later Kaneko (1994, as Eothenomys ) recognized kageus as occurring in E Honshu and smithii in W Honshu. The taxon okiensis , described as a subspecies of rufocanus , was placed in synonymy by Aimi (1980). Chromosomal data widely available, in comparisons among arvicoline species and within samples of smithii ( Ando et al., 1988, 1991; Iwasa and Tsuchiya, 2000; Iwasa et al., 1999 a, b; Tsuchiya, 1981; Vorontsov et al., 1980; Yoshida et al., 1989). See Kawamura (1991, 1994) for discussion of Holocene occurrence in archeological sites on Honshu, Shikoku, and Kyushu. Both M. smithii and M. andersoni are discussed by Dobson (1994, as Phaulomys ) in context of elucidating patterns of distribution in Japanese land mammals .
Aimi, M. 1980. A revised classification of the Japanese red-backed voles. Memoirs of the Faculty of Science, Kyoto University, Series of Biology, 8: 35 - 84.
Ando, A., S. Shiraishi, M. Harada, and T. A. Uchida. 1988. A karyological study of two intraspecific taxa in Japanese Eothenomys (Mammalia: Rodenta). Journal of the Mammalogical Society of Japan, 13: 93 - 104.
Corbet, G. B. 1978 c. The mammals of the Palaearctic region: A taxonomic review. British Museum (Natural History), London, 314 pp.
Dobson, M. 1994. Patterns of distribution in Japanese land mammals. Mammal Review, 24 (3): 91 - 111.
Ellerman, J. R., and T. C. S. Morrison-Scott. 1951. Checklist of Palaearctic and Indian mammals 1758 to 1946. Trustees of the British Museum (Natural History), London, 810 pp.
Imaizumi, Y. 1949. [The natural history of Japanese mammals.] Yoyoshobo, Tokyo, 348 pp. (in Japanese).
Iwasa, M. A., S. H. Han, and H. Suzuki. 1999 a. A karyological analysis of the Korean red-backed vole, Eothenomys regulus (Rodentia, Muridae), using differential staining methods. Mammal Study, 24: 35 - 41.
Iwasa, M. A., and K. Tsuchiya. 2000. Karyological analysis of the Eothenomys sp. from Nagano City, central Honshu, Japan. Chromosome Science, 4: 31 - 38.
Kaneko, Y. 1985. Examinations of diagnostic characters (mammae and bacula) between Eothenomys smithi and E. kageus. Journal of the Mammalogical Society of Japan, 10: 221 - 229.
Kaneko, Y. 1992 b. [Mammals of Japan. 17. Eothenomys smithii (Smith's red-backed vole).] Mammalian Science, 32 (1): 39 - 54 (in Japanese).
Kaneko, Y. 1994. [Muridae.] Pp. 90 - 110 and 168 - 183, in A pictorial guide to the mammals of Japan (H. Abe, N. Ishii, Y. Kaneko, K. Maeda, S. Miura, and M. Yoneda, eds.). Tokai University Publication, Tokyo, 195 pp. (In Japanese).
Kaneko, Y. 1996 a. Age variation of the third upper molar in Eothenomys smithii. Mammal Study, 21 (1): 1 - 13.
Kawamura, Y. 1988. Quaternary rodent faunas in the Japanese Islands (Part 1). Memoirs of the Faculty of Science, Kyoto University, Series of Geology and Mineralogy, 53: 31 - 348.
Kawamura, Y. 1991. Quaternary mammalian faunas in the Japanese Islands. The Quaternary Research, 30 (2): 213 - 220.
Kawamura, Y. 1994. Late Pleistocene to Holocene mammalian faunal succession in the Japanese Islands, with comments on the Late Quaternary extinctions. Archaeozoologia, 6 (2): 7 - 22.
Pavlinov, I. Ya, E. L. Yakhontov, and A. K. Agadzhanyan. 1995 a. [Mammals of Eurasia. I. Rodentia. Taxonomic and geographic guide.] Archives of the Zoological Museum, Moscow State University, 32: 289 pp. (in Russian).
Santos, I. B., G. A. B. da Fonseca, S. E. Rigueira, and R. B. Machado. 1994. The rediscovery of the Brazilian three banded armadillo and notes on its conservation status. Edentata, 1: 11 - 15.
Suzuki, H., M. Iwasa, M. Harada, S. Wakana, M. Sakaizumi, S. - H. Han, E. Kitahara, Y. Kimura, I. Kartavtseva, and K. Tsuchiya. 1999 b. Molecular phylogeny of red-backed voles in Far East Asia based on variation in ribosomal and mitochrondrial DNA. Journal of Mammalogy, 80 (2): 512 - 521.
Tanaka, R. 1971. A research into variation in molar and external features among a population of the Smith's red-backed vole for elucidation of its systematic rank. Japanese Journal of Zoology, 16: 163 - 176.
Thomas, O. 1905 b. On new Japanese mammals (Insectivora, Rodentia). Annals and Magazine of Natural History, ser. 7, 15: 487 - 495.
Tsuchiya, K. 1981. [On the chromosome variations in Japanese cricetid and murid rodents]. Honyurui Kagaku (Mammalian Science), 42: 51 - 58 (in Japanese, with English abstract).
Vorontsov, N. N., E. A. Lyapunova, Yu. M. Borisov, and V. E. Dovgal. 1980. Variability of sex chromosomes in mammals. Genetica, 52 / 53: 361 - 372.
Yoshida, I., Y. Obara, and N. Matsuoka. 1989. Phylogenetic relationships among seven taxa of the Japanese microtine voles revealed by karyological and biochemical techniques. Zoological Science, 6: 409 - 420.
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