Genetic diversity and genetic structure of Sorex isodon in Northeast China

doi:10.13287/j.1001-9332.202002.038

Abstract

Abstract: A total of 64 haplotypes were obtained from the complete Cytochrome b gene (Cyt b) of 77 Sorex isodon collected from three populations (Daxing’anling, Xiaoxing’anling, and Changbai Mountains) in Northeast China. The haplotype diversity was 0.9920 and the nucleotide diversity was 0.0105, indicating high genetic diversity. The genetic diversity of Changbai Mountains population was significantly higher than that of Daxing’anling and Xiaoxing’anling populations. The F-statistics, the number of migrants per generation and the genetic distance results showed that the genetic distances among the populations and among the sampling sites were generally consistent with geographical distance. Analysis of molecular variance showed that the differentiation among populations, among sampling sites, and within sampling site accounted for 33.4%, 10.2% and 56.4% of total variation, respectively. The analysis of population history showed that S. isodon in Northeast China experienced no population expansion. The reported complete sequence of Cyt b gene of S. isodon (GenBank) of Europe and other parts of Asia was downloaded to examine the genetic structure of S. isodon. The phylogenetic tree was divided into two large branches. One branch consisted mainly of Daxing’anling and Xiaoxing’anling samples. The other branch was departed into two sub-branches. Median-joining network analysis showed that there were three lineages: one lineage mainly consisted of haplotypes from Daxing’anling and Xiaoxing’anling, and also four haplotypes of Changbai Mountains, while the other lineage included a few haplotypes of three populations in Northeast China, and those from Baikal Lake, Russia and Finland. The last lineage was entirely composed of haplotypes from Changbai Mountains. The results of genetic diversity, phylogenetic tree and median-joining network all suggested that the Changbai Mountains was the refuge for S. isodon during last glacial.

LIU Zhu, WANG Qing-qing, BAI Wei, LI Bo-qi, TIAN Xin-min, LI Dian-wei, ZHANG Jun-sheng. Genetic diversity and genetic structure of Sorex isodon in Northeast China[J]. Chinese Journal of Applied Ecology, 2020, 31(2): 634-642.

References 44

[1]	Hutterer R. Order Soricomorpha// Wilson DE, Reeder DA, eds. Mammal Species of the World: A Taxonomic and Geographic Reference. 3rd Ed. Baltimore, Ame-rica: Johns Hopkins University Press, 2005: 223-311
[2]	Smith A, 解焱. 中国兽类野外手册. 长沙: 湖南教育出版社, 2009: 224-314 [Smith A, Xie Y. A Guide to the Mammals of China. Changsha: Hunan Education Press, 2009: 224-314]
[3]	王应祥. 中国哺乳动物种和亚种分类名录与分布大全. 北京: 中国林业出版社, 2003: 54-64 [Wang Y-X. A Complete Checklist of Mammal Species and Subspecies in China. Beijing: China Forestry Press, 2003: 54-64]
[4]	刘铸, 张隽晟, 白薇, 等. 中国东北地区鼩鼱科动物分类与分布. 兽类学报, 2019, 39(1): 24-42 [Liu Z, Zhang J-S, Bai W, et al. Classification and distribution of Soricids in Northeastern China. Acta Theriologica Sinica, 2019, 39(1): 24-42]
[5]	蒋志刚. 中国哺乳动物多样性及地理分布. 北京: 科学出版社, 2015: 41-70 [Jiang Z-G. China’s Mammal Diversity and Geographic Distribution. Beijing: Science Press, 2015: 41-70]
[6]	Hoffmann RS. A review of the systematics and distribution of Chinese red-toothed shrews (Mammalia: Soricinae). Acta Theriologica Sinica, 1987, 7: 100-139
[7]	Ohdachi SD, Abe H, Han SH. Phylogenetical positions of Sorex sp. (Insectivora, Mammalia) from Cheju Island and S. caecutiens from the Korean Peninsula, inferred from mitochondrial cytochrome b gene sequences. Zoological Science, 2003, 20: 91-95
[8]	Ohdachi SD, Abe H, Oh HS, et al. Morphological relationships among populations in the Sorex caecutiens/shinto group (Eulipotyphla, Soricidae) in East Asia, with a description of a new subspecies from Cheju Island, Korea. Mammalian Biology, 2005, 70: 345-358
[9]	Ohdachi SD, Dokuchaev NE, Hasegawa M, et al. Intraspecific phylogeny and geographical variation of six species of northeastern Asiatic Sorex shrews based on the mitochondrial cytochrome b sequences. Molecular Ecology, 2001, 10: 2199-2213
[10]	Naitoh Y, Ohdachi SD. Population genetic structure of Sorex unguiculatus and Sorex caecutiens (Soricidae, Mammalia) in Hokkaido, based on microsatellite DNA polymorphism. Ecological Research, 2006, 21: 586-596
[11]	Koh HS, Jang KH, In ST, et al. Genetic distinctness of Sorex caecutiens hallamontanus (Soricomorpha: Mammalia) from Jeju Island in Korea: Cytochrome oxidase I and cytochrome b sequence analyses. Animal Systema-tics, Evolution and Diversity, 2012, 28: 215-219
[12]	Fumagalli L, Taberlet P, Stewart DT, et al. Molecular phylogeny and evolution of Sorex shrews (Soricidae: Insectivora) inferred from mitochondrial DNA sequence data. Molecular Phylogenetics and Evolution, 1999, 11: 222-235
[13]	Kovaleva VY, Litvinov YN, Efimov VM. Shrews (Soricidae, Eulipotyphla) from the Russian Far East and Siberia: Combination and search for congruence of molecular genetic and morphological data. Biology Bulletin of the Russian Academy of Sciences, 2014, 41: 575-588
[14]	Ohdachi S, Masuda R, Abe H, et al. Phylogeny of Eura-sian soricine shrews (Insectivora, Mammalia) inferred from the mitochondrial cytochrome b gene sequences. Zoological Science, 1997, 14: 527-532
[15]	Hewitt GM. The genetic legacy of the Quaternary ice ages. Nature, 2000, 405: 907-913
[16]	Lister AM. The impact of Quaternary ice ages on mammalian evolution. Philosophical Transactions of the Royal Society B: Biological Sciences, 2004, 359: 221-241
[17]	Lee SJ, Lee MY, Lin LK, et al. Phylogeography of the Asian lesser white-toothed shrew, Crocidura shantungensis, in East Asia: Role of the Korean Peninsula as refugium for small mammals. Genetica, 2018, 146: 211-226
[18]	Hope AG, Waltari E, Dokuchaev NE, et al. High-latitude diversification within Eurasian least shrews and Alaska tiny shrews (Soricidae). Journal of Mamma-logy, 2010, 91: 1041-1057
[19]	Qu Y, Zhao Q, Lu H, et al. Population dynamics following the last glacial maximum in two sympatric lizards in Northern China. Asian Herpetological Research, 2014, 5: 213-227
[20]	Vila C, Amorim IR, Leonard JA, et al. Mitochondrial DNA phylogeography and population history of the grey wolf Canis lupus. Molecular Ecology, 1999, 8: 2089-2103
[21]	Walker CW, Vila C, Landa A, et al. Genetic variation and population structure in Scandinavian wolverine (Gulo gulo) populations. Molecular Ecology, 2001, 10: 53-63
[22]	Liu Z, Li B, Ma J, et al. Phylogeography and genetic diversity of the red squirrel (Sciurus vulgaris) in China: Implications for the species’ postglacial expansion history. Mammalian Biology, 2014, 79: 247-253
[23]	Li B, Malyarchuk B, Ma ZP, et al. Phylogeography of sable (Martes zibellina L. 1758) in the southeast portion of its range based on mitochondrial DNA variation: Highlighting the evolutionary history of the sable. Acta Theriologica, 2013, 58: 139-148
[24]	Guo WP, Lin XD, Wang W, et al. Phylogeny and origins of Hantaviruses harbored by bats, insectivores, and rodents. PLoS Pathogens, 2013, 9(2): 1-13
[25]	Thompson JD, Gibson TJ, Plewniak F, et al. The CLUSTAL X windows interface: Flexible strategies for multiple sequence alignment aided by quality analysis tools. Nucleic Acids Research, 1997, 25: 4876-4882
[26]	Librado P, Rozas J. DnaSP v5: A software for comprehensive analysis of DNA polymorphismdata. Bioinforma-tics, 2009, 25: 1451-1452
[27]	Excoffier L, Laval LG, Schneider S. Arlequin ver. 3.0: An integrated software package for population genetics data analysis. Evolutionary Bioinformatics Online, 2005, 1: 47-50
[28]	Swofford DL. PAUP: Phylogenetic Analysis using Parsimony ( and Other Methods), Version 4. Sunderland, MA, USA: Sinauer Associates, 2002
[29]	Bandelt H, Forster P, Rohl A. Median joining networks for inferring intraspecific phylogenics. Molecular Biology Evolution, 1999, 16: 37-48
[30]	Rozas J, Sanchez-DelBarrio JC, Messeguer X, et al. DnaSP, DNA polymorphism analyses by the coalescent and other methods. Bioinformatics, 2003, 19: 2496-2497
[31]	White TA, Searle JB. Genetic diversity and population size: Island populations of the common shrew, Sorex araneus. Molecular Ecology, 2007, 16: 2005-2016
[32]	Li WH, Ellsworth DL, Krushkal J, et al. Rates of nucleotide substitution in primates and rodents and the generation-time effect hypothesis. Molecular Phylogene-tics and Evolution, 1996, 5: 182-187
[33]	Gündüz I, Auffray JC, Britton-Davidian J, et al. Molecu-lar studies on the colonization of the Madeiran archipe-lago by house mice. Molecular Ecology, 2001, 10: 2023-2029
[34]	Ittig REG, Gardenal CN. Haplotype diversity of the mitochondrial DNA D-loop region in Calomys musculinus (Rodentia, Muridae) detected by PCR-RFLP. Bioche-mical Genetics, 2002, 40: 293-302
[35]	Metcalf AE, Nunney L, Hyman BC. Geographic patterns of genetic differentiation within the restricted range of the endangered Stephens’ kangaroo rat Dipodomys stephensi. Evolution, 2001, 55: 1233-1244
[36]	Charlesworth B, Charlesworth D, Barton NH. The effects of genetic and geographic structure on neutral variation. Annual Review of Ecology, Evolution, and Systematics, 2003, 34: 99-125
[37]	Hutchison DW, Templeton AR. Correlation of pairwise genetic and geographic distance measures: Inferring the relative influences of gene flow and drift on the distribution of genetic variability. Evolution, 1999, 53: 1898-1914
[38]	杨茜. 东北地区中鼩鼱(Sorex caecutiens)遗传多样性与分子系统地理学分析. 硕士论文. 牡丹江: 牡丹江师范学院, 2018: 24-26 [Yang X. Genetic Diversity and Phylogeography of Sorex caecutiens in Northeast China. Master Thesis. Mudanjiang: Mudanjiang Normal University, 2018: 24-26]
[39]	刘铸, 李博琦, 田新民, 等. 东北亚地区鼩鼱科动物分子生态学研究进展. 生态学报, 2019, 39(19): 7322-7331 [Liu Z, Li B-Q, Tian X-M, et al. Current progress and prospects in the molecular ecology of Soricidae in Northeast Asia. Acta Ecologica Sinica, 2019, 39(19): 7322-7331]
[40]	史艳霜. 中国东北地区东方铃蟾种群分化研究. 硕士论文. 哈尔滨: 东北农业大学, 2019: 14-24 [Shi Y-S. Population Differentiation of Bombina orientalis in Northeast China. Master Thesis. Harbin: Northeast Agricultural University, 2019: 14-24]
[41]	Yannic G, Pellissier L, Dubey S, et al. Multiple refugia and barriers explain the phylogeography of the Valais shrew, Sorex antinorii (Mammalia: Soricomorpha). Biological Journal of the Linnean Society, 2012, 105: 864-880
[42]	Polyakov AV, Zima J, Searle JB, et al. Chromosome races of the common shrew Sorex araneus in the Ural Mts: A link between Siberia and Scandinavia? Acta Theriologica, 2000, 45: 19-26
[43]	Vega R, Fløjgaard C, Lira-Noriega A, et al. Northern glacial refugia for the pygmy shrew Sorex minutus in Europe revealed by phylogeographic analyses and species distribution modelling. Ecography, 2010, 33: 260-271
[44]	Cook JA, McLean BS, Jackson DJ, et al. First record of the Holarctic least shrew (Sorex minutissimus) and associated helminths from Canada: New light on nor-thern Pleistocene refugia. Canadian Journal of Zoology, 2016, 94: 367-372