Arxius de Miscel·lània Zoològica. Volume 18 (2020) Pages: 75-83

Genetic polymorphism in populations of voles and shrews from the Kronotsky Reserve (Kamchatka Peninsula, Russia)

Zhigileva, O. N., Levykh, A. Y., Gorbacheva, E. V.

DOI: https://doi.org/10.32800/amz.2020.18.0075

Download

PDF

Keywords

Myodes, Sorex, Differentiation of populations, Genetic variability, ISSR markers, Kamchatka Peninsula

Cite

Zhigileva, O. N., Levykh, A. Y., Gorbacheva, E. V., 2020. Genetic polymorphism in populations of voles and shrews from the Kronotsky Reserve (Kamchatka Peninsula, Russia). Arxius de Miscel·lània Zoològica, 18: 75-83, DOI: https://doi.org/10.32800/amz.2020.18.0075

Reception date:

28/02/2020

Acceptation date:

03/06/2020

Publication date:

15/06/2020

Share

Visits

3051

Downloads

916

Abstract

Genetic polymorphism in populations of voles and shrews from the Kronotsky Reserve (Kamchatka Peninsula, Russia)

We studied genetic polymorphism of four mammal species Myodes rutilus, Myodes rufocanus, Sorex isodon, from four localities, the Valley of Geysers, Uzon volcanic caldera, the Death Valley, and the Shore of Kuril Lake. In total, 172 individuals were genotyped using the inter-simple sequence repeat technique. We observed the lowest polymorphism in shrews S. caecutiens. In this species, 68.8 % of bands were polymorphic, and Nei’s genetic diversity (h) was 0.27, while these values in S. isodon were 81.3 % and 0.29, respectively. Populations of M. rufocanus were the most polymorphic among the studied species (P = 91.4, h = 0.34). Polymorphism in M. rutilus from Kamchatka (P = 87.2, h = 0.29) was similar to that from Western Siberia. In addition, we found a high genetic differentiation of rodent populations. The interpopulation component of genetic variability was about 30–40 % (GST = 0.31 in M. rutilus and 0.39 in M. rufocanus). Gene flow among populations of M. rutilus from Kamchatka was two times lower than that of populations of the species from taiga ecosystems in Siberia.

Key words: Myodes, Sorex, Differentiation of populations, Genetic variability, ISSR markers, Kamchatka Peninsula

Resumen

Polimorfismo genético en poblaciones de topillos y musarañas de la reserva de Kronotski (península de Kamchatka, Rusia)

Estudiamos el polimorfismo genético de cuatro especies de mamíferos Myodes rutilus, Myodes rufocanus, Sorex isodon y Sorex caecutiens de cuatro localidades: el valle de los Géiseres, la caldera volcánica Uzon, el valle de la Muerte y las orillas del lago Kuril. Genotipamos un total de 172 ejemplares utilizando la técnica de intersecuencias simples repetidas. Observamos el polimorfismo más bajo en la musaraña S. caecutiens. En esta especie, el 68,8 % de las bandas resultaron polimórficas y la diversidad genética de Nei (h) fue de 0,27, mientras que en S. isodon estos valores fueron de 81,3 % y 0,29, respectivamente. Las poblaciones de M. rufocanus fueron las más polimórficas entre las especies estudiadas (P = 91,4;  h = 0,34). El polimorfismo de M. rutilus de Kamchatka (P = 87,2; h = 0,29) fue similar al de Siberia Occidental. Además, descubrimos una elevada diferenciación genética entre poblaciones de roedores. El componente interpoblacional de variabilidad genética fue del 30-40 % (GST = 0,31 en M. rutilus y 0,39 en M. rufocanus). El flujo genético entre las poblaciones de M. rutilus de Kamchatka fue dos veces más bajo que entre las poblaciones de especies de los ecosistemas de la taiga siberiana.

Palabras clave: Myodes, Sorex, Diferenciación de poblaciones, Variabilidad genética, Marcadores ISSR, Península de Kamchatka

Resum

Polimorfisme genètic en poblacions de talpons i musaranyes de la reserva de Kronotski (península de Kamtxatka, Rússia)

Vam estudiar el polimorfisme genètic de quatre espècies de mamífers Myodes rutilus, Myodes rufocanus, Sorex isodon i Sorex caecutiens de quatre localitats: la vall dels Guèisers, la caldera volcànica Uzon, la vall de la Mort i les ribes del llac Kuril. Vam genotipar un total de 172 exemplars mitjançant la tècnica d’interseqüències simples repetides. Vam observar el polimorfisme més baix en la musaranya S. caecutiens. En aquesta espècie, el 68.8 % de les bandes van resultar polimòrfiques i la diversitat genètica de Nei (h) va ser de 0.27, mentre que en S. isodon aquests valors van ser de 81.3 % i el 0.29, respectivament. Les poblacions de M. rufocanus van ser les més polimòrfiques entre les espècies estudiades (P = 91,4; h = 0,34). El polimorfisme de M. rutilus de Kamtxatka (P = 87,2; h = 0,29) va ser similar al de Sibèria Occidental. A més a més, vam descobrir una elevada diferenciació genètica entre poblacions de rosegadors. El component interpoblacional de variabilitat genètica va ser del 30-40 % (GST = 0,31 en M. rutilus i 0,39 en M. rufocanus). El flux genètic entre les poblacions de M. rutilus de Kamtxatka va ser dues vegades més baix que entre les poblacions d’espècies dels ecosistemes de la taigà siberiana.

Paraules clau: Myodes, Sorex, Diferenciació de poblacions, Variabilitat genètica, Marcadors ISSR, Península de Kamtxatka

Introduction

Boundary semi-isolated populations of common animal species are of great interest to population and evolutionary genetics. They are regarded as the cutting edge of evolution due to the peculiarity of the gene pool and ability for rapid evolutionary transformations. Many species of small mammals from the Far East form genetically well-differentiated populations or even endemic species (Naitoh and Ohdachi, 2006; Kovaleva et al., 2014). Genetic features of such forms allow us to consider them as separate conservation management units.

The wildlife of the Kamchatka Peninsula is unique due to the natural features of the environment and the protection of the Kronotsky Reserve and the South Kamchatka Sanctuary. The study of genetic diversity of animals is of particular interest for monitoring and protecting the genetic resources of the region.

Voles (Myodes spp.) and shrews (Sorex spp.) are common representatives of Palearctic fauna. They are widespread in Siberia and they also inhabit the Kamchatka Peninsula. Myodes (Rodentia) and Sorex (Eulipotyphla) are distinct orders. From an evolutionary point of view, shrews are a more ancient group than voles. These groups are also very different in their ecology, occupying different trophic niches in ecosystems. Despite this difference, in ecological studies they are often considered as a single group named micromammals. However, in evolutionary and environmental studies, they show very different patterns of distribution and population dynamics. Furthermore, as they have different adaptive and evolutionary potentials their conservation status also differs.

The genetic structure of Myodes populations from the Far East region has been studied using allozyme markers (Kawata and Ueda, 1984; Frisman et al., 2002; Primak and Zasypkin, 2011), mitochondrial markers (Iwasa et al., 2000, 2002; Abramson et al., 2012) and microsatellites (Iwasa et al., 2000; Matson and Baker, 2001). Pereverzeva and Primak (Pereverzeva et al., 2014; Pereverzeva and Primak, 2016; Pereverzeva et al., 2018) found a fairly high level of genetic polymorphism in Myodes rutilus (Pallas 1779) from the Far East, especially in mainland populations, whereas the island populations of this species showed a reduced level of polymorphism and a unique gene pool. Vole populations from islands were highly differentiated between themselves and in their comparison with mainland populations (Primak and Zasypkin, 2011; Pereverzeva et al., 2014). Besides, populations of Myodes rufocanus (Sundevall 1846) from some islands played an important role in enriching the gene pool of mainland populations due to historical interpopulation exchanges (Iwasa et al., 2000).

Data on the genetic polymorphism of mammal populations of the Kamchatka Peninsula are available in only a few papers (Iwasa et al., 2000; 2002; Frisman et al., 2002; Haring et al., 2011; Ohdachi et al., 2012). This may be due to difficult access to the territory and the general lack of study fauna in this area. However, these data are of great interest due to the unique natural habitats of animals on the peninsula. The specific climatic conditions, high seismic activity, and isolation supports the use of animal populations from Kamchatka as models to study mammalian adaptation to extreme environmental conditions. In addition, these data can contribute to the development of recommendations to protect the biodiversity of the peninsula. The purpose of our research was to study the genetic variability and differentiation of small mammal population from the Kronotsky Reserve. The first hypothesis was that the micromammal populations of the Kamchatka peninsula are highly differentiated genetically from populations of Siberia and have lower polymorphism due to isolation. The second hypothesis was that polymorphism estimates would be different for voles and shrews

Material and methods

We collected mammals in the Kronotsky Reserve and the South Kamchatka Sanctuary, the Kamchatka Peninsula, Russia, in July-August 2015-2016. In the Kronotsky Reserve, we caught mammals in three localities: in the Valley of Geysers (54.436 N, 160.136 E), in the Uzon volcanic caldera (54.512 N, 159.916 E), and in Death Valley (54.468 N, 160.189 E). The distance between these places is no more than 15 km but they differ in biotopic conditions and species composition. See table 1 for details. In the South Kamchatka Sanctuary, we caught mammals on the shore of Kuril lake (51.485 N, 157.041 E) (fig. 1).

Table 1. Locations and numbers of animals studied: Mrt, Myodes rutilus; Mrf, Myodes rufocanus; Ssd, Sorex isodon; Scc, Sorex caecutiens. Tabla 1. Localizaciones y número de animales investigados: Mrt, Myodes rutilus; Mrf, Myodes rufocanus; Ssd, Sorex isodon; Scc, Sorex caecutiens.

Fig. 1. Sample collection sites of mammals in the Kronotsky Reserve, Kamchatka Peninsula, Russia: 1, the Valley of Geysers; 2, Uzon volcanic caldera; 3, Death Valley; 4, the shore of Kuril lake. Fig. 1. Puntos de muestreo de mamíferos en la Reserva de Kronotsky, península de Kamchatka, Rusia: 1, valle de los Géiseres; 2, caldera volcánica Uzon; 3, valle de la Muerte; 4, orillas del lago Kuril.

 

Capture was carried out using Gero traps, and in some areas, the cylinder-day method was used. We processed a total of 2,359 trap-days and 396 cylinder-days. We treated the animals according to the regulations of the Ministry of Health of the Russian Federation (Order 755 of August 12, 1977). If the animals were alive when removed from the traps, they were immediately euthanized by placing them in a box with cotton wool moistened with chloroform.

The total sample size was 172 individuals: 89 Myodes (= Clethrionomys) rutilus (Pallas 1779); 43 Myodes (= Clethrionomys) rufocanus (Sundevall 1846); 26 Sorex isodon (Turov 1924); and 14 Sorex caecutiens (Laxmann 1788).

We extracted total genomic DNA from muscle tissue fixed in 70 % ethanol using the alkaline lysis technique (Bender et al., 1983). To estimate the polymorphism of such different taxonomic groups as voles and shrews, we used the nonspecific inter-simple sequence repeat (ISSR) markers that allow us to obtain amplification products of genetic material in different groups of organisms (Zietjiewicz et al., 1994). In particular, five primers (AG)8C, (GT)8C, (AC)8T, (TC)8C, and (TG)8A were used for (SSR)-anchored polymerase chain reaction amplification. We carried out the amplification in 25 μl of reaction mixture containing PCR buffer (0.01 M Tris-НCl, 0.05 M KCl, 0.1% triton X-100), 4 mM MgCl2, 0.2 mM of each dNTPs, 1 μl of total DNA solution, 2.5 mM of primer and 0.2 unit/μL of Taq-polymerase, with the following PCR conditions: 94 ºC 7 min; then 94ºC 30 sec, 52(56) ºC 45 sec, 72 ºC  2 min (40 cycles); 72 ºC  7 min. ISSR-fragments were separated by 2 % agarose gel electrophoresis with Tris-EDTA-Borate buffer. The sizes of the fragments were determined using 100 bp DNA molecular weight markers.

We used POPGEN software (Yeh et al., 1999) to compute the following population genetic characteristics: the percentage of polymorphic bands (Р), the observed (na) and the effective number of alleles (ne), Nei’s gene diversity (h), Nei’s original measures of genetic identity (I), the genetic distance (D), gene flow (Nm), and the interpopulation component of genetic variability (GST ).

Results

The ISSR polymorphism we recorded from four species of small mammals is presented in table 2. Populations of the gray red-backed vole M. rufocanus were the most polymorphic among the studied species. The percentage of polymorphic bands (Р) in this species was 91.4, and Nei’s gene diversity was 0.34. The polymorphism in populations of the northern red-backed vole M. rutilus from Kamchatka was also high (fig. 2). The proportion of polymorphic bands in this species was 87.2, and Nei’s gene diversity was 0.29.

Table 2. Indicators of ISSR polymorphism in small mammal populations of the Kamchatka Peninsula: n, sample size; N, the number of polymorphic bands; Р, percentage of polymorphic bands; h, Nei’s gene diversity; na, observed number of alleles; ne, effective number of alleles. Tabla 2. Indicadores de polimorfismo ISSR en poblaciones de pequeños mamíferos de la península de Kamchatka: n, tamaño de la muestra; N, número de bandas polimórficas; Р, porcentaje de bandas polimórficas; h, diversidad genética de Nei; na, número de alelos observados; ne, número efectivo de alelos.

Fig. 2. Gel electrophoresis profiles of ISSR–PCR fragments amplified using the (TC)8C primer: 1, 2, 7–10, specimens No. 278, 280, 286–289 of Myodes rutilus; 3–6, specimens No. 281, 283–285 of Myodes rufocanus from the Valley of Geysers; M, 100 bp DNA molecular weight marker (2 % agarose gel, ethidium bromide staining). Fig. 2. Electroforesis en gel de fragmentos ISSR–PCR amplificados utilizando el iniciador (TC)8C: especímenes 1, 2, 7–10, especímenes nº 278, 280, 286–289 de Myodes rutilus; 3–6, especímenes nº 281, 283–285 de Myodes rufocanus del valle de los Géiseres; M, marcador de peso molecular de ADN 100 bp (2 % gel de agarosa, colorante de bromuro de etidio).

 

The variability observed in the shrew S. caecutiens was lower than in the voles (table 2). In this species, 68.8% of bands were polymorphic, and Nei’s gene diversity (h) was 0.27 while these values in S. isodon were 81.3% and 0.29, respectively.

We found a high genetic differentiation among vole populations in Kamchatka. The genetic distances among M. rutilus populations varied from 0.112 at a microgeographic scale to 0.279, between two parts of the reserve studied. In M. rufocanus, genetic distances were 0.113 and 0.487, respectively. Populations of M. rufocanus in Kamchatka were characterized presenting the greatest genetic distance (table 3).

Table 3. Indicators of genetic differentiation of Myodes populations: I, Nei’s original measures of genetic identity; D, genetic distance; GST, interpopulation component of genetic variability; Nm, gene flow; * according to Zhigileva and Gorbacheva (2017). Tabla 3. Indicadores de diferenciación genética de las poblaciones de Myodes: I, medidas originales de identidad genética de Nei; D, distancia genética; GST, componente de variabilidad genética interpoblacional; Nm, flujo genético; * según Zhigileva y Gorbacheva (2017).

 

The interpopulation component of genetic variability was about 11–39 % in M. rufocanus (GST = 0.116–0.391) and 20–31 % in M. rutilus (GST = 0.198–0.306). Gene flow was especially low in M. rufocanus.

Discussion

Our data are the first estimates of genetic polymorphism using nuclear markers in small mammal species from Kamchatka. We identified high polymorphism in the vole M. rutilus. The findings of high polymorphism in this species are consistent with data obtained by other researchers using mitochondrial genetic markers (Pereverzeva et al., 2014). M. rutilus is an absolute numerical dominant in the main biotopes in the vicinity of Kuril Lake and is abundant in the Valley of Geysers.

The level of ISSR-polymorphism of voles from Kamchatka differs little from the polymorphism of the populations of Myodes species from Western Siberia. The proportion of polymorphic bands on the same set of the ISSR markers in populations of M. rutilus from Western Siberia was 91.8 %, Nei’s gene diversity was 0.34, and the effective number of alleles was 1.58 (Zhigileva and Gorbacheva, 2017). These data are similar to the mean values of these parameters in M. rutilus populations from Kamchatka (table 2). Evidently, living on the distribution border on the Peninsula does not affect the polymorphism of neutral genetic markers. However, the genetic differentiation of vole populations from Kamchatka is more pronounced than that in the ecosystems of Siberia. The indexes in populations from Kamchatka were higher than those in populations of Myodes species from Siberia (Zhigileva and Gorbacheva, 2017). Gene flow was two times less in Kamchatka than in Siberia (table 3). Gene flow in vole populations of the Kronotsky Reserve indicates that exchange of migrants may be empeded due to the landscape features of the reserve. The voles from the Valley of Geysers and Uzon volcanic caldera demonstrated asynchronous changes in their numbers, which also confirms their belonging to different populations. This indicates significant landscape-geographical isolation between Uzon volcanic caldera and the Valley of Geysers, although the distance between them is about 15 km.

In the Kamchatka Peninsula, local populations of small mammals are strongly isolated because migration is obstructed by mountains. Their movements are also limited by geothermal fields, which they avoid. This isolation makes the local populations vulnerable and increases the risk of loss of genetic diversity. The data on high genetic differentiation among small mammal populations in Kamchatka should be taken into account when developing recommendations for protection of genetic resources in the peninsula.

Acknowledgements

We are grateful to V. M. Evdash (Center for Academic Writing ‘Impulse’, University of Tyumen) for her assistance with the English language.

References

Abramson, N. I., Petrova, T. V., Dokuchaev, N. E., Obolenskaya, E. V., Lissovsky, A. A., 2012. Phylogeography of the gray red-backed vole Craseomys rufocanus (Rodentia: Cricetidae) across the distribution range inferred from nonrecombining molecular markers. Russian Journal of Theriology, 11(2): 137-156.
Bender, W., Pierre, S., Hogness, D. S., Chambon, P., 1983. Chromosomal walking and jumping to isolate DNA from Ace and rosy loci of bithorax complex in Drosophila melanogaster. Journal of Molecular Biology, 168: 17-33,  Doi: https://doi.org/10.1016/s0022-2836(83)80320-9
Frisman, L. V., Kartavtseva, I. V., Pavlenko, M. V., Kostenko, V. A., Suzuki, H., Iwasa, M., Nakata, K., Chernyavskii, F. B., 2002. Gene-geographical variation and genetic differentiation in red-backed voles of the genus Clethrionomys (Rodentia, Cricetidae) from the region of the sea of Okhotsk. Russian Journal of Genetics, 38(5): 538-547.
Haring, E., Sheremetyeva, I., Kryukov, A., 2011. Phylogeny of Palearctic vole species (genus Microtus, Rodentia) based on mitochondrial sequences. Mammalian Biology, 76: 258-267.
Iwasa, M. A., Kartavtseva, I. V., Dobrotvorsky, A. K., Panov, V. V., Suzuki, H., 2002. Local differentiation of Clethrionomys rutilus in northeastern Asia inferred from mitochondrial gene sequences. Mammalian Biology – Zeitschrift für Säugetierkunde, 67(3): 157-166.
Iwasa, M. A., Utsumi, Y., Nakata, K., Kartavtseva, I. V., Nevedomskaya, I. A., Kondoh, N., Suzuki, H., 2000. Geographic patterns of cytochrome b and Sry gene lineages in the gray red-backed vole, Clethrionomys rufocanus from Far East Asia including Sakhalin and Hokkaido. Zoological Science, 17(4): 477-484.
Kawata, M., Ueda, J., 1984. Protein polymorphisms and their genetic control in the red-backed vole, Clethrionomys rufocanus bedfordiae. Animal Blood Groups and Biochemical Genetics, 15(2): 143–150, Doi: https://doi.org/10.1111/j.1365-2052.1984.tb01110.x
Kovaleva V. Yu., Litvinov, Yu. N., Efimov, V., 2014. Shrews (Soricidae, Eulipotyphla) from the Russian Far East and Siberia: combination and search for congruence of molecular genetic and morphological data. Biology Bulletin, 41(7): 575-588.
Matson, C. W., Baker, R. J., 2001. DNA sequence variation in the mitochondrial control region of red-backed voles (Clethrionomys). Molecular Biology and Evolution, 18(8): 1494-1501.
Naitoh, Y., Ohdachi, S. D., 2006. Population genetic structure of Sorex unguiculatus and Sorex caecutiens (Soricidae, Mammalia) in Hokkaido, based on microsatellite DNA polymorphism. Ecological Research, 21: 586-596.
Ohdachi, S. D., Yoshizawa, K., Hanski, I., Kawai, K., Dokuchaev, N. E., Sheftel, B. I., Abramov, A. V., Moroldoevs, I., Kawahara, A., 2012. Intraspecific Phylogeny and Nucleotide Diversity of the Least Shrews, the Sorex minutissimusS. yukonicus Complex, Based on Nucleotide Sequences of the Mitochondrial Cytochrome b Gene and the Control Region. Mammal Study, 37(4): 281-297.
Pereverzeva, V. V., Primak, A. A., 2016. Genetic diversity of the cytochrome b gene fragment haplotypes in red-backed vole Myodes (Clethrionomys) rutilus Pallas, 1779. Russian Journal of Genetics, 52(2): 164-172.
Pereverzeva, V. V., Primak, A. A., Dubinin, E. A., 2014. Genetic structure of northern red-backed vole (Myodes (=Clethrionomys) rutilus Pallas, 1779) populations of the northern Priokhotye determined by sequence variation of the mtDNA cytochrome B gene. Russian Journal of Genetics: Applied Research, 4(1): 27-34, https://doi.org/10.1134/S2079059714010079
Pereverzeva, V. V., Primak, A. A., Dokuchaev, N. E., Dubinin, E. A., Evdokimova, A. A., 2018. [Variability of mtDNA cytochrome b gene of the gray red-backed vole Craseomys rufocanus Sundevall, 1846 from Northern Priokhotye and the Kolyma River basin]. Bulletin of the North-East Scientific Center, Russia Academy of Sciences Far East Branch, 1: 101-112, [in Russian, with English summary], http://vestnik.north-east.ru/2018/n1/e_Pereverzeva.htm
Primak, A. A., Zasypkin, M. Yu, 2011. [Allozyme variability and genetic heterogeneity of the red-backed vole Clethrionomys rutilus (Cricetidae) over some islands in the northern sea of Okhotsk]. Bulletin of the North-East Scientific Center, Russia Academy of Sciences Far East Branch, 2(26): 100-105. [in Russian, with English summary], https://www.elibrary.ru/item.asp?id=16377663
Yeh, F. C., Yang, R., Boyle, T., 1999. POPGENE, version 1.31. University of Alberta and Centre for International Forestry Research, https://sites.ualberta.ca/~fyeh/popgene.pdf. <https://sites.ualberta.ca/~fyeh/popgene_download.html> [visited on 20 January 2020].
Zietjiewicz, E., Rafalski, A., Labuda, D., 1994. Genome fingerprinting by simple sequence repeat (SSR)-anchored polymerase chain reaction amplification. Genomics, 20: 176-183.
Zhigileva, O. N., Gorbacheva, E. V., 2017. Distribution and parameters of genetic polymorphism in northern red-backed vole (Clethrionomys rutilus) and bank vole (Clethrionomys glareolus) in West Siberia. Contemporary Problems of Ecology, 10(1): 1-8.

Content appears on: