Introduction

Mongolia is known for its extraordinary landscape diversity, which evolved due to complex past and recent climatic and orographic conditions, producing an intricate pattern of distribution of taiga, steppe and desert elements of mammal fauna (Dmitriev et al. 1992). A large part of contemporary landscapes is favourable for different taxa of voles such as Microtus (Lasiopodomys) brandti, Microtus (Stenocranius) gregalis, Alticola semicanus, Ellobius tancrei, which are relatively widespread and abundant (Sokolov & Orlov 1980, Dmitriev et al. 1992). At the same time, many other species of Mongolian arvicolines are rare or have highly mosaic distribution. Since many voles are sensitive to environmental changes, one may expect that the history of their ranges would mirror the Pleistocene/Holocene history of specific landscapes of Mongolia, which is shaped largely by climatic fluctuations and, in particular, by alterations of arid and humid (pluvial) phases, the timing of which is still understood incompletely (Devyatkin 1981, Grunert et al. 2000). Thus, the study of genetic structure of arvicoline species could be informative for understanding the landscape dynamics in Central Asia.

In the present paper, we examine six species of voles with different habitat specialization including Microtus mongolicus Radde, 1861, M. maximowiczii Schrenk, 1859, M. limnophilus Büchner, 1889, Eolagurus luteus Eversmann, 1840, E. przewalskii Büchner, 1889 and Lagurus lagurus Pallas, 1773. The Mongolian vole, M. mongolicus, is a typical representative of the East Paleractic steppe faunal assemblage. In contrast, M. maximowiczii is a northern element and occurs mainly in forest and riparian habitats in the north-east and east of the country. Mongolian populations of the lacustrine vole M. limnophilus are restricted only to oases in the desert and semi-desert zones. Although voles and lemmings (tribe Lagurini) are an important component of steppe and semi-desert mammal fauna, they remain unstudied from a phylogeographic viewpoint. The steppe lemming (Lagurus) is widely distributed through the steppes of South Russia and Kazakhstan but is now extremely rare in Mongolia. The Przewalskii steppe vole, Eolagurus przewalskii has a broad range across the semidesert and desert zone of Mongolia, but the findings of this species are rare.

Fig. 1.

The geographic position of sampling localities. Locality names and detailed geographic information for sites 1-17 are given in Table 1. Locality 18 (cytb sequences KP190245-KP190246; Liu et al. 2017) – Hailar, Inner Mongolia, China.

The aim of our study was to examine the genetic structure of these arvicolines in Mongolia and adjacent areas in order to elucidate their phylogeographic history.

Material and Methods

Alignment, partitioning and phylogenetic tree reconstruction

All sequences were aligned by eye using Bioedit version 7.0.9.0 (Hall 1999). The cytb phylogenetic trees of Microtus were inferred from either a more compact alignment including only sequences longer than 900 bp or an extended alignment consisting of all available sequences for the subgenus Alexandromys (except M. oeconomus). Genbank sequences containing stop codons or multiple ambiguities were excluded from all analyses. The cytb mean genetic (p) distances were calculated in PAUP* 4.0b10 (Swofford 2003).

Table 1.

Characterization of the original material: species, specimen code, collection and geographic origin of specimens first used in this study. Abbreviations: ZMMU – Zoological Museum of Moscow University, main collection; ZMMU/tc – Zoological Museum of Moscow University, tissue collection. Numbers of localities shown in Fig. 1 (only Mongolia, N China and E Kazakhstan) are given in parentheses.

Table 1. Continued.

Table 2.

Sequences retrieved from GeneBank.

Phylogenetic cytb trees were reconstructed using Maximum Likelihood (ML) and Bayesian criteria. ML reconstructions were conducted in IQTREE version 1.6 (Nguyen et al. 2015). The ModelFinder routine (Kalyaanamoorthy et al. 2017) as implemented in IQTREE version 1.6 was used to determine the optimum partitioning scheme and the best-fit substitution models for each subset under Bayesian information criterion. Clade stability was tested using Ultrafast Bootstrap (Minh et al. 2013) with 10000 replicates.

Bayesian cytb tree reconstructions were performed in MrBayes 3.2 (Ronquist et al. 2012). Models with either two or six rate matrix parameters were selected for each subset using ModelFinder. For most parameters, default priors were used. Compound Dirichlet priors for branch lengths combined with gamma prior on the tree length were invoked. All parameters except branch lengths were unlinked across partitions. The analysis included two independent runs of four chains with the default heating scheme. The chain length was set at 20 million generations with the sampling of every 10000 generation. Tracer 1.6 software (Rambaut & Drummond 2003) was used to check for convergence and determine the necessary burn-in fraction, which was 10 % of the chain length. The effective sample size exceeded 200 for all estimated parameters.

The Bayesian ultrametric tree was reconstructed in BEAST version 1.84 (Drummond et al. 2012) based on the extended cytb alignment under strict clock. Partitioning and substitution models were defined as in the ML analysis. The birth-death tree prior was used; priors for other parameters were kept at default values. The chain length was set to 100 million generations; the burn-in was 10 million.

Each nuclear gene was analysed separately based on the phased datasets. For allelic phase reconstruction, the Phase module (Stephens et al. 2001, Stephens & Donnelly 2003) implemented in the software DNAsp (version 5; Librado & Rozas 2009) was used. Networks of haplotypes were reconstructed using TCS under default options (Clement et al. 2000) and visualized using tcsBU (Múrias dos Santos et al. 2015).

Molecular dating

The molecular dates for the interspecies and intraspecies divergences were estimated based on the cytb data using two different procedures. In the former case we followed the rationale outlined in Bannikova et al. (2010) and used the clock employing only transversions at the 3^rd codon positions (tv3). The node depths were estimated under ML criterion in PAUP. For Microtus, the tv3 substitution rate was set at 4 % per million years as estimated by Bannikova et al. (2010). For Lagurini the rate was calculated based on the assumption that the age of the Eolagurus/ Lagurus split is close to 3.3 My (million years) as estimated by Abramson et al. (2009).

Fig. 2.

The Bayesian tree of Microtus (Alexandromys) species A) as inferred in MrBayes from the cytb alignment containing sequences of more than 900 bp. Numbers above branches correspond to MrBayes posterior probabilities and ML bootstrap support (> 50 %) for the main clades. The tree branches that are not discussed in the paper (except of M. limnophilus) are collapsed. The M. limnophilus clade is shown separately B). The sequences that were first obtained in this study are marked with an asterisk.

Fig. 3.

The Bayesian cytb tree of Lagurini. The designations are as in Fig. 2.

Table 3.

Optimum substitution models for the ML analysis as identified by ModelFinder.

In case of intraspecies divergences the estimates were based on the complete cytb alignment. The node depths (relative node ages) were estimated using the ultrametric tree generated in BEAST for Alexandromys. The rate of the cytb for recent splits was estimated as described in Lebedev et al. (2018). The proportion of transversions at the 3^rd codon positions relative to the observed number of all substitutions was calculated within cytb lineages with maximum inter-haplotype divergence of less than 2 %; the tv3 substitution rate of 4 % per My was assumed. Prior to the analyses, the molecular clock assumption was tested separately for Lagurini and Alexandromys data sets using the hierarchical likelihood ratio test with all calculations performed in PAML 4.7 (Yang 2007).

Results

Phylogenetic analysis of the cytb data

The smaller and larger cytb alignments of Microtus included 229 and 337 sequences, respectively. The cytb data set of Lagurini contained 18 specimens including four outgroups. The length of all cytb alignments was 1140 bp. In all analyses the cytb data were partitioned into three codon positions. The models suggested by ModelFinder are presented in Table 3.

Among 12 species of Microtus present in the Bayesian cytb tree (Fig. 2 and Fig. S1-S4) six are distributed in Mongolia. All of them are represented by monophyletic assemblages except M. mongolicus and M. maximowiczii. Voles traditionally attributed to M. mongolicus are grouped in two separate clusters, which stand in a polytomy with M. middendorffi (Fig. 2, Fig. S1, S2). The first cluster includes animals distributed in the eastern part of the range (Transbaikalia and Khentii Mountains), the second (western) cluster comprises a sample from Khangai Mountains and a single animal captured in south-east Tuva near the border with Mongolia. Two shorter GeneBank sequences from Khangai Mountains are also associated with the western cluster (Fig. S2). The distance between the two clusters is about 5.5 %. The western clade is close to M. middenorffi (5.1 %) and both are relatively close to M. shantaricus (6.5 %). It is evident that the western clade corresponds to a recently described subspecies M. m. alpinus Lissovsky et al. (2018), while the eastern clade is expected to belong to the typical subspecies. However, taking into account that the rank of alpinus is disputable (see Discussion) we henceforth designate the two clades as “alpinus” lineage and “mongolicus” lineage.

Fig. 4.

The TCS network showing the relationships among the alleles of BRCA1, P53 and GHR genes in the studied species of Microtus. The size of circles corresponds to the number of specimens with identical alleles.

Table 4.

Approximate node age estimates (My) in Mongolian arvicolines based on mitochondrial data.

Our results on the genetic diversity of M. maximowiczii in Mongolia are presented in Fig. 2 (only longer sequences of cytb, > 900 bp) and Fig. S3 (short sequences of < 900 bp are also included). Two specimens from the River Khalkhin Gol, four specimens from Inner Mongolia (Xilinhot and Hailar) and the single specimen from Khentii (clade I, southwest haplogroup) form a clade separate from all other M. maximowiczi originating from Buryatia, China and Russian Far East (clade II, eastern haplogroup). Microtus maximowiczii clades I and II are placed in an unresolved polytomy in the cytb tree with M. mujanensis and M. evoronensis. The distance between the two clades of the Maximowicz's vole is 2.9 %. All specimens of M. limnophilus from Mongolia cluster as a separated supported branch while the sample from China appears paraphyletic (Fig. 2B). The distance between Mongolian and Chinese haplotypes is 2.2 %. The Mongolian sample is not completely homogeneous: the sequence of the specimen from the vicinities of the Alag Nuur (NW Transaltai Govi) is separated from other haplotypes (Great Lake basin, Sharga and Mongolian Dzungaria) by the p-distance of 1.5 %.

Fig. 5.

The female karyotype of Eolagurus przewalskii with 2n = 60, NFa = 58. Male sex chromosomes (XY) are framed. Conventional Giemsa staining.

In the MrBayes cytb tree of Lagurini (Fig. 3) the clade consisting of sister species Eolagurus luteus and E. przewalskii is separated from the steppe vole Lagurus lagurus by the distance of 12.1 %. The steppe vole is relatively polymorphic, the p-distance between three eastern and three western specimens is 1.7 %. Eolagurus luteus and E. przewalskii differ by 8.9 %. The difference between E. luteus from Mongolian Dzungaria vs. those from Zaisan is just 0.3 % although the two points are separated by ~750 km; E. przewalskii from the two sampled localties (east of the Great Lake basin and South Govi, geographic distance of ~700 km) also show little differentiation.

Discussion

The available genetic data indicate the existence of two separate genetic lineages within M. mongolicus sensu lato (s.l.). The genetic distance between these forms and the estimated time of their split (~300 kya) correspond to those between some indisputable species pairs in the genus Microtus (M. socialis –M. guentheri, M. sachalinensis – M. maximowiczii, M. arvalis – M. rossiaemeridionalis). Noteworthy, the genetic distance between the “alpinus” and “mongolicus” lineages of M. mongolicus is as high as that between M. mongolicus and M. middendorffi and is close to those between the above three lineages and M. shantaricus. The pattern of variation of nuclear genes in M. mongolicus s.l. from the territory of Mongolia (which was not described before) supports the differentiation between the “alpinus” and “mongolicus” as suggested by the mtDNA data. In two of the examined nuclear loci (P53 and BRCA1) the two lineages of the Mongolian vole share no common alleles, while the pattern observed in GHR can be explained by the slow evolutionary rate of this marker.

Karyotype variation in M. mongolicus s.l. is studied insufficiently. Yatsenko et al. (1980) found no essential difference between karyotypes described by them from Khangai and Khentii (2n = 50) as well as between these two and the karyotype from the Chita region presented in Meyer et al. (1967). At the same time, the former authors revealed several animals with 2n = 49 in the Khenteii population of the “mongolicus” lineage, which is likely explained by heterozygosity for a centric fusion.

Currently, there is no data that could clarify whether there is an effective reproductive barrier between the “alpinus” and “mongolicus”. The available genetic evidence provides no indication to gene flow. Based on the museum data the two lineages appear strictly allopatric; moreover, their distribution ranges are likely separated by a huge gap (ca. 400 km) covering the area between Khentii and Khangai Mountains (Fig. S7). This area is potentially suitable for the Mongolian vole (as follows from the results of ecological niche modelling by Shenbrot & Krasnov 2005); however, no records from this territory are known. The ecological affinities of the two lineages appear to be different: while the “mongolicus” lineage inhabits mostly lowland grasslands and riparian habitats, the “alpinus” lineage is found in Khangai predominantly in mountain steppe or alpine tundra above 2600 m (Dmitriev et al. 1992). In such a case, when the evidence of absence or presence of barriers to gene flow is lacking, species boundaries can be identified with the help of the operational criteria employed by the Genetic Species Concept sensu Bradley & Baker (2001) and Baker & Bradley (2006), i.e. by comparison of the levels of divergence between lineages of uncertain taxonomic status with those between indisputable species within the clade of interest. Based on the above arguments we consider that the “alpinus” and “mongolicus” lineages deserve full species rank.

Mongolian voles from the western part of the range were described as a subspecies M. m. alpinus (type locality: southern foothills of Otgontenger, western Khangai) based on both genetic and morphological differences vs. M. mongolicus from Transbaikalia (Lissovsky et al. 2018). However, in the latter study, the genetic sample of the western (“alpinus”) lineage was represented by a single specimen from south-eastern Tuva and two museum specimens from Khangai, for which only fragments of cytb were obtained. It is worth mentioning that both M. middendorffi and M. shantaricus are as well treated by Lissovsky et al. (2018) as subspecies of M. mongolicus. We believe that such a wide treatment of species in Microtus is unjustified. Thus, M. shantaricus and M. mongolicus differ from each other and their common ancestor in characteristic non-Robertsonian chromosomal rearrangements (Romanenko et al. 2018). The level of genetic divergence among these taxa corresponds to that between recognized species of grey voles (see above). Therefore, we suggest recognition of the West form of Mongolian voles as a distinct species Microtus alpinus and support species rank for M. middendorffi and M. shantaricus.

Microtus maximowiczii is characterized by extremely complex chromosomal polymorphism and pronounced genetic variation (for review see; Sheremetyeva et al. 2015). Five karyotype morphs (A, B, V, C and D) were described for the voles of Transbaikalia, Buryatia, Khentii, Middle Amur and East Mongolia, respectively (Kovalskaya 1977, Frisman et al. 2009, Kartavtseva et al. 2008, 2013). Based on the data by Kovalskaya (1977) with modification by Kartavtseva et al. (2008) we can assume that the voles examined in our study belong to variants V (Khentii) and D (East Mongolia). The analysis of the mitochondrial C-region in Maximowicz's voles revealed two haplogroups – west (B and V chromosomal forms) and east (A and chromosomal forms C) (Haring et al. 2011, Sheremetyeva et al. 2015). Due to the different choice of the mitochondrial marker (cytb) used in our study compared to the previous ones (control region) it is difficult to unambiguously identify the relations between the revealed haplogroups. Based on the geographical origin of samples and comparisons of average intergroup distances one may tentatively suppose that west C-region haplogroup (southern Buryatia) corresponds to the cytb south-western (SW) lineage, however additional analysis is necessary to verify this assumption.

Our data shows that the SW lineage of M. maximowiczii is distributed wider than it could have been expected as its range covers not only the Khentii region but also East Mongolia and adjacent regions of Inner Mongolia. The molecular clock results suggest that the group diverged from the rest of the M. maximowiczii species complex approximately ~110-120 kya (thousand years ago) (Bannikova et al. 2010, this study) what may correspond to the last Interglacial. The time of the most recent common ancestor (tmrca) of the group (Khentii/Khingan divergence) is estimated as ~34 kya, thus falling into the MIS3 interstadial period when precipitation in northern Mongolia was high (Ma et al. 2013). The taxonomic status of the SW group appears unclear. The distance separating it from M. maximowiczii sensu stricto (s.str.) is coinsistent rather with interspecific differentiation. At the same time, the two other species, M. mujanensis and M. evoronensis, the genetic divergence of which from M. maximowiczii appear even lower than that between the two lineages of the latter, are known to be reproductively isolated from it (Meyer et al. 1996). This phenomenon can be associated by high rate of chromosome evolution in the M. maximowiczii group. Kovalskaya (1977) reported the lack of reproductive isolation between chromosomal races A and V (the latter is from Khentii and likely belongs to the SW lineage), however, until the relationships between the SW lineage and other members of M. maximowiczii group are examined on a larger data set (including sampling from potential contact zones) one cannot rule out that the SW lineage can be, in fact, another, yet undescribed, “chromosomal” species in statu nascendi. Currently, there is no available name that can be put in correspondence to this putative taxon. Our data on cytb genetic structure in M. limnophilus suggest that Mongolian populations could have originated as a result of colonisation from China. Currently the Mongolian part of the range of the lacustrine vole is separated from the Chinese one by vast Alashan – South Govi deserts, which are unfavourable for mesic species. Noteworthy, Mongolian M. limnophilus is ecologically different from the Chinese populations. In Mongolia, the distribution is highly mosaic being restricted to oases in semidesert and desert zones; it is never found in lowland and mountain steppes or alpine grasslands, which are dominated by Microtus oeconomus and Microtus (Stenocranius) gregalis. In contrast, Chinese lacustrine voles occur in a plethora of mesic high altitude and lowland habitats being a common component of Tibetan humid grassland communities. The estimated time of colonisation of Mongolia by M. limnophilus falls between ~50 and ~ 100 kya. One may hypothesize that range expansion in the lacustrine vole was associated with a major pluvial episode in Central Asia the exact time of which is unclear. Potentially, this event can be attributed to the time of high lake levels in South Mongolia during MIS5e-MIS4 (Lehmkuhl et al. 2018).

Our study presents the first preliminary results on genetic variation in Lagurini. The data clearly indicate the high level of genetic divergence between Eolagurus luteus and E. przewalskii, which evidently correlates with known morphological differences including such diagnostic traits as bullae size and shape of thumb claw. The karyotype of E. przewalskii (2n = 60, NFa = 58), which was examined for the first time, is different from that described for E. luteus from Mongolian Dzungaria (2n = 56, NFa = 54 (?); Orlov et al. 1978). Our estimate of the divergence time between the two species (~1 My) may correspond to Early/Middle Pleistocene boundary, which is regarded as the time of major climate change towards more arid conditions (Head & Gibbard 2015). Climate shift could have promoted eastward range expansion in the common ancestor of the two contemporary species, which dwell mostly in semidesert habitats and are now among the most xerophylic vole taxa. The first fossil findings of Eolagurus in Transbaikalia are attributed to the late Early-Middle Pleistocene (Erbajeva & Alexeeva 2013), which is in line with the molecular estimate. Both E. luteus and E. przewalskii are featured by patchy distribution and relatively low population sizes with sporadic extreme peaks followed by population crashes (Sludskiy et al. 1978, Smith & Xie 2009). This type of population dynamics may explain the observed lack of genetic differentiation between the geographically distant populations in both species. It was generally believed that E. luteus, which underwent rapid range contraction during the last few hundred years (Formozov 1938), is now restricted to East Kazakhstan and Dzungarian basin. We collected a single specimen of this species in the Great Lake basin, which is located nearly 200 km northward from previously known Mongolian localities and is separated from the latter by the Altai Mountains. This finding may be explained by human-mediated long-range dispersal, nevertheless, we believe that the distribution of this species in western Mongolia requires additional study.

The steppe lemming is currently distributed across the western sector of Palearctic steppe zone from East Ukraine to Dzungarian basin with isolated enclaves in Tian Shan, southern Siberia and western Mongolia. The species was more widespread during cold stages of the Late Pleistocene, major contraction and fragmentation of the range can be attributed to the Pleistocene/Holocene boundary (Dupal et al. 2013). Our preliminary genetic data demonstrate the lack of deep divergence between specimens from the western and eastern parts of the range. In contrast to some other steppe mammals such as Spermophilus pygmaeus (Ermakov et al. 2006) and Nothocricetulus migratorius (Lebedev et al. 2018), the River Volga is not a boundary between well-differentiated lineages in the steppe lemming as follows from the low distance (1.1 %) between the specimen from West Siberia (Omsk region, AF429818) and the voles from the Don basin. The time of the most recent common ancestor can be tentatively attributed to the Middle/Late Pleistocene transition, however, this result should be treated with caution. The examined Mongolian sample is close to the specimen from the Zaisan depression. This finding is in line with the fact that Mongolian and Dzungarian populations are traditionally attributed to the subspecies L. l. altorum Thomas, 1912 (terra typica Barlyk Mountains, west of Dzungarian basin), which is featured by pale colouration of dorsal pelage. The range of the steppe lemming in Mongolia is fragmented in several isolates; one of which (Uvs depression, north-western Mongolia) is associated with lowland semidesert. On the contrary, populations of Mongolian Altai region (such as the one examined here) are only found in mountain dry steppes at the altitudes of 2000-3000 m, which suggests their recent origin due to an altitudinal shift in response to aridification of Mongolia in Holocene.

In conclusion, the results of our study contribute to vole taxonomy by supporting the species status of the two lineages of M. mongolicus s.l. and reveal a variety of phylogeographic patterns among voles of Central Asia, thus providing a basis for future studies on the history of regional fauna.