Abstract
BackgroundThe Yarkand hare (Lepus yarkandensis Günther, 1875) is endemic to oasis and desert areas around the Tarim Basin in the Xinjiang Uyghur Autonomous Region of northwest China; however, genome-wide information for this species remains limited. Moreover, the genetic variation, genetic structure, and phylogenetic relationships of Yarkand hare from the plateau mountain regions have not been reported. Thus, we used specific-length amplified fragment sequencing (SLAF-seq) technology to evaluate the genetic diversity of 76 Yarkand hares from seven geographic populations in the northern and southwestern parts of the Tarim Basin to investigate single-nucleotide polymorphism (SNP) marker-based population differentiation and evolutionary processes. Selective sweep analysis was conducted to identify genetic differences between populations.ResultsUsing SLAF-seq, a total of 1,835,504 SNPs were initially obtained, of which 308,942 high-confidence SNPs were selected for further analysis. Yarkand hares exhibited a relatively high degree of genetic diversity at the SNP level. Based on pairwise FST estimates, the north and southwest groups showed a moderate level of genetic differentiation. Phylogenetic tree and population structure analyses demonstrated evident systematic phylogeographical structure patterns consistent with the geographical distribution of the hares. Hierarchical analysis of molecular variation further indicated that genetic variation was mainly observed within populations. Low to moderate genetic differentiation also occurred among populations despite a common genomic background, likely due to geographical barriers, genetic drift, and differential selection pressure of distinct environments. Nevertheless, the observed lineage-mixing pattern, as indicated by the evolutionary tree, principal component analysis, population structure, and TreeMix analyses, suggests a certain degree of gene flow between the north and southwest groups. This may be related to the migration of hares to high-altitude water sources southwest of the basin during glacial climatic oscillations, as well as river re-diffusion and oasis restoration in the basin following the glacial period. We also identified candidate genes, and their associated gene ontology terms and pathways, related to the adaptation of Yarkand hares to different environmental habitats.ConclusionsThe identified genome-wide SNPs, genetic diversity, and population structure of Yarkand hares expand our understanding of the genetic background of this endemic species and provide valuable insights into its environmental adaptation, allowing for further exploration of the underlying mechanisms.
Highlights
The Yarkand hare (Lepus yarkandensis Günther, 1875) is endemic to oasis and desert areas around the Tarim Basin in the Xinjiang Uyghur Autonomous Region of northwest China; genome-wide information for this species remains limited
The identified genome-wide single-nucleotide polymorphism (SNP), genetic diversity, and population structure of Yarkand hares expand our understanding of the genetic background of this endemic species and provide valuable insights into its environmental adaptation, allowing for further exploration of the underlying mechanisms
Sampling and DNA extraction Muscle or skin tissue samples were collected from a total of 76 Yarkand hares (L. yarkandensis) from seven geographic populations around the Tarim Basin from 2008 to 2018; 20 samples were obtained from Korla (KRL), 10 from Akesu (AKS), 5 from Alar (ALR), 12 from Tashkurgan (TX), 16 from Aketu (AKT), 10 from Kashgar (KS), and 3 from Wuqia (WQ) in Xinjiang Uygur Autonomous Region (XUAR), northwestern China
Summary
The Yarkand hare (Lepus yarkandensis Günther, 1875) is endemic to oasis and desert areas around the Tarim Basin in the Xinjiang Uyghur Autonomous Region of northwest China; genome-wide information for this species remains limited. Identifying the levels of genetic variation within and between species or populations is an essential step in studying the influences of mutation, natural selection, and genetic drift [1]. Toward this end, it is often beneficial to understand genetic variation using population differentiation statistics such as the pairwise genetic differentiation estimate (FST) [2]. Research investigating the factors influencing genetic differentiation and gene flow within a species has mainly focused on geographical or geological factors—such as the impact of Quaternary glacial fluctuations [7,8,9] and habitat fragmentation [10, 11]—combined with anthropogenic activities, resulting in physical barriers that cause discontinuities in the distribution of a species [12]
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