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The House Mouse, Mus musculus, is a model organism that has greatly contributed to evolutionary research. Despite its significance, there remain gaps in our understanding of its phylogeography and population genetic structure in Asian regions. This comprehensive study aims to elucidate the evolutionary history, genetic diversity, and distribution patterns of M. musculus. A diverse data set of 281 M. musculus samples was collected from across Asia, covering 101 localities in 19 countries. Phylogenetic analysis using Cytochrome b and D-Loop region unveiled well-supported lineages. These lineages correspond to: M. m. musculus, M. m. domesticus, M. m. castaneus, and M. m. bactrianus. Also, validity of M. m. bactrianus was questioned. The analysis suggests a monophyletic origin of these subspecies approximately 0.59 million years ago (Mya), followed by 2 main lineages—one consisting of M. m. domesticus (~0.59 Mya) and the other comprising M. m. castaneus, M. m. bactrianus, and M. m. musculus (~0.56 Mya). Genetic diversity varied among subspecies, with M. m. domesticus exhibiting the highest diversity due to its extensive global distribution and M. m. bactrianus exhibiting the lowest diversity due to restriction in southwest Asia. Pairwise genetic distances and Fst values confirmed significant genetic differentiation among the subspecies, underlining their historical isolation. Additionally, a Mantel test indicated that geographical distance played a pivotal role in shaping genetic differentiation. Demographic analysis revealed evidence of population expansions in M. m. domesticus, M. m. musculus, and M. m. castaneus, while M. m. bactrianus showed characteristics of neutral selection and genetic drift. Species distribution modeling, assessing both Current Conditions and the Last Glacial Maximum, indicated habitat shifts and losses during glacial periods, particularly in the eastern and northern regions of Asia. However, each subspecies displayed unique responses to climatic changes, reflecting their distinct ecological adaptations. Historical biogeography analysis pointed to complex origins and a network of dispersal and vicariance events that led to the contemporary distribution of subspecies. Deserts and xeric shrublands emerged as critical areas for diversification and speciation. This study contributes to our understanding of the phylogeography and population genetics of M. musculus in Asia, highlighting the significance of geographical factors and climatic fluctuations in shaping its evolutionary history and genetic diversity.
The House Mouse, Mus musculus, is a model organism that has greatly contributed to evolutionary research. Despite its significance, there remain gaps in our understanding of its phylogeography and population genetic structure in Asian regions. This comprehensive study aims to elucidate the evolutionary history, genetic diversity, and distribution patterns of M. musculus. A diverse data set of 281 M. musculus samples was collected from across Asia, covering 101 localities in 19 countries. Phylogenetic analysis using Cytochrome b and D-Loop region unveiled well-supported lineages. These lineages correspond to: M. m. musculus, M. m. domesticus, M. m. castaneus, and M. m. bactrianus. Also, validity of M. m. bactrianus was questioned. The analysis suggests a monophyletic origin of these subspecies approximately 0.59 million years ago (Mya), followed by 2 main lineages—one consisting of M. m. domesticus (~0.59 Mya) and the other comprising M. m. castaneus, M. m. bactrianus, and M. m. musculus (~0.56 Mya). Genetic diversity varied among subspecies, with M. m. domesticus exhibiting the highest diversity due to its extensive global distribution and M. m. bactrianus exhibiting the lowest diversity due to restriction in southwest Asia. Pairwise genetic distances and Fst values confirmed significant genetic differentiation among the subspecies, underlining their historical isolation. Additionally, a Mantel test indicated that geographical distance played a pivotal role in shaping genetic differentiation. Demographic analysis revealed evidence of population expansions in M. m. domesticus, M. m. musculus, and M. m. castaneus, while M. m. bactrianus showed characteristics of neutral selection and genetic drift. Species distribution modeling, assessing both Current Conditions and the Last Glacial Maximum, indicated habitat shifts and losses during glacial periods, particularly in the eastern and northern regions of Asia. However, each subspecies displayed unique responses to climatic changes, reflecting their distinct ecological adaptations. Historical biogeography analysis pointed to complex origins and a network of dispersal and vicariance events that led to the contemporary distribution of subspecies. Deserts and xeric shrublands emerged as critical areas for diversification and speciation. This study contributes to our understanding of the phylogeography and population genetics of M. musculus in Asia, highlighting the significance of geographical factors and climatic fluctuations in shaping its evolutionary history and genetic diversity.
This study investigates the genetic diversity and phylogeographic structure of lion populations (Panthera leo) across Africa and Asia, revealing significant insights into their evolutionary history. Our analysis identifies two primary clades: the North Clade comprising Asian and northern African populations identified as Panthera leo leo, and the South Clade containing East and southern African populations identified as Panthera leo melanochaita. We estimate that the lion's modern lineage originated approximately 320-280 Kya, with a divergence into the North Clade around 170-130 Kya. The South Clade exhibits a deeper divergence about 290-180 Kya, suggesting a longer history of geographic isolation driven by environmental changes. These dates are older than earlier estimates, owing to new information on the time of divergence between P. leo and P. spelaea. Most famous and referenced studies used 0.55 Mya as the split time between P. leo and P. spelaea as the calibration point for their time calibrated trees but new studies demonstrated that split time between P. leo and P. spelaea is circa 1.89 Mya. Also, our findings indicate that the Indian lineage (Asian haplogroup) represents a genetically distinct group that should not be classified as a separate subspecies, as its genetic differentiation is trivial compared to that between P. l. leo and P. l. melanochaita. The results also indicate higher genetic diversity within P. l. melanochaita, suggesting a stable population structure influenced by historical environmental conditions. In contrast, P. l. leo exhibits lower genetic variability, likely due to recent anthropogenic pressures, including habitat loss and fragmentation. Demographic analyses illustrate a dramatic decline in effective population size starting in the mid-20th century, correlating with the well-documented reduction in lion range. Phylogeographic patterns in lions reflect broader trends in savannah mammals, underscoring the role of historical climatic fluctuations in shaping modern populations. Crucially, our results contest the hypothesis that the Indian lion population was bolstered by sub-Saharan lion introductions, indicating its ancient lineage. These findings highlight the necessity for targeted conservation strategies that consider the genetic and evolutionary context of lion populations, as well as the unique challenges they face in a changing landscape. Overall, this research underscores the importance of integrating genetic data into lion conservation efforts to ensure the long-term survival of this iconic species.
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