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Background
Y-chromosomal haplogroup (Y-HG) Q is suggested to originate in Asia and represent recent founder paternal Native American radiation into the Americas. This group is delineated into Q1, Q2 and Q3 subgroups defined by biallelic markers M120, M25/M143 and M3, respectively. Recently, a novel subgroup Q4 has been identified which is defined by bi-allelic marker M346, representing HG Q (0.41%, 3/728) in Indian population. With scanty details of HG Q in Asia, especially India, it was pertinent to explore the status of the Y-HG Q in Indian population to gather an insight to determine the extent of diversity within this region. 相似文献Isolation and development of new microsatellite markers for any species is still labour-intensive and requires substantial inputs of time, money and expertise. Therefore, cross-species microsatellite amplification can be an effective way in obtaining microsatellite loci for closely related taxa in bird species. We have reported microsatellite loci for Himalayan monal for the first time. Fifteen microsatellite markers developed for chicken were cross-amplified in Himalayan monal. All the tested 15 microsatellite markers were polymorphic, with mean (± s.e.) allelic number of 4 ± 1.51, ranging 2–7 per locus. The observed heterozygosity in the population ranged between 0.285 and 0.714, with mean (± s.e.) of 0.499 ± 0.125, indicating considerable genetic variation in this population. While 12 loci conformed to Hardy–Weinberg equilibrium (P > 0.05), 3 loci, i.e. MCW0295, MCW0081, MCW0330 deviated from it (P < 0.05). No evidence for linkage disequilibrium was observed among pair of loci. Our study show that these 15 microsatellites loci could be employed in population genetic studies for Himalayan monal and their applicability in Jungle Bush Quail, Grey francolin and Kalij pheasant.
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