Genome-wide association study and scan for signatures of selection point to candidate genes for body temperature maintenance under the cold stress in Siberian cattle populations

Igoshin, Alexander V.; Yurchenko, Andrey A.; Belonogova, Nadezhda M.; Petrovsky, D. V.; Aitnazarov, R. B.; Soloshenko, V. A.; Yudin, N. A.; Larkin, Denis M.

doi:10.1186/s12863-019-0725-0

Cited by 31 publications

(31 citation statements)

References 49 publications

(40 reference statements)

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“… Yang et al (2017) also identified the gene COL27A1 (found here in F ST 2 and ROH), which has been proposed to be involved in cartilage calcification, which is another important aspect in cold climates. Studying signatures of selection for candidate genes for body temperature maintenance under the cold stress in Siberian cattle populations, Igoshin et al (2019) found that the gene GRIA4 contribute to cold-stress resistance due to indirect involvement in body thermoregulation. In our study a gene from the same family ( GRIA1 ) was found for YAK in the F ST 3 and ROH scenarios.…”

Section: Discussionmentioning

confidence: 99%

“…For instance, a genomic evaluation for improved heat tolerance has been recently developed for Australian dairy cattle ( Nguyen et al, 2016 ). There is an increased interest in identifying and exploring signatures of selection (also known as selective sweeps) and the genomic diversity resulting from adaptation to environment and artificial selective pressure ( Igoshin et al, 2019 ; Osei-Amponsah et al, 2019 ; Upadhyay et al, 2019 ). Different approaches can be used to scan the genome for regions of homozygosity, as well as to estimate differences in the frequency of alleles or haplotypes between divergent populations or even generations within a population ( Boschiero et al, 2018 ; Ceballos et al, 2018 ).…”

Section: Introductionmentioning

confidence: 99%

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Genetic Diversity and Signatures of Selection for Thermal Stress in Cattle and Other Two Bos Species Adapted to Divergent Climatic Conditions

et al. 2021

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Understanding the biological mechanisms of climatic adaptation is of paramount importance for the optimization of breeding programs and conservation of genetic resources. The aim of this study was to investigate genetic diversity and unravel genomic regions potentially under selection for heat and/or cold tolerance in thirty-two worldwide cattle breeds, with a focus on Chinese local cattle breeds adapted to divergent climatic conditions, Datong yak (Bos grunniens; YAK), and Bali (Bos javanicus) based on dense SNP data. In general, moderate genetic diversity levels were observed in most cattle populations. The proportion of polymorphic SNP ranged from 0.197 (YAK) to 0.992 (Mongolian cattle). Observed and expected heterozygosity ranged from 0.023 (YAK) to 0.366 (Sanhe cattle; SH), and from 0.021 (YAK) to 0.358 (SH), respectively. The overall average inbreeding (±SD) was: 0.118 ± 0.028, 0.228 ± 0.059, 0.194 ± 0.041, and 0.021 ± 0.004 based on the observed versus expected number of homozygous genotypes, excess of homozygosity, correlation between uniting gametes, and runs of homozygosity (ROH), respectively. Signatures of selection based on multiple scenarios and methods (FST, HapFLK, and ROH) revealed important genomic regions and candidate genes. The candidate genes identified are related to various biological processes and pathways such as heat-shock proteins, oxygen transport, anatomical traits, mitochondrial DNA maintenance, metabolic activity, feed intake, carcass conformation, fertility, and reproduction. This highlights the large number of biological processes involved in thermal tolerance and thus, the polygenic nature of climatic resilience. A comprehensive description of genetic diversity measures in Chinese cattle and YAK was carried out and compared to 24 worldwide cattle breeds to avoid potential biases. Numerous genomic regions under positive selection were detected using three signature of selection methods and candidate genes potentially under positive selection were identified. Enriched function analyses pinpointed important biological pathways, molecular function and cellular components, which contribute to a better understanding of the biological mechanisms underlying thermal tolerance in cattle. Based on the large number of genomic regions identified, thermal tolerance has a complex polygenic inheritance nature, which was expected considering the various mechanisms involved in thermal stress response.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Genetic Diversity and Signatures of Selection for Thermal Stress in Cattle and Other Two Bos Species Adapted to Divergent Climatic Conditions

et al. 2021

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“…From the multivariate envGWAS in Red Angus, 9 of the 16 positional candidate genes have been identified by previous studies of adaptation or selection in humans or cattle (DIRC1, ABCB1, TBC1D1, AP5M1, GRIA4, LRRC4C, RBMS3, GADL1, PLA2G12B) 89,113,114 . For example, GRIA4 has been identified as a target of selection in coldadapted Yakutian cattle populations 115 . Of the other 7 candidate genes, three have been previously associated with adaptive phenotypes; body size (E2F7, BBS1) and circadian rhythm (ADCYAP1).…”

Section: Envgwas Detects Variants Segregating Along Continuous Enviromentioning

confidence: 99%

Powerful detection of polygenic selection and evidence of environmental adaptation in US beef cattle

Rowan

Durbin

Seabury

et al. 2020

Preprint

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Selection is a basic principle of evolution. Many approaches and studies have identified DNA mutations rapidly selected to high frequencies, which leave pronounced signatures on the surrounding sequence (selective sweeps). However, for many important complex, quantitative traits, selection does not leave these intense signatures. Instead, hundreds or thousands of loci experience small changes in allele frequencies, a process called polygenic selection. We know that directional selection and local adaptation are actively changing genomes; however we have been unable to identify the genomic loci responding to this polygenic, complex selection. Here we show that the use of novel dependent variables in linear mixed models (which allow us to account for population structure, relatedness, inbreeding) identify complex, polygenic selection and local adaptation. Thousands of loci are responding to artificial directional selection and hundreds of loci have evidence of local adaptation. While advanced reproduction and genomic technologies are increasing the rate of directional selection, local adaptation is being lost. In a changing climate, the loss of local adaptation may be especially problematic. These selection mapping approaches can be used in evolutionary, model, and agriculture contexts.

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“…After detection of significant and suggestive SNPs, the positions of SNPs on the chicken reference genome (Gallus-Gallus 4.0) were identified by NCBI database. According to Yates et al (2015), the names of the genes in 250 kbp up and down regions of significant SNPs were detected from NCBI and Ensembl (Goor et al 2015;Mengmeng et al 2016;Igoshin et al 2019). In order to investigate molecular and biological functions of the identified candidate genes, the UniProt (Universal Protein Resource) database was searched (Pundir et al 2015) and the animal QTLdb database was used for finding the QTL in the candidate genomic regions (Hu et al 2015).…”

Section: Post-gwas Analysismentioning

confidence: 99%

Genome‐wide association study of shank length and diameter at different developmental stages in chicken F2 resource population

et al. 2020

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In order to find SNPs and genes affecting shank traits, we performed a GWAS in a chicken F2 population of eight half‐sib families from five hatches derived from reciprocal crosses between an Arian fast‐growing line and an Urmia indigenous slow‐growing chicken. A total of 308 birds were genotyped using a 60K chicken SNP chip. Shank traits including shank length and diameter were measured weekly from birth to 12 weeks of age. A generalized linear model and a compressed mixed linear model (CMLM) were applied to achieve the significant regions. The value of the average genomic inflation factor (λ statistic) of the CMLM model (0.99) indicated that the CMLM was more effective than the generalized linear model in controlling the population structure. The genes surrounding significant SNPs and their biological functions were identified from NCBI, Ensembl and UniProt databases. The results indicated that 12 SNPs at 12 different ages passed the LD‐adjusted 5% Bonferroni significant threshold. Two SNPs were significant for shank length and nine SNPs were significant for shank diameter. The significant SNPs were located near to or inside 11 candidate genes. The results showed that a number of significant SNPs in the middle ages were higher than the rest. The MXRA8 gene was related to the significant SNP at week 1 that promotes proliferation of growth plate chondrocytes. A unique SNP of Gga_rs16689511 located on chicken Z chromosome within the LOC101747628 gene was related to shank length at three different ages of birds (weeks 8, 9 and 11). The significant SNPs for shank diameter were found at weeks 4 and 7 (four and five SNPs respectively). The identifications of SNPs and genes here could contribute to a better understanding of the genetic control of shank traits in chicken.

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Genome-wide association study and scan for signatures of selection point to candidate genes for body temperature maintenance under the cold stress in Siberian cattle populations

Cited by 31 publications

References 49 publications

Genetic Diversity and Signatures of Selection for Thermal Stress in Cattle and Other Two Bos Species Adapted to Divergent Climatic Conditions

Genetic Diversity and Signatures of Selection for Thermal Stress in Cattle and Other Two Bos Species Adapted to Divergent Climatic Conditions

Powerful detection of polygenic selection and evidence of environmental adaptation in US beef cattle

Genome‐wide association study of shank length and diameter at different developmental stages in chicken F2 resource population

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