Department of Crop and Soil Sciences, North Carolina State University, Raleigh, NC, 27695, USA.
NE Research and Extension Center, University of Arkansas, Keiser, AR, 72715, USA.
Theor Appl Genet. 2024 Sep 3;137(9):214. doi: 10.1007/s00122-024-04717-7.
A GWAS in an elite diversity panel, evaluated across 10 environments, identified genomic regions regulating six fiber quality traits, facilitating genomics-assisted breeding and gene discovery in upland cotton. In this study, an elite diversity panel of 348 upland cotton accessions was evaluated in 10 environments across the US Cotton Belt and genotyped with the cottonSNP63K array, for a genome-wide association study of six fiber quality traits. All fiber quality traits, upper half mean length (UHML: mm), fiber strength (FS: g tex), fiber uniformity (FU: %), fiber elongation (FE: %), micronaire (MIC) and short fiber content (SFC: %), showed high broad-sense heritability (> 60%). All traits except FE showed high genomic heritability. UHML, FS and FU were all positively correlated with each other and negatively correlated with FE, MIC and SFC. GWAS of these six traits identified 380 significant marker-trait associations (MTAs) including 143 MTAs on 30 genomic regions. These 30 genomic regions included MTAs identified in at least three environments, and 23 of them were novel associations. Phenotypic variation explained for the MTAs in these 30 genomic regions ranged from 6.68 to 11.42%. Most of the fiber quality-associated genomic regions were mapped in the D-subgenome. Further, this study confirmed the pleiotropic region on chromosome D11 (UHML, FS and FU) and identified novel co-localized regions on D04 (FU, SFC), D05 (UHML, FU, and D06 UHML, FU). Marker haplotype analysis identified superior combinations of fiber quality-associated genomic regions with high trait values (UHML = 32.34 mm; FS = 32.73 g tex; FE = 6.75%). Genomic analyses of traits, haplotype combinations and candidate gene information described in the current study could help leverage genetic diversity for targeted genetic improvement and gene discovery for fiber quality traits in cotton.
GWAS 在一个精英多样性面板中进行,该面板在 10 个环境中进行评估,确定了调节六个纤维质量性状的基因组区域,为陆地棉的基因组辅助育种和基因发现提供了便利。在这项研究中,对来自美国棉花带的 348 个陆地棉品种进行了精英多样性面板评估,并使用棉花 SNP63K 阵列进行了基因型分析,以进行六个纤维质量性状的全基因组关联研究。所有纤维质量性状,上半均值长度(UHML:mm)、纤维强度(FS:g tex)、纤维均匀度(FU:%)、纤维伸长率(FE:%)、马克隆值(MIC)和短纤维含量(SFC:%)均表现出高广义遗传力(>60%)。除 FE 外,所有性状均表现出高基因组遗传力。UHML、FS 和 FU 彼此之间均呈正相关,与 FE、MIC 和 SFC 呈负相关。对这六个性状的 GWAS 共鉴定出 380 个显著的标记-性状关联(MTAs),包括 30 个基因组区域上的 143 个 MTAs。这 30 个基因组区域包括在至少三个环境中鉴定到的 MTAs,其中 23 个是新的关联。这些 30 个基因组区域中的 MTAs 解释的表型变异范围为 6.68%至 11.42%。与纤维质量相关的大多数基因组区域都映射在 D 亚基因组上。此外,这项研究还证实了第 11 染色体上的多效性区域(UHML、FS 和 FU),并在第 04 染色体(FU、SFC)、第 05 染色体(UHML、FU 和第 06 染色体 UHML、FU)上鉴定出了新的共定位区域。标记单倍型分析确定了与纤维质量相关的基因组区域与高性状值(UHML=32.34 mm;FS=32.73 g tex;FE=6.75%)的优异组合。本研究中描述的性状、单倍型组合和候选基因的基因组分析可以帮助利用遗传多样性进行有针对性的遗传改良,并为棉花纤维质量性状的基因发现提供帮助。
