Amadu Manigben Kulai, Beyene Yoseph, Chaikam Vijay, Tongoona Pangirayi B, Danquah Eric Y, Ifie Beatrice E, Burgueno Juan, Prasanna Boddupalli M, Gowda Manje
International Maize and Wheat Improvement Center (CIMMYT), C/O: World Agroforestry Centre (ICRAF), United Nations Avenue, Gigiri, P.O. Box, Nairobi, 1041-00621, Kenya.
West Africa Centre for Crop Improvement (WACCI), University of Ghana, PMB 30 Legon, Accra, Ghana.
BMC Plant Biol. 2025 Feb 1;25(1):135. doi: 10.1186/s12870-025-06135-3.
Drought is a major abiotic stress in sub-Saharan Africa, impacting maize growth and development leading to severe yield loss. Drought tolerance is a complex trait regulated by multiple genes, making direct grain yield selection ineffective. To dissect the genetic architecture of grain yield and flowering traits under drought stress, a genome-wide association study (GWAS) was conducted on a panel of 236 maize lines testcrossed and evaluated under managed drought and optimal growing conditions in multiple environments using seven multi-locus GWAS models (mrMLM, FASTmrMLM, FASTmrEMMA, pLARmEB, pKWmEB, ISIS EM-BLASSO, and FARMCPU) from mrMLM and GAPIT R packages. Genomic prediction with RR-BLUP model was applied on BLUEs across locations under optimum and drought conditions.
A total of 172 stable and reliable quantitative trait nucleotides (QTNs) were identified, of which 77 are associated with GY, AD, SD, ASI, PH, EH, EPO and EPP under drought and 95 are linked to GY, AD, SD, ASI, PH, EH, EPO and EPP under optimal conditions. Among these QTNs, 17 QTNs explained over 10% of the phenotypic variation (R ≥ 10%). Furthermore, 43 candidate genes were discovered and annotated. Two major candidate genes, Zm00001eb041070 closely associated with grain yield near peak QTN, qGY_DS1.1 (S1_216149215) and Zm00001eb364110 closely related to anthesis-silking interval near peak QTN, qASI_DS8.2 (S8_167256316) were identified, encoding AP2-EREBP transcription factor 60 and TCP-transcription factor 20, respectively under drought stress. Haplo-pheno analysis identified superior haplotypes for qGY_DS1.1 (S1_216149215) associated with the higher grain yield under drought stress. Genomic prediction revealed moderate to high prediction accuracies under optimum and drought conditions.
The lines carrying superior haplotypes can be used as potential donors in improving grain yield under drought stress. Integration of genomic selection with GWAS results leads not only to an increase in the prediction accuracy but also to validate the function of the identified candidate genes as well increase in the accumulation of favorable alleles with minor and major effects in elite breeding lines. This study provides valuable insight into the genetic architecture of grain yield and secondary traits under drought stress.
干旱是撒哈拉以南非洲地区主要的非生物胁迫因素,影响玉米的生长发育,导致严重的产量损失。耐旱性是一个由多个基因调控的复杂性状,直接选择籽粒产量效果不佳。为剖析干旱胁迫下籽粒产量和开花性状的遗传结构,利用mrMLM和GAPIT R软件包中的7种多位点全基因组关联研究(GWAS)模型(mrMLM、FASTmrMLM、FASTmrEMMA、pLARmEB、pKWmEB、ISIS EM-BLASSO和FARMCPU),对236个玉米自交系的测交群体在多个环境的可控干旱和最佳生长条件下进行了测试和评估。采用RR-BLUP模型对最佳和干旱条件下不同地点的最佳线性无偏估计值(BLUEs)进行基因组预测。
共鉴定出172个稳定可靠的数量性状核苷酸(QTN),其中77个与干旱条件下的籽粒产量(GY)、抽雄期(AD)、散粉期(SD)、抽雄-吐丝间隔(ASI)、株高(PH)、穗位高(EH)、出籽率(EPO)和单穗粒重(EPP)相关,95个与最佳条件下的这些性状相关。在这些QTN中,17个QTN解释了超过10%的表型变异(R≥10%)。此外,还发现并注释了43个候选基因。在干旱胁迫下,鉴定出两个主要候选基因,Zm00001eb041070与峰值QTN qGY_DS1.1(S1_216149215)附近的籽粒产量密切相关,Zm00001eb364110与峰值QTN qASI_DS8.2(S8_167256316)附近的抽雄-吐丝间隔密切相关,分别编码AP2-EREBP转录因子60和TCP转录因子20。单倍型-表型分析确定了干旱胁迫下与较高籽粒产量相关联的qGY_DS1.1(S1_216149215)的优良单倍型。基因组预测显示在最佳和干旱条件下具有中等到较高的预测准确性。
携带优良单倍型的品系可作为提高干旱胁迫下籽粒产量的潜在供体。将基因组选择与GWAS结果相结合,不仅提高了预测准确性,还验证了已鉴定候选基因的功能,并增加了优良育种系中微效和主效有利等位基因的积累。本研究为干旱胁迫下籽粒产量和次要性状的遗传结构提供了有价值的见解。
