Dept. of Crop Science, North Carolina State University, Box 7620, Raleigh, NC 27695.
Dupont-Pioneer 7300 NW 62 Avenue P.O Box 1004 Johnston, IA, 50131-1004.
G3 (Bethesda). 2019 Jan 9;9(1):189-201. doi: 10.1534/g3.118.200866.
Southern Leaf Blight (SLB), Northern Leaf Blight (NLB), and Gray Leaf Spot (GLS) caused by , , and respectively, are among the most important diseases of corn worldwide. Previously, moderately high and significantly positive genetic correlations between resistance levels to each of these diseases were identified in a panel of 253 diverse maize inbred lines. The goal of this study was to identify loci underlying disease resistance in some of the most multiple disease resistant (MDR) lines by the creation of chromosome segment substitution line (CSSL) populations in multiple disease susceptible (MDS) backgrounds. Four MDR lines (NC304, NC344, Ki3, NC262) were used as donor parents and two MDS lines (Oh7B, H100) were used as recurrent parents to produce eight BCF CSSL populations comprising 1,611 lines in total. Each population was genotyped and assessed for each disease in replicated trials in two environments. Moderate to high heritabilities on an entry mean basis were observed (0.32 to 0.83). Several lines in each population were significantly more resistant than the MDS parental lines for each disease. Multiple quantitative trait loci (QTL) for disease resistance were detected for each disease in most of the populations. Seventeen QTL were associated with variation in resistance to more than one disease (SLB/NLB: 2; SLB/GLS: 7; NLB/GLS: 2 and 6 to all three diseases). For most populations and most disease combinations, significant correlations were observed between disease scores and also between marker effects for each disease. The number of lines that were resistant to more than one disease was significantly higher than would be expected by chance. Using the results from individual QTL analyses, a composite statistic based on Mahalanobis distance () was used to identify joint marker associations with multiple diseases. Across all populations and diseases, 246 markers had significant values. However further analysis revealed that most of these associations were due to strong QTL effects on a single disease. Together, these findings reinforce our previous conclusions that loci associated with resistance to different diseases are clustered in the genome more often than would be expected by chance. Nevertheless true MDR loci which have significant effects on more than one disease are still much rarer than loci with single disease effects.
南方叶枯病(SLB)、北方叶枯病(NLB)和灰斑病(GLS)分别由 、 和 引起,是全球玉米最重要的病害之一。此前,在一个由 253 个不同的玉米自交系组成的群体中,发现了这些疾病的抗性水平之间存在中度高和显著正的遗传相关性。本研究的目的是通过在多个易感(MDS)背景下创建染色体片段替换系(CSSL)群体,来鉴定一些多病害抗性(MDR)系中疾病抗性的基因座。四个 MDR 系(NC304、NC344、Ki3、NC262)被用作供体亲本,两个 MDS 系(Oh7B、H100)被用作轮回亲本,共产生了 8 个 BCF CSSL 群体,总计 1611 个系。每个群体都进行了基因型鉴定,并在两个环境中进行了重复试验,评估了每个疾病的抗性。在入口平均值基础上观察到中度到高度的遗传力(0.32 到 0.83)。每个群体中都有多个系比 MDS 亲本系对每种疾病的抗性显著更高。在大多数群体中,每个疾病都检测到多个数量性状基因座(QTL)与抗性变异相关。17 个 QTL 与一种以上疾病的抗性变异有关(SLB/NLB:2;SLB/GLS:7;NLB/GLS:2 和 6 与所有三种疾病有关)。对于大多数群体和大多数疾病组合,观察到疾病评分之间以及每个疾病的标记效应之间存在显著相关性。对多种疾病具有抗性的系的数量明显高于预期的随机数量。利用单个 QTL 分析的结果,基于马氏距离()的综合统计量用于识别与多种疾病相关的联合标记关联。在所有群体和疾病中,有 246 个标记具有显著的 值。然而,进一步的分析表明,这些关联大多是由于单个疾病上的强 QTL 效应所致。总之,这些发现强化了我们之前的结论,即与不同疾病抗性相关的基因座在基因组中聚集的频率高于预期的随机频率。然而,对多种疾病具有显著影响的真正 MDR 基因座仍然比具有单一疾病效应的基因座要罕见得多。
