大豆地方品种 PI 567139B 中两个抗大豆疫霉菌基因的分子作图

Molecular mapping of two genes conferring resistance to Phytophthora sojae in a soybean landrace PI 567139B.

机构信息

Department of Agronomy, Purdue University, West Lafayette, IN 47907, USA.

出版信息

Theor Appl Genet. 2013 Aug;126(8):2177-85. doi: 10.1007/s00122-013-2127-4. Epub 2013 May 21.

Abstract

Phytophthora root and stem rot (PRR), caused by the soil-borne oomycete pathogen Phytophthora sojae, is one of the most destructive diseases of soybean. PRR can be effectively controlled by race-specific genes conferring resistance to P. sojae (Rps). However, the Rps genes are usually non-durable, as populations of P. sojae are highly diverse and quick to adapt, and can be overcome 8-15 years after deployment. Thus, it is important to identify novel Rps genes for development of resistant soybean cultivars. PI 567139B is a soybean landrace carrying excellent resistance to nearly all predominant P. sojae races in Indiana. A mapping population consisting of 245 F2 individuals and 403 F2:3 families was developed from a cross between PI 567139B and the susceptible cultivar 'Williams', and used to dissect the resistance carried by PI 567139B. We found that the resistance in PI 567139B was conferred by two independent Rps genes, designated RpsUN1 and RpsUN2. The former was mapped to a 6.5 cM region between SSR markers Satt159 and BARCSOYSSR_03_0250 that spans the Rps1 locus on chromosome 3, while the latter was mapped to a 3.0 cM region between BARCSOYSSR_16_1275 and Sat_144, approximately 3.0-3.4 cM upstream of Rps2 on chromosome 16. According to the 'Williams 82' reference genome sequence, both regions are highly enriched with NBS-LRR genes. Marker assisted resistance spectrum analyses of these genes with 16 isolates of P. sojae, in combination with the mapping results, suggested that RpsUN1 was likely to be a novel allele at the Rps1 locus, while RpsUN2 was more likely to be a novel Rps gene.

摘要

大豆疫霉根腐和茎腐病（PRR）由土传卵菌病原体大豆疫霉引起，是大豆最具破坏性的疾病之一。PRR 可以通过赋予对 P. sojae（Rps）抗性的特异性基因来有效控制。然而，Rps 基因通常是不可持久的，因为 P. sojae 种群高度多样化且适应迅速，并且在部署后 8-15 年内就可以被克服。因此，鉴定用于开发抗大豆品种的新型 Rps 基因非常重要。PI 567139B 是一种携带对印第安纳州几乎所有主要 P. sojae 种群优异抗性的大豆地方品种。从 PI 567139B 和易感品种“Williams”之间的杂交中，开发了一个由 245 个 F2 个体和 403 个 F2:3 家系组成的作图群体，用于剖析 PI 567139B 携带的抗性。我们发现 PI 567139B 的抗性由两个独立的 Rps 基因赋予，分别命名为 RpsUN1 和 RpsUN2。前者被映射到 SSR 标记 Satt159 和 BARCSOYSSR_03_0250 之间的 6.5 cM 区域，该区域跨越染色体 3 上的 Rps1 基因座，而后者被映射到 BARCSOYSSR_16_1275 和 Sat_144 之间的 3.0 cM 区域，大约在染色体 16 上的 Rps2 上游 3.0-3.4 cM。根据“Williams 82”参考基因组序列，这两个区域都高度富含 NBS-LRR 基因。用 16 个大豆疫霉菌分离株对这些基因进行标记辅助抗性谱分析，并结合作图结果表明，RpsUN1 可能是 Rps1 基因座的一个新等位基因，而 RpsUN2 更可能是一个新的 Rps 基因。

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大豆地方品种 PI 567139B 中两个抗大豆疫霉菌基因的分子作图

Molecular mapping of two genes conferring resistance to Phytophthora sojae in a soybean landrace PI 567139B.

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