RLP/K enrichment sequencing; a novel method to identify receptor‐like protein (RLP) and receptor‐like kinase (RLK) genes

The New phytologist Pub Date : 2020-02-26 DOI:10.1101/2020.02.26.966085

Xiao Lin, M. Armstrong, Katie Baker, D. Wouters, R. Visser, P. J. Wolters, I. Hein, V. Vleeshouwers

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引用次数: 22

Abstract

The identification of immune receptors in crop plants is time-consuming but important for disease control. Previously, resistance gene enrichment sequencing (RenSeq) was developed to accelerate mapping of nucleotide-binding domain and leucine-rich repeat containing (NLR) genes. However, resistances mediated by pattern recognition receptors (PRRs) remain less utilised. Here, our pipeline shows accelerated mapping of PRRs. Effectoromics leads to precise identification of plants with target PRRs, and subsequent RLP/K enrichment sequencing (RLP/KSeq) leads to detection of informative SNPs that are linked to the trait. Using Phytophthora infestans as a model, we identified Solanum microdontum plants that recognize the apoplastic effectors INF1 or SCR74. RLP/KSeq in a segregating Solanum population confirmed the localization of the INF1 receptor on chromosome 12, and lead to the rapid mapping of the response to SCR74 to chromosome 9. By using markers obtained from RLP/KSeq in conjunction with additional markers, we fine-mapped the SCR74 receptor to a 43-kbp G-LecRK locus. Our findings show that RLP/KSeq enables rapid mapping of PRRs and is especially beneficial for crop plants with large and complex genomes. This work will enable the elucidation and characterisation of the non-NLR plant immune receptors and ultimately facilitate informed resistance breeding.

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RLP/K富集测序;一种鉴定受体样蛋白(RLP)和受体样激酶(RLK)基因的新方法

农作物免疫受体的鉴定耗时长，但对病害防治具有重要意义。此前，抗性基因富集测序(RenSeq)被开发用于加速核苷酸结合域和富含亮氨酸重复序列(NLR)基因的定位。然而，由模式识别受体(PRRs)介导的抗性仍然较少利用。这里，我们的管道显示了PRRs的加速映射。效应组学可以精确地鉴定出具有目标PRRs的植物，随后的RLP/K富集测序(RLP/KSeq)可以检测到与该性状相关的信息性snp。以疫霉菌为模型，我们发现了能识别胞外效应因子INF1或SCR74的小齿茄植物。在分离的龙葵群体中，RLP/KSeq证实了INF1受体在12号染色体上的定位，并导致对SCR74的反应快速定位到9号染色体上。通过使用从RLP/KSeq获得的标记以及其他标记，我们将SCR74受体精细定位到43 kbp的G-LecRK位点。我们的研究结果表明，RLP/KSeq能够快速定位PRRs，对具有大而复杂基因组的作物植物尤其有益。这项工作将有助于阐明和鉴定非nlr植物免疫受体，并最终促进知情的抗性育种。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The New phytologist

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