Effective leaf rust resistance genes of wheat in Novosibirsk Province in connection with the variability of the Puccinia triticina population

Q4 Biochemistry, Genetics and Molecular Biology

Proceedings on Applied Botany, Genetics and Breeding Pub Date : 2023-07-26 DOI:10.30901/2227-8834-2023-2-235-244

L. P. Sochalova, N. Boyko, A. A. Poteshkina, V. Piskarev

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Abstract

Background. Information on the races of Puccinia triticina Erikss. in Novosibirsk Province is needed to identify sources of effective genes for leaf rust resistance. The goal hereof was monitoring genetic variability of the P. triticina population in the Ob riverside forest-steppe, Novosibirsk Province, and detecting effective resistance genes to develop wheat cultivars resistant to the disease. Materials and methods. In 2015–2019, affliction of Thatcher lines (Tc) and cultivars under the disease pressure was assessed, and P. triticina structure in the Ob forest-steppe of Novosibirsk Province was monitored. P. triticina genotypes were identified using the Long–Kolmer system. Additionally, a set of cultivars with the Lr19, Lr20, Lr28, Lr39; 6 – Lr6Agi2, Lr6Agi1, LrKu, andLrSp2 genes was employed. Results. A high frequency of virulence was detected for cultivars with the Lr3ka, Lr10, Lr1, Lr2a, Lr2c, Lr3a, Lr11, Lr18, Lr20, Lr30, Lr16, Lr17, and LrB genes (66.7–100 %). The P. triticina structure consisted of 27 races, including 12 common ones: TGTT GB, TGTR GB, TQTT GB, TQTR GB, TGPT GB, THFR GB, KHTT GB, PHKT GB, PQTT GB, THTP BB, PGFR GB, and SGPR GB. Genotypes with the Lr6Agi2, Lr6Agi1, LrKu, Lr39, Lr42, Lr12, Lr19, Lr24, Lr25, Lr28, Lr35, Lr45, Lr47, Lr50, Lr52, LrSp2, Lr6Agi1+Lr19, Lr6Agi2+Lr10+Lr34, Lr11+Lr13+Lr22a, Lr13+LrTb, Lr24+Lr26, Lr37+Lr13, Lr37+Lr1, Lr34+Lr13, Lr43+Lr24, and Lr49+Lr34 genes were resistant to P. triticina under the infection pressure. Some wheat genotypes varied in leaf rust resistance across the years (0–5 % for TcLr29 and TcLr21, 0–10 % for CSP 44 and TcLr44, 0–20 % for TcLr13, 1–30 % for TcLr37, and 15–80 % for Pavon F 76). Conclusion. The local leaf rust population has changed slightly over the years of study (the Lr18 and Lr38 genes have lost resistance), and was very different from the population before 2010.

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新西伯利亚省小麦有效抗叶锈病基因与黑麦锈病群体变异的关系

背景。关于普契尼亚的种族信息。需要在新西伯利亚省鉴定抗叶锈病有效基因的来源。本研究的目的是监测新西伯利亚鄂布河畔森林草原小黑麦群体的遗传变异，检测有效的抗性基因，以开发小麦抗病品种。材料和方法。2015-2019年，对撒切尔株系(Tc)和品种在病害压力下的受害情况进行了评估，并对新西伯利亚鄂毕尔森林草原小麦黑麦结构进行了监测。利用Long-Kolmer系统对小麦小麦进行基因型鉴定。此外，还培育了Lr19、Lr20、Lr28、Lr39;采用6 - Lr6Agi2、Lr6Agi1、LrKu和lrsp2基因。结果。携带Lr3ka、Lr10、Lr1、Lr2a、Lr2c、Lr3a、Lr11、Lr18、Lr20、Lr30、Lr16、Lr17和LrB基因的品种毒力较高(66.7 ~ 100%)。黑小麦结构由27个小种组成，其中常见的有TGTT GB、TGTR GB、TQTT GB、TQTR GB、TGPT GB、THFR GB、KHTT GB、PHKT GB、PQTT GB、THTP BB、PGFR GB和SGPR GB 12个小种。Lr6Agi2、Lr6Agi1、LrKu、Lr39、Lr42、Lr12、Lr19、Lr24、Lr25、Lr28、Lr35、Lr45、Lr47、Lr50、Lr52、LrSp2、Lr6Agi1+Lr19、Lr6Agi2+Lr10+Lr34、Lr11+Lr13+Lr22a、Lr13+LrTb、Lr24+Lr26、Lr37+Lr13、Lr37+Lr1、Lr34+Lr13、Lr43+Lr24和Lr49+Lr34基因型在感染压力下对小麦黑麦草具有抗性。一些小麦基因型的抗叶锈病能力在不同年份存在差异(TcLr29和TcLr21为0 - 5%，CSP 44和TcLr44为0 - 10%，TcLr13为0 - 20%，TcLr37为1 - 30%，Pavon f76为15 - 80%)。结论。当地叶锈病种群在多年的研究中略有变化(Lr18和Lr38基因已失去抗性)，与2010年之前的种群有很大不同。

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