{"title":"对抗Ug99 -目前的情况","authors":"A. Afzal, S. Ali, M. Ijaz, M. Saeed","doi":"10.33687/PHYTOPATH.010.01.3487","DOIUrl":null,"url":null,"abstract":"The yield potential of wheat crop is not achieved abundantly because of disease pressure. One of the most destructive of such diseases is stem rust (SR). SR caused by Puccinia graminis f. sp. tritici (Pgt), had been controlled successfully during three decades throughout the world with deployment of semi-dwarf resistant cultivars in the last half of previous century. During 1999 appearance and dispersion of stem rust race Ug-99 in Uganda (a virulent race against Sr31) created an alarming situation worldwide. Widespread germplasm was protected by gene Sr31 found susceptible to this terrible strain as the gene was protecting 80% wheat lines cultivated throughout planet. The emergence of the Ug99 race of stem rust in Africa and the Middle East together with the appearance of new strains in Europe catalyzed a main effort to recognize sources of stem rust resistance genes against new virulent strains and incorporate these genes into wheat lines. Scientific community addressed the dilemma in time and efforts did not go waste. Worldwide concern regarding the danger to global wheat production caused by Ug99 led to breeding wheat for durable resistance against disease and achieved considerably. This success is attributed to team work of experts and serves as an example for research workers in future. However, the continued emergence of stem rust variants that overcome new resistance genes, demands an amplified emphasis on pathogen evolution and virulence mechanisms. A major role for BGRI is to keep ‘the eye on the ball’ with regard to all these aspects. This article enables us to design strategy to tackle a situation which appears without alarm but in this case intellectuals coordinated each other and solution became possible. The same principle does not apply in plant pathology but in Human pathology and Veterinary pathology.","PeriodicalId":36106,"journal":{"name":"International Journal of Phytopathology","volume":"27 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2021-04-13","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":"{\"title\":\"Combating Ug99 - Current Scenario\",\"authors\":\"A. Afzal, S. Ali, M. Ijaz, M. Saeed\",\"doi\":\"10.33687/PHYTOPATH.010.01.3487\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"The yield potential of wheat crop is not achieved abundantly because of disease pressure. One of the most destructive of such diseases is stem rust (SR). SR caused by Puccinia graminis f. sp. tritici (Pgt), had been controlled successfully during three decades throughout the world with deployment of semi-dwarf resistant cultivars in the last half of previous century. During 1999 appearance and dispersion of stem rust race Ug-99 in Uganda (a virulent race against Sr31) created an alarming situation worldwide. Widespread germplasm was protected by gene Sr31 found susceptible to this terrible strain as the gene was protecting 80% wheat lines cultivated throughout planet. The emergence of the Ug99 race of stem rust in Africa and the Middle East together with the appearance of new strains in Europe catalyzed a main effort to recognize sources of stem rust resistance genes against new virulent strains and incorporate these genes into wheat lines. Scientific community addressed the dilemma in time and efforts did not go waste. Worldwide concern regarding the danger to global wheat production caused by Ug99 led to breeding wheat for durable resistance against disease and achieved considerably. This success is attributed to team work of experts and serves as an example for research workers in future. However, the continued emergence of stem rust variants that overcome new resistance genes, demands an amplified emphasis on pathogen evolution and virulence mechanisms. A major role for BGRI is to keep ‘the eye on the ball’ with regard to all these aspects. This article enables us to design strategy to tackle a situation which appears without alarm but in this case intellectuals coordinated each other and solution became possible. 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引用次数: 1
摘要
由于病害压力,小麦作物的产量潜力没有得到充分发挥。其中最具破坏性的病害是茎锈病(SR)。小麦锈病是由小麦锈病(Puccinia graminis f. sp. tritici, Pgt)引起的,近30年来,随着半矮抗品种的推广,小麦锈病在世界范围内得到了成功的控制。1999年,茎锈病种Ug-99在乌干达的出现和扩散(一种对抗Sr31的毒种)在世界范围内造成了令人担忧的局面。广泛分布的种质资源受到Sr31基因的保护,该基因对这种可怕的菌株敏感,因为该基因保护了全球80%的小麦品系。在非洲和中东出现的Ug99种茎锈病以及在欧洲出现的新菌株,促使人们努力识别抗茎锈病新毒株的基因来源,并将这些基因纳入小麦品系。科学界及时解决了这一难题,努力没有白费。全世界都关注Ug99对全球小麦生产造成的危险,从而培育出具有持久抗病能力的小麦,并取得了相当大的成就。这一成功归功于专家们的团队合作,并为未来的研究工作者提供了榜样。然而,克服新抗性基因的茎锈病变异体的不断出现,需要对病原体进化和毒力机制的进一步重视。BGRI的一个主要角色是在所有这些方面保持“关注球”。本文使我们能够设计策略来应对一种看似毫无预警的情况,但在这种情况下,知识分子相互协调,解决问题成为可能。同样的原则并不适用于植物病理学,但适用于人类病理学和兽医病理学。
The yield potential of wheat crop is not achieved abundantly because of disease pressure. One of the most destructive of such diseases is stem rust (SR). SR caused by Puccinia graminis f. sp. tritici (Pgt), had been controlled successfully during three decades throughout the world with deployment of semi-dwarf resistant cultivars in the last half of previous century. During 1999 appearance and dispersion of stem rust race Ug-99 in Uganda (a virulent race against Sr31) created an alarming situation worldwide. Widespread germplasm was protected by gene Sr31 found susceptible to this terrible strain as the gene was protecting 80% wheat lines cultivated throughout planet. The emergence of the Ug99 race of stem rust in Africa and the Middle East together with the appearance of new strains in Europe catalyzed a main effort to recognize sources of stem rust resistance genes against new virulent strains and incorporate these genes into wheat lines. Scientific community addressed the dilemma in time and efforts did not go waste. Worldwide concern regarding the danger to global wheat production caused by Ug99 led to breeding wheat for durable resistance against disease and achieved considerably. This success is attributed to team work of experts and serves as an example for research workers in future. However, the continued emergence of stem rust variants that overcome new resistance genes, demands an amplified emphasis on pathogen evolution and virulence mechanisms. A major role for BGRI is to keep ‘the eye on the ball’ with regard to all these aspects. This article enables us to design strategy to tackle a situation which appears without alarm but in this case intellectuals coordinated each other and solution became possible. The same principle does not apply in plant pathology but in Human pathology and Veterinary pathology.