豌豆壳二孢菌中角质酶基因的破坏降低了其对豌豆的毒力。
Cutinase gene disruption in Fusarium solani f sp pisi decreases its virulence on pea.
作者信息
Rogers L M, Flaishman M A, Kolattukudy P E
机构信息
Ohio State Biotechnology Center, Ohio State University, Columbus 43210-1002.
出版信息
Plant Cell. 1994 Jul;6(7):935-45. doi: 10.1105/tpc.6.7.935.
Abstract
Fusarium solani f sp pisi (Nectria haematococca) isolate 77-2-3 with one cutinase gene produced 10 to 20% of the cutinase produced by isolate T-8 that has multiple cutinase genes, whereas cutinase gene-disrupted mutant 77-102 of isolate 77-2-3 did not produce cutinase. On the surface of pea stem segments, lesion formation was most frequent and most severe with T-8, less frequent and less severe with 77-2-3, and much less frequent and much milder with the gene-disrupted mutant. Microscopic examination of the lesions caused by the mutant strongly suggest that it penetrated the host mostly via the stomata. In seedling assays, 77-2-3 caused severe lesions on every seedling and stunted growth, whereas the mutant showed very mild lesions on one-third of the seedlings with no stunting. Thus, cutinase gene disruption resulted in a significant decrease in the pathogenicity of F. s. pisi on pea.
摘要
携带一个角质酶基因的豌豆镰刀菌(血红色丛赤壳菌)分离株77-2-3所产生的角质酶量,是携带多个角质酶基因的分离株T-8所产生角质酶量的10%至20%,而分离株77-2-3的角质酶基因破坏突变体77-102不产生角质酶。在豌豆茎段表面,T-8形成病斑的频率最高且最为严重,77-2-3形成病斑的频率和严重程度较低,而基因破坏突变体形成病斑的频率低得多且程度轻得多。对该突变体所引起病斑的显微镜检查有力地表明,它主要通过气孔侵入宿主。在幼苗试验中,77-2-3在每株幼苗上都引起严重病斑并导致生长受阻,而该突变体在三分之一的幼苗上仅表现出非常轻微的病斑,且没有生长受阻现象。因此,角质酶基因的破坏导致豌豆镰刀菌对豌豆的致病性显著降低。
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