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Analysis of the Abnormal Segregation of Pathogenicity in Magnaporthe grisea by Using a Genetic Cross of Oryza and Eleusine Isolates 被引量:3

Analysis of the Abnormal Segregation of Pathogenicity in Magnaporthe grisea by Using a Genetic Cross of Oryza and Eleusine Isolates
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摘要 A genetic cross between Oryza isolate Y93-164a-1 and Eleusine isolate SA98-4 was established, and the pathogenicity of 151 F1 progeny isolates was investigated on both host plants rice and finger millet. Results showed that the segregation of pathogenicity in this genetic cross was abnormal, i.e., most of the progeny isolates were nonpathogenic on both host plants. However, no abnormal segregation was observed when middle repetitive sequence MGR586 and 31 single-copy RFLP markers from all of the chromosomes were genetically analyzed. At the same time, comparison of the chromosomal organization among two pairs of parental isolates did not find any genomic abnormity. These results suggested that the "abnormal" inheritance of pathogenicity in this cross was most likely due to the reassortment of numerous host species specificity genes but not the biased segregation of the host species specificity genes. The host species specificities in M. grisea were likely to be multigenically controlled, at least in the genetic cross involving rice pathogen and the grasses pathogen other than rice. A genetic cross between Oryza isolate Y93-164a-1 and Eleusine isolate SA98-4 was established, and the pathogenicity of 151 F1 progeny isolates was investigated on both host plants rice and finger millet. Results showed that the segregation of pathogenicity in this genetic cross was abnormal, i.e., most of the progeny isolates were nonpathogenic on both host plants. However, no abnormal segregation was observed when middle repetitive sequence MGR586 and 31 single-copy RFLP markers from all of the chromosomes were genetically analyzed. At the same time, comparison of the chromosomal organization among two pairs of parental isolates did not find any genomic abnormity. These results suggested that the "abnormal" inheritance of pathogenicity in this cross was most likely due to the reassortment of numerous host species specificity genes but not the biased segregation of the host species specificity genes. The host species specificities in M. grisea were likely to be multigenically controlled, at least in the genetic cross involving rice pathogen and the grasses pathogen other than rice.
作者 YIN Liang-fen LUO Chao-xi Kusaba Motoaki Yaegashi Hiroshi
机构地区 Department of Plant Pathology Key Lab of Crop Disease Monitoring & Safety Control in Hubei Province Faculty of Agriculture
出处 《Agricultural Sciences in China》 CAS CSCD 2010年第3期383-391,共9页 中国农业科学(英文版)
基金 supported by a project (11660050) from the Ministry of Education, Culture, Sports, Science Technology of Japan and the project of the Scientific Research Foundation for the Returned Overseas Chinese Scholars, Huazhong Agricultural University, China(4002-30541)
关键词 Magnaporthe grisea rice blast fungus host species specificity PATHOGENICITY contour-clamped homogeneous electric field (CHEF) electrophoresis Southern hybridization Magnaporthe grisea, rice blast fungus, host species specificity, pathogenicity, contour-clamped homogeneous electric field (CHEF) electrophoresis, Southern hybridization
分类号 S511.035.1 [农业科学—作物学] TV6 [水利工程—水利水电工程]
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参考文献19

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同被引文献22

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Agricultural Sciences in China
2010年 第3期

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