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肉座菌(Nectria haematococca)的携带与豌豆致病性相关基因的额外染色体也携带豌豆根际竞争力的性状。

The supernumerary chromosome of Nectria haematococca that carries pea-pathogenicity-related genes also carries a trait for pea rhizosphere competitiveness.

作者信息

Rodriguez-Carres M, White G, Tsuchiya D, Taga M, VanEtten H D

机构信息

Division of Plant Pathology and Microbiology, Department of Plant Sciences, University of Arizona, Tucson, AZ 85721, USA.

出版信息

Appl Environ Microbiol. 2008 Jun;74(12):3849-56. doi: 10.1128/AEM.00351-08. Epub 2008 Apr 11.

DOI:10.1128/AEM.00351-08
PMID:18408061
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2446569/
Abstract

Fungi are found in a wide range of environments, and the ecological and host diversity of the fungus Nectria haematococca has been shown to be due in part to unique genes on different supernumerary chromosomes. These chromosomes have been called "conditionally dispensable" (CD) since they are not needed for axenic growth but are important for expanding the host range of individual isolates. From a biological perspective, the CD chromosomes can be compared to bacterial plasmids that carry unique genes that can define the habits of these microorganisms. The current study establishes that the N. haematococca PDA1-CD chromosome, which contains the genes for pea pathogenicity (PEP cluster) on pea roots, also carries a gene(s) for the utilization of homoserine, a compound found in large amounts in pea root exudates. Competition studies demonstrate that an isolate that lacks the PEP cluster but carries a portion of the CD chromosome which includes the homoserine utilization (HUT) gene(s) is more competitive in the pea rhizosphere than an isolate without the CD chromosome.

摘要

真菌存在于广泛的环境中,血座壳菌(Nectria haematococca)的生态和宿主多样性已被证明部分归因于不同超数染色体上的独特基因。这些染色体被称为“条件性可缺失”(CD)染色体,因为它们对于在无菌条件下生长并非必需,但对于扩大单个分离株的宿主范围很重要。从生物学角度来看,CD染色体可与携带独特基因的细菌质粒相比较,这些独特基因能够界定这些微生物的习性。当前研究表明,血座壳菌的PDA1 - CD染色体,其在豌豆根上含有豌豆致病性基因(PEP簇),还携带一个利用高丝氨酸的基因,高丝氨酸是在豌豆根分泌物中大量存在的一种化合物。竞争研究表明,一个缺乏PEP簇但携带包括高丝氨酸利用(HUT)基因的部分CD染色体的分离株,在豌豆根际比一个没有CD染色体的分离株更具竞争力。

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