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根瘤菌属菌株NGR234基因组中复杂重复元件NGRRS-1的结构与进化

Structure and evolution of NGRRS-1, a complex, repeated element in the genome of Rhizobium sp. strain NGR234.

作者信息

Perret X, Viprey V, Freiberg C, Broughton W J

机构信息

Laboratoire de Biologie Moleculaire de Plantes Supérieures, University of Geneva, Switzerland.

出版信息

J Bacteriol. 1997 Dec;179(23):7488-96. doi: 10.1128/jb.179.23.7488-7496.1997.

DOI:10.1128/jb.179.23.7488-7496.1997
PMID:9393715
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC179701/
Abstract

Much of the remarkable ability of Rhizobium sp. strain NGR234 to nodulate at least 110 genera of legumes, as well as the nonlegume Parasponia andersonii, stems from the more than 80 different Nod factors it secretes. Except for nodE, nodG, and nodPQ, which are on the chromosome, most Nod factor biosynthesis genes are dispersed over the 536,165-bp symbiotic plasmid, pNGR234a. Mosaic sequences and insertion sequences (ISs) comprise 18% of pNGR234a. Many of them are clustered, and these IS islands divide the replicon into large blocks of functionally related genes. At 6 kb, NGRRS-1 is a striking example: there is one copy on pNGR234a and three others on the chromosome. DNA sequence comparisons of two NGRRS-1 elements identified three types of IS, NGRIS-2, NGRIS-4, and NGRIS-10. Here we show that all four copies of NGRRS-1 probably originated from transposition of NGRIS-4 into a more ancient IS-like sequence, NGRIS-10. Remarkably, all nine copies of NGRIS-4 have transposed into other ISs. It is unclear whether the accumulation of potentially mutagenic sequences in large clusters is due to the nature of the IS involved or to some selection process. Nevertheless, a direct consequence of the preferential targeting of transposons into such IS islands is to minimize the likelihood of disrupting vital functions.

摘要

根瘤菌属NGR234菌株具有非凡的能力,能够与至少110个豆科属植物以及非豆科植物安德森帕拉豆形成根瘤,这很大程度上源于它分泌的80多种不同的结瘤因子。除了位于染色体上的nodE、nodG和nodPQ外,大多数结瘤因子生物合成基因分散在536,165碱基对的共生质粒pNGR234a上。镶嵌序列和插入序列(ISs)占pNGR234a的18%。其中许多是成簇的,这些IS岛将复制子分成功能相关基因的大区域。NGRRS - 1长6 kb,是一个显著的例子:在pNGR234a上有一个拷贝,在染色体上还有另外三个拷贝。对两个NGRRS - 1元件的DNA序列比较确定了三种类型的IS元件,即NGRIS - 2、NGRIS - 4和NGRIS - 10。我们在此表明,NGRRS - 1的所有四个拷贝可能都起源于NGRIS - 4转座到一个更古老的类IS序列NGRIS - 10中。值得注意的是,NGRIS - 4的所有九个拷贝都已转座到其他IS元件中。尚不清楚大簇中潜在诱变序列的积累是由于所涉及的IS元件的性质还是某种选择过程。然而,转座子优先靶向此类IS岛的直接结果是将破坏重要功能的可能性降至最低。

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