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赫氏疏螺旋体的抗原变异通过线性质粒上基因外重复元件之间的重组发生。

Antigenic variation by Borrelia hermsii occurs through recombination between extragenic repetitive elements on linear plasmids.

作者信息

Dai Qiyuan, Restrepo Blanca I, Porcella Stephen F, Raffel Sandra J, Schwan Tom G, Barbour Alan G

机构信息

Department of Microbiology, University of California Irvine, Irvine, CA, USA.

出版信息

Mol Microbiol. 2006 Jun;60(6):1329-43. doi: 10.1111/j.1365-2958.2006.05177.x.

DOI:10.1111/j.1365-2958.2006.05177.x
PMID:16796672
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5614446/
Abstract

The relapsing fever agent Borrelia hermsii undergoes multiphasic antigenic variation through gene conversion of a unique expression site on a linear plasmid by an archived variable antigen gene. To further characterize this mechanism we assessed the repertoire and organization of archived variable antigen genes by sequencing approximately 85% of plasmids bearing these genes. Most archived genes shared with the expressed gene a <or= 62 nucleotide (nt) region, the upstream homology sequence (UHS), that surrounded the start codon. The 59 archived variable antigen genes were arrayed in clusters with 13 repetitive, 214 nt long downstream homology sequence (DHS) elements distributed among them. A fourteenth DHS element was downstream of the expression locus. Informative nucleotide polymorphisms in UHS regions and DHS elements were applied to the analysis of the expression site of relapse serotypes from 60 infected mice in a prospective study. For most recombinations, the upstream crossover occurred in the UHS's second half, and the downstream crossover was in the DHS's second half. Usually the closest archival DHS element was used, but occasionally a more distant DHS was employed. The downstream extragenic crossover site in B. hermsii contrasts with the upstream [corrected] extragenic crossover site for antigenic variation in African trypanosomes.

摘要

回归热病原体赫氏疏螺旋体通过一个存档的可变抗原基因对线性质粒上独特表达位点的基因转换进行多相抗原变异。为了进一步表征这一机制,我们通过对携带这些基因的约85%的质粒进行测序,评估了存档可变抗原基因的种类和组织。大多数存档基因与表达基因共享一个≤62个核苷酸(nt)的区域,即围绕起始密码子的上游同源序列(UHS)。59个存档可变抗原基因成簇排列,其中有13个重复的、214 nt长的下游同源序列(DHS)元件分布在这些基因簇中。第14个DHS元件位于表达位点的下游。在一项前瞻性研究中,UHS区域和DHS元件中的信息性核苷酸多态性被应用于分析来自60只感染小鼠的回归血清型的表达位点。对于大多数重组,上游交叉发生在UHS的后半部分,下游交叉发生在DHS的后半部分。通常使用最接近的存档DHS元件,但偶尔也会使用更远的DHS元件。赫氏疏螺旋体中的下游基因外交叉位点与非洲锥虫抗原变异的上游[校正后]基因外交叉位点形成对比。

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