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一种多功能ABC转运蛋白(Opt)有助于乳酸球菌属内肽摄取特异性的多样性。

A multifunction ABC transporter (Opt) contributes to diversity of peptide uptake specificity within the genus Lactococcus.

作者信息

Lamarque Mauld, Charbonnel Pascale, Aubel Dominique, Piard Jean-Christophe, Atlan Danièle, Juillard Vincent

机构信息

Unité de Microbiologie et Génétique, CNRS UMR 5122, Université Lyon 1, Villeurbanne, France.

出版信息

J Bacteriol. 2004 Oct;186(19):6492-500. doi: 10.1128/JB.186.19.6492-6500.2004.

DOI:10.1128/JB.186.19.6492-6500.2004
PMID:15375130
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC516603/
Abstract

Growth of Lactococcus lactis in milk depends on the utilization of extracellular peptides. Up to now, oligopeptide uptake was thought to be due only to the ABC transporter Opp. Nevertheless, analysis of several Opp-deficient L. lactis strains revealed the implication of a second oligopeptide ABC transporter, the so-called Opt system. Both transporters are expressed in wild-type strains such as L. lactis SK11 and Wg2, whereas the plasmid-free strains MG1363 and IL-1403 synthesize only Opp and Opt, respectively. The Opt system displays significant differences from the lactococcal Opp system, which made Opt much more closely related to the oligopeptide transporters of streptococci than to the lactococcal Opp system: (i) genetic organization, (ii) peptide uptake specificity, and (iii) presence of two oligopeptide-binding proteins, OptS and OptA. The fact that only OptA is required for nutrition calls into question the function of the second oligopeptide binding protein (Opts). Sequence analysis of oligopeptide-binding proteins from different bacteria prompted us to propose a classification of these proteins in three distinct groups, differentiated by the presence (or not) of precisely located extensions.

摘要

乳酸乳球菌在牛奶中的生长依赖于细胞外肽的利用。到目前为止,寡肽摄取被认为仅归因于ABC转运蛋白Opp。然而,对几种Opp缺陷型乳酸乳球菌菌株的分析揭示了第二种寡肽ABC转运蛋白(即所谓的Opt系统)的作用。这两种转运蛋白在野生型菌株(如乳酸乳球菌SK11和Wg2)中均有表达,而无质粒菌株MG1363和IL-1403分别仅合成Opp和Opt。Opt系统与乳球菌Opp系统存在显著差异,这使得Opt与链球菌的寡肽转运蛋白的关系比与乳球菌Opp系统更为密切:(i)基因组织;(ii)肽摄取特异性;(iii)存在两种寡肽结合蛋白OptS和OptA。仅OptA是营养所必需的这一事实对第二种寡肽结合蛋白(OptS)的功能提出了质疑。对来自不同细菌的寡肽结合蛋白的序列分析促使我们提出将这些蛋白分为三个不同的组,根据是否存在精确定位的延伸进行区分。

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