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溶血素分泌1型转运体的组成部分HlyD发生突变，会影响分泌毒素的折叠。

Mutations in HlyD, part of the type 1 translocator for hemolysin secretion, affect the folding of the secreted toxin.

作者信息

Pimenta A L, Racher K, Jamieson L, Blight M A, Holland I B

机构信息

Université de Cergy Pontoise, Department of Biology, ERRMECe, 2 Av. Adolphe Chauvin, 95302Cergy-Pontoise cedex, France.

出版信息

J Bacteriol. 2005 Nov;187(21):7471-80. doi: 10.1128/JB.187.21.7471-7480.2005.

DOI:10.1128/JB.187.21.7471-7480.2005

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1272971/

Abstract

HlyD, a member of the membrane fusion protein family, is essential for the secretion of the RTX hemolytic toxin HlyA from Escherichia coli. Random point mutations affecting HlyA secretion were obtained, distributed in most periplasmic regions of the HlyD molecule. Analysis of the secretion phenotypes of different mutants allowed the identification of regions in HlyD involved in different steps of HlyA translocation. Four mutants, V349-I, T85-I, V334-I and L165-Q, were conditionally defective, a phenotype shown to be linked to the presence of inhibitory concentrations of Ca2+ in extracellular medium. Hly mutant T85-I was defective at an early stage in secretion, while mutants V334-I and L165-Q appeared to accumulate HlyA in the cell envelope, indicating a block at an intermediate step. Mutants V349-I, V334-I, and L165-Q were only partially defective in secretion, allowing significant levels of HlyA to be transported, but in the case of V349-I and L165-Q the HlyA molecules secreted showed greatly reduced hemolytic activity. Hemolysin molecules secreted from V349-I and V334-I are defective in normal folding and can be reactivated in vitro to the same levels as HlyA secreted from the wild-type translocator. Both V349-I and V334-I mutations mapped to the C-terminal lipoyl repeat motif, involved in the switching from the helical hairpin to the extended form of HlyD during assembly of the functional transport channel. These results suggest that HlyD is an integral component of the transport pathway, whose integrity is essential for the final folding of secreted HlyA into its active form.

摘要

HlyD是膜融合蛋白家族的成员，对大肠杆菌RTX溶血毒素HlyA的分泌至关重要。获得了影响HlyA分泌的随机点突变，这些突变分布在HlyD分子的大多数周质区域。通过分析不同突变体的分泌表型，确定了HlyD中参与HlyA转运不同步骤的区域。四个突变体V349-I、T85-I、V334-I和L165-Q存在条件性缺陷，这种表型与细胞外培养基中抑制浓度的Ca2+的存在有关。Hly突变体T85-I在分泌早期存在缺陷，而突变体V334-I和L165-Q似乎在细胞膜中积累了HlyA，表明在中间步骤受阻。突变体V349-I、V334-I和L165-Q在分泌方面仅存在部分缺陷，允许大量HlyA被转运，但就V349-I和L165-Q而言，分泌的HlyA分子溶血活性大大降低。从V349-I和V334-I分泌的溶血素分子在正常折叠方面存在缺陷，并且可以在体外重新激活至与野生型转运体分泌的HlyA相同的水平。V349-I和V334-I突变均位于C末端硫辛酰重复基序，该基序在功能性转运通道组装过程中参与HlyD从螺旋发夹结构转变为伸展形式。这些结果表明，HlyD是转运途径的一个组成部分，其完整性对于分泌的HlyA最终折叠成其活性形式至关重要。