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KtrB 膜区 M2C2 中的功能获得性突变打开了一个门控,控制了来自 Algino 溶藻弧菌的 KtrAB 系统的 K+转运。

Gain of function mutations in membrane region M2C2 of KtrB open a gate controlling K+ transport by the KtrAB system from Vibrio alginolyticus.

机构信息

Abteilung Mikrobiologie, University of Osnabrück, D-49076 Osnabrück, Germany.

出版信息

J Biol Chem. 2010 Apr 2;285(14):10318-27. doi: 10.1074/jbc.M109.089870. Epub 2010 Jan 22.

DOI:10.1074/jbc.M109.089870
PMID:20097755
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2856237/
Abstract

KtrB, the K(+)-translocating subunit of the Na(+)-dependent bacterial K(+) uptake system KtrAB, consists of four M(1)PM(2) domains, in which M(1) and M(2) are transmembrane helices and P indicates a p-loop that folds back from the external medium into the cell membrane. The transmembrane stretch M(2C) is, with its 40 residues, unusually long. It consists of three parts, the hydrophobic helices M(2C1) and M(2C3), which are connected by a nonhelical M(2C2) region, containing conserved glycine, alanine, serine, threonine, and lysine residues. Several point mutations in M(2C2) led to a huge gain of function of K(+) uptake by KtrB from the bacterium Vibrio alginolyticus. This effect was exclusively due to an increase in V(max) for K(+) transport. Na(+) translocation by KtrB was not affected. Partial to complete deletions of M(2C2) also led to enhanced V(max) values for K(+) uptake via KtrB. However, several deletion variants also exhibited higher K(m) values for K(+) uptake and at least one deletion variant, KtrB(Delta326-328), also transported Na(+) faster. The presence of KtrA did not suppress any of these effects. For the deletion variants, this was due to a diminished binding of KtrA to KtrB. PhoA studies indicated that M(2C2) forms a flexible structure within the membrane allowing M(2C3) to be directed either to the cytoplasm or (artificially) to the periplasm. These data are interpreted to mean (i) that region M(2C2) forms a flexible gate controlling K(+) translocation at the cytoplasmic side of KtrB, and (ii) that M(2C2) is required for the interaction between KtrA and KtrB.

摘要

KtrB 是 Na(+)-依赖的细菌 K(+)摄取系统 KtrAB 的 K(+)-转运亚基,由四个 M(1)PM(2)结构域组成,其中 M(1)和 M(2)是跨膜螺旋,P 表示从外部介质折叠回细胞膜的 p 环。跨膜伸展 M(2C)长 40 个残基,异常长。它由三个部分组成,疏水螺旋 M(2C1)和 M(2C3),由非螺旋 M(2C2)区域连接,该区域包含保守的甘氨酸、丙氨酸、丝氨酸、苏氨酸和赖氨酸残基。M(2C2)中的几个点突变导致来自弧菌 alginolyticus 的 KtrB 对 K(+)摄取的功能大大增强。这种效果仅归因于 K(+)转运的 V(max)增加。KtrB 的 Na(+)转运不受影响。M(2C2)的部分或完全缺失也导致通过 KtrB 摄取 K(+)的 V(max)值增加。然而,一些缺失变体也表现出更高的 K(m)值用于摄取 K(+),至少一种缺失变体 KtrB(Delta326-328)也更快地转运 Na(+)。KtrA 的存在没有抑制这些效应中的任何一个。对于缺失变体,这是由于 KtrA 与 KtrB 的结合减少。PhoA 研究表明,M(2C2)在膜内形成一个灵活的结构,允许 M(2C3)定向到细胞质或(人为地)到周质。这些数据的解释是(i)区域 M(2C2)形成一个灵活的门,控制 KtrB 细胞质侧的 K(+)转运,和(ii)M(2C2)是 KtrA 和 KtrB 之间相互作用所必需的。

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