非连续二硫键在必需的完整外膜蛋白中的形成。
Nonconsecutive disulfide bond formation in an essential integral outer membrane protein.
机构信息
Department of Molecular Biology, Princeton University, Princeton, NJ 08544, USA.
出版信息
Proc Natl Acad Sci U S A. 2010 Jul 6;107(27):12245-50. doi: 10.1073/pnas.1007319107. Epub 2010 Jun 21.
Abstract
The Gram-negative bacterial envelope is bounded by two membranes. Disulfide bond formation and isomerization in this oxidizing environment are catalyzed by DsbA and DsbC, respectively. It remains unknown when and how the Dsb proteins participate in the biogenesis of outer membrane proteins, which are transported across the cell envelope after their synthesis. The Escherichia coli protein LptD is an integral outer membrane protein that forms an essential complex with the lipoprotein LptE. We show that oxidation of LptD is not required for the formation of the LptD/E complex but it is essential for function. Remarkably, none of the cysteines in LptD are essential because either of two nonconsecutive disulfide bonds suffices for function. Oxidation of LptD, which is efficiently catalyzed by DsbA, does not involve the isomerase DsbC, but it requires LptE. Thus, oxidation is completed only after LptD interacts with LptE, an interaction that occurs at the outer membrane and seems necessary for LptD folding.
摘要
革兰氏阴性细菌的包膜由两层膜组成。在这个氧化环境中,二硫键的形成和异构化分别由 DsbA 和 DsbC 催化。目前尚不清楚 Dsb 蛋白何时以及如何参与外膜蛋白的生物发生,这些蛋白在合成后被转运穿过细胞包膜。大肠杆菌蛋白 LptD 是一种完整的外膜蛋白,它与脂联蛋白 LptE 形成一个必需的复合物。我们发现,LptD 的氧化对于 LptD/E 复合物的形成不是必需的,但对于功能却是必需的。值得注意的是,LptD 中的任何一个半胱氨酸都不是必需的,因为两个非连续的二硫键中的任何一个都足以发挥功能。LptD 的氧化由 DsbA 高效催化,不需要异构酶 DsbC,但需要 LptE。因此,只有在 LptD 与 LptE 相互作用后,氧化才能完成,这种相互作用发生在外膜上,似乎对 LptD 的折叠是必要的。
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