Abstract
SummaryThe Tat protein export system translocates folded proteins across the bacterial cytoplasmic membrane and the plant thylakoid membrane. The Tat system in E scherichia coli is composed of TatA, TatB and TatC proteins. TatB and TatC form an oligomeric, multivalent receptor complex that binds Tat substrates, while multiple protomers of TatA assemble at substrate‐bound TatBC receptors to facilitate substrate transport. We have addressed whether oligomerisation of TatC is an absolute requirement for operation of the Tat pathway by screening for dominant negative alleles of tatC that inactivate Tat function in the presence of wild‐type tatC. Single substitutions that confer dominant negative TatC activity were localised to the periplasmic cap region. The variant TatC proteins retained the ability to interact with TatB and with a Tat substrate but were unable to support the in vivo assembly of TatA complexes. Blue‐native PAGE analysis showed that the variant TatC proteins produced smaller TatBC complexes than the wild‐type TatC protein. The substitutions did not alter disulphide crosslinking to neighbouring TatC molecules from positions in the periplasmic cap but abolished a substrate‐induced disulphide crosslink in transmembrane helix 5 of TatC. Our findings show that TatC functions as an obligate oligomer.
Highlights
The targeting of proteins to their sites of cellular function is an essential process that is carried out by conserved protein sorting and translocation machineries
The Tat system in Escherichia coli is composed of TatA, TatB and TatC proteins
We have addressed whether oligomerisation of TatC is an absolute requirement for operation of the Tat pathway by screening for dominant negative alleles of tatC that inactivate Tat function in the presence of wild-type tatC
Summary
The targeting of proteins to their sites of cellular function is an essential process that is carried out by conserved protein sorting and translocation machineries. The TatA protein is found as small homomultimeric units that assemble into larger oligomers driven by the protonmotive force and interaction with the substratebound TatBC complex (Mori and Cline, 2002; Alami et al, 2003; Dabney-Smith et al, 2006; Leake et al, 2008; Alcock et al, 2013; Rose et al, 2013).
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