Abstract
Redox enzyme maturation proteins (REMPs) bind pre-proteins destined for translocation across the bacterial cytoplasmic membrane via the twin-arginine translocation system and enable the enzymatic incorporation of complex cofactors. Most REMPs recognize one specific pre-protein. The recognition site usually resides in the N-terminal signal sequence. REMP binding protects signal peptides against degradation by proteases. REMPs are also believed to prevent binding of immature pre-proteins to the translocon. The main aim of this work was to better understand the interaction between REMPs and substrate signal sequences. Two REMPs were investigated: DmsD (specific for dimethylsulfoxide reductase, DmsA) and TorD (specific for trimethylamine N-oxide reductase, TorA). Green fluorescent protein (GFP) was genetically fused behind the signal sequences of TorA and DmsA. This ensures native behavior of the respective signal sequence and excludes any effects mediated by the mature domain of the pre-protein. Surface plasmon resonance analysis revealed that these chimeric pre-proteins specifically bind to the cognate REMP. Furthermore, the region of the signal sequence that is responsible for specific binding to the corresponding REMP was identified by creating region-swapped chimeric signal sequences, containing parts of both the TorA and DmsA signal sequences. Surprisingly, specificity is not encoded in the highly variable positively charged N-terminal region of the signal sequence, but in the more similar hydrophobic C-terminal parts. Interestingly, binding of DmsD to its model substrate reduced membrane binding of the pre-protein. This property could link REMP-signal peptide binding to its reported proofreading function.
Highlights
Twin-arginine transport (Tat) systems are present in plant chloroplasts and many prokaryotes
The signal sequence of dimethylsulfoxide reductase (DmsA) fused to Green fluorescent protein (GFP) and the signal sequence of trimethylamine N-oxide reductase (TorA) fused to GFP were separately injected over this surface for a time period of 60 s
We used an in vitro approach to study the interaction between Redox enzyme maturation proteins (REMPs) and the substrate signal sequences
Summary
Twin-arginine transport (Tat) systems are present in plant chloroplasts and many prokaryotes. The Escherichia coli Tat system was first identified as a transporter of extracellular redox enzymes that require cofactor insertion and assembly in the cytoplasm prior to transport [1]. A broader range of proteins was added to the list of E. coli Tat substrates. The E. coli Tat translocon consists of the proteins TatA/TatE, TatB, and TatC [2]. There is currently no explicit evidence for additional proteins other than TatA/EBC essential for transport. There are instances where cytoplasmic chaperones play a role along the Tat pathway, presumably assisting the folding of substrates (for a review see [3]). Recent evidence demonstrates that E. coli DnaK is directly involved in the Tat pathway [4,5] but the involvement of other general E. coli chaperones, e.g. GroEL and SlyD, remains obscure owing to their largely overlapping functions
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