Mutations in subunits of the Escherichia coli twin-arginine translocase block function via differing effects on translocation activity or tat complex structure.

We have used a combination of blue-native (BN) gel electrophoresis and protein purification to analyze the effects of TatA or TatC mutations on the structures of the primary TatABC and multimeric TatA complexes in Escherichia coli. Expression of wild-type TatABC leads to the production of a single major TatABC complex of 370 kDa and a heterogeneous set of TatA complexes of <100 kDa to approximately 500 kDa. Two TatC mutations that block translocation have different effects on complex structures. P48A causes massive defects in TatABC assembly, including a marked separation of the TatBC subunits and the production of TatB and TatC aggregates. In contrast, TatABC complexes from the inactive TatC F94A mutant are structurally intact, suggesting that this mutation affects translocation activity rather than assembly. Neither TatC mutation affects the separate TatA complexes, showing that assembly of the TatA complexes is independent of TatABC assembly or activity. In contrast, three TatA mutations affect both the TatA and TatABC complexes. F39A assembles into smaller, incorrectly organized TatA complexes and the TatABC complexes contain an incorrect TatB:TatC ratio and unusually large amounts of TatA. A triple mutant in the amphipathic region forms slightly larger TatA complexes that are likewise disorganized, and a mutant containing three glycine substitutions in the transmembrane (TM) span assembles as grossly affected TatA complexes that are much larger than wild-type complexes. These mutants lead to a partial failure of TatB to assemble correctly. The data show that the amphipathic and TM regions play critical roles in TatA complex assembly. All of the TatA mutations lead to partial or substantial defects in TatABC complex formation, demonstrating that the properties of TatA can have a marked influence on the TatABC complex.

The core TatABC complex of the twin-arginine translocase in Escherichia coli: TatC drives assembly whereas TatA is essential for stability.

Current models for the action of the twin-arginine translocation (Tat) system propose that substrates bind initially to the TatBC subunits, after which a separate TatA complex is recruited to form an active translocon. Here, we have studied the roles of individual subunits in the assembly and stability of the core TatBC-containing substrate-binding complex. Previous studies have shown that TatB and TatC are active when fused together; we show here that deletion of the entire TatB transmembrane span from this Tat(BC) fusion inactivates the Tat system but does not affect assembly of the core complex. In this mutated complex, TatA is present but more loosely bound, indicating a role for TatB in the correct binding of TatA. In the absence of TatA, the truncated TatBC fusion protein still assembles into a complex of the correct magnitude, demonstrating that the transmembrane spans of TatC are the only determinants within the membrane bilayer that specify assembly of this complex. Further studies on both the Tat(BC) construct and the wild-type TatBC subunits show that the TatBC complex is unstable in the absence of TatA, and we show that TatA stabilises the TatB subunit specifically within this complex. The results demonstrate a dual role and location for TatA: in the functioning/maintenance of the core complex, and as a separate homo-oligomeric complex.

Consensus structural features of purified bacterial TatABC complexes.

The twin-arginine translocation (Tat) system transports folded proteins across bacterial plasma membranes and the chloroplast thylakoid membrane. Here, we investigate the composition and structural organization of three different purified Tat complexes from Escherichia coli, Salmonella typhimurium and Agrobacterium tumefaciens. First, we demonstrate the functional activity of these Tat systems in vivo, since expression of the tatABC operons from S.typhimurium or A.tumefaciens in an E.coli tat null mutant strain resulted in efficient Tat-dependent export of an E.coli cofactor-containing substrate, TMAO reductase. The three isolated, affinity-tagged Tat complexes comprised TatA, TatB and TatC in each case, demonstrating a strong interaction between these three subunits. Single-particle electron microscopy studies of all three complexes revealed approximately oval-shaped, asymmetric particles with maximal dimensions up to 13 nm. A common feature is a number of stain-excluding densities surrounding more or less central pools of stain, suggesting protein-lined pores or cavities. The characteristics of size variation among the particles suggest a modular form of assembly and/or the recruitment of varying numbers of TatBC/TatA units. Despite low levels of sequence homology, the combined data indicate structural and functional conservation in the Tat systems of these three bacterial species.