Abstract
The twin arginine translocation pathway exports folded proteins across the cytoplasmic membrane of many bacteria. In Escherichia coli and other Gram-negative bacteria, TatA, TatB, and TatC are all essential for efficient translocation, and current models suggest that separate TatABC and TatA complexes coalesce at the point of translocation. However, other microbes appear only to possess tatA and tatC genes. In Escherichia coli, virtually no translocation is observed when only TatA and TatC are present, but several mutations at the extreme N terminus of TatA were shown to support translocation. Here we show that these apparently bifunctional mutant TatA variants can function as typical TatA components because translocation is observed when they are co-expressed with TatBC, and they assemble into large, heterogeneous complexes that resemble wild type TatA complexes. However, cells expressing TatC plus the mutant TatA variants do not contain complexes that resemble the expected 370-kDa TatABC complex, clearly indicating that the mutant TatA forms cannot assemble efficiently, or stably, into this complex. The simultaneous expression of wild type TatA furthermore blocks translocation activity, suggesting that the mutant TatA forms preferentially bind to other TatA molecules rather than TatC. Surprisingly, we observe translocation in the absence of detectable free TatA, when translational fusions of the mutant TatAs with TatC are expressed. Transport can thus proceed in the simultaneous absence of TatABC and TatA complexes at detectable levels, and we conclude that the active translocon may be formed from dynamic twin arginine translocation complexes, one or more of which may await characterization.
Highlights
The twin arginine translocation (Tat)2 system is used to transport proteins across the thylakoid membrane of chloro
To analyze native E. coli Tat substrates, we tested whether these TatA ϩ TatC constructs can translocate a large cofactorcontaining protein, trimethylamine N-oxide (TMAO) reductase (TorA)
When wild type TatABC is expressed most of the TorA activity is located in the periplasm, confirming that the Tat system is active
Summary
TatA NcoI F TatA PstI R TatC PstI F TatC XbaI R TatA 10Asn PstI R TatC Xa PstI F M1 (G2SG3D) M2 (G3D) TatA NheI F TatA NcoI R gctacacgccATGGGTGGTATCAGTC gctacacgctgcagTTACACCTGCTCTTTATCG gctacacgctgcagATGTCTGTAGAAGATACTC gctacacgtctagaTTATTTCAAACTG gctacacgctgcaggttgttgttattgttgttgttattgttgttcACCTGCTCTTTATCGTG gctacacgctgcagatcgaaggtcgtTCTGTAGAAGATACTCAAC GGAGGAATTCACCATGaGTGatatcagtatttggcag GGAATTCACCATGGGTGaTATCAGTATTTGGCAG gctacacggctagcaggaggaattca gctacacgccatggtTTACACCTGCTCTTTATCG signal peptide associates with TatB and TatC and this can occur with de-energized membranes where further translocation is prevented [19, 20]. Most Gram-positive organisms contain only tatAC genes [12, 23, 24] suggesting that TatA may be bifunctional in these bacteria, fulfilling both TatA and TatB roles In support of this idea, Blaudeck et al [25] recently showed that translocation of a chimeric Tat substrate can occur in the presence of only TatA and TatC after selecting for TatA mutants that compensate, at least to a certain degree, for the absence of TatB. The modified TatA molecules have been analyzed using a chimeric Tat substrate, and the export capabilities of these TatA/ TatC mutant translocases have not been directly investigated at the protein level It is not clear whether typical Tat complexes are formed. We show that translocation can proceed in the absence of any of the previously identified Tat complexes
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
