Hydrophobic mismatch effect is a key factor in protein transport on the Tat pathway

The twin-arginine translocation (Tat) pathway transports folded proteins across membranes in bacteria, thylakoid, plant mitochondria, and archaea. In most species, the active Tat machinery consists of three independent subunits, TatA, TatB and TatC. TatA and TatB from all bacterial species possess short transmembrane alpha-helices (TMHs), both of which are only fifteen residues long in E. coli. Such short TMHs cause a hydrophobic mismatch between Tat subunits and the membrane bilayer. Here, by modifying the length of the TMHs of E. coli TatA and TatB, we access the functional importance of the hydrophobic mismatch in the Tat transport mechanism. Surprisingly, both TatA and TatB with as few as 11 residues in their respective TMHs are still able to insert into the membrane bilayer, albeit with a decline in membrane integrity. Three different assays, both qualitative and quantitative, were conducted to evaluate the Tat activity of the TMH length mutants. Our experiments indicate that the TMHs of TatA and TatB appear to be evolutionarily tuned to 15 amino acids, with activity dropping off with any modification of this length. We believe our study supports a model of Tat transport utilizing localized toroidal pores that form when the membrane bilayer is thinned to a critical threshold. In this context, the 15-residue length of the TatA and TatB TMHs can be seen as a compromise between the need for some hydrophobic mismatch to allow the membrane to reversibly reach the threshold thinness required for toroidal pore formation, and the permanently destabilizing effect of placing even shorter helices into these energy-transducing membranes.

Engineering a super-secreting strain of Escherichia coli by directed co-evolution of the multiprotein Tat translocation machinery

Escherichia coli remains one of the preferred hosts for biotechnological protein production due to its robust growth in culture and ease of genetic manipulation. It is often desirable to export recombinant proteins into the periplasmic space for reasons related to proper disulfide bond formation, prevention of aggregation and proteolytic degradation, and ease of purification. One such system for expressing heterologous secreted proteins is the twin-arginine translocation (Tat) pathway, which has the unique advantage of delivering correctly folded proteins into the periplasm. However, transit times for proteins through the Tat translocase, comprised of the TatABC proteins, are much longer than for passage through the SecYEG pore, the translocase associated with the more widely utilized Sec pathway. To date, a high protein flux through the Tat pathway has yet to be demonstrated. To address this shortcoming, we employed a directed co-evolution strategy to isolate mutant Tat translocases for their ability to deliver higher quantities of heterologous proteins into the periplasm. Three super-secreting translocases were selected that each exported a panel of recombinant proteins at levels that were significantly greater than that observed for wildtype TatABC or SecYEG translocases. Interestingly, all three of the evolved Tat translocases exhibited quality control suppression, suggesting that increased translocation flux was gained by relaxation of substrate proofreading. Overall, our discovery of highly efficient translocase variants paves the way for the use of the Tat system as a powerful complement to the Sec pathway for secreted production of both commodity and high value-added proteins.

Influence of the TorD signal peptide chaperone on Tat-dependent protein translocation

The twin-arginine translocation (Tat) pathway transports folded proteins across energetic membranes. Numerous Tat substrates contain co-factors that are inserted before transport with the assistance of redox enzyme maturation proteins (REMPs), which bind to the signal peptide of precursor proteins. How signal peptides are transferred from a REMP to a binding site on the Tat receptor complex remains unknown. Since the signal peptide mediates both interactions, possibilities include: i) a coordinated hand-off mechanism; or ii) a diffusional search after REMP dissociation. We investigated the binding interaction between substrates containing the TorA signal peptide (spTorA) and its cognate REMP, TorD, and the effect of TorD on the in vitrotransport of such substrates. We found that Escherichia coli TorD is predominantly a monomer at low micromolar concentrations (dimerization KD > 50 M), and this monomer binds reversibly to spTorA (KD 1 M). While TorD binds to membranes (KD 100 nM), it has no apparent affinity for Tat translocons and it inhibits binding of a precursor substrate to the membrane. TorD has a minimal effect on substrate transport by the Tat system, being mildly inhibitory at high concentrations. These data are consistent with a model in which the REMP-bound signal peptide is shielded from recognition by the Tat translocon, and spontaneous dissociation of the REMP allows the substrate to engage the Tat machinery. Thus, the REMP does not assist with targeting to the Tat translocon, but rather temporarily shields the signal peptide.

The ten amino acids of the oxygen-evolving enhancer of tobacco is sufficient as the peptide residues for protein transport to the chloroplast thylakoid

Key message The thylakoid transit peptide of tobacco oxygen-evolving enhancer protein contains a minimal ten amino acid sequences for thylakoid lumen transports. This ten amino acids do not contain twin-arginine, which is required for typical chloroplast lumen translocation. Abstract Chloroplasts are intracellular organelles responsible for photosynthesis to produce organic carbon for all organisms. Numerous proteins must be transported from the cytosol to chloroplasts to support photosynthesis. This transport is facilitated by chloroplast transit peptides (TPs). Four chloroplast thylakoid lumen TPs were isolated from Nicotiana tabacum and were functionally analyzed as thylakoid lumen TPs. Typical chloroplast stroma-transit peptides and thylakoid lumen transit peptides (tTPs) are found in N. tabacum transit peptides (NtTPs) and the functions of these peptides are confirmed with TP–GFP fusion proteins under fluorescence microscopy and chloroplast fractionation, followed by Western blot analysis. During the functional analysis of tTPs, we uncovered the minimum 10 amino acid sequence is sufficient for thylakoid lumen transport. These ten amino acids can efficiently translocate GFP protein, even if they do not contain the twin-arginine residues required for the twin-arginine translocation (Tat) pathway, which is a typical thylakoid lumen transport. Further, thylakoid lumen transporting processes through the Tat pathway was examined by analyzing tTP sequence functions and we demonstrate that the importance of hydrophobic core for the tTP cleavage and target protein translocation.

A Defect in the Twin-Arginine Translocation Pathway Decreases the Tolerance of Xanthomonas campestris pv. campestris to Phenazines

Phenazine-1-carboxylic acid (PCA), a member of phenazines secreted by microorganisms, inhibits the growth of many bacteria and fungi. Xanthomonas campestris pv. campestris is the causal agent of black rot, the most important disease of cruciferous crops worldwide, and is more tolerant to PCA than other Xanthomonas species. Previous studies reported that reactive oxygen species (ROS) scavenging ability is involved in regulating the PCA tolerance of Xanthomonas species. Additionally, the cytochrome c maturation (CCM) system has been found to play a more important role in tolerance to phenazines than the ROS scavenging system. In this study, a highly PCA-sensitive insertion mutant of X. campestris pv. campestris, X-5, was identified and studied. The insertion site of X-5 was found to be in tatB gene (XC_4183), which encodes a subunit of the twin-arginine translocation (TAT) complex. Disruption of the three genes of TAT pathway resulted in decreased biological fitness and reduced tolerance to phenazines in comparison with the wild-type strain 8004. These results imply that the tolerance mechanism of the TAT pathway to phenazines is related to the CCM system, but not due to the ROS scavenging system. Furthermore, respiration-related characteristic tests and peptide analysis suggested that disruption of the TAT complex causes a defect in the cytochrome bc1 complex, which may be involved in the tolerance to phenazines. In summary, this study sheds new light on the critical role of the TAT pathway in influencing the fitness and phenazines tolerance of Xanthomonas species.

Engineering of the Bacillus subtilis PhoD signal peptide to direct high-level, Tat-specific export of a single-chain antibody fragment to the periplasm in Eschericha coli

Background : Numerous high-value proteins have been produced in E. coli, and a favoured strategy is to export the protein of interest to the periplasm by means of an N-terminal signal peptide. While the Sec pathway has been extensively used for this purpose, the Tat pathway has potential because it transports fully-folded heterologous proteins. Most studies on the Tat pathway have used the E. coli TorA signal peptide to direct export, because it is highly Tat-specific, unlike many Tat signal peptides which can also function as Sec signal peptides. However, the TorA signal peptide is prone to degradation in the cytoplasm, leading to reduced export rates in some cases. Here, we have tested a range of alternative signal peptides for their ability to direct Tat-dependent export of a single-chain antibody fragment (scFv). Results : We show that the signal peptides of E. coli AmiC, MdoD and YcbK direct efficient export of the scFv by both the Tat and Sec pathways, which may be a disadvantage when Tat-specific export is required. The same applies to the Tat signal peptide of Bacillus subtilis PhoD, which likewise directs efficient export by Sec. We engineered the PhoD signal peptide by introduction of a Lys or Asn residue in the C-terminal domain of the signal peptide, and we show that this substitution renders the signal peptide Tat-specific. These signal peptides, designated PhoDk and PhoDn, direct efficient export of scFv in shake flask and fed-batch fermentation studies, reaching export levels that are well above those obtained with the TorA signal peptide. Culturing in ambr250 bioreactors was used to fine-tune the growth conditions, and the net result was export of the scFv by the Tat pathway at levels of approximately 1g protein/L culture. Conclusions : The new PhoDn and PhoDk signal peptides have significant potential for the export of heterologous proteins by the Tat system.

The Twin-Arginine Translocation System Is Important for Stress Resistance and Virulence of Brucella melitensis

ABSTRACT Brucella, the causative agent of brucellosis, is a stealthy intracellular pathogen that is highly pathogenic to a range of mammals, including humans. The twin-arginine translocation (Tat) pathway transports folded proteins across the cytoplasmic membrane and has been implicated in virulence in many bacterial pathogens. However, the roles of the Tat system and related substrates in Brucella remain unclear. We report here that disruption of Tat increases the sensitivity of Brucella melitensis M28 to the membrane stressor sodium dodecyl sulfate (SDS), indicating cell envelope defects, as well as to EDTA. In addition, mutating Tat renders M28 bacteria more sensitive to oxidative stress caused by H2O2. Further, loss of Tat significantly attenuates B. melitensis infection in murine macrophages ex vivo. Using a mouse model for persistent infection, we demonstrate that Tat is required for full virulence of B. melitensis M28. Genome-wide in silico prediction combined with an in vivo amidase reporter assay indicates that at least 23 proteins are authentic Tat substrates, and they are functionally categorized into solute-binding proteins, oxidoreductases, cell envelope biosynthesis enzymes, and others. A comprehensive deletion study revealed that 6 substrates contribute significantly to Brucella virulence, including an l,d-transpeptidase, an ABC transporter solute-binding protein, and a methionine sulfoxide reductase. Collectively, our work establishes that the Tat pathway plays a critical role in Brucella virulence.

Engineering of The Bacillus Subtilis PhoD Signal Peptide To Direct High-Level, Tat-Specific Export of A Single-Chain Antibody Fragment To The Periplasm in Eschericha Coli

Background: Numerous high-value proteins have been produced in E. coli, and a favoured strategy is to export the protein of interest to the periplasm by means of an N-terminal signal peptide. While the Sec pathway has been extensively used for this purpose, the Tat pathway has potential because it transports fully-folded heterologous proteins. Most studies on the Tat pathway have used the E. coli TorA signal peptide to direct export, because it is highly Tat-specific, unlike many Tat signal peptides which can also function as Sec signal peptides. However, the TorA signal peptide is prone to degradation in the cytoplasm, leading to reduced export rates in some cases. Here, we have tested a range of alternative signal peptides for their ability to direct Tat-dependent export of a single-chain antibody fragment (scFv). Results: We show that the signal peptides of E. coli AmiC, MdoD and YcbK direct efficient export of the scFv by both the Tat and Sec pathways, which may be a disadvantage when Tat-specific export is required. The same applies to the Tat signal peptide of Bacillus subtilis PhoD, which likewise directs efficient export by Sec. We engineered the PhoD signal peptide by introduction of a Lys or Asn residue in the C-terminal domain of the signal peptide, and we show that this substitution renders the signal peptide Tat-specific. These signal peptides, designated PhoDk and PhoDn, direct efficient export of scFv in shake flask and fed-batch fermentation studies, reaching export levels that are well above those obtained with the TorA signal peptide. Culturing in ambr250 bioreactors was used to fine-tune the growth conditions, and the net result was export of the scFv by the Tat pathway at levels of approximately 1g protein/L culture. Conclusions: The new PhoDn and PhoDk signal peptides have significant potential for the export of heterologous proteins by the Tat system.