Adaptation of protein secretion to extremely high-salt conditions by extensive use of the twin-arginine translocation pathway

Halophilic archaea thrive in environments with salt concentrations approaching saturation. However, little is known about the way in which these organisms stabilize their secreted proteins in such 'hostile' conditions. Here, we present data suggesting that the utilization of protein translocation pathways for protein secretion by the Halobacteriaceae differs significantly from that of non-haloarchaea, and most probably represents an adaptation to the high-salt environment. Although most proteins are secreted via the general secretion (Sec) machinery, the twin-arginine translocation (Tat) pathway is mainly used for the secretion of redox proteins and is distinct from the Sec pathway, in that it allows cytoplasmic folding of secreted proteins. tatfind (developed in this study) was used for systematic whole-genome analysis of Halobacterium sp. NRC-1 and several other prokaryotes to identify putative Tat substrates. Our analyses revealed that the vast majority of haloarchaeal secreted proteins were predicted substrates of the Tat pathway. Strikingly, most of these putative Tat substrates were non-redox proteins, the homologues of which in non-haloarchaea were identified as putative Sec substrates. We confirmed experimentally that the secretion of one such putative Tat substrate depended on the twin-arginine motif in its signal sequence. This extensive utilization of the Tat pathway in haloarchaea suggests an evolutionary adaptation to high-salt conditions by allowing cytoplasmic folding of secreted proteins before their secretion.     

Genetic and biochemical analysis of the twin-arginine translocation pathway in halophilic archaea

The twin-arginine translocation (Tat) pathway is present in a wide variety of prokaryotes and is capable of exporting partially or fully folded proteins from the cytoplasm. Although diverse classes of proteins are transported via the Tat pathway, in most organisms it facilitates the secretion of a relatively small number of substrates compared to the Sec pathway. However, computational evidence suggests that haloarchaea route nearly all secreted proteins to the Tat pathway. We have expanded previous computational analyses of the haloarchaeal Tat pathway and initiated in vivo characterization of the Tat machinery in a model haloarchaeon, Haloferax volcanii. Consistent with the predicted usage of the this pathway in the haloarchaea, we determined that three of the four identified tat genes in Haloferax volcanii are essential for viability when grown aerobically in complex medium. This represents the first report of an organism that requires the Tat pathway for viability when grown under such conditions. Deletion of the nonessential gene had no effect on the secretion of a verified substrate of the Tat pathway. The two TatA paralogs TatAo and TatAt were detected in both the membrane and cytoplasm and could be copurified from the latter fraction. Using size exclusion chromatography to further characterize cytoplasmic and membrane TatA proteins, we find these proteins present in high-molecular-weight complexes in both cellular fractions.     

Targeting of proteins to the twin-arginine translocation pathway

The twin-arginine protein transport (Tat pathway) is found in prokaryotes and plant organelles and transports folded proteins across membranes. Targeting of substrates to the Tat system is mediated by the presence of an N-terminal signal sequence containing a highly conserved twin-arginine motif. The Tat machinery comprises membrane proteins from the TatA and TatC families. Assembly of the Tat translocon is dynamic and is triggered by the interaction of a Tat substrate with the Tat receptor complex. This review will summarise recent advances in our understanding of Tat transport, focusing in particular on the roles played by Tat signal peptides in protein targeting and translocation.     

Involvement of the twin-arginine translocation system in protein secretion via the type II pathway.

The general secretory pathway (GSP) is a two-step process for the secretion of proteins by Gram-negative bacteria. The translocation across the outer membrane is carried out by the type II system, which involves machinery called the secreton. This step is considered to be an extension of the general export pathway, i.e. the export of proteins across the inner membrane by the Sec machinery. Here, we demonstrate that two substrates for the Pseudomonas aeruginosa secreton, both phospholipases, use the twin-arginine translocation (Tat) system, instead of the Sec system, for the first step of translocation across the inner membrane. These results challenge the previous vision of the GSP and suggest for the first time a mosaic model in which both the Sec and the Tat systems feed substrates into the secreton. Moreover, since P.aeruginosa phospholipases are secreted virulence factors, the Tat system appears to be a novel determinant of bacterial virulence.     

The twin-arginine translocation pathway is necessary for correct membrane insertion of the Rieske Fe/S protein in Legionella pneumophila

The twin-arginine translocation (Tat) pathway translocates folded proteins across the cytoplasmic membrane. Proteins transported through this secretion system typically carry two arginine residues in their signal peptide that is cleaved off during translocation. Recently, we demonstrated the presence of the Tat pathway in Legionella pneumophila Philadelphia-1 and the Rieske Fe/S protein PetA was one of the predicted Tat substrates. Because we observed that the signal peptide of PetA is not processed and that this protein is still membrane associated in the tat mutants, correct membrane insertion was assayed using a trypsin sensitivity assay. We conclude that the Tat pathway is necessary for correct membrane insertion of L. pneumophila PetA.     

Identification of Streptomyces lividans proteins secreted by the twin-arginine translocation pathway following growth with different carbon sources

Genome-based signal peptide predictions classified Streptomyces coelicolor as the microorganism that secretes the most proteins through the twin-arginine translocation (Tat)-dependent secretion pathway. Availability of a DeltatatC mutant of the closely related strain Streptomyces lividans impaired Tat-dependent protein secretion and enabled identification of many extracellular proteins that are secreted via the Tat pathway. Proteomic techniques were applied to analyze proteins from the supernatants of log-phase cultures. Since the bacterial secretome depends mainly on the carbon sources available during growth, xylose, glucose, chitin, and soil extracts were used. A total of 63 proteins were identified, among which 7 were predicted by the TATscan program, and 20 were not predicted but contained a potential Tat signal motif. Thirteen proteins having no signal sequence could be co-transported by Tat-dependent proteins because the genes that encode these proteins are in close proximity in the genome. Finally, the presence of 23 proteins lacking signal peptides was difficult to explain. More secreted proteins could be identified as Tat substrates in varying carbon sources.     

Haloferax volcanii twin-arginine translocation substates include secreted soluble, C-terminally anchored and lipoproteins

Recent in silico and in vivo studies have suggested that the majority of proteins destined for secretion in the haloarchaea are trafficked through the twin-arginine translocation (Tat) pathway. The presence of lipobox motifs in most haloarchaeal Tat signal sequences is intriguing as: (i) bioinformatic searches of archaeal genomes have not identified lipoprotein biogenesis enzymes and (ii) there are no known Tat substrates containing both a twin-arginine and a bona fide lipobox. We have examined six computationally designated Tat substrates in the haloarchaeon Haloferax volcanii to verify previous computational predictions and to initiate studies of lipoprotein biogenesis via the Tat pathway. Our results confirmed that the six candidate proteins were not only Tat substrates, but also belonged to diverse classes of secretory proteins. Analysis of predicted lipoprotein Tat substrates revealed that they are anchored to the archaeal membrane in a cysteine-dependent manner. Interestingly, despite the absence of an archaeal lipoprotein signal peptidase II (SPase II) homologue, the SPase II inhibitor globomycin impeded cell growth and specifically prevented maturation of lipoproteins. Together, this work not only represents the first experimental demonstration of a lipoprotein Tat substrate, but also indicates the presence of an unidentified lipoprotein biogenesis pathway in archaea.     

The tatC gene cluster is essential for viability in halophilic archaea

In prokaryotes the twin-arginine translocase (Tat) is a unique transport system for the export of folded proteins. The Tat pathway is usually involved in the export of a small proportion of extracytoplasmic proteins. An exception is found in halophilic archaea, in which the majority of secretory proteins have been predicted to be Tat-dependent. All haloarchaea analysed to date contain two genes encoding homologues of the Tat-component TatC. In all of these cases both genes are located adjacently on the chromosome, indicating that they form a functional unit. We show that this gene cluster is essential for viability in haloarchaea, which is in complete contrast to all other prokaryotes that have been tested thus far.     

High-Salinity Growth Conditions Promote Tat-Independent Secretion of Tat Substrates in Bacillus subtilis

The Gram-positive bacterium Bacillus subtilis contains two Tat translocases, which can facilitate transport of folded proteins across the plasma membrane. Previous research has shown that Tat-dependent protein secretion in B. subtilis is a highly selective process and that heterologous proteins, such as the green fluorescent protein (GFP), are poor Tat substrates in this organism. Nevertheless, when expressed in Escherichia coli, both B. subtilis Tat translocases facilitated exclusively Tat-dependent export of folded GFP when the twin-arginine (RR) signal peptides of the E. coli AmiA, DmsA, or MdoD proteins were attached. Therefore, the present studies were aimed at determining whether the same RR signal peptide-GFP precursors would also be exported Tat dependently in B. subtilis. In addition, we investigated the secretion of GFP fused to the full-length YwbN protein, a strict Tat substrate in B. subtilis. Several investigated GFP fusion proteins were indeed secreted in B. subtilis, but this secretion was shown to be completely Tat independent. At high-salinity growth conditions, the Tat-independent secretion of GFP as directed by the RR signal peptides from the E. coli AmiA, DmsA, or MdoD proteins was significantly enhanced, and this effect was strongest in strains lacking the TatAy-TatCy translocase. This implies that high environmental salinity has a negative influence on the avoidance of Tat-independent secretion of AmiA-GFP, DmsA-GFP, and MdoD-GFP. We conclude that as-yet-unidentified control mechanisms reject the investigated GFP fusion proteins for translocation by the B. subtilis Tat machinery and, at the same time, set limits to their Tat-independent secretion, presumably via the Sec pathway.     

TatB functions as an oligomeric binding site for folded Tat precursor proteins

Twin-arginine-containing signal sequences mediate the transmembrane transport of folded proteins. The cognate twin-arginine translocation (Tat) machinery of Escherichia coli consists of the membrane proteins TatA, TatB, and TatC. Whereas Tat signal peptides are recognized by TatB and TatC, little is known about molecular contacts of the mature, folded part of Tat precursor proteins. We have placed a photo-cross-linker into Tat substrates at sites predicted to be either surface-exposed or hidden in the core of the folded proteins. On targeting of these variants to the Tat machinery of membrane vesicles, all surface-exposed sites were found in close proximity to TatB. Correspondingly, incorporation of the cross-linker into TatB revealed multiple precursor-binding sites in the predicted transmembrane and amphipathic helices of TatB. Large adducts indicative of TatB oligomers contacting one precursor molecule were also obtained. Cross-linking of Tat substrates to TatB required an intact twin-arginine signal peptide and disappeared upon transmembrane translocation. Our collective data are consistent with TatB forming an oligomeric binding site that transiently accommodates folded Tat precursors.     

The Canonical Twin-Arginine Translocase Components Are Not Required for Secretion of Folded Green Fluorescent Protein from the Ancestral Strain of Bacillus subtilis

Cellular processes, such as the digestion of macromolecules, phosphate acquisition, and cell motility, require bacterial secretion systems. In Bacillus subtilis, the predominant protein export pathways are Sec (generalized secretory pathway) and Tat (twin-arginine translocase). Unlike Sec, which secretes unfolded proteins, the Tat machinery secretes fully folded proteins across the plasma membrane and into the medium. Proteins are directed for Tat-dependent export by N-terminal signal peptides that contain a conserved twin-arginine motif. Thus, utilizing the Tat secretion system by fusing a Tat signal peptide is an attractive strategy for the production and export of heterologous proteins. As a proof of concept, we expressed green fluorescent protein (GFP) fused to the PhoD Tat signal peptide in the laboratory and ancestral strains of B. subtilis. Secretion of the Tat-GFP construct, as well as secretion of proteins in general, was substantially increased in the ancestral strain. Furthermore, our results show that secreted, fluorescent GFP could be purified directly from the extracellular medium. Nonetheless, export was not dependent on the known Tat secretion components or the signal peptide twin-arginine motif. We propose that the ancestral strain contains additional Tat components and/or secretion regulators that were abrogated following domestication.     

Exploration of twin‐arginine translocation for expression and purification of correctly folded proteins in Escherichia coli

Historically, the general secretory (Sec) pathway of Gram‐negative bacteria has served as the primary route by which heterologous proteins are delivered to the periplasm in numerous expression and engineering applications. Here we have systematically examined the twin‐arginine translocation (Tat) pathway as an alternative, and possibly advantageous, secretion pathway for heterologous proteins. Overall, we found that: (i) export efficiency and periplasmic yield of a model substrate were affected by the composition of the Tat signal peptide, (ii) Tat substrates were correctly processed at their N‐termini upon reaching the periplasm and (iii) proteins fused to maltose‐binding protein (MBP) were reliably exported by the Tat system, but only when correctly folded; aberrantly folded MBP fusions were excluded by the Tat pathway's folding quality control feature. We also observed that Tat export yield was comparable to Sec for relatively small, well‐folded proteins, higher relative to Sec for proteins that required cytoplasmic folding, and lower relative to Sec for larger, soluble fusion proteins. Interestingly, the specific activity of material purified from the periplasm was higher for certain Tat substrates relative to their Sec counterparts, suggesting that Tat expression can give rise to relatively pure and highly active proteins in one step.     

A putative twin-arginine translocation pathway in Legionella pneumophila

Legionella pneumophila is a facultative intracellular human pathogen causing Legionnaires' disease, a severe form of pneumonia. Because of the importance of secretion pathways in virulence, we were interested in the possible presence of the twin-arginine translocation (Tat) pathway in L. pneumophila. This secretion pathway is used to transport folded proteins, characterized by two arginines in their signal peptide, across the cytoplasmic membrane. We describe here the presence of a putative Tat pathway in L. pneumophila. Three genes encoding Escherichia coli TatA, TatB, and TatC homologues were identified. The tatA and tatB genes were shown to constitute an operon while tatC is monocistronic. RT-PCR analysis revealed expression of the tat genes during both exponential and stationary growth as well as during intracellular growth in Acanthamoeba castellanii. A search for the conserved twin-arginine motif in predicted signal peptides resulted in a list of putative Tat substrates.     

Selective contribution of the twin-arginine translocation pathway to protein secretion in Bacillus subtilis

The availability of the complete genome sequence of Bacillus subtilis has allowed the prediction of all exported proteins of this Gram-positive eubacterium. Recently, approximately 180 secretory and 114 lipoprotein signal peptides were predicted to direct protein export from the cytoplasm. Whereas most exported proteins appear to use the Sec pathway, 69 of these proteins could potentially use the Tat pathway, as their signal peptides contain RR- or KR-motifs. In the present studies, proteomic techniques were applied to verify how many extracellular B. subtilis proteins follow the Tat pathway. Strikingly, the extracellular accumulation of 13 proteins with potential RR/KR-signal peptides was Tat-independent, showing that their RR/KR-motifs are not recognized by the Tat machinery. In fact, only the phosphodiesterase PhoD was shown to be secreted in a strictly Tat-dependent manner. Sodium azide-inhibition of SecA strongly affected the extracellular appearance of de novo synthesized proteins, including the lipase LipA and two other proteins with predicted RR/KR-signal peptides. The SecA-dependent export of pre-LipA is particularly remarkable, because its RR-signal peptide conforms well to stringent criteria for the prediction of Tat-dependent export in Escherichia coli. Taken together, our observations show that the Tat pathway makes a highly selective contribution to the extracellular proteome of B. subtilis.     

Genetic toggling of alkaline phosphatase folding reveals signal peptides for all major modes of transport across the inner membrane of bacteria

Prediction of export pathway specificity in prokaryotes is a challenging endeavor due to the similar overall architecture of N-terminal signal peptides for the Sec-, SRP- (signal recognition particle), and Tat (twin arginine translocation)-dependent pathways. Thus, we sought to create a facile experimental strategy for unbiased discovery of pathway specificity conferred by N-terminal signals. Using a limited collection of Escherichia coli strains that allow protein oxidation in the cytoplasm or, conversely, disable protein oxidation in the periplasm, we were able to discriminate the specific mode of export for PhoA (alkaline phosphatase) fusions to signal peptides for all of the major modes of transport across the inner membrane (Sec, SRP, or Tat). Based on these findings, we developed a mini-Tn5 phoA approach to isolate pathway-specific export signals from libraries of random fusions between exported proteins and the phoA gene. Interestingly, we observed that reduced PhoA was exported in a Tat-independent manner when targeted for Tat export in the absence of the essential translocon component TatC. This suggests that initial docking to TatC serves as a key specificity determinant for Tat-specific routing of PhoA, and in its absence, substrates can be rerouted to the Sec pathway, provided they remain compatible with the Sec export mechanism. Finally, the utility of our approach was demonstrated by experimental verification that four secreted proteins from Mycobacterium tuberculosis carrying putative Tat signals are bona fide Tat substrates and thus represent potential Tat-dependent virulence factors in this important human pathogen.     

Mapping the twin‐arginine protein translocation network of Bacillus subtilis

Bacteria employ twin‐arginine translocation (Tat) pathways for the transport of folded proteins to extracytoplasmic destinations. In recent years, most studies on bacterial Tat pathways addressed the membrane‐bound TatA(B)C subunits of the Tat translocase, and the specific interactions between this translocase and its substrate proteins. In contrast, relatively few studies investigated possible coactors in the TatA(B)C‐dependent protein translocation process. The present studies were aimed at identifying interaction partners of the Tat pathway of Bacillus subtilis, which is a paradigm for studies on protein secretion by Gram‐positive bacteria. Specifically, 36 interaction partners of the TatA and TatC subunits were identified by rigorous application of the yeast two‐hybrid (Y2H) approach. Our Y2H analyses revealed that the three TatA isoforms of B. subtilis can form homo‐ and heterodimers. Subsequently, the secretion of the Tat substrates YwbN and PhoD was tested in mutant strains lacking genes for the TatAC interaction partners identified in our genome‐wide Y2H screens. Our results show that the cell wall‐bound protease WprA is important for YwbN secretion, and that the HemAT and CsbC proteins are required for PhoD secretion under phosphate starvation conditions. Taken together, our findings imply that the Bacillus Tat pathway is embedded in an intricate protein–protein interaction network.     

Protein targeting by the bacterial twin-arginine translocation (Tat) pathway

The Tat (twin-arginine translocation) protein export system is found in the cytoplasmic membrane of most prokaryotes and is dedicated to the transport of folded proteins. The Tat system is now known to be essential for many bacterial processes including energy metabolism, cell wall biosynthesis, the nitrogen-fixing symbiosis and bacterial pathogenesis. Recent studies demonstrate that substrate-specific accessory proteins prevent improperly assembled substrates from interacting with the Tat transporter. During the transport cycle itself substrate proteins bind to a receptor complex in the membrane which then recruits a protein-translocating channel to carry out the transport reaction.     

Export of complex cofactor-containing proteins by the bacterial Tat pathway

The twin-arginine (Tat) protein translocase is a highly unusual protein transport machine that is dedicated to the movement of folded proteins across the bacterial cytoplasmic membrane. Proteins are targeted to the Tat pathway by means of N-terminal signal peptides harbouring a distinctive twin-arginine motif. In the model organism Escherichia coli, many of the Tat substrates bind redox cofactors that are inserted into apo-proteins before they engage with the Tat machinery. Here we review recent advances in understanding the events involved in the coordination of cofactor insertion with the export process. Current models for Tat protein transport are also discussed.     

Proteolytic processing of <Emphasis Type="Italic">Escherichia coli</Emphasis> twin-arginine signal peptides by LepB

The twin-arginine translocation (Tat) apparatus is a protein targeting system found in the cytoplasmic membranes of many prokaryotes. Substrate proteins of the Tat pathway are synthesised with signal peptides bearing SRRxFLK ‘twin-arginine’ amino acid motifs. All Tat signal peptides have a common tripartite structure comprising a polar N-terminal region, followed by a hydrophobic region of variable length and a polar C-terminal region. In Escherichia coli, Tat signal peptides are proteolytically cleaved after translocation. The signal peptide C-terminal regions contain conserved AxA motifs, which are possible recognition sequences for leader peptidase I (LepB). In this work, the role of LepB in Tat signal peptide processing was addressed directly. Deliberate repression of lepB expression prevented processing of all Tat substrates tested, including SufI, AmiC, and a TorA-23K reporter protein. In addition, electron microscopy revealed gross defects in cell architecture and membrane integrity following depletion of cellular LepB protein levels.