Functional importance of a conserved sequence motif in FhaC, a prototypic member of the TpsB/Omp85 superfamily

In Gram-negative bacteria, the two-partner secretion pathway mediates the secretion of TpsA proteins with various functions. TpsB transporters specifically recognize their TpsA partners in the periplasm and mediate their transport through a hydrophilic channel. The filamentous haemagglutinin adhesin (FHA)/FhaC pair represents a model two-partner secretion system, with the structure of the TpsB transporter FhaC providing the bases to decipher the mechanism of action of these proteins. FhaC is composed of a β-barrel preceded by two periplasmic polypeptide-transport-associated (POTRA) domains in tandem. The barrel is occluded by an N-terminal helix and an extracellular loop, L6, folded back into the FhaC channel. In this article, we describe a functionally important motif of FhaC. The VRGY tetrad is highly conserved in the TpsB family and, in FhaC, it is located at the tip of L6 reaching the periplasm. Replacement by Ala of the invariant Arg dramatically affects the secretion efficiency, although the structure of FhaC and its channel properties remain unaffected. This substitution affects the secretion mechanism at a step beyond the initial TpsA-TpsB interaction. Replacement of the conserved Tyr affects the channel properties, but not the secretion activity, suggesting that this residue stabilizes the loop in the resting conformation of FhaC. Thus, the conserved motif at the tip of L6 represents an important piece of two-partner secretion machinery. This motif is conserved in a predicted loop between two β-barrel strands in more distant relatives of FhaC involved in protein transport across or assembly into the outer membranes of bacteria and organelles, suggesting a conserved function in the molecular mechanism of transport.     

Translocator proteins in the two-partner secretion family have multiple domains

The two-partner secretion pathway in Gram-negative bacteria consists of a TpsA exoprotein and a cognate TpsB outer membrane translocator protein. Previous work has demonstrated that the TpsB protein forms a beta-barrel structure with pore forming activity and facilitates translocation of the TpsA protein across the outer membrane. In this study, we characterized the functional domains of the Haemophilus influenzae HMW1B protein, a TpsB protein that interacts with the H. influenzae HMW1 adhesin. Using c-Myc epitope tag insertions and cysteine substitution mutagenesis, we discovered that HMW1B contains an N-terminal surface-localized domain, an internal periplasmic domain, and a C-terminal membrane anchor. Functional and biochemical analysis of the c-Myc epitope tag insertions and a series of HMW1B deletion constructs demonstrated that the periplasmic domain is required for secretion of HMW1 and that the C-terminal membrane anchor (HMW1B-(234-545)) is capable of oligomerization and pore formation. Similar to our observations with HMW1B, examination of a Bordetella pertussis TpsB protein called FhaC revealed that the C terminus of FhaC (FhaC-(232-585)) is capable of pore formation. We speculate that all TpsB proteins have a modular structure, with a periplasmic domain that interacts with the cognate TpsA protein and with pore forming activity contained within the C terminus.     

Channel formation by FhaC, the outer membrane protein involved in the secretion of the Bordetella pertussis filamentous hemagglutinin

Many virulence factors of pathogenic microorganisms are presented at the cell surface. However, protein secretion across the outer membrane of Gram-negative bacteria remains poorly understood. Here we used the extremely efficient secretion of the Bordetella pertussis filamentous hemagglutinin (FHA) to decipher this process. FHA secretion requires a single specific accessory protein, FhaC, the prototype of a family of proteins necessary for the extracellular localization of various virulence proteins in Gram-negative bacteria. We show that FhaC is heat-modifiable and localized in the outer membrane. Circular dichroism spectra indicated that FhaC is rich in beta-strands, in agreement with structural predictions for this protein. We further demonstrated that FhaC forms pores in artificial membranes, as evidenced by single-channel conductance measurements through planar lipid bilayers, as well as by liposome swelling assays and patch-clamp experiments using proteoliposomes. Single-channel conductance appeared to fluctuate very fast, suggesting that the FhaC channels frequently assume a closed conformation. We thus propose that FhaC forms a specific beta-barrel channel in the outer membrane for the outward translocation of FHA.     

Secretion signal of the filamentous haemagglutinin, a model two-partner secretion substrate

The sorting of proteins to their proper subcellular compartment requires specific addressing signals that mediate interactions with ad hoc transport machineries. In Gram-negative bacteria, the widespread two-partner secretion (TPS) pathway is dedicated to the secretion of large, mostly virulence-related proteins. The secreted TpsA proteins carry a characteristic 250-residue-long N-terminal 'TPS domain' essential for secretion, while their TpsB transporters are pore-forming proteins that specifically recognize their respective TpsA partners and mediate their translocation across the outer membrane. However, the nature of the secretion signal has not been elucidated yet. The whooping cough agent Bordetella pertussis secretes its major adhesin filamentous haemagglutinin (FHA) via the TpsB transporter FhaC. In this work, we show specific interactions between an N-terminal fragment of FHA containing the TPS domain and FhaC by using two different techniques, an overlay assay and a pull-down of the complex. FhaC recognizes only non-native conformations of the TPS domain, corroborating the model that in vivo, periplasmic FHA is not yet folded. By generating single amino acid substitutions, we have identified interaction determinants forming the secretion signal. They are found unexpectedly far into the TPS domain and include both conserved and variable residues, which most likely explains the specificity of the TpsA-TpsB interaction. The N-terminal domain of FhaC is involved in the FHA-FhaC interaction, in agreement with its proposed function and periplasmic localization.     

Substrate recognition by the POTRA domains of TpsB transporter FhaC

Widespread in Gram-negative bacteria, the two-partner secretion (TPS) pathway mediates the secretion of large, β-helical 'TpsA' proteins with various functions. TpsA proteins harbour a conserved, N-proximal TPS domain essential for secretion. TpsB transporters specifically recognize their TpsA partners in the periplasm and mediate their translocation across the outer membrane through a hydrophilic channel. The FHA/FhaC pair of Bordetella pertussis represents a model TPS system. FhaC is composed of a β barrel preceded by two periplasmic POTRA domains in tandem. Here we show that both POTRAs are involved in FHA recognition. Surface plasmon resonance analyses indicated an interaction of micromolar affinity between the POTRAs and the TPS domain with fast association and dissociation steps, consistent with the transient character of this interaction in vivo. Major interaction sites in POTRAs correspond to hydrophobic grooves formed by a β sheet edge and the flanking α helix, well-suited to accommodate extended, amphipathic strands of the substrate and consistent with β augmentation. The initial recruitment of the TPS domain to POTRAs appears to be facilitated by electrostatic attractions. A domain corresponding to the first part of the repeat-rich central region of FHA is also recognized by the POTRAs, suggesting successive interactions in the course of secretion.     

Two-partner secretion of gram-negative bacteria: a single β-barrel protein enables transport across the outer membrane

The mechanisms of protein secretion by pathogenic bacteria remain poorly understood. In gram-negative bacteria, the two-partner secretion pathway exports large, mostly virulence-related "TpsA" proteins across the outer membrane via their dedicated "TpsB" transporters. TpsB transporters belong to the ubiquitous Omp85 superfamily, whose members are involved in protein translocation across, or integration into, cellular membranes. The filamentous hemagglutinin/FhaC pair of Bordetella pertussis is a model two-partner secretion system. We have reconstituted the TpsB transporter FhaC into proteoliposomes and demonstrate that FhaC is the sole outer membrane protein required for translocation of its cognate TpsA protein. This is the first in vitro system for analyzing protein secretion across the outer membrane of gram-negative bacteria. Our data also provide clear evidence for the protein translocation function of Omp85 transporters.     

Novel topological features of FhaC, the outer membrane transporter involved in the secretion of the Bordetella pertussis filamentous hemagglutinin

Many pathogenic Gram-negative bacteria secrete virulence factors across the cell envelope into the extracellular milieu. The secretion of filamentous hemagglutinin (FHA) by Bordetella pertussis depends on the pore-forming outer membrane protein FhaC, which belongs to a growing family of protein transporters. Protein alignment and secondary structure predictions indicated that FhaC is likely to be a beta-barrel protein with an odd number of transmembrane beta-strands connected by large surface loops and short periplasmic turns. The membrane topology of FhaC was investigated by random insertion of the c-Myc epitope and the tobacco etch virus protease-specific cleavage sequence. FhaC was fairly permissive to short linker insertions. Furthermore, FhaC appeared to undergo conformational changes upon FHA secretion. Surface detection of the inserted sequences indicated that several predicted loops in the C-terminal moiety as well as the N terminus of the protein are exposed. However, a large surface-predicted region in the N-terminal moiety of FhaC was inaccessible from the surface. In addition, the activity and the stability of the protein were affected by insertions in that region, indicating that it may have important structural and/or functional roles. The surface exposure of the N terminus and the presence of an odd number of beta-strands are novel features for beta-barrel outer membrane proteins.     

Role of DegP for two-partner secretion in Bordetella

Sorting of proteins destined to the surface or the extracellular milieu is mediated by specific machineries, which guide the protein substrates towards the proper route of secretion and determine the compartment in which folding occurs. In Gram-negative bacteria, the two-partner secretion (TPS) pathway is dedicated to the secretion of large proteins rich in β-helical structure. The secretion of the filamentous haemagglutinin (FHA), a 230 kDa adhesin of Bordetella pertussis , represents a model TPS system. FHA is exported by the Sec machinery and transits through the periplasm in an extended conformation. From there it is translocated across the outer membrane by its dedicated transporter FhaC to finally fold into a long β-helix at the cell surface in a progressive manner. In this work, we show that B. pertussis lacking the periplasmic chaperone/protease DegP has a strong growth defect at 37°C, and the integrity of its outer membrane is compromised. While both phenotypes are significantly aggravated by the presence of FHA, the chaperone activity of DegP markedly alleviates the periplasmic stress. In vitro , DegP binds to non-native FHA with high affinity. We propose that DegP chaperones the extended FHA polypeptide in the periplasm and is thus involved in the TPS pathway.     

FhaC takes a bow to FHA in the two‐partner do‐si‐do

FhaC is an outer membrane transporter from Bordetella pertussis belonging to the t wo‐ p artner s ecretion (TPS) pathway with its primary role being the secretion of the virulence factor f ilamentous h aem a gglutinin (FHA). FhaC serves as a model transporter of the TPS pathway and significant work has been done to characterize the role of FhaC in FHA secretion. Recent studies characterized interactions between FHA and the POTRA domains of FhaC, suggesting that secretion may involve a successive translocation mechanism mediated by β‐augmentation and/or electrostatic interactions. Moreover, it was also shown that reconstituted FhaC is necessary and sufficient to transport FHA into proteoliposomes. While the crystal structure of FhaC clearly suggests a role in transport, the putative transport pore is plugged by an N‐terminal α‐helix (H1 helix) that occludes access by FHA. Therefore, it has been proposed that the H1 helix must be expelled from the pore in order for secretion of FHA to occur. However, this has yet to be shown experimentally. Guérin et al. (2014) report the first direct experimental evidence to show that the FhaC H1 helix is quite dynamic and exchanges between closed and open states upon interaction with FHA.     

Evidence that a globular conformation is not compatible with FhaC-mediated secretion of the Bordetella pertussis filamentous haemagglutinin

The 220 kDa Bordetella pertussis filamentous haemagglutinin (FHA) is the major extracellular protein of this organism. It is exported using a signal peptide-dependent pathway, and its secretion depends on one specific outer membrane accessory protein, FhaC. In this work, we have investigated the influence of conformation on the FhaC-mediated secretion of FHA using an 80 kDa N-terminal FHA derivative, Fha44. In contrast to many signal peptide-dependent secretory proteins, no soluble periplasmic intermediate of Fha44 could be isolated. In addition, cell-associated Fha44 synthesized in the absence of FhaC did not remain competent for extracellular secretion upon delayed expression of FhaC, indicating that the translocation steps across the cytoplasmic and the outer membrane might be coupled. A chimeric protein, in which the globular B subunit of the cholera toxin, CtxB, was fused at the C-terminus of Fha44, was not secreted in B. pertussis or in Escherichia coli expressing FhaC. The hybrid protein was only secreted when both disulphide bond-forming cysteines of CtxB were replaced by serines or when it was produced in DsbA^?E. coli. The Fha44 portion of the secretion-incompetent hybrid protein was partly exposed on the cell surface. These results argue that the Fha44–CtxB hybrid protein transited through the periplasmic space, where disulphide bond formation is specifically catalysed, and that secretion across the outer membrane was initiated. The folded CtxB portion prevented extracellular release of the hybrid, in contrast to the more flexible CtxB domain devoid of cysteines. We propose a secretion model whereby Fha44 transits through the periplasmic space on its way to the cell surface and initiates its translocation through the outer membrane before being released from the cytoplasmic membrane. Coupling of Fha44 translocation across both membranes would delay the acquisition of its folded structure until the protein emerges from the outer membrane. Such a model would be consistent with the extensive intracellular proteolysis of FHA derivatives in B. pertussis.     

Lack of functional complementation between Bordetella pertussis filamentous hemagglutinin and Proteus mirabilis HpmA hemolysin secretion machineries.

The gram-negative bacterium Bordetella pertussis has adapted specific secretion machineries for each of its major secretory proteins. In particular, the highly efficient secretion of filamentous hemagglutinin (FHA) is mediated by the accessory protein FhaC. FhaC belongs to a family of outer membrane proteins which are involved in the secretion of large adhesins or in the activation and secretion of Ca2+-independent hemolysins by several gram-negative bacteria. FHA shares with these hemolysins a 115-residue-long amino-proximal region essential for its secretion. To compare the secretory pathways of these hemolysins and FHA, we attempted functional transcomplementation between FhaC and the Proteus mirabilis hemolysin accessory protein HpmB. HpmB could not promote the secretion of FHA derivatives. Likewise, FhaC proved to be unable to mediate secretion and activation of HpmA, the cognate secretory partner of HpmB. In contrast, ShlB, the accessory protein of the closely related Serratia marcescens hemolysin, was able to activate and secrete HpmA. Two invariant asparagine residues lying in the region of homology shared by secretory proteins and shown to be essential for the secretion and activation of the hemolysins were replaced in FHA by site-directed mutagenesis. Replacements of these residues indicated that both are involved in, but only the first one is crucial to, FHA secretion. This slight discrepancy together with the lack of functional complementation demonstrates major differences between the hemolysins and FHA secretion machineries.     

The structure of the Haemophilus influenzae HMW1 pro-piece reveals a structural domain essential for bacterial two-partner secretion

In pathogenic Gram-negative bacteria, many virulence factors are secreted via the two-partner secretion pathway, which consists of an exoprotein called TpsA and a cognate outer membrane translocator called TpsB. The HMW1 and HMW2 adhesins are major virulence factors in nontypeable Haemophilus influenzae and are prototype two-partner secretion pathway exoproteins. A key step in the delivery of HMW1 and HMW2 to the bacterial surface involves targeting to the HMW1B and HMW2B outer membrane translocators by an N-terminal region called the secretion domain. Here we present the crystal structure at 1.92 A of the HMW1 pro-piece (HMW1-PP), a region that contains the HMW1 secretion domain and is cleaved and released during HMW1 secretion. Structural analysis of HMW1-PP revealed a right-handed beta-helix fold containing 12 complete parallel coils and one large extra-helical domain. Comparison of HMW1-PP and the Bordetella pertussis FHA secretion domain (Fha30) reveals limited amino acid homology but shared structural features, suggesting that diverse TpsA proteins have a common structural domain required for targeting to cognate TpsB proteins. Further comparison of HMW1-PP and Fha30 structures may provide insights into the keen specificity of TpsA-TpsB interactions.     

The prodomain of the Bordetella two‐partner secretion pathway protein FhaB remains intracellular yet affects the conformation of the mature C‐terminal domain

Two‐partner secretion (TPS) systems use β‐barrel proteins of the Omp85‐TpsB superfamily to transport large exoproteins across the outer membranes of Gram‐negative bacteria. The Bordetella FHA/FhaC proteins are prototypical of TPS systems in which the exoprotein contains a large C‐terminal prodomain that is removed during translocation. Although it is known that the FhaB prodomain is required for FHA function in vivo, its role in FHA maturation has remained mysterious. We show here that the FhaB prodomain is required for the extracellularly located mature C‐terminal domain (MCD) of FHA to achieve its proper conformation. We show that the C‐terminus of the prodomain is retained intracellularly and that sequences within the N‐terminus of the prodomain are required for this intracellular localization. We also identify sequences at the C‐terminus of the MCD that are required for release of mature FHA from the cell surface. Our data support a model in which the intracellularly located prodomain affects the final conformation of the extracellularly located MCD. We hypothesize that maturation triggers cleavage and degradation of the prodomain.     

Protein secretion through autotransporter and two-partner pathways

Two distinct protein secretion pathways, the autotransporter (AT) and the two-partner secretion (TPS) pathways are characterized by their apparent simplicity. Both are devoted to the translocation across the outer membrane of mostly large proteins or protein domains. As implied by their name, AT proteins contain their own transporter domain, covalently attached to the C-terminal extremity of the secreted passenger domain, while TPS systems are composed of two separate proteins, with TpsA being the secreted protein and TpsB its specific transporter. In both pathways, the secreted proteins are exported in a Sec-dependent manner across the inner membrane, after which they cross the outer membrane with the help of their cognate transporters. The AT translocator domains and the TpsB proteins constitute distinct families of protein-translocating, outer membrane porins of Gram-negative bacteria. Both types of transporters insert into the outer membrane as beta-barrel proteins possibly forming oligomeric pores in the case of AT and serve as conduits for their cognate secreted proteins or domains across the outer membrane. Translocation appears to be folding-sensitive in both pathways, indicating that AT passenger domains and TpsA proteins cross the periplasm and the outer membrane in non-native conformations and fold progressively at the cell surface. A major difference between AT and TPS pathways arises from the manner by which specificity is established between the secreted protein and its transporter. In AT, the covalent link between the passenger and the translocator domains ensures the translocation of the former without the need for a specific molecular recognition between the two modules. In contrast, the TPS pathway has solved the question of specific recognition between the TpsA proteins and their transporters by the addition to the TpsA proteins of an N-proximal module, the conserved TPS domain, which represents a hallmark of the TPS pathway.     

Conserved Residues of the Putative L6 Loop of Escherichia coli BamA Play a Critical Role in the Assembly of β-Barrel Outer Membrane Proteins, Including That of BamA Itself

Many members of the Omp85 family of proteins form essential β-barrel outer membrane protein (OMP) biogenesis machinery in Gram-negative bacteria, chloroplasts, and mitochondria. In Escherichia coli, BamA, a member of the Omp85 family, folds into an outer membrane-embedded β-barrel domain and a soluble periplasmic polypeptide-transport-associated (POTRA) domain. Although the high-resolution structures of only the BamA POTRA domain of E. coli are available, the crystal structure of FhaC, an Omp85 family member and a component of the two-partner secretion system in Bordetella pertussis, suggests that the BamA β-barrel likely folds into a 16-stranded β-barrel. The FhaC β-barrel is occluded by an N-terminal α-helix and a large β-barrel loop, L6, which carries residues that are highly conserved among the Omp85 family members. Deletion of L6 in FhaC did not affect its biogenesis but abolished its secretion function. In this study, we tested the hypothesis that the conserved residues of the putative L6 loop, which presumably folds back into the lumen of the BamA β-barrel like the FhaC counterpart, play an important role in OMP and/or BamA biogenesis. The conserved (641)RGF(643) residues of L6 were either deleted or replaced with alanine in various permutations. Phenotypic and biochemical characterization of various BamA L6 mutants revealed that the conserved RGF residues are critical for OMP biogenesis. Moreover, three BamA L6 alterations, ΔRGF, AAA, and AGA, produced a conditional lethal phenotype, concomitant with severely reduced BamA levels and folding defects. Thus, the conserved (641)RGF(643) residues of the BamA L6 loop are important for BamA folding and biogenesis.     

Distinct roles of the N-terminal and C-terminal precursor domains in the biogenesis of the Bordetella pertussis filamentous hemagglutinin.

The 220-kDa Bordetella pertussis filamentous hemagglutinin (FHA) is the major exported protein found in culture supernatants. The structural gene of FHA has a coding potential for a 367-kDa protein, and the mature form constitutes the N-terminal 60% of the 367-kDa precursor. The C-terminal domain of the precursor was found to be important for the high-level secretion of full-length FHA but not of truncated analogs (80 kDa or less). The secretion of full-length and truncated FHA polypeptides requires the presence of the approximately 100-amino-acid N-terminal domain and the outer membrane protein FhaC, homologous to the N-terminal domains of the Serratia marcescens and Proteus mirabilis hemolysins and their accessory proteins, respectively. By analogy to these hemolysins, it is likely that the N-terminal domain of the FHA precursor interacts, directly or indirectly, with the accessory protein during FHA biogenesis. However, immunogenicity and antigenicity studies suggest that the N-terminal domain of FHA is masked by its C-terminal domain and therefore should not be available for its interactions with FhaC. These observations suggest a model in which the C-terminal domain of the FHA precursor may play a role as an intramolecular chaperone to prevent premature folding of the protein. Both heparin binding and hemagglutination are expressed by the N-terminal half of FHA, indicating that this domain contains important functional regions of the molecule.     

EtpB Is a Pore-Forming Outer Membrane Protein Showing TpsB Protein Features Involved in the Two-Partner Secretion System

Attachment to host tissues is a critical step in the pathogenesis of most bacterial infections. Enterotoxigenic Escherichia coli (ETEC) remains one of the principal causes of infectious diarrhea in humans. The recent identification of additional ETEC surface molecules suggests that new targets may be exploited in vaccine development. The EtpA protein identified in ETEC H10407 is a large glycosylated adhesin secreted via the two-partner secretion system. EtpA requires its putative partner EtpB for translocation across the outer membrane (OM). We investigated the biochemical and electrophysiological properties of purified EtpB. We showed that EtpB is 65-kDa heat-modifiable protein localized to the OM. Electrophysiological experiments indicated that EtpB is able to form pores in planar lipid bilayer membranes with an asymmetric current, suggesting its functional asymmetry. The pore of EtpB frequently assumes an opened conformation and fluctuates between three well-defined conductance states. In silico analysis of the EtpB amino acid sequence and molecular modeling suggest that EtpB is similar to the well-known TpsB protein FhaC from Bordetella pertussis and has a C-terminal transmembrane β-barrel domain that is occluded by an N-terminal α-helix, an extracellular loop, and two periplasmic polypeptide-transport-associated (POTRA) domains. Together, these data confirm that EtpB is a pore-forming protein mainly folded into a β-barrel conformation and indicate that EtpB presents typical features of the OM TpsB proteins.     

System Specificity of the TpsB Transporters of Coexpressed Two-Partner Secretion Systems of Neisseria meningitidis

The two-partner secretion (TPS) systems of Gram-negative bacteria consist of a large secreted exoprotein (TpsA) and a transporter protein (TpsB) located in the outer membrane. TpsA targets TpsB for transport across the membrane via its ∼30-kDa TPS domain located at its N terminus, and this domain is also the minimal secretory unit. Neisseria meningitidis genomes encode up to five TpsAs and two TpsBs. Sequence alignments of TPS domains suggested that these are organized into three systems, while there are two TpsBs, which raised questions on their system specificity. We show here that the TpsB2 transporter of Neisseria meningitidis is able to secrete all types of TPS domains encoded in N. meningitidis and the related species Neisseria lactamica but not domains of Haemophilus influenzae and Pseudomonas aeruginosa. In contrast, the TpsB1 transporter seemed to be specific for its cognate N. meningitidis system and did not secrete the TPS domains of other meningococcal systems. However, TpsB1 did secrete the TPS2b domain of N. lactamica, which is related to the meningococcal TPS2 domains. Apparently, the secretion depends on specific sequences within the TPS domain rather than the overall TPS domain structure.     

Two-partner secretion in Gram-negative bacteria: a thrifty, specific pathway for large virulence proteins

A collection of large virulence exoproteins, including Ca2+-independent cytolysins, an iron acquisition protein and several adhesins, are secreted by the two-partner secretion (TPS) pathway in various Gram-negative bacteria. The hallmarks of the TPS pathway are the presence of an N-proximal module called the 'secretion domain' in the exoproteins that we have named the TpsA family, and the channel-forming beta-barrel transporter proteins we refer to as the TpsB family. The genes for cognate exoprotein and transporter protein are usually organized in an operon. Specific secretion signals are present in a highly conserved region of the secretion domain of TpsAs. TpsBs probably serve as specific receptors of the TpsA secretion signals and as channels for the translocation of the exoproteins across the outer membrane. A subfamily of transporters also mediates activation of their cognate cytolysins upon secretion. The exoproteins are synthesized as precursors with an N-terminal cleavable signal peptide, and a subset of them carries an extended signal peptide of unknown function. According to our current model, the exoproteins are probably translocated across the cytoplasmic membrane in a Sec-dependent fashion, and their signal peptide is probably processed by a LepB-type signal peptidase. The N-proximal secretion domain directs the exoproteins towards their transporters early, so that translocation across both membranes is coupled. The exoproteins transit through the periplasm in an extended conformation and fold progressively at the cell surface before eventually being released into the extracellular milieu. Several adhesins also undergo extensive proteolytic processing upon secretion. The genes of many new TpsAs and TpsBs are found in recently sequenced genomes, suggesting that the TPS pathway is widespread.     

The Polypeptide Transport-associated (POTRA) Domains of TpsB Transporters Determine the System Specificity of Two-partner Secretion Systems

The two-partner secretion (TPS) systems of Gram-negative bacteria secrete large TpsA exoproteins by a dedicated TpsB transporter in the outer membrane. TpsBs contain an N-terminal module located in the periplasm that includes two polypeptide transport-associated (POTRA) domains. These are thought to initiate secretion of a TpsA by binding its N-terminal secretion signal, called the TPS domain. Neisseria meningitidis encodes up to five TpsA proteins that are secreted via only two TpsB transporters: TpsB1 and TpsB2. Of these two, the TpsB2 recognizes the TPS domains of all TpsAs, despite their sequence diversity. By contrast, the TpsB1 shows a limited recognition of a TPS domain that is shared by two TpsAs. The difference in substrate specificity of the TpsBs enabled us to investigate the role of the POTRA domains in the selection of TPS domains. We tested secretion of TPS domains or full-length TpsAs by TpsB mutants with deleted, duplicated, and exchanged POTRA domains. Exchanging the two POTRA domains of a TpsB resulted in a switch in specificity. Furthermore, exchanging a single POTRA domain showed that each of the two domains contributed to the cargo selection. Remarkably, the order of the POTRA domains could be reversed without affecting substrate selection, but this aberrant order did result in an alternatively processed secretion product. Our results suggest that secretion of a TpsA is initiated by engaging both POTRA domains of a TpsB transporter and that these select the cognate TpsAs for secretion.