Limited tolerance towards folded elements during secretion of the autotransporter Hbp

Many virulence factors secreted by pathogenic Gram-negative bacteria belong to the autotransporter (AT) family. ATs consist of a passenger domain, which is the actual secreted moiety, and a beta-domain that facilitates the transfer of the passenger domain across the outer membrane. Here, we analysed folding and translocation of the AT passenger, using Escherichia coli haemoglobin protease (Hbp) as a model protein. Dual cysteine mutagenesis, instigated by the unique crystal structure of the Hbp passenger, resulted in intramolecular disulphide bond formation dependent on the periplasmic enzyme DsbA. A small loop tied off by a disulphide bond did not interfere with secretion of Hbp. In contrast, a bond between different domains of the Hbp passenger completely blocked secretion resulting in degradation by the periplasmic protease DegP. In the absence of DegP, a translocation intermediate accumulated in the outer membrane. A similar jammed intermediate was formed upon insertion of a calmodulin folding moiety into Hbp. The data suggest that Hbp can fold in the periplasm but must retain a certain degree of flexibility and/or modest width to allow translocation across the outer membrane.     

A conserved aromatic residue in the autochaperone domain of the autotransporter Hbp is critical for initiation of outer membrane translocation

Autotransporters are bacterial virulence factors that share a common mechanism by which they are transported to the cell surface. They consist of an N-terminal passenger domain and a C-terminal β-barrel, which has been implicated in translocation of the passenger across the outer membrane (OM). The mechanism of passenger translocation and folding is still unclear but involves a conserved region at the C terminus of the passenger domain, the so-called autochaperone domain. This domain functions in the stepwise translocation process and in the folding of the passenger domain after translocation. In the autotransporter hemoglobin protease (Hbp), the autochaperone domain consists of the last rung of the β-helix and a capping domain. To examine the role of this region, we have mutated several conserved aromatic residues that are oriented toward the core of the β-helix. We found that non-conservative mutations affected secretion with Trp(1015) in the cap region as the most critical residue. Substitution at this position yielded a DegP-sensitive intermediate that is located at the periplasmic side of the OM. Further analysis revealed that Trp(1015) is most likely required for initiation of processive folding of the β-helix at the cell surface, which drives sequential translocation of the Hbp passenger across the OM.     

The Inverse Autotransporter Intimin Exports Its Passenger Domain via a Hairpin Intermediate

Autotransporter proteins comprise a large family of virulence factors that consist of a β-barrel translocation unit and an extracellular effector or passenger domain. The β-barrel anchors the protein to the outer membrane of Gram-negative bacteria and facilitates the transport of the passenger domain onto the cell surface. By inserting an epitope tag into the N terminus of the passenger domain of the inverse autotransporter intimin, we generated a mutant defective in autotransport. Using this stalled mutant, we could show that (i) at the time point of stalling, the β-barrel appears folded; (ii) the stalled autotransporter is associated with BamA and SurA; (iii) the stalled intimin is decorated with large amounts of SurA; (iv) the stalled autotransporter is not degraded by periplasmic proteases; and (v) inverse autotransporter passenger domains are translocated by a hairpin mechanism. Our results suggest a function for the BAM complex not only in insertion and folding of the β-barrel but also for passenger translocation.     

Intimin-mediated export of passenger proteins requires maintenance of a translocation-competent conformation

Intimins from pathogenic bacteria promote intimate bacterial adhesion to epithelial cells. Several structurally similar domains form on the bacterial cell surface an extended rigid rod that exposes the carboxy-terminal domain, which interacts with the translocated intimin receptor. We constructed a series of intimin-derived fusion proteins consisting of carboxy-terminally truncated intimin and the immunoglobulin light-chain variable domain REIv, ubiquitin, calmodulin, beta-lactamase inhibitor protein, or beta-lactamase. By systematically investigating the intimin-mediated cell surface exposure of these passenger domains in the presence or absence of compounds that interfere with outer membrane stability or passenger domain folding, we acquired experimental evidence that intimin-mediated protein export across the outer membrane requires, prior to export, the maintenance of a translocation-competent conformation that may be distinct from the final protein structure. We propose that, during export, competition exists between productive translocation and folding of the passenger domain in the periplasm into a stable conformation that is not compatible with translocation through the bacterial outer membrane. These results may expand understanding of the mechanism by which intimins are inserted into the outer membrane and expose extracellular domains on the cell surface.     

Signal Peptide-rheostat Dynamics Delay Secretory Preprotein Folding

Sec secretory proteins are distinguished from cytoplasmic ones by N-terminal signal peptides with multiple roles during post-translational translocation. They contribute to preprotein targeting to the translocase by slowing down folding, binding receptors and triggering secretion. While signal peptides get cleaved after translocation, mature domains traffic further and/or fold into functional states. How signal peptides delay folding temporarily, to keep mature domains translocation-competent, remains unclear. We previously reported that the foldon landscape of the periplasmic prolyl-peptidyl isomerase is altered by its signal peptide and mature domain features. Here, we reveal that the dynamics of signal peptides and mature domains crosstalk. This involves the signal peptide’s hydrophobic helical core, the short unstructured connector to the mature domain and the flexible rheostat at the mature domain N-terminus. Through this cis mechanism the signal peptide delays the formation of early initial foldons thus altering their hierarchy and delaying mature domain folding. We propose that sequence elements outside a protein’s native core exploit their structural dynamics to influence the folding landscape.     

Autodisplay: functional display of active beta-lactamase on the surface of Escherichia coli by the AIDA-I autotransporter

Members of the protein family of immunoglobulin A1 protease-like autotransporters comprise multidomain precursors consisting of a C-terminal autotransporter domain that promotes the translocation of N-terminally attached passenger domains across the cell envelopes of gram-negative bacteria. Several autotransporter domains have recently been shown to efficiently promote the export of heterologous passenger domains, opening up an effective tool for surface display of heterologous proteins. Here we report on the autotransporter domain of the Escherichia coli adhesin involved in diffuse adherence (AIDA-I), which was genetically fused to the C terminus of the periplasmic enzyme beta-lactamase, leading to efficient expression of the fusion protein in E. coli. The beta-lactamase moiety of the fusion protein was presented on the bacterial surface in a stable manner, and the surface-located beta-lactamase was shown to be enzymatically active. Enzymatic activity was completely removed by protease treatment, indicating that surface display of beta-lactamase was almost quantitative. The periplasmic domain of the outer membrane protein OmpA was not affected by externally added proteases, demonstrating that the outer membranes of E. coli cells expressing the beta-lactamase AIDA-I fusion protein remained physiologically intact.     

Concerted folding and binding of a flexible colicin domain to its periplasmic receptor TolA

Compared with folded structures, natively unfolded protein domains are over-represented in protein-protein and protein-DNA interactions. Such domains are common features of all colicins and are required for their translocation across the outer membrane of the target Escherichia coli cell. All of these domains bind to at least one periplasmic protein of the Tol or Ton family. Similar domains are found in Ton-dependent outer membrane transporters, indicating they may interact in a related manner. In this article we have studied binding of the colicin N translocation domain to its periplasmic receptor TolA, by fluorescence resonance energy transfer (FRET) using fluorescent probes attached to engineered cysteine residues and NMR techniques. The domain exhibits a random coil circular dichroism spectrum. However, FRET revealed that guanidinium hydrochloride denaturation caused increases in all measured intramolecular distances showing that, although natively unfolded, the domain is not extended. Furthermore NMR reported a compact hydrodynamic radius of 18 A. Nevertheless the FRET-derived distances changed upon binding to TolA indicating a significant structural rearrangement. Using 1H-15N NMR we show that, when bound, the peptide switches from a disordered state to an ordered state. The kinetics of binding and the associated structural change were measured by stopped-flow methods, and both events appear to occur simultaneously. The data therefore suggest that this molecular recognition involves the concerted binding and folding of a flexible but collapsed state.     

Multiple Driving Forces Required for Efficient Secretion of Autotransporter Virulence Proteins

Autotransporter (AT) proteins are a broad class of virulence proteins from Gram-negative bacterial pathogens that require their own C-terminal transmembrane domain to translocate their N-terminal passenger across the bacterial outer membrane (OM). But given the unavailability of ATP or a proton gradient across the OM, it is unknown what energy source(s) drives this process. Here we used a combination of computational and experimental approaches to quantitatively compare proposed AT OM translocation mechanisms. We show directly for the first time that when translocation was blocked an AT passenger remained unfolded in the periplasm. We demonstrate that AT secretion is a kinetically controlled, non-equilibrium process coupled to folding of the passenger and propose a model connecting passenger conformation to secretion kinetics. These results reconcile seemingly contradictory reports regarding the importance of passenger folding as a driving force for OM translocation but also reveal that another energy source is required to initiate translocation.     

Roles of Periplasmic Chaperone Proteins in the Biogenesis of Serine Protease Autotransporters of Enterobacteriaceae

The serine protease autotransporters of Enterobacteriaceae (SPATEs) represent a large family of virulence factors. The prevailing model for autotransporter secretion comprises entry to the periplasm via the Sec apparatus, followed by an obscure series of steps in which the C terminus of the periplasmic species inserts into the outer membrane as a β-barrel protein, accompanied by translocation of the passenger domain to the bacterial cell surface. Little is known about the fate of the autotransporter proteins in the periplasm, including whether accessory periplasmic proteins are involved in translocation to the external milieu. Here we studied the role of the major periplasmic chaperones in the biogenesis of EspP, a prototype SPATE protein produced by Escherichia coli O157:H7. The yeast two-hybrid approach, secretion analysis of chaperone mutant strains, and surface plasmon resonance analysis (SPR) revealed direct protein-protein interactions between the periplasmic SurA and DegP chaperones and either the EspP-β or EspP passenger domains. The secretion of EspP was moderately reduced in the surA and skp mutant strains but severely impaired in the degP background. Site-directed mutagenesis of highly conserved aromatic amino acid residues in the SPATE family resulted in ∼80% reduction of EspP secretion. Synthetic peptides containing aromatic residues derived from the EspP passenger domain blocked DegP and SurA binding to the passenger domain. SPR suggested direct protein-protein interaction between periplasmic chaperones and the unfolded EspP passenger domain. Our data suggest that translocation of AT proteins may require accessory factors, calling into question the moniker “autotransporter.”Secretion of proteins to the surface of gram-negative bacteria requires passage through the inner membrane (IM), the periplasm, and the outer membrane (OM). This formidable series of obstacles can be overcome only by complex biological processes. The autotransporter (AT) system, probably the most common gram-negative secretion mechanism (13), is characterized by formation of an OM β-barrel comprised of the C terminus of the periplasmic species. The precise events required for AT translocation across the OM, however, are controversial. The original model for OM translocation comprised targeting to the periplasm via the Sec apparatus, followed by formation of an OM β-barrel, which mediates passage of an unfolded or partially folded N-terminal passenger domain to the extracellular milieu (30). Three models of AT translocation have gained some acceptance (3, 16). According to the hairpin model, translocation of the passenger domain is initiated with the C-terminal end of the passenger forming a hairpin structure inside the AT β-barrel, followed by movement of the rest of the passenger through the barrel''s pore in a C-to-N direction. Under the Omp85 model, the pore-forming Omp85 (YaeT in Escherichia coli) OM protein (OMP) facilitates insertion of the AT translocator domain into the OM, whereupon the AT passenger domain translocates through the Omp85 pore. A third model entails the combination of the hairpin and Omp85 models, including concerted insertion and translocation. All models must reconcile observations seemingly in conflict. Bernstein and colleagues reported cleavage of the mature passenger by a protease located inside the C-terminal AT barrel (10); yet, the dimensions of the folded AT barrel channel are by most accounts too narrow to accommodate even a partially folded passenger species, which is suggested from experimental periplasmic disulfide bond formation within the passenger domain (7, 19, 21).The term “autotransporter” was initially proposed on the assumption that the translocated species contained all necessary information for movement to the extracellular space. We and others have challenged that assumption (11, 14). Recently, several periplasmic proteins have been implicated in the targeting and assembly of extracytoplasmic proteins, principally OMPs (27). Three biological functions have been recognized for these periplasmic proteins: (i) molecular chaperones such as DegP, SurA, Skp, FkpA, PpiA, and PpiD (1, 5, 8, 9, 23, 26) stabilize nonnative conformations of target proteins and facilitate their folding; (ii) peptidyl-prolyl cis-trans isomerases, such as SurA, PpiD, and FkpA (9, 33, 36), catalyze the rate-limiting steps of isomerization during folding; and (iii) proteases, such as DegP and DegQ (22), degrade unproductive or misfolded proteins. Recent reports have suggested the involvement of chaperones during the passage of the AT through the periplasm (31, 43), although the mechanisms have not been defined.Here we demonstrate further the requirement for periplasmic chaperones in the biogenesis of the serine protease ATs of Enterobacteriaceae (SPATEs). Our data suggest a requirement for these periplasmic factors in translocation and suggest direct binding of the chaperone proteins to specific highly conserved motifs in the AT passenger and β-domains.     

Requirements for translocation of periplasmic domains in polytopic membrane proteins.

Periplasmic domains of cytoplasmic membrane proteins require export signals for proper translocation. These signals were studied by using a MalF-alkaline phosphatase fusion in a genetic selection that allowed the isolation of mislocalization mutants. In the original construct, alkaline phosphatase is fused to the second periplasmic domain of the membrane protein, and its activity is thus confined exclusively to the periplasm. Mutants that no longer translocated alkaline phosphatase were selected by complementation of a serB mutation. A total of 11 deletions in the amino terminus were isolated, all of which spanned at least the third transmembrane segment. This domain immediately precedes the periplasmic domain to which alkaline phosphatase was fused. Our results obtained in vivo support the model that amino-terminal membrane-spanning segments are required for translocation of large periplasmic domains. In addition, we found that the inability to export the alkaline phosphatase domain could be suppressed by a mutation, prlA4, in the secretion apparatus.     

Cotranslational Translocation and Folding of a Periplasmic Protein Domain in Escherichia coli

In Gram-negative bacteria, periplasmic domains in inner membrane proteins are cotranslationally translocated across the inner membrane through the SecYEG translocon. To what degree such domains also start to fold cotranslationally is generally difficult to determine using currently available methods. Here, we apply Force Profile Analysis (FPA) – a method where a translational arrest peptide is used to detect folding-induced forces acting on the nascent polypeptide – to follow the cotranslational translocation and folding of the large periplasmic domain of the E. coli inner membrane protease LepB in vivo. Membrane insertion of LepB’s two N-terminal transmembrane helices is initiated when their respective N-terminal ends reach 45–50 residues away from the peptidyl transferase center (PTC) in the ribosome. The main folding transition in the periplasmic domain involves all but the ~15 most C-terminal residues of the protein and happens when the C-terminal end of the folded part is ~70 residues away from the PTC; a smaller putative folding intermediate is also detected. This implies that wildtype LepB folds post-translationally in vivo, and shows that FPA can be used to study both co- and post-translational protein folding in the periplasm.     

Size and conformation limits to secretion of disulfide-bonded loops in autotransporter proteins

Autotransporters are a superfamily of virulence factors typified by a channel-forming C terminus that facilitates translocation of the functional N-terminal passenger domain across the outer membrane of Gram-negative bacteria. This final step in the secretion of autotransporters requires a translocation-competent conformation for the passenger domain that differs markedly from the structure of the fully folded secreted protein. The nature of the translocation-competent conformation remains controversial, in particular whether the passenger domain can adopt secondary structural motifs, such as disulfide-bonded segments, while maintaining a secretion-competent state. Here, we used the endogenous and closely spaced cysteine residues of the plasmid-encoded toxin (Pet) from enteroaggregative Escherichia coli to investigate the effect of disulfide bond-induced folding on translocation of an autotransporter passenger domain. We reveal that rigid structural elements within disulfide-bonded segments are resistant to autotransporter-mediated secretion. We define the size limit of disulfide-bonded segments tolerated by the autotransporter system demonstrating that, when present, cysteine pairs are intrinsically closely spaced to prevent congestion of the translocator pore by large disulfide-bonded regions. These latter data strongly support the hairpin mode of autotransporter biogenesis.     

Structural tolerance of bacterial autotransporters for folded passenger protein domains

In this report we investigate the capacity of bacterial autotransporters (AT) to translocate folded protein domains across the outer membrane (OM). Polypeptides belonging to the AT family contain a C-terminal domain that supports the secretion of the N-domain (the passenger) across the OM of Gram-negative bacteria. Despite some controversial data, it has been widely accepted that N-passenger domains of AT must be unfolded and devoid of disulphide bonds for efficient translocation. To address whether or not AT are able to translocate folded protein domains across the OM, we employed several types of recombinant antibodies as heterologous N-passengers of the transporter C-domain of IgA protease (C-IgAP) of Neisseria gonorroheae. The N-domains used were single chain Fv fragments (scFv) and variable mono-domains derived from camel antibodies (V(HH)) selected on the basis of their distinct and defined folding properties (i.e. enhanced solubility, stability and presence or not of disulphide bonds). Expression of these hybrids in Escherichia coli shows that stable scFv and V(HH) domains are efficiently (>99%) translocated towards the bacterial surface regardless of the presence or not of disulphide bonds on their structure. Antigen-binding assays demonstrate that surface-exposed scFv and V(HH) domains are correctly folded and thus able to bind their cognate antigens. Expression of scFv- or V(HH)-C-IgAP hybrids in E. coli dsbA or fkpA mutant cells reveals that these periplasmic protein chaperones fold these N-domains before their translocation across the OM. Furthermore, large N-passengers composed of strings of V(HH) domains were secreted in a folded state by AT with no loss of efficacy (>99%) despite having multiple disulphide bonds. Thus AT can efficiently translocate toward the cell surface folded N-passengers composed of one, two or three immunoglobulin (Ig) domains, each with a folded diameter between approximately 2 nm and having disulphide bonds. This tolerance for folded protein domains of approximately 2 nm fits with the diameter of the central hydrophilic channel proposed for the ring-like oligomeric complex assembled by C-IgAP in the OM.     

A conserved region within the Bordetella pertussis autotransporter BrkA is necessary for folding of its passenger domain

Autotransporter secretion represents a unique mechanism that Gram-negative bacteria employ to deliver proteins to their cell surface. BrkA is a Bordetella pertussis autotransporter protein that mediates serum resistance and contributes to adherence of the bacterium to host cells. BrkA is a 103 kDa protein that is cleaved to form a 73 kDa alpha-domain and a 30 kDa beta domain. The alpha domain, also referred to as the passenger domain, is responsible for the effector functions of the protein, whereas the beta domain serves as a transporter. In an effort to characterize BrkA secretion, we have shown that BrkA has a 42 amino acid signal peptide for transit across the cytoplasmic membrane, and a translocation unit made up of a short linker region fused to the beta-domain to ferry the passenger domain to the bacterial surface through a channel formed by the beta-domain. In this report, we provide genetic, biochemical and structural evidence demonstrating that a region within the BrkA passenger (Glu601-Ala692) is necessary for folding the passenger. This region is not required for surface display in the outer membrane protease OmpT-deficient Escherichia coli strain UT5600. However, a BrkA mutant protein bearing a deletion in this region is susceptible to digestion when expressed in E. coli strains expressing OmpT suggesting that the region is required to maintain a stable structure. The instability of the deletion mutant can be rescued by surface expressing Glu601-Ala692in trans suggesting that this region is acting as an intramolecular chaperone to effect folding of the passenger concurrent with or following translocation across the outer membrane.     

The glucose transporter of the Escherichia coli phosphotransferase system: linker insertion mutants and split variants

The IICB(Glc) subunit of the glucose transporter acts by a mechanism which couples vectorial translocation with phosphorylation of the substrate. It contains 8 transmembrane segments connected by 4 periplasmic, 2 short, 1 long (80 residues), cytoplasmic loops and an independently folding cytoplasmic domain at the C-terminus. Random DNase I cleavage, EcoRI linker insertion, and screening for transport-active mutants afforded 12 variants with between 46% and 116% of wild-type sugar phosphorylation activity. They carried inserts of up to 29 residues and short deletions in periplasmic loops 1, 2, and 3, in the long cytoplasmic loop 3, and in the linker region between the membrane spanning IIC(Glc) and the cytoplasmic IIB(Glc) domains. Disruption of the gene at the sites of linker insertion decreased the expression level and diminished phosphotransferase activity to between 7% and 32%. IICB(Glc) with a discontinuity in the cytoplasmic loop was purified to homogeneity as a stable complex. It was active only if encoded by a dicistronic operon but not if encoded by two genes on two different replicons, suggesting that spatial proximity of the nascent polypeptide chains is important for folding and membrane assembly.     

Autodisplay: one-component system for efficient surface display and release of soluble recombinant proteins from Escherichia coli.

The immunoglobulin A protease family of secreted proteins are derived from self-translocating polyprotein precursors which contain C-terminal domains promoting the translocation of the N-terminally attached passenger domains across gram-negative bacterial outer membranes. Computer predictions identified the C-terminal domain of the Escherichia coli adhesin involved in diffuse adherence (AIDA-I) as a member of the autotransporter family. A model of the beta-barrel structure, proposed to be responsible for outer membrane translocation, served as a basis for the construction of fusion proteins containing heterologous passengers. Autotransporter-mediated surface display (autodisplay) was investigated for the cholera toxin B subunit and the peptide antigen tag PEYFK. Up to 5% of total cellular protein was detectable in the outer membrane as passenger autotransporter fusion protein synthesized under control of the constitutive P(TK) promoter. Efficient presentation of the passenger domains was demonstrated in the outer membrane protease T-deficient (ompT) strain E. coli UT5600 and the ompT dsbA double mutant JK321. Surface exposure was ascertained by enzyme-linked immunosorbent assay, immunofluorescence microscopy, and immunogold electron microscopy using antisera specific for the passenger domains. In strain UT2300 (ompT+), the passenger domains were released from the cell surface by the OmpT protease at a novel specific cleavage site, R / V. Autodisplay represents a useful tool for future protein translocation studies with interesting biotechnological possibilities.     

Dislocation of membrane proteins in FtsH-mediated proteolysis.

Escherichia coli FtsH degrades several integral membrane proteins, including YccA, having seven transmembrane segments, a cytosolic N-terminus and a periplasmic C-terminus. Evidence indicates that FtsH initiates proteolysis at the N-terminal cytosolic domain. SecY, having 10 transmembrane segments, is also a substrate of FtsH. We studied whether and how the FtsH-catalyzed proteolysis on the cytosolic side continues into the transmembrane and periplasmic regions using chimeric proteins, YccA-(P3)-PhoA-His6-Myc and SecY-(P5)-PhoA, with the alkaline phosphatase (PhoA) mature sequence in a periplasmic domain. The PhoA domain that was present within the fusion protein was rapidly degraded by FtsH when it lacked the DsbA-dependent folding. In contrast, both PhoA itself and the TM9-PhoA region of SecY-(P5)-PhoA were stable when expressed as independent polypeptides. In the presence of DsbA, the FtsH-dependent degradation stopped at a site near to the N-terminus of the PhoA moiety, leaving the PhoA domain (and its C-terminal region) undigested. The efficiency of this degradation stop correlated well with the rapidity of the folding of the PhoA domain. Thus, both transmembrane and periplasmic domains are degraded by the processive proteolysis by FtsH, provided they are not tightly folded. We propose that FtsH dislocates the extracytoplasmic domain of a substrate, probably using its ATPase activity.     

The soluble, periplasmic domain of OmpA folds as an independent unit and displays chaperone activity by reducing the self-association propensity of the unfolded OmpA transmembrane β-barrel

OmpA is one of only a few transmembrane proteins whose folding and stability have been investigated in detail. However, only half of the OmpA mass encodes its transmembrane β-barrel; the remaining sequence is a soluble domain that is localized to the periplasmic side of the outer membrane. To understand how the OmpA periplasmic domain contributes to the stability and folding of the full-length OmpA protein, we cloned, expressed, purified and studied the OmpA periplasmic domain independently of the OmpA transmembrane β-barrel region. Our experiments showed that the OmpA periplasmic domain exists as an independent folding unit with a free energy of folding equal to − 6.2 (± 0.1) kcal mol^-1 at 25 °C. Using circular dichroism, we determined that the OmpA periplasmic domain adopts a mixed alpha/beta secondary structure, a conformation that has previously been used to describe the partially folded non-native state of the full-length OmpA. We further discovered that the OmpA periplasmic domain reduces the self-association propensity of the unfolded barrel domain, but only when covalently attached (in cis). In vitro folding experiments showed that self-association competes with β-barrel folding when allowed to occur before the addition of membranes, and the periplasmic domain enhances the folding efficiency of the full-length protein by reducing its self-association. These results identify a novel chaperone function for the periplasmic domain of OmpA that may be relevant for folding in vivo. We have also extensively investigated the properties of the self-association reaction of unfolded OmpA and found that the transmembrane region must form a critical nucleus comprised of three molecules before undergoing further oligomerization to form large molecular weight species. Finally, we studied the conformation of the unfolded OmpA monomer and found that the folding-competent form of the transmembrane region adopts an expanded conformation, which is in contrast to previous studies that have suggested a collapsed unfolded state.     

Autotransporter β-domains have a specific function in protein secretion beyond outer-membrane targeting

Autotransporters (ATs) of Gram-negative bacteria contain an N-proximal passenger domain that is transported to the extracellular milieu and a C-terminal β-domain that inserts into the outer membrane (OM) in a β-barrel conformation. This β-domain facilitates translocation of the passenger domain across the OM and has long been considered to be the translocation pore. However, available crystal structures of β-domains show that the β-barrel pore is too narrow for the observed transport of folded elements within the passenger domains. ATs have recently been shown to interact with the β-barrel assembly machinery. These findings questioned a direct involvement of the β-domain in passenger translocation and suggested that it may only target the passenger to the β-barrel assembly machinery pore. To address the function of the β-domain in more detail, we have replaced the β-domain of the Escherichia coli AT hemoglobin protease by β-domains originating from other OM proteins. Furthermore, we have modified the diameter of the β-domain pore. The mutant proteins were analyzed for their capacity to insert into the OM and for surface display of the passenger. Our results show that efficient passenger secretion requires a specific β-domain that not only functions as a targeting device but also is directly involved in the translocation of the passenger to the cell surface.     

Crystal Structure of a Full-Length Autotransporter

The autotransporter (AT) secretion mechanism is the most common mechanism for the secretion of virulence factors across the outer membrane (OM) from pathogenic Gram-negative bacteria. In addition, ATs have attracted biotechnological and biomedical interest for protein display on bacterial cell surfaces. Despite their importance, the mechanism by which passenger domains of ATs pass the OM is still unclear. The classical view is that the β-barrel domain provides the conduit through which the unfolded passenger moves, with the energy provided by vectorial folding of the β-strand-rich passenger on the extracellular side of the OM. We present here the first structure of a full-length AT, the esterase EstA from Pseudomonas aeruginosa, at a resolution of 2.5 Å. EstA has a relatively narrow, 12-stranded β-barrel that is covalently attached to the passenger domain via a long, curved helix that occupies the lumen of the β-barrel. The passenger has a structure that is dramatically different from that of other known passengers, with a globular fold that is dominated by α-helices and loops. The arrangement of secondary-structure elements suggests that the passenger can fold sequentially, providing the driving force for passenger translocation. The esterase active-site residues are located at the apical surface of the passenger, at the entrance of a large hydrophobic pocket that contains a bound detergent molecule that likely mimics substrate. The EstA structure provides insight into AT mechanism and will facilitate the design of fusion proteins for cell surface display.