Comparative Analysis of the Biochemical and Functional Properties of C-Terminal Domains of Autotransporters

Autotransporters (ATs) are the largest group of proteins secreted by Gram-negative bacteria and include many virulence factors from human pathogens. ATs are synthesized as large precursors with a C-terminal domain that is inserted in the outer membrane (OM) and is essential for the translocation of an N-terminal passenger domain to the extracellular milieu. Several mechanisms have been proposed for AT secretion. Self-translocation models suggest transport across a hydrophilic channel formed by an internal pore of the β-barrel or by the oligomerization of C-terminal domains. Alternatively, an assisted-translocation model suggests that transport employs a conserved machinery of the bacterial OM such as the Bam complex. In this work we have investigated AT secretion by carrying out a comparative study to analyze the conserved biochemical and functional features of different C-terminal domains selected from ATs of gammaproteobacteria, betaproteobacteria, alphaproteobacteria, and epsilonproteobacteria. Our results indicate that C-terminal domains having an N-terminal α-helix and a β-barrel constitute functional transport units for the translocation of peptides and immunoglobulin domains with disulfide bonds. In vivo and in vitro analyses show that multimerization is not a conserved feature in AT C-terminal domains. Furthermore, we demonstrate that the deletion of the conserved α-helix severely impairs β-barrel folding and OM insertion and thereby blocks passenger domain secretion. These observations suggest that the AT β-barrel without its α-helix cannot form a stable hydrophilic channel in the OM for protein translocation. The implications of our data for an understanding of AT secretion are discussed.The classical autotransporter (AT) family, also known as the type Va protein secretion system, represents the largest group of proteins secreted by Gram-negative bacteria and includes many virulence factors from important human pathogens (10, 17). Bacteria produce AT proteins as large polypeptide precursors, with their virulence activity (e.g., cytotoxins, adhesins, and proteases, etc.) present in a passenger domain flanked by an N-terminal signal peptide (sp) for Sec-dependent translocation across the bacterial inner membrane (IM) and a C-terminal domain of ∼30 to 40 kDa for insertion into the bacterial outer membrane (OM) (see Fig. 2A). A self-translocation model was originally proposed to explain the secretion mechanism of AT proteins across the OM, based mostly on data obtained with the IgA protease (IgAP) from Neisseria gonorrhoeae (43). In this model the C-terminal domain of ATs was supposed to fold in the OM as a β-barrel protein with an internal hydrophilic pore that could be used for the translocation of the passenger domain. The finding that the B subunit of cholera toxin (CtxB) should not have disulfide bonds for its secretion when fused as a heterologous passenger to the C-terminal domain of IgAP (30, 31) indirectly suggests passenger translocation in an unfolded conformation through a narrow channel expected for a β-barrel. Similar observations with the C-terminal domains of IcsA from Shigella flexneri (56) and AIDA-I from Escherichia coli (36) supported this model.Previous work done by our group challenged the original self-translocation model, since a 45-kDa C-terminal fragment of IgAP was shown to form oligomeric ring-shaped complexes with a central hydrophilic pore of ∼2 nm (63). In addition, this C-terminal fragment of IgAP was found to translocate folded immunoglobulin (Ig) domains with disulfide bonds to the bacterial surface, indicating that at least a ∼2-nm pore was being used for passenger secretion (61, 62). These data led us to propose a “multimeric” version of the self-translocation model in which the secretion of the passenger may occur through the central channel assembled by the oligomerization of the C-terminal domains in the OM. Studies with IcsA from S. flexneri (7, 46, 47, 64) and EspP from E. coli (53) also provided evidence indicating that native and heterologous passengers adopt folded or at least partially folded conformations in the periplasm before OM translocation. Conversely, a limited capacity for the translocation of folded native passengers with engineered disulfide bonds has been reported by studies with Hbp from E. coli (23) and pertactin from Bordetella pertussis (24). Crystallographic structures of the C-terminal domains of NalP from Neisseria meningitidis (41) and EspP from E. coli (2) revealed distinct β-barrel folding with 12 amphipathic β-strands and one N-terminal α-helix filling the central hydrophilic pore of the β-barrel. No indication of oligomerization was obtained with the crystallographic data. In addition, the putative protein-conducting channels of the EspP and NalP β-barrels (of ∼1 nm in diameter) were found to be closed due to the presence of the internal α-helix, which would impede the transport of passenger polypeptides (either folded or unfolded) through the reported structures. Thus, an alternative model was proposed for the assisted translocation of ATs (3, 41), in which the protein-conducting channel for secretion across the OM would be provided by the conserved Bam complex. The Bam complex is required for the insertion of β-barrel proteins (32), and the depletion of its essential component BamA (formerly YaeT in E. coli and Omp85 in Neisseria) prevents the insertion of several ATs in the OM (i.e., IcsA and SepA from S. flexneri, AIDA-I and Hbp from E. coli, and BrkA from B. pertussis) (21, 50). BamA was reported to form hydrophilic pores in lipid membranes in vitro (54) and to cross-link in vivo with the passenger domain of a slow-secretion mutant of EspP (19), which supports a role for BamA in translocation.Despite the above-described progress made in our understanding of ATs, their actual molecular mechanism of secretion remains uncertain. This is partially because the reported information is based on studies with different model AT proteins and nonhomogenous experimental approaches used by different laboratories, which sometimes produce data that are difficult to compare or may be conflicting. Here, we report a comparative study to determine conserved biochemical and functional properties found in AT C-terminal domains. Following a uniform experimental approach for six AT C-terminal domains selected from the gammaproteobacteria, betaproteobacteria, alphaproteobacteria, and epsilonproteobacteria, we have investigated their capacities for the secretion of peptides and globular domains, their pore formation and oligomerization properties, and their requirement for an N-terminal α-helix for AT function and C-terminal domain stability. Our results shed light on the secretion mechanism of ATs from the conserved structural features found in their C-terminal domains.     

A structurally informed autotransporter platform for efficient heterologous protein secretion and display

ABSTRACT: BACKGROUND: The self-sufficient Autotransporter (AT) pathway, ubiquitous in Gram-negative bacteria, combines a relatively simple protein secretion mechanism with a high transport capacity. ATs consist of a secreted passenger domain and a beta-domain that facilitates transfer of the passenger across the cell-envelope. They have a great potential for the extracellular expression of recombinant proteins but their exploitation has suffered from the limited structural knowledge of carrier ATs. Capitalizing on its crystal structure, we have engineered the Escherichia coli AT Hemoglobin protease (Hbp) into a platform for the secretion and surface display of heterologous proteins, using the Mycobacterium tuberculosis vaccine target ESAT6 as a model protein. RESULTS: Based on the Hbp crystal structure, five passenger side domains were selected and one by one replaced by ESAT6, whereas a beta-helical core structure (beta-stem) was left intact. The resulting Hbp-ESAT6 chimeras were efficiently and stably secreted into the culture medium of E. coli. On the other hand, Hbp-ESAT6 fusions containing a truncated beta-stem appeared unstable after translocation, demonstrating the importance of an intact beta-stem. By interrupting the cleavage site between passenger and beta-domain, Hbp-ESAT6 display variants were constructed that remain cell associated and facilitate efficient surface exposure of ESAT6 as judged by proteinase K accessibility and whole cell immuno-EM analysis. Upon replacement of the passenger side domain of an alternative AT, EspC, ESAT6 was also efficiently secreted, showing the approach is more generally applicable to ATs. Furthermore, Hbp-ESAT6 was efficiently displayed in an attenuated Salmonella typhimurium strain upon chromosomal integration of a single encoding gene copy, demonstrating the potential of the Hbp platform for live vaccine development. CONCLUSIONS: We developed the first structurally informed AT platform for efficient secretion and surface display of heterologous proteins. The platform has potential with regard to the development of recombinant live vaccines and may be useful for other biotechnological applications that require high-level secretion or display of recombinant proteins by bacteria.     

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.     

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.     

A functional analysis of Wnt inducible signalling pathway protein ?1 (WISP-1/CCN4)

Wnt-1 inducible signalling pathway protein 1 (WISP-1/CCN4) is an extracellular matrix protein that belongs to the Cyr61 (cysteine-rich protein 61), CTGF (connective tissue growth factor) and NOV (CCN) family and plays a role in multiple cellular processes. No specific WISP-1 receptors have been identified but emerging evidence suggests WISP-1 mediates its downstream effects by binding to integrins. Here we describe a functional analysis of integrin receptor usage by WISP-1. Truncated WISP-1 proteins were produced using a baculovirus expression system. Full length WISP-1 and truncated proteins were evaluated for their ability to induce adhesion in A549 epithelial cells and β-catenin activation and CXCL3 secretion in fibroblasts (NRK49-F cells). Subsequent inhibition of these responses by neutralising integrin antibodies was evaluated. A549 cells demonstrated adhesion to full-length WISP-1 whilst truncated proteins containing VWC, TSP or CT domains also induced adhesion, with highest activity observed with proteins containing the C-terminal TSP and CT domains. Likewise the ability to induce β-catenin activation and CXCL3 secretion was retained in truncations containing C-terminal domains. Pre-treatment of A549s with either integrin αVβ5, αVβ3 or β1 neutralising antibodies partially inhibited full length WISP-1 induced adhesion whilst combining integrin αVβ5 and β1 antibodies increased the potency of this effect. Incubation of NRK49-F cells with integrin neutralising antibodies failed to effect β-catenin translocation or CXCL3 secretion. Analysis of natural WISP-1 derived from human lung tissue showed the native protein is a high order oligomer. Our data suggest that WISP-1 mediated adhesion of A549 cells is an integrin-driven event regulated by the C-terminal domains of the protein. Activation of β-catenin signalling and CXCL3 secretion also resides within the C-terminal domains of WISP-1 but are not regulated by integrins. The oligomeric nature of native WISP-1 may drive a high avidity interaction with these receptors in vivo.     

Use of Pseudomonas putida EstA as an Anchoring Motif for Display of a Periplasmic Enzyme on the Surface of Escherichia coli

The functional expression of proteins on the surface of bacteria has proven important for numerous biotechnological applications. In this report, we investigated the N-terminal fusion display of the periplasmic enzyme β-lactamase (Bla) on the surface of Escherichia coli by using the translocator domain of the Pseudomonas putida outer membrane esterase (EstA), which is a member of the lipolytic autotransporter enzymes. To find out the transport function of a C-terminal domain of EstA, we generated a set of Bla-EstA fusion proteins containing N-terminally truncated derivatives of the EstA C-terminal domain. The surface exposure of the Bla moiety was verified by whole-cell immunoblots, protease accessibility, and fluorescence-activated cell sorting. The investigation of growth kinetics and host cell viability showed that the presence of the EstA translocator domain in the outer membrane neither inhibits cell growth nor affects cell viability. Furthermore, the surface-exposed Bla moiety was shown to be enzymatically active. These results demonstrate for the first time that the translocator domain of a lipolytic autotransporter enzyme is an effective anchoring motif for the functional display of heterologous passenger protein on the surface of E. coli. This investigation also provides a possible topological model of the EstA translocator domain, which might serve as a basis for the construction of fusion proteins containing heterologous passenger domains.     

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.     

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.     

Evolutionary Conservation in Biogenesis of β-Barrel Proteins Allows Mitochondria to Assemble a Functional Bacterial Trimeric Autotransporter Protein

Yersinia adhesin A (YadA) belongs to a class of bacterial adhesins that form trimeric structures. Their mature form contains a passenger domain and a C-terminal β-domain that anchors the protein in the outer membrane (OM). Little is known about how precursors of such proteins cross the periplasm and assemble into the OM. In the present study we took advantage of the evolutionary conservation in the biogenesis of β-barrel proteins between bacteria and mitochondria. We previously observed that upon expression in yeast cells, bacterial β-barrel proteins including the transmembrane domain of YadA assemble into the mitochondrial OM. In the current study we found that when expressed in yeast cells both the monomeric and trimeric forms of full-length YadA were detected in mitochondria but only the trimeric species was fully integrated into the OM. The oligomeric form was exposed on the surface of the organelle in its native conformation and maintained its capacity to adhere to host cells. The co-expression of YadA with a mitochondria-targeted form of the bacterial periplasmic chaperone Skp, but not with SurA or SecB, resulted in enhanced levels of both forms of YadA. Taken together, these results indicate that the proper assembly of trimeric autotransporter can occur also in a system lacking the lipoproteins of the BAM machinery and is specifically enhanced by the chaperone Skp.     

Stepwise Folding of an Autotransporter Passenger Domain Is Not Essential for Its Secretion

Autotransporters are a superfamily of virulence proteins produced by Gram-negative bacteria. They consist of an N-terminal β-helical domain (“passenger domain”) that is secreted into the extracellular space and a C-terminal β-barrel domain (“β-domain”) that anchors the protein to the outer membrane. Because the periplasm lacks ATP, vectorial folding of the passenger domain in a C-to-N-terminal direction has been proposed to drive the secretion reaction. Consistent with this hypothesis, mutations that disrupt the folding of the C terminus of the passenger domain of the Escherichia coli O157:H7 autotransporter EspP have been shown to cause strong secretion defects. Here, we show that point mutations introduced at specific locations near the middle or N terminus of the EspP β-helix that perturb folding also impair secretion, but to a lesser degree. Surprisingly, we found that even multiple mutations that potentially abolish the stability of several consecutive rungs of the β-helix only moderately reduce secretion efficiency. Although these results provide evidence that the free energy derived from passenger domain folding contributes to secretion efficiency, they also suggest that a significant fraction of the energy required for secretion is derived from another source.     

Solution Structure of Calmodulin Bound to the Binding Domain of the HIV-1 Matrix Protein

Subcellular distribution of calmodulin (CaM) in human immunodeficiency virus type-1 (HIV-1)-infected cells is distinct from that observed in uninfected cells. CaM co-localizes and interacts with the HIV-1 Gag protein in the cytosol of infected cells. Although it has been shown that binding of Gag to CaM is mediated by the matrix (MA) domain, the structural details of this interaction are not known. We have recently shown that binding of CaM to MA induces a conformational change that triggers myristate exposure, and that the CaM-binding domain of MA is confined to a region spanning residues 8–43 (MA-(8–43)). Here, we present the NMR structure of CaM bound to MA-(8–43). Our data revealed that MA-(8–43), which contains a novel CaM-binding motif, binds to CaM in an antiparallel mode with the N-terminal helix (α1) anchored to the CaM C-terminal lobe, and the C-terminal helix (α2) of MA-(8–43) bound to the N-terminal lobe of CaM. The CaM protein preserves a semiextended conformation. Binding of MA-(8–43) to CaM is mediated by numerous hydrophobic interactions and stabilized by favorable electrostatic contacts. Our structural data are consistent with the findings that CaM induces unfolding of the MA protein to have access to helices α1 and α2. It is noteworthy that several MA residues involved in CaM binding have been previously implicated in membrane binding, envelope incorporation, and particle production. The present findings may ultimately help in identification of the functional role of CaM in HIV-1 replication.     

Intimin and Invasin Export Their C-Terminus to the Bacterial Cell Surface Using an Inverse Mechanism Compared to Classical Autotransport

Invasin and intimin are major virulence factors of enteropathogenic Yersiniae and Escherichia coli, mediating invasion into and intimate adherence to host cells, respectively. Several studies have hinted that extracellular portion of these homologous proteins might be exported via an autotransport mechanism, but rigorous experimental proof has been lacking. Here, we present a topology model for invasin and intimin, consistent with the hypothesis that the N-terminal β-barrel domain acts as a translocation pore to secrete the C-terminal passenger domain. We confirmed this topology model by inserting epitope tags into the loops of the β-barrel. We further show that obstructing the pore of β-barrel hinders the export of the passenger domain. As for classical autotransport, the biogenesis of invasin and intimin is dependent on the Bam complex and the periplasmic chaperone SurA, whereas the chaperone/protease DegP is involved in quality control. However, compared to classical autotransporters (Type Va secretion), the domain structure of intimin and invasin is inverted. We conclude that proteins of the intimin and invasin family constitute a novel group of autotransported proteins, and propose that this class of autotransporters be termed Type Ve secretion.     

Stimulation of human DNA polymerase epsilon by MDM2

The human DNA polymerase ε catalytic subunit consists of a 140-kDa N‐terminal domain that contains the catalytic activity and a 120-kDa C-terminal domain that binds to the other subunits and to exogenous peptides, including PCNA and MDM2. We report here that recombinant human MDM2 purified from insect cells or Escherichia coli stimulated the activity of DNA polymerase ε up to 10- and 40-fold, respectively, but not those of DNA polymerase β or Klenow fragment of E.coli DNA polymerase I. Kinetic studies indicated that MDM2 increased the maximum velocity of the reaction, but did not change substrate affinities. The stimulation depended upon the interaction of the N‐terminal 166 amino acid residues of MDM2 with the C-terminal domain of the full-length catalytic subunit, since the deletion of 166 amino acids from N‐terminal of MDM2 or the removal of the C-terminal domain of DNA polymerase ε by trypsin digestion or competition for binding to it by the addition of excess C-terminal fragment eliminated the stimulation. Since DNA polymerase ε appears to be involved in DNA replication, recombination and repair synthesis, we suggest that MDM2 binding to DNA polymerase ε might be part of a reconfiguration process that allows DNA polymerase ε to associate with repair/recombination proteins in response to DNA damage.     

Of linkers and autochaperones: an unambiguous nomenclature to identify common and uncommon themes for autotransporter secretion

Autotransporter (AT) proteins provide a diverse array of important virulence functions to Gram‐negative bacterial pathogens, and have also been adapted for protein surface display applications. The ‘autotransporter’ moniker refers to early models that depicted these proteins facilitating their own translocation across the bacterial outer membrane. Although translocation is less autonomous than originally proposed, AT protein segments upstream of the C‐terminal transmembrane β‐barrel have nevertheless consistently been found to contribute to efficient translocation and/or folding of the N‐terminal virulence region (the ‘passenger’). However, defining the precise secretion functions of these AT regions has been complicated by the use of multiple overlapping and ambiguous terms to define AT sequence, structural, and functional features, including ‘autochaperone’, ‘linker’ and ‘junction’. Moreover, the precise definitions and boundaries of these features vary among ATs and even among research groups, leading to an overall murky picture of the contributions of specific features to translocation. Here we propose a unified, unambiguous nomenclature for AT structural, functional and conserved sequence features, based on explicit criteria. Applied to 16 well‐studied AT proteins, this nomenclature reveals new commonalities for translocation but also highlights that the autochaperone function is less closely associated with a conserved sequence element than previously believed.     

Structure of a Conserved Golgi Complex-targeting Signal in Coronavirus Envelope Proteins

Coronavirus envelope (CoV E) proteins are ∼100-residue polypeptides with at least one channel-forming α-helical transmembrane (TM) domain. The extramembrane C-terminal tail contains a completely conserved proline, at the center of a predicted β-coil-β motif. This hydrophobic motif has been reported to constitute a Golgi-targeting signal or a second TM domain. However, no structural data for this or other extramembrane domains in CoV E proteins is available. Herein, we show that the E protein in the severe acute respiratory syndrome virus has only one TM domain in micelles, whereas the predicted β-coil-β motif forms a short membrane-bound α-helix connected by a disordered loop to the TM domain. However, complementary results suggest that this motif is potentially poised for conformational change or in dynamic exchange with other conformations.     

Purification of components of the translation elongation factor complex of Plasmodium falciparum by tandem affinity purification

Plasmodium falciparum is the causative agent of severe human malaria, responsible for over 2 million deaths annually. Of the 5,300 polypeptides predicted to control the parasite life cycle in mosquitoes and humans, 60% are of unknown function. A major challenge of malaria postgenomic biology is to understand how the 5,300 predicted proteins coexist and interact to perform the essential tasks that define the complex life cycle of the parasite. One approach to assign function to these proteins is by identifying their physiological partners. Here we describe the use of tandem affinity purification (TAP) and mass spectrometry for identification of native protein interactions and purification of protein complexes in P. falciparum. Transgenic parasites were generated which express the translation elongation factor PfEF-1β harboring a C-terminal PTP tag which consists of the protein C epitope, a tobacco etch virus protease cleavage site, and two protein A domains. Purification of PfEF-1β-PTP from crude extracts followed by mass spectrometric analysis revealed, in addition to the tagged protein itself, the presence of the native PfEF-1β, the G-protein PfEF-1α, and two new proteins that we named PfEF-1γ and PfEF-1δ based on their homology to other eukaryotic γ and δ translation elongation factor subunits. These data, which constitute the first application of TAP for purification of a protein complex under native conditions in P. falciparum, revealed that the translation elongation complex in this organism contains at least two subunits of PfEF-1β. The success of this approach will set the stage for a systematic analysis of protein interactions in this important human pathogen.     

Estimating the size of the active translocation pore of an autotransporter

Autotransporters (ATs) are large virulence factors secreted by Gram-negative bacteria. The passenger domain, carrying the virulence functions, is transported across the bacterial outer membrane in a step that is facilitated by a C-terminal β-domain. This domain folds into a β-barrel with a central aqueous pore of ～1 nm inner diameter according to crystal structures. However, these static dimensions are not compatible with the observed secretion of passengers that may contain natural short-spaced disulfide bonds or artificially fused folded elements. Here, we have systematically analyzed the dimensions of the active AT passenger translocator by inserting peptides of different length and structural complexity in the passenger of the AT hemoglobin protease. The peptides were introduced in a short loop protruding from the main structure and flanked by two single cysteines. Our results show that the attained secondary structure may be more critical for secretion than the length of peptide inserted. Furthermore, the data suggest that, during passenger translocation, at least four extended polypeptides or an extended polypeptide and an α-helix are accommodated in the translocator, indicating that the diameter of the active translocation pore is up to 1.7 nm. If the β-domain functions as the translocator, it must be forced into an expanded conformation during passenger translocation.     

Three-dimensional structure of ribulose-1,5-bisphosphate carboxylase/oxygenase from Rhodospirillum rubrum at 2.9 A resolution

The three-dimensional structure of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) from Rhodospirillum rubrum has been determined at 2.9 Å resolution by X-ray crystallographic methods. The MIR-electron density map was substantially improved by two-fold non-crystallographic symmetry averaging. The polypeptide chains in the dimer were traced using a graphics display system with the help of the BONES option in FRODO. The dimer has approximate dimensions of 50 x 72 x 105 Å. The enzyme subunit is a typical two-domain protein. The smaller, N-terminal domain consists of 137 amino acid residues and forms a central, mixed five-stranded β-sheet with α-helices on both sides of the sheet. The larger C-terminal domain consists of 329 amino acid residues. This domain has an eight-stranded parallel α/β barrel structure as found in triosephosphate isomerase and a number of other functionally non-related proteins. The active site in Rubisco determined by difference Fourier techniques and fitting of active site residues to the electron density map, is located at the carboxy-end of the β-strands in the α/β barrel of the C-terminal domain. There are few domain–domain interactions within the subunit. The interactions at the interface between the two subunits of the dimer are tight and extensive. There are tight contacts between the two C-terminal domains, which build up the core of the molecule. There are also interactions between the N-terminal domain of one subunit and the C-terminal domain of the second subunit, close to the active site.     

High Mobility Group Protein N5 (HMGN5) and Lamina-associated Polypeptide 2α (LAP2α) Interact and Reciprocally Affect Their Genome-wide Chromatin Organization

The interactions of nuclear lamins with the chromatin fiber play an important role in regulating nuclear architecture and chromatin function; however, the full spectrum of these interactions is not known. We report that the N-terminal domain of the nucleosome-binding protein HMGN5 interacts with the C-terminal domain of the lamin-binding protein LAP2α and that these proteins reciprocally alter their interaction with chromatin. Chromatin immunoprecipitation analysis of cells lacking either HMGN5 or LAP2α reveals that loss of either protein affects the genome-wide distribution of the remaining partner. Our study identifies a new functional link between chromatin-binding and lamin-binding proteins.     

Identification,Characterization, and Molecular Application of a Virulence-Associated Autotransporter from a Pathogenic Pseudomonas fluorescens Strain

A gene, pfa1, encoding an autotransporter was cloned from a pathogenic Pseudomonas fluorescens strain, TSS, isolated from diseased fish. The expression of pfa1 is enhanced during infection and is regulated by growth phase and growth conditions. Mutation of pfa1 significantly attenuates the overall bacterial virulence of TSS and impairs the abilities of TSS in biofilm production, interaction with host cells, modulation of host immune responses, and dissemination in host blood. The putative protein encoded by pfa1 is 1,242 amino acids in length and characterized by the presence of three functional domains that are typical for autotransporters. The passenger domain of PfaI contains a putative serine protease (Pap) that exhibits apparent proteolytic activity when expressed in and purified from Escherichia coli as a recombinant protein. Consistent with the important role played by PfaI in bacterial virulence, purified recombinant Pap has a profound cytotoxic effect on cultured fish cells. Enzymatic analysis showed that recombinant Pap is relatively heat stable and has an optimal temperature and pH of 50°C and pH 8.0. The domains of PfaI that are essential to autotransporting activity were localized, and on the basis of this, a PfaI-based autodisplay system (named AT1) was engineered to facilitate the insertion and transport of heterologous proteins. When expressed in E. coli, AT1 was able to deliver an integrated Edwardsiella tarda immunogen (Et18) onto the surface of bacterial cells. Compared to purified recombinant Et18, Et18 displayed by E. coli via AT1 induced significantly enhanced immunoprotection.Protein secretion plays important roles in bacterial life, as many of the secreted proteins are involved in biological processes that are fundamental to the survival and environmental adaptations of the cells. Gram-negative bacteria have evolved a number of secretion systems that utilize different secretion apparatus and mechanisms (9). The classical autotransporter secretion pathway belongs to the type V secretion system (8, 12, 13). Compared to other types of secretion mechanisms, the autotransporter system is unique in that all the components that are required for protein translocation are contained within a single polypeptide. Structurally, autotransporters are characterized by three domains: (i) an N-terminal signal sequence that is recognized by the Sec translocon; (ii) a central passenger domain (or α-domain) that contains the effector molecule and is highly variable; and (iii) a C-terminal translocation domain (or β-/autotransporter domain) that is conserved in length (250 to 300 amino acids) but varies in primary structure (7, 12, 55). In most cases, the β-domain contains 12 antiparallel strands of 9 to 12 residues that, upon integration into the outer membrane, form a β-barrel conformation (27, 57). Another conserved feature of the β-domain is the presence at the C terminus of a sequence motif, (Y/V/I/F/W)-X-(F/W), that is characterized by alternating hydrophobic and hydrophilic residues and ends with either a tryptophan or a phenylalanine (12, 16, 27). The integrity of this end motif seems to be required for protein translocation, as deletion of certain residues in this sequence impairs protein secretion. The secretion process of the autotransporter is initiated by the signal sequence, which directs the translocation of the protein precursor across the inner membrane into the periplasmic space via the Sec system. Once inside the periplasm, the β-domain inserts into the outer membrane and adopts the structure of a β-barrel through which the passenger domain is translocated to the cell surface, where it may exist as a membrane-anchored protein covalently linked to the β-domain or be cleaved from the β-domain as a result of proteolysis (7).Since the discovery of the gonococcal immunoglobulin A1 protease (35), the first autotransporter, and especially with the advent of genome sequencing technology, autotransporters have been identified in many bacterial species (18, 19, 28, 33). Functions assigned to autotransporters are mostly associated with bacterial pathogenicity, which includes adhesion and invasion into host cells, biofilm formation, and cytotoxicity (11, 54). In the present study, we identified and analyzed an autotransporter, PfaI, from a pathogenic Pseudomonas fluorescens strain isolated from diseased fish. We found that, like many of the autotransporters identified in other pathogens, PfaI is a virulence factor that is involved in interactions with host cells and modulation of host immune responses via a protease effector. In addition, we found that the autotransporter property of PfaI could be exploited for the delivery and surface display of an immunoprotective antigen.