Structure of the outer membrane translocator domain of the Haemophilus influenzae Hia trimeric autotransporter

Autotransporter proteins are defined by the ability to drive their own secretion across the bacterial outer membrane. The Hia autotransporter of Haemophilus influenzae belongs to the trimeric autotransporter subfamily and mediates bacterial adhesion to the respiratory epithelium. In this report, we present the crystal structure of the C-terminal end of Hia, corresponding to the entire Hia translocator domain and part of the passenger domain (residues 992-1098). This domain forms a beta-barrel with 12 transmembrane beta-strands, including four strands from each subunit. The beta-barrel has a central channel of 1.8 nm in diameter that is traversed by three N-terminal alpha-helices, one from each subunit. Mutagenesis studies demonstrate that the transmembrane portion of the three alpha-helices and the loop region between the alpha-helices and the neighboring beta-strands are essential for stability of the trimeric structure of the translocator domain, and that trimerization of the translocator domain is a prerequisite for translocator activity. Overall, this study provides important insights into the mechanism of translocation in trimeric autotransporters.     

Architecture and adhesive activity of the Haemophilus influenzae Hsf adhesin

Haemophilus influenzae type b is an important cause of meningitis and other serious invasive diseases and initiates infection by colonizing the upper respiratory tract. Among the major adhesins in H. influenzae type b is a nonpilus protein called Hsf, a large protein that forms fiber-like structures on the bacterial surface and shares significant sequence similarity with the nontypeable H. influenzae Hia autotransporter. In the present study, we characterized the structure and adhesive activity of Hsf. Analysis of the predicted amino acid sequence of Hsf revealed three regions with high-level homology to the HiaBD1 and HiaBD2 binding domains in Hia. Based on examination of glutathione S-transferase fusion proteins corresponding to these regions, two of the three had adhesive activity and one was nonadhesive in assays with cultured epithelial cells. Structural modeling demonstrated that only the two regions with adhesive activity harbored an acidic binding pocket like the binding pocket identified in the crystal structure of HiaBD1. Consistent with these results, disruption of the acidic binding pockets in the adhesive regions eliminated adhesive activity. These studies advance our understanding of the architecture of Hsf and the family of trimeric autotransporters and provide insight into the structural determinants of H. influenzae type b adherence.     

Trimeric autotransporters require trimerization of the passenger domain for stability and adhesive activity

In recent years, structural studies have identified a number of bacterial, viral, and eukaryotic adhesive proteins that have a trimeric architecture. The prototype examples in bacteria are the Haemophilus influenzae Hia adhesin and the Yersinia enterocolitica YadA adhesin. Both Hia and YadA are members of the trimeric-autotransporter subfamily and are characterized by an internal passenger domain that harbors adhesive activity and a short C-terminal translocator domain that inserts into the outer membrane and facilitates delivery of the passenger domain to the bacterial surface. In this study, we examined the relationship between trimerization of the Hia and YadA passenger domains and the capacity for adhesive activity. We found that subunit-subunit interactions and stable trimerization are essential for native folding and stability and ultimately for full-level adhesive activity. These results raise the possibility that disruption of the trimeric architecture of trimeric autotransporters, and possibly other trimeric adhesins, may be an effective strategy to eliminate adhesive activity.     

Structural basis for host recognition by the Haemophilus influenzae Hia autotransporter

Haemophilus influenzae is an important human pathogen that initiates infection by colonizing the upper respiratory tract. The H. influenzae Hia autotransporter is an adhesive protein that promotes adherence to respiratory epithelial cells. Hia adhesive activity resides in two homologous binding domains, called HiaBD1 and HiaBD2. These domains interact with the same host cell receptor, but bind with different affinities. In this report, we describe the crystal structure of the high-affinity HiaBD1 binding domain, which has a novel trimeric architecture with three-fold symmetry and a mushroom shape. The subunit constituents of the trimer are extensively intertwined. The receptor-binding pocket is formed by an acidic patch that is present on all three faces of the trimer, providing potential for a multivalent interaction with the host cell surface, analogous to observations with the trimeric tumor necrosis factor superfamily of proteins. Hia is a novel example of a bacterial trimeric adhesin and may be the prototype member of a large family of bacterial virulence proteins with a similar architecture.     

The Haemophilus influenzae Hia autotransporter contains an unusually short trimeric translocator domain

Gram-negative bacterial autotransporter proteins are a growing group of virulence factors that are characterized by their ability to cross the outer membrane without the help of accessory proteins. A conserved C-terminal beta-domain is critical for targeting of autotransporters to the outer membrane and for translocation of the N-terminal "passenger" domain to the bacterial surface. We have demonstrated previously that the Haemophilus influenzae Hia adhesin belongs to the autotransporter family, with translocator activity residing in the C-terminal 319 residues. To gain further insight into the mechanism of autotransporter protein translocation, we performed a structure-function analysis on Hia. In initial experiments, we generated a series of in-frame deletions and a set of chimeric proteins containing varying regions of the Hia C terminus fused to a heterologous passenger domain and discovered that the final 76 residues of Hia are both necessary and sufficient for translocation. Analysis by flow cytometry revealed that the region N-terminal to this shortened translocator domain is surface localized, further suggesting that this region is not involved in beta-barrel formation or in translocation of the passenger domain. Western analysis demonstrated that the translocation-competent regions of the C terminus migrated at masses consistent with trimers, suggesting that the Hia C terminus oligomerizes. Furthermore, fusion proteins containing a heterologous passenger domain demonstrated that similarly small C-terminal regions of Yersinia sp. YadA and Neisseria meningitidis NhhA are translocation-competent. These data provide experimental support for a unique subclass of autotransporters characterized by a short trimeric translocator domain.     

Stability and membrane interactions of an autotransport protein: MD simulations of the Hia translocator domain in a complex membrane environment

Hia is a trimeric autotransporter found in the outer membrane of Haemphilus influenzae. The X-ray structure of Hia translocator domain revealed each monomer to consist of an α-helix connected via a loop to a 4-stranded β-sheet, thus the topology of the trimeric translocator domain is a 12-stranded β-barrel containing 3 α-helices that protrude from the mouth of the β-barrel into the extracellular medium. Molecular dynamics simulations of the Hia monomer and trimer have been employed to explore the interactions between the helices, β-barrel and connecting loops that may contribute to the stability of the trimer. In simulations of the Hia monomer we show that the central α-helix may stabilise the fold of the 4-stranded β-sheet. In simulations of the Hia trimer, a H-bond network involving residues in the β-barrel, α-helices and loops has been identified as providing stability for the trimeric arrangement of the monomers. Glutamine residues located in the loops connecting the α-helices to the β-barrel are orientated in a triangular arrangement such that each forms 2 hydrogen bonds to each of the corresponding glutamines in the other loops. In the absence of the loops, the β‐barrel becomes distorted. Simulations show that while the trimeric translocator domain β-barrel is inherently flexible, it is unlikely to accommodate the passenger domain in a folded conformation. Simulations of Hia in an asymmetric model of the outer membrane have revealed membrane–protein interactions that anchor the protein within its native membrane environment.     

Trimeric autotransporters: a distinct subfamily of autotransporter proteins

Autotransporter proteins are a large family of gram-negative bacterial extracellular proteins. These proteins have a characteristic arrangement of functional domains, including an N-terminal signal peptide, an internal passenger domain, and a C-terminal translocator domain. Recent studies have identified a novel subfamily of autotransporters, defined by a short trimeric C-terminal translocator domain and known as trimeric autotransporters. In this article, we review our current knowledge of the structural and functional characteristics of trimeric autotransporters, highlighting the distinctions between this subfamily and conventional autotransporters. We speculate that trimeric autotransporters evolved to enable high-affinity multivalent adhesive interactions with host surfaces and circulating host molecules to take place.     

The Intracellular Citrus Huanglongbing Bacterium, ‘Candidatus Liberibacter asiaticus’ Encodes Two Novel Autotransporters

Proteins secreted by the type V secretion system (T5SS), known as autotransporters, are large extracellular virulence proteins localized to the bacterial poles. In this study, we characterized two novel autotransporter proteins of ‘ Candidatus Liberibacter asiaticus’ (Las), and redesignated them as LasA_I and LasA_II in lieu of the previous names Hyv_I and Hyv_II. As a phloem-limited, intracellular bacterial pathogen, Las has a significantly reduced genome and causes huanglongbing (HLB), a devastating disease of citrus worldwide. Bioinformatic analyses revealed that LasA_I and LasA_II share the structural features of an autotransporter family containing large repeats of a passenger domain and a unique C-terminal translocator domain. When fused to the GFP gene and expressed in E. coli, the LasA_I C-terminus and the full length LasA_II were localized to the bacterial poles, similar to other members of autotransporter family. Despite the absence of a typical signal peptide, LasA_I was found to localize at the cell surface by immuno-dot blot using a monoclonal antibody against the partial LasA_I protein. Its surface localization was also confirmed by the removal of the LasA_I antigen using a proteinase K treatment of the intact bacterial cells. When co-inoculated with a P19 gene silencing suppressor and transiently expressed in tobacco leaves, the GFP-LasA_I translocator targeted to the mitochondria. This is the first report that Las encodes novel autotransporters that target to mitochondria when expressed in the plants. These findings may lead to a better understanding of the pathogenesis of this intracellular bacterium.     

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 Basis for the Differential Binding Affinities of the HsfBD1 and HsfBD2 Domains in the Haemophilus influenzae Hsf Adhesin

Haemophilus influenzae is a human-specific gram-negative coccobacillus that causes a variety of human infections ranging from localized respiratory infections to invasive diseases. Hsf is the major nonpilus adhesin in encapsulated strains of H. influenzae and belongs to the trimeric autotransporter family of proteins. The Hsf protein contains two highly homologous binding domains, designated HsfBD1 and HsfBD2. In this study we characterized the differential binding properties of HsfBD1 and HsfBD2. In assays using HeLa cells, we found that bacteria expressing either full-length Hsf or HsfBD1 by itself adhered at high levels, while bacteria expressing HsfBD2 by itself adhered at low levels. Immunofluorescence microscopy and a cellular enzyme-linked immunosorbent assay using purified proteins revealed that the binding affinity was significantly higher for HsfBD1 than for HsfBD2. Purified HsfBD1 was able to completely block adherence by bacteria expressing either HsfBD1 or HsfBD2, while purified HsfBD2 was able to block adherence by bacteria expressing HsfBD2 but had minimal activity against bacteria expressing HsfBD1. Conversion of the residue at position 1935 in the HsfBD1 binding pocket from Asp to Glu resulted in HsfBD2-like binding properties, and conversion of the residue at position 569 in the HsfBD2 binding pocket from Glu to Asp resulted in HsfBD1-like binding properties, as assessed by adherence assays with recombinant bacteria and by immunofluorescence microscopy with purified proteins. This work demonstrates the critical role of a single amino acid in the core of the binding pocket in determining the relative affinities of the HsfBD1 and HsfBD2 binding domains.Haemophilus influenzae is a gram-negative coccobacillus that causes both serious invasive diseases and localized respiratory tract infections in humans (10, 17, 19). Isolates of H. influenzae can be separated into encapsulated and nonencapsulated or so-called nontypeable strains (12). Most strains recovered from patients with invasive disease are encapsulated and express the type b capsule, while the majority of strains associated with respiratory tract infections are nontypeable (19).The pathogenesis of disease due to H. influenzae type b begins with colonization of the upper respiratory tract (4, 8, 11, 13, 16, 19). Most type b strains are capable of expressing hemagglutinating pili, which mediate bacterial attachment to oropharyngeal epithelial cells, extracellular matrix proteins, and mucin and promote colonization. Mutant strains that lack hemagglutinating pili are also capable of adherence and colonization, highlighting the fact that nonpilus adhesive factors also exist (4, 5, 8, 20). In recent work, we have demonstrated that the major nonpilus adhesin in H. influenzae type b is a large protein called Hsf, which forms short fibers visible by electron microscopy (15).The Hsf adhesin is encoded by the hsf locus and is a trimeric autotransporter protein that shares significant homology with Hia, a trimeric autotransporter adhesin that is present in ∼25% of nontypeable H. influenzae strains. Hsf contains an N-terminal signal sequence, an internal passenger domain with two binding domains, and a C-terminal outer membrane pore-forming domain, analogous to Hia (3, 6). The binding domains in Hsf are called HsfBD1 and HsfBD2 and share high-level homology with each other and with the two binding domains in Hia (2, 14). HsfBD1 and HsfBD2 interact with the same host cell receptor structure on Chang epithelial cells, although with different affinities (3). Based on in vitro experiments using purified proteins and Chang epithelial cells, HsfBD1 has a dissociation constant (K_d) of ∼0.2 nM and HsfBD2 has a K_d of ∼2.5 nM.In previous work using X-ray crystallography and site-directed mutagenesis, we established that both HiaBD1 and HiaBD2 are trimeric structures with acidic binding pockets formed by contiguous IsNeck and Trp-ring domains (9, 21). Using structural modeling and site-directed mutagenesis, we determined that HsfBD1 and HsfBD2 possess the same fold and trimeric assembly as HiaBD1 and HiaBD2, with conservation of the residues that are essential for HiaBD1 adhesive activity (3).In the current study we examined the structural basis for the different binding affinities of HsfBD1 and HsfBD2. In initial experiments, we found that the differences between HsfBD1 and HsfBD2 were easier to observe with HeLa cells than with Chang cells, reflecting the fact that the receptor density is lower on HeLa cells. Our results demonstrated the critical role of a single amino acid in the core of the binding pocket in determining the relative affinities of HsfBD1 and HsfBD2.     

Structure of the translocator domain of a bacterial autotransporter

Autotransporters are virulence-related proteins of Gram-negative bacteria that are secreted via an outer-membrane-based C-terminal extension, the translocator domain. This domain supposedly is sufficient for the transport of the N-terminal passenger domain across the outer membrane. We present here the crystal structure of the in vitro-folded translocator domain of the autotransporter NalP from Neisseria meningitidis, which reveals a 12-stranded beta-barrel with a hydrophilic pore of 10 x 12.5 A that is filled by an N-terminal alpha-helix. The domain has pore activity in vivo and in vitro. Our data are consistent with the model of passenger-domain transport through the hydrophilic channel within the beta-barrel, and inconsistent with a model for transport through a central channel formed by an oligomer of translocator domains. However, the dimensions of the pore imply translocation of the secreted domain in an unfolded form. An alternative model, possibly covering the transport of folded domains, is that passenger-domain transport involves the Omp85 complex, the machinery required for membrane insertion of outer-membrane proteins, on which autotransporters are dependent.     

Model structure of the prototypical non-fimbrial adhesin YadA of Yersinia enterocolitica

Non-fimbrial adhesins, such as Yersinia YadA, Moraxella UspA1 and A2, Haemophilus Hia and Hsf, or Bartonella BadA represent an important class of molecules by which pathogenic proteobacteria adhere to their hosts. They form trimeric surface structures with a head-stalk-anchor architecture. Whereas head and stalk domains are diverse and appear (frequently repetitively) in different combinations, the anchor domains are homologous and display the properties of autotransporters. We have built a molecular model for the prototypical non-fimbrial adhesin, YadA, by combining the crystal structure of the head (PDB:1P9H) with theoretical models for the stalk and the anchor. The head domain is a single-stranded, left-handed beta-helix, connected to the stalk by a conserved trimerization element (the neck). The stalk consists of a right-handed coiled coil, containing ten 15-residue repeats with a C-terminal stutter (insertion of four residues). The stalk continues into the conserved anchor domain, which is formed by four heptads of a left-handed coiled coil, followed by four transmembrane beta-strands. Our model of the YadA coiled coil, generated with the program BeammotifCC, combines these periodicities into a structure that starts with a pronounced right-handed supercoil and ends with a canonical, left-handed conformation. The last two heptads of the coiled coil are located within a 12-stranded beta-barrel, formed by trimerization of the four transmembrane beta-strands in each monomer. We propose that this pore assembles in the outer membrane to form the opening through which the monomer chains exit the cell. After export is completed, the fiber folds and the pore is occluded by the coiled coil. Our model explains how these proteins can act as autotransporters in the absence of any homology to classical, single-chain autotransporters.     

The Haemophilus influenzae Hia adhesin is an autotransporter protein that remains uncleaved at the C terminus and fully cell associated

Nontypeable Haemophilus influenzae is a gram-negative commensal organism that is commonly associated with localized respiratory tract disease. The pathogenesis of disease begins with colonization of the nasopharynx, a process that likely depends on bacterial adherence to respiratory epithelial cells. Hia is the major adhesin expressed by a subset of nontypeable H. influenzae strains and promotes efficient adherence to a variety of human epithelial cell lines. Based on previous work, Hia is transported to the surface of Escherichia coli transformants and is capable of mediating E. coli adherence without the assistance of other H. influenzae proteins. In the present study, we examined the mechanism of Hia secretion. PhoA fusions, deletional mutagenesis, and N-terminal amino acid sequencing established that the signal for Hia export from the cytoplasm resides in the first 49 amino acids, including a 24-amino-acid stretch with striking similarity to the N terminus of a number of proteins belonging to the autotransporter family. Immunoelectron microscopy demonstrated that the Hia internal region defined by amino acids 221 to 779 is exposed on the bacterial surface. Secondary-structure analysis predicted that the C terminus of Hia forms a beta-barrel with a central hydrophilic channel, and site-specific mutagenesis and fusion protein analysis demonstrated that the C terminus targets Hia to the outer membrane and functions as an outer membrane translocator, analogous to observations with autotransporter proteins. In contrast to typical autotransporter proteins, Hia undergoes no cleavage between the internal and C-terminal domains and remains fully cell associated. Together, these results suggest that Hia is the prototype of an important subfamily of autotransporter proteins.     

Identification of a novel trimeric autotransporter adhesin in the cryptic genospecies of Haemophilus

Haemophilus biotype IV strains belonging to the recently recognized Haemophilus cryptic genospecies are an important cause of maternal genital tract and neonatal systemic infections and initiate infection by colonizing the genital or respiratory epithelium. To gain insight into the mechanism of Haemophilus cryptic genospecies colonization, we began by examining prototype strain 1595 and three other strains for adherence to genital and respiratory epithelial cell lines. Strain 1595 and two of the three other strains demonstrated efficient adherence to all of the cell lines tested. With a stably adherent variant of strain 1595, we generated a Mariner transposon library and identified 16 nonadherent mutants. All of these mutants lacked surface fibers and contained an insertion in the same open reading frame, which encodes a 157-kDa protein designated Cha for cryptic haemophilus adhesin. Analysis of the predicted amino acid sequence of Cha revealed the presence of an N-terminal signal peptide and a C-terminal domain bearing homology to YadA-like and Hia-like trimeric autotransporters. Examination of the C-terminal 120 amino acids of Cha demonstrated mobility as a trimer on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and the capacity to present the passenger domain of the Hia trimeric autotransporter on the bacterial surface. Southern analysis revealed that the gene that encodes Cha is conserved among clinical isolates of the Haemophilus cryptic genospecies and is absent from the closely related species Haemophilus influenzae. We speculate that Cha is important in the pathogenesis of disease due to the Haemophilus cryptic genospecies and is in part responsible for the apparent tissue tropism of this organism.     

In vivo expression of Neisseria meningitidis proteins homologous to the Haemophilus influenzae Hap and Hia autotransporters

The genome sequences of Neisseria meningitidis serogroup B strain MC58 and serogroup A strain Z2491 were systematically searched for open reading frames (ORFs) encoding autotransporters. Eight ORFs were identified, six of which were present in both genomes, whereas two were specific for MC58. Among the identified ORFs was the gene encoding the known autotransporter IgA1 protease. The deduced amino acid sequences of the other identified ORFs were homologous to known autotransporters and found to contain an N-terminal signal sequence and a C-terminal domain that could constitute a beta-barrel in the outer membrane. The ORFs NMB1985 and NMB0992, encoding homologs of the Hap (for Haemophilus adhesion and penetration protein) and Hia (for Haemophilus influenzae adherence protein) autotransporters of H. influenzae, were cloned from serogroup B strain H44/76 and expressed in Escherichia coli. Western blots revealed that all sera of patients (n=14) and healthy carriers (n=3) tested contained antibodies against at least one of the recombinant proteins. These results indicate that both genes are widely distributed among N. meningitidis isolates and expressed during colonization and infection.     

Mitochondria can recognize and assemble fragments of a beta-barrel structure

β-barrel proteins are found in the outer membranes of eukaryotic organelles of endosymbiotic origin as well as in the outer membrane of Gram-negative bacteria. Precursors of mitochondrial β-barrel proteins are synthesized in the cytosol and have to be targeted to the organelle. Currently, the signal that assures their specific targeting to mitochondria is poorly defined. To characterize the structural features needed for specific mitochondrial targeting and to test whether a full β-barrel structure is required, we expressed in yeast cells the β-barrel domain of the trimeric autotransporter Yersinia adhesin A (YadA). Trimeric autotransporters are found only in prokaryotes, where they are anchored to the outer membrane by a single 12-stranded β-barrel structure to which each monomer is contributing four β-strands. Importantly, we found that YadA is solely localized to the mitochondrial outer membrane, where it exists in a native trimeric conformation. These findings demonstrate that, rather than a linear sequence or a complete β-barrel structure, four β-strands are sufficient for the mitochondria to recognize and assemble a β-barrel protein. Remarkably, the evolutionary origin of mitochondria from bacteria enables them to import and assemble even proteins belonging to a class that is absent in eukaryotes.     

The turn of the screw: variations of the abundant beta-solenoid motif in passenger domains of Type V secretory proteins

Many virulence factors of gram-negative bacteria are secreted by the Type V secretion system via the autotransporter (AT) and two-partner secretion (TPS) pathways. AT proteins effect their own secretion. They comprise three domains: the amino-terminal leader sequence; the secreted passenger domain; and the translocator domain that forms the secretory channel. In the TPS pathway, the passenger and translocator domains are translated as separate proteins. In a previous publication, we proposed a beta-helical structure for the TPS passenger domain of the filamentous hemagglutinin (FHA) of Bordetella pertussis which contains two tracts, R1 and R2, of 19-residue sequence repeats and built molecular models for the R1 and R2 beta-helices. Here, we compare the structure predicted for R1 with the recently determined crystal structure of a fragment containing three R1 repeats and find close agreement, with an RMSD of 1.1A. In the interim, the number of known AT and TPS protein sequences has increased to >1000. To investigate the incidence of beta-helical structures among them, we carried out a sequence-based analysis and conclude that, despite wide diversity in the sizes and sequences of passenger domains, most of them contain beta-solenoids that we classify into thirteen types based on distinctive properties of their beta-coils (repeat length, numbers and lengths of beta-strands and turns, cross-sectional shape, presence of specific residues in certain positions) summarized in a 2D coil template. Some coil types are typical for conventional AT proteins, others, for TPS or trimeric AT proteins. Some beta-solenoids consist of stacked subdomains with coils of different types. To illustrate model-building from a coil template, we modeled a type-T4 beta-solenoid for TibA of Escherichia coli which is predicted to have two conserved polar residues, Thr and Gln, in interior positions.     

BamA is required for autotransporter secretion

BackgroundIn Gram-negative bacteria, type Va and Vc autotransporters are proteins that contain both a secreted virulence factor (the “passenger” domain) and a β-barrel that aids its export. While it is known that the folding and insertion of the β-barrel domain utilize the β-barrel assembly machinery (BAM) complex, how the passenger domain is secreted and folded across the membrane remains to be determined. The hairpin model states that passenger domain secretion occurs independently through the fully-formed and membrane-inserted β-barrel domain via a hairpin folding intermediate. In contrast, the BamA-assisted model states that the passenger domain is secreted through a hybrid of BamA, the essential subunit of the BAM complex, and the β-barrel domain of the autotransporter.MethodsTo ascertain the models' plausibility, we have used molecular dynamics to simulate passenger domain secretion for two autotransporters, EspP and YadA.ResultsWe observed that each protein's β-barrel is unable to accommodate the secreting passenger domain in a hairpin configuration without major structural distortions. Additionally, the force required for secretion through EspP's β-barrel is more than that through the BamA β-barrel.ConclusionsSecretion of autotransporters most likely occurs through an incompletely formed β-barrel domain of the autotransporter in conjunction with BamA.General significanceSecretion of virulence factors is a process used by practically all pathogenic Gram-negative bacteria. Understanding this process is a necessary step towards limiting their infectious capacity.     

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.     

Adhesive activity of the haemophilus cryptic genospecies cha autotransporter is modulated by variation in tandem Peptide repeats

The Haemophilus cryptic genospecies is an important cause of maternal genital tract and neonatal systemic infections and initiates infection by colonizing the genital or respiratory epithelium. In recent work, we identified a unique Haemophilus cryptic genospecies protein called Cha, which mediates efficient adherence to genital and respiratory epithelia. The Cha adhesin belongs to the trimeric autotransporter family and contains an N-terminal signal peptide, an internal passenger domain that harbors adhesive activity, and a C-terminal membrane anchor domain. The passenger domain in Cha contains clusters of YadA-like head domains and neck motifs as well as a series of tandem 28-amino-acid peptide repeats. In the current study, we report that variation in peptide repeat number gradually modulates Cha adhesive activity, associated with a direct effect on the length of Cha fibers on the bacterial cell surface. The N-terminal 404 residues of the Cha passenger domain mediate binding to host cells and also facilitate bacterial aggregation through intermolecular Cha-Cha binding. As the tandem peptide repeats expand, the Cha fiber becomes longer and Cha adherence activity decreases. The expansion and contraction of peptide repeats represent a novel mechanism for modulating adhesive capacity, potentially balancing the need of the organism to colonize the genital and respiratory tracts with the ability to attach to alternative substrates, disperse within the host, or evade the host immune system.