INTRODUCTION

Top Introduction Conclusion References

Bacterial pathogens must execute a prodigious array of complex functions in order to survive, multiply, and disseminate within mammalian hosts. Virulence determinants are usually proteinaceous in nature and are often either secreted to the bacterial cell surface or released into the external environment. Although secreted virulence proteins serve many divergent functions, remarkably, gram-negative bacteria have developed only a small number of secretion systems by which such proteins pass through their outer membranes. In this review, we discuss the virulence functions assigned or suspected for proteins secreted via the type V autotransporter pathway (Table 1).

	GRAM-NEGATIVE SECRETION MECHANISMS

Five major protein secretion pathways (respectively numbered, for better or worse, from I to V) have been characterized for gram-negative bacteria. Type I secretion is exemplified by the secretion pathway defined for Escherichia coli hemolysin (HlyA). Secretion requires three accessory proteins which comprise a channel spanning both the inner and outer membranes (40, 145). The type II protein secretion system is exemplified by the pullulanase (PulA) system of Klebsiella oxytoca. PulA secretion requires the action of approximately 14 additional accessory proteins, which are encoded on a single continuous operon (127). The type II system also features a macromolecular, multicomponent structure that most probably spans both inner and outer membranes (109). Notably, unlike the type I and type III secretion systems and some members of the type IV secretion system, secretion of pullulanase across the inner membrane is sec-dependent.

The type III secretion pathway is an area of intensive research. Secretion of type III effector molecules requires a complex apparatus of proteins which assemble into a tightly regulated oligomeric structure spanning the inner and outer membranes. Although the sec system is not required for secretion of the effector molecules, the sec machinery is required for translocation of some of the component proteins of the secretion apparatus across the inner membrane (50, 80).

It is worth noting here that for a variety of reasons the terminology for two secretion systems (type IV and type V) has been confused within the literature for quite some time. Recently, a consensus opinion on the terminology was published, and the nomenclature we use here reflects that consensus (68, 136). Thus, type IV secretion involves the coordinate action of at least nine proteins that are variously associated with the inner and outer membranes and are localized within the periplasm and cytoplasm. The best-characterized systems are those utilized by Bordetella pertussis to secrete pertussis toxin and by Agrobacterium tumefaciens to deliver T-DNA (17, 157). The export process is perhaps the least understood of the gram-negative bacterial secretion mechanisms.

Given the complex nature of the other secretion systems described above, the simplicity of the autotransporter (type V [see references 68 and 136]) secretion mechanism is remarkable. All proteins that are secreted by this mechanism possess an overall unifying structure, comprising (i) an amino-terminal leader peptide (for secretion across the inner membrane), (ii) the secreted mature protein (or passenger domain), and (iii) a dedicated C-terminal domain, which forms a pore in the outer membrane through which the passenger domain passes to the cell surface (Fig. 1). It is assumed that all the requirements for secretion across the outer membrane are contained within a single molecule and that secretion is an energy-independent process. Although this represents the simplest form of secretion, there are considerable biophysical constraints on secretion; since the protein must be secreted through a relatively small pore, the structural properties of the proteins are confined by the size of the pore (73).

View larger version (45K): [in this window] [in a new window]   FIG. 1.   Model of autotransporter (type V) secretion mechanism. Proteins exported by the autotransporter secretion mechanism are translated as a polyprotein possessing three domains. The three domains of the polyprotein (the leader sequence, the passenger domain, and the C-terminal -domain) are indicated. The leader sequence directs secretion via the sec apparatus and is cleaved at the inner membrane by a signal peptidase releasing the remaining portion of the molecule into the periplasm. Once in the periplasm the -domain assumes a biophysically favored state characterized by a -barrel shaped structure which inserts itself into the outer membrane to form a pore. After insertion into the outer membrane the passenger domain is translocated to the bacterial cell surface where it may remain intact or undergo processing. A processed protein may be released into the extracellular milieu or remain associated with the bacterial cell surface.

Once at the cell surface the destinies of autotransporter passenger domains diverge. The passenger domains may remain uncleaved and protrude from the bacterial surface, as a large polyprotein, or instead the protein may be cleaved from the -domain and then either remain loosely associated with the -domain or become released into the external milieu (73). Evidence from the study of other systems suggests that the proteolytic pathway followed by each passenger domain is integrally associated with the physiological function of the protein. Although a sizeable amount of evidence supports the above descriptions, they are still largely hypothetical and many questions relating to the basic mechanism of autotransporter secretion remain. The secretion mechanism and hypotheses surrounding secretion of the autotransporters have been adequately reviewed elsewhere (73) and will not be considered further here.

	PHYLOGENY OF AUTOTRANSPORTER PROTEINS

The autotransporters are a growing family of proteins, members of which have been identified across the breadth of the gram-negative evolutionary tree (Fig. 2A); as expected, the phylogeny of the proteins is complex. Although the -domains generally display a degree of conservation consistent with their highly conserved function, the passenger domains are widely divergent, reflecting their remarkably disparate roles (73). However, despite this complexity, several inferences can be made from the phylogenetic study of these proteins. The influence of horizontal gene transfer on autotransporter distribution within the gram-negative bacteria is illustrated by the immunoglobulin A1 (IgA1) proteases; despite the fact that Neisseria and Haemophilus are located on distinct branches of the evolutionary tree (Fig. 2), members of the IgA1 proteases can be found in both species. Evidence for divergent evolution among the autotransporters is provided by examination of the serine protease autotransporters of the Enterobacteriaceae (SPATEs). Members of this closely related group of proteins have evolved specific and distinct functions which are adaptive for the particular niche occupied by the pathogen even though they possess significant homology (40 to 100% identity) through the complete protein. In this review, we will discuss known functions (Table 1) of the best-characterized autotransporter passenger domains within the phylogenetic context. Our ability to identify distinct subfamilies allows us to infer evolutionary histories for many of these proteins and serves as a platform for a discussion of their functions (Fig. 2B).

View larger version (20K): [in this window] [in a new window]   FIG. 2.   Phylogenetic distribution of the autotransporters. (A) Phylogenetic tree of the eubacteria based on 16S rRNA sequences. The tree contains a detailed list of the gram-negative proteobacteria and their subdivisons (identified by Greek symbols) and was adapted from information appearing elsewhere (137) and at the Bergey's Manual Trust website (http://www.cme.msu.edu/Bergeys/btcomments/bt9.pdf). Genera for which autotransporters have been identified and characterized are indicated by boldface. The number of autotransporters identified per genus is given in parentheses after the genus name. (B) Phylogenetic tree of the autotransporter proteins inferred from comparison of the complete amino acid sequences of the polyproteins. The sequences were aligned using the multisequence alignment program CLUSTALX. Phylogenetic relationships and evolutionary distances were calculated, and a dendrogram was constructed using the neighbor-joining method. The positions of the autotransporter proteins within the tree are indicated by families such that the IgA1 proteases from Neisseria meningitidis and N. gonorrhoeae and H. influenzae cluster in the IgA1 protease family, etc.

	SERINE PROTEASE AUTOTRANSPORTERS OF THE TRYPSIN FAMILY

IgA1 proteases. The IgA1 proteases of Neisseria and Haemophilus were the first proteins for which the autotransporter secretion strategy was identified (123, 125). These are proteases of the serine protease family whose outer membrane translocation is dependent on the activity of the trypsin-like active site (GDGSP, where S is the catalytic residue) (122). Interestingly, the proteins are processed after secretion to form the mature active IgA1 protease and separate - and -peptides which appear to have distinct and separate functional roles (123, 124).

Hap. Nontypeable H. influenzae, a common commensal organism, is an important cause of localized respiratory tract disease. Infection is generally preceded by bacterial colonization of the nasopharynx; under certain circumstances, such as obstruction of the eustachian tube or sinus ostia, the organism can infect the middle ear or sinuses (129).

SPATEs. Over the last 10 years, workers at several laboratories have described serine protease autotransporters secreted by members of the Enterobacteriaceae. Members of this family, accordingly termed the SPATEs, have been found in several pathogens, although their full contributions to pathogenesis are as yet unknown (73). One of the prominent features of these proteins, however, is the fact that each is among the predominant secreted proteins of their respective pathogens and also that no SPATE has been identified in a nonpathogenic organism (I. R. Henderson and J. P. Nataro, unpublished observations).

View larger version (114K): [in this window] [in a new window]   FIG. 3.   Toxic effects of Pet. Both treated (A) and untreated (B) HEp-2 epithelial cells were incubated for 6 h at 37°C in culture medium without antibiotics and serum. Release of cellular focal contacts from the glass substratum, rounding of the cells, and cell detachment from the glass substratum are features consistently observed after treatment with Pet. Remnant cells after almost complete detachment of cells from the glass substratum are visible in panel A. Scanning electron photomicrographs of in vitro-cultured human colonic tissues infected with wild-type enteroaggregative E. coli expressing Pet (C) and an insertional mutant strain not expressing the protein (D) are also shown. The surface of the colon specimen shown in panel C is abnormal compared to that shown in panel D, as manifested by increased crypt aperture (arrowheads) and goblet cell pitting (arrows) when compared Bars, 50 µm.

	NONPROTEASE AUTOTRANSPORTERS OF ENTEROBACTERIACEAE

Ag43, AIDA-I, and TibA. Antigen 43 (Ag43), AIDA-I, and TibA appear to belong to an E. coli autotransporter subfamily which is defined on the basis of amino acid homology and the presence of repetitive amino acid motifs (as shown in the phylogram of Fig. 2). In this respect, these proteins resemble pertactin of Bordetella spp., which forms the largest -helix known to date (see below). Although the full roles of these repetitive elements has not been investigated, repetitive amino acid sequence motifs are often characteristic of proteins with adherence functions. Indeed, adhesive phenotypes have been attributed to all three of these proteins.

IcsA. S. flexneri causes diarrhea by directly invading the colonic epithelium and eliciting a localized inflammatory response. Once inside the cell, S. flexneri lyses the phagocytic vacuole and is released into the cytoplasm. Here the bacterium subverts the host cell cytoskeleton to move from one cell to the next. IcsA (also known as VirG), a 120-kDa autotransporter, mediates this intracellular motility by assembling actin into bundled filaments at one pole of the organism (57, 59, 147). The continuous polymerization of actin in this fashion propels the organism through the cytoplasm, eventually allowing the bacterium to spread to adjacent host cells. This autotransporter has been reviewed in detail elsewhere and will not be considered further here (56, 58, 133, 134).

	AUTOTRANSPORTERS OF BORDETELLA

The autotransporters of Bordetella form a homologous family defined on the basis of their conserved C termini and the possession of RGD motifs of the type implicated in integrin binding. However, despite the similarity and possession of identical functional motifs the apparent physiological roles of these proteins are remarkably divergent.

Pertactin. B. pertussis and Bordetella parapertussis are closely related organisms that are responsible for human pertussis. Bordetella bronchiseptica is normally an animal pathogen, but can cause respiratory disease in compromised human hosts. These three species produce a number of well-characterized virulence factors, including filamentous hemagglutinin (FHA), adenylate cyclase, pili, and a species-specific protein termed pertactin; only B. pertussis produces pertussis toxin (121). The passenger domains of the pertactin molecules are represented in B. pertussis (22), B. parapertussis (95), and B. bronchiseptica (94) as proteins of 69 kDa (P.69), 70 kDa (P.70), and 68 kDa (P.68), respectively. The processed mature passenger domain remains noncovalently associated with the 30-kDa -domain in a manner reminiscent of Ag43 and AIDA-I, described above (21). The difference in size between P.68, P.69, and P.70 can be accounted for by the number of internal repeats contained within the passenger domain; P.68 possesses the fewest and P.70 the most.

BrkA. Not surprisingly, wild-type B. pertussis is relatively resistant to the classical pathway of complement-dependent killing by normal human serum compared with E. coli HB101. Such resistance in B. pertussis is bvg regulated. FHA has been reported to bind C4 binding protein (13), an inhibitor of complement, but this activity does not contribute to serum resistance, as evidenced by the resistant phenotype of FHA mutants. Further studies have found that neither pertactin, pertussis toxin, adenylate cyclase toxin, dermonecrotic toxin, tracheal colonization factor, nor Vag8 mutants were more sensitive to serum killing than the wild type (42). Fernandez and Weiss identified an insertional mutant of B. pertussis which was at least 10-fold more susceptible to serum killing than the wild type and was less virulent in mice (41). The locus encoding this serum resistance function encodes two divergently transcribed open reading frames, termed BrkA and BrkB. Both ORFs are necessary for serum resistance. Within the 300 bases which separate the two ORFs are putative sites for BvgA binding. BrkA shows 29% identity to pertactin and has two RGD motifs in addition to a conserved proteolytic processing site and an outer membrane-targeting signal. Like pertactin, BrkA is involved in adherence and invasion. Despite the similarities, a pertactin mutant was not as sensitive to serum killing as the BrkA or BrkB mutants. BrkB is similar to ORFs of unknown function in E. coli and Mycobacterium leprae and is predicted to be a cytoplasmic membrane protein (41).

TcfA and Vag8. TcfA is produced by strains of B. pertussis but not B. bronchiseptica or B. parapertussis. The predicted amino acid sequence of tcfA suggests a 68-kDa RGD-containing, proline-rich protein, whose -domain displays 50% identity to the pertactin -domain (46). The 34-kDa passenger domain contains the RGD motif implicated in integrin binding. Polyclonal antiserum raised against the unique N-terminal portion of TcfA recognizes 90- and 60-kDa bands in immunoblots of B. pertussis whole-cell lysates. However, culture supernatants of B. pertussis contain only the 60-kDa form, indicating that outer-membrane-associated and secreted versions of the passenger domain exist. When mice are challenged with a strain of B. pertussis lacking TcfA, the number of bacteria isolated from the tracheas is decreased 10-fold compared to that isolated from tracheas of mice challenged with the wild-type organism (46). The mechanism contributing to this difference has yet to be elucidated.

	MORAXELLA AUTOTRANSPORTERS

Moraxella catarrhalis, an unencapsulated, gram-negative bacterium, is an important pathogen of the upper respiratory tract in children and adults. Efforts to identify potential vaccine candidates among M. catarrhalis surface antigens have focused on outer membrane proteins, in particular the UspA antigen (ubiquitous surface protein A) (66). Initial investigations of UspA indicated it was a high-molecular-weight protein (>250 kDa) responsible for serum resistance and attachment to human epithelial cells. It was therefore surprising when detailed investigations by Hansen and coworkers revealed that this UspA antigen was in fact composed of two proteins, UspA1 and UspA2, with different characteristics (2, 27). In M. catarrhalis 035E, the uspA1 and uspA2 genes encode predicted proteins of 88 and 62 kDa, the native forms of which form oligomers or aggregates (2). The amino acid sequences of UspA1 and UspA2 are 43% identical, but each possesses an internal immunoreactive region displaying 93% identity (102). This region, which is present in all disease-associated isolates of M. catarrhalis tested to date, induces the synthesis of antibodies that enhance the elimination of M. catarrhalis in a mouse pulmonary model (66).

Although structurally related, UspA1 and UspA2 appear to mediate different biological functions. Antiserum directed against the original purified UspA inhibited attachment of M. catarrhalis to epithelial cells (D. Chen, J. McMichael, K. Vandermeid, D. Hahn, R. Smith, J. Eldridge, and J. Cowell, Abstr. 95th Gen. Meet. Am. Soc. Microbiol. 1995, abstr. E-53, p. 290, 1995). In contrast, Verduin et al. (150; C. M. Verduin, H. J. Bootsma, C. Hol, A. Fleer, M. Jansze, K. L. Klingman, T. F. Murphy, and H. Var Dijk, Abstr. 95th Gen. Meet. Am. Soc. Microbiol. 1995, abstr. B-137, p. 189, 1995) suggested that UspA was a serum resistance factor produced by disease isolates of M. catarrhalis. Both studies were published before it was known that UspA was composed of two separate proteins. To dissect these properties Aebi et al. (1) constructed a set of isogenic mutants that lacked the ability to express UspA1, UspA2, or both of these proteins. Investigations using these mutants revealed that both the uspA1 and uspA1 uspA2 mutants were significantly handicapped in their ability to adhere to cells in vitro compared to the wild type. In contrast, the uspA2 mutant was unaffected. When the set of three isogenic M. catarrhalis mutants was incubated in normal human serum, the uspA2 mutant and the uspA1 uspA2 mutant were both readily killed. In contrast, the uspA1 mutant resisted killing as effectively as the wild-type parent strain did (1). However, the available data do not reveal whether UspA2 exerts a direct or indirect effect on serum resistance of M. catarrhalis; this is particularly important in view of the fact that a previous study had shown that lack of expression of the CopB outer membrane protein resulted in loss of serum resistance by M. catarrhalis (67).

Interestingly, analysis of other M. catarrhalis strains led to the discovery of a second type of UspA2 protein (UspA2h) that is comprised of amino acid segments from both UspA1 and UspA2 (90). Investigations suggested that like UspA1, this second type of UspA2 protein acts as an adhesin when expressed in H. influenzae and that it provides no protection against serum killing. This is not surprising given that the greatest degree of conservation between UspA2 and UspA2h lies in the C-terminal -barrel domains, whereas the greatest degree of conservation between UspA1 and UspA2h is found in the putative passenger or functional domain.

	NONSERINE PROTEASE AUTOTRANSPORTERS OF HAEMOPHILUS

In addition to the Hap and IgA1 proteases, H. influenzae possesses two other autotransporters, Hsf and Hia (5, 143). These proteins share significant homology (72% identity), predominately at the N- and C-terminal ends. However, Hsf is larger than Hia (244 kDa versus 114 kDa), a feature mediated in part by the presence of a repetitive domain in Hsf which is only present as a single copy in Hia. Interestingly, in experiments with human epithelial cell lines, both Hia and Hsf were found to confer similar adhesive properties. This phenotypic similarity in conjunction with the amino acid similarity suggests that Hia and Hsf are alleles of the same locus (142). Expression of Hsf has been observed in H. influenzae type b and is associated with the production of surface appendages termed fibrils (143). Analysis of a collection of nontypeable H. influenzae demonstrated the presence of Hia in approximately 20% of strains. Expression of Hia was only detected in those strains which were deficient in expression of the high-molecular-weight proteins HMW1 and HMW2, proteins which were secreted by a mechanism analogous to that of FHA from B. pertussis (89). The importance of Hia as a virulence determinant was suggested by the uniform presence of Hia in nontypeable H. influenzae lacking HMW1- and HMW2-like proteins or hemagglutinating pili (142).

	OTHER SERINE PROTEASE AUTOTRANSPORTERS

Aside from the trypsin-like serine proteases described above, the autotransporter family possesses serine proteases belonging to two other enzymatic families. Recently, a family of lipolytic autotransporter enzymes has been characterized which possess an active site defined by the residues GDSL, where the serine has been defined as the catalytic residue. The other group of autotransporter serine proteases belongs to an extensive family whose catalytic activity is provided by a charge relay system similar to that employed by the trypsin family but which apparently evolved convergently. The sequence surrounding the residues involved in the catalytic triad (D, S, and H residues) is different from the analogous residues in the trypsin-like serine proteases described above. Interestingly, this family of proteases is best characterized for Bacillus, and as a result its members are referred to as the subtilases.

Several autotransporter subtilases from different species have been identified, including PrtT and PrtS (both previously designated Ssp) (103). Ssp-H1 and Ssp-H2 from Serratia marcesens (110), PspA and PspB from Pseudomonas fluorescens (85), Ssa1 from Pasteurella haemolytica (60, 99), and the putative autotransporters BprV, BprB, AprV2, and BprX from Dichelobacter nodosus (96, 131, 149). Despite the identification of PrtT over 15 years ago, the subsequent identification of multiple homologs in different strains (110), and the extensive investigation on the secretion of this autotransporter (103, 111, 112, 138-140), little has been done to elucidate a role for this protein. PspA and PspB were only recently described and appear to be present on a chromosomal island with genes encoding the P. fluorescens lipase and alkaline protease. A role has not been demonstrated for either of these proteins (84). P. haemolytica strains have been grouped into 15 serotypes on the basis of standardized typing antisera raised in rabbits. In contrast to S. marcesens and P. fluorescens, P. haemolytica serotype 1 has been established as the primary agent responsible for acute lobar fibrinonecrotizing pleuropneumonia in cattle. Serotype 1 is rarely found in healthy cattle, but serotype 2 is cultured frequently from the upper respiratory tracts of healthy animals (60, 99). Interestingly, both serotypes possess the gene encoding serotype-specific antigen Ssa1 but P. haemolytica serotype 2 strains do not express serologically detectable levels of the Ssa1 protein. In addition, cattle showing resistance to pneumonic pasteurellosis have been shown to possess antibodies to Ssa1 which appear to be protective (153). Despite this promising early work on Ssa1, a distinct role for this autotransporter was never defined. D. nodosus is an obligate anaerobe and the causative agent of ovine foot rot (14). Virulent strains secrete at least three proteases into the extracellular milieu. Based on the levels of homology these putative serine protease autotransporters from D. nodosus appear to represent a different lineage of the subtilase family. The proteins have been implicated in tissue destruction, and hence virulence, by virtue of their ability to act as elastases in in vitro assays (14, 96, 131, 162).

Pseudomonas aeruginosa is a soil bacterium that is an important opportunistic pathogen of humans. Strains isolated from cystic fibrosis patients secrete a variety of proteins including lipase and two extracellular phopholipases which are involved in hydrolyzing long- and short-chain fatty acids and a variety of phosphoric monoester substrates. Recent investigations with lipase-negative mutants of P. aeruginosa identified residual lipolytic activity associated with the surface of the bacterium. This activity was attributed to a novel autotransporter esterase, EstA, which is a member of the GDSL family of serine proteases (155). Such lipases are important in the pathogenesis of cystic fibrosis, mediating complete hydrolysis of the major lung surfactant lipid, dipalmitoylphosphatidylcholine (155). Moreover, such enzymes have been shown to induce the release of the inflammatory mediator 12-hydroxyeicosatetraenoic acid from human platelets (87, 88). However, a specific substrate for EstA, and its relevance to pathogenicity, have yet to be defined in detail. Similar enzymes ApeE and PlaA, have been identified in Salmonella serovar Typhimurium (19, 26) and the insect pathogen Xenorhabdus luminescens (152), respectively. The data presented in the initial descriptions of these enzymes provide few clues to the physiological function of these proteins. They are not required for growth, although it is conceivable that these enzymes are required for the catabolic breakdown of fatty acid esters.

	RICKETTSIAL AUTOTRANSPORTERS

The Rickettsiales are fastidious bacteria which form a distinct monophylectic group within the -Proteobacteriaceae. Based on a variety of clinical and molecular factors Rickettsiales is normally divided into the typhus and the spotted fever groups. Two homologous autotransporter proteins, rOmpA and rOmpB, have been identified among the Rickettsiales (25, 29, 52, 54, 55). The rOmpB proteins appear to form an S layer on the surface of the bacteria (20, 62, 63), whereas a surface structure for rOmpA has not been described. No function has been clearly assigned to these proteins. The sequence variations in the rOmpA proteins have been used extensively in an effort to determine the evolutionary status of the spotted fever group of Rickettsiales (49, 132, 154), however, such analysis may be misleading, since rOmpA exhibits a mosaic structure (53). Nevertheless, rOmpA has been proposed to act as a mediator of adhesion and intracellular motility. In the latter respect, Rickettsia spp. have been shown to recruit actin and move through the cellular cytoplasm in a manner similar to that described for Shigella (see IcsA above) (61). Indeed, a common rOmpA-IcsA domain has been described, although mutagenesis of this domain had no apparent affect on actin-mediated motility (24). Furthermore, given the remarkable repetitive structure of the protein, in addition to the homology displayed with other known adhesins, a role as an adhesion factor seems more likely. Moreover, Li and Walker (93) have demonstrated that recombinant rOmpA protein inhibited rickettsial adhesion to host cells in a dose-dependent fashion. Similarly, antibodies directed to rOmpA competitively inhibited rickettsial attachment to eukaryotic cells. Alternatively, rOmpA may play a role in the induction of phagocytosis of Rickettsia spp.

The rOmpB protein is the most abundant surface protein on Rickettsia spp. anti-rOmpB antibodies protect mice against otherwise lethal rickettsial challenge. Ultrastructural analysis of the outer membrane reveals that rOmpB is responsible for the presence of a regularly arrayed surface structure, or S layer (20). Although information about the physical and chemical structure and the mode of assembly of S layers has been accumulating, the functions of the S layers remain unclear. As S layers exist as an interface between the cell and its environment, they have been purported to function as protective coats, molecular sieves, and ion traps and to be instrumental in cell adhesion (25, 135, 141).

	HELICOBACTER AUTOTRANSPORTERS

Helicobacter pylori is a gram-negative human pathogen which colonizes the human stomach in childhood and persists within the gastric mucus layer (104). Epidemiological investigations reveal a strong association between H. pylori disease and the ability of the bacterium to produce the vacuolating cytotoxin (VacA), the cytotoxin associated antigen (CagA), and the blood-group antigen binding adhesin (BabA) (43, 51). Interestingly, two of these proteins, VacA and BabA, are autotransporters.

VacA. VacA is a major virulence factor of H. pylori; several recent reviews are available on this well-studied toxin (4, 28, 44, 101, 120, 130). VacA is produced as a 140-kDa precursor, which is processed to a 95-kDa mature protein upon secretion into the extracellular milieu; here, it undergoes further processing into 37- and 58-kDa fragments that remain associated through noncovalent interaction. Acting at an intracellular site, mature VacA induces vacuolization of target cells by a mechanism that is still not completely understood. Transfection of recombinant VacA toxin into the cytosol of cultured cells has shown that the toxic domain resides within the 37-kDa polypeptide.

BabA. Recent studies have identified H. pylori adherence factors that mediate its tropism for the gastric epithelium. H. pylori bound to gastric surface mucous cells expressing the Lewis^b (-1,3/4-difucosylated) blood group antigen and colonized stomachs of transgenic mice expressing the Lewis^b antigen in gastric epithelial cells. A 78-kDa H. pylori outer membrane protein adhesin termed BabA was identified by cross-linking to the Lewis^b antigen (81). Moreover, additional investigations demonstrated that all members of a subset of strains expressing BabA bound to Lewis^b-coated microtiter dishes, whereas those organisms which did not express the protein did not adhere (51).

Hsr. Helicobacter mustelae is a spiral microaerophilic bacterium linked to gastritis and gastric ulcers in ferrets. The cell surface of H. mustelae differs markedly from other members of the genus Helicobacter by exhibiting a laterally extensive array of 8.5-nm-diameter rings. Genotypic, phenotypic, and immunological analyses of H. mustelae reveal that Hsr, a 150-kDa protein associated with the outer membrane of the organism, is responsible for the formation of these ring structures (113). Such analyses also reveal that Hsr is a member of the autotransporter family, is not cleaved into separate passenger and -domains, and remains anchored in the outer membrane as a single proteinaceous molecule. Cross-reactive proteins were identified in three H. mustelae strains, but not in H. pylori or Helicobacter felis (113). Hsr surface arrays are reminiscent of S layers described for many species of bacteria and bearing functional homology to the autotransporters of Rickettsia spp. Indeed, rOmpA and rOmpB display the greatest homology with the passenger domain of Hsr. In contrast, the C-terminal autotransporter domain displays the closest homology with the SPATEs described above (Henderson and Nataro, unpublished). It is possible that the presence of Hsr contributes to H. mustelae colonization by conferring serum resistance, antiphagocytic activity, or antigenic variation, roles which have been described for other S-layer proteins.

	CONCLUSIONS

Top Introduction Conclusion References

The autotransporter, or type V, secretion system is a dedicated protein translocation mechanism which allows the organism to secrete proteins to and beyond the bacterial surface. The characterization of the IgA1 protease secretion mechanism commenced the study of this now rapidly expanding family of proteins and it is likely that future investigations will reveal an even more complex array of proteins secreted in this fashion. The simplicity of the secretion mechanism and the ability to develop a new autotransporter protein simply by a single recombination event have presented bacteria with abundant opportunities to increase the efficiency of secretion of proteins that were probably already developed as periplasmic or exported virulence factors. In addition, phylogenetic data suggest that several autotransporter-secreted proteins were embued by evolution with new or expanded functions, often upon introduction into new pathogens occupying different niches (Henderson and Nataro, unpublished).

In addition to the autotransporter proteins listed above, several others have been described, e.g., MisL of Salmonella serovar Typhimurium (15), but are not yet characterized. Indeed, examination of the sequence databases reveals a plethora of new autotransporter candidates that await postgenomic studies (Henderson and Nataro, unpublished). Moreover, we feel that reexamination of already identified proteins is likely to expand the size and perhaps the definition of the autotransporter family. For example, Ssa1 of P. haemolytica possesses the characteristics of autotransporters but has not previously been recognized as a member of this family. A great deal of research is required to understand both the roles of these proteins and the fundamental features of autotransporter secretion and processing.