The unipolar Shigella surface protein IcsA is targeted directly to the bacterial old pole: IcsP cleavage of IcsA occurs over the entire bacterial surface

Shigella flexneri is an intracellular pathogen that is able to move within the cytoplasm of infected cells by the continual assembly of actin onto one pole of the bacterium. IcsA, an outer membrane protein, is localized to the old pole of the bacterium and is both necessary and sufficient for actin assembly. IcsA is slowly cleaved from the bacterial surface by the protease IcsP (SopA). Absence of IcsP leads to an alteration in the distribution of surface IcsA, such that the polar cap is maintained and some IcsA is distributed along the lateral walls of the bacillus. The mechanism of unipolar localization of IcsA and the role of IcsP in its unipolar localization are incompletely understood. Here, we demonstrate that cleavage of IcsA occurs exclusively in the outer membrane and that IcsP is localized to the outer membrane. In addition, we show that IcsA at the old pole is susceptible to cleavage by IcsP and that native IcsP is active at the pole. Taken together, these data indicate that IcsP cleaves IcsA over the entire bacterial surface. Finally, we show that, immediately after induction from a tightly regulated promoter, IcsA is expressed exclusively at the old pole in both the icsP- icsA- and the icsA- background. These data demonstrate that unipolar localization of IcsA results from its direct targeting to the pole, followed by its diffusion laterally in the outer membrane.     

The making of a gradient: IcsA (VirG) polarity in Shigella flexneri

The generation and maintenance of subcellular organization in bacteria is critical for many cell processes and properties, including growth, structural integrity and, in pathogens, virulence. Here, we investigate the mechanisms by which the virulence protein IcsA (VirG) is distributed on the bacterial surface to promote efficient transmission of the bacterium Shigella flexneri from one host cell to another. The outer membrane protein IcsA recruits host factors that result in actin filament nucleation and, when concentrated at one bacterial pole, promote unidirectional actin-based motility of the pathogen. We show here that the focused polar gradient of IcsA is generated by its delivery exclusively to one pole followed by lateral diffusion through the outer membrane. The resulting gradient can be modified by altering the composition of the outer membrane either genetically or pharmacologically. The gradient can be reshaped further by the action of the protease IcsP (SopA), whose activity we show to be near uniform on the bacterial surface. Further, we report polar delivery of IcsA in Escherichia coli and Yersinia pseudotuberculosis, suggesting that the mechanism for polar delivery of some outer membrane proteins is conserved across species and that the virulence function of IcsA capitalizes on a more global mechanism for subcellular organization.     

Actin-based motility is sufficient for bacterial membrane protrusion formation and host cell uptake

Shigella flexneri replicates in the cytoplasm of host cells, where it nucleates host cell actin filaments at one pole of the bacterial cell to form a 'comet tail' that propels the bacterium through the host's cytoplasm. To determine whether the ability to move by actin-based motility is sufficient for subsequent formation of membrane-bound protrusions and intercellular spread, we conferred the ability to nucleate actin on a heterologous bacterium, Escherichia coli . Previous work has shown that IcsA (VirG), the molecule that is necessary and sufficient for actin nucleation and actin-based motility, is distributed in a unipolar fashion on the surface of S. flexneri . Maintenance of the unipolar distribution of IcsA depends on both the S. flexneri outer membrane protease IcsP (SopA) and the structure of the lipopolysaccharide (LPS) in the outer membrane. We co-expressed IcsA and IcsP in two strains of E. coli that differed in their LPS structures. The E. coli were engineered to invade host cells by expression of invasin from Yersinia pseudotuberculosis and to escape the phagosome by incubation in purified listeriolysin O (LLO) from Listeria monocytogenes . All E. coli strains expressing IcsA replicated in host cell cytoplasm and moved by actin-based motility. Actin-based motility alone was sufficient for the formation of membrane protrusions and uptake by recipient host cells. The presence of IcsP and an elaborate LPS structure combined to enhance the ability of E. coli to form protrusions at the same frequency as S. flexneri , quantitatively reconstituting this step in pathogen intercellular spread in a heterologous organism. The frequency of membrane protrusion formation across all strains tested correlates with the efficiency of unidirectional actin-based movement, but not with bacterial speed.     

Functional Analysis of a Rickettsial OmpA Homology Domain of Shigella flexneri IcsA

Shigella flexneri is a gram-negative bacterium that causes diarrhea and dysentery by invasion and spread through the colonic epithelium. Bacteria spread by assembling actin and other cytoskeletal proteins of the host into “actin tails” at the bacterial pole; actin tail assembly provides the force required to move bacteria through the cell cytoplasm and into adjacent cells. The 120-kDa S. flexneri outer membrane protein IcsA is essential for actin assembly. IcsA is anchored in the outer membrane by a carboxy-terminal domain (the β domain), such that the amino-terminal 706 amino acid residues (the α domain) are exposed on the exterior of the bacillus. The α domain is therefore likely to contain the domains that are important to interactions with host factors. We identify and characterize a domain of IcsA within the α domain that bears significant sequence similarity to two repeated domains of rickettsial OmpA, which has been implicated in rickettsial actin tail formation. Strains of S. flexneri and Escherichia coli that carry derivatives of IcsA containing deletions within this domain display loss of actin recruitment and increased accessibility to IcsA-specific antibody on the surface of intracytoplasmic bacteria. However, site-directed mutagenesis of charged residues within this domain results in actin assembly that is indistinguishable from that of the wild type, and in vitro competition of a polypeptide of this domain fused to glutathione S-transferase did not alter the motility of the wild-type construct. Taken together, our data suggest that the rickettsial homology domain of IcsA is required for the proper conformation of IcsA and that its disruption leads to loss of interactions of other IcsA domains within the amino terminus with host cytoskeletal proteins.     

Cleavage of Shigella surface protein VirG occurs at a specific site, but the secretion is not essential for intracellular spreading.

The large plasmid-encoded outer membrane protein VirG (IcsA) of Shigella flexneri is essential for bacterial spreading by eliciting polar deposition of filamentous actin (F-actin) in the cytoplasm of epithelial cells. Recent studies have indicated that VirG is located at one pole on the surface of the bacterium and secreted into the culture supernatant and that in host cells it is localized along the length of the F-actin tail. The roles of these VirG phenotypes in bacterial spreading still remain to be elucidated. In this study, we examined the surface-exposed portion of the VirG protein by limited trypsin digestion of S. flexneri YSH6000 and determined the sites for VirG processing during secretion into the culture supernatant. Our results indicated that the 85-kDa amino-terminal portion of VirG is located on the external side of the outer membrane, while the 37-kDa carboxy-terminal portion is embedded in it. The VirG cleavage required for release of the 85-kDa protein into the culture supernatant occurred at the Arg-Arg bond at positions 758 to 759. VirG-specific cleavage was observed in Shigella species and enteroinvasive Escherichia coli, which requires an as yet unidentified protease activity governed by the virB gene on the large plasmid. To investigate whether the VirG-specific cleavage occurring in extracellular and intracellular bacteria is essential for VirG function in bacterial spreading, the Arg-Arg cleavage site was modified to an Arg-Asp or Asp-Asp bond. The virG mutants thus constructed were capable of unipolar deposition of VirG on the bacterial surface but were unable to cleave VirG under in vitro or in vivo conditions. However, these mutants were still capable of eliciting aggregation of F-actin at one pole, spreading into adjacent cells, and giving rise to a positive Sereny test. Therefore, the ability to cleave and secrete VirG in Shigella species is not a prerequisite for intracellular spreading.     

IcsA, a polarly localized autotransporter with an atypical signal peptide, uses the Sec apparatus for secretion, although the Sec apparatus is circumferentially distributed

Asymmetric localization of proteins is essential to many biological functions of bacteria. Shigella IcsA, an outer membrane protein, is localized to the old pole of the bacillus, where it mediates assembly of a polarized actin tail during infection of mammalian cells. Actin tail assembly provides the propulsive force for intracellular movement and intercellular dissemination. Localization of IcsA to the pole is independent of the amino-terminal signal peptide (Charles, M., Perez, M., Kobil, J.H., and Goldberg, M.B., 2001, Proc Natl Acad Sci USA 98: 9871-9876) suggesting that IcsA targeting occurs in the bacterial cytoplasm and that its secretion across the cytoplasmic membrane occurs only at the pole. Here, we characterize the mechanism by which IcsA is secreted across the cytoplasmic membrane. We present evidence that IcsA requires the SecA ATPase and the SecYEG membrane channel (translocon) for secretion. Our data suggest that YidC is not required for IcsA secretion. Furthermore, we show that polar localization of IcsA is independent of SecA. Finally, we demonstrate that while IcsA requires the SecYEG translocon for secretion, components of this apparatus are uniformly distributed within the membrane. Based on these data, we propose a model for coordinate polar targeting and secretion of IcsA at the bacterial pole.     

Mutagenesis of the Shigella flexneri autotransporter IcsA reveals novel functional regions involved in IcsA biogenesis and recruitment of host neural Wiscott-Aldrich syndrome protein

The IcsA (VirG) protein of Shigella flexneri is a polarly localized, outer membrane protein that is essential for virulence. Within host cells, IcsA activates the host actin regulatory protein, neural Wiskott-Aldrich syndrome protein (N-WASP), which in turn recruits the Arp2/3 complex, which nucleates host actin to form F-actin comet tails and initiate bacterial motility. Linker insertion mutagenesis was undertaken to randomly introduce 5-amino-acid in-frame insertions within IcsA. Forty-seven linker insertion mutants were isolated and expressed in S. flexneri Delta icsA strains. Mutants were characterized for IcsA protein production, cell surface expression and localization, intercellular spreading, F-actin comet tail formation, and N-WASP recruitment. Using this approach, we have identified a putative autochaperone region required for IcsA biogenesis, and our data suggest an additional region, not previously identified, is required for N-WASP recruitment.     

Quantification of Shigella IcsA required for bacterial actin polymerization

Shigella move through the cytoplasm of host cells by active polymerization of host actin to form an "actin tail." Actin tail assembly is mediated by the Shigella protein IcsA. The process of Shigella actin assembly has been studied extensively using IcsA-expressing Escherichia coli in cytoplasmic extracts of Xenopus eggs. However, for reasons that have been unclear, wild type Shigella does not assemble actin in these extracts. We show that the defect in actin assembly in Xenopus extracts by Shigella can be rescued by increasing IcsA expression by approximately 3-fold. We calculate that the number of IcsA molecules required on an individual bacterium to assemble actin filaments in extracts is approximately 1,500-2,100 molecules, and the number of IcsA molecules required to assemble an actin tail is approximately 4,000 molecules. The majority of wild type Shigella do not express these levels of IcsA when grown in vitro. However, in infected host cells, IcsA expression is increased 3.2-fold, such that the number of IcsA molecules on a significant percentage of intracellular wild type Shigella would exceed that required for actin assembly in extracts. Thus, the number of IcsA molecules estimated from our studies in extracts as being required on an individual bacterium to assemble actin filaments or an actin tail is a reasonable prediction of the numbers required for these functions in Shigella-infected cells.     

Periplasmic transit and disulfide bond formation of the autotransported Shigella protein IcsA

The Shigella outer membrane protein IcsA belongs to the family of type V secreted (autotransported) virulence factors. Members of this family mediate their own translocation across the bacterial outer membrane: the carboxy-terminal beta domain forms a beta barrel channel in the outer membrane through which the amino-terminal alpha domain passes. IcsA, which is localized at one pole of the bacterium, mediates actin assembly by Shigella, which is essential for bacterial intracellular movement and intercellular dissemination. Here, we characterize the transit of IcsA across the periplasm during its secretion. We show that an insertion in the dsbB gene, whose gene product mediates disulfide bond formation of many periplasmic intermediates, does not affect the surface expression or unipolar targeting of IcsA. However, IcsA forms one disulfide bond in the periplasm in a DsbA/DsbB-dependent fashion. Furthermore, cellular fractionation studies reveal that IcsA has a transient soluble periplasmic intermediate. Our data also suggest that IcsA is folded in a proteinase K-resistant state in the periplasm. From these data, we propose a novel model for the secretion of IcsA that may be applicable to other autotransported proteins.     

Molecular bases of epithelial cell invasion by Shigella flexneri

The pathogenesis of shigellosis is characterized by the capacity of the causative microorganism, Shigella, to invade the epithelial cells that compose the mucosal surface of the colon in humans. The invasive process encompasses several steps which can be summarized as follows: entry of bacteria into epithelial cells involves signalling pathways that elicit a macropinocitic event. Upon contact with the cell surface, S. flexneri activates a Mxi/Spa secretory apparatus encoded by two operons comprising about 25 genes located on a large virulence plasmid of 220 kb. Through this specialized secretory apparatus, Ipa invasins are secreted, two of which (IpaB, 62 kDa and IpaC, 42 kDa) form a complex which is itself able to activate entry via its interaction with the host cell membrane. Interaction of this molecular complex with the cell surface elicits major rearrangements of the host cell cytoskeleton, essentially the polymerization of actin filaments that form bundles supporting the membrane projections which achieve bacterial entry. Active recruitment of the protooncogene pp 60^c-src has been demonstrated at the entry site with consequent phosphorylation of cortactin. Also, the small GTPase Rho is controlling the cascade of signals that allows elongation of actin filaments from initial nucleation foci underneath the cell membrane. The regulatory signals involved as well as the proteins recruited indicate that Shigella induces the formation of an adherence plaque at the cell surface in order to achieve entry. Once intracellular, the bacterium lyses its phagocytic vacuole, escapes into the cytoplasm and starts moving the inducing polar, directed polymerization of actin on its surface, due to the expression of IcsA, a 120 kDa outer membrane protein, which is localized at one pole of the microorganism, following cleavage by SopA, a plasmid-encoded surface protease. In the context of polarized epithelial cells, bacteria then reach the intermediate junction and engage their components, particularly the cadherins, to form a protrusion which is actively internalized by the adjacent cell. Bacteria then lyse the two membranes, reach the cytoplasmic compartment again, and resume actin-driven movement.     

Disruption of IcsP, the major Shigella protease that cleaves IcsA, accelerates actin-based motility

Shigella pathogenesis involves bacterial invasion of colonic epithelial cells and movement of bacteria through the cytoplasm and into adjacent cells by means of actin-based motility. The Shigella protein IcsA (VirG) is unipolar on the bacterial surface and is both necessary and sufficient for actin-based motility. IcsA is inserted into the outer membrane as a 120-kDa polypeptide that is subsequently slowly cleaved, thereby releasing the 95-kDa amino-terminal portion into the culture supernatant. IcsP, the major Shigella protease that cleaves IcsA, was identified and cloned. It has significant sequence similarity to the E. coli serine proteases, OmpP and OmpT. Disruption of icsP in serotype 2a S. flexneri leads to a marked reduction in IcsA cleavage, increased amounts of IcsA associated with the bacterium and altered distribution of IcsA on the bacterial surface. The icsP mutant displays significantly increased rates of actin-based motility, with a mean speed 27% faster than the wild-type strain; moreover, a significantly greater percentage of the icsP mutant moves in the cytoplasm. Yet, plaque formation on epithelial monolayers by the mutant was not altered detectably. These data suggest that IcsA, and not a host protein, is limiting in the rate of actin-based motility of wild-type serotype 2a S. flexneri .     

Unipolar localization and ATPase activity of IcsA, a Shigella flexneri protein involved in intracellular movement.

Shigella flexneri uses elements of the host cell cytoskeleton to move within cells and from cell to cell. IcsA, an S. flexneri protein involved in this movement, was purified and studied in vitro. IcsA bound the radiolabelled ATP analog 3'(2')-O-(4-benzoyl)benzoyl-ATP and hydrolyzed ATP. In addition, the surface localization of IcsA on both extracellular and intracellular shigellae was unipolar. Further, in HeLa cells infected with shigellae, IcsA antiserum labelled the actin tail throughout its length, thereby suggesting that IcsA interacts with elements within the tail. Localization of IcsA within the tail at a distance from the bacterium would require its secretion; we demonstrate here that in vitro IcsA is secreted into the culture supernatant in a cleaved form.     

Biogenesis of YidC Cytoplasmic Membrane Substrates Is Required for Positioning of Autotransporter IcsA at Future Poles

Localization of proteins to specific sites within bacterial cells is often critical to their function. In rod-shaped bacteria, proteins involved in diverse and important cell processes localize to the cell poles. The molecular mechanisms by which these proteins are targeted to the pole, however, are poorly understood. The Shigella autotransporter protein IcsA, which is localized to the pole on the surface of the bacterium, is targeted to the pole in the cytoplasm by a mechanism that is conserved across multiple Gram-negative bacterial species and has thus served as an important and informative model for studying polar localization. We present evidence that in Escherichia coli, the establishment of polar positional information recognized by IcsA requires the activity of the cytoplasmic membrane protein insertase YidC. We show that the role of YidC in IcsA localization is independent of the cell septation and cytokinesis proteins FtsQ and FtsEX. FtsQ is required for polar localization of IcsA and, based on cross-linking studies, is inserted in the vicinity of YidC, but, we find, is not dependent on YidC for membrane insertion. FtsEX is a YidC substrate, but we find that it is not required for polar localization of IcsA. These findings indicate that polar positional information recognized by IcsA depends on one or more membrane proteins that require YidC for proper membrane insertion.     

Shigella interactions with the actin cytoskeleton in the absence of Ena/VASP family proteins

Shigella move through the cytosol of infected cells by assembly of a propulsive actin tail at one end of the bacterium. Vasodilator-stimulated phosphoprotein (VASP), a member of the Ena/VASP family of proteins, is important in cellular actin dynamics and is present on intracellular Shigella. VASP binds both profilin, an actin monomer-binding protein, and vinculin, a component of intercellular contacts that also binds the Shigella actin assembly protein IcsA. It has been postulated that VASP might serve as a linker between vinculin and profilin on intracellular Shigella, thereby delivering profilin to the Shigella actin assembly machinery. We show that Shigella actin-based motility is unaltered in cells that are deficient for the Ena/VASP family of proteins. In these cells, Shigella form normal-appearing actin tails and move at rates that are comparable to the rates of bacterial movement in Ena/VASP-deficient cells complemented with the Ena/VASP family member Mena. Finally, whereas vinculin can bind the Arp2/3 complex, we show that Arp2/3 recruitment to Shigella is not correlated with vinculin recruitment, indicating that the role of vinculin in Shigella motility is not recruitment of Arp2/3. Thus, although VASP is recruited to the surface of intracellular Shigella, it is not essential for Shigella actin-based motility.     

Effect of O side-chain length and composition on the virulence of Shigella flexneri 2a

IcsA of Shigella flexneri is required for intercellular spread and is located in the outer membrane at one pole of the bacterium, where it catalyses the polymerization of host-cell actin. The formation of the actin tail provides the force to move the bacterium in a unidirectional manner through the host-cell cytoplasm. We have previously demonstrated that rough lipopolysaccharide (LPS) mutants of S. flexneri 2a are avirulent and cannot form plaques in tissue-culture monolayers. This inability to form plaques is associated with non-polar localization of IcsA and loss of host-cell membrane-protrusion formation ('fireworks'). To define the minimal LPS structure required for fireworks formation, we constructed a strain of S. flexneri (BS497) that contains a mutation in rfc, encoding the O side-chain polymerase, and a strain, BS520, that possesses a defective O side-chain ligase due to a mutation in rfaL. BS497 produces a LPS that consists of a core with one repeat unit of the O side-chain, while BS520 produces a LPS consisting of a complete core with no O side-chain. BS497 remained invasive but did not form fireworks or plaques in tissue-culture monolayers and was negative in the Serény test. BS520 was invasive, generated reduced numbers of short fireworks, and made tiny plaques, but it was negative in the Serény test. Analysis of BS497 with anti-lcsA antibody demonstrated that IcsA was distributed over the entire cell surface. The distribution of IcsA on the surface of BS520 was predominantly unipolar, with some trail-back of IcsA label along the sides of the bacterium. A similar pattern was seen when infected monolayers were stained for polymerized actin. These results suggest that both the presence and the length of the O side-chain are important in the proper localization or maintenance of IcsA at the pole which subsequently affects the ability to form actin tails and produce fireworks. This reduced ability to form actin tails and fireworks results in a decreased ability of Shigella to move into adjacent host cells. To determine if the sugar composition of the O side-chain is important in the ability to form fireworks, the rfb region of S. flexneri2a was replaced with the rfb region from Escherichia coll serotype O8 or O25. Both hybrids were invasive, formed plaques, and gave positive Serény reactions. These results suggest that, unlike LPS length, the sugar composition of the O side-chain is not a critical requirement for the proper localization of IcsA and efficient intercellular movement.     

Purification and characterization of SopA and SopB proteins essential for F plasmid partitioning

Mini-F plasmid has the trans-acting genes sopA and sopB and the cis-acting site sopC which are essential for accurate partitioning of plasmid DNA molecules into both daughter cells. In this study, we purified independently SopA and SopB proteins, analyzed the in vitro DNA-binding activity of these proteins by the gel retardation assay, and determined the precise binding sites of DNA by the footprinting method. SopA binds to four repeated sequences (CTTTGC) located in the promoter-operator region of the sopAB operon. The SopA binding activity is enhanced by the addition of SopB protein. SopB protein itself does not bind to this DNA region. These results suggest that the complex of SopA and SopB proteins autoregulate the expression of the sopA-sopB operon. On the other hand, SopB protein binds to the sopC region, in which 12 direct repeats of 43-base pairs nucleotides exist. SopB protein recognizes the inverted repeats of 7 base pairs in each direct repeats. SopA protein does not affect the SopB binding activity to the sopC DNA segment.     

Presence of multiple sites containing polar material in spherical Escherichia coli cells that lack MreB

In rod-shaped bacteria, certain proteins are specifically localized to the cell poles. The nature of the positional information that leads to the proper localization of these proteins is unclear. In a screen for factors required for the localization of the Shigella sp. actin assembly protein IcsA to the bacterial pole, a mutant carrying a transposon insertion in mreB displayed altered targeting of IcsA. The phenotype of cells containing a transposon insertion in mreB was indistinguishable from that of cells containing a nonpolar mutation in mreB or that of wild-type cells treated with the MreB inhibitor A22. In cells lacking MreB, a green fluorescent protein (GFP) fusion to a cytoplasmic derivative of IcsA localized to multiple sites. Secreted full-length native IcsA was present in multiple faint patches on the surfaces of these cells in a pattern similar to that seen for the cytoplasmic IcsA-GFP fusion. EpsM, the polar Vibrio cholerae inner membrane protein, also localized to multiple sites in mreB cells and colocalized with IcsA, indicating that localization to multiple sites is not unique to IcsA. Our results are consistent with the requirement, either direct or indirect, for MreB in the restriction of certain polar material to defined sites within the cell and, in the absence of MreB, with the formation of ectopic sites containing polar material.     

Activation of the CDC42 effector N-WASP by the Shigella flexneri IcsA protein promotes actin nucleation by Arp2/3 complex and bacterial actin-based motility.

To propel itself in infected cells, the pathogen Shigella flexneri subverts the Cdc42-controlled machinery responsible for actin assembly during filopodia formation. Using a combination of bacterial motility assays in platelet extracts with Escherichia coli expressing the Shigella IcsA protein and in vitro analysis of reconstituted systems from purified proteins, we show here that the bacterial protein IcsA binds N-WASP and activates it in a Cdc42-like fashion. Dramatic stimulation of actin assembly is linked to the formation of a ternary IcsA-N-WASP-Arp2/3 complex, which nucleates actin polymerization. The Arp2/3 complex is essential in initiation of actin assembly and Shigella movement, as previously observed for Listeria monocytogenes. Activation of N-WASP by IcsA unmasks two domains acting together in insertional actin polymerization. The isolated COOH-terminal domain of N-WASP containing a verprolin-homology region, a cofilin-homology sequence, and an acidic terminal segment (VCA) interacts with G-actin in a unique profilin-like functional fashion. Hence, when N-WASP is activated, its COOH-terminal domain feeds barbed end growth of filaments and lowers the critical concentration at the bacterial surface. On the other hand, the NH(2)-terminal domain of N-WASP interacts with F-actin, mediating the attachment of the actin tail to the bacterium surface. VASP is not involved in Shigella movement, and the function of profilin does not require its binding to proline-rich regions.     

Contribution of the Periplasmic Chaperone Skp to Efficient Presentation of the Autotransporter IcsA on the Surface of Shigella flexneri

IcsA is an outer membrane protein in the autotransporter family that is required for Shigella flexneri pathogenesis. Following its secretion through the Sec translocon, IcsA is incorporated into the outer membrane in a process that depends on YaeT, a component of an outer membrane β-barrel insertion machinery. We investigated the role of the periplasmic chaperone Skp in IcsA maturation. Skp is required for the presentation of the mature amino terminus (alpha-domain) of IcsA on the bacterial surface and contributes to cell-to-cell spread of S. flexneri in cell culture. A mutation in skp does not prevent the insertion of the β-barrel into the outer membrane, suggesting that the primary role of Skp is the folding of the IcsA alpha-domain. In addition, the requirement for skp can be partially bypassed by disrupting icsP, an ortholog of Escherichia coli ompT, which encodes the protease that processes IcsA between the mature amino terminus and the β-barrel outer membrane anchor. These findings are consistent with a model in which Skp plays a critical role in the chaperoning of the alpha-domain of IcsA during transit through the periplasm.Type V secretion apparatuses (also called autotransporters) consist of an extensive class of large, outer membrane proteins of gram-negative bacteria, typically virulence factors, found in all subdivisions of proteobacteria (28). Although originally designated as “autotransporters” because they were thought to mediate their own insertion into and translocation across the outer membrane, more recent evidence suggests that autotransporter secretion and insertion requires the aid of accessory factors (21, 29). Secretion involves the insertion of the carboxy-terminal β-barrel domain into the outer membrane and translocation of the mature passenger (alpha) domain across the outer membrane (Fig. ​(Fig.1).1). Whether these two events occur sequentially or simultaneously is unclear. Analysis of crystal structures indicates that the carboxy-terminal end of the passenger domain is present within the central pore of the β-barrel (4, 27). Several studies provide evidence that at least some autotransporters are partially folded in the periplasm (7, 20), and one of these studies provides strong evidence that the passenger domain may be partially or fully incorporated into the β-barrel prior to incorporation of the mature protein into the outer membrane (20).Open in a separate windowFIG. 1.Schematic of the autotransporter IcsA. (A) Linear diagram showing the signal peptide (SP), alpha-domain (IcsA_53-757), and carboxy-terminal β-barrel domain. (B) IcsA in the outer membrane. The carboxy-terminal β-barrel is inserted into the outer membrane, and the mature amino-terminal alpha-domain is exposed on the bacterial surface. N′, mature amino terminus; C, carboxyl terminus; OM, outer membrane; arrow, proposed site of cleavage between residues 757 and 758 by IcsP.Shigella flexneri is a gram-negative human pathogen which, upon passage through the lower digestive tract, gains entry into colonic epithelial cells. Once S. flexneri is intracellular, it spreads to adjacent cells by secreting IcsA, a surface-associated autotransporter that is required for the polymerization of host cell actin on the bacterial surface. Actin polymerization occurs at a single pole of the bacterium and is required for infection of adjacent cells and disease pathogenesis (5, 24, 33).IcsA is encoded on a large virulence plasmid. The full-length protein is approximately 120 kDa and has three assigned functional and structural domains (25): an atypical Sec secretion signal (IcsA_1-52), the alpha-domain (IcsA_53-757), which is exposed on the bacterial surface and contains sequences that are required for actin polymerization, and the beta-domain (IcsA_758-1102), which forms a β-barrel structure in the outer membrane (Fig. ​(Fig.1A)1A) (21, 25). In vivo, a fraction of IcsA molecules are proteolytically processed at the junction between the alpha- and beta-domains by the protease IcsP (SopA), a protein which is also encoded on the virulence plasmid (14, 34). IcsA_53-757 is found in the supernatant of liquid cultures, while mature full-length IcsA (IcsA_53-1102), IcsA_758-1102 (14, 34), and some IcsA_53-757 (this work) remain cell associated. IcsA, like other autotransporters, is secreted at the bacterial pole (22), the site at which actin tail assembly occurs. As it is for other β-barrel-containing outer membrane proteins, insertion of IcsA and other autotransporters into the outer membrane requires the outer membrane insertase YaeT (BamA, Omp85) (21).Skp, DegP, and SurA are periplasmic chaperones that, like YaeT, appear to function in the targeting and/or insertion of outer membrane proteins (35). Evidence based on synthetic phenotypes suggests that during outer membrane protein insertion Skp and DegP act in one pathway and that SurA acts in a distinct but parallel pathway (35).We investigated the role of the periplasmic chaperone Skp in the folding and secretion of IcsA in S. flexneri. We found that in the absence of skp, IcsA is inefficiently presented on the surface of S. flexneri, leading to a cellular spread defect. Surprisingly, the protein was still efficiently cleaved by the outer membrane protease IcsP, as wild-type levels of IcsA_53-757 were detected in the culture supernatants. We found that introduction of the icsP mutation into the skp strain background led to an increase in the levels of full-length IcsA presented on the bacterial cell surface of the skp mutant, and we present models that could explain our results.     

Actin-based bacterial motility: towards a definition of the minimal requirements

At the border line between microbiology and cell biology, the spectacular capacity o f some intracellular bacterial pathogens, including Listeria monocytogenes, Shigella flexneri and several Rickettsias, to use actin polymerization as a driving force for intracellular movement, cell-to-cell spreading and dissemination within the infected tissue is being increasingly studied. Now that it is possible to manipulate the bacterial surface proteins involved in this process - ActA o f L. monocytogenes and IcsA of S. flexneri - these bacterial systems are providing experimental models in which to investigate the role o f actin filament dynamics in cell motility.