Salmonella host cell invasion emerged by acquisition of a mosaic of separate genetic elements, including Salmonella pathogenicity island 1 (SPI1), SPI5, and sopE2

Salmonella spp. possess a conserved type III secretion system encoded within the pathogenicity island 1 (SPI1; centisome 63), which mediates translocation of effector proteins into the host cell cytosol to trigger responses such as bacterial internalization. Several translocated effector proteins are encoded in other regions of the Salmonella chromosome. It remains unclear how this complex chromosomal arrangement of genes for the type III apparatus and the effector proteins emerged and how the different effector proteins cooperate to mediate virulence. By Southern blotting, PCR, and phylogenetic analyses of highly diverse Salmonella spp., we show here that effector protein genes located in the core of SPI1 are present in all Salmonella lineages. Surprisingly, the same holds true for several effector protein genes located in distant regions of the Salmonella chromosome, namely, sopB (SPI5, centisome 20), sopD (centisome 64), and sopE2 (centisomes 40 to 42). Our data demonstrate that sopB, sopD, and sopE2, along with SPI1, were already present in the last common ancestor of all contemporary Salmonella spp. Analysis of Salmonella mutants revealed that host cell invasion is mediated by SopB, SopE2, and, in the case of Salmonella enterica serovar Typhimurium SL1344, by SopE: a sopB sopE sopE2-deficient triple mutant was incapable of inducing membrane ruffling and was >100-fold attenuated in host cell invasion. We conclude that host cell invasion emerged early during evolution by acquisition of a mosaic of genetic elements (SPI1 itself, SPI5 [sopB], and sopE2) and that the last common ancestor of all contemporary Salmonella spp. was probably already invasive.     

Salmonella effectors within a single pathogenicity island are differentially expressed and translocated by separate type III secretion systems

Pathogenicity islands (PAIs) are large DNA segments in the genomes of bacterial pathogens that encode virulence factors. Five PAIs have been identified in the Gram-negative bacterium Salmonella enterica. Two of these PAIs, Salmonella pathogenicity island (SPI)-1 and SPI-2, encode type III secretion systems (TTSS), which are essential virulence determinants. These 'molecular syringes' inject effectors directly into the host cell, whereupon they manipulate host cell functions. These effectors are either encoded with their respective TTSS or scattered elsewhere on the Salmonella chromosome. Importantly, SPI-1 and SPI-2 are expressed under distinct environmental conditions: SPI-1 is induced upon initial contact with the host cell, whereas SPI-2 is induced intracellularly. Here, we demonstrate that a single PAI, in this case SPI-5, can encode effectors that are induced by distinct regulatory cues and targeted to different TTSS. SPI-5 encodes the SPI-1 TTSS translocated effector, SigD/SopB. In contrast, we report that the adjacently encoded effector PipB is part of the SPI-2 regulon. PipB is translocated by the SPI-2 TTSS to the Salmonella-containing vacuole and Salmonella-induced filaments. We also show that regions of SPI-5 are not conserved in all Salmonella spp. Although sigD/sopB is present in all Salmonella spp., pipB is not found in Salmonella bongori, which also lacks a functional SPI-2 TTSS. Thus, we demonstrate a functional and regulatory cross-talk between three chromosomal PAIs, SPI-1, SPI-2 and SPI-5, which has significant implications for the evolution and role of PAIs in bacterial pathogenesis.     

Salmonella exploits host Rho GTPase signalling pathways through the phosphatase activity of SopB

Salmonella uses Type 3 secretion systems (T3SSs) to deliver virulence factors, called effectors, into host cells during infection. The T3SS effectors promote invasion into host cells and the generation of a replicative niche. SopB is a T3SS effector that plays an important role in Salmonella pathogenesis through its lipid phosphatase activity. Here, we show that SopB mediates the recruitment of Rho GTPases (RhoB, RhoD, RhoH, and RhoJ) to bacterial invasion sites. RhoJ contributes to Salmonella invasion, and RhoB and RhoH play an important role in Akt activation. R‐Ras1 also contributes to SopB‐dependent Akt activation by promoting the localised production of PI(3,4)P₂/PI(3,4,5)P₃. Our studies reveal new signalling factors involved in SopB‐dependent Salmonella infection.     

HilD, HilC and RtsA constitute a feed forward loop that controls expression of the SPI1 type three secretion system regulator hilA in Salmonella enterica serovar Typhimurium

Salmonella enterica serovar Typhimurium invades intestinal epithelial cells using a type three secretion system (TTSS) encoded on Salmonella Pathogenicity Island 1 (SPI1). The SPI1 TTSS injects effector proteins into the cytosol of host cells where they promote actin rearrangement and engulfment of the bacteria. We previously identified RtsA, an AraC-like protein similar to the known HilC and HilD regulatory proteins. Like HilC and HilD, RtsA activates expression of SPI1 genes by binding upstream of the master regulatory gene hilA to induce its expression. HilA activates the SPI1 TTSS structural genes. Here we present evidence that hilA expression, and hence the SPI1 TTSS, is controlled by a feedforward regulatory loop. We demonstrate that HilC, HilD and RtsA are each capable of independently inducing expression of the hilC, hilD and rtsA genes, and that each can independently activate hilA. Using competition assays in vivo, we show that each of the hilA regulators contribute to SPI1 induction in the intestine. Of the three, HilD has a predominant role, but apparently does not act alone either in vivo or in vitro to sufficiently activate SPI1. The two-component regulatory systems, SirA/BarA and OmpR/EnvZ, function through HilD, thus inducing hilC, rtsA and hilA. However, the two-component systems are not responsible for environmental regulation of SPI1. Rather, we show that 'SPI1 inducing conditions' cause independent activation of the rtsA, hilC and hilD genes in the absence of known regulators. Our model of SPI1 regulation provides a framework for future studies aimed at understanding this complicated regulatory network.     

The invasion-associated type III secretion system of Salmonella enterica serovar Typhimurium is necessary for intracellular proliferation and vacuole biogenesis in epithelial cells

Type III secretion systems (TTSS) are used by Gram-negative pathogens to translocate proteins into eukaryotic host cells. Salmonella enterica serovar Typhimurium (S. Typhimurium) has two of these specialized systems, which are encoded on separate Salmonella pathogenicity islands (SPI-1 and SPI-2) and translocate unique sets of effectors. The specific roles of these systems in Salmonella pathogenesis remain undefined, although SPI-1 is required for bacterial invasion of epithelial cells and SPI-2 for survival/replication in phagocytic cells. However, because SPI-1 TTSS mutants are invasion-incompetent, the role of this TTSS in post-invasion processes has not been investigated. In this study, we have used two distinct methods to internalize a non-invasive SPI-1 TTSS mutant (invA) into cultured epithelial cells: (i) co-internalization with wild-type S. Typhimurium (SPI-1-dependent) and (ii) complementation with the Yersinia pseudotuberculosis invasin (inv) gene (SPI-1-independent). In both cases, internalized invA mutants were unable to replicate intracellularly, indicating that SPI-1 effectors are essential for this process and cannot be complemented by wild-type bacteria in the same cell. Analysis of the biogenesis of SCVs showed that vacuoles containing mutant bacteria displayed abnormal maturation that was dependent on the mechanism of entry. Manipulation of Salmonella-containing vacuole (SCV) biogenesis by pharmacologically perturbing membrane trafficking in the host cell increased intracellular replication of wild-type but not mutant S. Typhimurium This demonstrates a previously unknown role for SPI-1 in vacuole biogenesis and intracellular survival in non-phagocytic cells.     

RtsA and RtsB coordinately regulate expression of the invasion and flagellar genes in Salmonella enterica serovar Typhimurium

Salmonella enterica serovar Typhimurium encounters numerous host environments and defense mechanisms during the infection process. The bacterium responds by tightly regulating the expression of virulence genes. We identified two regulatory proteins, termed RtsA and RtsB, which are encoded in an operon located on an island integrated at tRNA(PheU) in S. enterica serovar Typhimurium. RtsA belongs to the AraC/XylS family of regulators, and RtsB is a helix-turn-helix DNA binding protein. In a random screen, we identified five RtsA-regulated fusions, all belonging to the Salmonella pathogenicity island 1 (SPI1) regulon, which encodes a type III secretion system (TTSS) required for invasion of epithelial cells. We show that RtsA increases expression of the invasion genes by inducing hilA expression. RtsA also induces expression of hilD, hilC, and the invF operon. However, induction of hilA is independent of HilC and HilD and is mediated by direct binding of RtsA to the hilA promoter. The phenotype of an rtsA null mutation is similar to the phenotype of a hilC mutation, both of which decrease expression of SPI1 genes approximately twofold. We also show that RtsA can induce expression of a SPI1 TTSS effector, slrP, independent of any SPI1 regulatory protein. RtsB represses expression of the flagellar genes by binding to the flhDC promoter region. Repression of the positive activators flhDC decreases expression of the entire flagellar regulon. We propose that RtsA and RtsB coordinate induction of invasion and repression of motility in the small intestine.     

Hierarchical effector protein transport by the Salmonella Typhimurium SPI-1 type III secretion system

Background

Type III secretion systems (TTSS) are employed by numerous pathogenic and symbiotic bacteria to inject a cocktail of different “effector proteins” into host cells. These effectors subvert host cell signaling to establish symbiosis or disease.

Methodology/Principal Findings

We have studied the injection of SipA and SptP, two effector proteins of the invasion-associated Salmonella type III secretion system (TTSS-1). SipA and SptP trigger different host cell responses. SipA contributes to triggering actin rearrangements and invasion while SptP reverses the actin rearrangements after the invasion has been completed. Nevertheless, SipA and SptP were both pre-formed and stored in the bacterial cytosol before host cell encounter. By time lapse microscopy, we observed that SipA was injected earlier than SptP. Computer modeling revealed that two assumptions were sufficient to explain this injection hierarchy: a large number of SipA and SptP molecules compete for transport via a limiting number of TTSS; and the TTSS recognize SipA more efficiently than SptP.

Conclusions/Significance

This novel mechanism of hierarchical effector protein injection may serve to avoid functional interference between SipA and SptP. An injection hierarchy of this type may be of general importance, allowing bacteria to precisely time the host cell manipulation by type III effectors.     

SopD acts cooperatively with SopB during Salmonella enterica serovar Typhimurium invasion

The intracellular bacterial pathogen, Salmonella enterica serovar Typhimurium (S. typhimurium), causes disease in a variety of hosts. To invade and replicate in host cells, these bacteria subvert host molecular machinery using bacterial proteins, called effectors, which they translocate into host cells using specialized protein delivery systems. One of these effectors, SopD, contributes to gastroenteritis, systemic virulence and persistence of S. typhimurium in animal models of infection. Recently, SopD has been implicated in invasion of polarized epithelial cells and here we investigate the features of SopD-mediated invasion. We show that SopD plays a role in membrane fission and macropinosome formation during S. typhimurium invasion, events previously shown to be mediated by the SopB effector. We further demonstrate that SopD acts cooperatively with SopB to promote these events during invasion. Using live cell imaging we show that a SopD-GFP fusion does not localize to HeLa cell cytosol as previously described, but instead is membrane associated. Upon S. typhimurium infection of these cells, SopD-GFP is recruited to the invasion site, and this recruitment required the phosphatase activity of SopB. Our findings demonstrate a role for SopD in manipulation of host-cell membrane during S. typhimurium invasion and reveal the nature of its cooperative action with SopB.     

Autophagy controls Salmonella infection in response to damage to the Salmonella-containing vacuole

Salmonella enterica serovar Typhimurium (S. Typhimurium) is a facultative intracellular pathogen that causes disease in a variety of hosts. S. Typhimurium actively invade host cells and typically reside within a membrane-bound compartment called the Salmonella-containing vacuole (SCV). The bacteria modify the fate of the SCV using two independent type III secretion systems (TTSS). TTSS are known to damage eukaryotic cell membranes and S. Typhimurium has been suggested to damage the SCV using its Salmonella pathogenicity island (SPI)-1 encoded TTSS. Here we show that this damage gives rise to an intracellular bacterial population targeted by the autophagy system during in vitro infection. Approximately 20% of intracellular S. Typhimurium colocalized with the autophagy marker GFP-LC3 at 1 h postinfection. Autophagy of S. Typhimurium was dependent upon the SPI-1 TTSS and bacterial protein synthesis. Bacteria targeted by the autophagy system were often associated with ubiquitinated proteins, indicating their exposure to the cytosol. Surprisingly, these bacteria also colocalized with SCV markers. Autophagy-deficient (atg5-/-) cells were more permissive for intracellular growth by S. Typhimurium than normal cells, allowing increased bacterial growth in the cytosol. We propose a model in which the host autophagy system targets bacteria in SCVs damaged by the SPI-1 TTSS. This serves to retain intracellular S. Typhimurium within vacuoles early after infection to protect the cytosol from bacterial colonization. Our findings support a role for autophagy in innate immunity and demonstrate that Salmonella infection is a powerful model to study the autophagy process.     

Identification of cognate host targets and specific ubiquitylation sites on the Salmonella SPI-1 effector SopB/SigD

Salmonella enterica is a bacterial pathogen responsible for enteritis and typhoid fever. Virulence is linked to two Salmonella pathogenicity islands (SPI-1 and SPI-2) on the bacterial chromosome, each of which encodes a type III secretion system. While both the SPI-1 and SPI-2 systems secrete an array of effectors into the host, relatively few host proteins have been identified as targets for their effects. Here we use stable isotope labeling with amino acids in cell culture (SILAC) and quantitative mass spectrometry-based proteomics to identify the host targets of the SPI-1 effector, SopB/SigD. The only host protein found to bind immunoprecipitated SopB was the small G-protein Cdc42. The interaction was confirmed by reciprocal immunoprecipitation, and Cdc42 also bound glutathione S-transferase-fused SopB and SopB delivered through infection by the bacteria, confirming the interaction by an orthogonal method and in a more physiological context. The region of SopB responsible for the interaction was mapped to residues 117–168, and SopB is ubiquitylated at both K19 and K541, likely as monoubiquitylation. SopB colocalizes with activated Cdc42 near the plasmalemma, but we found no evidence that SopB alone can alter Cdc42 activity. This approach is also widely applicable to identify binding partners to other bacterial effectors.     

Two newly identified SipA domains (F1, F2) steer effector protein localization and contribute to Salmonella host cell manipulation

Salmonella Typhimurium causes bacterial enterocolitis. The type III secretion system (TTSS)-1 is a key virulence determinant of S. Typhimurium mediating host cell invasion and acute enterocolitis. The TTSS-1 effector protein SipA is transported into host cells, accumulates in characteristic foci at the bacteria-host cell interface, manipulates signalling and affects virulence. Two functional domains of SipA have previously been characterized: The N-terminal SipA region (amino acids 1-105) mediates TTSS-1 transport and the C-terminal SipA 'actin-binding' domain (ABD; amino acids 446-685) manipulates F-actin assembly. Little is known about the central region of SipA. In a deletion analysis we found that the central SipA region harbours two distinct functional domains, F1 and F2. They are involved in SipA focus formation and host manipulation. The F1 domain (amino acids 170-271) drives SipA focus formation and domain F2 (amino acids 280-394) enhances this process by mediating SipA-SipA interactions. SipA variants lacking the F1-, the F2- or the actin binding domain were attenuated in virulence assays, namely host cell invasion and/or virulence in a mouse model for enterocolitis. Our results show that the newly identified SipA domains have distinct functions. Nevertheless, cooperation between the SipA domains F1, F2 and ABD is required to promote Salmonella virulence.     

The Salmonella enterica giant adhesin SiiE binds to polarized epithelial cells in a lectin‐like manner

The invasion of polarized epithelial cells by Salmonella enterica requires the cooperative activity of the Salmonella pathogenicity island (SPI) 1‐encoded type III secretion system (T3SS) and the SPI4‐encoded giant non‐fimbrial adhesin SiiE. SiiE is a highly repetitive protein composed of 53 bacterial Ig (BIg) domains and mediates binding to the apical side of polarized epithelial cells. We analysed the binding properties of SiiE and observed lectin‐like activity. SiiE‐dependent cell invasion can be ablated by chemical or enzymatic deglycosylation. Lectin blockade experiments revealed that SiiE binding is specific for glycostructures with terminal N‐acetyl‐glucosamine (GlcNAc) and/or α 2,3‐linked sialic acid. In line with these data, we found that SiiE‐expressing Salmonella bind to the GlcNAc polymer chitin. Various recombinant SiiE fragments were analysed for host cell binding. We observed that C‐terminal portions of SiiE bind to the apical side of polarized cells and the intensity of binding increases with the number of BIg domains present in the recombinant proteins. Based on these results, we propose that SiiE mediates multiple interactions per molecule with glycoproteins and/or glycosylated phospholipids present in the apical membrane of polarized epithelial cells. Thisintimate binding enables the subsequent function of the SPI1‐T3SS, resulting in host cell invasion.     

The chaperone binding domain of SopE inhibits transport via flagellar and SPI-1 TTSS in the absence of InvB

Type III secretion systems (TTSS) are used by many Gram-negative pathogens for transporting effector proteins into eukaryotic host cells. Two modes of type III effector protein transport can be distinguished: transport into the surrounding medium (secretion) and cell-contact induced injection of effector proteins directly into the host cell cytosol (translocation). Two domains within the N-terminal regions of effector proteins determine the mode of transport. The amino terminal approximately 20 amino acids (N-terminal secretion signal, NSS) mediate secretion. In contrast, translocation generally requires the NSS, the adjacent approximately 100 amino acids (chaperone binding domain, CBD) and binding of the cognate chaperone to this CBD. TTSS are phylogenetically related to flagellar systems. Because both systems are expressed in Salmonella Typhimurium, correct effector protein transport involves at least two decisions: transport via the Salmonella pathogenicity island 1 (SPI-1) but not the flagellar TTSS (= specificity) and translocation into the host cell instead of secretion into the surrounding media (= transport mode). The mechanisms guiding these decisions are poorly understood. We have studied the S. Typhimurium effector protein SopE, which is specifically transported via the SPI-1 TTSS. Secretion and translocation strictly require the cognate chaperone InvB. Alanine replacement of amino acids 30-42 (and to some extent 44-54) abolished tight InvB binding, abolished translocation into the host cell and led to secretion of SopE via both, the flagellar and the SPI-1 TTSS. In clear contrast to wild-type SopE, secretion of SopE(Ala30-42) and SopE(Ala44-54) via the SPI-1 and the flagellar export system did not require InvB. These data reveal a novel function of the CBD: the CBD inhibits secretion of wild-type SopE via the flagellar and the SPI-1 TTSS in the absence of the chaperone InvB. Our data provide new insights into mechanisms ensuring specific effector protein transport by TTSS.     

Activation of a RhoA/myosin II-dependent but Arp2/3 complex-independent pathway facilitates Salmonella invasion

Salmonella stimulates host cell invasion using virulence effectors translocated by the pathogen's type-three secretion system (T3SS). These factors manipulate host signaling pathways, primarily driven by Rho family GTPases, which culminates in Arp2/3 complex-dependent activation of host actin nucleation to mediate the uptake of Salmonella into host cells. However, recent data argue for the existence of additional mechanisms that cooperate in T3SS-dependent Salmonella invasion. We identify a myosin II-mediated mechanism, operating independent of but complementary to the Arp2/3-dependent pathway, as contributing to Salmonella invasion into nonphagocytic cells. We also establish that the T3SS effector SopB constitutes an important regulator of this Rho/Rho kinase and myosin II-dependent invasion pathway. Thus, Salmonella enters nonphagocytic cells by manipulating the two core machineries of actin-based motility in the host: Arp2/3 complex-driven actin polymerization and actomyosin-mediated contractility.     

SopB‐ and SifA‐dependent shaping of the Salmonella‐containing vacuole proteome in the social amoeba Dictyostelium discoideum

The ability of Salmonella to survive and replicate within mammalian host cells involves the generation of a membranous compartment known as the Salmonella‐containing vacuole (SCV). Salmonella employs a number of effector proteins that are injected into host cells for SCV formation using its type‐3 secretion systems encoded in SPI‐1 and SPI‐2 (T3SS‐1 and T3SS‐2, respectively). Recently, we reported that S. Typhimurium requires T3SS‐1 and T3SS‐2 to survive in the model amoeba Dictyostelium discoideum. Despite these findings, the involved effector proteins have not been identified yet. Therefore, we evaluated the role of two major S. Typhimurium effectors SopB and SifA during D. discoideum intracellular niche formation. First, we established that S. Typhimurium resides in a vacuolar compartment within D. discoideum. Next, we isolated SCVs from amoebae infected with wild type or the ΔsopB and ΔsifA mutant strains of S. Typhimurium, and we characterised the composition of this compartment by quantitative proteomics. This comparative analysis suggests that S. Typhimurium requires SopB and SifA to modify the SCV proteome in order to generate a suitable intracellular niche in D. discoideum. Accordingly, we observed that SopB and SifA are needed for intracellular survival of S. Typhimurium in this organism. Thus, our results provide insight into the mechanisms employed by Salmonella to survive intracellularly in phagocytic amoebae.