ExoU is a potent intracellular phospholipase

The combination of a large genome encoding metabolic versatility and conserved secreted virulence determinants makes Pseudomonas aeruginosa a model pathogen that can be used to study host-parasite interactions in many eukaryotic hosts. One of the virulence regulons that likely plays a role in the ability of P. aeruginosa to avoid innate immune clearance in mammals is a type III secretion system (TTSS). Upon cellular contact, the P. aeruginosa TTSS is capable of delivering a combination of at least four different effector proteins, exoenzyme S (ExoS), ExoT, ExoU, and ExoY. Two of the four translocated proteins, ExoS and ExoU, are cytotoxic to cells during infection and transfection. The mechanism of cytotoxicity of ExoS is unclear. ExoU, however, has recently been characterized as a member of the phospholipase A family of enzymes, possessing at least phospholipase A2 activity. Similar to ExoS, ExoT and ExoY, ExoU requires either a eukaryotic-specific modification or cofactor for its activity in vitro. The biologic effects of minimal expression of ExoU in yeast can be visualized by membrane damage to different organelles and fragmentation of the vacuole. In mammalian cells, the direct injection of ExoU causes irreversible damage to cellular membranes and rapid necrotic death. ExoU likely represents a unique enzyme and is the first identified phopholipase virulence factor that is translocated into the cytosol by TTSS.     

Identification of type III secreted products of the Pseudomonas aeruginosa exoenzyme S regulon.

Extracellular protein profiles from wild-type and regulatory or secretory isogenic mutants of the Pseudomonas aeruginosa exoenzyme S regulon were compared to identify proteins coordinately secreted with ExoS. Data from amino-terminal sequence analysis of purified extracellular proteins were combined with data from nucleotide sequence analysis of loci linked to exoenzyme S production. We report the identification of P. aeruginosa homologs to proteins of Yersinia spp. that function as regulators of the low calcium response, regulators of secretion, and mediators of the type III translocation mechanism.     

Delineation of exoenzyme S residues that mediate the interaction with 14-3-3 and its biological activity

14-3-3 proteins belong to a family of conserved molecules expressed in all eukaryotic cells, which play an important role in a multitude of signaling pathways. 14-3-3 proteins bind to phosphoserine/phosphothreonine motifs in a sequence-specific manner. More than 200 14-3-3 binding partners have been found that are involved in cell cycle regulation, apoptosis, stress responses, cell metabolism and malignant transformation. A phosphorylation-independent interaction has been reported to occur between 14-3-3 and a C-terminal domain within exoenzyme S (ExoS), a bacterial ADP-ribosyltransferase toxin from Pseudomonas aeruginosa. In this study, we have investigated the effect of amino acid mutations in this C-terminal domain of ExoS on ADP-ribosyltransferase activity and the 14-3-3 interaction. Our results suggest that leucine-428 of ExoS is the most critical residue for ExoS enzymatic activity, as cytotoxicity analysis reveals that substitution of this leucine significantly weakens the ability of ExoS to mediate cell death. Leucine-428 is also required for the ability of ExoS to modify the eukaryotic endogenous target Ras. Finally, single amino acid substitutions of positions 426-428 reduce the interaction potential of 14-3-3 with ExoS in vitro.     

Exoenzyme S of Pseudomonas aeruginosa is not able to induce apoptosis when cells express activated proteins, such as Ras or protein kinase B/Akt

Intracellular targeting of the Pseudomonas aeruginosa toxins, such as exoenzyme S (ExoS), cause cell death, as well as morphological and physiological changes in various tissue culture cells and animal models. In this report we have investigated the mechanism behind ExoS-mediated cell death. In order to address this issue, we have used cell lines expressing activated forms of various components of the Ras signalling pathway in order to evaluate the importance of the Ras pathway for viability and survival upon ExoS infection. Here we show that activated Ras is able to protect cells against cell death, regardless of whether it has been ADP-ribosylated by ExoS. Further, an activated form of protein kinase B (PKB)/Akt also leads to decreased level of cell death in response to ExoS infection, indicating that an important ExoS survival target is located upstream of Raf-1 and PKB/Akt. Moreover, we show that ExoS infection inhibits phosphorylation of FOXO3a, and induces caspase-3 activity, which are hallmarks for induction of cell death. In conclusion, we suggest that Ras proteins are an important cellular target for the P. aeruginosa toxin ExoS, which induces cell death during pathogenesis as a means of defending the bacterium against eukaryotic phagocytosis.     

The amino-terminal domain of Pseudomonas aeruginosa ExoS disrupts actin filaments via small-molecular-weight GTP-binding proteins

Pseudomonas aeruginosa delivers exoenzyme S (ExoS) into the intracellular compartment of eukaryotic cells via a type III secretion pathway. Intracellular delivery of ExoS is cytotoxic for eukaryotic cells and has been shown to ADP-ribosylate Ras in vivo and uncouple a Ras-mediated signal transduction pathway. Functional mapping has localized the FAS-dependent ADP-ribosyltransferase domain to the carboxyl-terminus of ExoS. A transient transfection system was used to examine cellular responses to the amino-terminal 234 amino acids of ExoS (DeltaC234). Intracellular expression of DeltaC234 elicited the rounding of Chinese hamster ovary (CHO) cells and the disruption of actin filaments in a dose-dependent manner. Expression of DeltaC234 did not inhibit the expression of two independent reporter proteins, GFP and luciferase, or induce trypan blue uptake, which indicated that expression of DeltaC234 was not cytotoxic to CHO cells. Carboxyl-terminal deletion proteins of DeltaC234 were less efficient in the elicitation of CHO cell rounding than DeltaC234. Cytoskeleton rearrangement elicited by DeltaC234 was blocked and reversed by the addition of cytotoxic necrotizing factor 1 (CNF-1). CNF-1 catalyses the deamidation of Gln-63 of members of the Rho subfamily of small-molecular-weight GTP-binding proteins, resulting in protein activation. This implies a role for small-molecular-weight GTP-binding proteins in the disruption of actin by DeltaC234. Together, these data identify ExoS as a cytotoxin that possesses two functional domains. Intracellular expression of the amino-terminal domain of ExoS elicits the disruption of actin, while expression of the carboxyl-terminal domain of ExoS possesses FAS-dependent ADP-ribosyltransferase activity and is cytotoxic to eukaryotic cells.     

Genetic relationship between the 53- and 49-kilodalton forms of exoenzyme S from Pseudomonas aeruginosa.

Exoenzyme S is an ADP-ribosylating extracellular protein of Pseudomonas aeruginosa that is produced as two immunologically related forms, a 49-kDa enzymatically active form and a 53-kDa inactive form. The postulated relationship between the two proteins involves a carboxy-terminal proteolytic cleavage of the 53-kDa precursor to produce an enzymatically active 49-kDa protein. To determine the genetic relationship between the two forms of exoenzyme S, exoS (encoding the 49-kDa form) was used as a probe in Southern blot analyses of P. aeruginosa chromosomal digests. Cross-hybridizing bands were detected in chromosomal digests of a strain of P. aeruginosa in which exoS had been deleted by allelic exchange. A chromosomal bank was prepared from the exoS deletion strain, 388deltaexoS::TC, and screened with a probe internal to exoS. Thirteen clones that cross-hybridized with the exoS probe were identified. One representative clone contained the open reading frame exoT; this open reading frame encoded a protein of 457 amino acids which showed 75% amino acid identity to ExoS. The exoT open reading frame, cloned into a T7 expression system, produced a 53-kDa protein in Escherichia coli, termed Exo53, which reacted to antisera against exoenzyme S. A histidine-tagged derivative of recombinant Exo53 possessed approximately 0.2% of the ADP-ribosyltransferase activity of recombinant ExoS. Inactivation of exoT in an allelic-replacement strain resulted in an Exo53-deficient phenotype without modifying the expression of ExoS. These studies prove that the 53- and 49-kDa forms of exoenzyme S are encoded by separate genes. In addition, this is the first report of the factor-activating-exoenzyme-S-dependent ADP-ribosyltransferase activity of the 53-kDa form of exoenzyme S.     

Intracellular localization modulates targeting of ExoS,a type III cytotoxin,to eukaryotic signalling proteins

ExoS is a bifunctional type III cytotoxin produced by Pseudomonas aeruginosa. Residues 96-232 comprise the Rho GTPase activating protein (Rho GAP) domain, whereas residues 233-453 comprise the 14-3-3-dependent ADP-ribosyltransferase domain. Earlier studies showed that the N-terminus targeted ExoS to intracellular membranes within eukaryotic cells. This N-terminal targeting region is now characterized for cellular and biological contributions to intoxications by ExoS. An ExoS(1-107)-green fluorescent protein (GFP) fusion protein co-localized with alpha-mannosidase, which indicated that the fusion protein localized near the Golgi. Residues 51-72 of ExoS (termed the membrane localization domain, MLD) were necessary and sufficient for membrane localization within eukaryotic cells. Deletion of the MLD did not inhibit type III secretion of ExoS from P. aeruginosa or type III delivery of ExoS into eukaryotic cells. Type III-delivered ExoS(DeltaMLD) localized within the cytosol of eukaryotic cells, whereas type III-delivered ExoS was membrane associated. Although type III-delivered ExoS(DeltaMLD) stimulated the reorganization of the actin cytoskeleton (a Rho GAP activity), it did not ADP-ribosylate Ras. Type III-delivered ExoS(DeltaMLD) and ExoS showed similar capacities for eliciting a cytotoxic response in CHO cells, which uncoupled the ADP-ribosylation of Ras from the cytotoxicity elicited by ExoS.     

The type III toxins of Pseudomonas aeruginosa disrupt epithelial barrier function

The type III secreted toxins of Pseudomonas aeruginosa are important virulence factors associated with clinically important infection. However, their effects on bacterial invasion across mucosal surfaces have not been well characterized. One of the most commonly expressed toxins, ExoS, has two domains that are predicted to affect cytoskeletal integrity, including a GTPase-activating protein (GAP) domain, which targets Rho, a major regulator of actin polymerization; and an ADP-ribosylating domain that affects the ERM proteins, which link the plasma membrane to the actin cytoskeleton. The activities of these toxins, and ExoS specifically, on the permeability properties of polarized airway epithelial cells with intact tight junctions were examined. Strains expressing type III toxins altered the distribution of the tight junction proteins ZO-1 and occludin and were able to transmigrate across polarized airway epithelial monolayers, in contrast to DeltaSTY mutants. These effects on epithelial permeability were associated with the ADP-ribosylating domain of ExoS, as bacteria expressing plasmids lacking expression of the ExoS GAP activity nonetheless increased the permeation of fluorescent dextrans, as well as bacteria, across polarized airway epithelial cells. Treatment of epithelial cells with cytochalasin D depolymerized actin filaments and increased permeation across the monolayers but did not eliminate the differential effects of wild-type and toxin-negative mutants on the epithelial cells, suggesting that additional epithelial targets are involved. Confocal imaging studies demonstrated that ZO-1, occludin, and ezrin undergo substantial redistribution in human airway cells intoxicated by ExoS, -T, and -Y. These studies support the hypothesis that type III toxins enhance P. aeruginosa's invasive capabilities by interacting with multiple eukaryotic cytoskeletal components.     

Intracellular targeting of exoenzyme S of Pseudomonas aeruginosa via type III-dependent translocation induces phagocytosis resistance, cytotoxicity and disruption of actin microfilaments

Exoenzyme S (ExoS) is an ADP-ribosyltransferase secreted by the opportunistic pathogen Pseudomonas aeruginosa . The amino-terminal half of ExoS exhibits homology to the YopE cytotoxin of pathogenic Yersinia . Recently, YopE was found to be translocated into the host cell by a bacteria–cell contact-dependent mechanism involving the ysc -encoded type III secretion system. By using an approach in which exoS was expressed in different strains of Yersinia , including secretion and translocation mutants, we could demonstrate that ExoS was secreted and translocated into HeLa cells by a similar mechanism to that described previously for YopE. Similarly to YopE, the presence of ExoS in the host cell elicited a cytotoxic response, correlating with disruption of the actin microfilament structure. A similar cytotoxic response was also induced by a mutated form of ExoS with a more than 2000-fold reduced ADP-ribosyltransferase activity. However, the enzymatically active ExoS elicited a more definite rounding up of the HeLa cells, which also correlated with decreased viability of the cells after prolonged infection compared with cells infected with strains expressing mutated ExoS or YopE. This suggests that ExoS can act through two different mechanisms on the host cell. The expression of ExoS by Yersinia also mediated an anti-phagocytic effect on macrophages. In addition, we present evidence that extracellularly located P. aeruginosa is able to target ExoS into eukaryotic cells. Taken together, our data suggest that P. aeruginosa , by analogy with Yersinia , targets virulence proteins into the eukaryotic cytosol via a type III secretion-dependent mechanism as part of an anti-phagocytic strategy.     

Exoenzyme S of Pseudomonas aeruginosa is secreted by a type III pathway

Exoenzyme S is an extracellular ADP-ribosyltransferase of Pseudomonas aeruginosa . Transposon mutagenesis of P. aeruginosa 388 was used to identify genes required for exoenzyme S production. Five Tn 5  Tc insertion mutants were isolated which exhibited an exoenzyme S-deficient phenotype (388::Tn 5  Tc 469, 550, 3453, 4885, and 5590). Mapping experiments demonstrated that 388::Tn 5  Tc 3453, 4885, and 5590 possessed insertions within a 5.0 kb Eco RI fragment that is not contiguous with the exoenzyme S trans -regulatory operon. 388::Tn 5  Tc 469 and 550 mapped to a region downstream of the trans -regulatory operon which has been previously shown to contain a promoter region that is co-ordinately regulated with exoenzyme S synthesis. Nucleotide sequence analysis of a 7.2 kb region flanking the 388::Tn 5  Tc 469 and 550 insertions, identified 12 contiguous open reading frames (ORFs). Database searches indicated that the first ORF, ExsD, is unique. The other 11 ORFs demonstrated high homology to the YscB–L proteins of the yersiniae Yop type III export apparatus. RNase-protection analysis of wild-type and mutant strains indicated that exsD and pscB–L form an operon. To determine whether ExoS was exported by a type III mechanism, derivatives consisting of internal deletions or lacking amino- or carboxy-terminal residues were expressed in P. aeruginosa . Deletion analyses indicated that the amino-terminal nine residues are required for ExoS export. Combined data from mutagenesis, regulatory, expression, and sequence analyses provide strong evidence that P. aeruginosa possesses a type III secretion apparatus which is required for the export of exoenzyme S and potentially other co-ordinately regulated proteins.     

The N-terminal domain of Pseudomonas aeruginosa exoenzyme S is a GTPase-activating protein for Rho GTPases

Pseudomonas aeruginosa exoenzyme S (ExoS) is a bifunctional cytotoxin. The ADP-ribosyltransferase domain is located within the C terminus part of ExoS. Recent studies showed that the N terminus part of ExoS (amino acid residues 1-234, ExoS(1-234)), which does not possess ADP-ribosyltransferase activity, stimulates cell rounding when transfected or microinjected into eukaryotic cells. Here we studied the effects of ExoS(1-234) on nucleotide binding and hydrolysis by Rho GTPases. ExoS(1-234) (100-500 nM) did not influence nucleotide exchange of Rho, Rac, and Cdc42 but increased GTP hydrolysis. A similar increase in GTPase activity was stimulated by full-length ExoS. Half-maximal stimulation of GTP hydrolysis by Rho, Rac, and Cdc42 was observed at 10-11 nM ExoS(1-234), respectively. We identified arginine 146 of ExoS to be essential for the stimulation of GTPase activity of Rho proteins. These data identify ExoS as a GTPase-activating protein for Rho GTPases.     

Expression of FAS-independent ADP-ribosyltransferase activity by a catalytic deletion peptide of Pseudomonas aeruginosa exoenzyme S

Earlier studies reported that Pseudomonas aeruginosa exoenzyme S (ExoS) possessed an absolute requirement for the eukaryotic protein factor activating exoenzyme S (FAS) for expressing ADP-ribosyltransferase activity. During the characterization of a serum-derived FAS-like activity, we observed the ability of a catalytic deletion peptide of ExoS (DeltaN222) to ADP-ribosylate target proteins in the absence of FAS. Characterization of the activation of DeltaN222 by FAS provided an opportunity to gain insight into the mechanism of ExoS activation by FAS. Under standard enzyme assay conditions, the initial rate of FAS-independent ADP-ribosyltransferase activity of DeltaN222 was not linear with time and rapidly approached zero. Dilution into high-ionic strength buffers stabilized DeltaN222 so it could express FAS-independent ADP-ribosyltransferase activity at a linear rate. This stabilization was a general salt effect, since dilution into a 1.0 M solution of either NaCH3COOH, NaCl, or KCl stabilized the ADP-ribosyltransferase activity of DeltaN222. Kinetic analysis in a high-ionic strength buffer showed that FAS enhanced the catalytic activity of DeltaN222 by increasing the affinity for NAD and stimulating the turnover rate. Velocity experiments indicated that the stabilization of DeltaN222 by high salt was not functionally identical to stabilization by FAS. Together, these data implicate a dual role for FAS in the allosteric activation of ExoS, involving both substrate binding and catalysis.     

Pseudomonas aeruginosa exoenzyme S requires a eukaryotic protein for ADP-ribosyltransferase activity

Pseudomonas aeruginosa exoenzyme S ADP-ribosylates several GTP-binding proteins of apparent Mr = 23,000-25,000. Exoenzyme S absolutely requires a soluble eukaryotic protein, which we have named FAS (Factor Activating exoenzyme S), in order to ADP-ribosylate all substrates. The rate of ADP-ribosylation of all exoenzyme S substrates increases linearly with time and with the FAS concentration. FAS is wide-spread in eukaryotes but appears to be absent from prokaryotes. We have estimated the molecular mass of the protein to be approximately 29,000 daltons and its pI to be 4.3-4.5. Several bacterial toxins share this sort of requirement for the presence of a eukaryotic protein for enzymic activity. In particular, FAS resembles ADP-ribosylation factor, a 21,000-dalton GTP-binding protein which performs an analogous function for cholera toxin. However, we can find no evidence that FAS binds GTP. In the presence of FAS, exoenzyme S ADP-ribosylates several proteins in lysates of P. aeruginosa. The requirement for a eukaryotic protein for enzymic activity, which is common to several bacterial toxins, may be a device to identify the eukaryotic environment and to ensure that the enzymes cannot function within and harm the toxin-producing bacteria.     

ADP-ribosylation and functional effects of Pseudomonas exoenzyme S on cellular RalA

Exoenzyme S (ExoS) is a bifunctional virulence factor directly translocated into eukaryotic cells by the type III secretory process of Pseudomonas aeruginosa. Bacterial translocation of ExoS into epithelial cells is associated with diverse effects on cell function, including inhibition of growth, alterations in cell morphology, and effects on adherence processes. Preferred substrates of the ADP-ribosyltransferase (ADPRT) portion of ExoS include low molecular weight G-proteins (LMWG-proteins) in the Ras family. In examining the ADP-ribosylation and functional effects of ExoS on RalA, ExoS was found to ADP-ribosylate endogenous RalA and recombinant RalADeltaCAAX at multiple sites, with Arg52 identified as the preferred site of ADP-ribosylation. The binding of RalA to the Ral binding domain (RBD) of its downstream effector, RalBP1, was inhibited by bacterially translocated ExoS, indicating an effect of ExoS on cellular RalA function. In vitro analyses confirmed that ADP-ribosylation of RalA directly interfered with its ability to bind to the RBD of RalBP1. The studies support the fact that RalA is a cellular substrate of bacterially translocated ExoS and that ADP-ribosylation by ExoS affects RalA interaction with its downstream effector, RalBP1.     

Different domains of Pseudomonas aeruginosa exoenzyme S activate distinct TLRs

Some bacterial products possess multiple immunomodulatory effects and thereby complex mechanisms of action. Exogenous administration of an important Pseudomonas aeruginosa virulence factor, exoenzyme S (ExoS) induces potent monocyte activation leading to the production of numerous proinflammatory cytokines and chemokines. However, ExoS is also injected directly into target cells, inducing cell death through its multiple effects on signaling pathways. This study addresses the mechanisms used by ExoS to induce monocyte activation. Exogenous administration resulted in specific internalization of ExoS via an actin-dependent mechanism. However, ExoS-mediated cellular activation was not inhibited if internalization was blocked, suggesting an alternate mechanism of activation. ExoS bound a saturable and specific receptor on the surface of monocytic cells. ExoS, LPS, and peptidoglycan were all able to induce tolerance and cross-tolerance to each other suggesting the involvement of a TLR in ExoS-recognition. ExoS activated monocytic cells via a myeloid differentiation Ag-88 pathway, using both TLR2 and the TLR4/MD-2/CD14 complex for cellular activation. Interestingly, the TLR2 activity was localized to the C-terminal domain of ExoS while the TLR4 activity was localized to the N-terminal domain. This study provides the first example of how different domains of the same molecule activate two TLRs, and also highlights the possible overlapping pathophysiological processes possessed by microbial toxins.     

Phosphorylation-independent interaction between 14-3-3 and exoenzyme S: from structure to pathogenesis

14-3-3 proteins are phosphoserine/phosphothreonine-recognizing adapter proteins that regulate the activity of a vast array of targets. There are also examples of 14-3-3 proteins binding their targets via unphosphorylated motifs. Here we present a structural and biological investigation of the phosphorylation-independent interaction between 14-3-3 and exoenzyme S (ExoS), an ADP-ribosyltransferase toxin of Pseudomonas aeruginosa. ExoS binds to 14-3-3 in a novel binding mode mostly relying on hydrophobic contacts. The 1.5 A crystal structure is supported by cytotoxicity analysis, which reveals that substitution of the corresponding hydrophobic residues significantly weakens the ability of ExoS to modify the endogenous targets RAS/RAP1 and to induce cell death. Furthermore, mutation of key residues within the ExoS binding site for 14-3-3 impairs virulence in a mouse pneumonia model. In conclusion, we show that ExoS binds 14-3-3 in a novel reversed orientation that is primarily dependent on hydrophobic residues. This interaction is phosphorylation independent and is required for the function of ExoS.     

Multiple Domains Are Required for the Toxic Activity of Pseudomonas aeruginosa ExoU

Expression of ExoU by Pseudomonas aeruginosa is correlated with acute cytotoxicity in a number of epithelial and macrophage cell lines. In vivo, ExoU is responsible for epithelial injury. The absence of a known motif or significant homology with other proteins suggests that ExoU may possess a new mechanism of toxicity. To study the intracellular effects of ExoU, we developed a transient-transfection system in Chinese hamster ovary cells. Transfection with full-length but not truncated forms of ExoU inhibited reporter gene expression. Inhibition of reporter activity after cotransfection with ExoU-encoding constructs was correlated with cellular permeability and death. The toxicity of truncated versions of ExoU could be restored by coexpression of the remainder of the molecule from separate plasmids in trans. This strategy was used to map N- and C-terminal regions of ExoU that are necessary but not sufficient for toxicity. Disruption of a middle region of the protein reduces toxicity. This portion of the molecule is postulated to allow the N- and C-terminal regions to functionally complement one another. In contrast to ExoS and ExoT, native and recombinant ExoU molecules do not oligomerize or form aggregates. The complex domain structure of ExoU suggests that, like other P. aeruginosa-encoded type III effectors (ExoS and ExoT), ExoU toxicity may result from a molecule that possesses more than one activity.     

Molecular heterogeneity of a type III cytotoxin, Pseudomonas aeruginosa exoenzyme S

Pseudomonas aeruginosa ExoS is a bifunctional type III cytotoxin. The N-terminus (residues 1-232) is a Rho GTPase activating protein (GAP) domain, while the C-terminus (residues 233-453) is a FAS-dependent ADP-ribosyltransferase domain that targets Ras and Ras-like GTPases. A membrane localization domain (residues 51-72) localizes ExoS to a perinuclear region within eukaryotic cells. Recent studies observed that ExoS is auto-ADP-ribosylated upon delivery into eukaryotic cells. Auto-ADP-ribosylated ExoS analyzed from eukaryotic cells displayed pI heterogeneity and prompted an analysis of this heterogeneity. Bacterial-associated ExoS and ExoS that had been secreted by P. aeruginosa also showed pI heterogeneity with five charge forms ranging in pI from 5.1 to 5.9. The pI heterogeneity of ExoS was independent of a mass change and thus represented molecular charge conformers. Urea was not required to observe the pI conformers of ExoS; it enhanced the resolution and formation of pI conformers during the focusing component of the analysis. ExoS(E381D), a mutant deficient in ADP-ribosyltransferase activity, isolated from cultured cells showed charge forms that migrated to a more acidic pI than type III secreted ExoS but more basic than auto-ADP-ribosylated ExoS. Incubation of cell lysates with Mn(2+) shifted the pI of ExoS(E381D) to a pI identical to secreted ExoS. This indicates that within the mammalian cells ExoS undergoes a negatively charged modification, in addition to auto-ADP-ribosylation observed for wild-type ExoS. ExoT, ExoU, and YopE also focus into multiple pI forms, suggesting that this is a common property of type III cytotoxins.     

How the Pseudomonas aeruginosa ExoS toxin downregulates Rac

Pseudomonas aeruginosa is an opportunistic bacterial pathogen. One of its major toxins, ExoS, is translocated into eukaryotic cells by a type III secretion pathway. ExoS is a dual function enzyme that affects two different Ras-related GTP binding proteins. The C-terminus inactivates Ras through ADP ribosylation, while the N-terminus inactivates Rho proteins through its GTPase activating protein (GAP) activity. Here we have determined the three-dimensional structure of a complex between Rac and the GAP domain of ExoS in the presence of GDP and AlF3. Composed of approximately 130 residues, this ExoS domain is the smallest GAP hitherto described. The GAP domain of ExoS is an all-helical protein with no obvious structural homology, and thus no recognizable evolutionary relationship, with the eukaryotic RhoGAP or RasGAP fold. Similar to other GAPs, ExoS downregulates Rac using an arginine finger to stabilize the transition state of the GTPase reaction, but the details of the ExoS-Rac interaction are unique. Considering the intrinsic resistance of P. aeruginosa to antibiotics, this might open up a new avenue towards blocking its pathogenicity.