Identification of the region of rho involved in substrate recognition by Escherichia coli cytotoxic necrotizing factor 1 (CNF1).

The Escherichia coli cytotoxic necrotizing factor 1 (CNF1) and the Bordetella dermonecrotic toxin (DNT) activate Rho GTPases by deamidation of Gln(63) of RhoA (Gln(61) of Cdc42 and Rac). In addition, both toxins possess in vitro transglutaminase activity in the presence of primary amines. Here we characterized the region of Rho essential for substrate recognition by the toxins using Rho/Ras chimeras as protein substrates. The chimeric protein Ras55Rho was deamidated or transglutaminated by CNF1. Rat pheochromocytoma PC12 cells microinjected with Ras55Rho developed formation of neurite-like structures after treatment with the CNF1 holotoxin indicating activation of the Ha-Ras chimera and Ras-like effects in intact cells. The Ras59Rho78Ras chimera protein contained the minimal Rho sequence allowing deamidation or transglutamination by CNF1. A peptide covering mainly the switch II region and consisting of amino acid residues Asp(59) through Asp(78) of RhoA was substrate for CNF1. Changes of amino acid residues Arg(68) or Leu(72) of RhoA into the corresponding residues of Ras (R68ARhoA and L72QRhoA) inhibited deamidation and transglutamination of the mutants by CNF1. In contrast to CNF1, DNT did not modify Rho/Ras chimeras or the switch II peptide (Asp(59) through Asp(78)). Glucosylation of RhoA at Thr(37) blocked deamidation by DNT but not by CNF. The data indicate that CNF1 recognizes Rho GTPases exclusively in the switch II region, whereas the substrate recognition by DNT is characterized by additional structural requirements.     

Change of the donor substrate specificity of Clostridium difficile toxin B by site-directed mutagenesis

The large cytotoxins of Clostridia species glycosylate and thereby inactivate small GTPases of the Rho family. Clostridium difficile toxins A and B and Clostridium sordellii lethal toxin use UDP-glucose as the donor for glucosylation of Rho/Ras GTPases. In contrast, alpha-toxin from Clostridium novyi N-acetylglucosaminylates Rho GTPases by using UDP-N-acetylglucosamine as a donor substrate. Based on the crystal structure of C. difficile toxin B, we studied the sugar donor specificity of the toxins by site-directed mutagenesis. The changing of Ile-383 and Gln-385 in toxin B to serine and alanine, respectively, largely increased the acceptance of UDP-N-acetylglucosamine as a sugar donor for modification of RhoA. The K(m) value was reduced from 960 to 26 mum for the double mutant. Accordingly, the potential of the double mutant of toxin B to hydrolyze UDP-N-acetylglucosamine was higher than that for UDP-glucose. The changing of Ile-383 and Gln-385 in the lethal toxin of C. sordellii allowed modification of Ras in the presence of UDP-N-acetyl-glucosamine and reduced the acceptance of UDP-glucose as a donor for glycosylation. Vice versa, the changing of the equivalent residues in C. novyi alpha-toxin from Ser-385 and Ala-387 to isoleucine and glutamine, respectively, reversed the donor specificity of the toxin from UDP-N-acetylglucosamine to UDP-glucose. These data demonstrate that two amino acid residues are crucial for the co-substrate specificity of clostridial glycosylating toxins.     

Change in substrate specificity of cytotoxic necrotizing factor unmasks proteasome-independent down-regulation of constitutively active RhoA

Cytotoxic necrotizing factors CNF1 and CNF2 are produced by pathogenic Escherichia coli strains. They constitutively activate small GTPases of the Rho family by deamidation of a glutamine, which is crucial for GTP hydrolysis. Recently, a novel CNF (CNF(Y)) encompassing 65% identity to CNF1 has been identified in Yersinia pseudotuberculosis. In contrast to the E. coli toxins, which activate several isoforms of Rho family GTPases, CNF(Y) is a strong and selective activator of RhoA in vivo. By constructing chimeras between CNF1 and CNF(Y), we show that this substrate specificity is based on differences in the catalytic domains, whereas the receptor binding and translocation domains have no influence. We further define a loop element (L8) on the surface of the catalytic domains as important for substrate recognition. A single amino acid exchange in L8 is sufficient to shift substrate specificity of CNF1. Moreover, it is shown that RhoA activation by CNF1 is transient, which may be the consequence of the broader substrate specificity of the E. coli toxin, leading to cross-talk between the activated GTPases.     

Rho GTPases as targets of bacterial protein toxins

Several bacterial toxins target Rho GTPases, which constitute molecular switches in several signaling processes and master regulators of the actin cytoskeleton. The biological activities of Rho GTPases are blocked by C3-like transferases, which ADP-ribosylate Rho at Asn41, but not Rac or Cdc42. Large clostridial cytotoxins (e. g., Clostridium difficile toxin A and B) glucosylate Rho GTPases at Thr37 (Rho) or Thr35 (Rac/Cdc42), thereby inhibiting Rho functions by preventing effector coupling. The 'injected' toxins ExoS, YopE and SptP from Pseudomonas aeruginosa, Yersinia and Salmonella ssp., respectively, which are transferred into the eukaryotic target cells by the type-III secretion system, inhibit Rho functions by acting as Rho GAP proteins. Rho GTPases are activated by the cytotoxic necrotizing factors CNF1 and CNF2 from Escherichia coli and by the dermonecrotizing toxin DNT from B. bronchiseptica. These toxins deamidate/transglutaminate Gln63 of Rho to block the intrinsic and GAP-stimulated GTP hydrolysis, thereby constitutively activating the GTPases. Rho GTPases are also activated by SopE, a type-III system injected protein from Salmonella ssp., that acts as a GEF protein.     

CNF and DNT

The actin cytoskeleton of mammalian cells is involved in many processes that affect the growth and colonization of bacteria, such as migration of immune cells, phagocytosis by macrophages, secretion of cytokines, maintenance of epithelial barrier functions and others. With respect to these functions, it is not surprising that many bacterial protein toxins, which are important virulence factors and causative agents of human and/or animal diseases, target the actin cytoskeleton of the host. Some toxins target actin directly, such as the C2 toxin produced by Clostridium botulinum. Moreover, bacterial toxins target the cytoskeleton indirectly by modifying actin regulators such as the low-molecular-mass guanosine triphosphate (GTP)-binding proteins of the Rho family. Remarkably, toxins affect these GTPases in a bidirectional manner. Some toxins inhibit and some activate the GTPases. Here we review the Rho-activating toxins CNF1 and CNF2 (cytotoxic necrotizing factors) from Escherichia coli, the Yersinia CNF_Y and the dermonecrotic toxin (DNT) from Bordetella species. We describe and compare their uptake into mammalian cells, mode of action, structure–function relationship, substrate specificity and role in diseases.     

A single amino acid substitution in the enzymatic domain of cytotoxic necrotizing factor type 1 of Escherichia coli alters the tissue culture phenotype to that of the dermonecrotic toxin of Bordetella spp

Cytotoxic necrotizing factor type 1 (CNF1) and dermonecrotic toxin (DNT) share homology within their catalytic domains and possess deamidase and transglutaminase activities. Although each toxin has a preferred enzymatic activity (i.e. deamidation for CNF1 and transglutamination for DNT) as well as target substrates, both modify a specific glutamine residue in RhoA, Rac1 and Cdc42, which renders these GTPases constitutively active. Here we show that despite their similar mechanisms of action CNF1 and DNT induced unique phenotypes on HEp-2 and Swiss 3T3 cells. CNF1 induced multinucleation of HEp-2 cells and was cytotoxic for Swiss 3T3 cells (with binucleation of the few surviving cells) while DNT showed no morphological effects on HEp-2 cells but did induce binucleation of Swiss 3T3 cells. To determine if the enzymatic domain of each toxin dictated the induced phenotype, we constructed enzymatically active chimeric toxins and mutant toxins that contained single amino acid substitutions within the catalytic site and tested these molecules in tissue culture and enzymatic assays. Moreover, both site-directed mutant toxins showed reduced time to maximum transglutamination of RhoA compared with the parent toxins. Nevertheless, the substitution of threonine for Lys(1310) in the DNT-based mutant, while affecting transglutamination efficiency of the toxin, did not abrogate that enzymatic activity.     

A Rho-related GTPase is involved in Ca(2+)-dependent neurotransmitter exocytosis

Rho, Rac, and Cdc42 monomeric GTPases are well known regulators of the actin cytoskeleton and phosphoinositide metabolism and have been implicated in hormone secretion in endocrine cells. Here, we examine their possible implication in Ca(2+)-dependent exocytosis of neurotransmitters. Using subcellular fractionation procedures, we found that RhoA, RhoB, Rac1, and Cdc42 are present in rat brain synaptosomes; however, only Rac1 was associated with highly purified synaptic vesicles. To determine the synaptic function of these GTPases, toxins that impair Rho-related proteins were microinjected into Aplysia neurons. We used lethal toxin from Clostridium sordellii, which inactivates Rac; toxin B from Clostridium difficile, which inactivates Rho, Rac, and Cdc42; and C3 exoenzyme from Clostridium botulinum and cytotoxic necrotizing factor 1 from Escherichia coli, which mainly affect Rho. Analysis of the toxin effects on evoked acetylcholine release revealed that a member of the Rho family, most likely Rac1, was implicated in the control of neurotransmitter release. Strikingly, blockage of acetylcholine release by lethal toxin and toxin B could be completely removed in <1 s by high frequency stimulation of nerve terminals. Further characterization of the inhibitory action produced by lethal toxin suggests that Rac1 protein regulates a late step in Ca(2+)-dependent neuroexocytosis.     

Structure of the Rho-activating domain of Escherichia coli cytotoxic necrotizing factor 1.

Certain uropathogenic and neonatal meningitis-causing strains of Escherichia coli express a 114 kDa protein toxin called cytotoxic necrotizing factor 1 (CNF1). The toxin causes alteration of the host cell actin cytoskeleton and promotes bacterial invasion of blood-brain barrier endothelial cells. CNF1 belongs to a unique group of large cytotoxins that cause constitutive activation of Rho guanosine triphosphatases (GTPases), which are key regulators of the actin cytoskeleton. This group also includes E. coli cytotoxic necrotizing factor 2 (CNF2, 114 kDa) and dermonecrotic toxins (DNT, 159 kDa) of Bordetella spp. with related sequences occurring in Yersinia spp. Here we show that the catalytic region of CNF1 exhibits a novel protein fold as determined by its 1.83 A resolution crystal structure. The structure reveals that CNF1 has a Cys-His-main chain oxygen catalytic triad reminiscent of enzymes belonging to the catalytic triad superfamily. The position of the catalytic Cys residue at the base of a deep pocket restricts access to potential substrates and helps explain the high specificity of this and related toxins.     

37-kDa laminin receptor precursor modulates cytotoxic necrotizing factor 1-mediated RhoA activation and bacterial uptake

Cytotoxic necrotizing factor 1 (CNF1) is a bacterial toxin known to activate Rho GTPases and induce host cell cytoskeleton rearrangements. The constitutive activation of Rho GTPases by CNF1 is shown to enhance bacterial uptake in epithelial cells and human brain microvascular endothelial cells. However, it is unknown how exogenous CNF1 exhibits such phenotypes in eukaryotic cells. Here, we identified 37-kDa laminin receptor precursor (LRP) as the receptor for CNF1 from screening the cDNA library of human brain microvascular endothelial cells by the yeast two-hybrid system using the N-terminal domain of CNF1 as bait. CNF1-mediated RhoA activation and bacterial uptake were inhibited by exogenous LRP or LRP antisense oligodeoxynucleotides, whereas they were increased in LRP-overexpressing cells. These findings indicate that the CNF1 interaction with LRP is the initial step required for CNF1-mediated RhoA activation and bacterial uptake in eukaryotic cells.     

Monoglucosylation of RhoA at threonine 37 blocks cytosol-membrane cycling.

The small GTPases Rho, Rac, and Cdc42 are monoglucosylated at effector domain amino acid threonine 37/35 by Clostridium difficile toxins A and B. Glucosylation renders the Rho proteins inactive by inhibiting effector coupling. To understand the functional consequences, effects of glucosylation on subcellular distribution and cycling of Rho GTPases between cytosol and membranes were analyzed. In intact cells and in cell lysates, glucosylation leads to a translocation of the majority of RhoA GTPase to the membranes whereas a minor fraction is monomeric in the cytosol without being complexed with the guanine nucleotide dissociation inhibitor (GDI-1). Rho complexed with GDI-1 is not substrate for glucosylation, and modified Rho does not bind to GDI-1. However, a membranous factor inducing release of Rho from the GDI complex makes cytosolic Rho available as a substrate for glucosylation. The binding of glucosylated RhoA to the plasma membranes is saturable, competable with unmodified Rho-GTPgammaS guanosine 5'-O-(3-thiotriphosphate), and takes place at a membrane protein with a molecular mass of about 70 kDa. Membrane-bound glucosylated Rho is not extractable by GDI-1 as unmodified Rho is, leading to accumulation of modified Rho at membranous binding sites. Thus, in addition to effector coupling inhibition, glucosylation also inhibits Rho cycling between cytosol and membranes, a prerequisite for Rho activation.     

Inactivation of small Rho GTPases by the multifunctional RTX toxin from Vibrio cholerae

Many bacterial toxins target small Rho GTPases in order to manipulate the actin cytoskeleton. The depolymerization of the actin cytoskeleton by the Vibrio cholerae RTX toxin was previously identified to be due to the unique mechanism of covalent actin cross-linking. However, identification and subsequent deletion of the actin cross-linking domain within the RTX toxin revealed that this toxin has an additional cell rounding activity. In this study, we identified that the multifunctional RTX toxin also disrupts the actin cytoskeleton by causing the inactivation of small Rho GTPases, Rho, Rac and Cdc42. Inactivation of Rho by RTX was reversible in the presence of cycloheximide and by treatment of cells with CNF1 to constitutively activate Rho. These data suggest that RTX targets Rho GTPase regulation rather than affecting Rho GTPase directly. A novel 548-amino-acid region of RTX was identified to be responsible for the toxin-induced inactivation of the Rho GTPases. This domain did not carry GAP or phosphatase activities. Overall, these data show that the RTX toxin reversibly inactivates Rho GTPases by a mechanism distinct from other Rho-modifying bacterial toxins.     

Molecular localization of the Escherichia coli cytotoxic necrotizing factor CNF1 cell-binding and catalytic domains

Cytotoxic necrotizing factor type 1 (CNF1) induces, in epithelial cells, the development of stress fibres via the GTPase Rho pathway. We showed that CNF1 is able to modify Rho both in vitro and in vivo. Recombinant N-terminal 33 kDa (CNF1Nter) and C-terminal 14.8–31.5 kDa (CNF1Cter) regions of the CNF1 protein allowed us to demonstrate that the N-terminal region contains the cell-binding domain of the toxin and that the C-terminal region is responsible for its catalytic activity. CNF1Nter lowered the activity of CNF1 when provided to cells before the toxin whereas CNF1Cter had no effect on CNF1 cell toxicity. CNF1Cter was sufficient to induce a typical CNF1 phenotype when microinjected into African green monkey kidney cells (Vero cells), and was able to modify Rho as previously reported for CNF1. The C-terminal domain lost its catalytic activity when deleted of various subdomains, suggesting a scattered distribution of catalytic-site amino acids. Elucidation of the CNF1 functional organization and analysis of amino acid homologies between CNFs (CNF1, CNF2), Pasteurella multocida toxin (PMT) and dermonecrotic toxin of Bordetella pertussis (DNT) allowed us to postulate that CNFs and DNT act on Rho via the same enzymatic activity located in their C-terminus, and that CNFs and PMT probably bind to analogous cell receptors.     

RhoD localization and function is dependent on its GTP/GDP-bound state and unique N-terminal motif

The atypical Rho GTPase RhoD has previously been shown to have a major impact on the organization and function of the actin filament system. However, when first discovered, RhoD was found to regulate endosome trafficking and dynamics and we therefore sought to investigate this regulation in more detail. We found that exogenously expressed RhoD in human fibroblasts localized to vesicles and the plasma membrane and that the active GTP-bound conformation was required for the plasma membrane localization but not for vesicle localization. In contrast to the GTPase deficient atypical Rho GTPases, which have a stalled GTPase activity, RhoD has an elevated intrinsic GDP/GTP exchange activity, rendering the protein constitutively active. Importantly, RhoD can still hydrolyze GTP and we found that an intact GTPase activity was required for efficient fusion of RhoD-positive vesicles. RhoD has a unique N-terminal extension of 14 amino acid residues, which is not present in the classical Rho GTPases RhoA, Cdc42 and Rac1. Deletion of this N-terminal motif often lead to clustering of RhoD positive vesicles, which were found accumulated at the peripheral membrane border. In addition, the number of vesicles per cell was increased manifold, suggesting that the N-terminal motif has an important regulatory role in vesicle dynamics.     

Differential role of Rho GTPases in intestinal epithelial barrier regulation in vitro

Maintenance of intestinal epithelial barrier functions is crucial to prevent systemic contamination by microbes that penetrate from the gut lumen. GTPases of the Rho-family such as RhoA, Rac1, and Cdc42 are known to be critically involved in the regulation of intestinal epithelial barrier functions. However, it is still unclear whether inactivation or activation of these GTPases exerts barrier protection or not. We tested the effects of Rho GTPase activities on intestinal epithelial barrier functions by using the bacterial toxins cytotoxic necrotizing factor 1 (CNF-1), toxin B, C3 transferase (C3 TF), and lethal toxin (LT) in an in vitro model of the intestinal epithelial barrier. Incubation of cell monolayers with CNF-1 for 3 h induced exclusive activation of RhoA whereas Rac1 and Cdc42 activities were unchanged. As revealed by FITC-dextran flux and measurements of transepithelial electrical resistance (TER) intestinal epithelial permeability was significantly increased under these conditions. Inhibition of Rho kinase via Y27632 blocked barrier destabilization of CNF-1 after 3 h. In contrast, after 24 h of incubation with CNF-1 only Rac1 and Cdc42 but not RhoA were activated which resulted in intestinal epithelial barrier stabilization. Toxin B to inactivate RhoA, Rac1, and Cdc42 as well as Rac1 inhibitor LT increased intestinal epithelial permeability. Similar effects were observed after inhibition of RhoA/Rho kinase signaling by C3 TF or Y27632. Taken together, these data demonstrate that both activation and inactivation of RhoA signaling increased paracellular permeability whereas activation of Rac1 and Cdc42 correlated with stabilized barrier functions.     

Rif proteins take to the RhoD: Rho GTPases at the crossroads of actin dynamics and membrane trafficking

The Rif and RhoD proteins belong to the Rho subfamily of small GTPases. Rif and RhoD have for too long remained in the shadows of the better known Rho GTPases Cdc42, Rac1 and RhoA. With this review article, our aim is to provide the currently available information regarding Rif and RhoD. Taken together, the data available to date indicate that Rif and RhoD have unique roles in the regulation of actin dynamics, and that RhoD can link actin reorganisation to endosomal vesicle transport.     

Identification of the C-terminal part of Bordetella dermonecrotic toxin as a transglutaminase for rho GTPases.

Bordetella dermonecrotic toxin (DNT) causes the deamidation of glutamine 63 of Rho. Here we identified the region of DNT harboring the enzyme activity and compared the toxin with the cytotoxic necrotizing factor 1, which also deamidates Rho. The DNT fragment (DeltaDNT) covering amino acid residues 1136-1451 caused deamidation of RhoA at glutamine 63 as determined by mass spectrometric analysis and by the release of ammonia. In the presence of dansylcadaverine or ethylenediamine, DeltaDNT caused transglutamination of Rho. Deamidase and transglutaminase activities were blocked in the mutant proteins Cys(1292) --> Ala, His(1307) --> Ala, and Lys(1310) --> Ala of DeltaDNT. Deamidation and transglutamination induced by DeltaDNT blocked intrinsic and Rho- GTPase-activating protein-stimulated GTPase activity of RhoA. DeltaDNT deamidated and transglutaminated Rac and Cdc42 in the absence and presence of ethylenediamine, respectively. Modification of Rho proteins by DeltaDNT was nucleotide-dependent and did not occur with GTPgammaS-loaded GTPases. In contrast to cytotoxic necrotizing factor, which caused the same kinetics of ammonia release in the absence and presence of ethylenediamine, ammonia release by DeltaDNT was largely increased in the presence of ethylenediamine, indicating that DeltaDNT acts primarily as a transglutaminase.     

Activation of rho through a cross-link with polyamines catalyzed by Bordetella dermonecrotizing toxin

The small GTPase Rho, which regulates a variety of cell functions, also serves as a specific substrate for bacterial toxins. Here we demonstrate that Bordetella dermonecrotizing toxin (DNT) catalyzes cross-linking of Rho with ubiquitous polyamines such as putrescine, spermidine and spermine. Mass spectrometric analyses revealed that the cross-link occurred at Gln63, which had been reported to be deamidated by DNT in the absence of polyamines. Rac1 and Cdc42, other members of the Rho family GTPases, were also polyaminated by DNT. The polyamination, like the deamidation, markedly reduced the GTPase activity of Rho without affecting its GTP-binding activity, indicating that polyaminated Rho behaves as a constitutively active analog. Moreover, polyamine-linked Rho, even in the GDP-bound form, associated more effectively with its effector ROCK than deamidated Rho in the GTP-bound form and, when microinjected into cells, induced the anomalous formation of stress fibers indistinguishable from those seen in DNT-treated cells. The results imply that the polyamine-linked Rho, transducing signals to downstream ROCK in a novel GTP-independent manner, plays an important role in DNT cell toxicity.     

Modification of plant Rac/Rop GTPase signalling using bacterial toxin transgenes

Bacterial protein toxins which modify Rho GTPase are useful for the analysis of Rho signalling in animal cells, but these toxins cannot be taken up by plant cells. We demonstrate in vitro deamidation of Arabidopsis Rop4 by Escherichia coli Cytotoxic Necrotizing Factor 1 (CNF1) and glucosylation by Clostridium difficile toxin B. Expression of the catalytic domain of CNF1 caused modification and activation of co‐expressed Arabidopsis Rop4 GTPase in tobacco leaves, resulting in hypersensitive‐like cell death. By contrast, the catalytic domain of toxin B modified and inactivated co‐expressed constitutively active Rop4, blocking the hypersensitive response caused by over‐expression of active Rops. In transgenic Arabidopsis, both CNF1 and toxin B inhibited Rop‐dependent polar morphogenesis of leaf epidermal cells. Toxin B expression also inhibited Rop‐dependent morphogenesis of root hairs and trichome branching, and resulted in root meristem enlargement and dwarf growth. Our results show that CNF1 and toxin B transgenes are effective tools in Rop GTPase signalling studies.     

Bacterial toxin and effector glycosyltransferases

Clostridial glucosylating cytotoxins, including Clostridium difficile toxins A and B, Clostridium novyi α-toxin, and Clostridium sordellii lethal toxin, are major virulence factors and causative agents of human diseases. These toxins mono-O-glucosylate (or mono-O-GlcNAcylate) a specific threonine residue of Rho/Ras-proteins, which is essential for the function of the molecular switches. Recently, a related group of glucosyltransferases from Legionella pneumophila has been identified. These Legionella glucosyltransferases modify the large GTPase elongation factor eEF1A at a serine residue by mono-O-glucosylation, thereby inhibiting protein synthesis of target cells. Recent results on structures, functions and biological roles of both groups of bacterial toxin glucosyltransferases will be discussed.