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 33kDa (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.

Membrane translocation of diphtheria toxin fragment A exploits early to late endosome trafficking machinery

After reaching early endosomes by receptor-mediated endocytosis, diphtheria toxin (DT) molecules have two possible fates. A large pool enters the degradative pathway whereas a few molecules become cytotoxic by translocating their catalytic fragment A (DTA) into the cytosol. Impairment of DT degradation by microtubule depolymerization does not block DT cytotoxicity. Therefore, DTA membrane translocation into the cytosol occurs from an endocytic compartment located upstream of late endosomes. Comparisons between early endosomes and endocytic carrier vesicles in a cell-free translocation assay have demonstrated that early endosomes are the earliest endocytic compartment from which DTA translocates. DTA translocation is ATP-dependent, requires early endosomal acidification, and is increased by the addition of cytosol. Cytosol-dependent DTA translocation is GTP gamma S-insensitive but is blocked by anti-beta COP antibodies.

Large clostridial cytotoxins--a family of glycosyltransferases modifying small GTP-binding proteins

Some Clostridium species produce ABX-type protein cytotoxins of high molecular weight. These toxins constitute the group of large clostridial cytotoxins (LCTs), which have homologous protein sequences, exert glycosyltransferase activity and modify GTP-binding proteins of the Ras-superfamily. These characteristics render the LCTs valuable tools for developmental and cell biologists.

Rho-dependent membrane folding causes Shigella entry into epithelial cells

The small GTPase rho is functionally involved in the formation of cytoskeletal structures like stress fibers or focal adhesion plaques. Shigella entry into HeLa cells induces a blossom-like membrane structure at the bacterial entry site. We show here that this membrane-folding process is rho-dependent. The three rho isoforms were recruited into bacterial entry sites with differential localization relative to the membrane structure. A rho-specific inhibitor abolished Shigella-induced membrane folding and impaired bacterial entry accordingly. S1-myosin labeling indicated that rho was involved in Shigella-induced actin polymerization but not actin nucleation in the bacterial invasion site. This provides a major link in the signalization cascade allowing entry of a bacterial pathogen into a eukaryotic cell.

Ras, Rap, and Rac small GTP-binding proteins are targets for Clostridium sordellii lethal toxin glucosylation

Lethal toxin (LT) from Clostridium sordellii is one of the high molecular mass clostridial cytotoxins. On cultured cells, it causes a rounding of cell bodies and a disruption of actin stress fibers. We demonstrate that LT is a glucosyltransferase that uses UDP-Glc as a cofactor to covalently modify 21-kDa proteins both in vitro and in vivo. LT glucosylates Ras, Rap, and Rac. In Ras, threonine at position 35 was identified as the target amino acid glucosylated by LT. Other related members of the Ras GTPase superfamily, including RhoA, Cdc42, and Rab6, were not modified by LT. Incubation of serum-starved Swiss 3T3 cells with LT prevents the epidermal growth factor-induced phosphorylation of mitogen-activated protein kinases ERK1 and ERK2, indicating that the toxin blocks Ras function in vivo. We also demonstrate that LT acts inside the cell and that the glucosylation reaction is required to observe its dramatic effect on cell morphology. LT is thus a powerful tool to inhibit Ras function in vivo.

UDP-glucose deficiency in a mutant cell line protects against glucosyltransferase toxins from Clostridium difficile and Clostridium sordellii

We have previously isolated a fibroblast mutant cell with high resistance to the two Rho-modifying glucosyltransferase toxins A and B of Clostridium difficile. We demonstrate here a low level of UDP-glucose in the mutant, which explains its toxin resistance since: (i) to obtain a detectable toxin B-mediated Rho modification in lysates of mutant cells, addition of UDP-glucose was required, and it promoted the Rho modification dose-dependently; (ii) high pressure liquid chromatography analysis of nucleotide extracts of cells indicated that the level of UDP-glucose in the mutant (0.8 nmol/10(6) cells) was lower than in the wild type (3.7 nmol/10(6) cells); and (iii) sensitivity to toxin B was restored upon microinjection of UDP-glucose. Using the mutant as indicator cell we also found that the related Clostridium sordellii lethal toxin is a glucosyltransferase which requires UDP-glucose as a cofactor. Like toxin B it glucosylated 21-23-kDa proteins in cell lysates, but Rho was not a substrate for lethal toxin.

Rho protein regulates tight junctions and perijunctional actin organization in polarized epithelia

The rho family of GTP-binding proteins regulates actin filament organization. In unpolarized mammalian cells, rho proteins regulate the assembly of actin-containing stress fibers at the cell-matrix interface. Polarized epithelial cells, in contrast, are tall and cylindrical with well developed intercellular tight junctions that permit them to behave as biologic barriers. We report that rho regulates filamentous actin organization preferentially in the apical pole of polarized intestinal epithelial cells and, in so doing, influences the organization and permeability of the associated apical tight junctions. Thus, barrier function, which is an essential characteristic of columnar epithelia, is regulated by rho.

Transient expression of RhoA, -B, and -C GTPases in HeLa cells potentiates resistance to Clostridium difficile toxins A and B but not to Clostridium sordellii lethal toxin

The bacterial pathogen Clostridium difficle synthesizes two high-molecular-weight toxins (A and B), which exhibit toxic effects in vivo and in vitro. Here, we present evidence that the major intracellular targets of these two toxins are the Rho GTPases. Overexpression of RhoA, RhoB, or RhoC GTPases in transfected HeLa cells conferred an increased resistance to toxins A and B, indicating that these toxins cause their cytopathic effects primarily by affecting Rho proteins. In addition, toxin A and B treatment appeared to result in modification of Rho, since Rho isolated from toxin-treated cells had a decreased ability to be ADP-ribosylated by Clostridium botulinum C3 exoenzyme. In contrast, the lethal toxin (LT) of Clostridium sordellii, although structurally and immunologically related to C. difficile toxin B, appeared to induce cytopathic effects independently of the Rho GTPases. Overexpression of RhoA in transfected HeLa cells did not protect them from the effect of LT, and Rho isolated from lysates of LT-treated cells was not resistant to modification by C3. Immunofluorescence studies showed that LT treatment caused a cytopathic effect that was very different from those described for C. difficile toxins A and B, resulting in an increase in cortical F-actin, with a concomitant decrease in the number of stress fibers, and in the formation of numerous microvilli containing the actin-bundling protein fimbrin/plastin.

Escherichia coli cytotoxic necrotizing factor 1: evidence for induction of actin assembly by constitutive activation of the p21 Rho GTPase

Cytotoxic necrotizing factor type 1 (CNF1) induces in HEp-2 cells an increase in F-actin structures, which was detectable by fluorescence-activated cell sorter analysis 24 h after addition of this factor to the culture medium. Increase in F-actin was correlated with the augmentation of both the cell volume and the total cell actin content. Actin assembly-disassembly is controlled by small GTP-binding proteins of the Rho family, which have been reported recently to be modified by CNF1 treatment. Clostridium difficile toxin B and Clostridium botulinum exoenzyme C3, both known to act on the Rho GTPase, were used as biological tools to study the effect of CNF1 on this protein. CNF1 incubated before, during, or after exposure to the chimeric toxin C3B (which is the product of a genetic fusion between the DNA coding for C3 and the one coding for the B fragment of diphtheria toxin) protected HEp-2 cells from the disruption of F-actin structures caused by inactivation of the Rho GTPase through its ADP-ribosylation. On the other hand, C. difficile toxin B cytopathic effect was not observed upon preincubation of cells with CNF1. Toxins acting through a Rho-independent mechanism, such as cytochalasin D and Clostridium spiroforme iota-like toxin, could not be modified in their cellular activities by CNF1 treatment. All of our results suggest that CNF1 modifies the Rho molecule, thus probably protecting this GTPase from further bacterial toxin modification.

ADP-ribosylation of Rho enhances actin polymerization-coupled shape oscillations in human neutrophils

Stimulated neutrophils exhibit coordinated sinusoidal oscillations in filamentous actin content and cellular shape. We investigated the effect of inhibition of the small G protein Rho on neutrophil actin polymerization, shape changes and oscillations using a genetically engineered toxin that enters cells and selectively ADP-ribosylates endogenous Rho. This treatment increased the amplitudes and frequencies of shape oscillations and duration of the oscillating transient. However, it had no effect on the initial actin polymerization and shape changes induced by N-formyl-Met-Leu-Phe. Regulation of these oscillations may be important for the control of neutrophil motility.

Role of bound GDP in the stability of the rho A-rho GDI complex purified from neutrophil cytosol

The rho A-rho GDI complex purified from bovine neutrophil cytosol was found to contain GDP as the only bound nucleotide at a ratio of 1 mol of GDP per mol of complex. The rho GDI component of the complex (pI 4.8-5.0, apparent molecular mass 28-29 kDa) and the rho A component (pI scattered between 5.0-6.2, apparent molecular mass 24 kDa) were resolved by 2D gel electrophoresis. Upon dephosphorylation of bound GDP by apyrase, the rho A component of the complex was prone to proteolytic cleavage. The integrity of rho A in the presence of apyrase was preserved by addition of excess GTP. These data suggest that rho A liganded by GDP in the rho A-rho GDI complex is maintained in a conformation that escapes action of proteases.

Organization of the botulinum neurotoxin C1 gene and its associated non-toxic protein genes in Clostridium botulinum C 468

A 12.3 kb DNA fragment encompassing the botulinum neurotoxin C1 (BoNT/C1) gene and an upstream flanking region was sequenced from Clostridium botulinum C 468 phage 1C. The resulting bont/C1 locus includes six genes which are organized into three transcriptional units. Cluster 1 encompasses the bont/C1 gene and an upstream gene encoding a non-toxic protein associated with the toxin (Antp139/C1). Transcriptional analysis revealed that these two genes form an operon; the bont/C1 gene can be transcribed alone or co-transcribed with antp139/C1. Cluster 2 encompasses three genes (antp33/C1, antp17/C1 and antp70/C1), which also form an operon. The corresponding proteins are similar to components of the hemagglutinin complex associated with BoNT/A and BoNT/B of C. botulinum A and B. In addition, Antp33/C1 is identical to HA-33, an hemagglutinin encoded by C. botulinum C-Stockholm phage C-St; Antp70/C1 displays some relatedness to C. perfringens enterotoxin. The third transcriptional unit consists of orf-22, which encodes a basic protein showing 29% identity with the gene product of uviA, a plasmid-encoded protein of 22 kDa which has been identified as a positive regulator of the bacteriocin production in C. perfringens. Orf-22 could be an effector controlling the expression of the bont/C1 and its antp genes in C. botulinum C 468.

Cytotoxic necrotizing factor type 2 produced by virulent Escherichia coli modifies the small GTP-binding proteins Rho involved in assembly of actin stress fibers

Cytotoxic necrotizing factor type 2 (CNF2) produced by Escherichia coli strains isolated from intestinal and extraintestinal infections is a dermonecrotic toxin of 110 kDa. We cloned the CNF2 gene from a large plasmid carried by an Escherichia coli strain isolated from a lamb with septicemia. Hydropathy analysis of the deduced amino acid sequence revealed a largely hydrophilic protein with two potential hydrophobic transmembrane domains. The N-terminal half of CNF2 showed striking homology (27% identity and 80% conserved residues) to the N-terminal portion of Pasteurella multocida toxin. Methylamine protection experiments and immunofluorescence studies suggested that CNF2 enters the cytosol of the target cell through an acidic compartment and induces the reorganization of actin into stress fibers. Since the formation of stress fibers in eukaryotic cells involves Rho proteins, we radiolabeled these small GTP-binding proteins from CNF2-treated and control cells with a Rho-specific ADP-ribosyltransferase. The [32P]ADP-ribosylated Rho proteins from CNF2-treated cells migrated slightly more slowly in SDS/PAGE than did the labeled proteins from the control cells. This shift in mobility of Rho proteins in SDS/PAGE was also observed when CNF2 and the RhoA protein were coexpressed in E. coli. We propose that Rho proteins are the targets of CNF2 in mammalian cells.

Clostridium difficile toxin B acts on the GTP-binding protein Rho

Clostridium difficile toxin B exhibits cytotoxic activity that is characterized by the disruption of the microfilamental cytoskeleton. Here we studied whether the GTP-binding Rho protein, which reportedly participates in the regulation of the actin cytoskeleton, is involved in the toxin action. Toxin B treatment of Chinese hamster ovary cells reveals a time- and concentration-dependent decrease in the ADP-ribosylation of Rho by Clostridium botulinum C3 exoenzyme in the cell lysate. Disruption of the microfilament system induced by C. botulinum C2 toxin or cytochalasin D does not cause impaired ADP-ribosylation of Rho. Toxin B exhibits its effects on Rho not only in intact cells but also when added to cell lysates. Besides endogenous Rho, RhoA-glutathione S-transferase (Rho-GST) fusion protein added to cell lysate showed decreased ADP-ribosylation after toxin B treatment. Immunoblot analysis reveals identical amounts of Rho-GST and no change in molecular mass after toxin B treatment compared with controls. ADP-ribosylation of Rho-GST purified from toxin B-treated cell lysate is inhibited, indicating a modification of Rho itself. Finally, transfection of rhoA DNA under the control of a strong promoter into cells protects them from the activity of toxin B. Altogether, the data indicate that C. difficile toxin B acts directly or indirectly on Rho proteins to inhibit ADP-ribosylation and suggest that the cytotoxic effect of toxin B involves Rho.

Epitope tagging of DAB389IL-2: new insights into C-domain delivery to the cytosol of target cells

The fusion toxin DAB389IL-2 is composed of the catalytic (C) and transmembrane (T) domains of native diphtheria toxin to which human interleukin-2 (IL-2) has been genetically fused (1,2). Following binding to the IL-2 receptor, the fusion toxin is internalized by receptor mediated endocytosis, and upon acidification of the endocytic vesicle, the T domain spontaneously inserts into the membrane, and facilitates the delivery of the C domain to the cytosol (3,4). In order to further study the process by which the C domain is delivered to the target cell cytosol, we genetically fused an eleven amino acid epitope derived from the vesicular stomatitis virus (VSV) G protein to the N-terminal end of DAB389IL-2. The epitope labelled fusion toxin, VSV-G-DAB389IL-2, was found to retain IL-2 receptor specific binding and cytotoxic activity. Target cells were incubated for various times in the presence of VSV-G-DAB389, fixed and then treated with anti-VSV G and FITC conjugated secondary antibody. Laser scanning confocal microscopy was used to determine the location of the fluorescent signal. The VSV-G epitope tagged fusion toxin was found only to be associated with small vesicles that were situated adjacent to the plasma membrane. These results suggest that the C domain of the fusion toxin is associated with an early intracellular compartment and is rapidly delivered to the cytosol. Since channel formation by the T domain is necessary for the delivery of the C domain, it follows that T domain insertion into the membrane also occurs early in the intoxication pathway.

Characterization of Clostridium perfringens iota-toxin genes and expression in Escherichia coli

The iota toxin which is produced by Clostridium perfringens type E, is a binary toxin consisting of two independent polypeptides: Ia, which is an ADP-ribosyltransferase, and Ib, which is involved in the binding and internalization of the toxin into the cell. Two degenerate oligonucleotide probes deduced from partial amino acid sequence of each component of C. spiroforme toxin, which is closely related to the iota toxin, were used to clone three overlapping DNA fragments containing the iota-toxin genes from C. perfringens type E plasmid DNA. Two genes, in the same orientation, coding for Ia (387 amino acids) and Ib (875 amino acids) and separated by 243 noncoding nucleotides were identified. A predicted signal peptide was found for each component, and the secreted Ib displays two domains, the propeptide (172 amino acids) and the mature protein (664 amino acids). The Ia gene has been expressed in Escherichia coli and C. perfringens, under the control of its own promoter. The recombinant polypeptide obtained was recognized by Ia antibodies and ADP-ribosylated actin. The expression of the Ib gene was obtained in E. coli harboring a recombinant plasmid encompassing the putative promoter upstream of the Ia gene and the Ia and Ib genes. Two residues which have been found to be involved in the NAD+ binding site of diphtheria and pseudomonas toxins are conserved in the predicted Ia sequence (Glu-14 and Trp-19). The predicted amino acid Ib sequence shows 33.9% identity with and 54.4% similarity to the protective antigen of the anthrax toxin complex. In particular, the central region of Ib, which contains a predicted transmembrane segment (Leu-292 to Ser-308), presents 45% identity with the corresponding protective antigen sequence which is involved in the translocation of the toxin across the cell membrane.

Comparative analysis of C3 and botulinal neurotoxin genes and their environment in Clostridium botulinum types C and D

The C3 exoenzyme gene is located on a bacteriophage in Clostridium botulinum types C and D (M. R. Popoff, D. Hauser, P. Boquet, M. W. Eklund, and D. M. Gill, Infect. Immun. 59:3673-3679, 1991). A derivative CN phage from phage C of C. botulinum Stockholm (C-St) (K. Oguma, H. Iida, and K. Inoue, Jpn. J. Microbiol. 19:167-172, 1975), isolated as neurotoxin negative, also does not produce exoenzyme C3. The botulinal neurotoxin C1 gene is present on the CN phage but contains a stop mutation in the DNA region encoding the N-terminal part of the heavy chain (codon 553). The putative truncated botulinal neurotoxin C1 protein was not recovered in a C. botulinum strain harboring the CN phage. We found that the C3 gene is localized on a 21.5-kbp DNA fragment flanked by the core motif 5'-AAGGAG-3' in DNAs of phage C of C. botulinum 468 (C-468), C-St phage, and phage D of C. botulinum 1873 (D-1873). The 21.5-kbp DNA fragment is deleted in CN phage DNA, and the motif 5'-AAGGAG-3' is present only in one copy at the deletion junction, but the deletion in the CN phage could be nonspecific, since this phage was obtained by nitrosoguanidine treatment. These findings could indicate that the C3 gene is localized on a 21.5-kbp mobile element. C. botulinum type C strain 003-9 produces a C3 exoenzyme (Y. Nemoto, T. Namba, S. Kozaki, and S. Narumiya, J. Biol. Chem. 266:19312-19319, 1991), and Staphylococcus aureus E1 produces a related C3 enzyme which is named epidernmal cell differentiation inhibitor (S. Inoue, M. Sugai, Y. Murooka, S. Y. Paik, Y. M. Hong, H. Oghai, and H. Suginaka, Biochem. Biophys. Res. Comm. 174:459-464, 1991) and which shares 80.6 and 56.6% similarity, respectively with the C3 enzymes from C-468 or C-St and D-1873 phages athe amino acid level. The features of the putative 21.5-kbp transposon were not found in C. botulinum 003-9 and S. aureus E1, as determined by analysis of the C3 and epidermal cell differentiation inhibitor gene-flanking DNA regions. These data suggest a common ancestral origin and divergent evolution of the C3 genes in these three groups of bacterial strains and dissemination of a 21.5-kbp element carrying the C3 gene C-468, C-St, and D-1873 phages.

Polymerase chain reaction assay for diagnosis of potentially toxinogenic Corynebacterium diphtheriae strains: correlation with ADP-ribosylation activity assay

We have developed a polymerase chain reaction assay for the clinical diagnosis of potentially toxinogenic strains of Corynebacterium diphtheriae, the causative agent of diphtheria. A 910-bp amplification product, overlapping a DNA portion encoding both fragments of the diphtheria toxin, has been found in 28 among the 36 strains tested. In addition, effective toxin production, as evidenced by the ability of bacterial culture supernatants to ADP ribosylate eukaryotic elongation factor 2, was determined. In every case, the presence of an amplification product correlated with an ADP-ribosylation activity, thus confirming the diagnosis. The polymerase chain reaction assay herein described is very rapid (2 h) compared with the Elek immunodiffusion test or the guinea pig lethality test. It can provide a convenient and reliable method for laboratories involved in the identification of toxinogenic corynebacteria.