Role of anions in low pH-induced translocation of diphtheria toxin

Previous work has shown that when Vero cells with surface-bound diphtheria toxin are exposed to low pH, toxin entry across the plasma membrane is induced and that this entry involves two steps, insertion of the B-fragment of the toxin into the membrane and translocation of the enzymatically active A-fragment to the cytosol. Here we have studied the role of permeant anions in this process. It was found that when the B-fragment was inserted into the membrane, part of it, a 25-kDa polypeptide, was shielded from externally added Pronase. This insertion did not require permeant anions. The translocation of the A-fragment was monitored by measuring either its ability to inhibit protein synthesis in the cells or the appearance of radioactively labeled 21-kDa fragment after treatment of the cells with externally applied Pronase. The translocation of the A-fragment was dependent on the presence of permeant anions in the medium. However, when the cells were depleted of Cl- by incubation in Cl- free buffer at high pH, translocation of the A-fragment did not require permeant anions in the medium. The possibility that translocation of the A-fragment is inhibited by an outward directed chloride gradient rather than by the absence of chloride is discussed.     

Interactions of diphtheria toxin B-fragment with cells. Role of amino- and carboxyl-terminal regions.

The B-fragment of diphtheria toxin binds to cell surface receptors and facilitates entry of the enzymatically active A-fragment into the cytosol. The roles of the amino- and carboxyl-terminal regions of the B-fragment in interactions with the cell membrane were studied by measuring specific binding, insertion into membranes at low pH, and formation of cation-selective channels, as well as by toxicity measurements after association with active A-fragment. Deletion of the amino-terminal 12 amino acids of the B-fragment did not affect its ability to bind to receptors and to form ion channels at low pH, whereas both abilities were strongly impaired when one more amino acid (Trp206) was removed. Replacement of the amino-terminal 31 residues with an amphipathic sequence from human apolipoprotein A1 restored receptor binding but not ion channel formation. The binding to cells was virtually abolished when 9 residues were deleted from the carboxyl terminus. Deletion of only 4 residues or extension by 12 residues did not prevent specific binding, but reduced insertion, channel formation, and toxicity. Those deletions that reduced receptor binding ability increased the trypsin sensitivity of the B-fragment. The results indicate that the amino- and carboxyl-terminal regions of diphtheria toxin B-fragment are important for receptor binding, possibly because they contribute to keep the B-fragment in a binding-competent conformation. Small alterations in the carboxyl-terminal end reduced insertion, channel formation, and toxicity more than the ability of the B-fragment to bind to cells.     

Low pH-induced release of diphtheria toxin A-fragment in Vero cells. Biochemical evidence for transfer to the cytosol

When Vero cells with surface-bound 125I-labeled, nicked diphtheria toxin were exposed to pH 4.5, two polypeptides of Mr 20,000 and 25,000 became protected against externally applied Pronase E. The 20-kDa polypeptide appears to be the toxin A-fragment, whereas the 25-kDa polypeptide must be derived from the B-fragment. Permeabilization of the cells with saponin allowed efflux of the 20-kDa fragment to occur, whereas most of the 25-kDa polypeptide remained associated with the cells. A number of compounds and conditions which protect cells against diphtheria toxin prevented the protection against Pronase E. Protection of the 25-kDa polypeptide occurred even when the transmembrane proton gradient (delta pH) was dissipated by acidification of the cytosol, whereas protection and release of the A-fragment were prevented under these conditions. Electrical depolarization and ATP depletion of the cells did not inhibit protection and release of the A-fragment. The data indicate that delta pH is required for the transfer of the A-fragment to the cytosol, whereas the insertion of part of the B-fragment into the membrane occurs at low pH, even in the absence of a delta pH.     

Insertion of diphtheria toxin B-fragment into the plasma membrane at low pH. Characterization and topology of inserted regions

When the enzymatically active A-fragment of diphtheria toxin is translocated to the cytosol, the B-fragment inserts into the membrane in such a way that a 25-kDa polypeptide becomes shielded from proteases added to the external medium. We have attempted to determine the boundaries of this polypeptide within the toxin B-fragment as well as the topology of the B-fragment in the membrane. Chemical cleavage of the 25-kDa polypeptide with hydroxylamine and o-iodosobenzoic acid yielded fragments of sizes indicating that the 25-kDa polypeptide starts at residue approximately 300 and extends to the COOH-terminal end. Experiments where the toxin was labeled with [35S]cysteine at distinct positions of the B-fragment supported this conclusion. Treatment of cells with inserted B-fragment with L-1-tosyl-amido-2-phenylethyl chloromethyl ketone-treated trypsin and with V8 protease from Staphylococcus aureus yielded protected 27- and 30-kDa fragments in addition to 25 kDa, indicating that the region 240-264 is also at the outside. The topology of the inserted B-fragment is discussed.     

Tight folding of acidic fibroblast growth factor prevents its translocation to the cytosol with diphtheria toxin as vector.

A fusion protein of acidic fibroblast growth factor and diphtheria toxin A-fragment was disulfide-linked to the toxin B-fragment. The complex bound specifically to diphtheria toxin receptors, and subsequent exposure to low pH induced the fusion protein to translocate to the cytosol. Heparin, inositol hexaphosphate and inorganic sulfate strongly increased the trypsin resistance of the growth factor part of the fusion protein, indicating tight folding, and they prevented translocation of the fusion protein to the cytosol. The data indicate that only a more disordered form of the growth factor is translocation competent.     

Translocation of diphtheria toxin to the cytosol and formation of cation selective channels.

A number of protein toxins act by translocating an enzymatically active polypeptide to the cytosol. The translocation process is best understood in the case of diphtheria toxin which binds to cell surface receptors, is then taken up by endocytosis and is subsequently translocated to the cytosol, where it inactivates elongation factor 2. The translocation of the enzymatically active part of the toxin can be induced at the level of the plasma membrane upon exposure to low pH of cells with surface-bound toxin. Receptor molecules appear to be involved in the translocation process, which also requires an inward directed H(+)-gradient and permeant anions. Cation-selective channels are formed in the membrane upon toxin entry. The B-fragment alone is much more efficient in inducing channels than the whole toxin. The current model of the translocation process is discussed.     

Peptides fused to the amino-terminal end of diphtheria toxin are translocated to the cytosol

Diphtheria toxin belongs to a group of toxic proteins that enter the cytosol of animal cells. We have here investigated the effect of NH2-terminal extensions of diphtheria toxin on its ability to become translocated to the cytosol. DNA fragments encoding peptides of 12-30 amino acids were fused by recombinant DNA technology to the 5'-end of the gene for a mutant toxin. The resulting DNA constructs were transcribed and translated in vitro. The translation products were bound to cells and then exposed to low pH to induce translocation across the cell membrane. Under these conditions all of the oligopeptides tested, including three viral peptides and the leader peptide of diphtheria toxin, were translocated to the cytosol along with the enzymatic part (A-fragment) of the toxin. Neither hydrophobic nor highly charged sequences blocked translocation. The results are compatible with a model in which the COOH-terminus of the A-fragment first crosses the membrane, whereas the NH2-terminal region follows behind. The possibility of using nontoxic variants of diphtheria toxin as vectors to introduce peptides into the cytosol to elicit MHC class I-restricted immune response and clonal expansion of the relevant CD8+ cytotoxic T lymphocytes is discussed.     

Direct Pathway from Early/Recycling Endosomes to the Golgi Apparatus Revealed through the Study of Shiga Toxin B-fragment Transport

Shiga toxin and other toxins of this family can escape the endocytic pathway and reach the Golgi apparatus. To synchronize endosome to Golgi transport, Shiga toxin B-fragment was internalized into HeLa cells at low temperatures. Under these conditions, the protein partitioned away from markers destined for the late endocytic pathway and colocalized extensively with cointernalized transferrin. Upon subsequent incubation at 37°C, ultrastructural studies on cryosections failed to detect B-fragment–specific label in multivesicular or multilamellar late endosomes, suggesting that the protein bypassed the late endocytic pathway on its way to the Golgi apparatus. This hypothesis was further supported by the rapid kinetics of B-fragment transport, as determined by quantitative confocal microscopy on living cells and by B-fragment sulfation analysis, and by the observation that actin- depolymerizing and pH-neutralizing drugs that modulate vesicular transport in the late endocytic pathway had no effect on B-fragment accumulation in the Golgi apparatus. B-fragment sorting at the level of early/recycling endosomes seemed to involve vesicular coats, since brefeldin A treatment led to B-fragment accumulation in transferrin receptor–containing membrane tubules, and since B-fragment colocalized with adaptor protein type 1 clathrin coat components on early/recycling endosomes. Thus, we hypothesize that Shiga toxin B-fragment is transported directly from early/recycling endosomes to the Golgi apparatus. This pathway may also be used by cellular proteins, as deduced from our finding that TGN38 colocalized with the B-fragment on its transport from the plasma membrane to the TGN.     

Diphtheria toxin at low pH depolarizes the membrane, increases the membrane conductance and induces a new type of ion channel in Vero cells.

Receptor-dependent translocation of diphtheria toxin across the surface membrane of Vero cells was studied using patch clamp techniques. Translocation was induced by exposing cells with surface-bound toxin to low pH. Whole cell current and voltage clamp recordings showed that toxin translocation was associated with membrane depolarization and increased membrane conductance. The conductance increase was voltage independent, with a reversal potential of approximately 15 mV. This value was unaffected by changing the Cl- gradient across the membrane and microfluorometric measurements showed that the cytosolic Ca2+ concentration was only marginally elevated by the translocation. The conductance increase is thus mainly due to monovalent cations. Exposing outside-out and cell-attached patches with bound toxin to low pH induced a new type of ion channel in the membrane. The channel current was inward at negative membrane potentials and the single channel conductance was approximately 30 pS. This value is about three times larger than for receptor-independent channels induced by diphtheria toxin or toxin fragments in artificial lipid membranes.     

Ability of the Tat basic domain and VP22 to mediate cell binding, but not membrane translocation of the diphtheria toxin A-fragment

A number of proteins are able to enter cells from the extracellular environment, including protein toxins, growth factors, viral proteins, homeoproteins, and others. Many such translocating proteins, or parts of them, appear to be able to carry with them cargo into the cell, and a basic sequence from the HIV-1 Tat protein has been reported to provide intracellular delivery of several fused proteins. For evaluating the efficiency of translocation to the cytosol, this TAT-peptide was fused to the diphtheria toxin A-fragment (dtA), an extremely potent inhibitor of protein synthesis which normally is delivered efficiently to the cytosol by the toxin B-fragment.The fusion of the TAT-peptide to dtA converted the protein to a heparin-binding protein that bound avidly to the cell surface. However, no cytotoxicity of this protein was detected, indicating that the TAT-peptide is unable to efficiently deliver enzymatically active dtA to the cytosol. Interestingly, the fused TAT-peptide potentiated the binding and cytotoxic effect of the corresponding holotoxin. We made a fusion protein between VP22, another membrane-permeant protein, and dtA, and also in this case we detected association with cells in the absence of a cytotoxic effect. The data indicate that transport of dtA into the cell by the TAT-peptide and VP22 is inefficient.     

Translocation of diphtheria toxin A-fragment to the cytosol. Role of the site of interfragment cleavage

Diphtheria toxin contains a trypsin-sensitive region with 3 closely spaced arginines in the sequence (Asn189, Arg190, Val191, Arg192, Arg193, Ser194). Cleavage of the toxin to yield A- and B-fragments ("nicking") appears to occur in a stochastic manner after either of these arginine residues. Isoelectric focusing of A-fragment prepared in vitro showed four bands of varying intensity with pI between 4.5 and 5.0, three of which could be accounted for by the three different cleavage sites. Exposure of cells with surface-bound toxin to pH less than 5.3 induces translocation of A-fragment to a position where it is shielded from external Pronase, presumably in the cytosol. A-fragment translocated in this manner had the same pI as the most acidic A-fragments, indicating that only A-fragments lacking both Arg192 and Arg193 are translocation-competent. This was confirmed by amino acid sequencing. Treatment of A-fragment with carboxypeptidase B eliminated the two bands with the highest pI while there was a concomitant increase in the bands corresponding to the two most acidic A-fragments. Such treatment of nicked diphtheria toxin increased the amount of translocated A-fragment and the ability of toxin to form cation-selective pores in the cell membrane. The site of trypsin cleavage therefore appears to be one of the factors limiting toxin entry to the cytosol.     

Elimination of the disulphide bridge in fragment B of diphtheria toxin: effect on membrane insertion, channel formation, and ATP binding

Active diphtheria toxin consists of two disulphide-linked fragments, termed A and B. Fragment B, which contains an internal disulphide bridge, facilitates translocation of the enzymatically active fragment A to the cytosol of eukaryotic cells. In this process cation-selective channels are formed. An in vitro translated full-length mutant lacking the internal disulphide bridge (A-58**) was functionally indistinguishable from its disulphide-containing counterpart (A-58) with respect to trypsin sensitivity, receptor binding, A-fragment translocation, and channel formation. In contrast, the B fragment of A-58** (B-36**) was slightly less trypsin resistant than the S-S-containing B fragment, B-36, and was approximately 300-fold less efficient than B-36 in permeabilizing cells. When first dialysed and then reconstituted with A fragment, B fragment without disulphide bridge yielded a less-active toxin than did wild-type B fragment. We conclude that the disulphide bridge in fragment B is not necessary for toxicity, as earlier believed, and that channel formation may play a role in membrane translocation.     

The pH-dependent conformational change of diphtheria toxin

Labeling by a hydrophobic photoactivatable reagent and limited proteolysis have been used to study conformational changes of diphtheria toxin related to its pH-dependent membrane insertion and translocation. TID (3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine) labels diphtheria toxin at pH 5 much more efficiently than at pH 7, both in the presence and absence of lipid vesicles. In the absence of membranes, the extent of labeling is greater and the pH dependence is stronger. As analyzed on sodium dodecyl sulfate-polyacrylamide gels and by high pressure liquid chromatography, both the A- and B-subunits and most of the cyanogen bromide fragments of the toxin are labeled by TID at acid pH. The products of trypsin cleavage of diphtheria toxin at pH 5 are different from those seen at neutral pH. Trypsin-susceptible sites were identified by gel electrophoresis of the trypsin fragments, combined with electrophoresis and high pressure liquid chromatography of CNBr digests of trypsin-treated toxin. At neutral pH, the main sites of digestion are at the junction between the A- and B-fragments and near the NH2 terminus of the A-fragment. At pH 5.2, these sites are less efficiently cut, and new sites appear near the NH2 terminus of the B-fragment, in an amphipathic portion of the sequence. Thus, even in the absence of membranes, acid pH induces a significant conformational change in diphtheria toxin. This change involves burial of some previously accessible sites, exposure of previously inaccessible sites, and the formation of hydrophobic regions over an extensive portion of the polypeptide chain.     

Diphtheria toxin-induced channels in Vero cells selective for monovalent cations

Ion fluxes associated with translocation of diphtheria toxin across the surface membrane of Vero cells were studied. When cells with surface-bound toxin were exposed to low pH to induce toxin entry, the cells became permeable to Na+, K+, H+, choline+, and glucosamine+. There was no increased permeability to Cl-, SO4(-2), glucose, or sucrose, whereas the uptake of 45Ca2+ was slightly increased. The influx of Ca2+, which appears to be different from that of monovalent cations, was reduced by several inhibitors of anion transport and by verapamil, Mn2+, Co2+, and Ca2+, but not by Mg2+. The toxin-induced fluxes of N+, K+, and protons were inhibited by Cd2+. Cd2+ also protected the cells against intoxication by diphtheria toxin, suggesting that the open cation-selective channel is required for toxin translocation. The involvement of the toxin receptor is discussed.     

Intracellular localization and degradation of diphtheria toxin

The internalization of surface-bound diphtheria toxin (DT) in BS-C-1 cells correlated with its appearance in intracellular endosomal vesicles; essentially no toxin appeared within secondary lysosomal vesicles. In contrast, internalized epidermal growth factor (EGF) was localized within both endosomal and lysosomal vesicles. Upon preincubation of cells with leupeptin, a lysosomal protease inhibitor, a threefold increase in the accumulation of EGF into lysosomes was observed. Under identical conditions, essentially all of the diphtheria toxin remained within endosomes (less than 2% of the intracellular diphtheria toxin accumulated in the lysosomal fraction), indicating that the inability to detect diphtheria toxin in lysosomes was not due to its rapid turnover within this vesicle. Following internalization of EGF or DT, up to 40% of the ligand appeared in the medium as TCA-soluble radioactivity. EGF degradation was partially leupeptin-sensitive and markedly NH4Cl-sensitive, indicating lysosomal degradation. In contrast, DT A-fragment degradation was resistant to these inhibitors, while B-fragment showed only partial sensitivity. These data suggest that the bulk of endocytosed diphtheria toxin is localized within endosomes and degraded by a pathway essentially independent of lysosomes.     

On the membrane translocation of diphtheria toxin: at low pH the toxin induces ion channels on cells.

Diphtheria toxin (DT) in acidic media forms ion-conducting channels across the plasma membrane and inhibits protein synthesis of both highly and poorly DT-sensitive cell lines. This results in loss of cell potassium and in entry of both sodium and protons with a concomitant rapid lowering of membrane potential. The pH dependency of the permeability changes is similar to that of the inhibition of cell protein synthesis. DT-induced ion channels close when the pH of the external medium is returned to neutrality and cells recover their normal monovalent cation content. Similar permeability changes were induced by two DT mutants defective either in enzymatic activity or in cell binding, but not with a mutant defective in membrane translocation. The implication of these findings for the mechanism of DT membrane translocation is discussed.     

Action of diphtheria toxin does not depend on the induction of large,stable pores across biological membranes

Summary Vero cells exposed to diphtheria toxin at pH 4.5 leak monovalent cations but not amino acids or phosphorylated metabolites; affected cells do not take up trypan blue. Monovalent cation leakage is inhibited by 1mmCd²⁺, but not by 1mmZn²⁺ or Ca²⁺. Cd²⁺ blocks calcein leakage from liposomes and closes diphtheria toxin-induced channels in lipid bilayers. It is concluded that translocation of the A fragment of diphtheria toxin across biological membranes does not depend on the formation of large stable pores, but that small Cd²⁺-sensitive pores may play a role.     

Localization of alkaline phosphatase and proteins related to intercellular junctions in rat hepatoma cell line McA-RH 7777.

We investigated the localization of alkaline phosphatase (ALP) and three proteins related to intercellular junctions in the McA-RH 7777 rat hepatoma cell line to determine if the formation of junctions between adjacent McA-RH 7777 cells triggers translocation of ALP from cytoplasm to the plasma membrane. Contact between adjacent McA-RH 7777 cells promotes translocation of ALP from the Golgi area of the cytoplasm to the plasma membrane, and also promotes translocation of two proteins, E-cadherin and ZO-1, related to intercellular junctions, from cytoplasm to the plasma membrane.     

Injection of Pseudomonas aeruginosa Exo toxins into host cells can be modulated by host factors at the level of translocon assembly and/or activity

Pseudomonas aeruginosa type III secretion apparatus exports and translocates four exotoxins into the cytoplasm of the host cell. The translocation requires two hydrophobic bacterial proteins, PopB and PopD, that are found associated with host cell membranes following infection. In this work we examined the influence of host cell elements on exotoxin translocation efficiency. We developed a quantitative flow cytometry based assay of translocation that used protein fusions between either ExoS or ExoY and the ?-lactamase reporter enzyme. In parallel, association of translocon proteins with host plasma membranes was evaluated by immunodetection of PopB/D following sucrose gradient fractionation of membranes. A pro-myelocytic cell line (HL-60) and a pro-monocytic cell line (U937) were found resistant to toxin injection even though PopB/D associated with host cell plasma membranes. Differentiation of these cells to either macrophage- or neutrophil-like cell lines resulted in injection-sensitive phenotype without significantly changing the level of membrane-inserted translocon proteins. As previous in vitro studies have indicated that the lysis of liposomes by PopB and PopD requires both cholesterol and phosphatidyl-serine, we first examined the role of cholesterol in translocation efficiency. Treatment of sensitive HL-60 cells with methyl-?-cyclodextrine, a cholesterol-depleting agent, resulted in a diminished injection of ExoS-Bla. Moreover, the PopB translocator was found in the membrane fraction, obtained from sucrose-gradient purifications, containing the lipid-raft marker flotillin. Examination of components of signalling pathways influencing the toxin injection was further assayed through a pharmacological approach. A systematic detection of translocon proteins within host membranes showed that, in addition to membrane composition, some general signalling pathways involved in actin polymerization may be critical for the formation of a functional pore. In conclusion, we provide new insights in regulation of translocation process and suggest possible cross-talks between eukaryotic cell and the pathogen at the level of exotoxin translocation.     

The p21 Rho-activating toxin cytotoxic necrotizing factor 1 is endocytosed by a clathrin-independent mechanism and enters the cytosol by an acidic-dependent membrane translocation step

Cytotoxic necrotizing factor 1 (CNF1), a protein produced by pathogenic strains of Escherichia coli, activates the p21 Rho-GTP-binding protein, inducing a profound reorganization of the actin cytoskeleton. CNF1 binds to its cell surface receptor on HEp-2 cells with high affinity (K(d) = 20 pM). In HEp-2 cells the action of CNF1 is not blocked in the presence of filipin, a drug described to reduce cholera toxin internalization by the caveolae-like mechanism. Moreover, HEp-2 cells, which express a dominant negative form of proteins that impair the formation of clathrin coated-vesicles and internalization of transferrin (Eps15, dynamin or intersectin-Src homology 3), are still sensitive to CNF1. In this respect, the endocytosis of CNF1 is similar to the plant toxin ricin. However, unlike ricin toxin, CNF1 does not cross the Golgi apparatus and requires an acidic cell compartment to transfer its enzymatic activity into the cytosol in a manner similar to that required by diphtheria toxin. As shown for diphtheria toxin, the pH-dependent membrane translocation step of CNF1 could be mimicked at the level of the plasma membrane by a brief exposure to a pH of 相似文献