Evidence that diphtheria toxin and modeccin enter the cytosol from different vesicular compartments

Inhibition of protein synthesis in Vero cells was measured at different periods of time after treatment with diphtheria toxin and the related plant toxin modeccin. Diphtheria toxin acted much more rapidly than modeccin. Cells were protected against both toxins with antiserum as well as with agents like NH4Cl, procaine, and the ionophores monensin, FCCP, and CCCP, which increase the pH of intracellular vesicles. Antiserum, which is supposed to inactivate toxin only at the cell surface, protected only when it was added within a short period of time after modeccin. Compounds that increase the pH of intracellular vesicles, protected even when added after 2 h, indicating that modeccin remains inside vesicles for a considerable period of time before it enters the cytosol. After addition of diphtheria toxin to the cells, compounds that increase the pH of intracellular vesicles protected only approximately to the same extent as antitoxin. This indicates that after endocytosis diphtheria toxin rapidly enters the cytosol. At 20 degrees C, the cells were more strongly protected against modeccin than against diphtheria toxin. The residual toxic effect of diphtheria toxin at 20 degrees C could be blocked with NH4Cl whereas this was not the case with modeccin. This indicates that at 20 degrees C the uptake of diphtheria toxin occurs by the normal route, whereas the uptake of modeccin occurs by a less efficient route than that dominating at 37 degrees C. The results indicate that after endocytosis diphtheria toxin rapidly enters the cytosol from early endosomes with low pH (receptosomes). Modeccin enters the cytosol much more slowly, possibly after fusion of the endocytic vesicles with another compartment.     

Diphtheria toxin entry into cells is facilitated by low pH

At neutral pH, NH4Cl and chloroquine protected cells against diphtheria toxin. A brief exposure of the cells to low pH (4.5-5.5) at 37 degrees completely abolished this protection. When, to cells preincubated with diphtheria toxin and NH4Cl, neutralizing amounts of anti-diphtheria toxin were added before the pH was lowered, the toxic effect was considerably reduced, but it was not completely abolished. A much stronger toxic effect was seen when antibodies were added immediately after incubation at low pH. Upon a short incubation with diphtheria toxin at low pH, the rate of protein synthesis in the cells decreased much faster than when the normal pH was maintained. The data suggest that, at low pH, diphtheria toxin (or its A fragment) penetrates directly through the surface membrane of the cell. The possibility is discussed that, when the medium has a neutral pH, the entry of diphtheria toxin involves adsorptive endocytosis and reduction of the pH in the vesicles possibly by fusion with lysosomes. Low pH did not facilitate the entry of the closely related toxins abrin, ricin, and modeccin.     

Active target cell processes, possibly involving receptor-mediated endocytosis, are critical for expression of cytotoxicity by natural killer cell-derived cytolytic factor

Inhibitors of energy metabolism, 2-deoxyglucose and cyanide were shown to inhibit NKCF-mediated lysis of L929 target cells at the same molar concentrations that effectively inhibited cellular ATP levels and the toxic effects of pseudomonas toxin A. In addition, inhibitors of receptor-mediated endocytosis, cytochalasin B, a microtubule disrupter, and trifluoperazine, an inhibitor of clathrin-coat formation, inhibited NKCF-mediated lysis and expression of pseudomonas toxin activity, but had little effect upon cellular ATP. Lysomotropic agents chloroquine, ammonium chloride, and dansylcadavarine also inhibited both NKCF-mediated lysis and pseudomonas toxin activity. These results are similar to those involving diphtheria toxin and the plant toxins abrin, modeccin, and ricin, whose mode of action involves inhibition of protein synthesis following receptor-mediated endocytosis. However, it was determined that NKCF did not cause a decrease in the rate of protein synthesis up to the time of cell death. These results suggest that active target cell processes (possibly involving receptor-mediated endocytosis of NKCF) must occur for target cell lysis to be completed.     

Effects of retinoids and phorbol esters on the sensitivity of different cell lines to the polypeptide toxins modeccin, abrin, ricin and diphtheria toxin.

The effects of retinoic acid and 12-O-tetradecanoylphorbol 13-acetate on the sensitivities of a number of cell lines to the toxins modeccin, abrin, ricin and diphtheria toxin were studied. Retinoic acid and some other retinoids were found to protect a number of the cell lines against the toxins. HeLa cells that were protected bound much more retinoic acid than L-cells that were not protected. The tumour promoter 12-O-tetradecanoylphorbol 13-acetate was found to increase the sensitivity of cells to abrin, ricin and modeccin in the absence as well as in the presence of retinoic acid. Neither retinoic acid nor 12-O-tetradecanoylphorbol 13-acetate affected the extent of binding and pinocytotic uptake of toxins by the cells. Apparently retinoic acid and 12-O-tetradecanoylphorbol 13-acetate interfere with the entry of the toxins through the cell membrane.     

The entry of diphtheria toxin into the mammalian cell cytoplasm: evidence for lysosomal involvement

Lysosomotropic amines, such as ammonium chloride, are known to protect cells from the cytotoxic effects of diphtheria toxin. These drugs are believed to inhibit the transport of the toxin from a receptor at the cell exterior into the cytoplasm where a fragment of the toxin arrests protein synthesis. We studied the effects of lysosomotropic agents on the cytotoxic process to better understand how the toxin enters the cytoplasm. The cytotoxic effects of diphtheria toxin were not inhibited by antitoxin when cells were preincubated at 37 degrees C with toxin and ammonium chloride, exposed to antitoxin at 4 degrees C, washed to relieve the ammonium chloride inhibition, and finally warmed to 37 degrees C. The antigenic determinants of the toxin were, therefore, either altered or sheltered. It is likely that the combination of ammonium chloride and a low temperature trapped the toxin in an intracellular vesicle from which the toxin could proceed to the cytoplasm. Because lysosomotropic amines raise the pH within acidic intracellular vesicles, such as lysosomes, they could trap the toxin within such a vesicle if an acidic environment were necessary for the toxin to penetrate into the cytoplasm. We simulated acidic conditions which the toxin might encounter by exposing cells with toxin bound to their surface to acidic medium. We then measured the effects of lysosomotropic amines on the activity of the toxin to see if the acidic environment substituted for the function normally inhibited by the drugs. The drugs no longer protected the cells. This suggests that exposing the toxin to an acidic environment, such as that found within lysosomes, is an important step in the penetration of diphtheria toxin into the cytoplasm.     

Enhancement of cytotoxicity of modeccin by nigericin in modeccin-resistant mutant cell lines

We have isolated a Chinese hamster ovary cell mutant (DMPR-2) simultaneously resistant to diphtheria toxin and modeccin. In addition to the increased resistance to these two toxins used in the selection, this mutant is more resistant to Pseudomonas toxin and hypersensitive to ricin than the parental cell line. In contrast to the wild-type cells in which nigericin protects cells from modeccin, the cytotoxicity of modeccin in the DMPR-2 mutant is enhanced by nigericin. We have also studied the effects of nigericin and NH4Cl on the cytotoxicity of modeccin in a modeccin-resistant mutant of HeLa cells (ModRI). The cytotoxicity of modeccin is enhanced by nigericin in ModRI mutant cells, in contrast to the protection of modeccin cytotoxicity by nigericin in the parental HeLa cells. Our results suggest that modeccin can reach the cytosol of mammalian cells by two distinct routes; the major route requires endosomal acidification and the minor route is activated by nigericin.     

Monensin blocks the transport of diphtheria toxin to the cell cytoplasm

Lysosomotropic amines are believed to inhibit the transport of diphtheria toxin to the cell cytoplasm by raising the pH within intracellular vesicles. If so, then other drugs that dissipate intracellular proton gradients should have a similar effect on toxin transport. We found that monensin, a proton ionophore unrelated to lysosomotropic amines, is a potent inhibitor of the cytotoxic effect of diphtheria toxin. Monensin appears to block the escape of endocytosed toxin from a vesicle to the cytoplasm. Monensin fails to protect cells from the effects of diphtheria toxin that is bound to the cell surface and exposed to acidic medium, suggesting that the step normally blocked by the drug is circumvented under these conditions. The inhibition of toxin transport caused by monensin could not be relieved when monensin was replaced by ammonium chloride, nor when ammonium chloride was again replaced by monensin. This suggests that both drugs block the same step of toxin transport. The effect of monensin on the transport of diphtheria toxin to the cytoplasm is consistent with the proposal (Draper and Simon. 1980. J. Cell Biol. 87:849-854; Sandvig and Olsnes. 1980. J. Cell Biol. 87:828-832) that the toxin is endocytosed and then, in response to an acidic environment, penetrates through the membrane of an intracellular vesicle to reach the cytoplasm.     

Disruption of the Golgi apparatus by brefeldin A inhibits the cytotoxicity of ricin, modeccin, and Pseudomonas toxin

We have studied the cytotoxicity of ricin in cells treated with brefeldin A (BFA), which dramatically disrupts the structure of the Golgi apparatus causing Golgi content and membrane to redistribute to the ER. BFA inhibits the cytotoxicity of ricin in Chinese hamster ovary, normal rat kidney, and Vero cells and abolishes the enhancement of ricin cytotoxicity by NH4Cl, nigericin, swainsonine, and tunicamycin or by a mutation in endosomal acidification. BFA protects cells from the cytotoxicities of modeccin and Pseudomonas toxin, but has no effect on the intoxication by diphtheria toxin. Pretreatment of BFA does not protect cells from ricin treatment in the absence of BFA. Our results suggest that ricin, modeccin, and Pseudomonas toxin share a common pathway of intracellular transport from endosomes to the Golgi region where they are released into the cytosol. In contrast, the lack of protection of Vero cells from diphtheria toxin by BFA indicates that diphtheria toxin is released from acidified endosomes without involving the Golgi region.     

Mode of inhibition of diphtheria toxin by ammonium chloride

Kim, K. (University of Washington, Seattle), and N. B. Groman. Mode of inhibition of diphtheria toxin by ammonium chloride. J. Bacteriol. 90:1557-1562. 1965.-The inhibition of diphtheria toxin by ammonium salts was independent of toxin concentration over a 100-fold range of toxin. Inhibition by minimal concentrations of ammonium chloride was abolished by lowering the pH, indicating that free ammonia is the active form of inhibitor. A single addition of ammonium chloride inhibited toxin for a limited period of time, but periodic readdition of the ammonium salt was required to sustain inhibition indefinitely in the absence of antitoxin. Toxin was not destroyed and its adsorption occurred equally well in the presence or absence of ammonium chloride. Preadsorbed toxin was also effectively inhibited by the addition of ammonium chloride. Inhibited toxin remained accessible to antitoxin neutralization. Attempts to reverse ammonia inhibition by the addition of succinate or reduced nicotinamide adenine dinucleotide were unsuccessful. Attempts to inhibit toxin by interfering with active transport were also unsuccessful.     

Receptor-mediated internalization of Pseudomonas toxin by mouse fibroblasts

Pseudomonas exotoxin (PE) was used as a probe to study the mechanism by which protein ligands are internalized by mammalian cells. Both biochemical and electron microscopic methods were used to look at the internalization of PE by mouse LM cell fibroblasts. Our data suggest that PE enters cells by receptor-mediated endocytosis, a process previously thought to be restricted to the entry of biologically significant molecules such as lysosomal enzymes and peptide hormones. Biochemical studies showed that methylamine (20 mM) and chloroquine (10 microM) protected LM cells from the action of PE. Full protection was observed if methylamine or chloroquine was added to the monolayers simultaneously with toxin or if they were added up to 10 min after toxin binding. Later addition of amine or chloroquine afforded partial protection to the monolayers. With immunoelectron microscopy we observed that in the cold toxin bound diffusely to the cell surface but was rapidly internalized when cells were warmed to 37 degrees C. In the presence of methylamine, chloroquine or ammonium chloride, internalization did not occur. We propose that PE enters mouse fibroblasts by receptor-mediated endocytosis and that chloroquine and methylamine, agents which are known to block this process, prevent expression of toxicity.     

The Different Behavior of Diphtheria Toxin, Modeccin and Ricin in HeLa Cells Infected with Trypanosoma cruzi

ABSTRACT. We have studied the action of diphtheria toxin, modeccin and ricin on HeLa cells infected by Trypanosoma cruzi . Parasitized HeLa cells were resistant to diphtheria toxin and modeccin, whereas non-parasitized cells from the same cultures and control cultures showed cytopathological alterations. Protein synthesis, assayed by the incorporation of labelled methionine, diminished in toxin-treated control cultures but remained unaltered in the infected ones, compared to synthesis by untreated infected cells. Ricin, on the other hand, is a toxin that enters the cytoplasm by endocytosis. It has greater cytopathological effects in parasitized cells than in non-parasitized ones from the same cultures or uninfected control cells. Protein synthesis was inhibited in infected cultures treated with ricin.     

Effect of potassium depletion of cells on their sensitivity to diphtheria toxin and pseudomonas toxin

When Vero cells were depleted of potassium, the cells were protected against diphtheria toxin. Potassium depletion of Vero cells strongly reduced the binding of the toxin to cell surface receptors. Likewise, potassium depleted L-cells were protected against pseudomonas toxin. Diphtheria toxin binding was completely restored upon addition of potassium to the cells. This restoration was not prevented by inhibition of protein synthesis by cycloheximide. When cells were depleted of potassium in the presence of metabolic inhibitors, and then treated with diphtheria toxin, protein synthesis was reduced to the same extent as in cells with normal intracellular level of potassium. The results indicate that potassium depletion of Vero cells reduces the ability of the cells to bind diphtheria toxin by an ATP requiring process, and that binding, endocytosis and transfer of diphtheria fragment A across the membrane may occur at low intracellular levels of potassium.     

Evidence that membrane phospholipids and protein are required for binding of diphtheria toxin in Vero cells

Treatment with phospholipase C strongly protected monkey kidney (Vero) cells against diphtheria toxin and reduced the ability of the cells to bind 125I-labelled toxin. Treatment with phospholipase D and with trypsin also protected the cells, although to a lesser extent. Phospholipase A2 had no protective effect. Phospholipase C also protected fetal hamster kidney cells against the toxin. After removal of the enzymes, as well as after treatment of the cells with 4-acetamide 4'-isothiocyanostilbene 2,2'-disulfonic acid, diphtheria toxin binding capability was restored slowly, apparently by a process requiring protein synthesis, since cycloheximide blocked the restoration. The data indicate that both phospholipids and protein are involved in the binding sites for diphtheria toxin.     

Internalization of Clostridium difficile cytotoxin into cultured human lung fibroblasts

In cultured human lung fibroblasts treated with Clostridium difficile cytotoxin, the latency before appearance of the cytopathogenic effect was dose-related with a minimum of 45 min. At 37°C, the toxin was accessible on all cells to inactivation with trypsin or neutralization with antitoxin during the first tenth of the latency. At 0°C, the toxin was accessible considerably longer. The cytopathogenic effect was reversibly prevented by the lysosomotropic agents chloroquine and ammonium chloride, which had to be added within one-fifth of the latency to protect all cells. In the presence of chloroquine, but not of ammonium chloride, the time period during which the toxin remained amenable to neutralization with antitoxin was prolonged. The protective effect of ammonium chloride was not influenced by dropping the extracellular pH to 4.5, but that of chloroquine was abolished. The expression of the intoxication was not affected by inhibitors of the DNA, RNA or protein synthesis. Inhibitors of the energy metabolism prevented the cytopathogenic effect when added before the last phase of the latency. The results suggest that expression of the cytopathogenic effect requires internalization of the toxin, and that metabolic energy but no macromolecular synthesis is needed for the action of the toxin after this internalization.     

Internalization of Clostridium difficile cytotoxin into cultured human lung fibroblasts

In cultured human lung fibroblasts treated with Clostridium difficile cytotoxin, the latency before appearance of the cytopathogenic effect was dose-related with a minimum of 45 min. At 37 degrees C, the toxin was accessible on all cells to inactivation with trypsin or neutralization with antitoxin during the first tenth of the latency. At 0 degrees C, the toxin was accessible considerably longer. The cytopathogenic effect was reversibly prevented by the lysosomotropic agents chloroquine and ammonium chloride, which had to be added within one-fifth of the latency to protect all cells. In the presence of chloroquine, but not of ammonium chloride, the time period during which the toxin remained amenable to neutralization with antitoxin was prolonged. The protective effect of ammonium chloride was not influenced by dropping the extracellular pH to 4.5, but that of chloroquine was abolished. The expression of the intoxication was not affected by inhibitors of the DNA, RNA or protein synthesis. Inhibitors of the energy metabolism prevented the cytopathogenic effect when added before the last phase of the latency. The results suggest that expression of the cytopathogenic effect requires internalization of the toxin, and that metabolic energy but no macromolecular synthesis is needed for the action of the toxin after this internalization.     

Entry of diphtheria toxin-protein A chimeras into cells

Fusion proteins consisting of diphtheria toxin and a duplicated Fc-binding domain of protein A were made in vitro after amplification of the DNA template by the polymerase chain reaction. The fusion proteins bound avidly to Vero cells coated with antibodies. A fusion protein containing full-length diphtheria toxin was toxic at lower concentrations than diphtheria toxin alone, apparently due to more efficient binding. The enzymatic part of the fusion protein was translocated across the surface membrane upon exposure to low pH. Like authentic diphtheria toxin, the fusion protein formed cation selective channels at low pH. Excess amounts of unlabeled diphtheria toxin inhibited formation of pronase-protected fragments derived from radiolabeled fusion protein. Furthermore, conditions that down-regulate the diphtheria toxin receptors reduced the sensitivity of the cells to the fusion protein, supporting the notion that authentic diphtheria toxin receptors are required. At temperatures below 18 degrees C the toxicity of the fusion protein was strongly reduced, whereas there was no temperature block for authentic diphtheria toxin. Brefeldin A protected Vero cells against the fusion protein but not against diphtheria toxin. The results indicate that the diphtheria toxin receptor is required for efficient toxin translocation even under conditions where the toxin is bound by an alternate binding moiety, and they suggest that the intracellular routing of the fusion protein is different from that of diphtheria toxin.     

Preparation and properties of a hybrid toxin of modeccin A-chain and ricin B-chain

Hybrid molecules were prepared from the A- and B-chains of the two toxic lectins ricin and modeccin by dialyzing mixtures of isolated chains to allow a disulfide bridge to be formed between them. Whereas the hybrid consisting of ricin A-chain and modeccin B-chain was non-toxic, the converse hybrid, modeccin A-chain/ricin B-chain, was even more toxic to Vero cells than were the parent toxins, native ricin and modeccin. A number of drugs (NH₄Cl, monensin, trifluoperazine, verapamil, ionophore A23187) which protect cells against modeccin, but not against ricin, protected to some extent against the toxic hybrid, but less so than against native modeccin. The possibility is discussed that the modeccin A-chain of the hybrid may enter the cytosol by two routes, one which is highly efficient and identical to that used by native modeccin and another less efficient one which cannot be used by native modeccin.     

Requirement of a transmembrane pH gradient for the entry of diphtheria toxin into cells at low pH

The effects of acidification of the cytosol and of electrical depolarization on the entry of diphtheria toxin were studied. Entry of the toxin from the cell surface was induced by low pH, and the presence of the toxin in the cytosol was monitored as toxin-induced inhibition of protein synthesis. To reduce the membrane potential the cells were incubated in a buffer containing a high concentration of potassium. The cytosol was acidified either by incubating the cells with acetic acid, by incubating them with ammonium chloride which was subsequently removed in the presence of amiloride to prevent pH regulation by the Na+/H+ exchanger, or by incubating the cells in isotonic KCl in the presence of nigericin and valinomycin. The results showed that when the cytosol was acidified by either method toxin entry was inhibited, while a reduction in the membrane potential did not strongly interfere with the entry. A pH gradient across the membrane of at least 1 pH unit was required for entry. Possibly this gradient acts as a driving force for diphtheria toxin entry.     

Identification of a cold-sensitive step in the mechanism of modeccin action

Modeccin is a toxic lectin that arrests protein synthesis in mammalian cells by catalytically inactivating 60 S ribosomes. To interact with 60 S ribosomes, the catalytic subunit of modeccin must pass through a membrane and enter the cytosol. Two known steps in the mechanism of modeccin action are the receptor-mediated internalization of the toxin into vesicles and a second step that requires a low pH within the vesicles. We report here another step required for modeccin to arrest protein synthesis, identified because this step was blocked at 15 degrees C. Modeccin traveling from cell surface receptors to the cytosol at 37 degrees C passed the low pH step within vesicles in a minimum time of 15 min after endocytosis and reached the cold-sensitive step 15 min later. There was no effect on protein synthesis until about 45 min after modeccin had passed the cold-sensitive step, suggesting that the toxin was still within vesicles at the time of the cold-sensitive event. The low temperature at which modeccin failed to reach the cytosol correlated with an apparent low temperature block in the transfer of endocytosed modeccin to lysosomes. The possibility is discussed that modeccin does not penetrate to the cytosol directly from endocytic vesicles.     

Effects of various basic compounds on the degradation of formaldehyde-treated 125I-labeled bovine serum albumin in mouse liver lysosomes

The effect of various basic compounds on degradation of formaldehyde-treated 125I-bovine serum albumin (denatured 125I-BSA) in livers of mice was studied in detail. Five basic compounds (BTTB, chloroquine, methylamine, ammonium chloride, and vinblastine) were tested. All the basic compounds inhibited the degradation of exogenous protein in lysosomes. When p-biphenylmethyl-(dl-tropyl-alpha-tropinium)bromide (BTTB) was used, the most effective inhibition was obtained at the concentration of 3.2 mM. Also, vinblastine, a well-known inhibitor of microtubular function, inhibited the degradation of an exogenous protein to the similar extent as that of chloroquine. The inhibition of protein degradation caused by BTTB closely related to the uptake of BTTB into lysosomes. It is supposed that BTTB accumulates in lysosomes and that it inhibits the hydrolytic enzyme by neutralizing intralysosomal pH. Furthermore, it is supposed that BTTB, a quaternary ammonium compound, becomes a useful tool in the study of protein degradation in lysosomes as well as the typically lysosomotropic compounds (chloroquine, ammonium chloride, and methylamine).