Interactions between diphtheria toxin entry and anion transport in Vero cells. IV. Evidence that entry of diphtheria toxin is dependent on efficient anion transport

Entry of prebound diphtheria toxin at low pH occurred rapidly in the presence of isotonic NaCl, NaBr, NaSCN, NaI, and NaNO3, but not in the presence of Na2SO4, 2-(N-morpholino)ethanesulfonic acid neutralized with Tris, or in buffer osmotically balanced with mannitol. SCN- was the most efficient anion to facilitate entry. Uptake studies with radioactively labeled anions showed that SCN- was transported into cells 3 times faster than Cl-, while the entry of SO2-4 occurred much more slowly. The anion transport inhibitors 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid and piretanide inhibited entry at low pH even in the presence of permeant anions. When cells with bound toxin were exposed to low pH in the absence of permeant anions, then briefly exposed to neutral pH and subsequently exposed to pH 4.5 in the presence of isotonic NaCl, toxin entry was induced. The data indicate that efficient anion transport at the time of exposure to low pH is required for entry of surface-bound diphtheria toxin into the cytosol. Since insertion of diphtheria toxin into the membrane occurs even in the absence of permeant anions, the results indicate that low pH is required not only for insertion of fragment B into the membrane, but also for the subsequent entry of fragment A into the cytosol.     

Purification of diphtheria toxin receptor from Vero cells

Diphtheria toxin receptor has been solubilized from Vero cell membranes with octyl beta-D-glucoside. CRM197, the product of a mutated diphtheria toxin gene, was used for the identification of the receptor. The binding activity of the solubilized receptor was assayed by precipitating the receptor with acetone in the presence of phospholipids and carrier proteins. The solubilized receptor was purified by the combination of several chromatographic steps in the presence of the detergent, resulting in about a 10(6)-fold purification of the receptor. The purified receptor showed essentially a single band of 14.5 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. When partially purified receptor fractions were subjected to ligand blotting analysis using 125I-CRM197 as the probe, the 14.5-kDa protein and a few minor protein bands were identified as diphtheria toxin-binding molecules. These results show clearly that the 14.5-kDa protein is the diphtheria toxin receptor, or at least the major diphtheria toxin-binding molecule. When partially purified receptor was applied to a Sephacryl S-300 column in the presence of detergent, the receptor was eluted in the fractions corresponding to the 60-90-kDa size range. This suggests that the protein forms a complex with itself or with another protein.     

Decreased sensitivity to diphtheria toxin of Vero cells cultured in serum-free medium.

Vero cell cultures are used in the quality control of Diphtheria vaccines: to estimate vaccine potency and to determine residual toxicity and reversion to toxicity. The impact of replacing foetal calf serum containing medium (SCM) by serum free media (SFM) on the sensitivity of Vero cells to Diphtheria Toxin was studied. Compared to SCM, SFM showed an eight-fold decrease in sensitivity to Diphtheria Toxin. This decrease was almost immediate, indicating that this phenomenon was not caused by a change in membrane structure or protein expression. We investigated the effect of SFM on Diphtheria Toxin in order to determine the cause of the decrease in sensitivity. Our results show that oligopeptides, which are often used in SFM as part of the replacement of foetal calf serum, are the most likely cause.     

Identification of diphtheria toxin receptor and a nonproteinous diphtheria toxin-binding molecule in Vero cell membrane

Two substances possessing the ability to bind to diphtheria toxin (DT) were found to be present in a membrane fraction from DT-sensitive Vero cells. One of these substances was found on the basis of its ability to bind DT and inhibit its cytotoxic effect. This inhibitory substance competitively inhibited the binding of DT to Vero cells. However this inhibitor could not bind to CRM197, the product of a missense mutation in the DT gene, and did not inhibit the binding of CRM197 to Vero cells. Moreover, similar levels of the inhibitory activity were observed in membrane fractions from DT-insensitive mouse cells, suggesting the inhibitor is not the DT receptor which is specifically present in DT-sensitive cells. The second DT-binding substance was found in the same Vero cell membrane preparation by assaying the binding of 125I-labeled CRM197. Such DT-binding activity could not be observed in membrane preparation from mouse L cells. From competition studies using labeled DT and CRM proteins, we conclude that this binding activity is due to the surface receptor for DT. Treatment of these substances with several enzymes revealed that the inhibitor was sensitive to certain RNases but resistant to proteases, whereas the DT receptor was resistant to RNase but sensitive to proteases. The receptor was solubilized and partially purified by chromatography on CM-Sepharose column. Immunoprecipitation and Western blotting analysis of the partially purified receptor revealed that a 14.5-kD protein is the DT receptor, or at least a component of it.     

Effect of ammonium chloride on receptor-mediated uptake of diphtheria toxin by Vero cells

The mechanism of NH₄Cl-mediated protection of Vero cells from diphtheria toxin was studied. In the presence of protective concentrations of NH₄Cl, Vero cells bound, internalized, and degraded radiolabeled diphtheria toxin at the same rate and to the same extent as did the control cells. However, in experiments where specific antibody was added to NH₄Cl-treated cells, a fraction of potentially lethal toxin molecules was maintained in a position accessible to antibody neutralization. This suggests the existence of two processing mechanisms for diphtheria toxin: a non-productive bulk degradation pathway and a productive NH₄Cl-sensitive pathway by which active fragment is eventually delivered to the cytoplasm.     

Interactions between diphtheria toxin entry and anion transport in Vero cells. II. Inhibition of anion antiport by diphtheria toxin

When cells with surface-bound diphtheria toxin were exposed to pH 4.5, the toxin became shielded against lactoperoxidase-catalyzed radioiodination, indicating that the toxin was inserted into the membrane. Cells thus treated had strongly reduced ability to take up 36Cl-, 35SO4(2-), and [14C]SCN-. The reduction of chloride uptake was strongest at neutral pH, whereas that of sulfate was strongest at acidic pH. Lineweaver-Burk plots indicated that the toxin treatment reduced the Jmax but not the Km for the anions. The toxin also inhibited the NaCl-stimulated efflux of 35SO4(2-), indicating that the toxin inhibits the antiporter. No inhibition was found when toxin-treated cells were not exposed to low pH, whereas exposure to pH 4.5 for 20 s induced close to maximal inhibition. Half-maximal inhibition was obtained after exposure to pH 5.4. The concentration of diphtheria toxin required to obtain maximal inhibition (0.3 micrograms/ml) was sufficient to ensure close to maximal toxin binding to the cells. Even in ATP-depleted cells and in the absence of permeant anions, low pH induced inhibition of anion antiport in toxin-treated Vero cells. There was no measurable inhibition of anion antiport in cells with little or no ability to bind the toxin.     

Interactions between diphtheria toxin entry and anion transport in Vero cells. I. Anion antiport in Vero cells

In sodium-free buffer of low ionic strength, the uptake of chloride and sulfate in Vero cells was found to occur mainly by antiport which was very sensitive to inhibition by 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid. Efflux of anions from the cells appeared to energize the uptake. While the uptake of Cl- occurred over a wide pH range, that of SO4(2-) showed a clear maximum at pH 6-7. The rate of efflux of 36Cl- and 35SO4(2-) was strongly increased by the presence of permeant anions in the efflux buffer. Preincubation of the cells at slightly alkaline pH strongly increased the rate of C1- efflux into buffers nominally free of permeant anions, as well as the efflux by exchange. This increase did not occur if the cells were depleted for ATP during the preincubation. Depolarization of the cells reduced the rate of efflux into buffers without permeant anions, indicating that the efflux is at least partly due to net, electrogenic, anion transport. The efflux by antiport was not affected by manipulations of the membrane potential, indicating electroneutral exchange. The uptake and efflux were increased to the same extent with increasing temperature, the activation energies were Ea = 25 kcal/mol of Cl- and Ea = 12 kcal/mol of SO4(2-). Similar anion antiport appears to occur in L, baby hamster kidney, and HeLa S3 cells.     

Diphtheria toxin receptor. Identification of specific diphtheria toxin-binding proteins on the surface of Vero and BS-C-1 cells

The biochemical characteristics of specific receptor molecules for diphtheria toxin on the surface of two toxin-sensitive cell lines (Vero and BS-C-1) were examined. Diphtheria toxin was found to bind to a number of different proteins in Nonidet P-40 solubilized extracts of 125I-labeled cells. In contrast, permitting diphtheria toxin to bind first to labeled intact cells, which were subsequently solubilized and subjected to immunoprecipitation with anti-diphtheria toxin, resulted in a far more restricted profile of diphtheria toxin-binding proteins that possessed Mrs in the range of 10,000-20,000. Direct chemical cross-linking of radioiodinated diphtheria toxin to cell surface proteins resulted in the appearance of several predominant bands possessing Mrs of approximately 80,000. The Mr approximately 80,000 complexes were shown to be composed of radiolabeled diphtheria toxin (Mr 60,000) and unlabeled Mr approximately 20,000 cellular proteins. These complexes were judged to be a result of specific binding in that their appearance could be preferentially inhibited by the addition of a 100-fold excess of unlabeled diphtheria toxin. The formation of the Mr approximately 80,000 complexes was sensitive to prior trypsin treatment of the cells and to known inhibitors of diphtheria toxin binding. Furthermore, prior incubation of the cells with diphtheria toxin at 37 degrees C ("down regulation") markedly and specifically reduced the subsequent formation of the Mr approximately 80,000 cross-linked complexes, and these down-regulated cells were less sensitive to diphtheria toxin in cytotoxicity assays. Further incubation of down-regulated cells at 37 degrees C restored their ability to form Mr approximately 80,000 complexes; this regeneration requires protein synthesis and restores the cells' sensitivity to diphtheria toxin-mediated cytotoxicity. These results strongly suggest that a Mr 10,000-20,000 cell surface protein is, or constitutes a portion of, the functional diphtheria toxin receptor.     

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.     

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.     

Binding properties of diphtheria toxin to cells are altered by mutation in the fragment A domain

CRM197, CRM176, and CRM228 are products of single or multiple missense mutations in the diphtheria toxin gene. CRM197 differs from wild-type toxin in 1 amino acid residue of the fragment A region, and also CRM176 and CRM228 have amino acid substitution(s) in fragment A. We compared the binding properties of CRM197 to toxin-sensitive Vero cells with those of diphtheria toxin and other CRMs. Nicked CRM197 is about 50 times more effective than intact CRM197 in inhibiting the action of diphtheria toxin on sensitive cells, as shown by inhibition of diphtheria toxin cytotoxicity or inhibition of binding of 125I-diphtheria toxin. The binding of native toxin or other CRMs was not significantly affected by nicking. Moreover, the binding of CRM197 to cells was unaffected by ATP, although ATP clearly inhibits binding of diphtheria toxin, CRM176, and CRM228. Two kinds of hybrid protein were formed using fragment B of CRM197: one with fragment A of diphtheria toxin and one with fragment A of CRM228. ATP inhibited the binding of these hybrid proteins. Furthermore, the affinities of these hybrid proteins for diphtheria toxin-sensitive cells were the same as that of native toxin. Thus, it was concluded that the altered binding properties of CRM197 were due to alteration of fragment A and what the interaction of diphtheria toxin with ATP involves both fragments. The results also suggest that fragment A plays a role in diphtheria toxin-receptor interaction.     

Binding and uptake of diphtheria toxin by toxin-resistant Chinese hamster ovary and mouse cells.

We investigated two phenotypically distinct types of diphtheria toxin-resistant mutants of Chinese hamster cells and compared their resistance with that of naturally resistant mouse cells. All are resistant due to a defect in the process of internalization and delivery of toxin to its target in the cytosol, elongation factor 2. By cell hybridization studies, analysis of cross-resistance, and determination of specific binding sites for 125I-labeled diphtheria toxin, we showed that these cell strains fall into two distinct complementation groups. The Dipr group encompasses Chinese hamster strains that are resistant only to diphtheria toxin, as well as mouse LM cells. These strains possess a normal complement of high-affinity binding sites for diphtheria toxin, but these receptors are unable to deliver active toxin fragment A to the cytosol. Cells of the DPVr group have a broader spectrum of resistance, including Pseudomonas exotoxin A and several enveloped viruses as well as diphtheria toxin. In these studies, which investigate the resistance of these cells to diphtheria toxin, we demonstrate that they possess a reduced number of specific binding sites for this toxin and behave, phenotypically, like cells treated with the proton ionophore monensin. Their resistance is related to a defect in a mechanism required for release of active toxin from the endocytic vesicle.     

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.     

Expression of DNA coding for diphtheria toxin chain a is toxic to plant cells

DNA coding for the enzymatically active subunit A of diphtheria toxin was placed under the control of the cauliflower mosaic virus 35S promoter and the Agrobacterium left transfer-DNA gene 7 polyadenylation signal. Agrobacteria carrying a binary plant vector with the chimeric diphtheria toxin A gene had very low transforming activity in tobacco (Nicotiana tabacum L.), and greatly diminished the recovery of stable transformants when mixed together with agrobacteria which alone transformed plant cells well. The introduction of this chimeric molecule into tobacco cells by electroporation lowered the level of the transient expression of the coelectroporated chloramphenicol acetyltransferase reporter gene indicating that expression of diphtheria toxin chain A in plant cells is toxic. We have developed a binary vector pGA987 which can be used for probing a variety of plant promoters.     

Binding of low density lipoproteins to lipoprotein lipase is dependent on lipids but not on apolipoprotein B

Lipoprotein lipase (LPL) efficiently mediates the binding of lipoprotein particles to lipoprotein receptors and to proteoglycans at cell surfaces and in the extracellular matrix. It has been proposed that LPL increases the retention of atherogenic lipoproteins in the vessel wall and mediates the uptake of lipoproteins in cells, thereby promoting lipid accumulation and plaque formation. We investigated the interaction between LPL and low density lipoproteins (LDLs) with special reference to the protein-protein interaction between LPL and apolipoprotein B (apoB). Chemical modification of lysines and arginines in apoB or mutation of its main proteoglycan binding site did not abolish the interaction of LDL with LPL as shown by surface plasmon resonance (SPR) and by experiments with THP-I macrophages. Recombinant LDL with either apoB100 or apoB48 bound with similar affinity. In contrast, partial delipidation of LDL markedly decreased binding to LPL. In cell culture experiments, phosphatidylcholine-containing liposomes competed efficiently with LDL for binding to LPL. Each LDL particle bound several (up to 15) LPL dimers as determined by SPR and by experiments with THP-I macrophages. A recombinant NH(2)-terminal fragment of apoB (apoB17) bound with low affinity to LPL as shown by SPR, but this interaction was completely abolished by partial delipidation of apoB17. We conclude that the LPL-apoB interaction is not significant in bridging LDL to cell surfaces and matrix components; the main interaction is between LPL and the LDL lipids.     

Improvement of a Vero cell assay to determine diphtheria antitoxin content in sera

Diphtheria antitoxin content in sera were determined automatically in Vero cell assay by spectrophotometric determination of the equivalence point between toxin and antitoxin followed by computer analysis of absorption values. The method was more accurate than visual reading and made handling of many samples easy.     

Mutations in diphtheria toxin to improve immunotoxin selectivity and understand toxin entry into cells

Diphtheria toxin can be used to selectively kill target cells by coupling it to cell-type-specific binding moieties such as monoclonal antibodies. These reagents have important potential in treating diseases, selectively ablating cell populations in experimental systems and for understanding how proteins cross membranes. Point mutations and deletions in the diphtheria toxin gene have been used to identify and localize regions of diphtheria toxin involved in cell killing. Mutations have been identified that prevent binding of the toxin to a cell surface receptor yet these mutations do not inhibit the cell entry activity or the intracellular cytotoxicity of the toxin. Coupling of these mutant toxins to new, cell-type-specific binding moieties yields potent reagents with up to 200,000-fold selectivity between target and nontarget cells. Mutations and deletions in the membrane transport regions are beginning to explain how the toxin enters cells and may also help in the design of more effective therapeutic reagents.     

Binding of E-MAP-115 to microtubules is regulated by cell cycle- dependent phosphorylation

Expression levels of E-MAP-115, a microtubule-associated protein that stabilizes microtubules, increase with epithelial cell polarization and differentiation (Masson and Kreis, 1993). Although polarizing cells contain significant amounts of this protein, they can still divide and thus all stabilized microtubules must disassemble at the onset of mitosis to allow formation of the dynamic mitotic spindle. We show here that binding of E-MAP-115 to microtubules is regulated by phosphorylation during the cell cycle. Immunolabeling of HeLa cells for E-MAP-115 indicates that the protein is absent from microtubules during early prophase and progressively reassociates with microtubules after late prophase. A fraction of E-MAP-115 from HeLa cells released from a block at the G1/S boundary runs with higher apparent molecular weight on SDS-PAGE, with a peak correlating with the maximal number of cells in early stages of mitosis. E-MAP-115 from nocodazole-arrested mitotic cells, which can be obtained in larger amounts, displays identical modifications and was used for further biochemical characterization. The level of incorporation of 32P into mitotic E-MAP-115 is about 15- fold higher than into the interphase protein. Specific threonine phosphorylation occurs in mitosis, and the amount of phosphate associated with serine also increases. Hyperphosphorylated E-MAP-115 from mitotic cells cannot bind stably to microtubules in vitro. These results suggest that phosphorylation of E-MAP-115 is a prerequisite for increasing the dynamic properties of the interphase microtubules which leads to the assembly of the mitotic spindle at the onset of mitosis. Microtubule-associated proteins are thus most likely key targets for kinases which control changes in microtubule dynamic properties at the G2- to M-phase transition.     

Monoclonal antibody against diphtheria toxin. Effect on toxin binding and entry into cells

A number of monoclonal antibodies against diphtheria toxin were isolated. Some of their properties were determined. Antibody 2 reacts with the region of between 30 and 45 kDa from the NH2 terminus of toxin. Antibody 7 reacts with the COOH-terminal 17-kDa region of toxin. These two antibodies show sharp contrasts in their effects on toxin action in cultured cells. When antibody 2 or 7 and toxin were mixed, incubated at 37 degrees C, and then added to sensitive Vero cells, antibody 7 blocked toxin action, but antibody 2 did not. When antibody 2 or 7 was added to cells to which toxin had been prebound at 4 degrees C, and the cells were then shifted to 37 degrees C, antibody 7 did not block toxin action, but antibody 2 inhibited intoxication. Antibody 7 blocked binding of 125I-toxin to cells and did not block degradation of toxin associated with cells. Antibody 2 did not block binding of 125I-toxin to cells, and was able to bind to cells in the presence of toxin. The results obtained from the effect of antibody 2 on degradation of 125I-toxin associated with cells resemble those seen with amines, which block toxin action but do not inhibit binding of toxin to cells. These facts show that antibody 2 does not block binding of toxin to cell surfaces, but blocks the entry of toxin into the cytosol at a step after binding of toxin to the receptor. Antibodies 14 and 15 react with fragment A of diphtheria toxin, but have no effect on any activity of toxin. The other monoclonal antibodies have effects on toxin binding and entry intermediate between those of 2 and 7.