Lipid interaction of diphtheria toxin and mutants with altered fragment B. 2. Hydrophobic photolabelling and cell intoxication

The membrane insertion of diphtheria toxin and of its B chain mutants crm 45, crm 228 and crm 1001 has been followed by hydrophobic photolabelling with photoactivatable phosphatidylcholine analogues. It was found that diphtheria toxin binds to the lipid bilayer surface at neutral pH while at low pH both its A and B chains also interact with the hydrocarbon chains of phospholipids. The pH dependence of photolabelling of the two protomers is different: the pKa of fragment B is around 5.9 while that of fragment A is around 5.2. The latter value correlates with the pH of half-maximal intoxication of cells incubated with the toxin in acidic mediums. These results suggest that fragment B penetrates into the bilayer first and assists the insertion of fragment A and that the lipid insertion of fragment B is not the rate-controlling step in the process of membrane translocation of diphtheria toxin. crm 45 behaves as diphtheria toxin in the photolabelling assay but, nonetheless, it is found to be three orders of magnitude less toxic than diphtheria toxin on acid-treated cells, suggesting that the 12-kDa COOH-terminal segment of diphtheria toxin is important not only for its binding to the cell receptor but also for the membrane translocation of the toxin. It is suggested that crm 1001 is non-toxic because of a defect in its membrane translocation which occurs at a lower extent and at a lower pH than that of the native toxin; as a consequence crm 1001 may be unable to escape from the endosome lumen into the cytoplasm before the fusion of the endosome with lysosomes.     

Interaction of diphtheria toxin fragments A, B and protein crm 45 with liposomes

Diphtheria toxin, its fragments A, B and the protein serologically related to toxin, crm 45, have been studied for their hydrophobicity using the method of charge shift electrophoresis. These molecules were then assayed for liposome interaction. The results have shown that the diphtheria toxin B fragment behaves as an amphiphatic protein because it contains a hydrophobic domain located in that portion of the B chain which remains in protein crm 45. Toxin fragment A is hydrophilic. Incubation of protein crm 45 or toxin fragment B with preformed liposomes leads to association of these proteins with lipid vesicles. Fragment A does not interact with liposomes. Binding of protein crm 45 with lipid vesicles is dependent on time and temperature. Protein crm 45 is unidirectionally associated with liposomes, its enzymic fragment A directed outside the liposome. Fragment B or protein crm 45, upon binding with liposomes, does not affect the permeability of the vesicles.     

Lipid interaction of diphtheria toxin and mutants with altered fragment B. 1. Liposome aggregation and fusion

The interaction of diphtheria toxin and its cross-reacting mutants crm 45,228 and 1001 with small unilamellar vesicles has been followed by a turbidity assay, electron microscopy, fluorescence energy transfer and membrane permeability. All toxins at pH lower than 6 induce the aggregation and fusion of liposomes containing negatively charged phospholipids; crm 45 and crm 1001 are less potent than diphtheria toxin. Isolated diphtheria toxin fragment B is very effective while isolated fragment A is ineffective. Liposome fusion induced by the toxins at low pH occurs without release of the internal content implying that fusion does not involve vesicle breakage and resealing. The pH dependence of the membrane interaction of diphtheria toxin monitored by turbidity is in close agreement with that monitored by fluorescence energy transfer. It shows that diphtheria toxin can alter the lipid bilayer structure in the pH interval 5-6. This pH range occurs in endosomes and suggests that histidyl and carboxyl residues are likely to be involved in the conformational change of diphtheria toxin triggered by acidic pH.     

Entry of diphtheria toxin into cells: possible existence of cellular factor(s) for entry of diphtheria toxin into cells was studied in somatic cell hybrids and hybrid toxins

Ehrlich ascites tumor cells were found to be very insensitive to diphtheria toxin. We formed 37 hybrids from Ehrlich tumor cells and diphtheria toxin-sensitive human fibroblasts. The effects of diphtheria toxin on protein synthesis in those hybrids were examined. The hybrids were divided into three groups on the basis of toxin sensitivity. Group A hybrids were as sensitive to diphtheria toxin as human fibroblasts, Group C were as resistant as Ehrlich tumor cells, and Group B had intermediate sensitivity. Group A hybrids had diphtheria toxin-binding sites but Group B and C had no detectable binding sites. Elongation factor-2 of all the hybrids was susceptible to ADP-ribosylation by fragment A of diphtheria toxin. Cells of Group A and B became more sensitive to CRM 45 (cross-reacting material 45 of diphtheria toxin) after they were exposed to low pH (pH = 4.5). The resistance of Group C to CRM 45 was not affected by the same treatment. Group A and B hybrids and human fibroblasts had similar sensitivities to a hybrid toxin composed of wheat germ agglutinin and fragment A of diphtheria toxin, but Group C and Ehrlich tumor cells were resistant to this hybrid toxin. All the hybrids and Ehrlich tumor cells were more sensitive to a hybrid toxin composed of wheat germ agglutinin and subunit A of ricin than were human fibroblasts. On subcloning of Group B hybrids, one Group C hybrid was obtained, but no Group A hybrid. These facts suggest that Ehrlich ascites tumor cells differ from human fibroblasts in the expression of a factor(s) that is involved in entry of fragment A of diphtheria toxin into the cytoplasm after the toxin binds to its surface receptors.     

Lipid interaction of diphtheria toxin and mutants. A study with phospholipid and protein monolayers

To study the structural change of diphtheria toxin (DT) induced by low pH and its influence on the interaction with membrane lipids, protein and lipid monolayers were formed and characterized. DT at neutral and acidic pH forms stable monolayers, whose surface-pressure-increase curves allow an estimation of the apparent molecular area of 29.5 nm2/molecule at pH 7.4 (corresponding to a radius of 3.06 nm) and 34.5 nm2/molecule at pH 5.0 (corresponding to a radius of 3.32 nm). DT at pH 7.4 does not insert into phospholipid monolayers, while at pH 5.0 it penetrates into the lipid layer with a portion of apparent molecular area of 21.0 nm2/molecule (corresponding to a radius of 2.6 nm). The low-pH driven lipid interaction of the toxin is favoured by the presence of acidic phospholipids, without an apparent requirement for a particular class of negative lipids. The DT mutants crm 45 and crm 197 are capable of hydrophobic interaction already at neutral pH and cause an increase of surface pressure with a further increase upon acidification.     

Cloning in Escherichia coli of the mutant gene coding the diphtheria toxin

Bacteriophage beta 45 of Corynebacterium diphtheriae was harvested. The extracted DNA of the bacteriophage was digested by the restriction endonuclease BamHI and inserted into the BamHI cleavage site of pUC19 vector plasmid. Plasmid pNVY5 containing a mutant gene crm45 of diphtheriae toxin in a 3.9 bpn fragment was isolated from the hybrid plasmids obtained. Cell free extracts of E. coli strain TG1 (pVNY5) contain the nontoxic protein crm45 possessing the specific enzymatic activity of diphtheriae toxin (ADP ribosylation on wheat elongation factor two). According to orientation of BamHI fragment in pNVY5 plasmid it is concluded that the crm45 gene is expressed using its own promoter.     

Primary structure of diphtheria toxin fragment B: structural similarities with lipid-binding domains

Two different lipid-associating domains have been identified in the B fragment of diphtheria toxin using automated Edman degradation of its cyanogen bromide peptides, secondary structure prediction analysis, and comparisons with known phospholipid-interacting proteins. The first domain is located in the highly hydrophilic (polarity index [PI] = 61.0%) 9.00-dalton N-terminal region of fragment B. This region shows primary and predicted secondary structures dramatically similar to those found for the phospholipid headgroup-binding domains of human apolipoprotein A1 (surface lipid-associating domain). The second domain is located in the highly hydrophobic (PI = 32.4%) middle region of fragment B. Its structure resembles that found for the membranous domain of intrinsic membrane proteins (transverse lipid-associating domain). In contrast, the hydrophilic C-terminal 8,000-dalton region of fragment B (PI = 53.8%) does not show structural similarity with lipid- associating domains.     

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.     

Studies of microbial toxins in Xenopus laevis oocytes

Xenopus laevis oocytes have been incubated or microinjected with cholera and diphtheria holotoxins or their respective isolated fragments A and B. Effects on progesterone-induced maturation, protein synthesis and cAMP levels were observed. Xenopus laevis oocytes were highly susceptible to cholera toxin upon incubation as evidenced by the increase of cAMP (two-fold increase in cAMP with 0.1 nM cholera toxin) and the blockade of progesterone-induced maturation. When isolated cholera toxin fragments A or B were incubated with oocytes, no activity could be detected. However, microinjection of cholera toxin fragment A into oocyte was able to mimic the effects of incubated holotoxin. Microinjection of cholera toxin B fragment was only effective at very high concentrations, probably due to trace contaminations by the A fragment. On the other hand, Xenopus laevis oocytes were very resistant to diphtheria toxin action upon incubation, a result attributable to lack of specific membrane receptors since, after microinjection of diphtheria toxin A fragment into oocytes, inhibition of protein synthesis was demonstrated. By simultaneous microinjection of highly radioactive adenine-labelled NAD and diphtheria toxin fragment A into oocytes, radioactive ADP ribosylation of the elongation factor 2 (EF₂) was observed. It is proposed that Xenopus laevis oocytes provide a new experimental approach for studying the mechanisms of action of microbial toxins.     

Requirement of specific receptors for efficient translocation of diphtheria toxin A fragment across the plasma membrane

The role of specific receptors in the translocation of diphtheria toxin A fragment to the cytosol and for the insertion of the B fragment into the cell membrane was studied. To induce nonspecific binding to cells, toxin was either added at low pH, or biotinylated toxin was added at neutral pH to cells that had been treated with avidin. In both cases large amounts of diphtheria toxin became associated with the cells, but there was no increase in the toxic effect. There was also no increase in the amount of A fragment that was translocated to the cytosol, as estimated from protection against externally added Pronase E. In cells where specific binding was abolished by treatment with 12-O-tetradecanoyl-phorbol 13-acetate, trypsin, or 4,4'-diisothiocyano-2,2'-stilbenedisulfonic acid, unspecific binding did not induce intoxication or protection against protease. This was also the case in untreated L cells, which showed no specific binding of the toxin. When Vero cells with diphtheria toxin bound to specific receptors were exposed to low pH, the cells were permeabilized to K+, whereas this was not the case when the toxin was bound nonspecifically at low pH or via avidin-biotin. The data indicate that the cell-surface receptor for diphtheria toxin facilitates both insertion of the B fragment into the cell membrane and translocation of the A fragment to the cytosol.     

Identification of DNA restriction fragments of corynebacteriophage β corresponding to hypotoxic peptides of diphtheria toxin

Abstract An Xba I/ Eco RI restriction fragment (ca. 2000 bp) from corynebacteriophage β DNA was shown to contain the entire structural gene ( tox ) for diphtheria toxin, plus about 500 bp upstream from the amino terminus of the mature toxin. Restriction analysis and partial sequencing of this fragment permitted us to identify 3 large subfragments coding for hypotoxic peptides of diphtheria toxin. Two Mbo I restriction fragments, F1 (ca. 825 bp) and F3 (ca. 1000 bp), contained regions coding for the enzymatically active A fragment and most of the B fragment, respectively, of the toxin. An Msp I fragment, F2 (ca. 1450 bp), encoded a toxin peptide corresponding approximately to CRM45, a chain termination fragment lacking the carboxyl terminal region of the toxin. Fragments F1, F2, and F3 are permissible to clone in Escherichia coli under P1 + EK1 conditions according to current recombinant DNA guidelines.     

Localization in diphtheria toxin fragment B of a region that induces pore formation in planar lipid bilayers at low pH

Like diphtheria toxin and the N-terminal (M_r 23 000) region of fragment B, CB1 (M_r 13 000), the cyanogen bromide peptide located in the middle region of fragment B is able to induce pore formation in lipid bilayer membrane at low pH. These two peptides (M_r 23 000 and 13 000) share a common segment (M_r 6300) containing the predicted amphipathic, -helical, transverse lipid-associating domain (M_r 2750) of fragment B[J. Cell Biol. (1980) 87, 837–840]. Therefore, we postulated this domain to be responsible for the pore formation ability of diphtheria toxin [Proc. Natl. Acad. Sci. USA (1981) 78, 172–176]. A relationship between the pH dependency of pore formation and the presence of a cluster of prolines in the C-terminal region of CB1 is proposed.     

Requirements for the translocation of diphtheria toxin fragment A across lipid membranes

The translocation of the enzymatic moiety of diphtheria toxin, fragment A, across the membranes of pure lipid vesicles was demonstrated. A new assay, which employed vesicles made to contain radiolabeled NAD and elongation factor-2, was used to measure the appearance of the enzymatic activity of the A fragment in the vesicles. When the vesicles were exposed to a low-pH medium in the presence of diphtheria toxin, small molecules, such as NAD, escaped into the extravesicular medium, whereas large molecules mostly remained inside the vesicles. The vesicle-entrapped elongation factor-2 became ADP-ribosylated, indicating the entry of fragment A into the vesicle. The translocation of the A fragment depended upon the pH of the medium, being negligible at pH greater than 7.0 and maximal at pH 4.5. The entire toxin molecule was needed for function; neither the A fragment nor the B fragment alone was able to translocate itself across and react with the sequestered substrates. After exposure of the toxin to low pH, the entry of the A fragment was rapid, being virtually complete within 2-3 min at pH 5.5, and within 1 min at pH 4.7. Translocation occurred in the absence of any protein in the vesicle membrane. These results are consistent with the notion that the diphtheria toxin molecule enters the cytoplasm of a cell by escaping from an acidic compartment such as an endocytic vesicle.     

A CNBR peptide located in the middle region of diphtheria toxin fragment B induces conductance change in lipid bilayers: Possible role of an amphipathic helical segment

Conductance measurements on planar lipid bilayers demonstrate that CB1, a CNBr peptide of diphtheria toxin fragment B located in its middle region, possesses the unique property to destabilize the lipid bilayer organization. It is suggested that a segment of 25 amino acids in the N-terminal sequence of CB1 could be responsible for this effect. Its very low polarity, its predicted amphipathic helical structure and a helix length corresponding to the thickness of the hydrocarbon region of the lipid bilayer should specifically favor its insertion in the membrane. The existence of such a transverse lipid-associating domain could confer upon the molecule the properties leading to the anchoring of diphtheria toxin in the cytoplasmic membrane.     

Expression of a biologically active diphtheria toxin fragment B in Escherichia coli

The toxB gene of Corynebacterium diphtheriae bacteriophage β encoding the B fragment of diphtheria toxin was cloned into an inducible expression vector. When expressed In Escherichia coli, fragment B was not proteolysed and was indistinguishable, by immunological criteria, from wild-type C. diphthsriae derived fragment B. Soluble fragment B was partially purified from the cytoplasm by saline precipitation steps and was shown to compete with the wild-type diphtheria toxin for binding to receptors of sensitive eukaryotic cells. A complete diphtheria toxin was reconstituted by formation of the disulphide bridge between purified fragment A and recombinant fragment B, which migrates at the expected Mr on Western blots and which was able to block protein synthesis by ADP-ribosylation of elongation factor–2, thereby indicating that the recombinant fragment B had retained its biological activity.     

Conformation and model membrane interactions of diphtheria toxin fragment A

Low pH is believed to play a critical role in the penetration of membranes by diphtheria toxin in vivo. In this report, the pH dependence of the conformation of fragment A of diphtheria toxin has been studied using fluorescence techniques. As pH is decreased, fragment A in solution undergoes a reversible conformational change beginning below pH 5. The conformational change occurs rapidly upon exposure to low pH. It involves both an increase in the exposure of tryptophanyl residues to solution and a switch from a hydrophilic state to a hydrophobic state as judged by fragment A binding to micelles of a mild detergent (Brij 96). At low pH fragment A also rapidly and tightly binds to and penetrates model membranes. Binding is reversed when pH is neutralized. The transition pH, the apparent midpoint of the change between the hydrophilic state and the membrane-penetrating hydrophobic state, occurs at about pH 3.5 in the presence of Brij 96 micelles, pH 4 in the presence of small unilamellar vesicles (SUV) composed of zwitterionic phosphatidylcholine, and pH 5 in the presence of SUV composed of 25 mol % anionic phosphatidylglycerol and 75% phosphatidylcholine. The effects of high temperature provide an important clue as to the nature of the changes at low pH. At neutral pH and high temperature, i.e. in the thermally denatured state, a conformational change similar to that observed at low pH occurs, although fragment A does not become hydrophobic. In addition, the effects of low pH and high temperature on the stability of the native state are cumulative. This indicates that the changes in fragment A both at high temperature and at low pH involve denaturation, although there appears to be only partial unfolding under these conditions. Based on the results of this study, the role of fragment A in diphtheria toxin membrane penetration and translocation is evaluated.     

Amino acid substitution in alpha-helix 7 of Cry1Ac delta-endotoxin of Bacillus thuringiensis leads to enhanced toxicity to Helicoverpa armigera Hubner.

Insecticidal proteins or delta-endotoxins of Bacillus thuringiensis are highly toxic to a wide range of agronomically important pests. The toxins are formed of three structural domains. The N-terminal domain is a bundle of eight alpha-helices and is implicated in pore formation in insect midgut epithelial membranes. All the delta-endotoxins share a common hydrophobic motif of eight amino acids in alpha-helix 7. A similar motif is also present in fragment B of diphtheria toxin (DT). Site-directed mutagenesis of Cry1Ac delta-endotoxin of B. thuringiensis was carried out to substitute its hydrophobic motif with that of DT fragment B. The mutant toxin was shown to be more toxic to the larvae of Helicoverpa armigera (cotton bollworm) than the wild-type toxin. Voltage clamp analysis with planar lipid bilayers revealed that the mutant toxin opens larger ion channels and induces higher levels of conductance than the wild-type toxin.     

pH dependent insertion of a diphtheria toxin B fragment peptide into the lipid membrane: a conformational analysis

A peptide of diphtheria toxin B fragment (residues 147-266) has been shown to induce pore formation in lipid bilayer membranes at low pH. Such an effect was obtained at a much lower extent or not at all at pH = 7. The region localized between residues 225 and 246 is highly hydrophobic (27.3% polarity) and characterized by a high concentration of proline residues. Since proline cis-trans isomerization is highly sensitive to the pH of the medium, we investigated the capability of the cis and trans isomers to penetrate into the lipid matrix. Obviously, the cis-trans isomerization of proline 242 and 245, assumed to be imposed by a low pH, uncovers the hydrophobic region and induces its insertion into a lipid layer of dipalmitoylphosphatidylcholine. The lipid matrix destabilization resulting from this process could promote the penetration into the lipid bilayer of an amphipatic structure (153-178) similar to the transverse lipid associating domains of membrane proteins.     

Simple procedure for purification of diphtheria toxin and separation of its fragments by hydrophobic chromatography

Diphtheria toxin and fragment B bind to hydrocarbon-coated agaroses. Fragment A of the toxin is not adsorbed to such resins. Using Seph-C₄, the toxin and fragment B can be eluted from the column after adsorption by increasing the ionic strength of the eluent. The toxin is also eluted from the Seph-C₆ column, but fragment B is eluted only in the denatured form. Purification of the toxin can be achieved simply by passing the growth medium supernatant through a small size Seph-C₆ column and eluting the toxin by 0.1 m NaCl. The fragments of diphtheria toxin obtained after mild trypsin treatment can be separated purely on a Seph-C₄ column. The hydrophobic chromatography system may thus serve as a tool for purification of the toxin and its fragments: it may also be useful in large-scale preparations.     

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.