Tetanus Toxin and Antigenic Derivatives II. Effect of Protein and Formaldehyde Concentration on Toxoid Formation

Tetanus toxoid formation was examined under varying conditions. Products of the reaction depended upon the concentration of both formaldehyde and toxin. High concentrations of protein and formaldehyde favored the formation of large polymers, whereas low concentrations yielded smaller polymers and monomer. The monomer had an observed S value of 7.1, whereas the polymers ranged from 10.1S to 110S. The cross-linking between toxin molecules to form toxoid polymers appeared to be random.     

Gas phase characterization of the noncovalent quaternary structure of cholera toxin and the cholera toxin B subunit pentamer

Cholera toxin (CTx) is an AB5 cytotonic protein that has medical relevance in cholera and as a novel mucosal adjuvant. Here, we report an analysis of the noncovalent homopentameric complex of CTx B chain (CTx B5) using electrospray ionization triple quadrupole mass spectrometry and tandem mass spectrometry and the analysis of the noncovalent hexameric holotoxin usingelectrospray ionization time-of-flight mass spectrometry over a range of pH values that correlate with those encountered by this toxin after cellular uptake. We show that noncovalent interactions within the toxin assemblies were maintained under both acidic and neutral conditions in the gas phase. However, unlike the related Escherichia coli Shiga-like toxin B5 pentamer (SLTx B), the CTx B5 pentamer was stable at low pH, indicating that additional interactions must be present within the latter. Structural comparison of the CTx B monomer interface reveals an additional alpha-helix that is absent in the SLTx B monomer. In silico energy calculations support interactions between this helix and the adjacent monomer. These data provide insight into the apparent stabilization of CTx B relative to SLTx B.     

Role of the essential thiol group in the thiol-activated cytolysin from Clostridium perfringens

A hemolysin, 0-toxin, produced by Clostridium perfringens has one cysteinyl residue in the free thiol form which is essential for its hemolytic activity. The cysteinyl residue was shown to be located at a position about 5 kDa from the C terminus of the molecule by the method of cysteine-specific chemical cleavage. Modification of the residue with a thiol-blocking agent, 5,5'-dithiobis(2-nitrobenzoic acid), reduced the binding affinity of the toxin to sheep erythrocytes to 1/100 that of intact toxin, resulting in a failure of binding at low cell concentrations (0.5%). Thus the failure of hemolysis at low cell concentrations is primarily ascribed to a decreased affinity of the toxin for erythrocytes. Effects of the modification on the lytic processes were examined using high cell concentrations where considerable amounts of modified toxin bound to the cells. The modified toxin hemolyzes erythrocytes once it binds to them; however, the efficiency of hemolysis is reduced by the modification. These, and additional results indicating that modification alters the sensitivity of toxin molecules to protease digestion, show that thiol-modification inactivates the toxin by affecting both binding and the subsequent lytic processes, probably through a conformational change introduced in the toxin molecules.     

Effect of pH on the conformation of diphtheria toxin and its implications for membrane penetration

The pH-triggered change in diphtheria toxin conformation and the physical properties of the toxin above and below the transition pH have been examined. Exposure to low pH (less than or equal to 5 at 23 degrees C, less than or equal to 5.3 at 37 degrees C) triggers a rapid (t1/2 less than 30 s) change in toxin conformation; the transition occurs over a narrow pH range (0.2 unit). Below the transition pH, buried tryptophans become exposed, and the toxin becomes hydrophobic, binding very tightly to detergent. Aggregation is observed at low pH, probably due to this extreme hydrophobicity. Circular dichroism and fluorescence properties show that the low-pH conformation is not extensively unfolded. Therefore, the toxin "opens" at low pH without becoming a random coil. The conformation change is partly irreversible, and the degree of irreversibility parallels the degree of aggregation. Reduction of the disulfide bonds does not increase hydrophobicity at neutral pH. Furthermore, none of the structural variants of toxin (monomer or dimer, bound to ApUp or free, and nicked between subunits or intact) are hydrophobic at neutral pH or differ in transition pH markedly. Therefore, these factors do not mimic the effect of low pH. These observations are consistent with a functional role for the pH-triggered changes during penetration of the membranes of acidic organelles. The toxin may have adapted a conformational change similar to partial denaturation for a critical role in function. The possible nature of the pH-sensitive interactions and the effects of aggregation are discussed briefly.     

Monomer/dimer equilibrium of the AB-type lectin from mistletoe enables combination of toxin/agglutinin activities in one protein: analysis of native and citraconylated proteins by ultracentrifugation/gel filtration and cell biological consequences of dimer destabilization

The biological activity of a lectin is influenced by its quaternary structure. Viscumin is special among the family members of toxic AB-type plant lectins, because it triggers mitogenicity, toxicity, and agglutination. Its activity profile is dependent on the concentration, motivating a thorough inspection of the status of quaternary structure. Over a broad range of protein concentrations (0.01-25 mg/mL), viscumin occurs as a dimer. At high concentrations, the solutions exhibited nonideality, self-association, and polydispersity in sedimentation equilibrium and velocity experiments caused by irreversible aggregation. Calculation of viscumin's overall shape based on sedimentation velocity data resulted in an elongated dimer form resembling that of crystallized agglutinin. Appearance of monomers was restricted to concentrations in the submicrogram/mL level, as demonstrated by fast protein liquid chromatography gel-filtration analysis. To shift the equilibrium to the monomer for comparative cell biological assays, we performed chemical modification under conditions protecting the lectin activity. Citraconylation was effective to destabilize the dimer. Binding studies by fluorescence-activated cell scan analysis revealed a reduction in cell association upon modification and a tendency for increased sensitivity towards haptenic inhibitors at microg/mL concentrations. Nonetheless, growth inhibition continued to be potent for the ricin-like monomer despite reduced extent of binding. Occurrence of a concentration-dependent monomer/dimer equilibrium appears to achieve the same objectives as the development of two separate protein entities in Ricinus communis, an alternative strategy to emergence of a monomeric toxin, and cell cross-linking dimeric agglutinin.     

Mechanism of resistance to ricin toxin in selected mouse lymphoma cell lines

The role of impaired toxin uptake in conferring cellular resistance to the plant toxin RCA_II (ricin) has been examined using a murine BW5 147 lymphoma line and a toxin-resistant variant (BW5 147 Ric^R.3) selected by repeated exposure to RCA_II. The toxin-resistant variant is 250 times more resistant to RCA_II in long-term growth experiments and 1,000 times more resistant in short-term protein synthesis assays. Experiments with ferritin-conjugated ¹²⁵I-labeled RCA_II (ferritin-¹²⁵I-RCA_II) indicated that toxin binding to sensitive and resistant cells is similar at low toxin concentrations where maximum differential cytotoxicity occurs but that major difference exist with respect to toxin uptake. In sensitive cells toxin is internalized via endocytosis, and as seen previously in other systems subsequent rupture of some of the toxin-containing endocytotic vesicles releases toxin into the cytoplasm, where it inhibits protein synthesis. The process of toxin transfer to the cytoplasm is presumed to account for the one-hour lag before toxin-induced inhibition of protein synthesis can be detected. Endocytotic uptake of toxin is impaired in resistant BW5147Ric^R.3 cells, and they are unaffected by toxin concentrations that inhibit protein synthesis and kill sensitive parental cells. Killing of resistant cells at low toxin concentrations was accomplished by encapsulating RCA_II into lipid vesicles capable of fusing with the plasma membrane. Direct introduction of toxin into resistant cells using lipid vesicles as carriers produced rapid inhibition (< 15 min) of protein synthesis and eliminated the lag in toxin action seen in sensitive cells exposed to free toxin. These findings are discussed in relation to the mechanism of toxin action and proposals that toxin activity requires structural modification of the toxin molecule at the cell surface before transport into the cell.     

Dimeric form of diphtheria toxin: purification and characterization

Many preparations of diphtheria toxin were found to contain dimeric and multimeric toxin forms. The monomeric and dimeric forms were fractionated to greater than 98% purity, and their properties were compared. Dimeric toxin slowly dissociated to native monomers in solution at neutral pH and could be rapidly dissociated with dimethyl sulfoxide. In cell culture assays and rabbit skin tests, the dimer exhibited no significant toxic activity, except for that attributable to trace contamination by monomer, or partial dissociation to monomer during the incubation period. In guinea pig lethality tests, however, toxic activity varied depending upon the dose. At least 7-fold greater amounts of dimer than monomer (161 ng vs. 22 ng, respectively) were required to cause death at 18 h, whereas similar weights of the two toxin forms (22 ng) caused death at 120 h. This variability probably reflected slow dissociation of dimer to monomer in the animal. The dimer was unable to bind toxin receptors on the surface of susceptible cells, whereas it retained full activity in the ADP-ribosyltransferase, NAD-glycohydrolase, or ligand-binding assays. Thus, the lack of toxicity of the dimeric toxin may have resulted from distortion or occlusion of the receptor binding site on the B moiety. We propose that the dimer contains two monomeric units bound by hydrophobic interactions and that the points of contact involve regions of the B moieties that are normally buried in the native monomer.     

On the interaction of cobra venom protein cardiotoxins with erythrocytes

The principally active hemolytic toxin (cardiotoxin) previously purified from the venom of the Thailand cobra, Naja naja siamensis, was shown to produce spontaneous twitching, contractures and membrane depolarization in sartorius muscles from the frog, Rana pipiens. Spontaneous twitching, observed at concentrations greater than 0.1 uM was completely abolished by addition of tetrodotoxin and not affected by d-tubocurarine. Dose and time dependent membrane depolarization of muscle fibers was observed to occur within 10-30 min at 0.2 to 1.0 uM concentrations of the toxin. These observations, taken together with an amino acid analysis characteristic of previously described cobra venom cardiotoxins, characterized this hemolytic toxin as a cardiotoxin. In the absence of EDTA the initial velocities of erythrocyte hemolysis for this toxin showed a sigmoidal concentration dependence which became hyperbolic in the presence of EDTA. The largest increases in hemolysis rates on addition of 1 mM EDTA were observed at low toxin concentrations. In the presence of EDTA extracellular and membrane associated divalent cations are complexed, thus alleviating their competition with toxin for binding to the membrane, a key and apparently rate-determining initial step which leads to hemolysis. In the presence of EDTA hemolysis rates increased linearly at low toxin concentration and reached an extrapolated maximum value at toxin concentrations at which, given its molecular dimensions, there are just sufficient toxin molecules to cover the entire membrane surface area provided by the erythrocytes.     

Partially folded intermediates in insulin fibrillation

Native zinc-bound insulin exists as a hexamer at neutral pH. Under destabilizing conditions, the hexamer dissociates, and is very prone to forming fibrils. Insulin fibrils exhibit the typical properties of amyloid fibrils, and pose a problem in the purification, storage, and delivery of therapeutic insulin solutions. We have carried out a systematic investigation of the effect of guanidine hydrochloride (Gdn.HCl)-induced structural perturbations on the mechanism of fibrillation of insulin. At pH 7.4, the addition of as little as 0.25 M Gdn.HCl leads to dissociation of insulin hexamers into dimers. Moderate concentrations of Gdn.HCl lead to formation of a novel partially unfolded dimer state, which dissociates into a partially unfolded monomer state. High concentrations of Gdn.HCl resulted in unfolded monomers with some residual structure. The addition of even very low concentrations of Gdn.HCl resulted in substantially accelerated fibrillation, although the yield of fibrils decreased at high concentrations. Accelerated fibrillation correlated with the population of the expanded (partially folded) monomer, which existed up to >6 M Gdn.HCl, accounting for the formation of substantial amounts of fibrils under such conditions. In the presence of 20% acetic acid, where insulin exists as the monomer, fibrillation was also accelerated by Gdn.HCl. The enhanced fibrillation of the monomer was due to the increased ionic strength at low denaturant concentrations, and due to the presence of the partially unfolded, expanded conformation at Gdn.HCl concentrations above 1 M. The data suggest that under physiological conditions, the fibrillation of insulin involves both changes in the association state (with rate-limiting hexamer dissociation) and conformational changes, leading to formation of the amyloidogenic expanded monomer intermediate.     

Inhibition of macromolecular synthesis in cultured macrophages by Pseudomonas pseudomallei exotoxin

Pseudomonas pseudomallei exotoxin was found to be a potent inhibitor of protein and DNA synthesis in cultured macrophages. Inhibition of DNA synthesis occurred at toxin concentrations as low as 1-2 micrograms/ml and inhibition of 3H-thymidine uptake was almost complete at concentrations of 8 micrograms/ml or more. A close correlation between cell damage and inhibition by DNA synthesis was observed. For protein synthesis, inhibition was obtained at much lower doses (0.06-2.0 micrograms/ml) of the toxin. At similar toxin concentrations, DNA synthesis was marginally affected. Further, it was shown that protein synthesis inhibition occurred almost immediately after incubation, reaching its maximal inhibitory effect of 70% after 6 hr. DNA synthesis, however, was minimally affected by a similar toxin concentration even after 10 hr of incubation. The inhibition of macromolecular synthesis in macrophages by P. pseudomallei exotoxin may be relevant to its modulatory effect on the host defense mechanism.     

Diphtheria Toxin Forms Pores of Different Sizes Depending on Its Concentration in Membranes: Probable Relationship to Oligomerization

Diphtheria toxin forms pores in biological and model membranes upon exposure to low pH. These pores may play a critical role in the translocation of the A chain of the toxin into the cytoplasm. The effect of protein concentration on diphtheria toxin pore formation in model membrane systems was assayed by using a new fluorescence quenching method. In this method, the movement of Cascade Blue labeled dextrans of various sizes across membranes is detected by antibodies which quench Cascade Blue fluorescence. It was found that at low pH the toxin makes pores in phosphatidylcholine/phosphatidylglycerol vesicles with a size that depends on protein concentration. At the lowest toxin concentrations only the entrapped free fluorophore (MW 538) could be released from model membranes. At intermediate toxin concentrations, a 3 kD dextran could be released. At the highest toxin concentration, a 10 kD dextran could be released, but not a 70 kD dextran. Similar pore properties were found using vesicles lacking phosphatidylglycerol or containing 30% cholesterol. However, larger pores formed at lower protein concentrations in the presence of cholesterol. The dependence of pore size on toxin concentration suggests that toxin oligomerization regulates pore size. This behavior may explain some of the conflicting data on the size of the pores formed by diphtheria toxin. The formation of oligomers by membrane-inserted toxin is consistent with the results of chemical crosslinking and measurements of the self-quenching of rhodamine-labeled toxin. Based on these experiments we propose diphtheria toxin forms oligomers with a variable stoichiometry, and that pore size depends on the oligomerization state. Reasons why oligomerization could assist proper membrane insertion of the toxin and other proteins that convert from soluble to membrane-inserted states are discussed. Received: 10 March 1999/Revised: 22 June 1999     

Pseudomonas toxin binds triton X-114 at low pH.

Pseudomonas toxin was found to bind Triton X-114 at pH values below pH 5.0, whereas much less binding was observed at higher pH values. The toxin bound Triton X-114 at a higher pH value in the presence of 0.14 M-NaCl, -KCl or -NaNO3 than at low salt concentrations. The results suggest that low pH in an intracellular compartment facilitates the transport of Pseudomonas toxin across the membrane and into the cytosol by inducing a conformational change in the molecule.     

T-2 toxin decreases logarithmic growth rates of tobacco callus tissues

T-2 toxin, a mycotoxin produced by Fusarium tricinctum, decreases logarithmic growth rates of tobacco (Nicotiana tabacum L.) pith callus tissues. Toxin concentrations as low as 0.003 μm will decrease growth rates; a concentration of 0.081 μm will halt growth completely. Additional exogenous cytokinin will reduce the inhibition by toxin only when the initial cytokinin and toxin concentrations are quite low (about 0.01 μm). When inhibited tissues are transferred to media lacking toxin, they assume the faster, control rates almost immediately. Maximal yields of tissue (yields at the point at which no sugar was detected in the medium) are not affected by toxin concentrations of 0.01 to 0.036 μm.     

Staphylococcus aureus alpha-toxin. Dual mechanism of binding to target cells

Staphylococcal alpha-toxin was radiolabeled to high specific radioactivity (1,500-3,000 Ci/mmol) under retention of its hemolytic activity. Binding studies with susceptible rabbit erythrocytes and highly resistant human erythrocytes revealed that binding of alpha-toxin to target cells can occur via two different mechanisms. Binding of alpha-toxin to rabbit erythrocytes initially involves specific binding sites and occurs at low concentrations, with half-maximal binding at 1-2 nM. In contrast, toxin binding to human erythrocytes is absorptive and nonspecific, in this case, significant binding as well as hemolysis occur only at alpha-toxin concentrations exceeding 1 microM. Autoradiographic analyses of membrane-associated alpha-toxin from either cell species proved that hemolysis was inevitably associated with the formation of toxin hexamers. Our data indicate that the high susceptibility of certain target cells toward alpha-toxin is caused by the presence of specific binding sites. However, membrane damage of both susceptible and nonsusceptible target cells occurs via a common mechanism involving toxin oligomerization and pore formation.     

A calorimetric examination of the effect of myotoxin a on the thermotropic phase behavior of model lipid membranes

The effect of myotoxin a on the thermotropic phase behavior of aqueous dispersions of dimyristoyl phosphatidylcholine (DMPC) and dimyristoyl phosphatidylserine (DMPS) was examined using differential scanning calorimetry (DSC). Myotoxin a significantly altered the normal phase behavior of DMPC in a concentration dependent fashion. This effect is perturbed by Ca2+ and is sensitive to ionic strength and pH. High concentrations of toxin eliminate the characteristic pretransition associated with the polar head group of DMPC. They also increase the temperature of the main gel-to-liquid crystal transition from 23 degrees C to 32-35 degrees C. At low concentrations of toxin, the first visible effect is upon the pretransition which is split into two components that diminish with time. The main transition is less affected at low toxin concentrations, although the magnitude of the transition is reduced while it is simultaneously shifted to higher temperatures. The main transition is also split into multiple components. The toxin also had pH specific effects on the phase behavior of DMPS. Above physiological pH (8.5) the normal transition of DMPS at 36-38 degrees C was split in the presence of myotoxin a and new components appeared centered at 31 degrees C and 35 degrees C. These observations are consistent with reports that the skeletal muscle membrane system is the major site of the myonecrotic effect of myotoxin a.     

Mechanisms of ferric and ferrous iron uptake by Bifidobacterium bifidum var. pennsylvanicus

Iron uptake studies in Bifidobacterium bifidum var. pennsylvanicus were carried out using ferric citrate at iron concentrations above 0.01 mM and pH 7, ferrous iron at concentrations less than 0.01 mM at pH 5. Two ferric iron transport systems were distinguished: the temperature-insensitive polymer, and the temperature-sensitive monomer uptake. Both showed a saturation phenomenon. The transport of ferrous iron at concentrations below 0.01 mM was temperature-dependent, and its affinity for iron was higher than that of a system operating at iron concentrations higher than 0.01 mM. The use of various metabolic inhibitors indicated that ferrous iron transport at pH 5 at both high and low iron concentrations was mediated by transport-type ATPase. Proton gradient dissipators abolished ferrous iron uptakes as well as the ferric monomer uptake. Uptake of the ferric polymer was insensitive to metabolic inhibitors. The functional significance of the various types of iron transport systems may be related to the nutritional immunity phenomenon.     

Centipede (Scolopendra subspinipes mutilans) venom toxin peptide exhibits cytotoxic and cell growth effects in a concentration-dependent manner

Centipede venom contains a variety of proteins, peptides, and enzymes. However, the biological actions of toxin peptides in centipede venom remain largely unknown. In this study, we identified a centipede (Scolopendra subspinipes mutilans) venom toxin peptide (SsmTP) that was shown to act as a cell growth factor at low concentrations-in vitro. SsmTP was found to consist of 66 amino acids that display seven cysteine residues, which exhibited high similarity to the predicted neurotoxin. SsmTP was expressed in the venom gland of S. s. mutilans. A recombinant SsmTP peptide of approximately 5.2 kDa was produced in baculovirus-infected insect cells. Interestingly, SsmTP exhibited cytotoxicity in murine cells in a concentration-dependent manner but displayed a cell growth effect at low concentrations. SsmTP at a low concentration also protected murine cells against oxidative damage through the inhibition of caspase-1 and apoptosis. Our data indicate that SsmTP acts as a cell growth factor and a toxin peptide in a concentration-dependent manner. Consequently, our results provide evidence that the identification of SsmTP, a centipede toxin peptide, may not only elucidate the biological action of toxin peptides but also offer additional insight into the pharmacological applications of centipede venoms.     

Stimulation of insulin fibrillation by urea-induced intermediates

Fibrillar deposits of insulin cause serious problems in implantable insulin pumps, commercial production of insulin, and for some diabetics. We performed a systematic investigation of the effect of urea-induced structural perturbations on the mechanism of fibrillation of insulin. The addition of as little as 0.5 m urea to zinc-bound hexameric insulin led to dissociation into dimers. Moderate concentrations of urea led to accumulation of a partially unfolded dimer state, which dissociates into an expanded, partially folded monomeric state. Very high concentrations of urea resulted in an unfolded monomer with some residual structure. The addition of even very low concentrations of urea resulted in increased fibrillation. Accelerated fibrillation correlated with population of the partially folded intermediates, which existed at up to 8 m urea, accounting for the formation of substantial amounts of fibrils under such conditions. Under monomeric conditions the addition of low concentrations of urea slowed down the rate of fibrillation, e.g. 5-fold at 0.75 m urea. The decreased fibrillation of the monomer was due to an induced non-native conformation with significantly increased alpha-helical content compared with the native conformation. The data indicate a close-knit relationship between insulin conformation and propensity to fibrillate. The correlation between fibrillation and the partially unfolded monomer indicates that the latter is a critical amyloidogenic intermediate in insulin fibrillation.     

An engineered transthyretin monomer that is nonamyloidogenic, unless it is partially denatured

Transthyretin (TTR) is a soluble human plasma protein that can be converted into amyloid by acid-mediated dissociation of the homotetramer into monomers. The pH required for disassembly also results in tertiary structural changes within the monomeric subunits. To understand whether these tertiary structural changes are required for amyloidogenicity, we created the Phe87Met/Leu110Met TTR variant (M-TTR) that is monomeric according to analytical ultracentrifugation and gel filtration analyses and nonamyloidogenic at neutral pH. Results from far- and near-UV circular dichroism spectroscopy, one-dimensional proton NMR spectroscopy, and X-ray crystallography, as well as the ability of M-TTR to form a complex with retinol binding protein, indicate that M-TTR forms a tertiary structure at pH 7 that is very similar if not identical to that found within the tetramer. Reducing the pH results in tertiary structural changes within the M-TTR monomer, rendering it amyloidogenic, demonstrating the requirement for partial denaturation. M-TTR exhibits stability toward acid and urea denaturation that is nearly identical to that characterizing wild-type (WT) TTR at low concentrations (0.01-0.1 mg/mL), where monomeric WT TTR is significantly populated at intermediate urea concentrations prior to the tertiary structural transition. However, the kinetics of denaturation and fibril formation are much faster for M-TTR than for tetrameric WT TTR, particularly at near-physiological concentrations, because of the barrier associated with the tetramer to folded monomer preequilibrium. These results demonstrate that the tetramer to folded monomer transition is insufficient for fibril formation; further tertiary structural changes within the monomer are required.     

Influence of T-2 and HT-2 Toxin on the Blood-Brain Barrier In Vitro: New Experimental Hints for Neurotoxic Effects

The trichothecene mycotoxin T-2 toxin is a common contaminant of food and feed and is also present in processed cereal derived products. Cytotoxic effects of T-2 toxin and its main metabolite HT-2 toxin are already well described with apoptosis being a major mechanism of action. However, effects on the central nervous system were until now only reported rarely. In this study we investigated the effects of T-2 and HT-2 toxin on the blood-brain barrier (BBB) in vitro. Besides strong cytotoxic effects on the BBB as determined by the CCK-8 assay, impairment of the barrier function starting at low nanomolar concentrations were observed for T-2 toxin. HT-2 toxin, however, caused barrier disruption at higher concentrations compared to T-2 toxin. Further, the influence on the tight junction protein occludin was studied and permeability of both toxins across the BBB was detected when applied from the apical (blood) or the basolateral (brain) side respectively. These results clearly indicate the ability of both toxins to enter the brain via the BBB.