Production, purification, and composition of staphylococcal alpha toxin

Conformational alteration in alpha-toxin from Staphylococcus aureus concomitant with the transformation of the water-soluble monomer to the membrane oligomer

The membrane-damaging alpha-toxin aggregate of Staphylococcus aureus was characterized physicochemically. The aggregate weight of the toxin formed by various methods appeared to be 6 times higher than the molecular weight of the monomer as determined by the laser light scattering technique, suggesting the presence of a hexamer in the membrane. The aggregates fluoresced 20 to 50% more than the monomer at 336 nm. Circular dichroism measurements revealed that both the monomer and the oligomer showed essentially beta-sheet structure with the maximum ellipticity about -8,400 deg.cm2.dmol-1 at 215 nm. Circular dichroism spectrum of the oligomers showed ellipticity difference of -6,600, -44 and +84 deg.cm2.dmol-1, at 200, 250 and 280 nm, respectively, compared with the monomer. All these results suggest that the conformational change in the toxin molecule occurs concomitant with the transformation of the water-soluble monomer to the membrane-embedded hexamer.

Action of staphylococcal alpha-toxin on membranes: some recent advances

Recent developments in the area of Staphylococcal alpha-toxin studies are presented which modify the concepts previously held with respect to both biological and physical properties of alpha-toxin. New data concerning the nature of the binding site for alpha-toxin on rabbit erythrocyte membranes and a model to explain the various observed complexes of alpha-toxin and membrane receptor are discussed. Finally, evidence suggesting that Staphylococcal alpha-toxin is a potent demyelinating agent is presented.

Purification and some properties of a lethal toxic fragment of staphylococcal alpha-toxin by tryptic digestion

Purified staphylococcal alpha-toxin (molecular weight approximately 36,000) was mildly digested with trypsin, yielding two components by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A fast-moving component (molecular weight 17,000 +/- 5%) which is relatively resistant to tryptic digestion and a slow-moving component (molecular weight 20,000 +/- 5%) which tends to aggregate. The fast-moving component was highly purified by means of combined procedures of column chromatography on Sephadex G-200 with zone electrophoresis on starch. The purified fast-moving component retained a high degree of lethal toxicity for mouse but lacked hemolytic and dermonecrotic activities, whereas the slow-moving component proved to be a nontoxic polypeptide. The lethal toxic fragment was antigenically active showing partial immunological identity with the parent alpha-toxin and stimulated the formation of antibodies capable of neutralizing the lethal action of alpha-toxin in vivo. Some physical properties and the amino acid composition of the purified lethal toxic fragment have been compared with those of native alpha-toxin.

Spontaneous alpha-toxin mutants of Staphylococcus aureus

Prolonged cultivation of strain Wood 46 in fluid cultures resulted in a selection of mutants with low or no haemolytic activity. In one group of mutants, four out of five strains showed no production of alpha-toxin when examined by polyacrylamide gel electrophoresis and by double diffusion in agar. Two major extracellular proteins which have been identified by other methods as degradation products of alpha-toxin were also absent. The absence of alpha-toxin did not affect growth in fluid or solid media. Fibrinolysin was produced by these mutants but at a much lower rate than by the wild type. A second group of mutants was characterized by a slow rate of growth on rabbit blood agar and showed a heterogeneous extracellular protein pattern. These mutants had a high growth rate in fluid medium consisting of acid hydrolysed proteins. Production of fibrinolysin was absent or low in three out of four mutants in the second group. The slow growth and low production of alpha-haemolysin in rabbit blood agar probably was caused by deficient extracellular proteolytic activity of the mutants.

Proteolytic degradation of staphylococcal alpha-toxin

Staphylococcal alpha-toxin of mol.wt. 39,000 was degraded at an alkaline pH by staphylococcal extracellular proteases resulting in the formation of three relatively stable intermediates with mol.wt. 27,500, 23,500 and 12,000. The intermediate with mol.wt. 27,500 which existed in two charged forms, was isolated by column chromatography and found to be non-haemolytic. Furthermore, it could be obtained by proteolysis of alpha-toxin (mol.wt. 39,000) with chymotrypsin in low concentrations. This intermediate was further degraded by trypsin to the protein with mol.wt. 23,500 and 12,000.

Multiple forms of staphylococcal alpha-toxin

A group of proteins was readily extracted at neutrality from trichloroacetic acid precipitates of staphylococcal culture filtrate supernatants, while alpha-toxin was dissolved and activated by treating the precipitate with 8 M urea, with acidic buffers or by heating to 90-100 degrees C at neutrality. Heat activation of the precipitate produced a relatively pure alpha-toxin with a molecular weight of 39,000. alpha-Toxin was eluted together with three other proteins on hydroxyl apatite chromatography, and evidence was obtained for an association between the four proteins. On isoelectric focusing a haemolytic fraction was obtained at pH 6.2, probably due to acid activation of the precipitate formed at the cathodic end of the column. The alpha-haemolytic fractions with pI's of 7.4 and 8.6 were shown to consist of alpha-toxin only when analyzed by acrylamide electrophoresis in the presence of sodium dodecyl sulphate. The haemolytic component with a pI of 9.2 contained two additional components of molecular weights of 27,500 and 18,000. Chromatography of this material on Sephadex G-200 showed that alpha-toxin and the two proteins appeared as a high molecular complex.

The hemolysins of Staphylococcus aureus

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Cellular location of alpha-hemolysin in Staphylococcus aureus

Protoplast fractionation techniques were used to prepare subcellular fractions of three strains of Staphylococcus aureus for the analysis of alpha-hemolysin activity. More than 90% of the cellular hemolytic activity was localized in the periplasm, only a trace was detected in the cytoplasm, and none was found in either plasma membranes or mesosomes. This cellular portion constituted approximately 4 to 10% of the total hemolytic activity of the culture. The erythrocyte lysis spectrum and Sephadex G-100 filtration studies indicated that the cellular hemolysin closely resembles the extracellular form.

Cellular streptolysin S-related hemolysins of group A Streptococcus C203S

Group A streptococci strain C203S, grown in heart infusion broth with 0.3% maltose, produce two cellular hemolysins related to extracellular streptolysin S (SLS). Enzymatic lysis of the streptococci by group C streptococcal phage-associated lysin results in release of low titer, labile hemolysin, which can be stabilized by ribonucleic acid (RNA)-core (RNA preparation from yeast). This labile hemolysin can be detected only after the higher titer cellular streptolysin O is removed by erythrocyte membranes or inactivated by N-ethylmaleimide. The other cellular SLS-related hemolysin is released in a latent state (potential hemolysin) which can be activated to high-titer hemolysin by sonication with RNA-core. The titer of such activated hemolysin depends upon the intensity of sonic energy, duration of sonication, and amount of RNA-core. RNA obtained from the streptococci is far less effective than RNA-core. When the cocci are disrupted by sonication or grinding, potential hemolysin and/or activated form may be released, depending upon the conditions employed. The potential hemolysin material is large and heterogeneous; activation appears to involve, in part, disaggregation or fragmentation. Labile hemolysin, potential hemolysin, and the activated form of potential hemolysin can all be converted to hemolysin having the same hemolytic and physical properties as RNA-core SLS, suggesting that all have the same hemolytic moiety. The presence of glucose in heart infusion broth prevents formation of both potential hemolysin and RNA-core SLS by log-phase cells, whereas addition of glucose to a culture in heart infusion broth with 0.3% maltose stops accumulation of potential hemolysin but does not affect continuation of RNA-core SLS release. These results suggest that potential hemolysin is a cellular precursor to RNA-core SLS.

Comparison of purified alpha-toxins from various strains of Staphylococcus aureus

Alpha-toxin from five strains of Staphylococcus aureus, including Wood 46, was purified by isoelectric focusing. The alpha-toxins obtained from different strains were similar. The isoelectric point of the purified toxins was 8.65 +/- 0.15. Sharp concentration peaks were not always obtained. In the ultracentrifuge the alpha-toxins migrated usually as three peaks which could be dissociated with propionic acid to yield one peak. A single line of identity was obtained in immunoelectrophoresis when a heterologous antiserum was reacted with the five purified toxins. It was concluded that the widespread use of the Wood 46 strain for the production of alpha-toxin is justified.

Electron microscopic localization of alpha toxin within the staphylococcal cell by ferritin-labeled antibody

Highly purified staphylococcal alpha toxin has been used to produce monospecific anti-alpha antibody in rabbits. Gamma globulin prepared from the serum of these rabbits was coupled with ferritin by using toluene diisocyanate. Staphylococcal cells which had been disrupted by two passages through an LKB X-press were treated with this conjugate. Electron microscopic examination of this material showed alpha toxin or an antigenically mature precursor located on the cytoplasmic membrane. The possible function of alpha toxin in this situation is discussed.

Production of staphylococcal alpha toxin. I. Relationship between cell growth and toxin formation

Alpha toxin production and its relationship to cell growth were studied in the Wood 46 strain of Staphylococcus aureus. Toxin first appeared in the culture in the late logarithmic stage, but at least 80% was produced during the subsequent period of slower cell growth. The toxin concentration per unit of cell mass or viable count increased continually throughout the period of toxin production and and at its maximum represented 1.6 to 2.0% of the dry weight of the cells. The possibility that alpha toxin is released as a result of cell lysis was examined by using the appearance of cellular deoxyribonucleic acid in the medium as an indicator of lysis. The results showed that no appreciable amount of lysis occurred during toxin production; at a time when almost maximum amounts of toxin were present in the culture, less than% 4 of the cells had lysed. This finding, together with the observation that less than 0.25% of the total amount of toxin in the culture could be found intracellularly, indicates that alpha toxin is released from intact cells shortly after it is synthesized.

Ultracentrifugal analysis of staphylococcal alpha toxin

Ultracentrifugal examination of staphylococcal alpha toxin at different stages of purification showed the presence of a major component having a sedimentation coefficient of 2.8S, present to the extent of more than 90% of the sample, and identifiable with active toxin. Several minor components having S(20,w) values of 11.5S, 8.5S, and 2.0S were detected. The 11.5S component presumably is identical with a toxin aggregate studied earlier and designated 12S; the 8.5S component appears to be delta toxin. A sedimentation equilibrium study of more highly purified material gave 32,700 as the best estimate of molecular weight of alpha toxin. Lowering the pH of the partially purified alpha toxin from 10.2 to 5.3 resulted in a small increase in S(20,w) of the 11.5S component and in the disappearance of the 8.5S component, whereas the S(20,w), molecular weight, and hemolytic activity of the toxin remained constant. Exposure of toxin to pH 3.5 irreversibly reduced the S(20,w) to 2.0S, the molecular weight to about 16,000, and caused irreversible inactivation. Raising the pH of acid-inactivated toxin and adding sodium dodecyl sulfate to 1% increased the S(20,w) to near its normal value (2.7S) but did not restore activity.

Properties of purified staphylococcal beta-hemolysin

Purification of beta-hemolysin was achieved by ammonium sulfate precipitation, Sephadex G-100 gel filtration, carboxymethyl cellulose column chromatography, and density gradient electrophoresis. Active fractions eluted from carboxymethyl cellulose contained at least one nonhemolytic protein, and omission of this step was not detrimental to the purification process. Density gradient electrophoresis yielded approximately 1.6 mg of highly active purified beta-hemolysin per liter of culture supernatant liquid. Purified beta-hemolysin gave a single line on gel double diffusion and immunoelectrophoresis. A single symmetrical peak formed in the analytical ultracentrifuge, and the sedimentation coefficient was calculated to be 1.7S. The purified beta-hemolysin was stable at 4 C and could be lyophilized. Magnesium cations were required for full expression of beta-hemolytic activity. beta-Hemolysin was lethal for rabbits when injected intravenously in amounts between 40 and 160 mug. Crude beta-hemolysin was more stable than purified beta-hemolysin when heated at 60 C for 30 min. Purified beta-hemolysin lost almost all of its activity on subsequent heating at 100 C for 10 min.

Inhibition of staphylococcal alpha-toxin. A kinetic evaluation of aromatic polysulphonic acids as inhibitors of haemolysis

1. The effect of a number of aromatic polysulphonic acids on the kinetics of haemolysis of rabbit erythrocyte suspensions by crude staphylococcal alpha-toxin was studied at pH8.6 and 6.8. 2. All of the inhibitory compounds caused an increase in the prelytic lag time (tau) of the sigmoid haemolysis curves, an increase in the time to reach 50% haemolysis (t((1/2))) and a decrease in the maximum rate of haemolysis (R(max.)). The most inhibitory compounds caused a 50% decrease in R(max.) at concentrations between 0.1 and 0.2mm. 3. The effect of pH varied considerably: compounds (I) and (II) were almost equally inhibitory at both pH values, compounds (IV) and (IX) were more inhibitory at pH6.8 than at pH8.6, and compounds (VII), (VIII), (X), (XI) and (XII) were more inhibitory at pH8.6. 4. Increased time of premixing alpha-toxin with compound (I) caused increased inhibition. 5. An attempt was made, where possible, to relate the inhibitory activity to the structure of the test compound.

Physical states of staphylococcal alpha-toxin

At least three different forms of staphylococcal alpha-toxin have been shown to exist: soluble active alpha-toxin (alpha 3S), soluble inactive alpha-toxin (alpha(12s)), and insoluble inactive aggregate. Aggregation to the insoluble, biologically inactive form could be induced by brief heating to 60 C. The aggregate was dissociated by treatment with 8 m urea with reappearance of biological activity. Subsequent removal of urea by dialysis resulted in some spontaneous reaggregation to the insoluble state. The supernatant fluid obtained after dialysis contained soluble active alpha-toxin of high specific activity, possessing physical, toxic, and immunological properties closely resembling those of native toxin. The soluble biologically inert component (alpha(12s)) was identified as a third physical state. Negatively stained preparations of this material, when examined in the electron microscope, showed rings of approximately 100 A outside diameter containing 6 +/- 1 subunits.