Ken'ichiro Mitsui

The quaternary structure of carp muscle alkaline protease

Abstract Carp muscle alkaline protease consists of four kinds of subunits, and its composition was assumed to be ( αβγ 2 δ 2 ) 4 . It dissociated in the presence of 2-mercaptoethanol into an enzyme and α-subunits which upon removal of 2-mercaptoethanol rapidly aggregated to form a precipitate. The composition of the 2-mercaptoethanol-treated enzyme was ( βμ 2 δ 2 ) 4 . The pH of a 2-mercaptoethanol-treated enzyme solution was lowered to 4.5 by the addition of acetic acid in the presence of 0.4 M LiCl and centrifuged to separate the precipitate formed; this exhibited little activity and was mainly composed of β-subunits. The supernatant fluid recovered 53% of activity and contained an enzyme, whose composition was ( γ 4 δ 4 ) 4 . The temperature-activity curve of the native enzyme was the same as that of the 2-mercaptoethanol-treated enzyme and both were unable to hydrolyze casein at all below 55°C. However, the temperature dependence for activity of the LiCl-treated enzyme was ordinary: it hydrolyzed casein at physiological temperatures. When the 2-mercaptoethanol-treated enzyme was incubated with 4.5 M urea at 45°C for 20 min and this was followed by column chromatography, a little activity was recovered and the amount of recovery was parallel with the amount of δ-subunit in the fractions. These findings suggest; (1) the α-subunit does not take any part in activity but is a protein necessary for binding between subunits or between the enzyme and some functional proteins in the cells, (2) the β-subunit is used as inhibitor in the quaternary structure of the enzyme, (3) the δ-subunit is the catalytic one, and (4) binding with the γ-subunit is necessary for the δ-subunit to retain its active comformation.

Ring formation of perfringolysin O as revealed by negative stain electron microscopy.

Abstract Perfringolysin O revealed ring- and arc-shaped structures in the absence of cholesterol by negative staining electron microscopy, while before activation with cysteine it showed indistinct arcs and irregularly curved sticks but no rings. These structures were observed only at high concentrations (more than 17 000 hemolytic units per ml) and seemed to be particle associates with 20–28 particles (about 4 nm per particle) linked in a circle. The toxin produced an inactive and high molecular weight complex in the presence of phosphotungstic acid, which was isolated by Sephadex gel filtration. These findings suggest that the rings are the toxin-phosphotungstic acid complexes produced during specimen preparation on a grid in vacuo. The toxin lost the properties necessary for ring formation though moderate modification with glutaraldehyde, showing spindle- and egg-shaped particles of about 4 nm in minor and 5 nm in major axis by negative staining. These facts suggest that the aldehyde modifies the binding sites for phosphotungstic acid, which probably are the basic groups of the toxin molecules. In the presence of cholesterol, even at a low concentration, the toxin revealed rings and arcs by negative staining and also by carbon shadowing electron microscopy, although the toxin itself did not show any characteristic structure without phosphotungstic acid. These observations suggest that the rings are the toxin-cholesterol complexes themselves. The toxin-phosphotungstic acid complexes seemed to have a structure of a single layer of particle associates, while that of the toxin-cholesterol complexes may consist of double or triple layers of the associates because its border was thicker and more distinct.

A modified θ-toxin produced by limited proteolysis and methylation : a probe for the functional study of membrane cholesterol

A derivative of cytolytic theta-toxin from Clostridium perfringens was prepared by limited proteolytic digestion of the native toxin followed by methylation. Among the chloroform/methanol-extractable, lipid components of sheep and human erythrocytes, the proteinase-nicked and methylated derivative (MC theta) specifically binds to cholesterol. While MC theta retains binding affinity comparable to that of intact toxin, it causes no obvious membrane damage, resulting in no hemolysis at temperatures of 37 degrees C or lower. Using MC theta, we demonstrated the possible existence of high- and low-affinity sites for theta-toxin on sheep erythrocytes at both 37 degrees C and 10 degrees C. The number of high-affinity sites on sheep erythrocytes was estimated to be approximately 3-times larger at 37 degrees C than that at 10 degrees C. In addition, high- and low-affinity sites were demonstrated in human erythrocytes and a lymphoma B cell line, BALL-1 cells. Both binding sites disappear upon simultaneous treatment of cells with sublytic doses of digitonin, suggesting that cholesterol is an essential component of both the high- and low-affinity sites and that the mode of cholesterol existence in plasma membranes is heterogeneous in these cells. Because of its high affinity for membrane cholesterol without causing any obvious membrane changes at physiological temperatures, MC theta may provide a probe for use in the functional study of membrane cholesterol.

Membrane disorganization induced by perfringolysin O (theta-toxin) of Clostridium perfringens — effect of toxin binding and self-assembly on liposomes

theta-Toxin (perfringolysin O) of Clostridium perfringens binds to membrane cholesterol with high (Kd approximately 10(-9) M) and low (Kd approximately 10(-7) M) affinities and causes membrane lysis of intact cells and liposomes. In order to understand the lytic process at the molecular level, the lysis of liposomes was investigated in comparison with that of intact cells. The toxin dose required to cause 50% lysis (RD50) of phosphatidylcholine/phosphatidylglycerol (82:18, mol/mol) liposomes containing 36-40 mol% cholesterol was 300-1400-times higher than the RD50 value for sheep or human erythrocytes when samples with the same cholesterol concentration were compared. However, the average number of toxin molecules bound per liposome vesicle at 50% lysis was estimated as 10-18 from the RD50 values, close to the number on erythrocytes at 50% lysis, suggesting that the number of toxin molecules adsorbed per vesicle is important for lysis. As to the toxin dose required for membrane lysis, no significant difference was observed between liposomes containing both high- and low-affinity toxin-binding sites and those containing only low-affinity sites, suggesting that theta-toxin molecules bound to low-affinity sites can assemble and cause membrane lysis as well as those bound to high-affinity sites. theta-Toxin assembles on liposomal membranes, as on erythrocytes, in a high-molecular-weight polymeric form as judged from sedimentation patterns in sucrose density-gradient centrifugation. The high-molecular-weight polymers were detected only under conditions where cell or liposome lysis occurred. At low toxin doses, slower sedimenting toxin oligomers and monomers were predominant on liposomal membranes. These results indicate that toxin assembly on membranes is essential for liposome lysis as it is for cell lysis and that assembly occurs on membranes without membrane proteins.

Purification and Some Properties of Tetanolysin

Tetanolysin was purified from the culture fluid of a strain of Clostridium tetani by ammonium sulfate fractionation, acetone precipitation and repeated gel filtration. Two hemolysins with different molecular weights were separated by gel filtration, and the smaller one, tetanolysin, was further purified. The purification raised the specific activity of tetanolysin 1,050‐fold to 500 HU/μg of protein. The purified preparation gave a single, relatively broad band on polyacrylamide gel electrophoresis, in which the activity was roughly parallel with the protein concentration. However, on sodium dodecylsulfate‐gel electrophoresis it gave two bands with nearly equal amounts of proteins, showing molecular weights of 53,000 and 48,000±3,000. Furthermore, isoelectric focusing revealed four peaks of the activity whose isoelectric pHs were 6.1, 5.6, 5.3, and 6.6 in decreasing order of the activity. These findings suggest that the preparation contains four hemolysins with different pis, which are classifiable into two groups by molecular size. The preparation was completely free of tetanus neurotoxin and proteases. Tetanolysin was more strongly inhibited by cholesterol and more rapidly adsorbed onto erythrocytes than θ‐toxin of Cl. perfringens.

Effects of cholesterol evulsion on susceptibility to perfringolysin o of human erythrocytes

Human erythrocytes preincubated with a phosphatidylcholine suspension (preincubated cells) showed decreased susceptibility to perfringolysin O, the decrease being strongly affected by preincubation time and temperature, and the phosphatidyl choline concentration. The binding of the toxin to the preincubated cells also decreased with the preincubation time and reached minimum at 37 degrees C for 6 h. Through this preincubation, about 30% of cholesterol was removed from cells without lysis. The susceptibility of preincubated cells to the toxin seemed to be affected by the amount of cholesterol removed from cells, but not by the cholesterol content of cell membranes. This indicates that most of the cholesterol interactive with the toxin is removable from cell membranes by preincubation with phosphatidylcholine suspension, and that the residual cholesterol is firmly constituted in the membrane structure and cannot interact with the toxin. After cholesterol evulsion by the preincubated plasma method (Murphy, J.R. (1962) J. Lab. Clin. Med. 60, 86-109 and 60, 571-578), cells also exhibited lower susceptibility to the toxin and to saponins, but higher susceptibility to lysophosphatidylcholine.

Chemokine Production by Rat Macrophages Stimulated with Streptolysin O from Streptococcus pyogenes

The contribution of streptolysin O (SLO) from Streptococcus pyogenes to neutrophil infiltration in inflammatory lesions was determined by production of cytokine‐induced neutrophil chemoattractant (CINC)−1, −2 and −3, and macrophage inflammatory protein (MIP)‐1α by rat macrophages stimulated with SLO in culture. Active SLO induced the production of CINCs and MIP‐1α in dose‐ and time‐dependent manners. These inductions were ascertained by chemokine mRNA expression in macrophages. Streptolysin S was without effect. The SLO‐cholesterol complex induced the chemokine production in proportion to the residual hemolytic activity of the complex. In addition, the effects of SLO on the chemokine production were confirmed by the injection of active SLO into the preformed air pouch on the back of rats. The infiltration of neutrophils into the pouch fluid (exudate) increased steadily with a lag phase of about 2 hr. The major chemokine found in exudates was MIP‐1α but not CINCs. In this study, it became clear that active SLO, but not the inactive one, contributed to the production of MIP‐1α and CINCs in the conditioned medium and in exudates.

Activation of phosphatidic acid metabolism of human erythrocyte membranes by perfringolysin O

The effect of perfringolysin O on the lipid metabolism of human erythrocyte membranes was investigated. Erythrocytes were prelabeled with [3H]arachidonic acid and [32P]inorganic phosphate. In the presence of calcium ion(5.5 mM), the effect of perfringolysin O on lipid metabolism was very similar to that of an calcium-ionophore A23187. In the absence of calcium ion, the accumulation of phosphatidic acid and its following decreasing trend were observed during the reaction with the toxin. Such changes were not caused by filipin. These results suggest that perfringolysin O causes the activation of a diglyceride-phosphatidic acid cycle, which might be involved in the calcium transport.