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

Perfringolysin O: The Underrated Clostridium perfringens Toxin?

The anaerobic bacterium Clostridium perfringens expresses multiple toxins that promote disease development in both humans and animals. One such toxin is perfringolysin O (PFO, classically referred to as θ toxin), a pore-forming cholesterol-dependent cytolysin (CDC). PFO is secreted as a water-soluble monomer that recognizes and binds membranes via cholesterol. Membrane-bound monomers undergo structural changes that culminate in the formation of an oligomerized prepore complex on the membrane surface. The prepore then undergoes conversion into the bilayer-spanning pore measuring approximately 250–300 Å in diameter. PFO is expressed in nearly all identified C. perfringens strains and harbors interesting traits that suggest a potential undefined role for PFO in disease development. Research has demonstrated a role for PFO in gas gangrene progression and bovine necrohemorrhagic enteritis, but there is limited data available to determine if PFO also functions in additional disease presentations caused by C. perfringens. This review summarizes the known structural and functional characteristics of PFO, while highlighting recent insights into the potential contributions of PFO to disease pathogenesis.

Binding, oligomerization, and pore formation by streptolysin O in erythrocytes and fibroblast membranes: detection of nonlytic polymers

Streptolysin O (SLO) is a representative of the family of cholesterol-binding cytolysins that form large pores in target cell membranes. Aggregation of the toxin to polymeric structures is required for pore formation. However, it is not known whether, vice versa, polymers may under certain circumstances remain nonfunctional, and whether this might be the cause underlying the relative resistance of certain cells towards toxin action. In the present study, we applied radioiodinated, functionally active SLO to human, rabbit, and mouse erythrocytes and to human fibroblasts and keratinocytes. Binding and polymerization were quantified and correlated with membrane damage. At low toxin concentrations, human and rabbit but not mouse erythrocytes were lysed, but binding and polymerization of SLO were essentially identical in all cases. Nonlytic polymers were also detected on human fibroblasts and keratinocytes treated with subcytotoxic concentrations of SLO, and quantitative estimates indicated that nonpermeabilized cells could carry hundreds of polymers on their surface. When applied at low concentrations to fibroblasts, much of the toxin remained in monomer form and was subsequently shed from the cells. This was shown by monitoring the fate of radioiodinated toxin and also by using a sensitive cell enzyme-linked immunosorbent assay that permitted immunological detection of surface-exposed SLO. Thus, relative resistance of cells towards the permeabilizing action of SLO may be due to their ability to tolerate formation of a limited number of SLO polymers and to shedding of nonoligomerized toxin from their surface.

Age-dependent decrease of the lateral diffusion constant of proteins in the plasma membrane of hepatocytes as revealed by fluorescence recovery after photobleaching in tissue smears

When fresh liver is smeared on slides and incubated in Krebs-Henseleit Ringer solution containing 1 mM H2O2 at 37 degrees C, a yellowish-green autofluorescence develops in the hepatocyte plasma membrane. Indirect evidence shows that this peroxide-induced autofluorescence (PIAF) is due most probably to chemical reactions between proteins and the malondialdehyde produced by the membrane lipid peroxidation. Although the chemical nature of the PIAF has not been clarified yet, it is suitable under certain conditions for the measurement of the average lateral diffusion constant of the membrane proteins by means of the fluorescence recovery after photobleaching (FRAP) technique without the addition of any external fluorescent label. Analysis of four age groups for both sexes of Fischer 344 rats (3-5 rats per group, total 32) from 2 to 31 months of age revealed a significant negative linear correlation of the lateral diffusion constant of proteins with age in both sexes, with the slope of the females being somewhat smaller. Young males showed a diffusion constant about 2.8 X 10(-10) decreasing to 1.7 X 10(-10) cm2 X s-1 by 31 months of age at 37 degrees C, whereas the respective values in females were 2.7 X 10(-10) and 1.9 X 10(-10). The results are consistent with the predictions of the membrane hypothesis of aging, according to which an age-dependent loss of the passive permeability of the cell membrane for potassium (and probably for water) is the crucial point of the cellular aging.