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The peroxisome (microbody) membrane: effects of detergents and lipid solvents on its ultrastructure and permeability to catalase

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Synopsis

The effects of detergents, organic lipid solvents, and several adjuvants used in cell fractionation on the ultrastructure of the peroxisomal (microbody) membrane and its permeability to catalase have been investigated. Chopper sections of glutaraldehyde-fixed liver were incubated in the presence of various agents, followed by cytochemical staining for catalase and processed for electron microscopy. Catalase activity was also determined biochemically in the incubation medium. Marked catalase diffusion was found after treatment with 1% or 0.5% Triton X-100 or deoxycholate, as well as with 50% ethanol or acetone or 20% propanol ort-butanol. In contrast, 1% digitonin and lower concentrations of the above agents, as well as sucrose or glycerine caused selective diffusion of catalase from a limited population of peroxisomes. Tieatment with 10% polyvinylpyrrolidone (PVP), which has been used as a protective agent in the isolation of microbodies, did not produce any alteration in the fine structure and cytochemical appearance of peroxisomes. These findings concur with earlier biochemical studies on freshly isolated peroxisomes and demonstrate the susceptibility of microbodies, even in glutaraldehyde-fixed rat liver to the effects of various agents which affect the microbody membrane. A close correlation between the ultrastructural integrity of the microbody membrane and its permeability to catalase has been found. The significance of these observations for the assessment of the permeability characteristics of the microbody membrane is discussed.

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  1. Department of Anatomy, II Division, University of Heidelberg, 6900, Heidelberg, West Germany

    S. Yokota & H. D. Fahimi

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  1. S. Yokota
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  2. H. D. Fahimi
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Yokota, S., Fahimi, H.D. The peroxisome (microbody) membrane: effects of detergents and lipid solvents on its ultrastructure and permeability to catalase. Histochem J 10, 469–487 (1978). https://doi.org/10.1007/BF01003010

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  • DOI: https://doi.org/10.1007/BF01003010

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