AN EXAMINATION OF THE CYTOTOXIC EFFECTS OF SILICA ON MACROPHAGES

doi:10.1084/jem.124.2.141

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ARTICLE

AN EXAMINATION OF THE CYTOTOXIC EFFECTS OF SILICA ON MACROPHAGES

A. C. Allison B.M.¹, J. S. Harington M.B.¹, and M. Birbeck M.Sc.¹

¹ From the National Institute for Medical Research, and the Chester Beatty Research Institute, London, England

Effects of silica, diamond dust, and carrageenan on mouse macrophageswere studied by phase-contrast cine-micrography, electron microscopy,histochemical techniques for lysosomal enzymes and measurementsof the release of lysosomal enzymes into the culture medium.

Alladded materials were rapidly taken up into phagosomes, to whichlysosomes became attached. In all cases lysosomal enzymes weredischarged into the phagosomes to form secondary lysosomes.Within 24 hr most of the silica particles and enzyme had escapedfrom the secondary lysosomes and lysosomal enzymes were foundin the culture media. Most macrophages were killed by this time.With nontoxic particles (diamond dust, aluminium-coated silica,or silica in the presence of the protective agent polyvinyl-pyridine-N-oxide,PVPNO) ingested particles and lysosomal enzymes were retainedwithin the secondary lysosomes for a much longer time, and cytotoxiceffects were considerably delayed or absent altogether.

It isconcluded that silica particles are toxic because they are efficientlytaken up by macrophages and can then react relatively rapidlywith the membranes surrounding the secondary lysosomes. Theparticles and lytic enzymes can then escape into the cytoplasm,producing general damage, and thence into the culture medium.It is suggested that hydrogen bonding of silicic acid with lipidand protein constituents of the membrane accounts for the inducedpermeability. Protective agents such as PVPNO are retamed inlysosomes and preferentially form hydrogen bonds with silicicacid.

Carrageenan is demonstrable within macrophages by itsmetachromatic reaction. It brings about release of enzymes fromsecondary lysosomes, but much more slowly than does silica.Silica released from killed macrophages is as cytotoxic as theoriginal preparation. It is suggested that repeated cycles ofmacrophage killing in vivo leads to the mobilization of fibroblastsand fibrogenesis characterizing the disease silicosis.

Submitted on March 8, 1966

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