Abstract
The pathogenicity of quartz involves lysosomal alteration in alveolar macrophages. This event triggers the inflammatory cascade that may lead to quartz-induced silicosis and eventually lung cancer. Experiments with synthetic quartz crystals recently showed that quartz dust is cytotoxic only when the atomic order of the crystal surfaces is upset by fracturing. Cytotoxicity was not observed when quartz had as-grown, unfractured surfaces. These findings raised questions on the potential impact of quartz surfaces on the phagolysosomal membrane upon internalization of the particles by macrophages. To gain insights on the surface-induced cytotoxicity of quartz, as-grown and fractured quartz particles in respirable size differing only in surface properties related to fracturing were prepared and physico-chemically characterized. Synthetic quartz particles were compared to a well-known toxic commercial quartz dust. Membranolysis was assessed on red blood cells, and quartz uptake, cell viability and effects on lysosomes were assessed on human PMA-differentiated THP-1 macrophages, upon exposing cells to increasing concentrations of quartz particles (10–250 µg/ml). All quartz samples were internalized, but only fractured quartz elicited cytotoxicity and phagolysosomal alterations. These effects were blunted when uptake was suppressed by incubating macrophages with particles at 4 °C. Membranolysis, but not cytotoxicity, was quenched when fractured quartz was incubated with cells in protein-supplemented medium. We propose that, upon internalization, the phagolysosome environment rapidly removes serum proteins from the quartz surface, restoring quartz membranolytic activity in the phagolysosomes. Our findings indicate that the cytotoxic activity of fractured quartz is elicited by promoting phagolysosomal membrane alteration.
Highlights
Exposure to crystalline silica dusts, in particular quartz, induces severe toxic effects in humans (American Thoracic Society 1997; Parks et al 1999; Leung et al 2009; IARC 2012)
We investigate the effects of quartz dusts on THP-1 monocytes phorbol 12-myristate 13-acetate (PMA)-differentiated into macrophages, chosen as a model for alveolar macrophages, and we focus on quartz impact on the phagolysosomal membrane
One of the most robust paradigm about the origin of the toxicological response to quartz dust involves the interaction of particles internalized by macrophages with the phagolysosomal membrane as the molecular initiating event (MIE) of quartz-induced cytotoxic and inflammatory response (Pavan and Fubini 2017)
Summary
Exposure to crystalline silica dusts, in particular quartz, induces severe toxic effects in humans (American Thoracic Society 1997; Parks et al 1999; Leung et al 2009; IARC 2012). It is known that a cluster of dust properties, including particle size (Wiessner et al 1989; Fenoglio et al 2000), the capacity to induce free radicals (Vallyathan et al 1988; Dalal et al 1990; Schins et al 2002), and the degree of hydrophilicity, related to the distribution of siloxanes and silanol families on the particle surface (Bolis et al 1991; Hemenway et al 1994), give a contribution to the adverse effects of quartz in vitro and in vivo. A revisited mechanism of toxicity for quartz particles in the alveolar space has been proposed (Pavan and Fubini 2017). According to this model, inhaled particles are recognized and internalized by alveolar macrophages to be cleared out from the lungs (Hamilton et al 2008). The deposition of non-cleared particles onto the alveolar epithelium causes the recruitment and the activation of new macrophages and neutrophils, in a self-sustained detrimental process which gives rise to persistent inflammation, as long as the particles remain in the alveolar space
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