Altered calcium homeostasis and membrane destabilization in erythrocytes of hamsters infected with Leishmania donovani.

Homeostatic mechanisms regulating intracellular concentrations of Ca2+ at a low level are prerequisites for maintaining the integral and cytoskeletal structure of erythrocytes under normal physiological conditions. The present study was undertaken to assess the contribution of Ca2+ homeostasis in modifying red-cell stability in hamsters, during the anaemia caused by Leishmania donovani. Erythrocytes from the infected animals became increasingly fragile as infection progressed. This fragility may be the result of a gradual change in membrane permeability, as indicated by enhanced uptake of 45Ca2+. The increase in cytosolic Ca2+ and decrease in membrane-bound Ca2+ observed indicate the release of Ca2+ from the membrane store, leading to [Ca2+]i accumulation in the later stages of the post-infection period. Decline in the efficacy of Ca(2+)-effluxing enzyme may also contribute to the enhanced [Ca2+]i level, with subsequent degradation of membrane proteins in the erythrocytes of the infected animals. Marked inhibition of proteolytic degradation by the Ca(2+)-dependent thiol protease inhibitor leupeptin, with concomitant thiol depletion, indicates the involvement of Ca(2+)-induced thiol protease in the observed degradation of membrane proteins. The results indicate that an altered Ca2+ homeostasis in erythrocytes following leishmanial infection causes enhanced cellular accumulation of Ca2+, which in turn may lead to haemolysis in experimental visceral leishmaniasis.