Mechanism of cAMP-induced H(+)-efflux of Dictyostelium cells: a role for fatty acids.

Aggregating Dictyostelium cells release protons when stimulated with cAMP. To find out whether the protons are generated by acidic vesicles or in the cytosol, we permeabilized the cells and found that this did not alter the cAMP-response. Proton efflux in intact cells was inhibited by preincubation with the V-type H(+) ATPase inhibitor concanamycin A and with the plasma membrane H(+) ATPase blocker miconazole. Surprisingly, miconazole also inhibited efflux in permeabilized cells, indicating that this type of H(+) ATPase is present on intracellular vesicles as well. Vesicular acidification was inhibited by miconazole and by concanamycin A, suggesting that the acidic vesicles contain both V-type and P-type H(+) ATPases. Moreover, concanamycin A and miconazole acted in concert, both in intact cells and in vesicles. The mechanism of cAMP-induced Ca2(+)-fluxes involves phospholipase A2 activity. Fatty acids circumvent the plasma membrane and stimulate vesicular Ca2(+)-efflux. Here we show that arachidonic acid elicited H(+)-efflux not only from intact cells but also from acidic vesicles. The target of regulation by arachidonic acid seemed to be the vesicular Ca2(+)-release channel.

Differential effect of amphotericin B on the three evolutive stages of Trypanosoma cruzi and on the host cell-parasite interaction

1. Amphotericin B (Am.B) was shown to have a direct effect on T. cruzi, with the three forms of the parasite presenting different susceptibilities to the drug in the following order: amastigotes > trypomastigotes > epimastigotes. These differences highlight the importance of using the vertebrate forms of the parasite in tests of new drugs. 2. The treated parasites showed alterations of the plasma membrane, suggesting that, as in fungi, the primary effect of Am.B was probably via formation of complexes with membrane components. 3. When exposed to filipin, another polyene antibiotic, the three parasite forms were observed to present a similar order of susceptibility, with comparable ultrastructural modifications. 4. Higher concentrations of Am.B were required to damage the intracellular parasites in vitro, 2.3 micrograms/ml for parasites inside peritoneal macrophages and 7 micrograms/ml for parasites inside heart muscle cells. 5. Am.B is effective against the parasite, but is also toxic to mammalian cells. Testing of Am.B for the control of Chagas' disease by blood transfusion may be useful, since bloodstream forms are lysed by lower concentrations of the drug than those required to affect intracellular parasites