All-or-none interactions of inhibitors of the plasma membrane ATPase with Saccharomyces cerevisiae

Potassium ion efflux induced by cationic compounds in yeast

Potassium efflux in yeast induced by several cationic compounds showed different characteristics. All of the observed efflux required glucose as substrate at the concentrations used. For most of them, the phenomenon required binding of the cationic compound to the cell surface and increased with the negative cell surface charge, and for all the compounds tested, it depended on a metabolizable substrate. Efflux induced with terbium chloride appeared more likely due to the function of a K+/H+ antiporter. With DEAE-dextran and dihydrostreptomycin, potassium efflux was dependent on the cell potassium content and was also sensitive to osmotic changes of the medium. DEAE-dextran-provoked efflux was not due to cell disruption. Dihydrostreptomycin seemed to activate a potassium efflux system which could not be studied in isolation, but its inhibition of potassium uptake may also be involved. Except for cells treated with ethidium bromide, no appreciable cell disruption was observed. The potassium efflux observed appears to be a membrane phenomenon reversible after washing with magnesium chloride.

Photodynamic treatment of yeast cells with the dye toluidine blue: all-or-none loss of plasma membrane barrier properties

Photodynamic treatment of Kluyveromyces marxianus with the sensitizer Toluidine blue leads to the loss of colony forming capacity. In this paper, the influence of this treatment on the barrier properties of the plasma membrane has been studied. Photodynamic treatment with the dye Toluidine blue resulted in efflux of potassium ions and E260-absorbing material. Moreover, cells became stainable with erythrosine. It is concluded that the permeability change induced by photodynamic treatment proceeds in an all-or-none fashion. Treatment of this yeast strain, with the dye and light, also induced a diminution of the cell volume. This process is most likely not coupled to the cellular potassium content, but rather to the integrity of the vacuole. These data suggest that the vacuole has an important function in the maintenance of cell volume. Finally, it was observed that the loss of cell viability was not induced by the all-or-none loss of barrier properties.

Are proton symports in yeast directly linked to H(+)-ATPase acidification?

Transport of amino acids in Saccharomyces cerevisiae is an H(+)-driven secondary active transport. Inhibitors of the plasma membrane H(+)-ATPase, particularly heavy water, diethylstilbestrol and suloctidil, were shown to affect the H(+)-extruding ATPase activity as well as the ATP-hydrolyzing activity, to a similar degree as they inhibited the transport of amino acids. The inhibitors had virtually no effect on the membrane electric potential or on the delta pH which constitute the thermodynamically relevant source of energy for these transports. Transport of acidic amino acids was affected much more than that of the neutral and especially of the basic ones. The effects were greater with higher amino acid concentrations. All this is taken as evidence that the amino acid carriers respond kinetically to the presence of protons directly at the membrane site where they are extruded by the H(+)-ATPase, rather than to the overall protonmotive force.

An energy-dependent efflux system for potassium ions in yeast

An efflux of potassium ions was demonstrated in mutants of yeast cells lacking a functional high affinity carrier system for monovalent cations. This efflux showed the following characteristics: (a) It was stimulated by the presence of a substrate, either glucose or ethanol. (b) It was stimulated by several cationic organic molecules, such as ethidium bromide, dihydrostreptomycin, diethylaminoethyldextran, and also by trivalent cations, such as Al3+ and lanthanides; this stimulation also depended on the presence of a substrate. (c) K+ efflux was decreased in yeast mutants with decreased ATPase activity, which generated a lower membrane potential. (d) Although the efflux appeared to be of an electrogenic nature, producing hyperpolarization of cells, it was accompanied by the efflux of phosphate, probably as an anion partially compensating for the large amount of cations leaving the cell. (e) K+ efflux was also accompanied by an uptake of protons. (f) The efflux appeared more clearly in cells grown in YPD medium, and not in more complex media nor in the same YPD medium if supplemented with Ca2+ or Mg2+. Efflux of monovalent cations produced by Tb3+ and organic cationic agents was also demonstrated in wild type strains. This efflux system appears to be, at least partially, electrogenic, but seems to be also an exchange system for protons and to function as a symport with phosphate; it may be involved in the regulation of the internal pH of the cell, and appears to be regulated by its link to the energetic status of the cell, probably through the membrane potential.

Simulation of all-or-none K+ efflux from yeast provoked by xenobiotics

In experiments dealing with the effect of xenobiotics upon the efflux of K+ from yeast cells, one should be aware that when this efflux proceeds via an all-or-none process, the K+ being released from the intoxicated cells can again be accumulated into the still unaffected cells. Therefore, the measured net efflux of K+ will be less than the efflux from the intoxicated cells. The difference between these two magnitudes can be minimalized by incubating the cells for only a short period and on applying yeast densities that are not too high. When the cells are permeabilized relatively slowly but ultimately to a great extent, the kinetics of K+ efflux may be quite complicated.

The effects of azole and polyene antifungals on the plasma membrane enzymes of Candida albicans

The two clinically important classes of antimycotic drugs, the polyenes and azoles, act on the plasma membrane of the cell. The primary modes of action are believed to be through interaction with sterols (polyenes) and alteration in sterol composition of the membrane (azoles). In this report we show that, at growth inhibitory concentrations, the polyenes (nystatin and amphotericin) and azoles (miconazole and ketoconazole) also inhibit plasma membrane enzymes. There was extensive (greater than 75%) inhibition of the Candida albicans plasma membrane enzymes ATPase, glucan synthase, adenyl cyclase and 5'-nucleotidase, when assayed in situ. The antifungals papulacandin and echinocandin, which inhibit glucan synthesis, also inhibited plasma membrane enzymes in situ; glucan synthase (greater than 90%), 5'-nucleotidase (greater than 80%) and ATPase (70-80%). Purified plasma membrane was prepared from yeast cells of C. albicans by two different techniques: concanavalin A stabilization and coating of spheroplasts with silica microbeads. In the purified plasma membrane vesicles prepared from concanavalin A the adenyl cyclase and phosphodiesterase were extensively (greater than 90%) inhibited by the three different classes of antifungal drugs; variable inhibition was observed with ATPase (70-100%). The 3',5'-cyclic phosphodiesterase of the plasma membrane purified by the microbeads method was almost completely inhibited by all of the antifungals tested and there was partial inhibition of ATPase (20-85%) and adenyl cyclase (30-90%).

The lysosomal H+ pump: 8-azido-ATP inhibition and the role of chloride in H+ transport

Lysosomes (tritosomes) were purified from the livers of rats injected with Triton WR 1339. The lysosomes developed an Mg2+-ATP-dependent pH gradient as measured by Acridine orange accumulation. H+ transport was supported by chloride, but not sulfate, and was independent of the cation used. H+ transport and Mg2+-stimulated ATPase was inhibited by diethylstilbesterol (K0.5 = 2 microM). N-Ethylmaleimide inhibited H+ transport (K0.5 = 30 microM). At low concentrations of N-ethylmaleimide, ATP partially protected H+ transport from inhibition with N-ethylmaleimide. Photolysis with 8-azido-ATP inhibited H+ transport and Mg2+-stimulated ATPase activity. Under these same conditions, 8-azido-[alpha-32P]ATP reacted with a number of polypeptides of the intact lysosome and lysosomal membranes. Pump-dependent potentials were measured using the fluorescent potential-sensitive dye, DiSC3(5) (3,3'-dipropylthiocarbocyanine) and ATP-dependent potential generation was inhibited by diethylstilbesterol. Chloride, but not sulfate reduced the magnitude of the ATP-dependent membrane potential, as measured using merocyanine 540. The chloride conductance, independent of ATP, was of sufficient magnitude to generate a H+ gradient driven by external chloride in the presence of tetrachlorosalicylanilide. In Cl- free media, ATP-dependent H+ transport was restored to control levels by outwardly directed K+ gradients in the presence of valinomycin. The role of cell Cl- is to provide the necessary conductance for supporting lysosomal acidification by the electrogenic proton pump.

Isolation of mutants of Candida glabrata resistant to miconazole

Elucidation of the mode of action of azole antifungals would be aided by studying resistant mutants. It is difficult to obtain mutants of Candida albicans in the laboratory, and there have only been a few studies on clinical isolates which seem to be resistant because of impaired drug uptake. C. glabrata, unlike C. albicans, is haploid and more likely to give rise to resistant variants. Over 30 mutants have been isolated by selection with miconazole on solid medium and have MICs of miconazole about ten times that of the parental strain. One such mutant has a reduced growth rate and final cell yield. In intact cells, ergosterol biosynthesis is tenfold less sensitive to miconazole than in the parent. However, uptake of [3H]miconazole by cells is identical in both strains. The significance of these observations is discussed.

A study of the mechanism by which inhibitors of the plasmamembrane ATPase enhance uptake of divalent cations in yeast

The enhancement of divalent cation uptake in yeast provoked by the membrane ATPase inhibitors trifluoperazine, miconazole, compound 48/80, ethidium, DIO-9 and calmidazolium should be ascribed to an increase in cation permeability of the yeast rather than to hyperpolarisation of the yeast cell membrane. For trifluoperazine and miconazole it is unequivocally shown that the cells are hyperpolarized though for miconazole only transiently. Whether the other drugs also hyperpolarize the yeast cells is uncertain. The apparent hyperpolarisation caused by trifluoperazine and miconazole may be attributed to a specific increase in the K+ permeability of the yeast plasmamembrane evoked by these compounds.

Detection of a yeast polyphosphate fraction localized outside the plasma membrane by the method of phosphorus-31 nuclear magnetic resonance

Non-penetrating cations, like UO2+(2) and Eu3+, are bound to the outside of yeast cells in a reversible fashion. Binding of these ions was attended with a decrease of the 31P NMR polyphosphate signal. Subsequent addition of EDTA to the suspension restored the original spectrum. These experiments confirm the localization of a polyphosphate fraction outside the plasma membrane of yeast.