An H(+)-ATPase regulates cytoplasmic pH in Pneumocystis carinii trophozoites

Functional complementation of the yeast P-type H-ATPase, PMA1, by the Pneumocystis carinii P-type H-ATPase, PCA1

The opportunistic fungus Pneumocystis is the etiologic agent of an interstitial plasma cell pneumonia that primarily afflicts immunocompromised individuals. Like other fungi Pneumocystis maintains a H(+) plasma membrane gradient to drive nutrient uptake and regulates intracellular pH by ATP-dependent proton efflux. Previously, we identified a Pneumocystis gene, PCA1, whose predicted protein product was homologous to fungal proton pumps. In this study, we show by functional complementation in a Saccharomyces strain whose endogenous PMA1 proton pump activity is repressed that the Pneumocystis PCA1 encodes a H(+)-ATPase. The properties of PCA1 characterized in this system closely resemble those of yeast PMA1. Yeast expressing PCA1 grow at low pH and are able to acidify the external media. Maximal enzyme activity (V(max)) and efficiency of substrate utilization (K(m)) in plasma membranes were nearly identical for PCA1 and PMA1. PCA1 contains an inhibitory COOH-terminal domain; removal of the final 40 amino acids significantly increased V(max) and growth at pH 6.5. PCA1 activity was inhibited by proton pump inhibitors omeprazole and lansoprazole, but was unaffected by H(+)/K(+)-ATPase inhibitor SCH28080. Thus, H(+) homeostasis in Pneumocystis is likely regulated as in other fungi. This work also establishes a system for screening PCA1 inhibitors to identify new anti-Pneumocystis agents.

Detection of two distinct transporter systems for 2-deoxyglucose uptake by the opportunistic pathogen Pneumocystis carinii

Since the opportunistic pathogen Pneumocystis carinii grows only slowly in vitro, the mechanism of glucose uptake was investigated to better understand how the organism transports nutrients. Using the non-metabolizable analogue 2-deoxyglucose, two uptake systems were detected with Q(10) values of 2.12 and 2.09, respectively. One had a high affinity (K(m)=67.5 microM) and the other a low affinity (K(m)=5.99 mM) for 2-deoxyglucose uptake. Glucose or deoxyglucose phosphate products from transported radiolabeled substrates were not detected during the incubation times used in this study. Both systems were inhibited by mannose, galactose, fructose, galactosamine, glucosamine, and glucose but not by allose, 5-thioglucose, xylose, glucose 6-phosphate and glucuronic acid. Salicylhydroxamate, KCN, iodoacetate, and 2,4-dinitrophenol inhibited the high-affinity transporter, suggesting it required ATP. Ouabain, monensin, carbonyl cyanide m-chlorophenylhydrazone, and N,N'-dicyclohexylcarbodiimide also inhibited deoxyglucose uptake, as did the replacement of Na(+) in the incubation medium with choline, indicating requirements for Na(+) and H(+). The high-affinity system was also inhibited by the protein synthesis inhibitors cycloheximide and chloramphenicol. In contrast, the low-affinity system transported deoxyglucose by facilitated diffusion mechanisms. Unlike the human erythrocyte glucose transporter GLUT1, the P. carinii transporters recognized fructose and galactose and were relatively insensitive to cytochalasin B, suggesting that the P. carinii glucose transporters may be good drug targets.

Are cytochrome b gene mutations the only cause of atovaquone resistance in Pneumocystis?

There is evidence that exposure of the opportunistic pathogen Pneumocystis to atovaquone enhances the development of resistance to the drug. Atovaquone is a structural analog of ubiquinone, which binds to the mitochondrial cytochrome bc(1) complex and inhibits electron transport. Like the parasites Plasmodium and Toxoplasma, atovaquone resistance can result from mutations in the cytochrome b gene of Pneumocystis. However, atovaquone resistance cannot be explained by cytochrome b gene mutations in all cases. The discovery that atovaquone also inhibits biosynthesis of ubiquinone in P. carinii may unfold other mechanisms by which drug resistance develops.

Uptake of the neutral amino acids glutamine, leucine, and serine by Pneumocystis carinii

Experiments to elucidate the mechanism by which Pneumocystis carinii transports glutamine, leucine, and serine were performed in this study. Uptake of all three radiolabeled amino acids exhibited first-order, saturation kinetics as extracellular substrate concentrations were increased, thus ruling out simple diffusion and indicating carrier-mediated transport. Kinetic analyses of amino acid uptake and the results of competitive inhibition experiments suggested that leucine, serine, and glutamine were taken up via a common transporter system. The uptake of serine was examined in greater detail to characterize the nature of the carrier. Serine uptake was not affected by N, N'-dicyclohexylcarbodiimide, carbonyl cyanide m-chlorophenyl hydrazone, ouabain, gramicidin, valinomycin, sodium azide, salicylhydroxamine acid (SHAM), iodoacetate, iodoacetate plus SHAM, KCN, and azide. Thus serine uptake did not require sodium or energy from ATP, an electrochemical proton gradient or a membrane potential across the cell surface (i.e., proton-motive force). Serine uptake was dependent on glucose in the extracellular compartment. In the presence of glucose, serine uptake was inhibited by chloramphenicol but not cycloheximide. The results from these experiments are most consistent with facilitated diffusion as the mechanism. After 30 min of incubation, most of the radioactivity was in the cellular soluble fraction. In most cases, incorporation into the extractable total lipids and the remaining particulate cellular components were detectable after this incubation period.

Transport of aspartic acid, arginine, and tyrosine by the opportunistic protist Pneumocystis carinii

In order to improve culture media and to discover potential drug targets, uptake of an acidic, a basic, and an aromatic amino acid were investigated. Current culture systems, axenic or co-cultivation with mammalian cells, do not provide either the quantity or quality of cells needed for biochemical studies of this organism. Insight into nutrient acquisition can be expected to lead to improved culture media and improved culture growth. Aspartic acid uptake was directly related to substrate concentration, Q(10) was 1.10 at pH 7.4. Hence the organism acquired this acidic amino acid by simple diffusion. Uptake of the basic amino acid arginine and the aromatic amino acid tyrosine exhibited saturation kinetics consistent with carrier-mediated mechanisms. Kinetic parameters indicated two carriers (K(m)=22.8+/-2.5 microM and K(m)=3.6+/-0.3 mM) for arginine and a single carrier for tyrosine (K(m)=284+/-23 microM). The effects of other L-amino acids showed that the tyrosine carrier was distinct from the arginine carriers. Tyrosine and arginine transport were independent of sodium and potassium ions, and did not appear to require energy from ATP or a proton motive force. Thus facilitated diffusion was identified as the mechanism of uptake. After 30 min of incubation, these amino acids were incorporated into total lipids and the sedimentable material following lipid extraction; more than 90% was in the cellular soluble fraction.

Regulation of the plasma membrane potential in Pneumocystis carinii

Many protists use a H(+) gradient across the plasma membrane, the proton motive force, to drive nutrient uptake. This force is generated in part by the plasma membrane potential (DeltaPsi). We investigated the regulation of the DeltaPsi in Pneumocystis carinii using the potentiometric fluorescent dye bisoxonol. The steady state DeltaPsi in a buffer containing Na(+) and K(+) (standard buffer) was found to be -78+/-8 mV. In the absence of Na(+) and K(+) (NMG buffer) or Cl(-) (gluconate buffer), DeltaPsi was not significantly changed suggesting that cation and anion conductances do not play a significant role in the regulation of DeltaPsi in P. carinii. The DeltaPsi was also not affected by inhibitors of the Na(+)/K(+)-ATPase, ouabain (1 mM), and the K(+)/H(+)-ATPase, omeprazole (1 mM). In contrast, inhibitors of the plasma membrane H(+)-ATPase, dicyclohexylcarbodiimide (100 microM), N-ethylmaleimide (100 microM) and diethylstilbestrol (25 microM), significantly depolarized the DeltaPsi to -43+/-7, -56+/-5 and -40+/-12 mV, respectively. The data support that the plasma membrane H(+)-ATPase plays a significant role in the regulation of DeltaPsi in P. carinii.

Functional expression of a vacuolar-type H+-ATPase in the plasma membrane and intracellular vacuoles of Trypanosoma cruzi

Acid-loaded Trypanosoma cruzi amastigotes and trypomastigotes regained normal cytoplasmic pH (pHi), as measured in cells loaded with 2',7'-bis-(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF), by a process that was sensitive to bafilomycin A1 at concentrations comparable to those that inhibited vacuolar (V) H+-ATPases from different sources. Steady-state pHi was also decreased by similar concentrations of bafilomycin A1 in a concentration-dependent manner. The efflux of H+ equivalents from amastigotes and trypomastigotes was measured by following changes in the fluorescence of extracellular BCECF. Basal H+ extrusion in the presence of glucose was 15.4+/-2.8 (S.D.) nmol of H+/min per 10(8) amastigotes and 6. 37+/-0.8 nmol of H+/min per 10(8) trypomastigotes. Bafilomycin A1 treatment significantly decreased the efflux of H+ equivalents by amastigotes (8.9+/-2.2 nmol of H+/min per 10(8) cells), but not by trypomastigotes (5.1+/-1.7 nmol of H+/min per 10(8) cells). The localization of the V-H+-ATPase of T. cruzi was investigated by immunocytochemistry. Confocal and electron microscopy indicated that, in addition to being located in cytoplasmic vacuoles, the V-H+-ATPase of different stages of T. cruzi is also located in the plasma membrane. However, no labelling was detected in the plasma membrane lining the flagellar pocket of the different developmental stages. Surface localization of the V-H+-ATPase was confirmed by experiments involving the biotinylation of cell surface proteins and immunoprecipitation with antibodies against the V-H+-ATPase. Taken together, the results are consistent with the presence of a functional V-H+-ATPase in the plasma membrane of amastigotes and with an important role for intracellular acidic compartments in the maintenance of pHi in different stages of T. cruzi.

Analysis of the uptake of the fluorescent marker 2',7'-bis-(2-carboxyethyl)-5(and-6)-carboxyfluorescein (BCECF) by hydrogenosomes in Trichomonas vaginalis

The fluorescent dye 2',7'-bis-(2-carboxyethyl)-5(and-6)-carboxyfluorescein (BCECF) has been widely used as an indicator of cytosolic pH. Here we report that BCECF localizes to hydrogenosomes (hydrogen-generating organelles found in several phylogenetically separate groups of anaerobic protists) in Trichomonas vaginalis, where it was observable by fluorescence microscopy. Its cellular location was confirmed by treatment of BCECF-loaded cells with diaminobenzidine and hydrogen peroxide together with UV illumination. This produced an osmiophilic precipitate in the matrix of hydrogenosomes, observable by electron microscopy. Use of a short (7.5 min) loading period, loading on ice, use of concentrations of BCECF (acetoxymethyl ester) down to 10 nM, and inclusion of the anion channel blockers probenicid or sulfinpyrazone, or the K+/H+ ionophore nigericin in the loading buffer all failed to prevent hydrogenosomal accumulation of BCECF. This uptake was best observed when intact cells were loaded with the ester form of BCECF, but could also be seen using free BCECF following either incubation with ruptured cells or electroporation of intact cells. Hydrogenosomal BCECF loading was also obtained with washed cell lysates, without cytoplasm or metabolic substrates. We tested a range of other fluorogenic dyes designed for cytosolic labeling, and found that the calcium indicator fura-2 (acetoxymethyl ester) and the cell viability marker fluorescein diacetate also labeled hydrogenosomes. The results illustrate a novel use for BCECF as a fluorescent marker for hydrogenosomes (the first such marker), but present a warning against the indiscriminate use of fluorogenic ester dyes to measure properties of the cytosol in hydrogenosome-containing organisms - the dyes may also be indicating the properties of the hydrogenosome.

Vacuolar-type H+-ATPase regulates cytoplasmic pH in Toxoplasma gondii tachyzoites

Cytoplasmic pH (pHi) regulation was studied in Toxoplasma gondii tachyzoites by using the fluorescent dye 2',7'-bis-(2-carboxyethyl)-5(6)-carboxyfluorescein. Their mean baseline pHi (7.07+/-0.06; n=5) was not significantly affected in the absence of extracellular Na+, K+ or HCO3(-) but was significantly decreased in a dose-dependent manner by low concentrations of N, N'-dicyclohexylcarbodi-imide (DCCD), N-ethylmaleimide (NEM) or bafilomycin A1. Bafilomycin A1 also inhibited the recovery of tachyzoite pHi after an acid load with sodium propionate. Similar concentrations of DCCD, NEM and bafilomycin A1 produced depolarization of the plasma membrane potential as measured with bis-(1,3-diethylthiobarbituric)trimethineoxonol (bisoxonol), and DCCD prevented the hyperpolarization that accompanies acid extrusion after the addition of propionate, in agreement with the electrogenic nature of this pump. Confocal laser scanning microscopy indicated that, in addition to being located in cytoplasmic vacuoles, the vacuolar (V)-H+-ATPase of T. gondii tachyzoites is also located in the plasma membrane. Surface localization of the V-H+-ATPase was confirmed by experiments using biotinylation of cell surface proteins and immunoprecipitation with antibodies against V-H+-ATPases. Taken together, the results are consistent with the presence of a functional V-H+-ATPase in the plasma membrane of these intracellular parasites and with an important role of this enzyme in the regulation of pHi homoeostasis in these cells.

The role of a H(+)-ATPase in the regulation of cytoplasmic pH in Trypanosoma cruzi epimastigotes

Cytoplasmic pH (pHi) regulation was studied in Trypanosoma cruzi epimastigotes using fluorescent probes. Steady-state pHi was maintained even in the absence of extracellular Na+ or K+, but was significantly decreased in the absence of Cl-. Acid-loaded epimastigotes regained normal pHi by a process that was ATP-dependent and sensitive to N-ethylmaleimide, dicyclohexyl-carbodi-imide and diethylstiboestrol, suggesting involvement of a H(+)-pumping ATPase. Recovery from an acid load was independent of extracellular Na+ or K+ and insensitive to omeprazole, vanadate and low concentrations of bafilomycin A1. Using the fluorescent probe bisoxonol to measure the membrane potential of intact cells, acid loading of epimastigotes was shown to result in a dicyclohexylcarbodi-imide-sensitive hyperpolarization, which suggests electrogenic pumping of protons across the plasma membrane. Addition of glucose, but not of 6-deoxyglucose, produced a transient cellular acidification of possible metabolic origin, and increased the rate of recovery from an acid load. Taken together, these results are consistent with an important role of a H(+)-ATPase in the regulation of pHi homoeostasis in T. cruzi.