Glucose transport in Leishmania donovani promastigotes

Biophysical and Pharmacological Characterization of Energy-Dependent Efflux of Sb in Laboratory-Selected Resistant Strains of Leishmania (Viannia) Subgenus

The growing resistance of leishmaniasis to first-line drugs like antimonials in some regions limits the control of this parasitic disease. The precise mechanisms involved in Leishmania antimony resistance are still subject to debate. The reduction of intracellular Sb^III accumulation is a common change observed in both laboratory-selected and field isolated resistant Leishmania strains, but the exact transport pathways involved in antimony resistance have not yet been elucidated. In order to functionally characterize the antimony transport routes responsible for resistance, we performed systematic transport studies of Sb^III in wild-type and resistant strains of L. (Viannia) guyanensis and L. (V.) braziliensis. Those include influx and efflux assays and the influence of ABC transporters and metabolism inhibitors: prochlorperazine, probenecid, verapamil, BSO, and sodium azide. The mRNA levels of genes associated with antimony resistance (MRPA, GSH1, ODC, AQP1, ABCI4, and ARM58) were also investigated in addition to intracellular thiol levels. A strong reduction of Sb influx was observed in L. guyanensis resistant mutant (LgSbR), but not in L. braziliensis (LbSbR). Both mutants showed increased energy-dependent efflux of Sb^III, when compared to their respective parental strains. In LgSbR, BSO and prochlorperazine inhibited antimony efflux and resistance was associated with increased MRPA and GSH1 mRNA levels, while in LbSbR antimony efflux was inhibited by probenicid and prochlorperazine in absence of resistance-associated gene modulation. Intracellular thiol levels were increased in both Sb-resistant mutants. An energy-dependent Sb^III efflux pathway sensitive to prochlorperazine was clearly evidenced in both Sb-resistant mutants. In conclusion, the present study allowed the biophysical and pharmacological characterization of energy-dependent Sb efflux pathway apparently independent of MRPA, ABCI4, and ARM58 upregulation, in Leishmania (Vianna) mutant selected in vitro for resistance to Sb^III. Prochlorperazine has also been identified as an effective chemosensitizer in both Sb resistant mutants, which acts through inhibition of the active efflux of Sb.

An Arginine Deprivation Response Pathway Is Induced in Leishmania during Macrophage Invasion

Amino acid sensing is an intracellular function that supports nutrient homeostasis, largely through controlled release of amino acids from lysosomal pools. The intracellular pathogen Leishmania resides and proliferates within human macrophage phagolysosomes. Here we describe a new pathway in Leishmania that specifically senses the extracellular levels of arginine, an amino acid that is essential for the parasite. During infection, the macrophage arginine pool is depleted due to its use to produce metabolites (NO and polyamines) that constitute part of the host defense response and its suppression, respectively. We found that parasites respond to this shortage of arginine by up-regulating expression and activity of the Leishmania arginine transporter (LdAAP3), as well as several other transporters. Our analysis indicates the parasite monitors arginine levels in the environment rather than the intracellular pools. Phosphoproteomics and genetic analysis indicates that the arginine-deprivation response is mediated through a mitogen-activated protein kinase-2-dependent signaling cascade.

Protozoa of the genus Leishmania are the causative agents of leishmaniasis in humans. These parasites cycle between promastigotes in the sand fly mid-gut and amastigotes in phagolysosome of mammalian macrophages. During infection, host cells up-regulate nitric oxide while/or parasites induce expression of host arginase, both of which use arginine as a substrate. These elevated activities deplete macrophage arginine pools, a situation that invading Leishmania must overcome since it is an essential amino acid. Leishmania donovani imports exogenous arginine via a mono-specific amino acid transporter (AAP3) and utilizes it primarily through the polyamine pathway to provide precursors for trypanothione biosynthesis as well as hypusination of eukaryotic translation Initiation Factor 5A. Here we report the discovery of a pathway whereby Leishmania sense the lack of environmental arginine and respond with rapid up-regulation in the expression and activity of AAP3, as well as several other transporters. Significantly, this arginine deprivation response is also activated in parasites during macrophage infection. Phosphoproteomic analyses of L. donovani promastigotes have implicated a mitogen-activated protein kinase 2 (MPK2)-mediated signaling cascade in this response, and L. mexicana mutants lacking MPK2 are unable to respond to arginine deprivation. The arginine-sensing pathway might play an important role in Leishmania virulence and hence serve as target for drug development.

A unique, highly conserved secretory invertase is differentially expressed by promastigote developmental forms of all species of the human pathogen, Leishmania

Leishmania are protozoan pathogens of humans that exist as extracellular promastigotes in the gut of their sand fly vectors and as obligate intracellular amastigotes within phagolysosomes of infected macrophages. Between infectious blood meal feeds, sand flies take plant juice meals that contain sucrose and store these sugars in their crop. Such sugars are regurgitated into the sand fly anterior midgut where they impact the developing promastigote parasite population. In this report we showed that promastigotes of all Leishmania species secreted an invertase/sucrase enzyme during their growth in vitro. In contrast, neither L. donovani nor L. mexicana amastigotes possessed any detectable invertase activity. Importantly, no released/secreted invertase activity was detected in culture supernatants from either Trypanosoma brucei or Trypanosoma cruzi. Using HPLC, the L. donovani secretory invertase was isolated and subjected to amino acid sequencing. Subsequently, we used a molecular approach to identify the LdINV and LmexINV genes encoding the ~72 kDa invertases produced by these organisms. Interestingly, we identified high fidelity LdINV-like homologs in the genomes of all Leishmania sp. but none were present in either T. brucei or T. cruzi. Northern blot and RT-PCR analyses showed that these genes were developmentally/differentially expressed in promastigotes but not amastigotes of these parasites. Homologous transfection studies demonstrated that these genes in fact encoded the functional secretory invertases produced by these parasites. Cumulatively, our results suggest that these secretory enzymes play critical roles in the survival/growth/development and transmission of all Leishmania parasites within their sand fly vector hosts.

A versatile proline/alanine transporter in the unicellular pathogen Leishmania donovani regulates amino acid homoeostasis and osmotic stress responses

Unlike all other organisms, parasitic protozoa of the family Trypanosomatidae maintain a large cellular pool of proline that, together with the alanine pool, serve as alternative carbon sources as well as reservoirs of organic osmolytes. These reflect adaptation to their insect vectors whose haemolymphs are exceptionally rich in the two amino acids. In the present study we identify and characterize a new neutral amino acid transporter, LdAAP24, that translocates proline and alanine across the Leishmania donovani plasma membrane. This transporter fulfils multiple functions: it is the sole supplier for the intracellular pool of proline and contributes to the alanine pool; it is essential for cell volume regulation after osmotic stress; and it regulates the transport and homoeostasis of glutamate and arginine, none of which are its substrates. Notably, we provide evidence that proline and alanine exhibit different roles in the parasitic response to hypotonic shock; alanine affects swelling, whereas proline influences the rate of volume recovery. On the basis of our data we suggest that LdAAP24 plays a key role in parasite adaptation to its varying environments in host and vector, a phenomenon essential for successful parasitism.

Functional analysis of Leishmania cyclopropane fatty acid synthetase

The single gene encoding cyclopropane fatty acid synthetase (CFAS) is present in Leishmania infantum, L. mexicana and L. braziliensis but absent from L. major, a causative agent of cutaneous leishmaniasis. In L. infantum, usually causative agent of visceral leishmaniasis, the CFAS gene is transcribed in both insect (extracellular) and host (intracellular) stages of the parasite life cycle. Tagged CFAS protein is stably detected in intracellular L. infantum but only during the early log phase of extracellular growth, when it shows partial localisation to the endoplasmic reticulum. Lipid analyses of L. infantum wild type, CFAS null and complemented parasites detect a low abundance CFAS-dependent C19Δ fatty acid, characteristic of a cyclopropanated species, in wild type and add-back cells. Sub-cellular fractionation studies locate the C19Δ fatty acid to both ER and plasma membrane-enriched fractions. This fatty acid is not detectable in wild type L. major, although expression of the L. infantum CFAS gene in L. major generates cyclopropanated fatty acids, indicating that the substrate for this modification is present in L. major, despite the absence of the modifying enzyme. Loss of the L. infantum CFAS gene does not affect extracellular parasite growth, phagocytosis or early survival in macrophages. However, while endocytosis is also unaffected in the extracellular CFAS nulls, membrane transporter activity is defective and the null parasites are more resistant to oxidative stress. Following infection in vivo, L. infantum CFAS nulls exhibit lower parasite burdens in both the liver and spleen of susceptible hosts but it has not been possible to complement this phenotype, suggesting that loss of C19Δ fatty acid may lead to irreversible changes in cell physiology that cannot be rescued by re-expression. Aberrant cyclopropanation in L. major decreases parasite virulence but does not influence parasite tissue tropism.

A novel sucrose/H+ symport system and an intracellular sucrase in Leishmania donovani

The flagellated form of pathogenic parasitic protozoa Leishmania, resides in the alimentary tract of its sandfly vector, where sucrose serves as a major nutrient source. In this study we report the presence of a sucrose transport system in Leishmania donovani promastigotes. The kinetics of sucrose uptake in promastigotes are biphasic in nature with both high affinity K(m) (K(m) of ∼ 75 μM) and low affinity K(m) (K(m)∼ 1.38 mM) components. By contrast the virulent amastigotes take up sucrose via a low affinity process with a K(m) of 2.5mM. The transport of sucrose into promastigotes leads to rapid intracellular acidification, as indicated by changes in the fluorescence of the pH indicator 2',7'-bis-(2-carboxyethyl)-5-(6) Carboxyfluorescein (BCECF). In experiments with right side-out plasma membrane vesicles derived from L. donovani promastigotes, an artificial pH gradient was able to drive the active accumulation of sucrose. These data are consistent with the operation of a H(+)-sucrose symporter. The symporter was shown to be independent of Na(+) and to be insensitive to cytochalasin B, to the flavonoid phloretin and to the Na(+)/K(+) ATPase inhibitor ouabain. However, the protonophore carbonylcyanide P- (trifluromethoxy) phenylhydrazone (FCCP) and a number of thiol reagents caused significant inhibition of sucrose uptake. Evidence was also obtained for the presence of a stable intracellular pool of the sucrose splitting enzyme, sucrase, in promastigote stage parasites. The results are consistent with the hypothesis that L. donovani promastigotes take up sucrose via a novel H(+)-sucrose symport system and that, on entering the cell, the sucrose is hydrolysed to its component monosaccharides by an intracellular sucrase, thereby providing an energy source for the parasites.

Glucose transporters in parasitic protozoa

Glucose and related hexoses play central roles in the biochemistry and metabolism of single-cell parasites such as Leishmania, Trypanosoma, and Plasmodium that are the causative agents of leishmaniasis, African sleeping sickness, and malaria. Glucose transporters and the genes that encode them have been identified in each of these parasites and their functional properties have been scrutinized. These transporters are related in sequence and structure to mammalian facilitative glucose transporters of the SLC2 family, but they are nonetheless quite divergent in sequence. Hexose transporters have been shown to be essential for the viability of the infectious stage of each of these parasites and thus may represent targets for development of novel anti-parasitic drugs. The study of these transporters also illuminates many aspects of the basic biology of Leishmania, trypanosomes, and malaria parasites.

Arginine homeostasis and transport in the human pathogen Leishmania donovani

Arginine is an essential amino acid for the human pathogen Leishmania but not to its host. Thus, the mechanism by which this protozoan parasite regulates cellular homeostasis of arginine is critical for its survival and virulence. In a previous study, we cloned and functionally characterized a high affinity arginine-specific transporter, LdAAP3, from Leishmania donovani. In this investigation, we have characterized the relationship between arginine transport via LdAAP3 and amino acid availability. Starving promastigotes for amino acids decreased the cellular level of most amino acids including arginine but also increased the abundance of both LdAAP3 mRNA and protein and up-regulated arginine transport activity. Genetic obliteration of the polyamine biosynthesis pathway for which arginine is the sole precursor caused a significant decrease in the rate of arginine transport. Cumulatively, we established that LdAAP3 expression and activity changed whenever the cellular level of arginine changed. Our findings have led to the hypothesis that L. donovani promastigotes have a signaling pathway that senses cellular concentrations of arginine and subsequently activates a mechanism that regulates LdAAP3 expression and activity. Interestingly, this response of LdAAP3 to amino acid availability in L. donovani is identical to that of the mammalian cation amino acid transporter 1. Thus, we conjecture that Leishmania mimics the host response to amino acid availability to improve virulence.

Leishmania amazonensis: Metabolic adaptations induced by resistance to an ABC transporter blocker

We compared growth rate, cell glucose turnover and expression of ATP-binding-cassette (ABC) transporters in Leishmania amazonensis (LTB0016; LTB) versus LTB(160) selected for resistance against the ABC transporter blocker glibenclamide. Additionally, we evaluated the influence of drug-resistance on Leishmania sensitivity against 2-mercaptoacetate and 2-deoxyglucose. Our data demonstrate that (1) LTB(160) and LTB constitutively express ABC transporters for neutral substrates, (2) glibenclamide resistance induces the expression of organic anion ABC transporters, members of the drug resistance associated transporters subfamily, (3) LTB(160) parasites use less glucose as energy substrate and exhibit a slower glucose uptake than LTB cells, and (4) LTB(160) parasites are less sensitive to 2-mercaptoacetate and 2-deoxyglucose than the glibenclamide-sensitive Leishmania LTB. Together these and previous results indicate that the metabolic adaptations expressed in drug-resistant LTB(160) differ from those described for mammalian drug resistant cells and constitute general mechanisms that underlie drug resistance in Leishmania and may be helpful for identifying alternative strategies to circumvent drug resistance in leishmaniasis.

Glucose and proline transport in kinetoplastids

The parasitic protozoa belonging to the kinetoplastids can use both sugars and amino acids as carbon and energy sources. In this review, Benno ter Kuile discusses nutrient acquisition and utilization and how the metabolic strategies reflect the environment encountered in host and vector. Recent genetic and physiological evidence suggests that facilitated diffusion may be the primary uptake mechanism for glucose, and possibly for proline as well, even though there is biochemical and genetic evidence suggesting that active transport occurs, if not across the plasma membrane, then across the membranes of organelles. Trypanosoma brucei seems to have a metabolic strategy that strives for maximum energy efficiency, making no storage materials and thereby limiting the control over its internal conditions. On the other hand, Leishmania donovani does create a storage buffer, entrapping glucose in the cell. In this manner, it maintains constant internal conditions at the expense of energy, enabling it to survive more adverse conditions in the macrophage and in its vector.

Arginase plays a pivotal role in polyamine precursor metabolism in Leishmania. Characterization of gene deletion mutants

The polyamine pathway of protozoan parasites has been successfully targeted in anti-parasitic therapies and is significantly different from that of the mammalian host. To gain knowledge into the metabolic routes by which parasites synthesize polyamines and their precursors, the arginase gene was cloned from Leishmania mexicana, and Deltaarg null mutants were created by double targeted gene replacement and characterized. The ARG sequence exhibited significant homology to ARG proteins from other organisms and predicted a peroxisomal targeting signal (PTS-1) that steers proteins to the glycosome, an organelle unique to Leishmania and related parasites. ARG was subsequently demonstrated to be present in the glycosome, whereas the polyamine biosynthetic enzymes, in contrast, were shown to be cytosolic. The Deltaarg knockouts expressed no ARG activity, lacked an intracellular ornithine pool, and were auxotrophic for ornithine or polyamines. The ability of the Deltaarg null mutants to proliferate could be restored by pharmacological supplementation, either with low putrescine or high ornithine or spermidine concentrations, or by complementation with an arginase episome. Transfection of an arg construct lacking the PTS-1 directed the synthesis of an arg that mislocalized to the cytosol and notably also complemented the genetic lesion and restored polyamine prototrophy to the Deltaarg parasites. This molecular, biochemical, and genetic dissection of ARG function in L. mexicana promastigotes establishes: (i) that the enzyme is essential for parasite viability; (ii) that Leishmania, unlike mammalian cells, expresses only one ARG activity; (iii) that the sole vital function of ARG is to provide polyamine precursors for the parasite; and (iv) that ARG is present in the glycosome, but this subcellular milieu is not essential for its role in polyamine biosynthesis.

Critical parameters for functional reconstitution of glucose transport in Trypanosoma brucei membrane vesicles

The glucose transporter of Trypanosoma brucei was reconstituted by incorporating Escherichia coli phospholipid liposomes into detergent-solubilised trypanosome membranes. Proteoliposome vesicles were formed by detergent dilution and used in glucose-uptake assays. The minima for functional reconstitution of the glucose transporter were established and used to probe the mechanism of glucose transport. The uptake pattern of radiolabelled glucose showed a counterflow transient at about 3 s, after which the sugar equilibrated across the proteoliposomal membrane. This observation is consistent with a facilitated transporter. There was a six-fold increase in the initial rate of glucose uptake compared to non-reconstituted or native membranes. In addition, the transporter exhibited stereospecificity to D-glucose but poorly transported L-glucose. Directionality, stereoselectivity or substrate specificity and cis-inhibition by phloridzin were therefore the main criteria for validation of glucose transport. The observed counterflow transient also provided further evidence for a facilitated glucose transporter within the trypanosome plasma membrane, and was the single most important criterion for this assertion. A stoichiometry of 0.78 mol of glucose per mol of transporter was estimated.

Entamoeba histolytica lacks trypanothione metabolism

Entamoeba histolytica lacks glutathione reductase activity and the ability to synthesise glutathione de novo. However, a recent report suggested that exogenous glutathione can be taken up and conjugated to spermidine to form trypanothione, a metabolite found so far only in trypanosomatids. Given the therapeutic implications of this observation, we have carefully analysed E. histolytica for evidence of trypanothione metabolism. Using a sensitive fluorescence-based HPLC detection system we could confirm previous reports that cysteine and hydrogen sulphide are the principal low molecular mass thiols. However, we were unable to detect trypanothione or its precursor N1-glutathionylspermidine [ < 0.01 nmol (10(6) cells)(-1) or < 1.7 microM]. In contrast, Trypanosoma cruzi epimastigotes (grown in a polyamine-supplemented medium) and Leishmania donovani promastigotes contained intracellular concentrations of trypanothione two to three orders of magnitude greater than the limits of detection. Likewise, trypanothione reductase activity was not detectable in E. histolytica [ < 0.003 U (mg protein)(-1)] and therefore at least 100-fold less than trypanosomatids. Moreover, although E. histolytica were found to contain trace amounts of glutathione (approximately 20 microM), glutathione reductase activity was below the limits of detection [ < 0.005 U (mg protein)(-1)]. These findings argue against the existence of trypanothione metabolism in E. histolytica.

Leishmania spp.: mechanisms of toxicity of nitrogen oxidation products

Intracellular killing of Leishmania parasites within activated murine macrophages is thought to result from the toxic activities of nitrogen oxidation products (referred to as NO) released by the activated cells. In order to determine possible mechanisms of NO toxicity for these microorganisms, promastigotes of Leishmania major and Leishmania enriettii were exposed to NO generated chemically from acidified nitrite, S-nitrosocysteine, diethylamine NONOate, or nitroprusside. Treatment with these agents led to loss of viability (as determined from decreased motility and inhibition of [3H]TdR uptake upon reincubation in NO-free medium) with kinetics characteristic for each compound L. major was less sensitive to these effects than L. enriettii, and amastigotes displayed the same sensitivity as promastigotes of the same species. The early effects of NO toxicity could be detected within minutes of exposure to the NO donors; they included decreased respiration rate and inhibition of glucose, proline, and adenine incorporation. Inhibition of the activities of glyceraldehyde 3-phosphate dehydrogenase and of aconitase were also evidenced. In order to determine whether these phenomena reflected the mechanisms of toxicity of bona fide NO generated by macrophages, promastigotes were exposed to IFN-gamma + LPS-activated macrophages across permeable membranes. This resulted in marked inhibition of proline and adenine uptake in the parasites, which was restored, however, to control levels when macrophages were activated in the presence of the nitric oxide synthase inhibitor NGMMA. These results indicate that several cellular targets may be subject to NO toxicity in Leishmania parasites, including enzymes of glycolysis and respiratory metabolism as well as trans-membrane transport systems.

Kinetoplastid glucose transporters

Protozoa of the order kinetoplastida have colonized many habitats, and several species are important parasites of humans. Adaptation to different environments requires an associated adaptation at a cell's interface with its environment, i.e. the plasma membrane. Sugar transport by the kinetoplastida as a phylogenetically related group of organisms offers an exceptional model in which to study the ways by which the carrier proteins involved in this process may evolve to meet differing environmental challenges. Seven genes encoding proteins involved in glucose transport have been cloned from several kinetoplastid species. The transporters all belong to the glucose transporter superfamily exemplified by the mammalian erythrocyte transporter GLUT1. Some species, such as the African trypanosome Trypanosoma brucei, which undergo a life cycle where the parasites are exposed to very different glucose concentrations in the mammalian bloodstream and tsetse-fly midgut, have evolved two different transporters to deal with this fluctuation. Other species, such as the South American trypanosome Trypanosoma cruzi, multiply predominantly in conditions of relative glucose deprivation (intracellularly in the mammalian host, or within the reduviid bug midgut) and have a single, relatively high-affinity type, transporter. All of the kinetoplastid transporters can also transport d-fructose, and are relatively insensitive to the classical inhibitors of GLUT1 transport cytochalasin B and phloretin.

Changing the transport of a cell

The review deals with some of the transport functions of different systems that have been implicated with several pathological disorders. Membrane transport role in parasitic diseases and metal resistance is discussed as a few selected examples. Among various limitations that are encountered in recombinant technology and in heterologous expression of proteins, transport functions of the host organisms cannot be ignored. Recently, membrane transport has acquired a new emerging role in multidrug resistance. Several membrane transporters, particularly ATP binding cassette (ABC) proteins that are involved in drug resistance, have been identified throughout the evolutionary scale. The review briefly emphasizes that membranes are not only important as structural elements but are also adopted to perform diverse functions.

Hexose uptake in Trypanosoma cruzi: structure-activity relationship between substrate and transporter

The gene encoding a hexose transporter, TcrHt1, from Trypanosoma cruzi has been functionally expressed in mammalian Chinese hamster ovary cells. Kinetic parameters of the heterologously expressed protein are very similar to those of the transporter identified in T. cruzi epimastigotes, confirming that TcrHT1 is the major transporter functioning in these parasites. A detailed analysis of substrate recognition using analogues of D-glucose substituted at each carbon position has been performed. The glucose transporter of T. cruzi does not recognize C-3 or C-6 analogues of D-glucose, whereas these analogues were recognized by the glucose transporter of bloodstream-form T. brucei. As for other kinetoplastid transporters, but in stark contrast to the mammalian GLUT family, TcrHT1 can also transport D-fructose, with relatively high affinity (Km = 0.682 +/- 0.003 mM). Amino acid side-chain-modifying reagents were also used to identify residues of the transporter present at the substrate-binding site. While specific modifiers of cysteine, histidine and arginine all inhibited catalytic activity, protection using substrate was only observed using the arginine-specific reagent, phenylglyoxal. Reagents which modify lysine residues had no effect on transport.

Enhanced acquisition of purine nucleosides and nucleobases by purine-starved Crithidia luciliae

The effects of purine starvation on the ability of the trypanosomatid Crithidia luciliae to accumulate purines were determined. Kinetic studies showed that the uptake of the nucleoside adenosine by purine-starved organisms was approximately 7-fold faster than by nutrient-replete cells. Further, these studies demonstrated that purine-starved organisms accumulated the nucleobases hypoxanthine and adenine at a rate > 100-fold faster than organisms cultivated under replete conditions. Activities of several intracellular purine-salvage enzymes were measured in organisms from both culture conditions. Of those measured, the activities of adenine deaminase and hypoxanthine phosphoribosyltransferase were elevated approximately 4-fold and approximately 11-fold, respectively, in purine-starved organisms. Competitive substrate specificity studies suggested that these elevated enzyme activities were not responsible for the increased rates of uptake by purine-starved cells. The results are consistent with the induction of novel surface membrane purine transporters expressed in response to purine starvation. These studies using C. luciliae may provide insights into the mechanisms of trypanosomatid adaptation to altered environments encountered during the course of the life cycle.

Glucose transport in amastigotes and promastigotes of Leishmania mexicana mexicana

Promastigotes and amastigotes of Leishmania mexicana mexicana transported 2-deoxy-D-glucose (2-DOG) by a saturable process with a Km of 24 +/- 3 microM and Vmax of 2.21 nmol min-1 (mg protein)-1 for the promastigote and a Km of 29 +/- 8 microM and Vmax of 0.13 nmol min-1 (mg protein)-1 for the amastigote stage. Amastigotes incorporated 2-DOG maximally at pH 5.0, while for promastigotes the optimum was at pH 7.0. Mid-log phase promastigotes were found to accumulate 2-DOG via a stereospecific carrier-mediated process which was competitively inhibited by D-glucose and D-mannose but not L-glucose. Transport was dependent upon temperature, with a Q10 in promastigotes of 1.83 and an optimum rate at 35 degrees C (+/- 4 degrees C) with an activation energy of 50.12 kJ mol-1. Stationary phase promastigotes accumulated 2-DOG at approximately twice the rate of mid-log phase promastigotes. Cytochalasin B, forskolin and phloretin were all found to inhibit human erythrocyte 2-DOG uptake but only cytochalasin B was found significantly to inhibit promastigote 2-DOG uptake. Interestingly, leishmanial 2-DOG uptake was inhibited by a series of membrane potential antagonists including the ionophore monensin, the H+ATPase inhibitor N, N'-dicyclohexylcarbodiimide (DCCD) and uncoupling agent carbonylcyanide-4-(triflouromethoxy) phenylhydrazone (FCCP), as well as, the tricyclic drugs chlomipramine and imipramine, but was insensitive to the Na+/K+ATPase inhibitor ouabain and the antitrypanosomal drugs Pentostam and Suramin. We therefore conclude that there are significant structural and mechanistic differences between the D-glucose uptake systems of Leishmania and the mammalian host to merit the inclusion of glucose transporters as putative targets for rational drug design.

Kinetics and molecular characteristics of arginine transport by Leishmania donovani promastigotes

Characteristics of transport of L-arginine were studied in Leishmania donovani promastigotes grown in vitro in a defined medium. The promastigotes exhibited a time-dependent, temperature-sensitive, pH-dependent and saturable uptake of arginine. Metabolic inhibitors caused 81-92% inhibition, indicating that arginine influx in promastigotes is an energy requiring process. The presence of Na+ ions was necessary for full activity. Considerable inhibition was also noticed with valinomycin, gramicidin and amiloride. The transporter seems to involve an -SH group at the active site. The most distinctive feature of the leishmanial transporter was that lysine and ornithine did not show significant competition with arginine transport. Other neutral and acidic amino acids, as well as polyamines were also ineffective. The arginine analogues, viz., nitro-L-arginine methyl ester, N-nitro-L-arginine, aminoguanidine, agmatine and D-arginine were not recognised by the transporter, while N-methyl-L-arginine acetate and phospho-L-arginine showed competition, indicating stereo-specificity of the transporter and recognition of both the guanidino group, as well as the arginine side chain by the transporter. No exchange of intracellular [14C]arginine taken up by the promastigotes was noticed during incubation with 2 or 5 mM arginine in the extracellular medium. Eighty percent of the arginine taken up remained in the trichloroacetic acid-soluble fraction. Pentamidine caused competitive inhibition of arginine transport, exhibiting an IC50 value of 40 microM. Results indicate the presence of a novel distinct arginine transporter in Leishmania promastigotes.

Membrane-related processes and overall energy metabolism in Trypanosoma brucei and other kinetoplastid species

An electrochemical proton gradient exists across the plasma membrane and the mitochondrial membrane of the bloodstream form of Trypanosoma brucei. The membrane potential across the plasma membrane and the regulation of the internal pH depend on the temperature. Leishmania donovani regulates its internal pH and maintains a constant electrochemical proton gradient across its plasma membrane under all conditions examined. The mitochondrion of the T. brucei bloodstream form is energized, even though the reactions taking place in it do not result in net ATP synthesis and the Kreb's cycle and the respiratory chain are absent. Glucose is transported across the plasma membrane of T. brucei by a facilitated diffusion carrier, that can transport a wider range of substrates than its mammalian counterparts. Pyruvate exits the cell via a facilitated diffusion transporter as well. Conflicting evidence exists for the mechanism of glucose transport in L. donovani; biochemical evidence suggests proton/glucose symport, while facilitated diffusion is indicated by physiological data.

Biochemistry and molecular genetics of Leishmania glucose transporters

Glucose is utilized as a significant source of metabolic energy by Leishmania parasites. This sugar is accumulated by the parasite via a specific carrier-mediated transport system located in the parasite membrane. Parasites may also contain another transporter that shuttles glucose between the cytoplasm and the glycosome, a membrane-bound organelle where the early steps of glycolysis occur. The transport systems of both the insect stage promastigotes and the intracellular amastigotes have been characterized and shown to have kinetic properties that are consistent with the different physiological environments of the insect gut and the macrophage phagolysosome. Several genes have been cloned from Leishmania species which encode proteins with substantial sequence similarity to glucose transporters from mammals and lower eukaryotes. Two of these genes are expressed preferentially in the promastigote stage of the life cycle, where glucose is more readily available and more rapidly transported and metabolized than in the intracellular amastigotes. One of these two developmentally-regulated genes has been functionally expressed in Xenopus oocytes and shown to encode a glucose transporter. A third gene encodes a protein that is also a member of the glucose transporter family on the basis of sequence similarity and proposed secondary structure. However, the significant differences between this protein and the other two suggest that it is likely to transport a different substrate. Functional expression will be required to define the specific biochemical role of each gene within the parasite.

An unusual active hexose transport system in human and mouse preimplantation embryos

In a metabolic study of human and mouse preimplantation embryos (preembryos), we measured glucose uptake and phosphorylation with nonradioactive 2-deoxyglucose (DG) as tracer. Initial experiments indicated an active hexose transport capacity, a property thought to be restricted in mammals to intestinal villi and kidney tubules [Baly, D. L. & Horuk, R. (1988) Biochim. Biophys. Acta 947, 571-590]. Significant findings are as follows: (i) During a 60-min incubation with a low level of DG, mouse blastocyst DG rose to levels up to 30 times that of the medium. (The intestinal active system does not transport DG [Crane, R. K. (1960) Physiol. Rev. 40, 789-825].) (ii) Active preembryo transport was not blocked (as it would have been in the intestine) by phlorizin [Alvarado, F. & Crane, R. K. (1962) Biochem. Biophys. Acta 56, 170-172 and Sacktor, B. (1989) Kidney Int. 36, 342-350] or by replacement of Na+ with choline+ or K+ [Crane (1960) and Sacktor (1989)]. (iii) Transport of DG was blocked by cytochalasin B (which is not true for the intestinal transporter). We conclude that a distinct active hexose transporter and at least one facilitated transporter are present in preembryos, perhaps appearing in tandem on different membranes during formation of the increasingly complex preembryo structure.

Regulation of L-proline transport in Leishmania donovani by extracellular pH

We have previously shown that Leishmania donovani promastigotes adapted to long-term culture at acidic pH can serve as a model to study parasite development in a lysosomal-like environment. In this study we investigated the effect of growth pH on L. donovani L-proline transport systems. Reducing the pH of the growth medium causes an up to 7-fold decrease in the extent of L-proline transport. Transport resumes after switching the culture from pH 4.5 to pH 7 for 48 h by a protein synthesis-dependent process. The pH optimum for transport changes from 7.5 in promastigotes grown at pH 7 to 5.5 in cells grown at pH 4.5. In addition, kinetic analysis of L-proline transport showed that Vmax in pH 4.5-grown L. donovani promastigotes is one-tenth that of cells grown at pH 7 (4.5 and 44.7 nmol min-1 (10(8) cells)-1, respectively). The apparent Km for L-proline in pH 4.5 promastigotes is one-half of the Km in pH 7 cells (0.30 and 0.65 mM, respectively). In contrast to L-proline transport, D-glucose transport demonstrates a growth pH-independent activity: Km and Vmax as well as optimum pH of transport are similar in promastigotes grown at either pH 7 or pH 4.5. Taken together, the results indicate that in L. donovani, expression and activity of L-proline transport is regulated by culture pH. The pH-dependent expression of L-proline transporters may be of physiological significance during the promastigote-amastigote transition.

Uptake and turnover of glucose in Leishmania donovani

Glucose uptake and metabolism by Leishmania donovani promastigotes was studied using D-[14C]glucose in combination with the silicone oil centrifugation technique on organisms preadapted to different growth rates and glucose availability in the chemostat. The uptake step was differentiated from the subsequent metabolism by separation in time rather than by using non-metabolisable analogues. The uptake of glucose was measured as a function of time and/or the external glucose concentration on cells grown at high or low growth rate with glucose either as growth rate-limiting substrate, or present in excess. Glucose uptake as a function of its external concentration could be described as consisting of two components (1) a rapid equilibration owing to facilitated diffusion, followed by (2) a much slower uptake that involves an enzymatic component. This slower accumulation of label could be explained as the conversion of glucose into metabolites and a storage carbohydrate. Uptake experiments in the presence of inhibitors indicated that the conversion of glucose was an energy dependent process. These experiments indicate that the active uptake of glucose by L. donovani, as reported by others does not occur across the plasma membrane and should be reinterpreted as the intracellular conversion of glucose into metabolites and storage carbohydrate.

Interaction between facilitated diffusion of glucose across the plasma membrane and its metabolism in Trichomonas vaginalis

The parasitic protist Trichomonas vaginalis transports glucose across the plasma membrane by facilitated diffusion. The Km of the transporter for glucose was 1.6 mM. The uptake of labelled glucose in a minimal medium not allowing growth reached saturation only after 2.5 h, indicating the turnover of storage carbohydrate. Organisms grown on glucose showed higher activities both of the transporter and of the subsequent metabolic pathway than organisms grown on maltose. At low external glucose concentrations the transport step was rate limiting, at higher levels a subsequent enzymatic step. The uptake mechanism for glucose of T. vaginalis resembled that of parasitic kinetoplastid protists and Entamoeba histolytica.

Uptake and metabolism of S-adenosyl-L-methionine by Leishmania mexicana and Leishmania braziliensis promastigotes

Promastigotes of Leishmania mexicana and Leishmania braziliensis incorporate S-adenosyl-L-[3H-methyl]methionine (AdoMet) against a concentration gradient through a saturable system. This concentrative uptake requires metabolic energy and is sensitive to temperature and sulfhydryl reagents such as N-ethyl maleimide. Intracellular AdoMet exchanges with external AdoMet. At steady state, unaltered ADoMet in the intracellular pool is at about a 1800-fold concentration in relation to that found in the external medium. Glucose, galactose and ribose did not stimulate uptake rates. Incorporated AdoMet goes into the soluble AdoMet pool, where a small fraction is metabolized, chiefly into methylthioadenosine, decarboxylated AdoMet and methanol. After a 60 min pulse the radioactivity associated with the [3H]AdoMet incorporated disappears with a half-time of 2 h. Transmethylation reactions were analyzed following [3H]AdoMet incorporation. Fractionation experiments indicate that 45-62% and 30-42% of the radioactivity is incorporated into lipids and protein methyl esters respectively, with 5-14% present in the soluble pool of parasites. Sinefungin or its cyclic derivative (1 and 10 micrograms ml-1) in the incubation medium produces 58% and 64% inhibition of AdoMet incorporation into Leishmania promastigotes. Most transmethylation reactions are inhibited, as there is a 50% decrease in the total radioactivity present in both the base-labile and lipidic fraction, with a parallel increase in the percentage of radioactivity in the soluble pool. Previous results give evidence of the importance of AdoMet in American Leishmania promastigote metabolism.

Glucose transport in Crithidia luciliae

The glucose analogue, 2-deoxy-D-glucose, was used to characterise the glucose transport system in Crithidia luciliae choanomastigotes. Uptake was temperature dependent with a Q10 of 2, and saturable with a Km of 0.22 mM and Vmax of 5.5 nmol min-1 (mg protein)-1 at 23 degrees C. Preloaded cells showed rapid exchange of intracellular 2-deoxy-D-glucose when incubated with extracellular D-glucose or 2-deoxy-D-glucose but little exchange with L-glucose. The substrate specificity of the uptake was studied using a number of D-glucose analogues. 6-Deoxy-D-glucose, 3-fluoro-3-deoxy-D-glucose and 4-fluoro-4-deoxy-D-glucose all competed for the transporter and had significant inhibitory effects on 2-deoxy-D-glucose transport. In contrast, 1-thio-beta-D-glucose, trehalose, 3-O-methyl-D-glucose, arginine, thymidine, L-sorbose and L-glucose were not inhibitory. The results imply the existence of a glucose transporter. The transport was blocked by a number of inhibitors and ionophores, including fluoride, azide, cyanide, dinitrophenol, valinomycin and nigericin. Overall, the uptake, exchange and efflux of 2-deoxy-D-glucose is consistent with transport via facilitated diffusion.

Arginine catabolism by Leishmania donovani promastigotes

Leishmania donovani promastigotes were grown to late log phase, washed and resuspended in iso-osmotic buffer containing L-arginine, and the rate of urea formation was then measured under various conditions. Addition of glucose or mannose activated urea formation, whereas 2-deoxyglucose inhibited and 6-deoxyglucose had no effect. Addition of alanine or of alpha-aminoisobutyrate inhibited urea formation, alanine causing a greater inhibition than alpha-aminoisobutyrate. Addition of leucine, proline, glycine, or lysine had no effect on urea formation. The presence of glutamate also increased the rate of urea formation from arginine, but to a lesser extent than did glucose. The presence of both glucose and alanine caused no net change in urea formation, whereas the inhibitory effect of alanine exceeded the activating effect of glutamate, so that a small inhibition in the rate of urea formation occurred in the presence of both alanine and glutamate. Cells grown to 3-day stationary phase had a markedly reduced rate of arginine catabolism to urea, but the activating effect of glucose and the inhibitory effect of alanine were qualitatively similar to their effects on late log phase cells. Addition of water to cells suspended in buffer also inhibited urea formation, but this appeared to be due primarily to the release of alanine caused by the hypo-osmotic stress. Addition of mannitol to cells suspended in buffer caused a small inhibition of arginine catabolism. Addition of dibutyrylcyclic AMP, 3',5'-cyclic GMP, phorbol myristic acid, or A23187 had no effect on the rate of urea formation from arginine.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of osmolality on 86Rb+ uptake and release by Leishmania donovani

Promastigotes from late-log phase cultures of Leishmania donovani were washed and resuspended in Hanks' Balanced Salt Solution without glucose or phenyl red but with 20 mM (N-[2-hydroxyethyl] piperazine-N'-[2-ethanesulfonic acid]) (HEPES) (HBSS-, 305 mOsm/kg). They were then added to a solution containing 86Rb such that the final osmolality and ionic composition was as desired. Samples were taken at known times and the amount of intracellular 86Rb was measured. Similarly, experiments were performed in which 86Rb was added to the cultures about 18 hr before collection, and the amount of 86Rb released from the washed cells was measured. Under iso-osmotic conditions only about 1.3% of the intracellular 86Rb was released in 900 sec. This increased about 4-fold if the osmolality was reduced from 305-153 mOsm/kg. This is much slower than the very rapid release of alanine in response to hypo-osmotic stress, indicating that alanine release is not via a non-specific pore. Reducing the temperature from 26 degrees C to 3-4 degrees C completely inhibits 86Rb release under iso-osmotic conditions and largely inhibits it under hypo-osmotic conditions. The rate of 86Rb release was not sensitive to K+ concentration and was not altered if chloride was replaced by sulfamate. Ouabain had no effect on either 86Rb uptake or release, but carbonylcyanide P-trifluoromethoxyphenylhydrazone (FCCP) reduced the rate of 86Rb release and, after about a 300 sec exposure, completely inhibited 86Rb uptake. Amiloride partially inhibited 86Rb release, but had no effect on uptake. A decrease in pH from 7.1-5.9 had little effect on 86Rb release under iso-osmotic conditions and slightly increased the rate of release under hypo-osmotic conditions, but it decreased the rate of uptake under both iso-osmotic and hypo-osmotic conditions. Cells taken from 3-day stationary phase cultures released 86Rb more slowly under iso-osmotic conditions than cells from late log phase cultures, but were more responsive to hypo-osmotic stress than were log phase cells. These data appear to rule out an [Na-K-Cl] transporter or a [K-Cl] cotransporter as the means of K+ release, but are consistent with the possibility that a K+/H+ exchanger is present. The possibility that other carrier systems may be present is also discussed.

Comparative physiology of two protozoan parasites, Leishmania donovani and Trypanosoma brucei, grown in chemostats

Cultures of the insect stage of the protozoan parasites Leishmania donovani and Trypanosoma brucei were grown in chemostats with glucose as the growth rate-limiting substrate. L. donovani has a maximum specific growth rate (mu max) of 1.96 day-1 and a Ks for glucose of 0.1 mM; the mu max of T. brucei is 1.06 day-1 and the Ks is 0.06 mM. At each steady state (specific growth rate, mu, equals D, the dilution rate), the following parameters were measured: external glucose concentration (Glcout), cell density, dry weight, protein, internal glucose concentration (Glcin), cellular ATP level, and hexokinase activity. L. donovani shows a relationship between mu and yield that allows an estimation of the maintenance requirement (ms) and the yield per mole of ATP (YATP). Both the ms and the YATP are on the higher margin of the range found for prokaryotes grown on glucose in a complex medium. L. donovani maintains the Glcin at a constant level of about 50 mM as long as it is not energy depleted. T. brucei has a decreasing yield with increasing mu, suggesting that it oxidizes its substrate to a lesser extent at higher growth rates. Glucose is not concentrated internally but is taken up by facilitated diffusion, while phosphorylation by hexokinase is probably the rate-limiting step for glucose metabolism. The Ks is constant as long as glucose is the rate-limiting substrate. The results of this study demonstrate that L. donovani and T. brucei have widely different metabolic strategies for dealing with varying external conditions, which reflect the conditions they are likely to encounter in their respective insect hosts.

The plasma membrane electrical gradient (membrane potential) in Leishmania donovani promastigotes and amastigotes

The equilibrium distribution of tetraphenylphosphonium bromide was used to measure the membrane potential in Leishmania donovani amastigotes and promastigotes and to investigate mechanisms underlying the maintenance of membrane potential. At pH 7.0, membrane potential ranges between -90 and -113 mV. Increasing the external concentrations of hydrogen or potassium ions decreased membrane potential as did treatments with carbonylcyanide chlorophenylhydrazone or valinomycin. These observations are consistent with a membrane potential set by hydrogen and potassium ion diffusion gradients. Anaerobiosis lowered membrane potential, suggesting the involvement of ATPase(s) in maintaining membrane potential. Membrane potential was insensitive to treatment with ouabain, demonstrating the absence of a Na+/K(+)-ATPase. Treatment with dicyclohexylcarbodiimide caused a temporary hyperpolarization of the membrane suggesting the participation of a proton ATPase in the maintenance of membrane potential. Determination of the membrane potential makes it possible to quantitate the total proton motive force which is the force for active transport across the parasite membrane.

Proline transport in Leishmania donovani amastigotes: dependence on pH gradients and membrane potential

Amastigotes of Leishmania donovani develop and multiply within the acidic phagolysosomes of mammalian macrophages. Isolated amastigotes are acidophilic; they catabolize substrates and synthesize macromolecules optimally at pH 5.5. Substrate transport in amastigotes has not been characterized. Here we show that amastigotes exhibit an uphill transport of proline (active transport) with an acid pH optimum (pH 5.5). It is dependent upon metabolic energy and is driven by proton motive force. Agents which selectively disturb the component forces of proton motive force, such as carbonyl cyanide chlorophenylhydrazone, nigericin and valinomycin, inhibit proline transport. Transport is sensitive to dicyclohexylcarbodiimide and insensitive to ouabain, demonstrating the involvement of a proton ATPase in the maintenance of proton motive force. It is suggested that the plasma membrane pH gradient probably makes the greatest contribution to proton motive force that drives substrate transport in the amastigote stage.

Changes in intracellular levels of fructose 2,6-bisphosphate and several glycolytic intermediates in Leishmania major promastigotes as a function of pO2

Leishmania major promastigotes were grown to late log phase, washed and resuspended in Hanks' balanced salt solution, and incubated with glucose at various pO2s in the presence of 5% CO2. Samples were taken at times from 0-40 min and assayed for fructose 2,6-bisphosphate (Fru(2,6)P2), glucose-6-phosphate (G6P), fructose-6-phosphate (F6P), phospho(enol)pyruvate (PEP), and ATP. At 95% O2 ATP remained constant throughout the incubation. It did not decrease significantly at 10% O2, but decreased by about 20% and 30% at 6% and 0% O2, respectively. At 95% O2, Fru(2,6)P2 increased about 15-fold within 5 min after the addition of glucose and remained at this high level. At 10%, 6%, and 0% O2 Fru(2,6)P2 rose about 5-fold within 5 min and then declined slightly during the remainder of the incubation. G6P increased from about 0.5 to 12 nmol (mg protein)-1 at 5 min in cells incubated under 95% O2 and then declined to about 5 nmol (mg protein)-1. It increased to about 8 nmol (mg protein)-1 at 5 min and then declined slightly in cells incubated under 10% O2. F6P levels were approximately one-eighth of G6P levels under all conditions, suggesting that phosphohexoseisomerase was not subject to regulation. PEP levels were initially high, but at 95% O2 there was a 50% drop in PEP at 5 min, while at 10%, 6%, and 0% O2 there was less of a decline. The observation that the rise in Fru(2,6)P2 levels at 10%, 6%, or 0% O2 is the same at 5 min and less than the rise at 95% O2 supports the presence of a low affinity oxygen sensor. The different time course of changes in G6P, F6P, and PEP levels suggests that in addition to an activation of pyruvate kinase by Fru(2,6)P2, other regulatory events are also operative at low pO2.

Differences in glucose transport between blood stream and procyclic forms of Trypanosoma brucei rhodesiense

In African trypanosomes the requirements for glucose and its metabolism vary in different stages of the life cycle. Here we present evidence that cultured procyclic trypanosomes of Trypanosoma brucei rhodesiense uptake glucose against a concentration gradient in a time and dose-dependent manner. Moreover, glucose transport is completely inhibited by the sulphydryl inhibitor N-ethylmaleimide, suggesting the presence of a protein moiety as the carrier molecule. Comparison of glucose uptake in bloodstream and procyclic trypanosomes point to the possibility that different transporters may function in the 2 developmental stages. Glucose uptake by bloodstream trypanosomes requires Na+ ions and is inhibited by phlorizin, an inhibitor of Na(+)-dependent glucose transporters in mammalian cells. Conversely, procyclic trypanosomes transport glucose in a Na(+)-dependent manner, and transport is not affected by phlorizin. Finally, the putative procyclic glucose transporter has a higher affinity for glucose (apparent Km 23 microM) than the bloodstream carrier (apparent Km 237 microM).

Maintenance of internal pH and an electrochemical gradient in Trypanosoma brucei

The internal pH value (pHi) of the long-slender bloodstream form of Trypanosoma brucei was estimated from the distribution of 14C-labeled 5,5-dimethyl-2,4-oxazolidinedione or 14C-labeled methyl amine between the intracellular space of the cells and the medium. The pHi of T. brucei remained relatively constant at 7.0-7.2 throughout an extracellular pH (pHo) range of 6.0-8.0. The maintenance of an internal pH more acidic than the environment appears to be a unique feature. Preincubation of T. brucei with carbonyl cyanide m-chlorophenyl hydrazone (CCCP) or CCCP + valinomycin had no appreciable effect on the delta pH across the T. brucei membrane when the external pH was 8.0. However, when the external pH was 6.0, CCCP abolished the observed delta pH. Nigericin significantly dissipated the delta pH across the T. brucei membrane at all pHo values. These data suggest that under physiological conditions, the maintenance of a delta pH across the bloodstream-form T. brucei membrane may be by a mechanism other than an energy-dependent gradient, whereas an energy-dependent pump may be needed for maintaining the pHi in an acidic environment. The electrical potential (delta psi) across the trypanosomal plasma membrane was also estimated using the lipophilic cation, [3H]tetraphenyl-phosphonium bromide. It appears dependent on both the external pH and the external salt conditions. Under ionic conditions similar to the host bloodstream, it ranges from -76 to -160 mV over an external pH range of 6.0 to 8.0, with an estimated value of -155.5 +/- 0.7 at the physiological pH.(ABSTRACT TRUNCATED AT 250 WORDS)

Active transport of 2-deoxy-D-glucose in Trypanosoma brucei procyclic forms

The characteristics of glucose transport by procyclic forms of Trypanosoma brucei were examined in a rapid transport assay using the glucose analogue 2-deoxyglucose. In contrast to bloodforms where the Km for 2-deoxyglucose transport is about 1 mM, procyclic forms have a Km of about 38 microM. Procyclic forms show temperature-dependent, saturable import, and import of 2-deoxyglucose is competitive with glucose and mannose. Unlike the bloodforms which employ facilitated diffusion, the procyclic forms actively transport glucose. Use of inhibitors and ionophores suggests that a protonmotive force is required for glucose transport in procyclic forms. Unlike the human erythrocyte glucose transporter, the glucose transporter of the T. brucei procyclic form is relatively insensitive to inhibition by cytocholasin B.

Tricyclic drugs reduce proton motive force in Leishmania donovani promastigotes

Tricyclic compounds have been suggested as potential anti-leishmanial drugs. We have studied the effect of tricyclic drugs on several cellular functions in L. donovani promastigotes. Imipramine inhibits proline transport and reduces delta pH and cellular ATP at relatively high concentrations (IC50 = 50-80 microM). High concentrations of imipramine are also required to kill L. donovani promastigotes (LD50 greater than 50 microM). The presence of a chlorine atom in the side ring of either imipramine or promazine results in a three-fold increase in both IC50 and LD50 values. Tricyclic compounds in which the nitrogen in the middle ring was substituted with a carbon atom (amitryptyline and chlorprothixene) are most effective in causing cell death and in decreasing proline transport and delta pH (IC50 congruent to 5 microM), whereas depletion of cellular ATP requires a higher drug concentration (IC50 = 12 microM). Transchlorprothixene has IC50 values for proline transport, delta pH and cellular ATP that are similar to those of amitriptyline, whereas the cis isomer is less active. Imipramine, chlomipramine and chlorpromazine decrease the membrane potential in promastigotes. There is a direct correlation between inhibition of membrane transport of proline and the size of the membrane potential at various concentrations of the drugs. Taken together, the multiple effects of the tricyclic drugs on cellular functions in Leishmania suggest that the drugs cause cellular death by non-specific mechanisms, probably involving a general increase in membrane permeability.

Developmentally regulated gene from Leishmania encodes a putative membrane transport protein

We have cloned a developmentally regulated gene from the parasitic protozoan Leishmania enrietti. The mRNA from this gene accumulates to a much higher level in the promastigote stage of the parasite life cycle that lives in the gut of the insect vector than in the amastigote stage of the parasite that lives inside the macrophages of the mammalian host. The predicted protein encoded by this gene is homologous to the human erythrocyte glucose transporter and to several sugar-transport proteins from Escherichia coli. These structural similarities strongly suggest that the cloned gene encodes a membrane transport protein that is developmentally induced when the parasite enters its insect vector. Regulated membrane transporters may be required for the parasite to adapt to the environment of the insect gut.

Maintenance of cytoplasmic pH and proton motive force in promastigotes of Leishmania donovani

Three methods were used to measure intracellular pH (pHi) of Leishmania donovani promastigotes: (a) measurement of the fluorescence of the pH indicator 2',7'-bis-(carboxyethyl)-5,6-carboxyfluorescein; (b) pH null point assays; and (c) determination of the distribution across the promastigote plasma membrane of the fluorescent amine acridine orange and of the weak acid 5,5-dimethyl-2,4-oxazolidinedione. The three methods gave similar results and showed that promastigotes of L. donovani maintain pHi at a narrow range of 6.4-6.7, throughout an extracellular pH (pHo) range of 5.5-7.4. L-Proline transport in L. donovani promastigotes, which is known to be coupled to proton translocation, was used to estimate the proton electrochemical gradient across parasite plasma membrane. While proline uptake is optimal at pHo 7.5, an outward-directed concentration gradient is obtained at steady state throughout a pHo range of 5-8. The calculated electrochemical gradient of proline across the parasite plasma membrane at steady state is 90-100 mV within a pHo range of 5-8, suggesting an almost constant proton electrochemical gradient at this pHo range. Taken together, the results show that the parasites regulate both pHi and the size of the chemiosmotic energy required to drive active transport of nutrients.

Affinity labeling of the folate-methotrexate transporter from Leishmania donovani

An affinity labeling technique has been developed to identify the folate-methotrexate transporter of Leishmania donovani promastigotes using "activated" derivatives of the ligands. These "activated" derivatives were synthesized by incubating folate and methotrexate with a 10-fold excess of 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide (EDC) for 10 min at ambient temperature in dimethyl sulfoxide. Preincubation of intact cells with nonradioactive "activated" folate or methotrexate at a concentration of 40 microM inhibited the capacity of wild-type cells to transport submicromolar concentrations of unmodified ligand. When intact wild-type (DI700) Leishmania donovani or preparations of their membranes were incubated with a 0.4 microM concentration of either "activated" [3H]folate or "activated" [3H]methotrexate, the radiolabeled ligands were covalently incorporated into a polypeptide with a molecular weight of approximately 46,000, as demonstrated by SDS-polyacrylamide gel electrophoresis. No affinity labeling of a 46,000-dalton protein was observed when equimolar concentrations of "activated" radiolabeled ligands were incubated with intact cells or membranes prepared from a methotrexate-resistant mutant clone of Leishmania donovani, MTXA5, that is genetically defective in folate-methotrexate transport capability [Kaur, K., Coons, T., Emmett, K., & Ullman, B. (1988) J. Biol. Chem. 263, 7020-7028]. However, some labeling of a 46,000-dalton protein was observed when MTXA5 cells were incubated with higher concentrations of "activated" ligands. Time course studies indicated that maximal labeling of the 46,000-dalton protein occurred within 5-10 min of incubation of intact cells with "activated" ligand.(ABSTRACT TRUNCATED AT 250 WORDS)