Glucose transport in Crithidia luciliae

The effect of tunicamycin on the glucose uptake, growth, and cellular adhesion in the protozoan parasite Crithidia fasciculata

Crithidia fasciculata represents a very interesting model organism to study biochemical, cellular, and genetic processes unique to members of the family of the Trypanosomatidae. Thus, C. fasciculata parasitizes several species of insects and has been widely used to test new therapeutic strategies against parasitic infections. By using tunicamycin, a potent inhibitor of glycosylation in asparaginyl residues of glycoproteins (N-glycosylation), we demonstrate that N-glycosylation in C. fasciculata cells is involved in modulating glucose uptake, dramatically impacting growth, and cell adhesion. C. fasciculata treated with tunicamycin was severely affected in their ability to replicate and to adhere to polystyrene substrates and losing their ability to aggregate into small and large groups. Moreover, under tunicamycin treatment, the parasites were considerably shorter and rounder and displayed alterations in cytoplasmic vesicles formation. Furthermore, glucose uptake was significantly impaired in a tunicamycin dose-dependent manner; however, no cytotoxic effect was observed. Interestingly, this effect was reversible. Thus, when tunicamycin was removed from the culture media, the parasites recovered its growth rate, cell adhesion properties, and glucose uptake. Collectively, these results suggest that changes in the tunicamycin-dependent glycosylation levels can influence glucose uptake, cell growth, and adhesion in the protozoan parasite C. fasciculata.

Characterization of D-glucose transport in Trypanosoma rangeli

Like in other trypanosomatids D-glucose is a crucial source of energy to Trypanosoma rangeli, a non-pathogenic parasite that in Central and South America infects triatomine vectors and different mammalian species, including humans. In several trypanosome species, D-glucose transporters were already described and cloned. In this study, we characterized the D-glucose transport activity present in 2 life-stage forms of T. rangeli (epimastigotes and trypomastigotes) using D-[U-14C]glucose as substrate. Our results indicate that T. rangeli transports D-glucose with high affinity in both epimastigote (Km 30 microM) and trypomastigotes (Km 80 microM) life-forms. Both transport activities were inhibited by Cytochalasin B and Phloretin, indicating that probably D-glucose uptake in T. rangeli is mediated by facilitated diffusion of the sugar. Significant differences were observed between epimastigotes and trypomastigotes in relation to their affinity for D-glucose analogues, and the predicted amino acid sequence of a putative D-glucose transporter from T. rangeli (TrHT1) showed a larger identity with the T. cruzi D-glucose transporter encoded by the TcrHT1 gene than with other transporters already characterized in trypanosomatids.

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.

Osmoregulation in the parasitic protozoan Tritrichomonas foetus

Tritrichomonas foetus was shown to undergo a regulatory volume increase (RVI) when it was subjected to hyperosmotic challenge, but there was no regulatory volume decrease after hypoosmotic challenge, as determined by using both light-scattering methods and measurement of intracellular water space to monitor cell volume. An investigation of T. foetus intracellular amino acids revealed a pool size (65 mM) that was similar to that of Trichomonas vaginalis but was considerably smaller than those of Giardia intestinalis and Crithidia luciliae. Changes in amino acid concentrations in response to hyperosmotic challenge were found to account for only 18% of the T. foetus RVI. The T. foetus intracellular sodium and potassium concentrations were determined to be 35 and 119 mM, respectively. The intracellular K(+) concentration was found to increase considerably during exposure to hyperosmotic stress, and, assuming that there was a monovalent accompanying anion, this increase was estimated to account for 87% of the RVI. By using light scattering it was determined that the T. foetus RVI was enhanced by elevated external K(+) concentrations and was inhibited when K(+) and/or Cl(-) was absent from the medium. The results suggested that the well-documented Na(+)-K(+)-2Cl(-) cotransport system was responsible for the K(+) influx activated during the RVI. However, inhibitors of Na(+)-K(+)-2Cl(-) cotransport in other systems, such as quinine, ouabain, furosemide, and bumetanide, had no effect on the RVI or K(+) influx in T. foetus.

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.

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.

Giardia intestinalis: volume recovery in response to cell swelling

The trophozoite from of the protozoan parasite Giardia intestinalis is subjected to a changing osmotic environment in the small intestine of the host, and consequently effective osmoregulation and control of cell volume are essential to its survival. As a first step toward investigating the mechanism by which hypoosmotically-activated transport is controlled in this organism, we used a light scattering technique to monitor continuously changes in cell volume after osmotic challenge. There was a hyperbolic relationship between A550 and giardial protein concentration, resulting in linear double reciprocal plots and allowing the calculation of relative Giardia cell volumes from A550 values. The initial rate of cell swelling was directly proportional to the hypoosmotic gradient when the hypoosmotic difference was greater than 50 mOsm kg-1. However, a hypoosmotic challenge of < 30 mOsm kg-1 had little effect on cell swelling, suggesting that giardial cell rigidity can resist small changes in medium osmolarity. The use of light scattering as a measure of giardial cell volume changes was validated using a rapidly penetrating solute, ethylene glycol, to induce isoosmotic cell swelling. We have previously shown that trophozoites swelled initially when subjected to a hypoosmotic challenge and that a subsequent regulatory volume decrease was accompanied by rapid alanine efflux and activation of the uptake of an alanine analog, 2-aminoisobutyrate. The ethylene glycol-induced isoosmotic cell swelling was also followed by a regulatory volume decrease, accompanied by a similar rapid release of intracellular alanine and activation of 2-aminoisobutyric acid uptake. This suggests that an increase in cell volume is the primary stimulus for the rapid alanine efflux after hypoosmotic challenge.

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.

Glucose uptake in Trypanosoma vivax and molecular characterization of its transporter gene

A gene, TvHT1, encoding a glucose transporter protein, has been cloned from the haemoflagellate protozoon, Trypanosoma vivax, which has an active Kreb's cycle in the mammalian stage. The deduced polypeptide is similar in amino acid sequence to other kinetoplastid hexose transporters from Trypanosoma brucei (THT1 and THT2), Trypanosoma cruzi (TcrHT1) and Leishmania (Pro-1). The similarity is higher with THT2 (expressed in T. brucei insect forms) than with the other isoforms. The kinetic properties of glucose uptake in Chinese Hamster Ovary (CHO) cells expressing TvHT1 and in trypanosomes show s a saturable transport mechanism typical of a facilitated carrier system, with a similar affinity for D-glucose as that of the T. brucei bloodstream form carrier, THT1 (Km = 0.548 +/- 0.01 mM, Vmax = 4.26 +/- 0.12 nmol.min-1.mg protein-1 in CHO cells and Km = 0.585 +/- 0.068 mM, Vmax = 88.5 +/- 6.2 nmol.min-1.mg protein-1 in T. vivax). The specificity of the TvHT1 protein for various D-glucose analogues, as judged by inhibition of 2-deoxy-D-arabinose-hexose transport, shows properties that are intermediate between those of THT1 on the one hand and TcrHT1 and THT2 on the other. As with the hexose transporters in the other members of Kinetoplastida, the TvHT1-encoded system differs from erythrocyte-type glucose transport by its moderate sensitivity to cytochalasin B and its capacity to transport fructose.

Characterization of glucose transport and cloning of a hexose transporter gene in Trypanosoma cruzi

A gene from Trypanosoma cruzi, TcrHT1, which encodes a member of the glucose transporter superfamily has been cloned. The gene is similar in sequence to the T. brucei hexose transporter THT1 and the Leishmania transporter Pro-1 and is present in the T. cruzi genome as a cluster of at least eight tandemly reiterated copies. Northern blot analysis revealed two mRNA transcripts which differ in size with respect to their 3' untranslated regions. When injected with in vitro transcribed TcrHT1 mRNA, Xenopus oocytes express a hexose transporter with properties similar to those of T. cruzi. Glucose transport in T. cruzi is mediated via a carrier with unique properties when compared with the other glucose transporters already characterized among the Kinetoplastida. It is a facilitated transporter with a high affinity for D-glucose (Km = 84.1 +/- 7.9 microM and Vmax = 46 +/- 9.4 nmol/min per mg of protein) that shares with other kinetoplastid hexose transporters the ability to recognize D-fructose, which distinguishes these carriers from the human erythrocyte glucose transporter GLUT1.

Nucleoside transport in Crithidia luciliae

Nucleoside transport was evaluated in the trypanosomatid Crithidia luciliae by a rapid sampling technique. C. luciliae was shown to possess two independent nucleoside transporters, one which transported adenosine, deoxyadenosine, tubercidin, sangivamycin and the pyrimidine nucleoside thymidine, while the second was specific for guanosine, inosine and deoxyguanosine. The rapid influx occurred by a process of facilitated transport. The apparent Km values for adenosine and guanosine were 9.34 +/- 1.30 and 10.6 +/- 2.60 microM, respectively. The pyrimidine nucleoside thymidine was transported at a rate approximately 50% lower than the purine nucleosides, whilst uridine, deoxyuridine and deoxycytidine were not transported. The optical isomer, L-adenosine entered the organism by simple diffusion rather than by facilitated transport. In contrast to mammalian cells, neither of the nucleoside transporters in C. luciliae were inhibited by nitrobenzylthioinosine, dilazep, or dipyridamole, potent inhibitors of nucleoside transport in mammalian cells, whilst p-chloromercuribenzoate sulphonate inhibited both nucleoside transporters in C. luciliae.

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.