Induction of germ tube formation by N-acetyl-D-glucosamine in Candida albicans: uptake of inducer and germinative response

A number of strains of Candida albicans were tested for germ tube formation after induction by N-acetyl-D-glucosamine (GlcNAc) and other simple (proline, glucose plus glutamine) or complex (serum) compounds. A proportion of strains (high responders) were induced to form germ tubes evolving to true hyphae by GlcNAc alone or by proline or glucose plus glutamine mixture. The majority of strains were low responders because they could be induced only by serum or GlcNAc-serum medium. Two strains were found to be nonresponders: they grew as pseudohyphae in serum. Despite minor quantitative differences, all strains efficiently utilized GlcNAc for growth under the yeast form at 28 degrees C. They also had comparable active, inducible, and constitutive uptake systems for GlcNAc. During germ tube formation in GlcNAc, the inducible uptake system was modulated, as expected from induction and decay of GlcNAc kinase. Uranyl acetate, at a concentration of 0.01 mM, inhibited both GlcNAc uptake and germ tube formation and was reversed by phosphates. Germinating and nongerminating cells differed in the rapidity and extent of GlcNAc incorporation into acid-insoluble and alkali-acid-insoluble cell fractions. During germ tube formation induced by proline, GlcNAc was almost totally incorporated into the acid-insoluble fraction after 60 min. Moreover, hyphal development on induction by either GlcNAc or proline was characterized by an apparent "uncoupling" between protein and polysaccharide metabolism, the ratio between the two main cellular constituents falling from more than 1 to less than 0.5 after 270 min of development. The data suggest that utilization of the inducer for wall synthesis is a determinant of germ tube formation C. albicans but that the nature and extent of inducer uptake is not a key event for this phenomenon to occur.     

Regulation of N-acetylglucosamine uptake in yeast.

Various yeasts have been investigated for their ability to grow on N-acetylglucosamine as the sole carbon source and only those which are associated with the disease, candidiasis, gave positive results. The yeasts unable to grow on N-acetylglucosamine lacked the capacity to transport the aminosugar across the cell membrane. In pathogenic yeasts, two systems of different affinity for substrate were found to operate in the uptake of N-acetylglucosamine. In glucose-grown cells a constitutive, low affinity uptake system was present, but upon addition of inducer, a specific high affinity uptake system was synthesized. Experiments with the inhibitors of macromolecule synthesis suggested that the synthesis of RNA and protein is necessary for induction whereas the synthesis of DNA is not. In glucose-grown Candida albicans cells which are devoid of N-acetylglucosamine enters into the cells as phosphorylated form using a constitutive uptake system. Uranyl acetate (0.01 mM) which binds to cell membrane-associated polyphosphates, inhibited completely the inducible uptake of N-acetylglucosamine. Labelling experiments, designed to determine the temporal sequence of appearance of N-acetylglucosamine in intracellular free sugar and sugar-phosphate pools, indicated that N-acetylglucosamine first appeared in the cells as pohosphorylated form. Similar results were obtained with Saccharomyces phosphorylated form. Similar results were obtained with Saccharomyces cerevisiae 3059 and some other yeasts which are devoid of N-acetylglucosamine kinase in both uninduced and induced conditions. These results are consistent with the model of van Steveninck that involves phosphorylation during transpost. Furthermore, inhibitors of energy metabolism (arsenate, azide and cyanide), proton conductor (m-chlorocarbonylcyanide phenylhydrazine) and dibenzyl diammonium ion (membrane permeable cation) inhibited the inducible N-acetylglucosamine uptake in C. albicans.     

Proline-induced germ-tube formation in Candida albicans: role of proline uptake and nitrogen metabolism

Proline-induced germ-tube formation and cell-cell aggregation in four strains of Candida albicans were completely inhibited when the pH of the medium was 5.0 or lower, whereas morphogenesis induced by N-acetylglucosamine (GlcNAc) was unaffected even at pH 4.5. The pH sensitivity of proline-induced germ-tube formation was not caused by a modulation of proline uptake, which was unchanged over the pH range 4.5-6.5. The proline uptake system was specific, constitutive and subject to ammonium repression, and only one permease was detected, with a Km of 179 microM. Cultures deprived of nitrogen in the presence of glucose were derepressed for proline uptake but the yeast-mycelial transition could not be mediated by either proline or GlcNAc. The inhibition of morphogenesis was reversed when the nitrogen starvation was relieved by the addition of ammonium ions, proline, or certain amino acids. These results indicate that the nitrogen status of the cells is critical for the morphogenesis of C. albicans.     

Carbon-13 nuclear magnetic resonance spectroscopy of high-spin iron(III) porphyrin compounds

1. There was no apparent correlation between the rate of respiration and rate of accumulation of proline in Candida albicans cells. 2. In contrast to normal cells, the respiration in the starved cells became completely cyanide insensitive. The starvation of cells in the presence of cycloheximide prevented the cells from becoming cyanide insensitive. The addition of Fe(III), however, accelerated the process. 3. Oxidizable substrates e.g. NADH, acetate and glucose, when added to cyanide-insensitive starved cells, exhibited 40--280% stimulation in respiration rate. However, this enhancement in oxidation by various substrates was not coupled to a simultaneous increase in the proline uptake or in intracellular ATP levels. 4. There was 6-fold stimulation in proline uptake when cyanide-insensitive cells were preincubated with 50 mM glucose. The preincubation of starved cells resulted in a partial restoration of cyanide sensitivity and increased intracellular ATP levels. The preincubation of starved cells with other oxidizable substrates resulted in a partial restoration of cyanide sensitivity but had no stimulatory effect on intracellular ATP levels and proline accumulation. 5. Both the enhanced uptake and ATP levels in glucose preincubated cells were found to be completely abolished by iodoacetate. 6. It is proposed that the increased proline uptake in cells preincubated with glucose was mainly due to the production of glycolytic energy.     

Structural requirements for hemoglobin to induce fibronectin receptor expression in Candida albicans

Hemoglobin (Hb) is a host factor that induces expression of a promiscuous receptor on Candida albicans for fibronectin (FN) and several other extracellular matrix proteins. FN receptor expression was induced by ferric (Hb(+)Met and Hb(+)CN), ferrous (HbCO and HbO(2)), and cobalt-protoporphyrin derivatives of Hb, whereas globin was inactive. The Hb derivatives all exhibited saturable, dose-dependent kinetics of FN receptor induction, suggesting that Hb may be acting as a receptor ligand. Soluble Hb bound saturably to a low-affinity binding site [K(d) = (1.1+/-0.2) x 10(-6) M] on C. albicans blastospores. However, uptake of (55)FeHb revealed that heme or iron transport into the cell is not required for induction, since internalization of (55)Fe from Hb did not occur until after induction of FN binding. The serum Hb-binding protein, haptoglobin, specifically abrogated this response, indicating that protein structure rather than the heme ligand or iron is necessary for induction of this signaling pathway. C. albicans also adhered to immobilized Hb, which was sufficient to induce FN receptor expression, and to Hb polymers that formed in defined Hb liquid media in the presence of cells. Formation of Hb polymers in solution required metabolic energy, since the aggregation process was halted with azide addition. Collectively, these data demonstrate that C. albicans recognizes polymerized Hb through multivalent low-affinity interactions, and this may be a host environmental cue that triggers extracellular matrix receptor expression at a septic site.     

Induction of nitrate transport in maize roots, and kinetics of influx, measured with nitrogen-13

Unlike phosphate or potassium transport, uptake of nitrate by roots is induced, in part, by contact with the substrate ion. Plasmalemma influx of ¹³N-labeled nitrate in maize roots was studied in relation to induction of the uptake system, and the influence of short-term N starvation. Maize (Zea mays) roots not previously exposed to nitrate had a constitutive transport system (state 1), but influx increased 250% during six hours of contact with 100 micromolar nitrate, by which time the transport mechanism appeared to be fully synthesized (state 2). A three-day period of N starvation prior to induction and measurement of nitrate influx resulted in a greater capacity to transport nitrate than in unstarved controls, but this was fully expressed only if roots were kept in contact with nitrate for the six hours needed for full induction (state 2E). A kinetic analysis indicated a 160% increase in maximum influx in N-starved, induced roots with a small decrease in K_m. The inducible component to nitrate influx was induced only by contact with nitrate. Full expression of the nitrate inducible transport system was dependent upon mRNA synthesis. An inhibitor of cytoplasmic protein synthesis (cycloheximide) eliminated the formation of the transport system while inhibition by chloramphenicol of mitochondrial- or plastid-coded protein synthesis had no effect. Poisoning of membrane-bound proteins effectively disabled both the constitutive and induced transport systems.     

Glutamate-induced uptake of proline by Streptomyces antibioticus.

Streptomyces antibioticus possesses an energy-dependent, carrier mediated transport system for the uptake of L-glutamate and L-proline. Amino acid transport was found to have a temperature optimum of 35 degrees C and a pH optimum from 7.0 to 8.0 for glutamate and 6.5 to 7.5 for proline uptake. Uptake did not depend upon Mg2+, Ca2+, Zn2+, Na+, or Fe2+ ions. Reversible p-hydroxymercuribenzoate inhibition of uptake indicated the involvement of an active sulfhydryl group. L-Glutamate uptake was mediated by a glutamate-inducible, nonspecific transport system, which was extremely stable and was not subject to substrate inhibition by L-proline. On the other hand, L-proline transport was mediated by at least two systems. The L-glutamate-inducible nonspecific system can account for uptake of proline by the mycelium grown in glutamate. In addition, a proline-specific, constitutive transport system was found to be present in the mycelium grown in organic and inorganic nitrogen sources other than L-glutamate. Shift experiments revealed that proline transport is not as stable as glutamate transport when the glutamate-inducible nonspecific system is utilized.     

Activation of a new proline transport system in Salmonella typhimurium.

Proline uptake can be mediated by three different transport systems in wild-type Salmonella typhimurium: a high-affinity proline transport system encoded by the putP gene and two glycine-betaine transport systems with a low affinity for proline encoded by the proP and proU genes. However, only the PutP permease transports proline well enough t allow growth on proline as a sole carbon or nitrogen source. By selecting for mutations that allow a putP mutant to grow on proline as a sole nitrogen source, we isolated mutants (designated proZ) that appeared to activate a cryptic proline transport system. These mutants enhanced the transport of proline and proline analogs but did not require the function of any of the known proline transport genes. The mutations mapped between 75 and 77.5 min on the S. typhimurium linkage map. Proline transport by the proZ mutants was competitively inhibited by isoleucine and leucine, which suggests that the ProZ phenotype may be due to unusual mutations that alter the substrate specificity of the branched-chain amino acid transport system encoded by the liv genes.     

Transport of ribitol and D-glucose in the yeastCandida guillermondii

The uptakes of the linear polyol ribitol and ofd-glucose byCandida guillermondii were found to be carrier-mediated and to require metabolic energy. In glucose-grown cells ribitol possibly enters by simple diffusion but after an induction period a specific transport system is synthesized, inhibitable by higher concentrations of arabinitols, xylitol, mannitol and sorbitol. Actidione blocks the synthesis of the inducible ribitol transport system. Two systems of different affinity for substrate were found to operate in the uptake of both glucose and of ribitol. Counter-transport experiments with ribitol,d-glucose and 3-O-methyl-d-glucose support the carrier nature of the uptake system.     

Absence of derepression of amino acids transport in Candida

The transport of glycine, L-alanine, L-proline, L-leucine, L-lysine, L-phenylalanine and L-glutamic acid did not enhance in various strains of Candida cells, when they were grown in proline containing medium or preincubated with proline. However, under similar conditions, a significant enhancement in the level of accumulation of amino acids (derepression) was observed in Saccharomyces cerevisiae X-2180-A2 (GAP+) cells, which was sensitive to ammonium ions (NH4+). As expected, the derepression was absent in GAP- cells of S. cerevisiae X-2180 (GAP- mutant). In contrast to S. cerevisiae (GAP+) cells, the increase in few amino acids uptake in different Candida strains, grown in proline or preincubated in proline, could not be inhibited by cycloheximide, NH4+ or their D-stereoisomers. It appears that derepression of amino acids transport, a well known phenomenon in S. cerevisiae, may not exist in Candida species.     

Uptake of pyrimidines and their derivatives into Candida glabrata and Candida albicans

The uptake of pyrimidines and their derivatives into Candida glabrata and Candida albicans was measured using a novel technique in which the cells were rapidly separated from their suspending medium by centrifugation through a layer of an inert oil. The uptake of [14C]cytosine was linear for 30 s for all concentrations of pyrimidine tested. In C. glabrata but not C. albicans cytosine transport was mediated by both a high affinity (Km 0.8 +/- 0.1 microM), low capacity [V 40 +/- 4 pmol (microliters cell water)-1 s-1] and a low affinity [Km 240 +/- 35 microM], high capacity system [V 770 +/- 170 pmol (microliters cell water)-1 s-1]. The cytosine permease in C. glabrata was specific for cytosine and 5-fluorocytosine. In C. albicans there was only one cytosine transport system [Km 2.4 +/- 0.3 microM; V 50 +/- 4 pmol (microliters cell water)-1 s-1]; this system also transported adenine, guanine and hypoxanthine. Differences in nucleoside transport were also observed for C. glabrata and C. albicans, with the uridine permease in C. glabrata transporting only uridine and 5-fluorouridine whereas cytidine and adenosine were also transported by the uridine permease in C. albicans. Studies on the effect of nucleoside analogues on uridine transport in C. glabrata demonstrated the importance of the sugar moiety in determining the specificity of transport, with a hydroxyl residue on C-2 being apparently essential for transport.     

A transport system for phosphoenolpyruvate, 2-phosphoglycerate, and 3-phosphoglycerate in Salmonella typhimurium.

Salmonella typhimurium strain LT-2 was found to utilize phosphoenolpyruvate, 2-phosphoglycerate, and 3-phosphoglycerate as sole sources of carbon and energy for growth, but Escherichia coli strains did not. The following evidence suggests that this growth difference was due to the presence in Salmonella cells of an inducible phosphoglycerate permease distinct from previously studied transport systems: (a) The ability of cells to take up 3-phospho[14-C]glycerate was induced by growth in the presence of phosphoenolpyruvate, 2-phosphoglycerate, or 3-phosphoglycerate, but not glycerate, alpha-glycerophosphate, or other carbon sources tested. (b) Uptake of 3-phospho[14-C]glycerate was strongly inhibited by the three nonradioactive inducers of 3-phosphoglycerate uptake, but not by glycerate or alpha-glycerophosphate. (c) Mutants which lost the ability to utilize and take up 3-phosphoglycerate simultaneously lost the ability to utilize 2-phosphoglycerate and phosphoenolpyruvate, but not other compounds tested. (d) Mutant strains which constitutively synthesized the phosphoglycerate transport system could use both phosphoglycerates and phosphoenolpyruvate as sole sources of phosphate at low substrate concentrations. (e) A strain lacking alkaline and acid phosphatases could still grow with 3-phosphoglycerate as sole carbon source. Maximal rates of 3-phospho[14-C]glycerate uptake occurred at pH 6 in the presence of an exogenous energy source. The apparent Km for 3-phosphoglycerate uptake under these conditions was about 10-minus 4 M. The maximal uptake rate (but not the Km) was dependent on potassium ions. Although synthesis of the phosphoglycerate transport system appeared to be under adenosine 3:5-monophosphate control, glucose repressed induction only slightly. The genes controlling synthesis of the phosphoglycerate transport system (pgt genes) appeared to map at about 74 min on the Salmonella chromosome.     

Choline transport activity in Staphylococcus aureus induced by osmotic stress and low phosphate concentrations.

Uptake of [14C]choline upon hyperosmotic stress of exponential-phase Staphylococcus aureus cultures in a complex medium occurred after a delay of 2.5 to 3.5 h. This uptake could be prevented by chloramphenicol, suggesting that it occurred via an inducible transport system. Radioactivity from [14C]choline was accumulated as [14C]glycine betaine. However, neither choline nor glycine betaine could act as the major carbon and energy source for the organism, suggesting that choline was not metabolized beyond glycine betaine. Assay of choline transport activity in cells grown under different conditions in defined media revealed that osmotic stress was mainly responsible for the induction, but choline gave a further increase in induction. The system was not induced in anaerobically grown cells. Choline transport activity was repressed by glycine betaine and proline betaine, suggesting that these compounds are corepressors. Choline transport activity was not induced in cells osmotically stressed by 1 M potassium phosphate or 0.5 M sodium phosphate, but was induced in cells grown in low-phosphate medium in the absence of osmotic stress. This suggests that there is a connection between the phosphate and osmotic stress regulons. Choline transport was energy and Na+ dependent and had a Km of 46 microM and a maximum rate of transport (Vmax) of 54 nmol/min/mg (dry weight). The results of competition studies suggested that N-methyl and an alcohol group or aldehyde groups at the ends of the molecule were important in its recognition by the system. Glycine betaine was not a highly effective competitor, suggesting that its transport system and the choline transport system were distinct from each other. Choline transport was highly susceptible to a variety of inhibitors, which may be related to the greater dependence on respiratory metabolism of cells grown in the presence of high NaC1 concentrations.     

Substrate specificity of peptide permeases in Candida albicans

Abstract Specificity of peptide transport systems in Candida albicans was studied using as an experimental tool novel anticandidal peptides, containing the N³-4-methoxyfumaroyl- l -2,3-diamino-propanoic acid residue. Studies on cross-resistance and on peptide uptake by spontaneous mutants resistant to toxic peptides, confirmed the multiplicity of peptide permeases in Candida albicans . At least two peptide permeases exist in this microorganism; the first one, specific for di- and tripeptides and the second, for oligopeptides containing 3–6 amino acids. The rate of the tritetra tetra-, penta- and hexapeptide transport in the mycelial form of Candida albicans is about 2-times higher than in the yeast form, while that of dipeptides is markedly reduced.
Tripeptides are proposed as the most efficient carriers for the delivery of 'warhead' amino acids into Candida albicans cells.     

Virulence of Mycobacterium tuberculosis

Abstract Different strains of Candida albicans show varied sensitivities to the peptide analogues bacilysin, polyoxins and nikkomycins. From a sensitive strain, B2630, spontaneous mutants were selected for resistance to each analogue; certain mutants showed cross-resistance to other analogues and associated defects in peptide transport. A bacilysin-resistant mutant was cross resistant to the other analogues and to m -fluorophenylalanyl-Ala (FPA) but retained sensitivity to m -fluorophenylalanyl-Ala—Ala (FPAA). It showed defective dipeptide transport but normal oligopeptide transport. A revertant, selected for its ability to utilize Ala-Ala as sole nitrogen source, regained wild-type dipeptide transport activity and analogue sensitivity. Thus, C. albicans has distinguishable mechanisms for dipeptide and oligopeptide transport which can be exploited for uptake of peptide-drug adducts.     

Dimorphism-associated changes in amino acid transport of Candida albicans

Abstract Amino acid uptake was followed during pH-regulated dimorphism of Candida albicans . It was observed that transport activities of various amino acids differed with the morphological phenotype. The uptake rates of l-alanine , l -phenylalanine and of l -lysine were lower and those of l -methionine were higher in elongated hypha (germ tube), while the rates of glycine, l -glutamic acid and l -proline were similar in bud and hyphal phenotypes. Minimum threshold of amino acids transport activity is required at the time of phenotypic commitment in a diverging population of Candida albicans .     

Inducible transport of citrate in Lactobacillus rhamnosus ATCC 7469

Lactobacillus rhamnosus ATCC 7469 exhibited diauxie when grown in a medium containing both glucose and citrate as energy source. Glucose was used as the primary energy source during the glucose-citrate diauxie. Uptake of citrate was carried out by an inducible citrate transport system. The induction of citrate uptake system was repressed in the presence of glucose. This repression was reversible and mediated by cAMP.     

Regulation of amino acid transport in L6 muscle cells: I. Stimulation of transport system a by amino acid deprivation

The regulation of amino acid transport in L6 muscle cells by amino acid deprivation was investigated. Proline uptake was Na⁺-dependent, saturable and concentrative, and was predominantly through system A. Proline uptake was inhibited by alanine, α-amino isobutyric acid (AIB), and by α-methylamino isobutyric acid, but not by lysine or valine. At 25°C, Km of proline uptake was 0.5 mM. Amino acid-deprivation resulted in a progressive increase in the rate of proline uptake, reaching up to 6-fold stimulation after 6 hours. The basal and stimulated transport were equally Na⁺-dependent, and both were inhibited by competition with the same amino acids. Kinetic analysis showed that Km decreased by a factor of 2.4 and Vmax increased 1.9-fold in deprived cells. Amino acid-deprivation did not stimulate amino acid uptake through systems other than system A. This suggests that the higher Km in proline-supplemented cells is not due to release of intracellular amino acids into unstirred layers surrounding the cells. The presence of amino acids which are substrates of system A (including AIB) during proline-deprivation, prevented stimulation of proline uptake, whereas those transported by systems Ly⁺ or L exclusively were ineffective. The stimulation of the transport-rate in deprived cells could be reversed by subsequent exposure to proline or other substrates of system A. L6 cells, deprived of proline for 6 hours, retained the stimulation of transport after detachment from the monolayers with trypsin. Uptake rates were comparable in suspended and attached cells in monolayer culture. Thus, amino acid-depreivation of L6 cells results in an adaptive increase in proline uptake, which is not due to unstirred layers but appears to be mediated by other mechanisms of selective transport regulation.