Ureidosuccinic acid permeation in Saccharomyces cerevisiae.

Some strains of Saccharomyces cerevisiae exhibit a specific transport system for ureidosuccinic acid, which is regulated by nitrogen metabolism. Ureidosuccinic acid uptake occurs with proline but with ammonium sulfate as nitrogen source it is inhibited. The V for transport is 20-25 mumol/ml cell water per min. The apparent Km is 3-10(-5) M. For the urep1 mutant (ureidosuccinic acid permease less) the internal concentration never exceeds the external one. In the permease plus strain ureidosuccinic acid can be concentrated up to 10 000 fold and the accumulated compound remains unchanged in the cells. Energy poisons such as dinitrophenol, carbonyl cyanide-m-chlorophenyldrazone (CCCP) or NaN3 inhibit the uptake. No significant efflux of the accumulated compound occurs even in the presence of these drugs. The specificity of the permease is very strict, only amino acids carrying an alpha-N-carbamyl group are strongly competitive inhibitors. The high concentration capacity of the cells and lack of active exit of the accumulated compound support the hypothesis of a carrier mediated active transport system.     

Multiplicity of the Amino Acid Permeases in Saccharomyces cerevisiae IV. Evidence for a General Amino Acid Permease

Kinetic and genetic evidences are presented to show that, in addition to specific amino acid permeases, Saccharomyces cerevisiae has a general amino acid permease which catalyzes the transport of basic and neutral amino acids, but most probably not that of proline. The general amino acid permease appears to be constitutive, and its activity is inhibited when ammonium ions are added to the culture medium. A mutant which has lost the general amino acid permease activity was isolated. Its mutation, named gap (general amino acid permease), is not allelic to the aap (amino acid permease) mutation of Surdin et al., which has a quite different phenotype and cannot be considered as having selectively lost the general amino acid permease activity.     

Mutations in Saccharomyces cerevisiae which confer resistance to several amino acid analogs.

Four new complementation groups of mutations which confer resistance to several amino acid analogs in Saccharomyces cerevisiae are described. These mutants were isolated on medium containing urea as the nitrogen source, in contrast to previous studies that had used medium containing proline. All four resistance to amino acid analog (raa) complementation groups appear to confer resistance by reducing amino acid analog and amino acid uptake. In some genetic backgrounds, raa leu2 and raa thr4 double mutants are inviable, even on rich medium. The raa4 mutation may affect multiple amino acid transport systems, since raa4 mutants are unable to use proline as a nitrogen source. raa4 is, however, unlinked to a previously described amino acid analog resistance and proline uptake mutant, aap1, or to the general amino acid permease mutant gap1. Both raa4 and gap1 prevent uptake of [3H]leucine in liquid cultures. The raa1, raa2, and raa3 mutants affect only a subset of the amino acid analogs and amino acids affected by raa4. The phenotypes of raa1, -2, and -3 mutants are readily observed on agar plates but are not seen in uptake and incorporation of amino acids measured in liquid media.     

Physiological and regulatory properties of the general amino acid transport system of Neurospora crassa.

The fundamental properties of the general amino acid transport system of Neurospora crassa were investigated in the conidial stage of the life cycle. The transport activity was found to be under genetic control, and an isogenic set of mutants deficient for the neutral, basic, or general amino acid transport systems and combinations thereof was constructed and used for analyzing the properties specific to the general permease. Amino acid transport by this system was found to be a carrier-mediated active process with broad specificity for the neutral and basic amino acids. Kinetic analysis revealed that a common binding site functioned to transport both neutral and basic amino acids and that the permease had a high affinity for its substrates. The kinetic parameters Km, Vmax, and Ki were defined for several substrates. Two modes of regulation were detected: substrate inhibition and ammonium repression. Activity of the general system was enhanced by the removal of ammonium ions from the incubation medium with a concomitant decline in either neutral or basic permease activity, suggesting that a common component exists between the neutral and the general systems and between the basic and the general systems.     

Ureidosuccinic acid permeation in Saccharomyces cerevisiae

Some strains of Saccharomyces cerevisiae exhibit a specific transport system for ureidosuccinic acid, which is regulated by nitrogen metabolism. Ureidosuccinic acid uptake occurs with proline but with ammonium sulfate as nitrogen source it is inhibited. The V for transport is 20–25 μmol/ml cell water per min. The apparent K_m is 3 · 10^-5. For the urep1 mutant (ureidosuccinic acid permease less) the internal concentration never exceeds the external one.In the permease plus strain ureidosuccinic acid can be concentrated up to 10 000 fold and the accumulated compound remains unchanged in the cells. Energy poisons such as dinitrophenol, carbonyl cyanide-m-chlorophenyl-drazone (CCCP) or NaN₃ inhibit the uptake. No significant efflux of the accumulated compound occurs even in the presence of these drugs.The specificity of the permease is very strict, only amino acids carrying an α-N-carbamyl group are strongly competitive inhibitors.The high concentration capacity of the cells and the lack of active exit of the accumulated compound support the hypothesis of a carrier mediated active transport system.     

GLN3 encodes a global regulator of nitrogen metabolism and virulence of C. albicans

The function of GLN3, a GATA factor encoding gene, in nitrogen metabolism of Candida albicans was examined. GLN3 null mutants had reduced growth rates on multiple nitrogen sources. More severe growth defects were observed in mutants lacking both GLN3 and GAT1, a second GATA factor gene. GLN3 was an activator of two genes involved in ammonium assimilation, GDH3, encoding NADP-dependent glutamate dehydrogenase, and MEP2, which encodes an ammonium permease. GAT1 contributed to MEP2 expression, but not that of GDH3. A putative general amino acid permease gene, GAP2, was also activated by both GLN3 and GAT1, but activation by GLN3 was nitrogen source dependent. GLN3 was constitutively expressed, but GAT1 expression varied with nitrogen source and was reduced 2- to 3-fold in gln3 mutants. Both gln3 and gat1 mutants exhibited reduced sensitivity to rapamycin, suggesting they function downstream of TOR kinase. Hyphae formation by gln3 and gat1 mutants differed in relation to nitrogen source. The gln3 mutants formed hyphae on several nitrogen sources, but not ammonium or urea, suggesting a defect in ammonium assimilation. Virulence of gln3 mutants was reduced in a murine model of disseminated disease. We conclude that GLN3 has a broad role in nitrogen metabolism, partially overlapping, but distinct from that of GAT1, and that its function is important for the ability of C. albicans to survive within the host environment.     

GLN3 encodes a global regulator of nitrogen metabolism and virulence of C. albicans.

The function of GLN3, a GATA factor encoding gene, in nitrogen metabolism of Candida albicans was examined. GLN3 null mutants had reduced growth rates on multiple nitrogen sources. More severe growth defects were observed in mutants lacking both GLN3 and GAT1, a second GATA factor gene. GLN3 was an activator of two genes involved in ammonium assimilation, GDH3, encoding NADP-dependent glutamate dehydrogenase, and MEP2, which encodes an ammonium permease. GAT1 contributed to MEP2 expression, but not that of GDH3. A putative general amino acid permease gene, GAP2, was also activated by both GLN3 and GAT1, but activation by GLN3 was nitrogen source dependent. GLN3 was constitutively expressed, but GAT1 expression varied with nitrogen source and was reduced 2- to 3-fold in gln3 mutants. Both gln3 and gat1 mutants exhibited reduced sensitivity to rapamycin, suggesting they function downstream of TOR kinase. Hyphae formation by gln3 and gat1 mutants differed in relation to nitrogen source. The gln3 mutants formed hyphae on several nitrogen sources, but not ammonium or urea, suggesting a defect in ammonium assimilation. Virulence of gln3 mutants was reduced in a murine model of disseminated disease. We conclude that GLN3 has a broad role in nitrogen metabolism, partially overlapping, but distinct from that of GAT1, and that its function is important for the ability of C. albicans to survive within the host environment.     

Histidine Uptake in Strains of Neurospora crassa with Normal and Mutant Transport Systems

Kinetic parameters for three systems of active histidine uptake by germinated conidia of Neurospora crassa have been measured. Each system appears to follow typical Michaelis-Menten kinetics when studied separately from the other systems. Under the conditions studied, the general amino acid transport system was found to account for the major portion of histidine uptake from low concentrations. Three types of transport mutants with altered growth inhibition patterns were selected in a histidine auxotroph. Growth of one mutant, type bas(a), could be inhibited by the addition of methionine to a histidine-supplemented medium, and another type, neu(a), could be inhibited by the addition of arginine. These mutants were shown to be lacking active histidine uptake by the basic amino acid and neutral amino acid transport systems, respectively. Another type of double mutant (his-3, neu(r)) could be inhibited only by the addition of very high concentrations of methionine in the presence of arginine and histidine, and the mutation appeared to have altered the specificity of the neutral amino acid permease.     

Arabidopsis LHT1 is a high-affinity transporter for cellular amino acid uptake in both root epidermis and leaf mesophyll

Amino acid transport in plants is mediated by at least two large families of plasma membrane transporters. Arabidopsis thaliana, a nonmycorrhizal species, is able to grow on media containing amino acids as the sole nitrogen source. Arabidopsis amino acid permease (AAP) subfamily genes are preferentially expressed in the vascular tissue, suggesting roles in long-distance transport between organs. We show that the broad-specificity, high-affinity amino acid transporter LYSINE HISTIDINE TRANSPORTER1 (LHT1), an AAP homolog, is expressed in both the rhizodermis and mesophyll of Arabidopsis. Seedlings deficient in LHT1 cannot use Glu or Asp as sole nitrogen sources because of the severe inhibition of amino acid uptake from the medium, and uptake of amino acids into mesophyll protoplasts is inhibited. Interestingly, lht1 mutants, which show growth defects on fertilized soil, can be rescued when LHT1 is reexpressed in green tissue. These findings are consistent with two major LHT1 functions: uptake in roots and supply of leaf mesophyll with xylem-derived amino acids. The capacity for amino acid uptake, and thus nitrogen use efficiency under limited inorganic N supply, is increased severalfold by LHT1 overexpression. These results suggest that LHT1 overexpression may improve the N efficiency of plant growth under limiting nitrogen, and the mutant analyses may enhance our understanding of N cycling in plants.     

Characterization of AAT1: a gene involved in the regulation of amino acid transport in Saccharomyces cerevisiae

A new class of Saccharomyces cerevisiae mutants (aat1 - amino acid transport) has been identified. These mutants are unable to grow on rich medium or on minimal medium supplemented with certain amino acids (isoleucine, methionine, phenylalanine, tyrosine or valine). This phenotype is directly linked to the presence of the leu2 allele in these strains: aat1 LEU2 organisms grow normally on all media tested. Leucine uptake through the leucine-specific permease is inhibited to less than 35% of wild-type levels in aat1 cells preincubated in nonpermissive media, and the activity of the general amino acid permease is also low in these conditions. aat1 cells are therefore unable to grow on rich media because they cannot take up enough leucine to supplement their auxotrophic requirement.     

Physiological Adaptation to the Loss of Amino Acid Transport Ability

A strain of Neurospora crassa devoid of constitutive amino acid transport ability can utilize arginine as the sole nitrogen source. Nitrogen starvation, presence of arginine, and mutational inactivation of the general permease are key factors in signaling production of an extracellular enzyme which removes the alpha-amino group from the amino acid.     

The Gap1 general amino acid permease acts as an amino acid sensor for activation of protein kinase A targets in the yeast Saccharomyces cerevisiae

Addition of a nitrogen source to yeast (Saccharomyces cerevisiae) cells starved for nitrogen on a glucose-containing medium triggers activation of protein kinase A (PKA) targets through a pathway that requires for sustained activation both a fermentable carbon source and a complete growth medium (fermentable growth medium induced or FGM pathway). Trehalase is activated, trehalose and glycogen content as well as heat resistance drop rapidly, STRE-controlled genes are repressed, and ribosomal protein genes are induced. We show that the rapid effect of amino acids on these targets specifically requires the general amino acid permease Gap1. In the gap1Delta strain, transport of high concentrations of l-citrulline occurs at a high rate but without activation of trehalase. Metabolism of the amino acids is not required. Point mutants in Gap1 with reduced or deficient transport also showed reduced or deficient signalling. However, two mutations, S391A and S397A, were identified with a differential effect on transport and signalling for l-glutamate and l-citrulline. Specific truncations of the C-terminus of Gap1 (e.g. last 14 or 26 amino acids) did not reduce transport activity but caused the same phenotype as in strains with constitutively high PKA activity also during growth with ammonium as sole nitrogen source. The overactive PKA phenotype was abolished by mutations in the Tpk1 or Tpk2 catalytic subunits. We conclude that Gap1 acts as an amino acid sensor for rapid activation of the FGM signalling pathway which controls the PKA targets, that transport through Gap1 is connected to signalling and that specific truncations of the C-terminus result in permanently activating Gap1 alleles.     

Amino acid transport systems of JapaneseParamecium symbiont F36-ZK

Analyses of amino acid transport systems in JapaneseParamecium symbiont F36-ZK were performed using¹⁴C-amino acids. Kinetic analyses of amino acid uptake and competitive experiments revealed three transport systems; a basic amino acid transport system, which catalyzed transport of L-Arg and L-Lys, a general amino acid transport system, which had broad specificity for 19 amino acids (but not L-Arg), and an alanine transport system. These three systems were considered to be capable of active transport. Amino acid-proton symport was indicated by the following data: decreases in pH of the medium observed during L-Ser and L-Ala uptake, and uptake of L-Arg, L-Ser and L-Ala being inhibited by carbonyl cyanide m-chlorophenylhydrazone, sodium azide and vanadate. The optimal pH for uptake of neutral amino acids and L-Arg was around 5 and 5 to 6.5, respectively. Uptake of L-Asp and L-Glu was very sensitive to pH and little uptake of L-Asp was measured above pH 6.0. Amino acid uptake was not inhibited by nitrate or ammonium, and cultured cells with ammonium also possessed constitutive uptake systems.     

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.     

Ammonia regulation of amino acid permeases in Saccharomyces cerevisiae.

The activities of the proline-specific permease (PUT4) and the general amino acid permease (GAP1) of Saccharomyces cerevisiae vary 70- to 140-fold in response to the nitrogen source of the growth medium. The PUT4 and GAP1 permease activities are regulated by control of synthesis and control of activity. These permeases are irreversibly inactivated by addition of ammonia or glutamine, lowering the activity to that found during steady-state growth on these nitrogen sources. Mutants altered in the regulation of the PUT4 permease (Per-) have been isolated. The mutations in these strains are pleiotropic and affect many other permeases, but have no direct effect on various cytoplasmic enzymes involved in nitrogen assimilation. In strains having one class of mutations (per1), ammonia inactivation of the PUT4 and GAP1 permeases did not occur, whereas glutamate and glutamine inactivation did. Thus, there appear to be two independent inactivation systems, one responding to ammonia and one responding to glutamate (or a metabolite of glutamate). The mutations were found to be nuclear and recessive. The inactivation systems are constitutive and do not require transport of the effector molecules per se, apparently operating on the inside of the cytoplasmic membrane. The ammonia inactivation was found not to require a functional glutamate dehydrogenase (NADP). These mutants were used to show that ammonia exerts control of arginase synthesis largely by inducer exclusion. This may be the primary mode of nitrogen regulation for most nitrogen-regulated enzymes of S. cerevisiae.     

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.     

The importance of amino acids as carbon sources for Micromonospora echinospora (ATCC 15837)

AIMS: This study set out to investigate the effect of amino acids on the uptake of glucose by Micromonospora eichinospora (ATCC 15837). METHODS AND RESULTS: The specific rate of glucose uptake was found to be reduced when organic nitrogen components were present in the medium. Radioactive uptake studies revealed that the Km for glucose in this organism was 53 mm, indicating a low affinity for uptake compared with other actinomycete sugar transport systems. Individual amino acids negatively influenced the rate of glucose transport, suggesting a relationship between amino acid metabolism and glucose uptake in this organism. The sugar transport system was found to be an active process being inhibited by ionophores and KCN. CONCLUSIONS: The data suggest a direct link between amino acid metabolism and glucose uptake at the level of sugar transport. SIGNIFICANCE AND IMPACT OF THE STUDY: This study shows that the uptake of glucose, a major carbon source for many antibiotic fermentations, is significantly reduced in the presence of amino acids. This fact should inform the medium design and feeding regimes of fermentations involving similar actinomycetes.     

Inhibition of amino acid transport by ammonium ion in Saccharomyces cerevisiae.

The rate of transport of L-amino acids by Saccharomyces cerevisiae epsilon 1278b increased with time in response to nitrogen starvation. This increase could be prevented by the addition of ammonium sulfate or cycloheximide. A slow time-dependent loss of transport activity was observed when ammonium sulfate (or ammonium sulfate plus cycloheximide) was added to cells after 3 h of nitrogen starvation. This loss of activity was not observed in the presence of cycloheximide alone. In a mutant yeast strain which lacks the nicotinamide adenine dinucleotide phosphate-dependent (anabolic) glutamate dehydrogenase, no significant decrease in amino acid transport was observed when ammonium sulfate was added to nitrogen-starved cells. A double mutant, which lacks the nicotinamide adenine dinucleotide phosphate-dependent enzyme and in addition has a depressed level of the nicotinamide adenine dinucleotide-dependent (catabolic) glutamate dehydrogenase, shows the same sensitivity to ammonium ion as the wild-type strain. These data suggest that the inhibition of amino acid transport by ammonium ion results from the uptake of this metabolite into the cell and its subsequent incorporation into the alpha-amino groups of glutamate and other amino acids.