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.     

Nucleotide sequence of the Saccharomyces cerevisiae PUT4 proline-permease-encoding gene: similarities between CAN1, HIP1 and PUT4 permeases

The complete nucleotide (nt) sequence of the PUT4 gene, whose product is required for high-affinity proline active transport in the yeast Saccharomyces cerevisiae, is presented. The sequence contains a single long open reading frame of 1881 nt, encoding a polypeptide with a calculated Mr of 68,795. The predicted protein is strongly hydrophobic and exhibits six potential glycosylation sites. Its hydropathy profile suggests the presence of twelve membrane-spanning regions flanked by hydrophilic N- and C-terminal domains. The N terminus does not resemble signal sequences found in secreted proteins. These features are characteristic of integral membrane proteins catalyzing translocation of ligands across cellular membranes. Protein sequence comparisons indicate strong resemblance to the arginine and histidine permeases of S. cerevisiae, but no marked sequence similarity to the proline permease of Escherichia coli or to other known prokaryotic or eukaryotic transport proteins. The strong similarity between the three yeast amino acid permeases suggests a common ancestor for the three proteins.     

Engineering of yeast Put4 permease and its application to lager yeast for efficient proline assimilation

The Saccharomyces cerevisiae Put4 permease is significant for the transport of proline, alanine, and glycine. Put4p downregulation is counteracted by npi1 mutation that affects the cellular ubiquitination function. Here we describe mutant Put4 permeases, in which up to nine lysine residues in the cytoplasmic N-terminal domain have been replaced by arginine. The steady-state protein level of the mutant permease Put4-20p (Lys9, Lys34, Lys35, Lys60, Lys68, Lys71, Lys93, Lys105, Lys107 --> Arg) was largely higher compared to that of the wild-type Put4p, indicating that the N-terminal lysines can undergo ubiquitination and the subsequent degradation steps. Proline is the only amino acid that yeast assimilates with difficulty under standard brewing conditions. A lager yeast strain provided with Put4-20p was able to assimilate proline efficiently during beer fermentations. These results suggest possible industrial applications of the mutant Put4 permeases in improved fermentation systems for beer and other alcoholic beverages based on proline-rich fermentable sources.     

A C-terminal di-leucine motif and nearby sequences are required for NH4+-induced inactivation and degradation of the general amino acid permease, Gap1p, of Saccharomyces cerevisiae

The general amino acid permease, Gap1, of Saccharomyces cerevisiae is very active in cells grown on proline as the sole nitrogen source. Adding NH₄⁺ to the medium triggers inactivation and degradation of the permease via a regulatory process involving Npi1p/Rsp5p, a ubiquitin–protein ligase. In this study, we describe several mutations affecting the C-terminal region of Gap1p that render the permease resistant to NH₄⁺-induced inactivation. An in vivo isolated mutation ( gap1 ^pgr  ) causes a single Glu→Lys substitution in an amino acid context similar to the DXKSS sequence involved in ubiquitination and endocytosis of the yeast α-factor receptor, Ste2p. Another replacement, substitution of two alanines for a di-leucine motif, likewise protects the Gap1 permease against NH₄⁺-induced inactivation. In mammalian cells, such a motif is involved in the internalization of several cell-surface proteins. These data provide the first indication that a di-leucine motif influences the function of a plasma membrane protein in yeast. Mutagenesis of a putative phosphorylation site upstream from the di-leucine motif altered neither the activity nor the regulation of the permease. In contrast, deletion of the last eleven amino acids of Gap1p, a region conserved in other amino acid permeases, conferred resistance to NH₄⁺ inactivation. Although the C-terminal region of Gap1p plays an important role in nitrogen control of activity, it was not sufficient to confer this regulation to two NH₄⁺-insensitive permeases, namely the arginine (Can1p) and uracil (Fur4p) permeases.     

Nitrogen-regulated Ubiquitination of the Gap1 Permease of Saccharomyces cerevisiae

Addition of ammonium ions to yeast cells growing on proline as the sole nitrogen source induces rapid inactivation and degradation of the general amino acid permease Gap1 through a process requiring the Npi1/Rsp5 ubiquitin (Ub) ligase. In this study, we show that NH₄⁺ induces endocytosis of Gap1, which is then delivered into the vacuole where it is degraded. This down-regulation is accompanied by increased conversion of Gap1 to ubiquitinated forms. Ubiquitination and subsequent degradation of Gap1 are impaired in the npi1 strain. In this mutant, the amount of Npi1/Rsp5 Ub ligase is reduced >10-fold compared with wild-type cells. The C-terminal tail of Gap1 contains sequences, including a di-leucine motif, which are required for NH₄⁺-induced internalization and degradation of the permease. We show here that mutant Gap1 permeases affected in these sequences still bind Ub. Furthermore, we provide evidence that only a small fraction of Gap1 is modified by Ub after addition of NH₄⁺ to mutants defective in endocytosis.     

Control of the synthesis, activity, and turnover of enzymes of sulfur metabolism in Neurospora crassa

The synthesis of aryl sulfatase, choline-O-sulfate permease, and two distinct sulfate permeases are repressed by methionine, but the activity of these enzymes is not subject to feedback inhibition. The permease species, but not aryl sulfatase, are also regulated by dynamic turnover, displaying a functional half-life of approximately 2 hr. The rate of turnover of these permeases is not influenced by the presence of the end product, methionine. Development of sulfate permease activity occurs only by de novo synthesis which requires both a lifting of methionine repression and a functional cys-3 product. The turnover system for sulfate permease is not present in dormant conidia but appears to be synthesized relatively rapidly during germination. Preexisting conidial sulfate permease is lost by turnover during germination and outgrowth into the mycelial phase, during which both permease species are synthesized anew, although the high affinity system contributes most of the total activity in growing mycelia.     

Control of Amino Acid Permease Sorting in the Late Secretory Pathway of Saccharomyces Cerevisiae by Sec13, Lst4, Lst7 and Lst8

The SEC13 gene was originally identified by temperature-sensitive mutations that block all protein transport from the ER to the Golgi. We have found that at a permissive temperature for growth, the sec13-1 mutation selectively blocks transport of the nitrogen-regulated amino acid permease, Gap1p, from the Golgi to the plasma membrane, but does not affect the activity of constitutive permeases such as Hip1p, Can1p, or Lyp1p. Different alleles of SEC13 exhibit different relative effects on protein transport from the ER to the Golgi, or on Gap1p activity, indicating distinct requirements for SEC13 function at two different steps in the secretory pathway. Three new genes, LST4, LST7, and LST8, were identified that are also required for amino acid permease transport from the Golgi to the cell surface. Mutations in LST4 and LST7 reduce the activity of the nitrogen-regulated permeases Gap1p and Put4p, whereas mutations in LST8 impair the activities of a broader set of amino acid permeases. The LST8 gene encodes a protein composed of WD-repeats and has a close human homologue. The LST7 gene encodes a novel protein. Together, these data indicate that SEC13, LST4, LST7, and LST8 function in the regulated delivery of Gap1p to the cell surface, perhaps as components of a post-Golgi secretory-vesicle coat.     

Regulation of sulfate transport in neurospora by transinhibition and by inositol depletion

Neurospora possesses two distinct sulfate transport systems, a low-affinity form (Permease I) which is the only type found in conidia, and a second species (Permease II) which predominates during the mycelial stage. Although methionine represses the synthesis of both of these permeases, inorganic sulfate only partially represses the mycelial form and does not affect the synthesis of Permease I. Both transport systems are also regulated by transinhibition. The transinhibition which occurs in mycelia is not due to an intracellular pool of inorganic sulfate, but is instead exerted by an early intermediate of the sulfate assimilatory pathway.The development of functional sulfate transport activity depends upon genetic and metabolic events which affect the cell membrane. The synthesis of sulfate permease activity in the inos mutant requires an exogenous supply of inositol. The effect of the cot mutant, which is thought to interfere with membrane synthesis, also prevents the development of sulfate permease at the restrictive temperature. The maintenance of pre-existing functional sulfate permease activity apparently also requires a continuous renewal of membrane components since withdrawal of inositol from inos mutants results in a rapid inactivation of transport activity.     

Evidence for Positive Regulation of the Proline Utilization Pathway in Saccharomyces cerevisiae

A mutation has been identified that prevents Saccharomyces cerevisiae cells from growing on proline as the sole source of nitrogen, causes noninducible expression of the PUT1 and PUT2 genes, and is completely recessive. In the put3-75 mutant, the basal level of expression (ammonia as nitrogen source) of PUT1-lacZ and PUT2-lacZ gene fusions as measured by beta-galactosidase activity is reduced 4- and 7-fold, respectively, compared with the wild-type strain. Normal regulation is not restored when the cells are grown on arginine as the sole nitrogen source and put3-75 cells remain sensitive to the proline analog, L-azetidine-2-carboxylic acid, indicating that the block is not at the level of transport of the inducer, proline. In a cross between the put3-75 strain and the semidominant, constitutive mutation PUT3c-68, only parental ditype tetrads were found, indicating allelism of the two mutations. Further support for allelism derives from the comparison of enzyme levels in heteroallelic and heterozygous diploid strains. The constitutive allele appears to be fully dominant to the noninducible allele but only partially dominant to the wild type, suggesting an interaction between the wild-type and PUT3c-68 gene products. The PUT3 gene maps on chromosome XI, about 5.7 cM from the centromere. The phenotypes of alleles of the PUT3 gene, either recessive and noninducible (the put3-75 phenotype) or semidominant and constitutive (the PUT3c-68 phenotype), and their pleiotropy suggest that the PUT3 gene product is a positive activator of the proline utilization pathway.     

Physiological studies of tryptophan transport and tryptophanase operon induction in Escherichia coli.

Escherichia coli forms three permeases that can transport the amino acid tryptophan: Mtr, AroP, and TnaB. The structural genes for these permeases reside in separate operons that are subject to different mechanisms of regulation. We have exploited the fact that the tryptophanase (tna) operon is induced by tryptophan to infer how tryptophan transport is influenced by the growth medium and by mutations that inactivate each of the permease proteins. In an acid-hydrolyzed casein medium, high levels of tryptophan are ordinarily required to obtain maximum tna operon induction. High levels are necessary because much of the added tryptophan is degraded by tryptophanase. An alternate inducer that is poorly cleaved by tryptophanase, 1-methyltryptophan, induces efficiently at low concentrations in both tna+ strains and tna mutants. In an acid-hydrolyzed casein medium, the TnaB permease is most critical for tryptophan uptake; i.e., only mutations in tnaB reduce tryptophanase induction. However, when 1-methyltryptophan replaces tryptophan as the inducer in this medium, mutations in both mtr and tnaB are required to prevent maximum induction. In this medium, AroP does not contribute to tryptophan uptake. However, in a medium lacking phenylalanine and tyrosine the AroP permease is active in tryptophan transport; under these conditions it is necessary to inactivate the three permeases to eliminate tna operon induction. The Mtr permease is principally responsible for transporting indole, the degradation product of tryptophan produced by tryptophanase action. The TnaB permease is essential for growth on tryptophan as the sole carbon source. When cells with high levels of tryptophanase are transferred to tryptophan-free growth medium, the expression of the tryptophan (trp) operon is elevated. This observation suggests that the tryptophanase present in these cells degrades some of the synthesized tryptophan, thereby creating a mild tryptophan deficiency. Our studies assign roles to the three permeases in tryptophan transport under different physiological conditions.     

Proline transport in Salmonella typhimurium: putP permease mutants with altered substrate specificity.

The putP gene encodes a proline permease required for Salmonella typhimurium LT2 to grow on proline as the sole source of nitrogen. The wild-type strain is sensitive to two toxic proline analogs (azetidine-2-carboxylic acid and 3,4-dehydroproline) also transported by the putP permease. Most mutations in putP prevent transport of all three substrates. Such mutants are unable to grow on proline and are resistant to both of the analogs. To define domains of the putP gene that specify the substrate binding site, we used localized mutagenesis to isolate rare mutants with altered substrate specificity. The position of the mutations in the putP gene was determined by deletion mapping. Most of the mutations are located in three small (approximately 100-base-pair) deletion intervals of the putP gene. The sensitivity of the mutants to the proline analogs was quantitated by radial streaking to determine the affinity of the mutant permeases for the substrates. Some of the mutants showed apparent changes in the kinetics of the substrates transported. These results indicate that the substrate specificity mutations are probably due to amino acid substitutions at or near the active site of proline permease.