Purification and properties of glutamine synthetase from Saccharomyces cerevisiae

We have purified glutamine synthetase over 130-fold from Saccharomyces cerevisiae. The enzyme exhibits a Km for glutamate of 6.3 mM and a Km for ATP of 1.3 mM in the biosynthetic reaction, with a pH optimum from 6.1 to 7.0. Ten to twelve 43,000 molecular weight subunits comprise the active enzyme of 470,000 molecular weight. Rabbit antibodies prepared against the purified enzyme were used to show that induction of enzyme activity correlates with de novo synthesis of the enzyme subunit.     

Regulation of glutamine synthetase from Saccharomyces cerevisiae by repression, inactivation and proteolysis

Glutamine synthetase activity is modulated by nitrogen repression and by two distinct inactivation processes. Addition of glutamine to exponentially grown yeast leads to enzyme inactivation. 50% of glutamine synthetase activity is lost after 30 min (a quarter of the generation time). Removing glutamine from the growth medium results in a rapid recovery of enzyme activity. A regulatory mutation (gdhCR mutation) suppresses this inactivation by glutamine in addition to its derepressing effect on enzymes involved in nitrogen catabolism. The gdhCR mutation also increases the level of proteinase B in exponentially grown yeast. Inactivation of glutamine synthetase is also observed during nitrogen starvation. This inactivation is irreversible and consists very probably of a proteolytic degradation. Indeed, strains bearing proteinase A, B and C mutations are no longer inactivated under nitrogen starvation.     

Three regulatory systems control production of glutamine synthetase in Saccharomyces cerevisiae.

Production of glutamine synthetase in Saccharomyces cerevisiae is controlled by three regulatory systems. One system responds to glutamine levels and depends on the positively acting GLN3 product. This system mediates derepression of glutamine synthetase in response to pyrimidine limitation as well, but genetic evidence argues that this is an indirect effect of depletion of the glutamine pool. The second system is general amino acid control, which couples derepression of a variety of biosynthetic enzymes to starvation for many single amino acids. This system operates through the positive regulatory element GCN4. Expression of histidinol dehydrogenase, which is under general control, is not stimulated by glutamine limitation. A third system responds to purine limitation. No specific regulatory element has been identified, but depression of glutamine synthetase is observed during purine starvation in gln3 gcn4 double mutants. This demonstrates that a separate purine regulatory element must exist. Pulse-labeling and immunoprecipitation experiments indicate that all three systems control glutamine synthetase at the level of subunit synthesis.     

Biochemical and physiological aspects of glutamine synthetase inactivation in Saccharomyces cerevisiae

Saccharomyces cerevisiae glutamine synthetase is inactivated in vivo by the addition of glutamine or ammonia. Inactivation is characterized by a specific loss of synthetase activity; transferase activity remains stable. Several physiological perturbations cause inactivation, such as carbon starvation or limitation for a required amino acid, which could cause a buildup of glutamine. The kinetics of reappearance of synthetase activity after inactivation suggest that the process is reversible in vivo. No change in the native size of the enzyme was associated with inactivation but there appears to be a change in the immunological properties of the enzyme subunit.     

Structure of the N-terminal domain of Escherichia coli glutamine synthetase adenylyltransferase

We report the crystal structure of the N-terminal domain of Escherichia coli adenylyltransferase that catalyzes the reversible nucleotidylation of glutamine synthetase (GS), a key enzyme in nitrogen assimilation. This domain (AT-N440) catalyzes the deadenylylation and subsequent activation of GS. The structure has been divided into three subdomains, two of which bear some similarity to kanamycin nucleotidyltransferase (KNT). However, the orientation of the two domains in AT-N440 differs from that in KNT. The active site of AT-N440 has been identified on the basis of structural comparisons with KNT, DNA polymerase beta, and polyadenylate polymerase. AT-N440 has a cluster of metal binding residues that are conserved in polbeta-like nucleotidyl transferases. The location of residues conserved in all ATase sequences was found to cluster around the active site. Many of these residues are very likely to play a role in catalysis, substrate binding, or effector binding.     

Identification and specificities of N-terminal acetyltransferases from Saccharomyces cerevisiae.

N-terminal acetylation can occur cotranslationally on the initiator methionine residue or on the penultimate residue if the methionine is cleaved. We investigated the three N-terminal acetyltransferases (NATs), Ard1p/Nat1p, Nat3p and Mak3p. Ard1p and Mak3p are significantly related to each other by amino acid sequence, as is Nat3p, which was uncovered in this study using programming alignment procedures. Mutants deleted in any one of these NAT genes were viable, but some exhibited diminished mating efficiency and reduced growth at 37 degrees C, and on glycerol and NaCl-containing media. The three NATs had the following substrate specificities as determined in vivo by examining acetylation of 14 altered forms of iso-1-cytochrome c and 55 abundant normal proteins in each of the deleted strains: Ard1p/Nat1p, subclasses with Ser-, Ala-, Gly- and Thr-termini; Nat3p, Met-Glu- and Met-Asp- and a subclass of Met-Asn-termini; and Mak3p subclasses with Met-Ile- and Met-Leu-termini. In addition, a special subclass of substrates with Ser-Glu- Phe-, Ala-Glu-Phe- and Gly-Glu-Phe-termini required all three NATs for acetylation.     

Biotin protein ligase from Saccharomyces cerevisiae. The N-terminal domain is required for complete activity.

Catalytically active biotin protein ligase from Saccharomyces cerevisiae (EC 6.3.4.15) was overexpressed in Escherichia coli and purified to near homogeneity in three steps. Kinetic analysis demonstrated that the substrates ATP, biotin, and the biotin-accepting protein bind in an ordered manner in the reaction mechanism. Treatment with any of three proteases of differing specificity in vitro revealed that the sequence between residues 240 and 260 was extremely sensitive to proteolysis, suggesting that it forms an exposed linker between an N-terminal 27-kDa domain and the C-terminal 50-kDa domain containing the active site. The protease susceptibility of this linker region was considerably reduced in the presence of ATP and biotin. A second protease-sensitive sequence, located in the presumptive catalytic site, was protected against digestion by the substrates. Expression of N-terminally truncated variants of the yeast enzyme failed to complement E. coli strains defective in biotin protein ligase activity. In vitro assays performed with purified N-terminally truncated enzyme revealed that removal of the N-terminal domain reduced BPL activity by greater than 3500-fold. Our data indicate that both the N-terminal domain and the C-terminal domain containing the active site are necessary for complete catalytic function.     

A glutamine synthetase mutant of Saccharomyces cerevisiae shows defect in cell wall

To study the organization and biosynthesis of the yeast cell wall, hypo-osmolarity-sensitive mutants of Saccharomyces cerevisiae were analyzed. Cells of JS4 were irregular in shape and fragile. Calcofluor staining and quantitative analysis indicated that the chitin content was reduced. By DNA cloning and genetic analysis, the mutation hpo1-1 was found to be allelic to GLN1 which encodes glutamine synthetase. The glutamine content was significantly low in JS4, and the mutant was recovered from the cell wall defect by supplying glutamine in the medium. Partial inhibition of glutamine synthetase by phosphinothricin also induced defects in the cell wall. These results indicate that the shortage of glutamine affects cell wall integrity prior to other cellular functions.     

The polyanion-binding domain of cytoplasmic Lys-tRNA synthetase from Saccharomyces cerevisiae is not essential for cell viability.

Cytoplasmic Lys-tRNA synthetase (LysRS) from Saccharomyces cerevisiae is a dimeric enzyme made up of identical subunits of 68 kDa. By limited proteolysis, this enzyme can be converted to a truncated dimer without loss of activity. Whereas the native enzyme strongly interacts with polyanionic carriers, the modified form displays reduced binding properties. KRS1 is the structural gene for yeast cytoplasmic LysRS. It encodes a polypeptide with an amino-terminal extension composed of about 60-70 amino acid residues, compared to its prokaryotic counterpart. This segment, containing 13 lysine residues, is removed upon proteolytic treatment of the native enzyme. The aim of the present study was to probe in vivo the significance of this amino-terminal extension. We have constructed derivatives of the KRS1 gene, encoding enzymes lacking 58 or 69 amino-terminal residues and, by site-directed mutagenesis, we have changed four or eight lysine residues from the amino-terminal segment of LysRS into glutamic acids. Engineered proteins were expressed in vivo after replacement of the wild-type KRS1 allele. The mutant enzymes displayed reduced specific activities (2-100-fold). A series of carboxy-terminal deletions, encompassing 3, 10 or 15 amino acids, were introduced into the LysRS mutants with modified amino-terminal extensions. The removal of three residues led to a 2-7-fold increase in the specific activity of the mutant enzymes. This partial compensatory effect suggests that interactions between the two extreme regions of yeast LysRS are required for a proper conformation of the native enzyme. All KRS1 derivatives were able to sustain growth of yeast cells, although the mutant cell lines displaying a low LysRS activity grew more slowly. The expression, as single-copy genes, of mutant enzymes with a complete deletion of the amino-terminal extension or with four Lys----Glu mutations, that displayed specific activities close to that of the wild-type LysRS, had no discernable effect on cell growth. We conclude that the polycationic extensions of eukaryotic aminoacyl-tRNA synthetases are dispensable, in vivo, for aminoacylation activities. The results are discussed in relation to the triggering role in in situ compartmentalization of protein synthesis that has been ascribed to the polypeptide-chain extensions that characterize most, if not all, eukaryotic aminoacyl-tRNA synthetases.     

Cloning and characterization of methenyltetrahydrofolate synthetase from Saccharomyces cerevisiae

The folate derivative 5-formyltetrahydrofolate (folinic acid; 5-CHO-THF) was discovered over 40 years ago, but its role in metabolism remains poorly understood. Only one enzyme is known that utilizes 5-CHO-THF as a substrate: 5,10-methenyltetrahydrofolate synthetase (MTHFS). A BLAST search of the yeast genome using the human MTHFS sequence revealed a 211-amino acid open reading frame (YER183c) with significant homology. The yeast enzyme was expressed in Escherichia coli, and the purified recombinant enzyme exhibited kinetics similar to previously purified MTHFS. No new phenotype was observed in strains disrupted at MTHFS or in strains additionally disrupted at the genes encoding one or both serine hydroxymethyltransferases (SHMT) or at the genes encoding one or both methylenetetrahydrofolate reductases. However, when the MTHFS gene was disrupted in a strain lacking the de novo folate biosynthesis pathway, folinic acid (5-CHO-THF) could no longer support the folate requirement. We have thus named the yeast gene encoding methenyltetrahydrofolate synthetase FAU1 (folinic acid utilization). Disruption of the FAU1 gene in a strain lacking both 5-aminoimidazole-4-carboxamide ribonucleotide (AICAR) transformylase isozymes (ADE16 and ADE17) resulted in a growth deficiency that was alleviated by methionine. Genetic analysis suggested that intracellular accumulation of the purine intermediate AICAR interferes with a step in methionine biosynthesis. Intracellular levels of 5-CHO-THF were determined in yeast disrupted at FAU1 and other genes encoding folate-dependent enzymes. In fau1 disruptants, 5-CHO-THF was elevated 4-fold over wild-type yeast. In yeast lacking MTHFS along with both AICAR transformylases, 5-CHO-THF was elevated 12-fold over wild type. 5-CHO-THF was undetectable in strains lacking SHMT activity, confirming SHMT as the in vivo source of 5-CHO-THF. Taken together, these results indicate that S. cerevisiae harbors a single, nonessential, MTHFS activity. Growth phenotypes of multiply disrupted strains are consistent with a regulatory role for 5-CHO-THF in one-carbon metabolism and additionally suggest a metabolic interaction between the purine and methionine pathways.     

Regulation of acetyl-CoA synthetase of Saccharomyces cerevisiae.

Acetyl-coenzyme A synthetase (EC 6.2.1.1) activity of Saccharomyces cerevisiae was determined by a radioactive assay procedure. The activity in vitro was inhibited significantly by NADPH, NADH, or AMP and to a lesser extent by NADP, NAD, or ADP. Glutamic acid and alpha-ketoglutaric acid were not inhibitory. The enzyme level was repressed when the cells were grown in a complex nutrient medium as opposed to the minimal medium. However, a glutamic acid auxotroph glul, when grown in excess glutamic acid, demonstrated a fivefold increase of acetyl-CoA synthetase.     

Characterization of sterol-ester synthetase in Saccharomyces cerevisiae.

Cell-free extracts of Saccharomyces cerevisiae grown under aerobic as well as semi-anaerobic conditions were found to catalyze the synthesis of fatty acid ester of sterol from cholesterol, fatty acid, ATP and CoA, or from cholesterol and fatty acyl-CoA. This result indicates that the enzyme involved in the formation of the ester is acyl-CoA:sterol O-acyltransferase (EC 2.3.1.26). The enzyme had a broad substrate specificity for sterols and acyl-CoAs. The enzyme levels in the cells grown under aerobic and semi-anaerobic conditions were almost equal. The enzyme was located in the microsomal fraction of the aerobically grown cells.     

Sequence of a peptide susceptible to mixed-function oxidation. Probable cation binding site in glutamine synthetase

Mixed-function oxidation of glutamine synthetase from Escherichia coli causes loss of catalytic activity. The inactivation correlates with the loss of 1 of 16 histidine residues/subunit (Levine, R.L. (1983) J. Biol. Chem. 258, 11823-11827). A cyanogen bromide peptide containing the oxidizable histidine has been isolated. Within the protein, the sequence is Met-His-Cys-His-Met. This hydrophilic sequence likely forms one of the divalent metal-binding sites of glutamine synthetase. Binding of Fe2+ to this site permits generation of an activated oxygen species which reacts with a nearby histidine residue. This site-specific free radical mechanism accounts for the specificity of the mixed-function oxidation.     

Partial purification and characterization of succinyl-CoA synthetase from Saccharomyces cerevisiae

Succinyl-CoA synthetase from Saccharomyces cerevisiae was partially purified (20-fold) with a yield of 44%. The Michaelis-Menten constants were determined: Km (succinate) = 17 mM; Km (ATP) = 0.13 mM; Km (CoA) = 0.03 mM. The succinyl-CoA synthetase has a molecular weight of about 80000 dalton (as determined by polyacrylamide gradient gel electrophoresis). The pH optimum is at 6.0. During fermentation the activity of succinyl-CoA synthetase is lower than in aerobically grown yeast cells. The presence of succinyl-CoA synthetase in fermenting yeasts may be regarded as an indication for the oxidative formation of succinate. In fermenting yeast cells succinyl-CoA synthetase is repressed by glucose if ammonium sulphate serves as nitrogen source. This catabolite repression is not observed with disaccharides or when amino acids are used as nitrogen source.     

Primary structure of peptides from bovine brain glutamine synthetase. Comparison with sequences of glutamine synthetases from other organisms

An analysis of the covalent structure of bovine brain glutamine synthetase has been initiated. Cyanogen bromide and tryptic digests have yielded peptides accounting for most of the polypeptide subunit, and sequence analysis has placed in order over half of the amino acids within these peptides. The amino terminus is acetylated and has the following partial sequence: Ac(H, S3, A2, T)-L-B-K-G-I-K-Z-V-Y-M. The carboxyl-terminal sequence is: A-L-P-Q-G-D-K-V-Q-A-M. The peptides isolated from bovine glutamine synthetase show a high degree of homology with peptides isolated from ovine and porcine brain glutamine synthetases. In contrast to the sequence homologies of the proteins from eukaryotic sources, there are no obvious amino acid sequence homologies between bovine brain glutamine synthetase and any prokaryotic glutamine synthetase. Bovine brain glutamine synthetase is inactivated by phenylglyoxal and N-ethylmaleimide. In both cases catalytic activity is protected by the presence of ATP, suggesting the presence of arginine and cysteine residues at or near the ATP binding site.     

Cyclization of backbone-substituted peptides catalyzed by the thioesterase domain from the tyrocidine nonribosomal peptide synthetase

The excised C-terminal thioesterase (TE) domain from the multidomain tyrocidine nonribosomal peptide synthetase (NRPS) was recently shown to catalyze head-to-tail cyclization of a decapeptide thioester to form the cyclic decapeptide antibiotic tyrocidine A [Trauger, J. W., Kohli, R. M., Mootz, H. D., Marahiel, M. A., and Walsh, C. T. (2000) Nature 407, 215-218]. The peptide thioester substrate was a mimic of the TE domain's natural, synthetase-bound substrate. We report here the synthesis of modified peptide thioester substrates in which parts of the peptide backbone are altered either by the replacement of three amino acid blocks with a flexible spacer or by replacement of individual amide bonds with ester bonds. Rates of TE domain catalyzed cyclization were determined for these substrates and compared with that of the wild-type substrate, revealing that some parts of the peptide backbone are important for cyclization, while other parts can be modified without significantly affecting the cyclization rate. We also report the synthesis of a modified substrate in which the N-terminal amino group of the wild-type substrate, which is the nucleophile in the cyclization reaction, is replaced with a hydroxyl group and show that this compound is cyclized by the TE domain to form a macrolactone at a rate comparable to that of the wild-type substrate. These results demonstrate that the TE domain from the tyrocidine NRPS can catalyze cyclization of depsipeptides and other backbone-substituted peptides and suggest that during the cyclization reaction the peptide substrate is preorganized for cyclization in the enzyme active site in part by intramolecular backbone hydrogen bonds analogous to those in the product tyrocidine A.     

Fatty acid synthetase of Saccharomyces cerevisiae

A light particle fraction of Saccharomyces cerevisiae, obtained from the crude ribosomal material, and containing the fatty acid synthetase, consisted primarily of 27S and 47S components. This fraction has a protein-ribonucleic acid ratio of about 13. Electron micrographs showed particles ranging in diameter between 100 and 300 A in this material. By use of density gradient analysis, the fatty acid synthetase was found in the 47S component. This component contained particles which were predominantly 300 A in diameter and which were considerably flatter than ribosomes, and it consisted almost entirely of protein.