Use of analogues of methionine and methionyl adenylate to sample conformational changes during catalysis in Escherichia coli methionyl-tRNA synthetase

Binding of methionine to methionyl-tRNA synthetase (MetRS) is known to promote conformational changes within the active site. However, the contribution of these rearrangements to enzyme catalysis is not fully understood. In this study, several methionine and methionyl adenylate analogues were diffused into crystals of the monomeric form of Escherichia coli methionyl-tRNA synthetase. The structures of the corresponding complexes were solved at resolutions below 1.9A and compared to those of the enzyme free or complexed with methionine. Residues Y15 and W253 play key roles in the strength of the binding of the amino acid and of its analogues. Indeed, full motions of these residues are required to recover the maximum in free energy of binding. Residue Y15 also controls the size of the hydrophobic pocket where the amino acid side-chain interacts. H301 appears to participate to the specific recognition of the sulphur atom of methionine. Complexes with methionyl adenylate analogues illustrate the shielding by MetRS of the region joining the methionine and adenosine moieties. Finally, the structure of MetRS complexed to a methionine analogue mimicking the tetrahedral carbon of the transition state in the aminoacylation reaction was solved. On the basis of this model, we propose that, in response to the binding of the 3'-end of tRNA, Y15 moves again in order to deshield the anhydride bond in the natural adenylate.     

Role of methionyl-transfer ribonucleic acid in the regulation of methionyl-transfer ribonucleic acid synthetase of Escherichia coli K-12.

A decrease in the in vivo acylation level of methionine transfer ribonucleic acid (tRNAmet) induced by methioninyl adenylate led to a specific derepression of methionyl-transfer ribonucleic acid (tRNA) synthetase formation. This derepression required de novo protein synthesis and was reflected by overproduction of unaltered enzyme. Two different strains of Escherichia coli K-12 that have normal levels of methionyl-tRNA synthetase were examined and the derepression of methionyl-tRNA synthetase was observed in both. Moreover, for one of these strains, the relation between the level of methionyl-tRNA synthetase and deacylation level of tRNAmet was established; under the growth conditions used, when more than 25% of tRNAmet was deacylated, methionyl-tRNA synthetase formation was derepressed and the level of derepression became proportional to the amount of tRNAmet deacylated. Concomitantly, the enzyme was subject to specific inactivation as a consequence of which the true de novo rate of derepression of the formation of this enzyme was higher than that determined by measurements of enzyme activity. These studies were extended to strains AB311 and ed2, which had a constitutive enhanced level of methionyl-tRNA synthetase. In these strains no derepression of enzyme formation was observed on reducing the acylation level of tRNAmet by use of methioninyl adenylate.     

Methionyl-transfer ribonucleic acid deficiency during G1 arrest of Saccharomyces cerevisiae.

The mesl- mutants of Saccharomyces cerevisiae cease division and accumulate in the G1 interval of the cell cycle when deprived of methionine or shifted from 23 to 36 degrees C in the presence of methionine. Synchronous cell cycle arrest results from a deficiency of charged methionyl-transfer ribonucleic acid (methionyl-tRNAMet) as shown by direct measurement of the in vivo pools of methionine, S-adenosylmethionine, and methionyl-tRNAMet. The deficiency of methionyl-tRNAMet in these cells is the consequence of a lesion in a single gene, mes1. mes1 appears to be the structural gene for the methionyl-tRNA synthetase because some revertants of this mutation exhibited a thermolabile methionyl-tRNA synthetase in vitro. A sufficient hypothesis to explain these and previous results is that the control of cell division by S. cerevisiae in response to nutrient limitation is mediated through aminoacyl-tRNA or subsequent steps in protein biosynthesis.     

Covalent methionylation of Escherichia coli methionyl-tRNA synthethase: identification of the labeled amino acid residues by matrix-assisted laser desorption-ionization mass spectrometry.

Methionyl-adenylate, the mixed carboxylic-phosphoric acid anhydride synthesized by methionyl-tRNA synthetase (MetRS) is capable of reacting with this synthetase or other proteins, by forming an isopeptide bond with the epsilon-NH2 group of lysyl residues. It is proposed that the mechanism for the in vitro methionylation of MetRS might be accounted for by the in situ covalent reaction of methionyl-adenylate with lysine side chains surrounding the active center of the enzyme, as well as by exchange of the label between donor and acceptor proteins. Following the incorporation of 7.0 +/- 0.5 mol of methionine per mol of a monomeric truncated methionyl-tRNA synthetase species, the enzymic activities of [32P]PPi-ATP isotopic exchange and tRNA(Met) aminoacylation were lowered by 75% and more than 90%, respectively. The addition of tRNA(Met) protected the enzyme against inactivation and methionine incorporation. Matrix-assisted laser desorption-ionization mass spectrometry designated lysines-114, -132, -142 (or -147), -270, -282, -335, -362, -402, -439, -465, and -547 of truncated methionyl-tRNA synthetase as the target residues for covalent binding of methionine. These lysyl residues are distributed at the surface of the enzyme between three regions [114-150], [270-362], and [402-465], all of which were previously shown to be involved in catalysis or to be located in the binding sites of the three substrates, methionine, ATP, and tRNA.     

Initiation of protein synthesis by folate-sufficient and folate-deficient Streptococcus faecalis R: partial purification and properties of methionyl-transfer ribonucleic acid synthetase and methionyl-transfer ribonucleic acid formyltransferase

The initiation of protein synthesis by Streptococcus faecalis R grown in folate-free culture occurs without N-formylation or N-acylation of methionyl-tRNA(f) (Met). Methionyl-tRNA synthetase and methionyl-tRNA formyltransferase were partially purified from S. faecalis grown under normal culture conditions in the presence of folate (plus-folate); the general properties of the enzymes were determined and compared with the properties of the enzymes purified from wild-type cells grown in the absence of folate (minus-folate). S. faecalis methionyl-tRNA synthetase displays optimal activity at pH values between 7.2 and 7.8, requires Mg(2+), and has an apparent molecular weight of 106,000, as determined by gel filtration, and 127,000, as determined by sucrose density gradient centrifugation. The K(m) values of plus-folate methionyl-tRNA synthetase for each of the three substrates in the aminoacylation reaction (l-methionine, adenosine triphosphate, and tRNA) are nearly identical to the respective substrate Michaelis constants of minus-folate methionyl-tRNA synthetase. Furthermore, both plus- and minus-folate S. faecalis methionyl-tRNA synthetases catalyze, at equal rates, the aminoacylation of tRNA(f) (Met) and tRNA(m) (Met) isolated from either plus-folate or minus-folate cells. S. faecalis methionyl-tRNA formyltransferase displays optimal activity at pH values near 7.0, is stimulated by Mg(2+), and has an apparent molecular weight of approximately 29,900 when estimated by sucrose density gradient centrifugation. The K(m) value of plus-folate formyltransferase for plus-folate Met-tRNA(f) (Met) does not differ significantly from that of minus-folate formyltransferase for minus-folate Met-tRNA(f) (Met). Both enzymes can utilize either 10-formyltetrahydrofolate or 10-formyltetrahydropteroyltriglutamate as the formyl donor; the Michaelis constant for the monoglutamyl pteroyl coenzyme is slightly less than that of the triglutamyl pteroyl coenzyme for both transformylases. Tetrahydrofolate and uncharged tRNA(f) (Met) are competitive inhibitors of both plus- and minus-folate S. faecalis formyltransferase; folic acid, pteroic acid, aminopterin, and Met-tRNA(m) (Met) are not inhibitory. These results indicate that the presence or absence of folic acid in the culture medium of S. faecalis has no apparent effect on either methionyl-tRNA synthetase or methionyl-tRNA formyltransferase, the two enzymes directly involved in the formation of formylmethionyl-tRNA(f) (Met). Therefóre, the lack of N-formylation of Met-tRNA(f) (Met) in minus-folate S. faecalis is due to the absence of the formyl donor, a 10-formyl-tetrahydropteroyl derivative. Although the general properties of S. faecalis methionyl-tRNA synthetase are similar to those of other aminoacyl-tRNA synthetases, S. faecalis methionyl-tRNA formyltransferase differs from other previously described transformylases in certain kinetic parameters.     

Amino acid binding by the class I aminoacyl-tRNA synthetases: role for a conserved proline in the signature sequence.

Although partial or complete three-dimensional structures are known for three Class I aminoacyl-tRNA synthetases, the amino acid-binding sites in these proteins remain poorly characterized. To explore the methionine binding site of Escherichia coli methionyl-tRNA synthetase, we chose to study a specific, randomly generated methionine auxotroph that contains a mutant methionyl-tRNA synthetase whose defect is manifested in an elevated Km for methionine (Barker, D.G., Ebel, J.-P., Jakes, R.C., & Bruton, C.J., 1982, Eur. J. Biochem. 127, 449-457), and employed the polymerase chain reaction to sequence this mutant synthetase directly. We identified a Pro 14 to Ser replacement (P14S), which accounts for a greater than 300-fold elevation in Km for methionine and has little effect on either the Km for ATP or the kcat of the amino acid activation reaction. This mutation destabilizes the protein in vivo, which may partly account for the observed auxotrophy. The altered proline is found in the "signature sequence" of the Class I synthetases and is conserved. This sequence motif is 1 of 2 found in the 10 Class I aminoacyl-tRNA synthetases and, in the known structures, it is in the nucleotide-binding fold as part of a loop between the end of a beta-strand and the start of an alpha-helix. The phenotype of the mutant and the stability and affinity for methionine of the wild-type and mutant enzymes are influenced by the amino acid that is 25 residues beyond the C-terminus of the signature sequence.(ABSTRACT TRUNCATED AT 250 WORDS)     

The detection of messenger ribonucleic acid sequences in heterogeneous nuclear ribonucleic acid fractions of the oestrogen-stimulated rat uterus.

Active xanthine oxidase was labelled specifically with 33S in the cyanide-labile site of the molybdenum centre. The Very Rapid molybdenum (V) e.p.r. signal, generated from this, shows strong coupling of 33S to molybdenum, providing unambiguous evidence that, at least in the signal-giving species, this sulphur atom is a ligand of molybdenum. The structure of the signal-giving species is discussed.     

Mechanism of repression of methionine biosynthesis in Escherichia coli. II. The effect of metJ mutations on the free amino acid pool

Summary Ethionine-resistant mutants (metJ mutants) were isolated and characterized as constitutive in the biosynthesis of methionine. Such mutations resulted in marked differences or alterations in the free amino acid pool. In some strains the levels of threonine and histidine were elevated by as much as 13 and 22 times that of the wild type level. The possibility that structural modifications of methionyl-tRNA were giving rise to constitutive methionine biosynthesis and the apparent aberrations in the free amino acid pool, was in large part ruled out by a comparison of the mobilities of wild type and mutant methionyl-tRNA on benzoylated DEAE-cellulose columns. The results obtained are consistent with the view that the product of the metJ locus is a repressor protein which is directly involved in the repression of the methionine genes.     

Levels and modification of methionyl-transfer RNA in preimplantation rabbit embryos.

Transfer RNA with l-methionine acceptor activity was extracted from preimplantation rabbit embryos and purified on reverse-phase-3 columns. The molar quantity of methionine acylated to RNA increases as embryo development proceeds from the 16-cell stage to the 80,000 cell blastocyst stage. However, the quantity of methionyl-tRNA per genome declines 100-fold as the embryo cell number increases. Formylation of methionyl-tRNA illustrated that approximately one-third of tRNA^Met extracted was tRNA_f^Met. Methylation of purified methionyl-tRNA by an adult rabbit liver methylase extract illustrated that two-day preimplantation embryo tRNA is highly hypomethylated relative to tRNA from later stages of development. The hypomethylated methionyl-tRNA was also less effective in ribosome binding studies than more fully methylated methionyl-tRNA present in the later stages of embryo development.     

Activation of methionine by Escherichia coli methionyl-tRNA synthetase

In the present work, we have examined the function of three amino acid residues in the active site of Escherichia coli methionyl-tRNA synthetase (MetRS) in substrate binding and catalysis using site-directed mutagenesis. Conversion of Asp52 to Ala resulted in a 10,000-fold decrease in the rate of ATP-PPi exchange catalyzed by MetRS with little or no effect on the Km's for methionine or ATP or on the Km for the cognate tRNA in the aminoacylation reaction. Substitution of the side chain of Arg233 with that of Gln resulted in a 25-fold increase in the Km for methionine and a 2000-fold decrease in kcat for ATP-PPi exchange, with no change in the Km for ATP or tRNA. These results indicate that Asp52 and Arg233 play important roles in stabilization of the transition state for methionyl adenylate formation, possibly directly interacting with complementary charged groups (ammonium and carboxyl) on the bound amino acid. Primary sequence comparisons of class I aminoacyl-tRNA synthetases show that all but one member of this group of enzymes has an aspartic acid residue at the site corresponding to Asp52 in MetRS. The synthetases most closely related to MetRS (including those specific for Ile, Leu, and Val) also have a conserved arginine residue at the position corresponding to Arg233, suggesting that these conserved amino acids may play analogous roles in the activation reaction catalyzed by each of these enzymes. Trp305 is located in a pocket deep within the active site of MetRS that has been postulated to form the binding cleft for the methionine side chain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Methionine-mediated repression in Saccharomyces cerevisiae: a pleiotropic regulatory system involving methionyl transfer ribonucleic acid and the product of gene eth2

Detailed study of methionine-mediated repression of enzymes involved in methionine biosynthesis in Saccharomyces cerevisiae led to classification of these enzymes into two distinct regulatory groups. Group I comprises four enzymes specifically involved in different parts of methionine biosynthesis, namely, homoserine-O-transacetylase, homocysteine synthetase, adenosine triphosphate sulfurylase, and sulfite reductase. Repressibility of these enzymes is greatly decreased in strains carrying a genetically impaired methionyl-transfer ribonucleic acid (tRNA) synthetase (mutation ts(-) 296). Conditions leading to absence of repression in the mutant strain have been correlated with a sharp decrease in bulk tRNA(met) charging, whereas conditions which restore repressibility of group I enzymes also restore tRNA(met) charging. These findings implicate methionyl-tRNA in the regulatory process. However, the absence of a correlation in the wild type between methionyl-tRNA charging and the levels of methionine group I enzymes suggests that only a minor iso accepting species of tRNA(met) may be devoted with a regulatory function. Repressibility of the same four enzymes (group I) was also decreased in strains carrying the regulatory mutation eth2(r). Although structural genes coding for two of these enzymes, as well as mutations ts(-) 296 and eth2(r) segregate independently to each other, synthesis of group I enzymes is coordinated. The pleiotropic regulatory system involved seems then to comprise beside a "regulatory methionyl tRNA(met)," another element, product of gene eth2, which might correspond either to an aporepressor protein or to the "regulatory tRNA(met)" itself. Regulation of group II enzymes is defined by response to exogenous methionine, absence of response to either mutations ts(-) 296 and eth2(r), and absence of coordinacy with group I enzymes. However, the two enzymes which belong to this group and are both involved in threonine and methionine biosynthesis undergo distinct regulatory patterns. One, aspartokinase, is subject to a bivalent repression exerted by threonine and methionine, and the other, homoserine dehydrogenase, is subject only to methionine-mediated repression. Participation of at least another aporepressor and another corepressor, different from the ones involved in regulation of group I enzymes, is discussed.     

Methionine-and S-adenosyl methionine-mediated repression in a methionyl-transfer ribonucleic-acid synthetase mutant of Saccharomyces cerevisiae.

A Saccharomyces cerevisiae mutant strain unable to grow at 38 C and bearing a modified methionyl-transfer ribonucleic acid (tRNA) synthetase has been studied. It has been shown that, in this mutant, the percentage of tRNAmet charged in vivo paralleled the degree of repressibility of methionine biosynthetic enzymes by exogenous methionine. On the contrary, the repression mediated by exogenous S-adenosylmethionine does not correlate with complete acylation of tRNAmet. Althought McLaughlin and Hartwell reported previously that the thermosensitivity and the defect in the methionyl-tRNA synthetase were due to the same genetic lesion (1969), no diffenence could be found in the methionyl-tRNA synthetase activity or in the pattern of repressibility of methionine biosynthetic pathway after growth at the premissive and at a semipermissive temperature. It appears that the mutant also exhibits some other modified characters that render unlikely the existence of only one genetic lesion in this strain. A genetic study of this mutant was undertaken which led to the conclusion that the thermosensitivity and the other defects are not related to the methionyl-tRNA synthetase modification. It was shown that the modified repressibility of methionine biosynthetic enzymes by methionine and the lack of acylation of tRNAmet in vivo follow the methionyl-tRNA synthetase modification. These results are in favor of the idea that methionyl-tRNAmet, more likely than methionine, is implicated in the regulation of the biosynthesis of methionine.     

Purification and some properties of a protein binding and deacylating initiator transfer ribonucleic acid

1. A protein factor promoting the binding of initiator tRNA to the 40S ribosomal subunit was purified to homogeneity (more than 2500-fold) from rat liver cytosol. It has a mol.wt. of 265000 and is composed of four subunits of identical molecular weight. 2. This factor directs the binding of methionyl-tRNA(fMet) and to a lesser extent also of N-acetylphenylalanyl-tRNA, but not of methionyl-tRNA(Met) or phenylalanyl-tRNA, to the smaller ribosomal subunit at high concentrations of GTP (8-10mm) with an optimum at pH4.0. As evidenced by sucrose-density-gradient centrifugation, initiator tRNA becomes bound to the 40S subunit or to 80S ribosomes. 3. A deacylase activity specific for methionyl-tRNA(fMet) is associated with the pure factor. The factor significantly stimulates the translation of natural message in systems containing polyribosomes and both purified peptide-elongation factors. 4. The factor binds initiator tRNA or GTP to form unstable binary complexes and forms a ternary complex with methionyl-tRNA(fMet) and GTP. This complex is relatively stable. 5. In the absence of any cofactors the factor forms a stable complex with 40S and 80S ribosomes. This preformed ribosomal complex binds efficiently initiator tRNA at pH7.5 and low concentrations of GTP (1-2mm). The ternary complex of the factor with methionyl-tRNA(fMet) and GTP may be liberated from this ribosomal complex. 6. A protein factor capable of promoting the binding and simultaneously the deacylation of initiator tRNA may apparently have a regulatory function in physiological gene translation by removing an excess of methionyl-tRNA(fMet) not required for translation.     

Modification of specific lysine residues in E. coli methionyl-tRNA synthetase by crosslinking to E. coli formylmethionine tRNA

A protein affinity labeling derivative of E. coli tRNAfMet has been prepared which carries an average of one reactive side chain per molecule, distributed over four structural regions. Each side chain contains a disulfide bond capable of reaction with cysteine residues and an N-hydroxysuccinimide ester group capable of coupling to lysine epsilon-amino groups in proteins. Reaction of the modified tRNA with E. coli methionyl-tRNA synthetase leads to crosslinking only by reaction with lysine residues in the protein. Examination of the tRNA present in the crosslinked complex reveals that the enzyme is coupled to side chains attached to the 5' terminal nucleotide, the dihydrouridine loop, the anticodon and the CCA sequence. Digestion of the crosslinked enzyme with trypsin followed by peptide mapping reveals that the major crosslinking reactions occur at four specific lysine residues, with minor reaction at two additional sites. Native methionyl-tRNA synthetase contains 90 lysine residues, 45 in unique sequences of the dimeric alpha 2 enzyme. Crosslinking of the protein to different regions in tRNAfMet thus occurs with the high degree of selectivity necessary for use in determining the peptide sequences which are near specific nucleotide sequences of tRNA bound to the protein.     

Lysine 335, part of the KMSKS signature sequence, plays a crucial role in the amino acid activation catalysed by the methionyl-tRNA synthetase from Escherichia coli.

The KMSKS pattern, conserved among several aminoacyl-tRNA synthetase sequences, was first recognized in the Escherichia coli methionyl-tRNA synthetase through affinity labelling with an oxidized reactive derivative of tRNA(Met)f. Upon complex formation, two lysine residues of the methionyl-tRNA synthetase (Lys61 and 335, the latter being part of the KMSKS sequence) could be crosslinked by the 3'-acceptor end of the oxidized tRNA. Identification of an equivalent reactive lysine residue at the active centre of tyrosyl-tRNA synthetase designated the KMSKS sequence as a putative component of the active site of methionyl-tRNA synthetase. To probe the functional role of the labelled lysine residue within the KMSKS pattern, two variants of methionyl-tRNA synthetase containing a glutamine residue at either position 61 or 335 were constructed by using site-directed mutagenesis. Substitution of Lys61 slightly affected the enzyme activity. In contrast, the enzyme activities were very sensitive to the substitution of Lys335 by Gln. Pre-steady-state analysis of methionyladenylate synthesis demonstrated that this substitution rendered the enzyme unable to stabilize the transition state complex in the methionine activation reaction. A similar effect was obtained upon substituting Lys335 by an alanine instead of a glutamine residue, thereby excluding an effect specific for the glutamine side-chain. Furthermore, the importance of the basic character of Lys335 was investigated by studying mutants with a glutamate or an arginine residue at this position. It is concluded that the N-6-amino group of Lys335 plays a crucial role in the activation of methionine, mainly by stabilizing the transient complex on the way to methionyladenylate, through interaction with the pyrophosphate moiety of bound ATP-Mg2+. We propose, therefore, that the KMSKS pattern in the structure of an aminoacyl-tRNA synthetase sequence represents a signature sequence characteristic of both the pyrophosphate subsite and the catalytic centre.     

How methionyl-tRNA synthetase creates its amino acid recognition pocket upon L-methionine binding

Amino acid selection by aminoacyl-tRNA synthetases requires efficient mechanisms to avoid incorrect charging of the cognate tRNAs. A proofreading mechanism prevents Escherichia coli methionyl-tRNA synthetase (EcMet-RS) from activating in vivo L-homocysteine, a natural competitor of L-methionine recognised by the enzyme. The crystal structure of the complex between EcMet-RS and L-methionine solved at 1.8 A resolution exhibits some conspicuous differences with the recently published free enzyme structure. Thus, the methionine delta-sulphur atom replaces a water molecule H-bonded to Leu13N and Tyr260O(eta) in the free enzyme. Rearrangements of aromatic residues enable the protein to form a hydrophobic pocket around the ligand side-chain. The subsequent formation of an extended water molecule network contributes to relative displacements, up to 3 A, of several domains of the protein. The structure of this complex supports a plausible mechanism for the selection of L-methionine versus L-homocysteine and suggests the possibility of information transfer between the different functional domains of the enzyme.     

The control of ribonucleic acid synthesis in bacteria. Fluctuations in messenger ribonucleic acid synthesis in cultures recovering from amino acid starvation

Changes in the cell content and rate of synthesis of mRNA were studied in auxotrophs of Escherichia coli recovering from a period of amino acid deprivation. Parallel studies were carried out on bacterial strains inhibited with trimethoprim, when glycine and methionine were added to relieve an amino acid deficiency. In the latter case, protein synthesis was still severely inhibited through a lack of N-formylmethionyl-tRNA(fMet) for chain initiation, so that fewer ribosomes were attached to mRNA chains. (1) In RC(str) strains recovering from amino acid starvation, there was a transient oversynthesis of mRNA, but the amounts returned to normal after about a 15-min period of recovery. RC(rel) strains did not show this effect; any extra mRNA accumulated during the previous starvation period was rapidly lost, but no oversynthesis occurred during the resumption of growth. (2) In trimethoprim-inhibited cultures supplemented with glycine and methionine, mRNA was produced at the same rate, relative to stable RNA species, as during normal growth. The evidence implied that decreased rates of ribosome attachment had no effect on the functional or chemical lifetime of the mRNA fraction. This suggests that mRNA stability does not depend on the frequency of translation by ribosomes. (3) Changes in the mRNA contents of trimethoprim-inhibited RC(str) and RC(rel) cultures were noted soon after supplementation with glycine and methionine. These closely followed those observed in cultures recovering from simple amino acid withdrawal.     

Enhanced level and metabolic regulation of methionyl-transfer ribonucleic acid synthetase in different strains of Escherichia coli K-12.

The methionyl-transfer ribonucleic acid (tRNA) synthetase of Escherichia coli K-12 eductants carrying P2-mediated deletions in the region of the structural gene of this enzyme was investigated. No structural alteration of this enzyme was observed in three eductants examined. These were isolated from strain AB311, which had a threefold higher level of methionyl-tRNA synthetase than most haploid strains examined. In two of the three eductants studied, the level of this enzyme was twofold higher than in their parental strain regardless of growth conditions used. In contrast, isoleucyl-, leucyl-, and valyl-tRNA synthetases had similar levels in all strains examined. Like valyl-tRNA synthetase, but to a lesser extent, methionyl-tRNA synthetase was subject to metabolic regulation. Coupling between the level of methionyl-tRNA synthetase and growth rate was observed even in strains that had an enhanced level of methionyl-tRNA synthetase. These results suggest that the formation of methionyl-tRNA synthetase remains subject to metabolic regulation even when the repression-like mechanism that controls the synthesis of this enzyme is altered. In addition, we report that in the merodiploid strain EM20031, which was haploid for the valyl-tRNA synthetase structural gene and diploid for the structural genes of methionyl-tRNA synthetase and D-serine deaminase, the levels of these latter two enzymes varied to a minor yet significant extent with the phosphate concentration of the culture medium; under the same conditions, the level of valyl-tRNA synthetase remained unchanged. Moreover, no variation of the levels of these three enzymes in response to phosphate was observed in the haploid strain HfrH. These results indicate that in the merodiploid strain EM20031, which carries the episome F32, the number of episomes per chromosome varies to some extent according to the phosphate concentration of the culture medium.     

Physiological analysis of mutants of Saccharomyces cerevisiae impaired in sulphate assimilation.

The assimilation of sulphate in Saccharomyces cerevisiae, comprising the reduction of sulphate to sulphide and the incorporation of the sulphur atom into a four-carbon chain, requires the integrity of 13 different genes. To date, the functions of nine of these genes are still not clearly established. A set of strains, each bearing a mutation in one MET gene, was studied. Phenotypic studies and enzyme determinations showed that the products of at least five genes are needed for the synthesis of an enzymically active sulphite reductase. These genes are MET1, MET5, MET8, MET10 and MET20. Wild-type strains of S. cerevisiae can use organic metabolites such as homocysteine, cysteine, methionine and S-adenosylmethionine as sulphur sources. They are also able to use inorganic sulphur sources such as sulphate, sulphite, sulphide or thiosulphate. Here we show that both of the two sulphur atoms of thiosulphate are used by S. cerevisiae. Thiosulphate is cleaved into sulphite and sulphide prior to utilization by the sulphate assimilation pathway, as the metabolism of one sulphur atom from thiosulphate requires the presence of an active sulphite reductase.