Identification of AAS genes and their regulatory role in general control of amino acid biosynthesis in yeast

A rapid method for determining tRNA charging levels in vivo: analysis of yeast mutants defective in the general control of amino acid biosynthesis

We describe a simple method to quantitate the intracellular levels of charged tRNA species representing all 20 amino acids. Small RNA species are isolated from yeast cells under conditions where amino acids remain bound to their cognate tRNAs. After chromatographic removal of free amino acids, the tRNAs are discharged, and the amounts of the released amino acids are then quantitated. This method was applied to yeast cells from a wild type strain and from three mutant strains that are defective both in the general control of amino acid biosynthesis and in protein synthesis. Two of these mutant strains, previously shown to be defective in the methionine or isoleucine tRNA synthetases, respectively contain undetectable amounts of charged methionine or isoleucine although their levels of the remaining 19 amino acids are similar to a wild type strain. In contrast, a gcd1 mutant strain has normal levels of all 20 amino-acyl tRNA species. Thus, gcd1 strains are defective in general control of amino acid biosynthesis for reasons other than artifactual starvation of an amino acid due to a failure in tRNA changing.

Negative regulatory gene for general control of amino acid biosynthesis in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, many amino acid biosynthetic pathways are coregulated by a complex general control system: starvation for a single amino acid results in the derepression of amino acid biosynthetic genes in multiple pathways. Derepression of these genes is mediated by positive (GCN) and negative (GCD) regulatory genes. In this paper we describe the isolation and characterization of a previously unreported negative regulatory gene, GCD3. A gcd3 mutation is recessive to wild type, confers resistance to multiple amino acid analogs, and results in overproduction and partially constitutive elevation of mRNA levels for amino acid biosynthetic genes. Furthermore, a gcd3 mutation can overcome the derepression-deficient phenotype of mutations in the positive regulatory GCN1, GCN2, and GCN3 genes. However, the gcd3 mutation cannot overcome the derepression-deficient phenotype of a gcn4 mutation, suggesting that GCD3 acts as a negative regulator of the important GCN4 gene. Northern blot analysis confirmed this conclusion, in that the steady-state levels of GCN4 mRNA are greatly increased in a gcd3 mutant. Thus, the negative regulatory gene GCD3 plays a central role in derepression of amino acid biosynthetic genes.

Translational control of ADP-ribosylation in eucaryotic cells

Starvation of the mouse hepatoma cell line Hepa for an essential amino acid (Trp, His, Leu, Ile or Phe) stimulated the incorporation of [3H]adenosine as ADP-ribose monomer into an 80,000-Mr protein, P80. Two-dimensional electrophoresis of Hepa proteins showed that P80 was the only protein labeled under starvation conditions. Time course experiments showed that the ADP-ribosylation of P80 was a consequence rather than the cause of reduced translational activity. Cycloheximide treatment and incubation at reduced temperatures also reduced the rate of protein synthesis and stimulated the ADP-ribosylation of P80. Starvation-dependent ADP-ribosylation of P80 was shown to occur in three other cell lines (Chang, Neuro-2a, and chick comb fibroblasts).

GCN4 protein, a positive transcription factor in yeast, binds general control promoters at all 5' TGACTC 3' sequences

The GCN4 gene is required for the general amino acid control derepression response in yeast. GCN4 protein protects a repeated sequence motif in the 5'-untranslated region of HIS4, HIS3, ILV1, and ILV2 genes subject to general control. At low concentrations of GCN4, only certain repeats in these genes are bound. The repeats differ slightly from the 5' TGACTC 3' consensus core sequence, and the selective binding of some sites at low GCN4 concentrations is related to the relative affinity of these sites to GCN4. Using purified GCN4 protein obtained from an overproducing strain of Escherichia coli, we were able to obtain complete protection of all of the repeat elements in these four genes at high GCN4 concentrations. Analysis of the relative binding constant to the 15 repeated sequences protected by GCN4 shows that the optimal binding site for GCN4 is 5' RRTGACTC 3' followed by a short stretch of thymidines. Another protein, present mostly in yeast nuclear extracts, binds to the HIS4 promoter at a site overlapping one of the GCN4 binding sites. This protein is displaced from its binding site at high GCN4 concentrations.

Saturation mutagenesis of the yeast his3 regulatory site: requirements for transcriptional induction and for binding by GCN4 activator protein

Expression of the yeast his3 and other amino acid biosynthetic genes is induced during conditions of amino acid starvation. The coordination of this response is mediated by a positive regulatory protein called GCN4, which binds specifically to regulatory sites upstream of all coregulated genes and stimulates their transcription. The nucleotide sequence requirements of the his3 regulatory site were determined by analysis of numerous point mutations obtained by a novel method of cloning oligonucleotides. Almost all single base pair mutations within the nine base pair sequence ATGACTCTT significantly reduce his3 induction in vivo and GCN4 binding in vitro, whereas changes outside this region have minimal effects. One mutation, which generates a sequence that most closely resembles the consensus for 15 coregulated genes, increases both the level of induction and the affinity for GCN4 protein. The palindromic nature of the optimal sequence, ATGACTCAT, suggest that GCN4 protein binds as a dimer to adjacent half-sites that possibly overlap.

General amino acid control and specific arginine repression in Saccharomyces cerevisiae: physical study of the bifunctional regulatory region of the ARG3 gene

To characterize further the regulatory mechanism modulating the expression of the Saccharomyces cerevisiae ARG3 gene, i.e., the specific repression by arginine and the general amino acid control, we analyzed by deletion the region upstream of that gene, determined the nucleotide sequence of operator-constitutive-like mutations affecting the specific regulation, and examined the behavior of an ARG3-galK fusion engineered at the initiating codon of ARG3. Similarly to what was observed in previous studies on the HIS3 and HIS4 genes, our data show that the general regulation acts as a positive control and that a sequence containing the nucleotide TGACTC, between positions -364 and -282 upstream of the transcription start, functions as a regulatory target site. This sequence contains the most proximal of the two TGACTC boxes identified in front of ARG3. While the general control appears to modulate transcription efficiency, the specific repression by arginine displays a posttranscriptional component (F. Messenguy and E. Dubois, Mol. Gen. Genet. 189:148-156, 1983). Our deletion and gene fusion analyses confirm that the specific and general controls operate independently of each other and assign the site responsible for arginine-specific repression to between positions -170 and +22. In keeping with this assignment, the two operator-constitutive-like mutations were localized at positions -80 and -46, respectively, and thus in a region which is not transcribed. We discuss a hypothesis accounting for the involvement of untranscribed DNA in a posttranscriptional control.

A hierarchy of trans-acting factors modulates translation of an activator of amino acid biosynthetic genes in Saccharomyces cerevisiae

The GCN4 gene encodes a positive effector of amino acid biosynthetic genes in Saccharomyces cerevisiae. Genetic analysis has suggested that GCN4 is regulated by a hierarchy of interacting positive and negative effectors in response to amino acid starvation. Results presented here for a GCN4-lacZ gene fusion support this regulatory model and suggest that the regulators of GCN4 exert their effects primarily at the level of translation of GCN4 mRNA. Both the GCN2 and GCN3 products appear to stimulate translation of GCN4 mRNA in response to amino acid starvation, because a recessive mutation in either gene blocked derepression of GCN4-lacZ fusion enzyme levels but did not reduce the fusion transcript level relative to that in wild-type cells grown in the same conditions. The GCD1 product appears to inhibit translation of GCN4 mRNA because under certain growth conditions, the gcd1-101 mutation led to derepression of the GCN4-lacZ fusion enzyme level in the absence of any increase in the fusion transcript level. In addition, the gcd1-101 mutation suppressed the low translational efficiency of GCN4-lacZ mRNA observed in gcn2- and gcn3- cells. A deletion of four small open reading frames in the 5' leader of GCN4-lacZ mRNA mimicked the effect of a gcd1 mutation and derepressed translation of the fusion transcript in the absence of either starvation conditions or the GCN2 and GCN3 products. By contrast, in a gcd1- strain, the deletion resulted in little additional increase in the translational efficiency of the fusion transcript. These results suggest that GCD1 mediates the translational repression normally exerted by the GCN4 leader sequences and that GCN2 and GCN3 antagonize these negative elements in response to amino acid starvation. The effects of the trans-acting mutations on the translation of GCN4-lacZ mRNA remained intact even when transcription of the fusion gene was placed under the control of the S. cerevisiae GAL1 transcriptional control element.

Negative regulatory gene for general control of amino acid biosynthesis in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, many amino acid biosynthetic pathways are coregulated by a complex general control system: starvation for a single amino acid results in the derepression of amino acid biosynthetic genes in multiple pathways. Derepression of these genes is mediated by positive (GCN) and negative (GCD) regulatory genes. In this paper we describe the isolation and characterization of a previously unreported negative regulatory gene, GCD3. A gcd3 mutation is recessive to wild type, confers resistance to multiple amino acid analogs, and results in overproduction and partially constitutive elevation of mRNA levels for amino acid biosynthetic genes. Furthermore, a gcd3 mutation can overcome the derepression-deficient phenotype of mutations in the positive regulatory GCN1, GCN2, and GCN3 genes. However, the gcd3 mutation cannot overcome the derepression-deficient phenotype of a gcn4 mutation, suggesting that GCD3 acts as a negative regulator of the important GCN4 gene. Northern blot analysis confirmed this conclusion, in that the steady-state levels of GCN4 mRNA are greatly increased in a gcd3 mutant. Thus, the negative regulatory gene GCD3 plays a central role in derepression of amino acid biosynthetic genes.

Genetic manipulation of Saccharomyces cerevisiae by use of the LYS2 gene

The structural gene for alpha-aminoadipate reductase (LYS2) was isolated from a Saccharomyces cerevisiae genomic DNA library by complementation of a lys2 mutant. Both genetic and biochemical criteria confirmed that the DNA obtained corresponds to the LYS2 locus on chromosome II. Subcloning and deletion analysis showed that a functional LYS2 gene is contained within a 4.6-kilobase (kb) EcoRI-HindIII fragment of the original insert, and the slightly larger EcoRI-ClaI segment (4.8 kb) was used to construct a series of cloning vehicles, including integrating, episomal, replicative, and centromeric vectors. The cloned DNA was also used to generate a genomic deletion that lacks all LYS2 coding sequences on chromosome II. The level of the LYS2 transcript (4.2 kb) was 10-fold higher in cells grown on minimal medium than in cells grown on complete medium and was not repressed by the presence of lysine alone. Gene disruption, gene replacement, and promoter analysis of the major alpha-factor structural gene (MF alpha 1) were performed to illustrate the utility of the LYS2 gene for the genetic manipulation of yeasts. Because all fungi synthesize lysine via the alpha-aminoadipate pathway, the techniques developed here for using the S. cerevisiae LYS2 gene should be directly applicable to other fungal systems.

Regulation of amino acid synthetic enzymes in Neurospora crassa in the presence of high concentrations of amino acids

Ornithine carbamoyl transferase and leucine aminotransferase of Neurospora crassa represent two of many amino acid synthetic enzymes which are regulated through cross-pathway (or general) amino acid control. In the wild-type strain both enzymes display derepressed activities if the growth medium is supplemented with high (mM range) concentrations of L-amino acids derived from branched pathways, i.e. the aspartate, pyruvate, glycerophosphate and aromatic families of amino acids. A cpc-1 mutant strain, impaired in cross-pathway regulation i.e. lacking the ability to derepress, shows delayed growth under such conditions. In the presence of glycine, homoserine and isoleucine various cpc-1 isolates do not grow at all. Derepression of the wild-type enzymes and the retarded growth of the mutant strain can be reversed if certain amino acids are present in the medium in addition to the inhibitory amino acids.

New positive and negative regulators for general control of amino acid biosynthesis in Saccharomyces cerevisiae

The biosynthesis of most amino acids in Saccharomyces cerevisiae is coregulated. Starvation for a single amino acid results in the derepression of amino acid biosynthetic enzymes in many unrelated pathways. This phenomenon, known as general control, is mediated by both positive (GCN) and negative (GCD) regulatory genes. In this paper we describe the identification and characterization of several new regulatory genes for this system, GCN6, GCN7, GCN8, GCN9, and GCD5. A mutation in the negative regulator GCD5 was isolated on the basis of its suppression of a gcn2 mutation. The effect of gcd5 is a posttranscriptional increase in histidine biosynthetic enzyme activity. Suppressors of gcd5 which are deficient in derepression were in turn isolated. Eight such mutations, defining four new positive regulatory genes (GCN6 through GCN9), were obtained. These mutations are recessive, confer sensitivity to multiple amino acid analogs, and result in decreased mRNA levels for genes under general control. The GCN6 and GCN7 gene products were shown to be positive regulators for transcription of the GCN4 gene, the most direct-acting positive regulator thus far identified. The interaction of GCN6 and GCN7 with GCN4 is fundamentally different from that of previously isolated GCN genes. It should also be noted that these gcn selections gave a completely different nonoverlapping set of mutations from earlier selections which relied on analog sensitivity. Thus, we may have identified a new class of GCN genes which are functionally distinct from GCN1 through GCN5.

Identification and characterization of four new GCD genes in Saccharomyces cerevisiae

Mutant strains, resistant against the amino acid analogues 5-methyltryptophan, 5-fluorotryptophan and canavanine were isolated, starting with a trp2 leaky auxotrophic strain. Of 10 such strains, only four turned out to be of the "general control derepressed" (gcd) mutant type. Three other isolates were shown to be defective in the general amino acid permease system, while the remaining three strains displayed low spore viability and were not further investigated. Complementation tests amongst the four new gcd-mutant strains, including strain RH558 gcd2-1 isolated earlier, yielded five complementation groups: GCD2, GCD3, GCD4, GCD5, and GCD6. All mutant strains showed a dual phenotype, which was not separable by wild type backcrosses: "constitutive derepression" and "slow growth". Epistasis of all gcd mutations over gcn1-1, gcn2-1 and gcn3-1 was found with respect to both phenotypes, except for gcd5-1, which was lethal in these combinations. On the other hand gcn4-101 was found to be epistatic over all gcd mutations, but only with respect to the "constitutive derepression" phenotype, and not to "slow growth"; again the combination with gcd5-1 was lethal. Mutation gcd2-1 was mapped on chromosome VII, 50 cM from leu1 and 22 cM from ade6. A new model is discussed, in which GCD-genes are involved in the amino acid uptake into the vacuoles.

Cloning of the arg-12 gene of Neurospora crassa and regulation of its transcript via cross-pathway amino acid control

The arg-12 locus of Neurospora crassa encodes ornithine carbamoyl transferase, which is one of many amino acid synthetic enzymes whose activity is regulated through cross-pathway (or general) amino acid control. We report here the use of probes derived from the functionally equivalent arg-B gene of Aspergillus nidulans to identify and clone a 10 kb Neurospora DNA fragment carrying the arg-12 gene. Short Neurospora DNA probes derived from this fragment were used to identify a 1.5 kb polyA+ transcript of the arg-12 region. Arg-12 transcript levels increased approximately 20 fold under conditions of arginine or histidine limitation in strains having normal cross-pathway regulation (cpc-1+) but showed no such response in a cpc-1 mutant strain impaired in this regulation. Time course studies in cpc-1+ strains revealed a rapid response (within 10 m) of arg-12 transcript levels following inhibition of histidine synthesis by 3 amino 1,2,4 triazole, but a delayed response following arginine deprivation of an arginine requiring strain. In contrast to the behaviour of arg-12 mRNA, the level of the Neurospora am gene transcript (specifying NADP dependent glutamate dehydrogenase) was unaffected either by amino acid limitation or by the cpc-1 mutation. A possible role for the cpc-1+ product as a positive regulator of transcription of genes subject to cross-pathway control is discussed.

A new negative control gene for amino acid biosynthesis in Saccharomyces cerevisiae

Enzyme levels in multiple amino acid biosynthetic pathways in yeast are coregulated. This control is effected largely at the transcriptional level by a number of regulatory genes. We report the isolation and characterization of a new negative regulatory gene, GCD4, for this general control system. GCD4 mutations are recessive and define a single Medelian gene on chromosome III. A gcd4 mutation results in resistance to different amino acid analogs and elevated, but fully inducible, mRNA levels of genes under general control. Epistasis analysis indicates that GCD4 acts more directly than the positive regulators GCN1, GCN2, GCN3 and GCN5, but less directly than GCN4, on the transcription of the amino acid biosynthetic genes. These data imply that GCD4 is a negative regulator of the positive effector, GCN4. Although GCD4 occupies the same position relative to the GCN genes as other GCD genes, it produces a unique phenotype. These results illustrate the diversity of function of negative regulators in general control.

The general control of amino acid biosynthetic genes in the yeast Saccharomyces cerevisiae

Enzymes in diverse amino acid biosynthetic pathways in Saccharomyces cerevisiae are subject to a general amino acid control in which starvation for any amino acid leads to increased levels of the mRNAs encoding these enzymes. The short nucleotide sequence TGACTC, found nontandemly repeated upstream from the coregulated structural genes, serves as a cis-acting site for positive regulation of transcription. Multiple trans-acting repressors and activators have been identified. Most of these factors act indirectly by regulating the level of an activator encoded by the GCN4 gene. This regulation occurs at the level of GCN4 translation and is mediated by sequences in the long 5' leader of GCN4 mRNA. The GCN4 protein is the most likely candidate for the transcriptional activator that interacts with the TGACTC sequences at the structural genes.

General amino acid control and specific arginine repression in Saccharomyces cerevisiae: physical study of the bifunctional regulatory region of the ARG3 gene

To characterize further the regulatory mechanism modulating the expression of the Saccharomyces cerevisiae ARG3 gene, i.e., the specific repression by arginine and the general amino acid control, we analyzed by deletion the region upstream of that gene, determined the nucleotide sequence of operator-constitutive-like mutations affecting the specific regulation, and examined the behavior of an ARG3-galK fusion engineered at the initiating codon of ARG3. Similarly to what was observed in previous studies on the HIS3 and HIS4 genes, our data show that the general regulation acts as a positive control and that a sequence containing the nucleotide TGACTC, between positions -364 and -282 upstream of the transcription start, functions as a regulatory target site. This sequence contains the most proximal of the two TGACTC boxes identified in front of ARG3. While the general control appears to modulate transcription efficiency, the specific repression by arginine displays a posttranscriptional component (F. Messenguy and E. Dubois, Mol. Gen. Genet. 189:148-156, 1983). Our deletion and gene fusion analyses confirm that the specific and general controls operate independently of each other and assign the site responsible for arginine-specific repression to between positions -170 and +22. In keeping with this assignment, the two operator-constitutive-like mutations were localized at positions -80 and -46, respectively, and thus in a region which is not transcribed. We discuss a hypothesis accounting for the involvement of untranscribed DNA in a posttranscriptional control.

A hierarchy of trans-acting factors modulates translation of an activator of amino acid biosynthetic genes in Saccharomyces cerevisiae

The GCN4 gene encodes a positive effector of amino acid biosynthetic genes in Saccharomyces cerevisiae. Genetic analysis has suggested that GCN4 is regulated by a hierarchy of interacting positive and negative effectors in response to amino acid starvation. Results presented here for a GCN4-lacZ gene fusion support this regulatory model and suggest that the regulators of GCN4 exert their effects primarily at the level of translation of GCN4 mRNA. Both the GCN2 and GCN3 products appear to stimulate translation of GCN4 mRNA in response to amino acid starvation, because a recessive mutation in either gene blocked derepression of GCN4-lacZ fusion enzyme levels but did not reduce the fusion transcript level relative to that in wild-type cells grown in the same conditions. The GCD1 product appears to inhibit translation of GCN4 mRNA because under certain growth conditions, the gcd1-101 mutation led to derepression of the GCN4-lacZ fusion enzyme level in the absence of any increase in the fusion transcript level. In addition, the gcd1-101 mutation suppressed the low translational efficiency of GCN4-lacZ mRNA observed in gcn2- and gcn3- cells. A deletion of four small open reading frames in the 5' leader of GCN4-lacZ mRNA mimicked the effect of a gcd1 mutation and derepressed translation of the fusion transcript in the absence of either starvation conditions or the GCN2 and GCN3 products. By contrast, in a gcd1- strain, the deletion resulted in little additional increase in the translational efficiency of the fusion transcript. These results suggest that GCD1 mediates the translational repression normally exerted by the GCN4 leader sequences and that GCN2 and GCN3 antagonize these negative elements in response to amino acid starvation. The effects of the trans-acting mutations on the translation of GCN4-lacZ mRNA remained intact even when transcription of the fusion gene was placed under the control of the S. cerevisiae GAL1 transcriptional control element.

Changes in gene expression elicited by amino acid limitation in Neurospora crassa strains having normal or mutant cross-pathway amino acid control

The effects of amino acid limitation on gene expression have been investigated in Neurospora crassa strains carrying normal (cpc-1+) or mutant (cpc-1) alleles at a locus implicated in cross-pathway amino acid control. Electrophoresis and fluorography were used to reveal the patterns of label incorporation into polypeptides in vivo, or after in vitro translation of extracted mRNAs. In a cpc-1+ strain at least 20% of detectable in vitro translation products showed relative increases in incorporation when RNA was obtained from mycelium grown under conditions of arginine limitation, by comparison with conditions of arginine sufficiency. A cpc-1 mutation, which impairs derepression of a variety of amino acid synthetic enzymes following amino acid limitation, had little detectable effect on in vivo polypeptide synthesis during amino acid sufficient growth or following pyrimidine limitation. However the mutation substantially altered the response to arginine or histidine limitation. The majority of in vitro translation products that showed increased expression in arginine limited cpc-1+ failed to increase in cpc-1 strains, but arginine limitation of cpc-1 also resulted in increases that did not occur in cpc-1+ strains. This may reflect both direct and indirect consequences of the impairment of cross-pathway control.

Positive regulatory interactions of the HIS4 gene of Saccharomyces cerevisiae

The role of cis- and trans-acting elements in the expression of HIS4 has been examined by using HIS4-lacZ fusions in which lacZ expression is dependent upon the HIS4 5' noncoding region. The cis-acting sequences involved in regulation were defined by studying the effects of the wild-type and various deletions and their revertants on regulation via the general control of amino acid biosynthesis. The role of trans-acting genes was analyzed by studying the regulation of the HIS4-lacZ fusions in strains carrying mutations in the GCN (AAS) or GCD (TRA) genes and in strains carrying the GCN genes on high-copy-number plasmids. These studies have led to the following conclusions. (i) HIS4 is positively regulated by the general control. (ii) At least one copy of the 5'TGACTC3' repeat at -136 is required in cis for this regulation. (iii) Both the GCN4 gene and at least one copy of the repeated sequence are required for expression at the repressed level. (iv) The open reading frames in the 5' noncoding region are not required in either cis or trans for the regulation of HIS4.

Oxygen regulation of anaerobic and aerobic genes mediated by a common factor in yeast

The expression of a number of yeast genes is regulated by oxygen levels. While many of these are known to be induced in the presence of oxygen, we have described a gene, ANB1, that responds in the opposite fashion, being expressed only under anaerobic conditions. To identify genes involved in regulation of ANB1 and other oxygen-regulated genes, we selected mutations causing constitutive expression of ANB1, using a fusion of the ANB1 modulator segment to the CYC1 gene. A number of trans-acting mutations affecting a gene designated ROX1 caused constitutive expression of both the fused and wild-type genes, indicating that the ROX1 gene product operates through the ANB1 modulator sequence at the level of transcription. The mutant alleles of ROX1 fall into two phenotypic classes. The rox1-a class is semi-dominant, and the rox1-b class is recessive. One mutant, rox1-a1, is pleiotropic and causes constitutive expression of three oxygen-induced genes--CYC1, SOD (superoxide dismutase), and tr-1 (an oxygen-induced gene with homology to ANB1)--as well as constitutive expression of the oxygen-repressed ANB1 gene. Alleles of the rox1-b class cause constitutive expression of ANB1 but do not affect expression of the oxygen-induced genes tested. The pleiotropy of the rox1-a1 mutant indicates that the ROX1 gene product is involved in coordinate expression of both oxygen-induced and oxygen-repressed genes.

Evidence for translational regulation of the activator of general amino acid control in yeast

The GCN4 gene encodes a positive regulator of unlinked amino acid biosynthetic genes in yeast. I present evidence that the GCN4 gene is itself regulated by amino acid availability and that the regulation occurs at the translational level. A GCN4-lacZ fusion was used as a measure of the expression of GCN4 gene product. Starvation for histidine leads to derepression of the fusion enzyme in the wild type but not in a gcn2- strain. The gcn2- mutation does not reduce fusion transcript levels relative to wild type, suggesting that the product of GCN2 functions as an activator of GCN4 translation. The GCN4 transcript has a 5' leader that is approximately equal to 600 nucleotides long and contains four small open reading frames. A deletion of the small open reading frames results in constitutive derepression of fusion enzyme levels as the result of an approximately equal to 10-fold increase in the efficiency of translation of the fusion transcript. The deletion suppresses the requirement for GCN2 function. These results suggest that the GCN4 5' leader acts in cis to repress GCN4 translation and that GCN4 translation increases in response to amino acid starvation as the result of GCN2 antagonism of the repressing sequences in the GCN4 5' leader.

5' untranslated sequences are required for the translational control of a yeast regulatory gene

In yeast, many genes encoding amino acid biosynthetic enzymes are subject to a common regulatory system called the general control of amino acid biosynthesis. The product of the regulatory gene GCN4 is required for an increase in transcription of general control-regulated genes when yeast are grown under amino acid-starvation conditions. In this report, we show that the expression of the GCN4 gene is regulated at the translational level: the efficiency of translation of the GCN4 mRNA is dramatically increased during growth under amino acid-starvation conditions. The complete nucleotide sequence of the GCN4 gene, presented here, reveals the existence of an unusually long 5' untranslated region in the corresponding mRNA. In vivo analysis of the effects of a deletion in this 5' leader has enabled us to define a region required for the translational regulation of the GCN4 mRNA.

Positive regulatory interactions of the HIS4 gene of Saccharomyces cerevisiae

The role of cis- and trans-acting elements in the expression of HIS4 has been examined by using HIS4-lacZ fusions in which lacZ expression is dependent upon the HIS4 5' noncoding region. The cis-acting sequences involved in regulation were defined by studying the effects of the wild-type and various deletions and their revertants on regulation via the general control of amino acid biosynthesis. The role of trans-acting genes was analyzed by studying the regulation of the HIS4-lacZ fusions in strains carrying mutations in the GCN (AAS) or GCD (TRA) genes and in strains carrying the GCN genes on high-copy-number plasmids. These studies have led to the following conclusions. (i) HIS4 is positively regulated by the general control. (ii) At least one copy of the 5'TGACTC3' repeat at -136 is required in cis for this regulation. (iii) Both the GCN4 gene and at least one copy of the repeated sequence are required for expression at the repressed level. (iv) The open reading frames in the 5' noncoding region are not required in either cis or trans for the regulation of HIS4.

Temporal analysis of general control of amino acid biosynthesis in Saccharomyces cerevisiae: role of positive regulatory genes in initiation and maintenance of mRNA derepression

In Saccharomyces cerevisiae, starvation for a single amino acid results in the derepression of enzyme activities in multiple amino acid biosynthetic pathways. Derepression is a consequence of increased transcription of the genes encoding these enzymes. Analysis of the kinetics of mRNA elevation established that derepression occurs within 5 min of a shift of the culture from rich medium to starvation medium. Any starvation condition was sufficient to trigger an initial high mRNA elevation; however, it was the severity of starvation which determined the steady-state mRNA levels that were subsequently established. The products of the positive regulatory genes AAS101, AAS103, and AAS2 were shown to be required in the initiation phase of this response, whereas the AAS102 gene product was required to maintain the new elevated steady-state mRNA levels. The AAS101 and AAS102 genes were cloned. Consistent with their respective roles in initiation and maintenance of derepression. AAS101 mRNA was found to be expressed at high levels in both rich and starvation media, whereas AAS102 mRNA was derepressed only under starvation conditions. The derepression of AAS102 mRNA is dependent on the AAS101 gene product.

Temporal analysis of general control of amino acid biosynthesis in Saccharomyces cerevisiae: role of positive regulatory genes in initiation and maintenance of mRNA derepression

In Saccharomyces cerevisiae, starvation for a single amino acid results in the derepression of enzyme activities in multiple amino acid biosynthetic pathways. Derepression is a consequence of increased transcription of the genes encoding these enzymes. Analysis of the kinetics of mRNA elevation established that derepression occurs within 5 min of a shift of the culture from rich medium to starvation medium. Any starvation condition was sufficient to trigger an initial high mRNA elevation; however, it was the severity of starvation which determined the steady-state mRNA levels that were subsequently established. The products of the positive regulatory genes AAS101, AAS103, and AAS2 were shown to be required in the initiation phase of this response, whereas the AAS102 gene product was required to maintain the new elevated steady-state mRNA levels. The AAS101 and AAS102 genes were cloned. Consistent with their respective roles in initiation and maintenance of derepression. AAS101 mRNA was found to be expressed at high levels in both rich and starvation media, whereas AAS102 mRNA was derepressed only under starvation conditions. The derepression of AAS102 mRNA is dependent on the AAS101 gene product.

Positive regulation in the general amino acid control of Saccharomyces cerevisiae

Starvation of yeast for a single amino acid leads to derepression of enzymes in many different amino acid biosynthetic pathways. This general control is regulated by several transacting genes. Mutations in the TRA3 gene result in constitutive derepression, whereas mutations in AAS genes lead to the inability to derepress. We have isolated aas mutations as suppressors of the tra3-1 mutation. Some of these suppressors are alleles of AAS2 and others define a heretofore unidentified gene, AAS3. We have studied the regulatory behavior of strains containing both aas and tra3 mutations and strains containing the cloned AAS genes in high copy number. Either aas1- or aas2- in combination with tra3- has the Tra- phenotype, whereas aas3- in combination with tra3- has the Aas- phenotype. These interactions suggest that the AAS1 and AAS2 products act indirectly to bring about derepression by disabling the repressive effect of TRA3, whereas the AAS3 product functions more directly and is required even in the absence of the TRA3 function. When present in high copy number, the AAS3 gene complements mutations in AAS1 and AAS2, whereas AAS1 and AAS2 only complement their cognate mutations. Taken together these data suggest that AAS1 and AAS2 are negative regulators of TRA3, which in turn is a negative regulator of AAS3. AAS3 is a positive regulator, which is required for the general control response. This model of negative and positive interactions is formally identical to those proposed for the regulation of the galactose and phosphatase systems in yeast.