Integration of amino acid biosynthesis into the cell cycle of Saccharomyces cerevisiae

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.

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

In yeast, most amino acid biosynthetic pathways are coregulated: starvation for a single amino acid results in derepression of enzyme activities for many different biosynthetic pathways. This phenomenon is referred to as "general control of amino acid biosynthesis." In this paper we describe the isolation and characterization of 43 amino acid analog-sensitive (aas-) mutants that are perturbed in this general regulatory system. These 43 mutations define four unlinked complementation groups, AAS101, AAS102, AAS103, and AAS104, two of which identify previously unreported genes involved in general control. These aas mutants are unable to derepress a number of amino acid biosynthetic genes, resulting in increased sensitivity to amino acid analogs, reduced growth rates, and reduced enzyme activity levels under amino acid starvation conditions. Thus, the AAS+ gene products function as positive regulatory elements for this system. We show that the AAS genes mediate these effects by regulating the mRNA levels of genes under their control.

Expression in Saccharomyces cerevisiae of human interferon-alpha directed by the TRP1 5' region

The complete 5' flanking region of the yeast TRP1 gene encoding N-(5'-phosphoribosyl)- anthranilate isomerase, a nonabundant protein, has been cloned and the nucleotide sequence data has been extended from -102 to -440. The CT block--CAAG structure common to all efficiently expressed yeast genes is altered in the 5' region of TRP1 and a sequence postulated to be involved in general amino acid regulation is absent. There are two possible TATA boxes at -224 and -262. TRP1, in common with HIS3, HIS4 and TRP5 has a region of dyad symmetry upstream of the coding sequence which may play a role in initiation of transcription. The relative efficiency of gene expression directed by the complete 5' TRP1 region was assessed by comparison with that of PGK by inserting a cDNA for a human interferon-alpha downstream of their respective 5' regions. The respective interferon yields indicate that their in vivo expression capabilities are a function of their 5' regions.

Regulation of HIS4-lacZ fusions in Saccharomyces cerevisiae

The beginning of the Saccharomyces cerevisiae HIS4 gene has been fused to the structural gene for Escherichia coli beta-galactosidase. This construction, which contains HIS4 DNA from -732 to +30 relative to the translation initiation codon, has been integrated into the yeast genome at two chromosomal locations, HIS4 and URA3. At both locations, this 762-base-pair stretch of DNA is sufficient for initiating expression of beta-galactosidase activity in S. cerevisiae and confers upon this activity the regulatory response normally found for HIS4.

Initiation of meiosis in yeast mutants defective in adenylate cyclase and cyclic AMP-dependent protein kinase

Control of the initiation of meiosis was examined in diploids of yeast homozygous for two temperature-sensitive mutations, cyr1 and CYR3, which are defective in adenylate cyclase and cAMP-dependent protein kinase, respectively. The cyr1 and CYR3 mutations permitted the initiation of meiosis, but resulted in the frequent production of two-spored asci at the restrictive temperature. Unlike the wild-type diploid cells, the cyr1 and CYR3 homozygous diploid cells were capable of initiating meiosis even in nutrient growth media. This unique feature of the cyr1 and CYR3 mutants suggests that these mutations relate to the choice between mitotic and meiotic processes. In diploids homozygous for the bcy1 mutation that results in deficiency of the regulatory subunit of cAMP-dependent protein kinase and production of a high level of the catalytic subunit of this enzyme, no premeiotic DNA replication and commitment to intragenic recombination occurred, and no spores were formed. We conclude that the initiation of meiosis may be dependent upon the repression of cAMP production and the inactivation of cAMP-dependent protein kinase.

Participation of transcriptional and post-transcriptional regulatory mechanisms in the control of arginine metabolism in yeast

In yeast, as in other organisms, amino acid biosynthetic pathways share a common regulatory control. The manifestation of this control is that derepression of the enzymes belonging to several amino acid biosynthetic pathways follows amino acid starvation or tRNA discharging. The arginine anabolic and catabolic pathways are, in addition, regulated specifically by arginine in opposite ways by common regulators. We have measured the mRNA levels for four genes subject to the general amino acid control: HIS4, ARG3, ARG4 and CPAII and compared them to the corresponding enzyme levels. Similarly we have measured the mRNA levels for two genes subject to the arginine specific regulation: ARG3 and CAR1, the former gene belongs to the arginine anabolic pathway and the latter to the arginine catabolic one. HIS4, ARG4 and CPAII enzyme and messenger amounts are perfectly coordinated in all the conditions of general repression or derepression tested. However, arginine does not reduce the level of the ARG3 mRNA enough to explain the reduction of ornithine carbamoyltransferase activity nor does it increase the level of the CAR1 mRNA enough to explain the extent of induction of arginase. Coordination of enzyme and ARG3 mRNA is achieved only when the specific control is eliminated. The half-lives of the ARG3 and CAR1 messengers are enhanced in mutants leading to constitutive expression of ornithine carbamoyltransferase and arginase. These data suggest that the control that coordinates the synthesis of all the amino acids in the yeast cell operates at the level of transcription while the arginine specific regulatory mechanism seems to operate at a post-transcriptional level.

[General control of amino acid biosynthesis in mutants of Candida spec. EH 15/D]

The general control of amino acid biosynthesis was investigated in Candida spec. EH 15/D, using single and double mutant auxotrophic strains and prototrophic revertants starved for their required amino acids. These experiments show that starvation for lysine, histidine, arginine, leucine, threonine, proline, serine, methionine, homoserine, asparagine, glutamic acid or aspartic acid can result in derepression of enzymes. A correlation was found between the degree of derepression, growth of strains, and concentration of required amino acids. The amino acids pool pattern of mutants and revertants is different from that in the wild type strain.

A short nucleotide sequence required for regulation of HIS4 by the general control system of yeast

We have made deletions of the HIS4 5' noncoding region in vitro and inserted these deletions into the yeast genome by transformation. Deletions that extend from -588 to -235 have no detectable effects on either promoter or regulatory functions. Deletions that extend to -138 affect promoter function, but are still regulated by the general control of amino acid biosynthesis. A deletion that extends to -136 cannot derepress HIS4 mRNA in response to the general control. This deletion removes all copies of the sequence 5'-TGACTC-3', which appears at positions -194, -182 and -138 in strains without the deletion. The importance of at least one copy of this repeat for regulation of HIS4 is shown by the reappearance of this sequence in revertants of the -136 deletion that have regained the regulatory response. The fact that deletion of this sequence leads to the inability to derepress suggests that HIS4 is under positive control.

[Gene-enzyme relationships of the arom aggregate of Schizosaccharomyces pombe]

The gene-enzyme relationships of the arom multienzyme complex of Schizosaccharomyces pombe that catalyzes steps two through six in the prechorismate polyaromatic amino acid biosynthetic pathway have been studied. The various mutants were subjected to biochemical analysis by direct enzymic assays. These studies have established that aro-3A, aro-3B, aro-3C, aro-3D, and aro-3E mutants lack, respectively, the enzymic activities 5-dehydroquinate synthase, 5-dehydroquinase, shekimate kinase, 3-enolpyruvylshikimate 5-phosphate synthase, and shikimate: NADP oxidoreductase. In S. pombe lack enzymic activities for the inducible quinate catabolic pathway. The functional significance of the arom aggregate is discussed.

Nucleotide sequence of yeast LEU2 shows 5'-noncoding region has sequences cognate to leucine

The LEU2 structural gene and its regulatory sequences were isolated on a 2200 bp Xho I-Sal I fragment. Sequencing of the 5'-noncoding region showed that at -151 there is an open reading frame of 23 codons of which six are for leucine. The leucine codon usage in this reading frame follows exactly that of other yeast genes. At the carboxy-terminal end and immediately after the peptide reading frame, a 14 bp hairpin (followed by a T-rich segment) can form in the putative mRNA; this arrangement closely resembles an RNA polymerase terminator. These and other features suggest a model for regulation. Preceding this is a gene (which starts at -463) for tRNALeu3, the major tRNALeu isoacceptor. RNA polymerase III transcription start and termination signals flank 5' and 3' ends, respectively, of the structural gene. The features noted above are in the same DNA strand that codes for the LEU2 gene product.

Regulation of HIS4-lacZ fusions in Saccharomyces cerevisiae

The beginning of the Saccharomyces cerevisiae HIS4 gene has been fused to the structural gene for Escherichia coli beta-galactosidase. This construction, which contains HIS4 DNA from -732 to +30 relative to the translation initiation codon, has been integrated into the yeast genome at two chromosomal locations, HIS4 and URA3. At both locations, this 762-base-pair stretch of DNA is sufficient for initiating expression of beta-galactosidase activity in S. cerevisiae and confers upon this activity the regulatory response normally found for HIS4.

sigma, a repetitive element found adjacent to tRNA genes of yeast

sigma is a DNA element of about 340 base pairs (bp) that is repeated many times in the yeast genome. The element has 8-bp inverted repeats at its ends and is flanked by 5-bp direct repeats. The 5-bp repeats are different for each sigma and have no homology with the ends of the sigma sequence. sigma is located 16 or 18 bp from the 5' end of several tRNA genes. Southern analysis of different yeast strains shows that the pattern of hybridization is different even for closely related strains.

Evidence that alpha-isopropylmalate synthase of Saccharomyces cerevisiae is under the "general" control of amino acid biosynthesis

The specific activity and the immunoreactive amount of alpha-isopropylmalate synthase were more than three times above wild-type values in a Saccharomyces cerevisiae mutant (cdr1) with constitutively derepressed levels of enzymes known to be under the "general" control of amino acid biosynthesis. The specific activity was also higher in lysine- and arginine-leaky strains when these were grown under limiting conditions, and in wild-type cells grown in the presence of 5-methyltryptophan. A low specific activity was found in a mutant (ndr1) unable to derepress enzymes of the general control system. Neither isopropylmalate isomerase nor beta-isopropylmalate dehydrogenase responded to general control signals.

The nucleotide sequence of the HIS4 region of yeast

We have determined the nucleotide sequence of the yeast HIS4 gene and its 5' and 3' flanking sequences. The protein chain has a calculated Mr-value of 87 935. Th 5' end of the HIS4 transcript maps at a position 63 bp upstream from the site of initiation of protein synthesis. The 3' end of the HIS4 transcript maps at a position approx. 118 bp after the UAG termination codon. There is no evidence for intervening sequences within the transcription unit. Functional sub-regions within the HIS4 coding frame have been identified by determining the sequence changes for various his4 mutations.

Mutants affecting amino acid cross-pathway control in Neurospora crassa

Arginine-requiring mutants ofNeurospora crassawere isolated using a strain partially impaired in an enzyme of the arginine pathway (bradytroph). Among these, five strains were found which carry mutations at a new locus,cpc-1+. The recessivecpc-1alleles interfere with the cross-pathway control of amino acid biosynthetic enzymes. The enzymes studied, three of arginine and one each of histidine and lysine biosynthesis, fail to derepress under conditions which normally result in elevation of enzyme concentration, namely arginine, histidine or tryptophan limitation. Enzymes not involved in amino acid biosynthesis are still able to derepress in the presence ofcpc-1. In wild-type backgound, i.e. with the bradytroph replaced,cpc-1strains lose the original arginine-requirement.cpc-1mutations confer sensitivity of growth to 3-amino-1,2,4-triazole.

Cloning arg3, the gene for ornithine carbamoyltransferase from Saccharomyces cerevisiae: expression in Escherichia coli requires secondary mutations; production of plasmid beta-lactamase in yeast

The yeast arg3 gene, coding for ornithine carbamoyltransferase (carbamoylphosphate:L-ornithine carbamoyltransferase, EC 2.1.3.3), has been cloned on a hybrid pBR322-2-micrometers plasmid. The cloned gene gives a normal regulatory response in yeast. It is not expressed at 35 degrees C when a mutation preventing mRNA export from the nucleus at this temperature is included in the genetic make-up of the carrier strain. In Escherichia coli, no functional expression can be observed from the native yeast arg3 gene. The study of a mutant plasmid (M1) producing low levels of yeast carbamoyltransferase in E. coli has permitted the localization and orientation of arg3 on the plasmid. The mutation involved is a deletion that alters the regulatory response of arg3 in yeast. The plasmid bla gene produces detectable amounts of beta-lactamase (penicillin amido-beta-lactamhydrolase, EC 3.5.2.6) in yeast: the data provide an estimate of the beta-lactamase activity associated with one exemplar of the plasmid expressing arg3 (0.6 units).

Biological role of the general control of amino acid biosynthesis in Saccharomyces cerevisiae

The biological role of the "general control of amino acid biosynthesis" has been investigated by analyzing growth and enzyme levels in wild-type, bradytrophic, and nonderepressing mutant strains of Saccharomyces cerevisiae. Amino acid limitation was achieved by using either bradytrophic mutations or external amino acid imbalance. In the wild-type strain noncoordinate derepression of enzymes subject to the general control has been found. Derepressing factors were in the order of 2 to 4 in bradytrophic mutant strains grown under limiting conditions and only in the order of 1.5 to 2 under the influence of external amino acid imbalance. Nonderepressing mutations led to slower growth rates under conditions of amino acid limitation, and no derepression of enzymes under the general control was observed. The amino acid pools were found to be very similar in the wild type and in nonderepressing mutant strains under all conditions tested. Our results indicate that the general control affects all branched amino acid biosynthetic pathways, namely, those of the aromatic amino acids and the aspartate family, the pathways for the basic amino acids lysine, histidine, and arginine, and also the pathways of serine and valine biosyntheses.

Deletion mapping a eukaryotic promoter

The phenotypes of 24 mutants that successively delete DNA sequences adjacent to the 5' end of the Saccharomyces cerevisiae (yeast) his3 structural gene are described. Deletions retaining greater than 155 base pairs before the mRNA coding sequences are phenotypically indistinguishable from the wild-type his3 allele. Deletions having end points between 113 and 65 base pairs before the transcription initiation site express his3 at reduced levels. Mutations retaining less than 45 base pairs are indistinguishable from null alleles of the his3 locus. These results indicate (i) that a sequence(s) located 113--155 base pairs upstream from the transcribed region is necessary for wild-type expression and (ii) that the T-A-T-A box (a sequence in front of most eukaryotic genes) is not sufficient for wild-type promoter function. Thus, the yeast his3 promoter region appears large when compared with prokaryotic promoters, suggesting that it may be more complex than a simple site of interaction between RNA polymerase and DNA.

31P NMR studies of intracellular pH and phosphate metabolism during cell division cycle of Saccharomyces cerevisiae

We have analyzed changes in intracellular pH and phosphate metabolism during the cell cycle of Saccharomyces cerevisiae (NCYC 239) by using high-resolution 31P NMR spectroscopy. High-density yeast cultures (2 x 10(8) cells per ml) were arrested prior to "start" by sequential glucose deprivation, after which they synchronously replicated DNA and divided after a final glucose feeding. Oxygenation of arrested cultures in the absence of glucose led to increased levels of sugar phosphates and ATP and an increase in intracellular pH. However, these conditions did not initiate cell cycle progression, indicating that energization is not used as an intracellular signal for initiation of the cell division cycle and that the cells need exogenous carbon sources for growth. Glucose refeeding initiated an alkaline intracellular pH transient only in the synchronous cultures, showing that increased intracellular pH accompanies the traversal of start. Changes in phosphate flow and utilization also were observed in the synchronous cultures. In particular, there was increased consumption of external phosphate during DNA synthesis. When external phosphate levels were low, the cells consumed their internal polyphosphate stores. This shows that, under these conditions, polyphosphate acts as a phosphate supply.

[General control of amino acid biosynthesis in Hansenula henricii]

The general control of amino acid biosynthesis was investigated in Hansenula henricii. By limitation for single amino acids in wild type strain and mutants no derepression of enzymes was caused. In prototrophic revertants however, obtained from auxotrophic mutants (his, pdx) enzyme activities were 2 - 17 times higher than in the wild type. In these revertants enzymes of the biosynthetic pathways for tryptophan, phenylalanine, tyrosine, arginine, histidine, cysteine, methionine, asparagine, threonine, and isoleucine were derepressed. The amino acid pool pattern of the revertants if completely different from that in the wild type strain. A discussion of possible mechanisms of general control of amino acid biosynthesis in H. henricii is presented.

Recombination of dispersed repeated DNA sequences in yeast

Yeast transformation can be used to insert new sequence arrangements into a variety of chromosomal locations by homologous recombination. These newly inserted sequences can recombine with similar sequences located on other chromosomes. In these events, information is duplicated without being lost at the site from which it is derived. Similar mechanisms might be utilized by cells to provide new functions during development or differentiation.

Regulation of compartmentation of amino acid pools in Saccharomyces cerevisiae and its effects on metabolic control

Compartmentation of intracellular amino acid pools has been studied under various growth conditions in wild-type strains as well as in mutants. Aspartate, glutamate, leucine and isoleucine pools are present in high concentrations in the cytoplasm, while all the other amino acids are more vacuolar. The nature of the nitrogen source for growth, the effectiveness of nitrogen assimilation, the rate of protein synthesis and the presence of high internal basic amino acid pools are important factors in the repartition of amino acid pools between the cytoplasm and the vacuole.

Isolation and characterization of Neurospora crassa mutants impaired in feedback control of ornithine synthesis

Thirty-two independent mutants were isolated which overcame the proline requirement of pro-3 mutations in Neurospora crassa. The mutations were not revertants, appeared to be allelic, were closely linked or allelic to arg-6, and in strains unable to degrade ornithine no longer suppressed the proline requirement. The suppressor mutations did not alter the levels of biosynthetic or catabolic enzymes, yet allowed accumulation of ornithine. Suppressed strains unable to degrade arginine still produced ornithine (as detected by growth) in arginine-supplemented medium. The results suggest that the suppressor mutants were impaired in the feedback inhibition of ornithine synthesis by arginine. The activity of the appropriate biosynthetic enzyme was less sensitive to inhibition by arginine. The potential usefulness of such mutations is discussed.

Effect of carbon source on enzymes and metabolites of arginine metabolism in Neurospora

The levels of enzymes and metabolites of arginine metabolism were determined in exponential cultures of Neurospora crassa grown on various carbon sources. The carbon sources decreased in effectiveness (as determined by generation times) in the following order: sucrose, acetate, glycerol, and ethanol. The basal and induced levels of the catabolic enzymes, arginase (EC 3.5.3.1) and ornithine transaminase (EC 2.6.1.13), were lower in mycelia grown on poor carbon sources. Arginase was more sensitive to variations in carbon source than was ornithine transaminase. Induction of both enzymes was sensitive to nitrogen metabolite control, but this sensitivity was reduced in mycelia grown on glycerol or ethanol. The pools of arginine and ornithine were reduced in mycelia grown in unsupplemented medium containing poor carbon sources, but the biosynthetic enzyme ornithine transcarbamylase (EC 2.1.3.3) was not derepressed. The arginine pools were similar, regardless of carbon source, in mycelia grown in arginine-supplemented medium. The ornithine pool was reduced by growth on poor carbon sources. The rate of arginine degradation was proportional to the level of arginase in both sucrose- and glycerol-grown mycelia. The distribution of arginine between cytosol and vesicles was only slightly altered by growth on glycerol instead of sucrose. The slightly smaller cytosolic arginine concentration did not appear to be sufficient to account for the alterations in basal and induced enzyme levels. The results suggest a possible carbon metabolite effect on the expression or turnover of a variety of genes for enzymes of arginine metabolism in Neurospora.

Regulation of activity and synthesis of N-acetylglutamate synthase from Saccharomyces cerevisiae

Feedback inhibition of N-acetylgutamate synthase in a particulate fraction from Saccharomyces cerevisiae by L-arginine was synergistically enhanced by N-actylglutamate, whereas coenzyme A let to an additive enhancement of arginine inhibition. N-acetylglutamate synthase was not inhibited by polyamines, nor was the enzyme inactivated by incubation in the presence of coenzyme A and zinc ions. Evidence was obtained for the involvement of at least three different regulatory mechanisms in the expression of N-acetylglutamate synthase: arginine-specific repression, glucose repression and general amino acid control. The combined action of these control mechanisms led to a 90-fold variation in the specific activity of the enzyme.

General and lysin specific control of saccharopine dehydrogenase levels in the yeast Saccharomycopsis lipolytica

Lysine supplementation of the growth medium of a wild type strain of the yeast Saccharomycopsis lipolytica specifically results in saccharopine dehydrogenase repression. Starvation of the strain for histidine triggers a general depression of various histidine, leucine, arginine and lysine biosynthetic enzymes, including saccharopine dehydrogenase. These two types of control, specific and general, act independently on saccharopine dehydrogenase expression, since mutants which fail to respond to the specific control still are sensitive to the general one. These mutants were first selected as unable to catabolize lysine, suggesting that a link may exist between saccharopine dehydrogenase specific regulation and activity of the catabolic pathway.

Concerted repression of the synthesis of the arginine biosynthetic enzymes by aminoacids: a comparison between the regulatory mechanisms controlling aminoacid biosyntheses in bacteria and in yeast

It has been shown that in bacteria, besides specific regulatory mechanisms, the synthesis of aminoacid biosynthetic enzymes is also controlled by the endogenous aminoacid pool. The latter regulates the intracellular level of ppGpp, a positive effector of RNA messenger transcription. A similar regulatory control exists in yeast but does not appear to involve the same general effector. This was established by the observation that derepression of the enzymes belonging to several aminoacid biosynthetic pathways follows aminoacid starvation or tRNA discharging. We now report the repression of the arginine pathway by the total aminoacid pool. New mutations affecting the repressibility of the arginine enzymes as well as enzymes belonging to other aminoacid biosyntheses, when cells are grown in the presence of an excess of aminoacids, were identified.

Organization and expression of a two-gene cluster in the arginine biosynthesis of Saccharomyces cerevisiae

In Saccharomyces cerevisiae, argB and argC define two adjacent and complementing loci, with mutants defective in two consecutive steps of arginine biosynthesis: N-acetylglutamate kinase (AG-kinase) and N-acetylglutamyl-phosphate reductase (AGPreductase). These enzymic activities are readily separated by ammonium sulfate fractionation or Sephadex G-200 chromatography. This suggests that each activity is carried in vivo by a different protein. The synthesis of the two enzymes is coordinately regulated, with an 85-fold difference in specific activities between fully repressed and fully derepressed cells. Missence mutations of the argB locus are defective in AGkinase only. Nonsense mutations in the argB locus are defective in both activities. Missense and nonsense mutations in the argC locus are defective in AGPreductase, with a few alleles also showing a reduced level of AGkinase. These data are best explained by assuming that argB and argC are two genes transcribed as a single messenger from argB to argC. This messenger produces in vivo two distinct proteins corresponding to the argB and argC gene products, either because translation can be initiated at the beginning of both genes, or because a large polypeptide is specifically cut in vivo to yield the gene products of argB and argC.

Effect of carbon source and the role of cyclic adenosine 3',5'-monophosphate on the Caulobacter cell cycle

The expression of cell cycle events in Caulobacter crescentus CB13 has been shown to be associated with regulation of carbohydrate utilization. Growth on lactose and galactose depends on induction of specific enzymes. Prior growth on glucose results in a delay in enzyme expression and cell cycle arrest at the nonmotile, predivisional stage. Dibutyryl cyclic adenosine 3',5'-monophosphate (AMP) was shown to stimulate expression of the inducible enzymes and, thus, the initiation of the cell cycle. beta-Galactosidase-constitutive mutants did not exhibit a cell cycle arrest upon transfer of cultures from glucose to lactose. Furthermore, carbon source starvation results in accumulation of the cells at the predivisional stage. The cell cycle arrest therefore results from nutritional deprivation and is analogous to the general control system exhibited by yeast (Hartwell, Bacteriol. Rev. 38:164-198, 1974; Wolfner et al., J. Mol. Biol. 96:273-290, 1975), which coordinates cell cycle initiation with metabolic state. Transfer of C. crescentus CB13 from glucose to mannose did not result in a cell cycle arrest, and it was demonstrated that this carbon source is metabolized by constitutive enzymes. Growth on mannose, however, is stimulated by exogenous dibutyryl cyclic AMP without a concomitant increase in the specific activity of the mannose catabolic enzymes. The effect of cyclic AMP on growth on sugars metabolized by inducible enzymes, as well as on sugars metabolized by constitutive enzymes, may represent a regulatory system common to both types of sugar utilization, since they share features that differ from glucose utilization, namely, temperature-sensitive growth and low intracellular concentrations of cyclic guanosine 3',5'-monophosphate.

Evidence that specific and "general" control of ornithine carbamoyltransferase production occurs at the level of transcription in Saccharomyces cerevisiae

Ornithine carbamoyltransferase synthesis is subject to two major regulatory systems in Saccharomyces cerevisiae. One system is specific for the arginine biosynthetic enzymes, whereas the other appears to be general, acting on a variety of other amino acid pathways as well. We observed that the synthetic capacity for continued ornithine carbamoyltransferase synthesis had the same short half-life (ca. 5 to 7 min) whether repression of enzyme production was brought about by action of the specific or general control system. We present evidence suggesting that both control systems regulate accumulation or ornithine carbamoyltransferase-specific synthetic capacity, rather than modulating its expression.

Inhibition of aminoacyl-transfer ribonucleic acid synthetases and the regulation of amino acid biosynthetic enzymes in Neurospora crassa

Growth conditions that result in the accumulation of the tryptophan intermediate indoleglycerol phosphate or of the histidine intermediate imidazoleglycerol phosphate cause mycelia of Neurospora crassa to exhibit an immediate and sustained increase in the differential rate at which the biosynthetic enzymes of the tryptophan, histidine, and arginine pathways are synthesized. These accumulated intermediates are shown to be inhibitors of the activity of aminoacyltransfer ribonucleic acid (tRNA) synthetases, as judged by an in vitro esterification assay. The tryptophan intermediate is shown to inhibit the charging of tryptophan, and the histidine intermediate is shown to inhibit charging of histidine. The inhibitions noted are consistent with the finding that the level of charged tRNATrp is decreased significantly in cells that have accumulated indoleglycerol phosphate and that of tRNAHis is decreased significantly in cells that have accumulated imidazoleglycerol phosphate. These results are interpreted as support for the involvement of aminoacyl-tRNA species in mediating cross-pathway regulation of the tryptophan, histidine, and arginine biosynthetic pathways as proposed in Lester's polyrepressor hypothesis (G. Lester, 1971). the correlations noted lead to the conclusion that Neurospora utilizes regulatory mechanisms that have the ability to react to changes in the level of charging of tRNA species.