Expression of the ROAM mutations in Saccharomyces cerevisiae: involvement of trans-acting regulatory elements and relation with the Ty1 transcription

The regulatory mutations in Saccharomyces cerevisiae designated cargA + Oh, cargB + Oh, and durOh are alterations in the control regions of the respective structural genes. The alteration causing the cargA + Oh mutation has been shown to be an insertion of a Ty1 element in the 5' noncoding region of the CAR1 ( cargA ) locus. All three mutations cause overproduction of their corresponding gene products and belong to the ROAM family of mutations (Regulated Overproducing Allele responding to Mating signals) in yeast. The amount of overproduction in ROAM mutants is determined, at least in part, by signals that control mating functions in yeast. We report the identification of two genetic loci that regulate Oh mutant gene expression but that do not affect mating ability. These loci are defined by the recessive roc mutations ( ROAM mutation control) that reduce the amount of overproduction caused by the cargA + Oh, cargB + Oh, and durOh mutations. RNAs homologous to CAR1 ( cargA ), DUR1 ,2 and Ty1 DNA probes were analyzed by the Northern hybridization technique. In comparison with wild-type strains, cargA + Oh and durOh mutant strains grown on ammonia medium contain increased amounts of CAR1 and DUR1 ,2 RNA. This RNA overproduction is diminished in MATa/MAT alpha diploid strains as well as in haploid strains that also carry the ste7 mutation which prevents mating or that carry either of the roc1 or roc2 mutant alleles. The amount of RNA homologous to Ty1 DNA is also reduced in ste7 , roc1 , and roc2 mutant strains. This reduction is not observed in a strain with the ste5 mutation, which prevents mating but has no effect on overproduction of ROAM mutant gene products.(ABSTRACT TRUNCATED AT 250 WORDS)     

An operator constitutive mutant affecting the synthesis of two enzymes involved in the catabolism of nucleosides in Escherichia coli

Summary A new type of mutant of mutant of Escherichia coli that synthesises thymidine phosphorylase constitutively has been isolated and characterised. The mutation leading to constitutivity is located to the left of the gene specifying deoxyriboaldolase. The mutation is cis dominant in its effect on thymidine phosphorylase activity and therefore believed to be a mutation of the operator-constitutive type. The specific activity of purine nucleoside phosphorylase is not affected by the mutation indicating that the gene specifying this enzyme is located in a different operon from that containing the genes specifying thymidine phosphorylase and deoxyriboaldolase.     

Functional analysis of the regulatory region adjacent to the cargB gene of Saccharomyces cerevisiae. Nucleotide sequence, gene fusion experiments and cis-dominant regulatory mutation analysis

In Saccharomyces cerevisiae the expression of the cargB gene (coding for ornithine aminotransferase) is submitted to dual regulation: an induction by allophanate and a specific induction process by arginine. We have determined the nucleotide sequence of the cargB gene along with its 5' region. The coding portion of the gene encodes a protein of 423 amino acid residues with a calculated Mr value of 46049. To characterize further the regulatory mechanisms modulating the expression of the gene we have analyzed fusions of several fragments of the 5' non-coding region to lacZ, compared the 5' sequences of the cargA (coding for arginase) and cargB coregulated genes and determined the nature of two constitutive cis-dominant mutations affecting the arginine control. These approaches allowed us to define three domains in the 5' non-coding region. The upstream one is implicated in the induction by allophanate. The two other domains are involved in the specific control by arginine; the target of the ARGR gene products, that mediate a positive regulation by arginine, lies upstream of another site where a repression by the CARGRI molecule occurs. The constitutive cargB+O- mutations are located in this repressor domain. The 5' non-coding region of cargA presents the same two-domain organization. These two domains contain three sequences homologous to the cargA and cargB 5' regions.     

Repression of 3-deoxy-D-arabinoheptulosonic acid-7-phosphate synthetase (trp) and enzymes of the tryptophan pathway in Escherichia coli K-12

Mutant strains of Escherichia coli K-12 have been isolated in which the synthesis of 3-deoxy-d-arabinoheptulosonic acid-7-phosphate (DAHP) synthetase (trp) is partially constitutive. The mutation causing derepression is closely linked to aroH [the structural gene for DAHP synthetase (trp)] and occurs in a locus designated aroJ. The aroJ mutation is not recessive in an aroJ(+)/aroJ(-) diploid strain, as the synthesis of DAHP synthetase (trp) is still derepressed in this strain. On the basis of its close linkage to aroH and its continued expression in an aroJ(+)/aroJ(-) diploid, it is postulated that aroJ is an operator locus controlling the expression of the structural gene aroH. In support of this conclusion, the synthesis of anthranilate synthetase is still normally repressible in aroJ(-) strains, whereas, in trpR(-) strains, both DAHP synthetase (trp) and anthranilate synthetase are synthesized constitutively. The synthesis of DAHP synthetase (trp) remains repressible in an operator-constitutive mutant of the tryptophan operon. In two trpS mutants which possess defective tryptophanyl transfer ribonucleic acid synthetase enzymes, neither DAHP synthetase (trp) nor anthranilate synthetase derepress under conditions in which the defective synthetase causes a decrease in growth rate. On the other hand, an effect of the trpS mutant alleles on the level of anthranilate synthetase has been observed in strains which are derepressed for the synthesis of this enzyme, because of a mutation in the gene trpR. Possible explanations for this effect are presented.     

Lifetime of messenger ribonucleic acid for penicillinase synthesis in several strains of bacilli

1. Previous studies of penicillinase synthesis in Bacillus licheniformis showed that enzyme synthesis after the addition of actinomycin continues for far longer in the constitutive mutant 749/C than in the parental inducible strain (Yudkin, 1966). This result was interpreted as indicating a difference in the lifetime of specific messenger RNA in the two strains. Other bacilli have now been examined in an attempt to see whether this difference is general. 2. There was no difference in the lifetime of messenger RNA for penicillinase synthesis between an inducible and a constitutive strain of Bacillus cereus. 3. Three freshly isolated constitutive mutants of B. licheniformis also had short-lived messenger RNA, like their inducible parent. 4. A reinvestigation of mutant 749/C confirmed the original finding that, on treatment with actinomycin, it continued to synthesize penicillinase far longer than did its parent. 5. An inducible revertant of mutant 749/C was indistinguishable from the original inducible strain, and appeared to have lost both constitutivity and long-lived messenger RNA in the back mutation.     

Role of small molecules in regulation of D-serine deaminase synthesis.

Cyclic AMP is required for optimal synthesis of D-serine deaminase synthesis from dsdO+ templates and for optimal hyperinducible synthesis from low constitutive dsdO templates both in vitro and in vivo. Neither D-serine, cyclic AMP, nor dsdC activator has an effect on expression of a high constitutive dsdO template. The synthesis of the dsdC activator itself in vitro is independent of cyclic AMP. Guanosine tetraphosphate does not have a significant effect on in vitro D-serine deaminase synthesis from dsdO+ or dsdO templates. A previously described class of dsdO mutants showing partial catabolite sensitivity of constitutive D-serine deaminase synthesis proved to be low dsdO types. They all contain a low constitutive dsdC mutation; the two effects are additive with regard to level of constitutivity, but only that portion of synthesis attributable to the dsdC mutation is cyclic AMP dependent.     

The regulation of urea amidolyase of Saccharomyces cerevisiae: mating type influence on a constitutivity mutation acting in cis.

Summary Constitutivity for the synthesis of the urea amidolyase bienzymatic complex is obtained by dur0^hmutations located in the regulatory genetic region adjacent to the dur1, dur2 gene cluster. The dur0^hmutations act only in cis and are a new case of cis effect strongly cancelled in /a diploid, similar to cargA ⁺0^hmutation shown previously to lead to arginase constitutivity. Illegitimate diploids do not show such a cancellation of constitutivity.The constitutivity produced by dur0^hmutation comprises the process of induction and the release of the glutamine effect. It does not impair the NH ₄ ⁺ effect.     

L-ornithine transaminase synthesis in Saccharomyces cerevisiae: Regulation by inducer exclusion

Summary The ornithine transaminase (EC.2.6.1.13) of Saccharomyces cerevisiae is induced by arginine, ornithine, and their analogs. Genetic regulatory elements which are involved in this induction process have been defined due to the isolation of specific mutants. Two classes of OTAse operator mutants have previously been described; three unlinked genes are presumed to code for a specific repressor, CARGR of both of the arginine catabolic enzymes, arginase, and ornithine transaminase. The level of transaminase of cells grown on ammonia plus arginine is much lower than it is when arginine is the sole nitrogen source. Ammonia thus seems to limit the amount of enzyme synthesized when arginine is present in the growth medium. Nevertheless, all attempts to disclose a nitrogen catabolite repression process in OTAse synthesis have failed; neither the action of mutations that release this regulation on arginase and other catabolic enzymes, nor the use of derepressing growth conditions, affect OTAse synthesis. A decrease of the cells' arginine pool when amonia or aminoacids (serine, glutamate) are added to arginine as a nitrogen nutrient results in a progressive reduction of transaminase synthesis. This suggests that arginine is the only physiological effector in those conditions: ammonia or some aminoacids would reduce the enzyme synthesis because of an inducer exclusion. The first stage of OTAse induction would then be operated by the CARGR repressor, and an additional regulatory element might take part in the full scale process. Preliminary data favoring the involvment of such an element are presented.     

Nucleotide pool in pho regulon mutants and alkaline phosphatase synthesis in Escherichia coli.

The intracellular nucleotide pool of Escherichia coli W3110 reproducibly changes from conditions of growth in phosphate excess to phosphate starvation, with at least two nucleotides appearing under starvation conditions and two nucleotides appearing only under excess phosphate conditions. Strains bearing a deletion of the phoA gene show the same pattern, indicating that dephosphorylation by alkaline phosphatase is not responsible for the changes. Strains with mutations in the phoU gene, which result in constitutive expression of the pho regulon, show the nucleotide pattern of phosphate-starved cells even during phosphate excess growth. These changes in nucleotides are therefore due to phoU mutation but not to alkaline phosphatase constitutivity. In fact, a phoR (phoR68) mutant strain has the patterns of the wild type in spite of being constitutive for alkaline phosphatase. That these nucleotides might be specific signals for pho regulon expression was supported by the fact that the two nucleotides appearing under phosphate starvation induced the synthesis of alkaline phosphatase in repressed permeabilized wild-type cells under conditions of phosphate excess.     

Genetic control of tyramine oxidase, which is involved in derepressed synthesis of arylsulfatase in Klebsiella aerogenes.

Mutants of Klebsiella aerogenes with three types of mutations affecting regulation of tyramine oxidase were isolated by a simple selection method. In the first type, the mutation (tynP) was closely linked to the structural gene for tyramine oxidase tynA). The order of mutation sites was atsA-tynP-tynA. In the second type, the mutation that relieves catabolite repression of the syntheses of several catabolite repression-sensitive enzymes are not linked to the tyn gene by P1 transduction. These strains contained high levels of cyclic adenosine 5'-monophosphate when grown on glucose. The third type of mutation, in which tyramine oxidase was synthesized constitutively, was shown by genetic analysis to involve mutations of tynP and tynR. The tynR gene was not linked to tynA. Results using the constitutive mutants showed that the constitutive expression of the tynA gene resulted in depression of arylsulfatase synthesis in the absence of tyramine.     

Catabolite repression of the lac operon: effect of operator-constitutive mutations

Summary We have constructed and tested three lac diploid strains in an attempt to show whether operator-constitutive mutations relieve catabolite repression of the lac operon. Each of these carries a different operator mutation on the chromosome, and all three have the genotype I⁺P⁺O^cZ⁺Y^-polar/Flac I⁺P⁺O⁺Z^delY⁺A⁺. When these strains were grown in medium containing glucose plus gluconate, synthesis of -galactosidase (directed by a gene cis to a mutant operator) and of thiogalactoside transacetylase (directed by a gene cis to an intact operator) suffered equal catabolite repression. We conclude that the operator-constitutive mutations have no effect on catabolite repression. Since it has been shown in analogous experiments that all promoter mutations tested do alleviate catabolite repression, these results are consistent with the view that the operator and promoter are functionally distinct.     

Suppression of dnaE nonsense mutations by pcbA1.

DNA polymerase III has been recognized as the required replication enzyme in Escherichia coli. The synthesis subunit of DNA polymerase III holoenzyme (alpha subunit) is encoded by the dnaE gene. We have reported that E. coli cells can survive and grow in the absence of a functional dnaE gene product if DNA polymerase I and the pcbA1 mutation are present. Existing mutations in the dnaE gene have been conditionally defective thermolabile mutations. We report here construction of nonsense mutations in the dnaE gene by use of a temperature-sensitive suppressor mutation to permit survival at the permissive temperature (32 degrees C). Introduction of the pcbA1 mutation eliminated the temperature-sensitive phenotype. We confirmed by immunoblotting the lack of detectable alpha subunit at 43 degrees C.     

Homothallic mating type switching generates lethal chromosome breaks in rad52 strains of Saccharomyces cerevisiae.

In homothallic cells of Saccharomyces cerevisiae, a or alpha mating type information at the mating type locus (MAT) is replaced by the transposition of the opposite mating type allele from HML alpha or HMRa. The rad52-1 mutation, which reduces mitotic and abolishes meiotic recombination, also affects homothallic switching (Malone and Esposito, Proc. Natl. Acad. Sci. U.S.A. 77:503-507, 1980). We have found that both HO rad52 MATa and HO rad52 MAT alpha cells die. This lethality is suppressed by mutations that substantially reduce but do not eliminate homothallic conversions. These mutations map at or near the MAT locus (MAT alpha inc, MATa-inc, MATa stk1) or are unlinked to MAT (HO-1 and swi1). These results suggest that the switching event itself is involved in the lethality. With the exception of swi1, HO rad52 strains carrying one of the above mutations cannot convert mating type at all. MAT alpha rad52 HO swi1 strains apparently can switch MAT alpha to MATa. However, when we analyzed these a maters, we found that few, if any, of them were bona fide MATa cells. These a-like cells were instead either deleted for part of chromosome III distal to and including MAT or had lost the entire third chromosome. Approximately 30% of the time, an a-like cell could be repaired to a normal MATa genotype if the cell was mated to a RAD52 MAT alpha-inc strain. The effects of rad52 were also studied in mata/MAT alpha-inc rad52/rad52 ho/HO diploids. When this diploid attempted to switch mata to MATa, an unstable broken chromosome was generated in nearly every cell. These studies suggest that homothallic switching involves the formation of a double-stranded deoxyribonucleic acid break or a structure which is labile in rad52 cells and results in a broken chromosome. We propose that the production of a double-stranded deoxyribonucleic acid break is the lethal event in rad52 HO cells.     

Suppression of polarity of insertion mutations within the gal operon of E. coli.

Summary Phenotypic revertants of galOP::IS1 and galOP::IS2 mutations have been isolated after mutagenesis with nitrosoguanidine, they are probably caused by mutations in gene suA. The polarity suppressor mutations described in this study and a known mutation in gene suA isolated by D. Morse (Morse and Guertin, 1972) suppress polarity caused by IS1 more effectively than that caused by IS2 or IS4. Furthermore, suppressibility is influenced by the site and orientation of IS integration.The synthesis of the three enzymes in galOP::IS suA double mutants is constitutive and the ratio of the three enzymes is altered in comparison to the wild type. The reasons for constitutive synthesis of the galactose enzymes and for the altered ratio of enzyme synthesis are discussed.     

Selection for Early Meiotic Mutants in Yeast

In the yeast Saccharomyces cerevisiae, only a/alpha cells can enter meiosis; a and alpha cells cannot. Because a/alpha cells are typically diploid and a and alpha cells are typically haploid, this cell type restriction ensures that only diploid cells enter meiosis. Entry into meiosis is accompanied by an increase in expression of the IME1 gene; the IME1 product (IME1) then activates IME2 and other meiotic genes. We have found that IME1 expression is toxic to starved haploid cells, presumably because IME1 directs them into meiosis. IME1 toxicity is greater in rad52 mutants, in which meiotic recombination causes lethal damage. Suppressors of IME1 toxicity include recessive mutations in two genes, RIM11 and RIM16 (Regulator of Inducer of Meiosis), that are required for IME1 to activate IME2 expression. RIM11 maps near CIN4 on chromosome XIII.     

Pseudoreversion of lactose operator-constitutive mutants.

A set of pseudorevertants of lactose operator-constitutive (lacOc) mutant has been obtained. Analysis of a subset of these pseudorevertants indicates that, in some cases, the secondary mutation alters the lactose repressor (lacl gene product), whereas in others it seems to have occurred in the lactose operator (lacO) itself. Of the lacl gene mutations, the lacl8 mutation, already known to suppress all lacOc mutations nonspecifically, was recovered by a selection technique developed for this study. However, two additional lacl gene mutants were selected which appear to suppress lacOc sequences in a more-or-less specific fashion; repressor interaction with some operator sequences is facilitated, whereas the binding with lacO+ and others is attenuated concomitantly.     

The timing of UV mutagenesis in yeast: continuing mutation in an excision-defective (rad1-1) strain.

Summary Mutation induction by ultraviolet light was studied in excision-defective (rad1-1) strains of Saccharomyces cerevisiae. Information about the timing of mutations in relation to postirradiation DNA replication was obtained. The experimental system involved pedigree analysis of G1 diploid cells and subsequent tetrad analysis of the mitotic segregants to detect mutations.The mutation pattern of rad1-1 strains differed from that of wild type in two respects: (1) few or none of the mutations affected both strands of the DNA, (2) mutations appeared as frequently in the second postirradiation mitotic generation as in the first.The data have led to the following conclusions about the mutation process in excision-defective (rad1-1) yeast: (a) Mutations are not fixed prior to the first postirradiation round of DNA replication. (b) Unexcised thymine dimers persist as mutagenic lesions through repeated postirradiation cell divisions. (c) Heteroduplex repair is involved in the mutation process. (d) Overlapping daughter-strand gaps are not a prerequisite for mutation. (e) The results provide no evidence that error-prone repair in this strain is inducible rather than constitutive. The data also show that (f) all 2-strand mutations (whole-colony mutants) induced in yeast by exposure to low levels of ultraviolet light are associated with excision repair, and that (g) essentially all lesions induced in excision-proficient strains have been excised at the time of the second round of postirradiation DNA synthesis.On leave of absence from the Department of Genetics, University of Edinburgh, West Mains Road, Edinburgh, Scotland EH9 3JN