Isolation and characterization of further cis- and trans-acting regulatory elements involved in the synthesis of glucose-repressible alcohol dehydrogenase (ADHII) in Saccharomyces cerevisiae.

Summary Starting with yeast cells lacking the constitutive alcohol dehydrogenase activity (ADHI), mutants with partially glucose-insensitive formation of ADHII were isolated. Genetic analysis showed that four mutants (designated ADR3 ^c) were linked to the ADHII-structural gene, ADR2, and were cis-dominant. On derepression, two of them produced elevated ADHII-levels, indicating a promotor function of the altered controlling site. The other ADR3 ^c-mutant alleles affected the ADHII-subunit association in diploids carrying two electrophoretically distinct alleles of the structural gene ADR2. Twelve semidominant constitutive mutants could be attributed to gene ADR1 (ADR1 ^c-alleles) previously identified by recessive mutants with blocked derepression. This suggested a positive regulatory role of the ADR1 gene product on the expression of the ADHII-structural gene. A pleiotropic mutation ccr1 (Ciriacy, 1977) was epistatic over glucose-resistant ADHII-formation caused by ADR1 ^c-alleles. From this it was concluded that CCR1 specifies for a product co-activating the structural gene or modifying the ADR1-gene product. A further regulatory element (gene designation ADR4) not linked to the structural gene could be identified upon isolation of recessive constitutive mutants adr4 from a ccr1 ADR1 ^c-double mutant.     

A positive regulatory gene is required for accumulation of the functional messenger RNA for the glucose-repressible alcohol dehydrogenase from Saccharomyces cerevisiae

The amount of glucose-repressible alcohol dehydrogenase is regulated by the amount of its functional messenger RNA. ADHII² protein was detected by a radioimmune assay and differentiated from ADHI, the classical ADH isozyme, by limited proteolysis with Staphylococcus aureus protease. When yeast containing the wild-type alleles for ADR2 (the ADH II structural locus) and for ADR1 (its positive regulatory gene) were pulse-labeled with [³⁵S]methionine during derepression, radioactive label accumulated in the antibody-precipitated ADHII coterminously with the appearance of ADHII activity. The kinetics of functional ADHII mRNA appearance during derepression in this strain were shown to be the same as those for ADHII protein synthesis in vivo when RNA, extracted from derepressed cells, was translated in a wheat germ cell-free translation system.The role of the positive regulatory gene, ADR1, in ADHII expression was analyzed using two strains mutated at that locus. Yeast containing the adr1-1 allele are incapable of derepressing ADHII activity. When this strain was pulselabeled with [³⁵S]methionine during derepression, approximately one-tenth to one-twentieth the level of ADHII protein synthesis was detected as in the wild-type strain. When RNA was extracted during derepression from cells containing the udr1-1 allele and translated in a wheat germ cell-free system, little functional ADHII mRNA was found to be present.The role of the ADR1 gene was further analyzed using a strain containing the ADR1-5^c allele, which allows constitutive synthesis of ADHII activity. In this strain during glucose repression. ADHII protein synthesis and amount of functional mRNA were at levels comparable to those found for the wild-type strain after complete derepression. Similar kinetics of ADHII protein synthesis and of mRNA accumulation during derepression were observed in the strain carrying the ADR1-5^c allele when compared to that carrying the ADR1 allele, but the absolute amounts were greater by three- to fourfold in cells containing the ADR1-5^c allele. These results indicate that the ADR1 gene acts to increase the level of functional ADHII mRNA during derepression.     

Analysis of mutations affecting Ty-mediated gene expression in Saccharomyces cerevisiae

Summary Yeast translocatable, Ty, elements can cause constitutive synthesis of the glucose-repressible alcohol dehydrogenase (ADHII) when inserted upstream from the 5 end of the structural gene, ADR2. These insertion mutations, ADR3 ^c, are unstable and give rise to secondary ADHII^– mutations. The majority of such mutants, adr3, can be attributed to excision of the insertion sequence, leaving behind a single copy of the -sequence which occurs as a direct repeat at the ends of the Ty elements. A few adr3 mutants appear to be generated by DNA-rearrangements in the vicinity of the Ty insertion. The occurrence of recessive mutants, tye, which are unlinked to ADR2 indicates that the constitutive expression of ADR2 caused by the Ty insertions requires the function of trans-acting genes. These results support the idea that regulation of Ty-linked ADR2 is actively mediated by the insertion sequence and is probably not due to a mere disruption of the wild-type controlling site.     

Transposable elements associated with constitutive expression of yeast alcohol dehydrogenase II

The yeast structural gene ADR2, coding for the glucose-repressible alcohol dehydrogenase (ADHII), has been isolated by complementation of function in transformed yeast. The chromosomal DNA from nine yeast strains with cis-dominant constitutive mutations (ADR3^c) has been investigated by restriction enzyme analysis, using the cloned ADR2 DNA as a hybridization probe. Seven mutants appear to have insertions of approximately 5.6 kb near the 5′ end of the ADR2-coding region. Four of these insertions have the same restriction pattern as the yeast transposable element Tyl. Two differ from Tyl by the presence of an additional Hind III site, and a seventh insertion differs from Tyl at a number of restriction sites. All are inserted in the same orientation with respect to the structural gene. A DNA fragment containing the ADR2 gene and adjacent sequences from a constitutive mutant has been cloned and shown by heteroduplex analysis to contain an insertion near the 5′ end of the structural gene. The cloned insertion sequence hybridizes to multiple genomic DNA fragments, indicating that it contains a moderately repetitive sequence. Thus it appears that insertion of a transposable element near the 5′ terminus of the structural gene can produce constitutive expression of a normally glucose-repressed enzyme. Such insertions seem to be the most common way of generating cis-dominant constitutive mutations of ADHII.     

Isolation and characterization of the positive regulatory gene ADR1 from Saccharomyces cerevisiae.

The DNA segments containing the ADR1 gene and a mutant allele, ADR1-5c, have been isolated by complementation of function in Saccharomyces cerevisiae. The ADR1 gene is required for synthesis of the glucose-repressible alcohol dehydrogenase (ADHII) when S. cerevisiae cells are grown on a nonfermentable carbon source, whereas the ADR1-5c allele allows ADHII synthesis even during glucose repression. A plasmid pool consisting of yeast DNA fragments isolated from a strain carrying the ADR1-5c allele was used to transform a strain containing the adr1-1 allele, which prevents ADHII depression. Transformants were isolated which expressed ADHII during glucose repression. A plasmid isolated from one of these transformants was shown to carry the ADR1-5c allele by its ability to integrate at the chromosomal adr1-1 locus. The wild-type ADR1 gene was isolated by colony hybridization, using the cloned ADR1-5c gene as a probe. The ADR1-5c and ADR1 DNA segments were indistinguishable by restriction site mapping. A partial ADR1 phenotype could be conferred by a 1.9-kilobase region, but DNA outside of this region appeared to be necessary for normal activation of ADHII by the ADR1 gene.     

Triallelic complementation and hybrid enzyme formation in Chlamydomonas reinhardi

Summary In Chlamydomonas, the arg-7 cistron (linkage group I) is the structural gene for the multimeric (probably pentameric) enzyme argininosuccinate lyase. Most of the alleles of the cistron were previously shown to complement in some pair combinations, giving rise to phenotypically wild-type diploids.By crossing diploid (mt^-) and haploid (mt⁺) cells bearing different markers of auxotrophy, seven different presumptive triploid strains, phenotypically wild-type, were isolated. Each strain had 3 different arg-7 alleles or 2 mutant alleles associated with a wild one.The isolates were cytologically and biochemically analyzed: it could be concluded that they were triploid or ar least trisomic for the linkage group I.The specific activity and the thermosensitivity of the lyase were compared in the different triploids and in the diploids bearing two of the three corresponding arg-7 alleles. In most cases, the enzyme formed by triallelic complementation was more active and more heat resistant than the enzyme formed by diallelic complementation. These results can be interpreted by assuming that hybrid enzyme is formed by interaction between the products of the three different alleles. They provide a molecular basis for explaining the increased vigor often found in polyploids.     

Identification of New Genes Involved in the Regulation of Yeast Alcohol Dehydrogenase II

Recessive mutations in two negative control elements, CRE1 and CRE2, have been obtained that allow the glucose-repressible alcohol dehydrogenase (ADHII) of yeast to escape repression by glucose. Both the cre1 and cre2 alleles affected ADHII synthesis irrespective of the allele of the positive effector, ADR1. However, for complete derepression of ADHII synthesis, a wild-type ADR1 gene was required. Neither the cre1 nor cre2 alleles affected the expression of several other glucose-repressible enzymes. A third locus, CCR4, was identified by recessive mutations that suppressed the cre1 and cre2 phenotypes. The ccr4 allele blocked the derepression of ADHII and several other glucose-repressible enzymes, indicating that the CCR4 gene is a positive control element. The ccr4 allele had no effect on the repression of ADHII when it was combined with the ADR1-5c allele, whereas the phenotypically similar ccr1 allele, which partially suppresses ADR1-5c, did not suppress the cre1 or cre2 phenotype. Complementation studies also indicated that ccr1 and snf1 are allelic. A model of ADHII regulation is proposed in which both ADR1 and CCR4 are required for ADHII expression. CRE1 and CRE2 negatively control CCR4, whereas CCR1 is required for ADR1 function.     

Regulation of the expression of iso 2-cytochrome c gene in S. cerevisiae: cloning of the positive regulatory gene CYP1 and identification of the region of its target sequence on the structural gene CYP3

Summary CYP1 is a trans acting regulatory locus modulating both iso 1- and iso 2-cytochrome c synthesis. Genetical analysis of various mutated alleles has allowed us to identify the gene product as a positive regulatory element.The region of the target sequence of the CYP1 product on the iso 2-cytochrome c structural gene was located by molecular and genetic analysis of two cis acting mutations located at the CYP3 locus: CYP3-36 and CYP3-4, which have been shown to arise from the integration of TY1 elements near the promoter site. Determination of the amount of iso 2-cytochrome c synthesized by strains bearing various genetic constructions, in which the cis acting mutations were associated with different alleles of the CYP1 trans acting locus, showed that TY1 inserted into CYP3-36 extinguishes the activation function due to a mutated overproducer allele CYP1-18, while CYP3-4 amplifies this function. This result identifies at least a part of the target sequence of the CYP1 product within the region separating the two TY1 insertions.To clone the CYP1 gene, we took advantage of the iso 2-cytochrome c overproducer phenotype of the mutated allele CYP1-18, which confers a Lactate⁺ phenotype on an iso 1-cytochrome c-deficient strain. Such a phenotype allowed the isolation of a recombinant plasmid YEpJFM1 carrying the mutated allele, able to complement on lactate medium a lactate ^- recipient strain. The identity of the YEpJFM1 sequence with the chromosomal gene was confirmed by homologous recombination at the CYP1 locus.     

Metabolic suppressors of a regulatory mutant in Neurospora

The synthesis of a number of enzymes of sulfur assimilation in Neurospora crassa is controlled by the sulfur source. Mutants in one regulatory gene, cys-3, are unable to make any of the enzymes. This locus is thought to specify a macromolecule that is required for the expression of the structural genes. A mutant, scon ^c, of another regulatory gene is nonrepressible for the synthesis of the enzymes. We report here the isolation of suppressed scon ^c strains which are actually the double mutant, scon ^c,cys-3. These strains are phenotypically indistinguishable from single mutants at the cys-3 locus. Thus cys-3 is epistatic to scon ^c. Evidence that the expression of the cys-3 gene is itself controlled is also presented.This work is supported by a Public Health Service grant, GM-08995, from the National Institute of General Medical Sciences. One of us (R.L.M.) is supported by a Public Health Service Career Development Award.     

Approaches for the Isolation of Arabidopsis adh1 Regulatory Mutants Using Allyl Alcohol Selection

Allyl alcohol, a suicide substrate for the alcohol dehydrogenase enzyme (EC.1.1.1.1), has been frequently used as a negative selection method for the isolation of alcohol dehydrogenase mutants in plants, animals and microorganisms. This approach led to the isolation of mutants that mapped to the ADH gene itself. We attempted to use allyl alcohol selection for the isolation of adh1 regulatory mutants in Arabidopsis. First we selected at plantlet level on ADH1–GUS transgenic plants. This enabled us to use GUS staining to discriminate between structural and regulatory mutants. Allyl alcohol selection of 50000 EMS-treated seeds did not yield any potential mutants. Secondly we selected EMS and -ray-treated seeds of a transgenic line transformed with an additional copy of the ADH1 gene including its own promoter. Fifteen allyl alcohol-resistant plants were selected from the mutagenized seed. Genetic analysis of three putative mutants (adr8, adr10, and adr15) indicated that the ADH1-null phenotype was due to monogenic trans-recessive mutations. But treatment with the demethylating agent 5-azacytidine and analysis of methylation levels of the ADH1 gene indicated that these mutant candidates have increased levels of methylation in the promoter and coding region of ADH1. These results suggest that the allyl alcohol resistance of adr8, adr10, and adr15 is due to silencing of ADH1 rather than to a mutation of a regulatory locus.     

Mutations of the Adh1 gene in maize following infection with barley stripe mosaic virus

Summary Mutations at the Adh1 locus in maize were selected from plants infected with barley stripe mosaic virus (BSMV). Pollen from the infected inbred line 1s2p, which is homozygous for Adh1-S (abbreviated S), Adh2-P, c and r was treated with allyl alcohol and applied to silks of a tester stock homozygous for Adh1-F, Adh2-N, C and R. From these pollinations 356 kernels arose on the F₁ ears. Of these eight showed no activity of the S allele in scutellar samples while two exhibited low levels. Five of the putative mutant kernels germinated and two of these contained the contamination markers Adh2-P, c and r. The newly arisen mutations were designated S5446 and S5453. S5453 exhibited an abnormally low level of ADH activity in the F₁ scutellum. In the F₂ generation the mutant reverted at a high frequency with only about 5% of the S5453 alleles expressing low levels. DNA blotting and hybridization analyses showed no alterations in the restriction patterns of S5453 when compared to the progenitor S allele. S5446 which exhibited no ADH activity in the F₁ scutellum is unstable in the pollen; reversion frequencies approaching 10^-2 were observed in samples from some plants. Restriction digestion patterns of DNA from this mutant revealed the presence of a 3.3 kb insertion at Adh. The insert does not appear to contain sequences homologous to the BSMV genome but rigorous analyses remain to be carried out. It is hypothesized that BSMV infection may mobilize endogenous but dormant transposable elements in maize.     

Fidelity of meiotic gene conversion in yeast

Summary Gene conversion was studied in a sample of 3869 unselected meiotic tetrads obtained from three diploids, respectively; heterozygous for a single ochre mutant, heteroallelic for a pair of ochre alleles, and heterozygous for an ochre specific suppressor. Although the genetic system were sufficiently sensitive to detect single base changes at the mutant codon level, none were found among 36 conversions (1+:3m) of the ochre mutants and 153 conversions (3S:1+) of the suppressor locus. These findings lead to the conclusion that the informational transfer in gene conversion occurred with complete fidelity. Gene conversion conserved and did not generate new genetic information. The error level of conversion was estimated as less than 10^-2/N.P.     

Isolation of Hem3 mutants from Candida albicans by sequential gene disruption

Summary Molecular methods for directed mutagenesis in Candida albicans have relied on a combination of gene disruption by transformation to inactivate one allele and UV-induced mitotic recombination or point mutation to produce lesions in the second allele. An alternate method which uses two sequential gene disruptions was developed and used to construct a C. albicans mutant defective in a gene essential for synthesizing tetrapyrrole (uroporphyrinogen I synthase). The Candida gene was cloned from a random library by complementation of the hem3 mutation in Saccharomyces cerevisiae. The complementing region was limited to a 2.0 kb fragment by subcloning and a BglII site was determined to be within an essential region. Linear fragments containing either the Candida URA3 or LEU2 gene inserted into the BglII site were used to disrupt both alleles of a leu2, ura3 mutant by sequential transformation. Ura⁺, Leu⁺ heme-requiring strains were recovered and identified as hem3 mutants by Southern hybridization, transformation to heme independence by the cloned gene, and enzyme assays.     

The detection of post-meiotic segregation without tetrad analysis in Ustilago maydis

Summary Post-meiotic segregation (PMS) results in the formation of mixed genotypes from single meiotic products. A method is described in which single members of tetrads are selected, and these are then tested for their genetic homogeneity. The method is applied to Ustilago maydis using crosses which are heteroallelic for nar 1, the structural gene for nitrate reductase. In the absence of PMS, meiotic products containing a nar ⁺ recombinant are genetically pure (the equivalent of a 6 mutant: 2 wild-type octad). With PMS, a nar ⁺ recombinant clone arises in association with a nar ^- clone and these are otherwise genetically identical (the equivalent of a 7 mutant: 1 wild type octad). The procedure will make it possible to search for mutant strains which are defective in the correction of mismatched bases in hybrid DNA formed during recombination. Among 26 nar ⁺ recombinants from a control cross, PMS was detected on 3 occasions. In an equivalent cross, both parents were uvs 3, a mutant defective in the excision of pyrimidine dimers from DNA. Among 43 nar ⁺ recombinants, 7 arose from PMS. Thus the frequency of PMS for the nar alleles is about 15% and the excision of pyrimidine dimers is probably unrelated to the repair of mismatched bases in hybrid DNA.     

Conjugation-deficient mutants of Escherichia coli distinguish classes of functions of the outer membrane OmpA protein

Summary Sixty-two E. coli mutants, selected as being deficient as recipients in F factor conjugation, are altered either in the amount or function of the outer membrane OmpA protein or in lipopolysaccharide structure. These two components may function together in conjugation, since the residual conjugation activity of a mutant lacking OmpA protein was unaffected by the additional presence of a lipopolysaccharide defect. Sixty of the strains carried mutations mapping to ompA, and these could be divided into classes depending on the amount of OmpA protein in their membranes. Representatives of these classes of mutant alleles failed to complement in diploids, indicating that they all affect the ompA structural gene and nearby sequences needed for its expression. The properties of these classes distinguish three groups of OmpA protein functions: 1) the structural function in the outer membrane in providing resistance to chelating agents and the hydrophobic antibiotic novobiocin, 2) the receptor functions in phage Tull^* and K3 infection, and 3) the functions of binding cells together during conjugation, facilitating the uptake of receptorbound colicin K or L, and allowing phage Ox2 to infect. Different cellular amounts or sites in OmpA protein are thus required for these three groups of functions.