CYP1 (HAP1) regulator of oxygen-dependent gene expression in yeast. I. Overall organization of the protein sequence displays several novel structural domains.

In the yeast Saccharomyces cerevisiae the CYP1 gene that modulates the expression of iso1-(CYC1) and iso2-cytochrome c (CYP3) structural genes gives rise to two classes of mutated alleles; one class, represented by CYP1-18, has opposite effects on CYC1 and CYP3, it reduces the expression of CYC1 while it stimulates that of CYP3. The other class, represented by cyp1-23 or the related allele hap1-1, reduces the expression of both CYC1 and CYP3 genes. Genetic data suggested that the CYP1 product is a positive regulator of the cytochrome c genes. The CYP1-18 allele has been cloned. We show here that the iso2 overproducer function of CYP1-18 is included in a 5300 base XhoI-PstI fragment. The sequence of this fragment reveals a unique, long, uninterrupted open reading frame of 4449 nucleotides able to encode a protein of 1483 amino acid residues. The predicted product of this open reading frame contains several interesting features. The N-terminal part of the protein resembles a nucleic acid-binding domain, in which two domains can be distinguished. The first is similar to a "finger" DNA binding motif, as found in TFIIIA and other regulatory proteins. The second consists of seven tandemly repeated sequences with a KCPVDH motif. Because of its structure, it is tempting to speculate that this region may act as a "redox sensor" folded around a metal atom or heme and involved in recognition of respiratory effectors. These two domains are separated by an "opa" sequence of 13 Gln residues. Implication of these domains for the function of CYP1-18 is discussed.

CYP1 (HAP1) regulator of oxygen-dependent gene expression in yeast. II. Missense mutation suggests alternative Zn fingers as discriminating agents of gene control.

In the accompanying paper, we present and analyse the sequence of a "superactivator" mutant allele of the CYP1 (HAP1) gene. This locus encodes a trans-acting pleiotropic positive regulator of the transcription of both isocytochrome c structural genes. In this paper, we present the genetic localization of the mutation and the sequence of the wild-type fragment that includes the mutation. The mutated phenotype that commutes the expression of the two isocytochrome structural genes (superactivation of CYP3 and inhibition of CYC1) results from a transversion in an AGT codon (serine) in the wild-type to an AGG codon (arginine) in the mutant. Moreover, we show that the missense mutation that affects the amino acid preceding the first cysteine of the "Zn finger" is responsible on its own account for the entire mutated phenotype. In all seven yeast regulatory proteins analysed so far, this position is occupied by a neutral amino acid (serine, alanine or glycine), thus the serine-arginine replacement is a radical one. This result is consistent with the hypothesis of alternative and mutually exclusive Zn fingers, formed either at low or high redox potential, recognizing the target sequences identified in the upstream regions of the CYC1 and CYP3 isocytochrome c structural genes.

Genetic structure and internal rearrangements of stable merodiploids from Bacillus subtilis strains carrying the trpE26 mutation.

Transformation and transduction to tryptophan independence of strains of Bacillus subtilis carrying the "trpE26" chromosomal aberrations (a translocation and an inversion) with a "normal" 168 type strain as donor induce a tandem duplication of the thrA-ilvA region of the chromosome. The clones possessing this unstable duplication segregate besides the Trp- some stable Trp+ cells which retain only part of the duplication (the trpE-ilvA region) in nontandem configuration. Such clones may also be produced directly during the crosses. The genetic map of these clones (designated as class I stable merodiploids) was constructed: they possess the translocation and the inversion of the trpE26 parental strain. Another type of stable Trp+ clones (class II) also appears, although more rarely, in similar crosses. Studies on their genetic structure revealed that they are haploid for the trpE-ilvA region and carry a nontandem duplication of the thrA-trpE region. In these clones the cysB-tre region has the orientation of the 168 type strain. The duplications in both classes are stable, that of class I being more stable than that of class II where loss of one copy of the thrA-trpE region leads to about 1% haploid cells. Detailed genetic studies on heterozygous clones from both classes have shown exchange of alleles between copies of the nontandem duplications. Models are proposed for the formation of each class of merodiploids and for recombination events taking place in them. These models imply recombination at sequences of intrachromosomal homology and (or) introduction of heterologous junctions ("novel joints") by transformation or transduction.

The transcriptional regulator Hap1p (Cyp1p) is essential for anaerobic or heme-deficient growth of Saccharomyces cerevisiae: Genetic and molecular characterization of an extragenic suppressor that encodes a WD repeat protein.

We report here that Hap1p (originally named Cyp1p) has an essential function in anaerobic or heme-deficient growth. Analysis of intragenic revertants shows that this function depends on the amino acid preceding the first cysteine residue of the DNA-binding domain of Hap1p. Selection of recessive extragenic suppressors of a hap1-hem1- strain allowed the identification, cloning, and molecular analysis of ASC1 (Cyp1 Absence of growth Supressor). The sequence of ASC1 reveals that its ORF is interrupted by an intron that shelters the U24 snoRNA. Deletion of the intron, inactivation of the ORF, and molecular localization of the mutations show unambiguously that it is the protein and not the snoRNA that is involved in the suppressor phenotype. ASC1, which is constitutively transcribed, encodes an abundant, cytoplasmically localized 35-kD protein that belongs to the WD repeat family, which is found in a large variety of eucaryotic organisms. Polysome profile analysis supports the involvement of this protein in translation. We propose that the absence of functional Asc1p allows the growth of hap1-hem1- cells by reducing the efficiency of translation. Based on sequence comparisons, we discuss the possibility that the protein intervenes in a kinase-dependent signal transduction pathway involved in this last function.

Functional analysis of the zinc cluster domain of the CYP1 (HAP1) complex regulator in heme-sufficient and heme-deficient yeast cells.

CYP1 determines the expression of several genes whose transcription is heme-dependent in yeast. It exerts regulatory functions even in the absence of heme, usually considered to be its effector. It mediates both positive and negative effects, depending on the target gene and on the redox state of the cell. In the presence of heme, it binds through a cysteine-rich domain in which a histidine residue occupies the position of the sixth and essential cysteine of the otherwise classical zinc cluster DNA-binding domain exemplified by GAL4. We constructed specific missense mutations in the potential CYP1 zinc cluster domain by site-directed mutagenesis and looked for regulatory effects of the mutated proteins under specific physiological conditions. We show that CYP1 does belong to the zinc cluster regulatory family since a sixth essential cysteine residue is indeed present, albeit at a modified position when compared to the consensus sequence. We also show that the amino acid preceding the first cysteine residue of the DNA-binding domain critically affects the efficiency of regulation both in the presence and in the absence of heme: mutations known to affect DNA binding under heme-sufficient conditions also affect regulation under heme-deficient conditions. We therefore surmise that regulation under heme-deficient conditions is dependent upon DNA binding.

Characterization of a promoter mutation in the CYP3 gene of Saccharomyces cerevisiae which cancels regulation by Cyp1p (Hap1p) without affecting its binding site.

Cyp1p (Hap1p) activates, among others, the two structural genes, CYC1 and CYP3 (CYC7) which encode isocytochromes c in Saccharomyces cerevisiae. This activation is believed to occur through the binding of the protein to the dissimilar upstream activation sequences (UASs), UAS1 and UAS', present upstream of CYC1 and CYP3, respectively. In this paper, we describe a novel promoter mutation, CYP3-5, which results from a 39-bp deletion located about 160 bp upstream of the well-characterized CYP3 UAS. This deletion includes a sequence identical to the 3' moiety of the CYC1 UAS1. Strikingly, a sequence identical to the 5' part of the CYC1 UAS1 is also present 60 bp downstream of the 3' half in the wild-type gene, suggesting that a spatial organization of the promoter might lead to the reconstitution in vivo of an active UAS1-like sequence. Interestingly, we find that in the presence of the CYP3-5 mutation, which disrupts this potential UAS1, the CYP-UAS' complex is importantly diminished and the transcription of CYP3 is insensitive to the wild-type CYP1-activating protein.

CYP1 (HAP1) is a determinant effector of alternative expression of heme-dependent transcribed genes in yeast [corrected].

The CYP1 (HAP1) gene of Saccharomyces cerevisiae is known to activate a number of target genes in response to the presence of heme. Several features of the protein, deduced from the sequence of the gene, suggest that CYP1 is a general sensor of the redox state of the cell. To investigate further the function of CYP1, we analysed its effects on the transcription of two genes, HEM13 and 14DM, which are preferentially expressed in anaerobiosis. HEM13 encodes coproporphyrinogen oxidase which catalyses the sixth enzymatic step in the heme biosynthetic pathway and 14DM encodes lanosterol-14-demethylase which is involved in sterol biosynthesis and is a member of the cytochrome P450 family. Isogenic CYP1+ and cyp1 degree deleted strains, either heme-sufficient or heme-deficient (HEM1 disrupted), were grown in aerobic or anaerobic conditions, and transcripts of HEM13 and 14DM were analysed on Northern blots. The results show that in anaerobic and in heme-deficient cells, CYP1 activates the transcription of HEM13 and inhibits that of 14DM. Opposite effects of CYP1 are observed in aerobic, heme-sufficient cells. We concluded that: (i) CYP1 is an efficient activator especially in heme-depleted cells; (ii) CYP1 exerts both positive and negative regulatory effects; (iii) the nature of the regulatory function of CYP1 depends on the target gene; and (iv) for a given gene, the presence or absence of heme or oxygen reverses the sense of CYP1-dependent regulation.

A 'natural' mutation in Saccharomyces cerevisiae strains derived from S288c affects the complex regulatory gene HAP1 (CYP1).

The HAP1 gene encodes a complex transcriptional regulator of many genes involved in electron-transfer reactions and is essential in anaerobic or heme-depleted conditions. We show here that strains derived from S288c carry a defective Ty1 element inserted in the 3' region of the HAP1 ORF. This mutant allele acts as a HAP1 null allele in terms of cytochrome c expression and CYC1 UAS1-dependent transcription, but is able to sustain limited growth in heme-depleted conditions.