Rosine Labbe-Bois

Regulation of Cu,Zn- and Mn-superoxide dismutase transcription in Saccharomyces cerevisiae

The regulation of Cu,Zn‐ and Mn‐superoxide dismutases (SOD) was investigated by Northern blotting and gene fusions of SOD1 and S0D2 promoters with the β‐galactosidase reporter gene. Cu,ZnSOD expression was increased 3‐fold under glucose derepressing conditions, and decreased 4‐ to 6‐fold by oxygen or heme deficiency. MnSOD expression was increased 5‐fold by glucose derepression, and decreased 8‐ to 10‐fold by anaerobiosis and 4‐ to 5‐fold by heme deficiency. Induction by paraquat was modest, about 50% for SOD1 and 100% for SOD2; it was apparently independent of the respiratory chain function.

Probing the Active-site Residues in Saccharomyces cerevisiae Ferrochelatase by Directed Mutagenesis IN VIVO AND IN VITRO ANALYSES

Ferrochelatase is a mitochondrial inner membrane-bound enzyme that catalyzes the insertion of ferrous iron into protoporphyrin, the terminal step in protoheme biosynthesis. The functional/structural roles of 10 invariant amino acid residues were investigated by site-directed mutagenesis in the yeast Saccharomyces cerevisiae ferrochelatase. The mutant enzymes were expressed in a yeast strain lacking the ferrochelatase gene HEM15 and in Escherichia coli. The kinetic parameters of the mutant enzymes were determined for the enzymes associated with the yeast membranes and the enzymes in the bacterial soluble fraction. They were compared with the in vivo functioning of the mutant enzymes. The main conclusions are the following. Glu-314 is critical for catalysis, and we suggest that it is the base responsible for abstracting the N-pyrrole proton(s). His-235 is essential for metal binding. Asp-246 and Tyr-248 are also involved in metal binding in a synergistic manner. The K for protoporphyrin was also increased in the H235L, D246A, and Y248L mutants, suggesting that the binding sites of the two substrates are not independent of each other. The R87A, Y95L, Q111E, Q273E, W282L, and F308A mutants had 1.2-2-fold increased V and 4-10-fold increased K values for protoporphyrin, but the amount of heme made in vivo was 10-100% of the normal value. These mutations probably affected the geometry of the active center, resulting in improper positioning of protoporphyrin.

Changes in the activities of the protoheme-synthesizing system during the growth of yeast under different conditions☆

Abstract The levels of some enzymatic activities involved in protoheme synthesis have been measured in subcellular fractions obtained at different stages of the growth of the yeast Saccharomyces cerevisiae grown anaerobically and aerobically with glucose (50 or 6 g/ liter), and ethanol (20 g/liter) as the carbon source. The degree of repression of the respiratory system is estimated by the respiratory capacity of whole cells, by the activities of succinate-cytochrome c reductase and cytochrome c oxidase of the mitochondrial particles, and by the cytochrome spectra. The results show that (i) the more porphyrins (cytochromes) that are synthesized by the cells, the lower is the specific activity of δ-aminolevulinic acid (ALA) synthetase and the higher is the specific activity of ALA dehydratase, the activity ratio ALA synthetase/ALA dehydratase decreasing at least 10-fold compared to the repressed cells; (ii) the amount of intracellular ALA found under all conditions tested (from 0.05 to 1.5 m m in the cell sap) correlates well with the measured ALA synthetase activity; its presence argues against a rate-limiting function for ALA synthetase and rather favors such a role for the ALA dehydratase in the formation of heme in yeast; (iii) the rate of porphyrin synthesis measured in vitro is higher in the case of cells with high cytochrome contents; and (iv) the specific activities of succinyl CoA synthetase and protoheme ferrolyase are always present in nonlimiting amounts. Some experiments are described showing that the values of the activities which are calculated from these in situ and in vivo experiments compare well with the values measured in vitro in the acellular extracts. The results concerning the enzymatic activities, together with (i) the excretion of coproporphyrin(ogen) and the accumulation of protoporphyrin + Zn-protoporphyrin in anaerobiosis, (ii) the presence of protoporpho(di)methene (P503) in anaerobic and repressed cells, and (iii) the presence of intracellular ALA under all growth conditions, are discussed in terms of possible control(s) of heme synthesis in yeast.

CYP1 (HAP1) is a determinant effector of alternative expression of heme-dependent transcription in yeast

SummaryThe 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° 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.

Characterization of an Upstream Activation Sequence and Two Rox1p-responsive Sites Controlling the Induction of the Yeast HEM13 Gene by Oxygen and Heme Deficiency*

The Saccharomyces cerevisiae HEM13 gene codes for coproporphyrinogen oxidase, an oxygen-requiring enzyme catalyzing the sixth step of heme biosynthesis. Its transcription has been shown to be induced 40-50-fold in response to oxygen or heme deficiency, in part through relief of repression exerted by Rox1p and in part by activation mediated by an upstream activation sequence (UAS). This report describes an analysis of HEM13 UAS and of the Rox1p-responsive sites by electrophoretic mobility shift assays, DNase I footprinting, and mutational mapping. HEM13 UAS is composed of two subelements: a 16-base pair sequence binding a constitutive factor acting as a transcriptional activator, and a 5′-flanking 20-base pair GC-rich region. Both subelements were required additively for transcription, but each element alone was sufficient for almost normal control by oxygen/heme deficiency. Mutations in both elements decreased the induction ratio 3-4-fold. HEM13 UAS conferred a 2-4-fold oxygen/heme control on a heterologous reporter gene. Two Rox1p-responsive sites, R1 and R3, were identified, which accounted for the 6-7-fold repression by Rox1p. A factor bound to a sequence close to site R3. This DNA-binding activity was only detected in protein extracts of aerobic heme-sufficient ROX1 TUP1 cells, suggesting a possible role in site R3 function.

Positive and negative elements involved in the differential regulation by heme and oxygen of the HEM13 gene (coproporphyrinogen oxidase) in Saccharomyces cerevisiae.

The Saccharomyces cerevisiae HEM13 gene codes for coproporphyrinogen oxidase (CPO), an oxygen-requiring enzyme catalysing the sixth step of heme biosynthesis. Its transcription is increased 40–50-fold in response to oxygen- or heme-deficiency. We have analyzed CPO activity and HEM13 mRNA levels in a set of isogenic strains carrying single or double deletions of the CYP1 (HAP1), ROX1, SSN6, or TUPI genes. The cells were grown in the presence or absence of oxygen and under heme-deficiency (hem1Δ background). Both Rox1p and Cyp1p partially repressed HEM13 in aerobic heme-sufficient cells, probably in an independent manner. In the absence of heme, Cyp1p activated HEM13 and strongly repressed ROX1, allowing de-repression of HEM13. Cyp1p had no effect on HEM13 expression in anaerobic cells. Deletions of SSN6 or TUP1 dramatically de-repressed HEM13 in aerobic cells. A series of deletions in the HEM13 promoter identified at least four regulatory regions that are required for HEM13 regulation. Two regions, containing motifs similar to the Rox1p consensus sequences, act as repression sites under aerobic growth. The two other sites act as activation sequences required for full induction under oxygen- or heme-deficiency. Taken together, these results suggest that induction of HEM13 occurs in part through relief of repression exerted by Rox1p and Cyp1p, and in part by activation mediated partly by Cyp1p under heme-deficiency and by unknown factors under oxygen-deficiency.

Cloning by genetic complementation and restriction mapping of the yeast HEM1 gene coding for 5-aminolevulinate synthase

SummaryWe have cloned the structural gene HEM1 for 5-aminolevulinate (ALA) synthase from Saccharomyces cerevisiae by transformation and complementation of a yeast hem1–5 mutant which was previously shown to lack ALA synthase activity (Urban-Grimal and Labbe Bois 1981) and had no immunodetectable ALA synthase protein when tested with yeast ALA synthase antiserum. The gene was selected from a recombinant cosmid pool which contained wild-type yeast genomic DNA fragments of an average size of 40 kb. The cloned gene was identified by the restauration.of growth on a non fermentable carbon source without addition of exogenous ALA. Sub cloning of partial Sau3A digests and functional analysis by transformation allowed us to isolate three independent plasmids, each carrying a 6 kb yeast DNA fragment inserted in either orientation into the single BamHI site of the vector pHCG3 and able to complement hem1–5 mutation. Analysis of the three plasmids by restriction endonucleases showed that HEM1 is contained within a 2.9 kb fragment. The three corresponding yeast trans formants present a 1, 2.5 and 16 fold increase in ALA synthase activity as compared to the wild-type strain. The gene product immunodetected in the transformant yeast cells has identical size as the wild-type yeast ALA synthase and its amount correlates well with the increase in ALA synthase activity.

Analysis of heme biosynthesis in catalase and cytochrome deficient yeast mutants.

SummaryMutants of Saccharomyces cerevisiae, described as catalase and cytochromes deficient (Pachecka et al., 1974), have been analyzed for heme biosynthesis ability. Some enzymatic activities involved in protoheme synthesis were measured in acellular extracts, whereas whole cells were analyzed for cytochrome spectra and for possible accumulation of porphyrin synthesis intermediates. A good correlation was found between these in vitro and in vivo studies. Results show that two mutants were impaired in 5-aminolevulinate synthesis, two mutants were devoid of uroporphyrinogen I synthetase activity and one mutant presented defects in coproporphyrinogen III oxidase activity.

Synthèse du protohème par la levure Saccharomyces cerevisiae: II. Influence exercée par le glucose sur l'adaptation respiratoire

Summary The addition of glucose, in presence of oxygen, to resting cells from Saccharomyces cerevisiae anaerobically grown with glucose as carbon source, is followed by: — cytochrome a + a3, b, c1 and c synthesis and cytochrome c oxidase and succinate cytochrome c reductase activities (respiratory adaptation) ; the speed of these syntheses depends on initial glucose concentration in the adaptation medium (« contre effet Pasteur ) : the less glucose, the faster is the adaptation (Slonimski [4]) ; — the rapid disappearance of δALA synthetase (less than 1 hour) which is not recovered for 9 hours at 25°; however, the presence of large quantities of free δALA at the beginning of the respiratory adaptation explains respiratory chain linked cytochrome formation ; — the fast disappearance of one (or more) enzyme(s) of the protohaem synthesis chain located between porphobilinogen and protoporphyrin ; the lost enzyme, which could be the enzymic complex PBG desaminase-uroporphyrinogen III cosynthetase is synthesized de novo when glucose has disappeared from the respiratory adaptation medium. The mechanism of these enzymic activities disappearances does not seem to depend on inhibitory protein(s) synthesis induced by glucose. The same phenomena are observed when yeast resting cells are incubated with glucose in the absence of oxygen. Similar results are obtained with resting cells from aerobically grown yeast with glucose as carbon source. However, for anaerobically grown yeast with glactose as carbon source, the respiratory adaptation of which is very fast, glucose addition does not induce the disappearance of porphobilinogen → protoporphyrin : δALA synthetase disappears even in the absence of glucose. These results are discussed in correlation with yeast respiratory adaptation ; particularly, glycogen metabolism (formation and degradation) by yeast resting cells during respiratory adaptation (involving changes of glycolytic metabolite intracellular concentration) could play an important role with the onset of « contre effet Pasteurand consequently with cytochrome formation at the level of haem formation.

Isolation and characterization of extragenic mutations affecting the expression of the uroporphyrinogen decarboxylase gene (HEM12) in Sacharomyces cerevisiae

Uroporphyrinogen decarboxylase (Uro-d; EC 4.1.1.37), the fifth enzyme in the heme biosynthetic pathway, which catalyzes the sequential decarboxylation of uroporphyrinogen to coproporphyrinogen, is encoded by the HEM12 gene in Saccharomyces cerevisiae. The HEM12 gene is transcribed into a major short mRNA and a minor longer one, approximately 1.35 and 1.55 kb, respectively, in size, and that differ in the 5′ untranslated region. “Uroporphyric” mutants, which have no mutations in the HEM12 gene but accumulate uroporphyrinogen, a phenotype chracteristic of partial Uro-d deficiency, were investigated. Genetic analysis showed that the mutant phenotype depends on the combined action of two unlinked mutations, udt1 and either ipa1, ipa2, or ipa3. ipa1 is tightly linked to HEM12 The mutation udt1 apparently acts specifically on the HEM12 gene, and causes a six to tenfold decrease in the levels of the short HEM12 mRNA, in the β-galactosidase activity of a HEM12-lacZ fusion, in immunodetectable protein and enzyme activity. But heme synthesis is normal and porphyrin accumulation was modest. The mutations ipa1, ipa2, and ipa3 had no phenotype on their own, but they caused an increase in porphyrin accumulation in a udt1 background. This multiplicity of genetic factors leading to uroporphyric yeast cells closely resembles the situation in human porphyria cutanea tarda.