Cloning of the GSH1 and GSH2 genes complementing the defective biosynthesis of glutathione in the methylotrophic yeast Hansenula polymorpha

The cloning of 7.2- and 9.6-kbp fragments of the methylotrophic yeast Hansenula polymorpha DNA restored the wild-type phenotype Gsh+ in the glutathione-dependent gsh1 and gsh2 mutants of this yeast defective in glutathione (GSH) synthesis because of a failure of the gamma-glutamylcysteine synthetase reaction. The 9.6-kbp DNA fragment was found to contain a 4.3-kbp subfragment, which complemented the Gsh- phenotype of the gsh2 mutant. The Gsh+ transformants of the gsh1 and gsh2 mutants, which bear plasmids pG1 and pG24 with the 7.2- and 4.3-kbp DNA fragments, respectively, had a completely restored wild-type phenotype with the ability to synthesize GSH and to grow in GSH-deficient synthetic media on various carbon sources, including methanol, and with acquired tolerance to cadmium ions. In addition, the 4.3-kbp DNA fragment borne by plasmid pG24 eliminated pleiotropic changes in the gsh2 mutants associated with methylotrophic growth in a semisynthetic (GSH-supplemented) medium (poor growth and alterations in the activity of the GSH-catabolizing enzyme gamma-glutamyltransferase and the methanol-oxidizing enzyme alcohol oxidase).     

Glutathione production by Escherichia coli cells with hybrid plasmid containing tandemly polymerized genes for glutathione synthetase

Summary A DNA fragment containing the structural and promoter regions of glutathione synthetase (GSH II) gene (gsh II) from Escherichia coli B were polymerized. The dimeric and trimeric DNA fragments obtained were inserted into Bam HI site of vector plasmid pBR325 and the resulting hybrid plasmids were designated pGS401-02 and pGS401-03, respectively. The GSH II activity of E. coli cells with these hybrid plasmids increased depending on the number of the genes (gsh II) contained. To construct hybrid plasmids useful for glutathione production, another DNA fragment with a gene (gsh I) for -glutamylcysteine synthetase (GSH I) from E. coli B was inserted into Pst I sites of pGS401-02 and pGS401-03 and the hybrid plasmids obtained (pGS501-12 and pGS501-13, respectively) were introduced into E. coli B cells. Although the glutathione-producing activities of the cells with these plasmids were little improved as compared with that of cells with the hybrid plasmid (pGS501-11) containing both gsh I and gsh II because of the low activity of GSH I, our method has brought to light a new type of gene amplification.     

Restricting glutathione biosynthesis to the cytosol is sufficient for normal plant development

Glutathione (GSH) homeostasis in plants is essential for cellular redox control and efficient responses to abiotic and biotic stress. Compartmentation of the GSH biosynthetic pathway is a unique feature of plants. The first enzyme, γ-glutamate cysteine ligase (GSH1), responsible for synthesis of γ-glutamylcysteine (γ-EC), is, in Arabidopsis, exclusively located in the plastids, whereas the second enzyme, glutathione synthetase (GSH2), is located in both plastids and cytosol. In Arabidopsis, gsh2 insertion mutants have a seedling lethal phenotype in contrast to the embryo lethal phenotype of gsh1 null mutants. This difference in phenotype may be due to partial replacement of GSH functions by γ-EC, which in gsh2 mutants hyperaccumulates to levels 5000-fold that in the wild type and 200-fold wild-type levels of GSH. In situ labelling of thiols with bimane and confocal imaging in combination with HPLC analysis showed high concentrations of γ-EC in the cytosol. Feedback inhibition of Brassica juncea plastidic GSH1 by γ-EC in vitro strongly suggests export of γ-EC as functional explanation for hyperaccumulation. Complementation of gsh2 mutants with the cytosol-specific GSH2 gave rise to phenotypically wild-type transgenic plants. These results support the conclusion that cytosolic synthesis of GSH is sufficient for plant growth. The transgenic lines further show that, consistent with the exclusive plastidic localization of GSH1, γ-EC is exported from the plastids to supply the cytosol with the immediate precursor for GSH biosynthesis, and that there can be efficient re-import of GSH into the plastids to allow effective control of GSH biosynthesis through feedback inhibition of GSH1.     

Accumulation of cadmium ions in the methylotrophic yeast Hansenula polymorpha

Intracellular cadmium (Cd²⁺) ion accumulation and the ability to produce specific Cd²⁺ ion chelators was studied in the methylotrophic yeast Hansenula polymorpha. Only one type of Cd²⁺ intracellular chelators, glutathione (GSH), was identified, which suggests that sequestration of this heavy metal in H. polymorpha occurs similarly to that found in Saccharomyces cerevisiae, but different to Schizosaccharomys pombe and Candida glabrata which both synthesize phytochelatins. Cd²⁺ ion uptake in the H. polymorpha wild-type strains appeared to be an energy dependent process. It was found that Δgsh2 mutants, impaired in the first step of GSH biosynthesis, are characterized by increase in net Cd²⁺ ion uptake by the cells, whereas Δgsh1/Δmet1 and Δggt1 mutants impaired in sulfate assimilation and GSH catabolism, respectively, lost the ability to accumulate Cd²⁺ intracellularly. Apparently H. polymorpha, similarly to S. cerevisiae, forms a Cd-GSH complex in the cytoplasm, which in turn regulates Cd²⁺ uptake. Genes GSH1/MET1 and GGT1 are involved in maturation and metabolism of cellular Cd-GSH complex, respectively. Transport of [³H]N-ethylmaleimide-S-glutathione ([³H]NEM-SG) conjugate into crude membrane vesicules, purified from the wild-type cells of H. polymorpha appeared to be MgATP dependent, uncoupler insensitive and vanadate sensitive. We suggest that MgATP dependent transporter involved in Cd-GSH uptake in H. polymorpha, is similar to S. cerevisiae Ycf1-mediated vacuolar transporter responsible for accumulation of organic GS-conjugates and Cd-GSH complex.     

Glutathione Deficiency Leads to Riboflavin Oversynthesis in the Yeast Pichia guilliermondii

The Pichia guilliermondii GSH1 and GSH2 genes encoding Saccharomyces cerevisiae homologues of glutathione (GSH) biosynthesis enzymes, γ-glutamylcysteine synthetase and glutathione synthetase, respectively, were cloned and deleted. Constructed P. guilliermondii Δgsh1 and Δgsh2 mutants were GSH auxotrophs, displayed significantly decreased cellular GSH+GSSG levels and sensitivity to tert-butyl hydroperoxide, hydrogen peroxide, and cadmium ions. In GSH-deficient synthetic medium, growths of Δgsh1 and Δgsh2 mutants were limited to 3–4 and 5–6 cell divisions, respectively. Under these conditions Δgsh1 and Δgsh2 mutants possessed 365 and 148 times elevated riboflavin production, 10.7 and 2.3 times increased cellular iron content, as well as 6.8 and 1.4 fold increased ferrireductase activity, respectively, compared to the wild-type strain. Glutathione addition to the growth medium completely restored the growth of both mutants and decreased riboflavin production, cellular iron content, and ferrireductase activity to the level of the parental strain. Cysteine also partially restored the growth of the Δgsh2 mutants, while methionine or dithiothreitol could not restore the growth neither of the Δgsh1, nor of the Δgsh2 mutants. Besides, it was shown that in GSH presence riboflavin production by both Δgsh1 and Δgsh2 mutants, similarly to that of the wild-type strain, depended on iron concentration in the growth medium. Furthermore, in GSH-deficient synthetic medium P. guilliermondii Δgsh2 mutant cells, despite iron overload, behaved like iron-deprived wild-type cells. Thus, in P. guilliermondii yeast, glutathione is required for proper regulation of both riboflavin and iron metabolism.     

Cloning and functional analysis of the GSH1/MET1 gene complementing cysteine and glutathione auxotrophy of the methylotrophic yeast Hansenula polymorpha

The Hansenula polymorpha GSH1/MET1 gene was cloned by complementation of glutathione-dependent growth of H. polymorpha gsh1 mutant isolated previously as N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) resistant and cadmium ion sensitive clone. The H. polymorpha GSH1 gene was capable of restoring cadmium ion resistance, MNNG sensitivity, normal glutathione level and cell proliferation on minimal media without addition of cysteine or glutathione, when introduced into the gsh1 mutant cells. It was shown that the H. polymorpha GSH1 gene has homology to the Saccharomyces cerevisiae MET1 gene encoding S-adenosyl-L-methionine uroporphyrinogen III transmethylase, responsible for the biosynthesis of sulfite reductase cofactor, sirohaem. The H. polymorpha GSH1/MET1 gene deletion cassette (Hpgsh1/met1::ScLEU2) was constructed and corresponding null mutants were isolated. Crossing data of the point gsh1 and null gsh1/met1 mutants demonstrated that both alleles were located to the same gene. The null gsh1/met1 mutant showed total growth restoration on minimal media supplemented with cysteine or glutathione as a sole sulfur source, but not with inorganic (sulfate, sulfite) or organic (methionine, S-adenosylmethionine) sources of sulfur. Moreover, both the point gsh1 and null gsh1/met1 mutants displayed increased sensitivity to the toxic carbon substrate methanol, formaldehyde, organic peroxide and cadmium ions.     

GSH2, a gene encoding gamma-glutamylcysteine synthetase in the methylotrophic yeast Hansenula polymorpha

The GSH2 gene, encoding Hansenula polymorpha gamma-glutamylcysteine synthetase, was cloned by functional complementation of a glutathione (GSH)-deficient gsh2 mutant of H. polymorpha. The gene was isolated as a 4.3-kb XbaI fragment that was capable of restoring GSH synthesis, heavy-metal resistance and cell proliferation when introduced into gsh2 mutant cells. It possesses 53% identical and 69% similar amino acids compared with the Candida albicans homologue (Gcs1p). In comparison to the Saccharomyces cerevisiae homologue (Gsh1p), it possesses 47% identical and 61% similar amino acids. The GSH2 sequence appears in the GenBank database under accession No. AF435121.     

Role of Glutathione in the Response of Escherichia coli to Osmotic Stress

The growth of Escherichia coli mutants deficient in glutathione synthesis (gshA) and in glutathione reductase (gor) was suppressed in medium of elevated osmolarity. A mutant in -glutamyl transpeptidase (ggt) displayed better ability for osmoadaptation than the parental strain. The unfavorable effect of the gsh mutation on osmoadaptation of growing E. coli cells was more pronounced at low concentrations of K⁺ in the medium. An increase in osmolarity caused an increase in the intracellular content of glutathione. Changes in the extracellular glutathione level were biphasic: the glutathione level rapidly decreased during the first stage of the response and increased during the second stage. The changes in glutathione levels suggest that under hyperosmotic shock the glutathione transport from the medium into the cell can contribute to the intracellular glutathione accumulation. Changes in the level of intracellular K⁺ were similarly biphasic: a rapid increase in the K⁺ level during the first stage of the response to hyperosmotic shock changed to a gradual decrease during the second stage. In mutant gshA cells adapted to osmotic shock, the intracellular K⁺ level was markedly higher than in the parental strain cells. The possible role of glutathione in the response of E. coli to osmotic shock is discussed.     

Growth conditions of F9 embryonal carcinoma cells affect the degree of DNA methylation

We have investigated differences in C^*pG methylation between F9 embryonal carcinoma cellsin vitro and as tumor cells grownin vivo usingMsp I andHpa II restriction isoschizomers. Southerns were hybridized with two low copy number probes, mouse major -globin (f7) and a class I, histocompatibility-2 cDNA clone (pH-2^d-4). In each case, the tumor-DNA was hypomethylated while the DNA from F9 cells grownin vitro was moderately methylated. We conclude that growth conditions or cell-cell interactions can greatly affect methylation of C^*pG sites.     

Development of glutathione-deficient embryos in Arabidopsis is influenced by the maternal level of glutathione

Glutathione (GSH) biosynthesis-deficient gsh1 and gsh2 null mutants of Arabidopsis thaliana have late embryonic-lethal and early seedling-lethal phenotypes, respectively, when segregating from a phenotypically wild-type parent plant, indicating that GSH is required for seed maturation and during germination. In this study, we show that gsh2 embryos generated in a partially GSH-deficient parent plant, homozygous for either the cad2 mutation in the GSH1 gene or homozygous for mutations in CLT1, CLT2 and CLT3 encoding plastid thiol transporters, abort early in embryogenesis. In contrast, individuals homozygous for the same combinations of mutations but segregating from heterozygous, phenotypically wild-type parents exhibit the parental gsh2 seedling-lethal phenotype. Similarly, homozygous gsh1 embryos generated in a gsh1/cad2 partially GSH-deficient parent plant abort early in development. These observations indicate that the development of gsh1 and gsh2 embryos to a late stage is dependent on the level of GSH in the maternal plant.     

Effect of an Insertional Mutation in the cspA Gene Encoding the Major Cold-Shock Protein on Radiation Resistance of Escherichia coli

Plasmid pCspA::Km carrying a cloned mutant allele of the cspA gene for the major Escherichia coli cold-shock protein CspA with an insertion of the kanamycin resistance gene cassette from transposon Tn903 into the core region of the coding sequence causes a 2.3-fold increase in radioresistance of wild-type E. coli cells (cspA ⁺). The radiation protective effect of this plasmid is abolished or drastically reduced in mutants recA13and rpoH15defective in RecA protein and in induction of the heat-shock protein regulon, respectively. Plasmid pCspA::Km causes a 1.3-fold elevation in the resistance to -irradiation of E. coli mutants with an intermediate level of radiation resistance (Gam^r445 and KS0160) but slightly diminishes resistance of a highly radiation-resistant Gam^r444 mutant. In the chromosome of E. coli strain with normal DNA repair systems, the cspA::Km mutation in the homozygous state enhances resistance to the lethal effect of -rays and UV light 2.9 and 1.4 times, respectively. These data suggest that the system of cold-shock proteins can modulate resistance of E. colicells to the lethal effect of -rays and UV light.     

Comparative analysis of the two-step reaction catalyzed by prokaryotic and eukaryotic phytochelatin synthase by an ion-pair liquid chromatography assay

Genes encoding phytochelatin (PC) synthase have been found in higher plants, fission yeast and worm. Recently, kinetic and mutagenic analyses of recombinant PC synthase have been revealing the molecular mechanisms underlying PC synthesis, however, a conclusive model has not been established. To clarify the mechanism of PC synthase found in eukaryotes, we have compared the two-step reactions catalyzed by the prokaryotic Nostoc PC synthase (NsPCS) and the eukaryotic Arabidopsis PC synthase (AtPCS1). Comparative analysis shows that in the first step of PC synthesis corresponding to the cleavage of -glutamylcysteine (-EC) from glutathione (GSH), free GSH or PCs acts as a donor molecule to supply a -EC unit for elongation of the PC chain, and heavy metal ions are required to carry out the cleavage. Furthermore, functional analyses of various mutants of NsPCS and AtPCS1, selected by comparing the sequences of NsPCS and AtPCS1, indicate that the N-terminal region (residues 1–221) in AtPCS1 is the catalytic domain, and in this region, the Cys⁵⁶ residue is associated with the PC synthesis reaction. These results enable us to propose an advanced model of PC synthesis, describing substrate specificity, heavy metal requirement, and the active site in the enzyme.     

Genetic and physical studies of restriction-deficient mutants of the Inc FIV plasmids R124 and R124/3

Summary R124 and R124/3 are R plasmids that carry the genes for two different restriction and modification systems. The phenotype of strains carrying either of these plasmids along with the F'lac ⁺ plasmid, is restriction-deficient (Res^-). The Res^- phenotype is not due to selection of preexisting mutants but rather to a complex mutational event caused by the F plasmid. Restriction-deficient mutants carry extensive deletions and other DNA rearrangements. Tn7 insertion is used to locate the restriction gene. Many of the Res^- mutants are genetically unstable and revert at exceptionally high frequencies. Reversion is accompanied by DNA rearrangements which result in a net gain of 9 kb of DNA. F derivates of F⁺ which do not cause restriction-deficiency but do cause deletion were used to distinguish between the DNA rearrangements associated with restriction-deficiency and those associated with deletion. From Res⁺ revertants of strains carrying F'lac ⁺ and R124 or R124/3 we have isolated F plasmids that now carry the genes for the R124 or R124/3 restriction and modification systems. It is suggested that interaction between part of the F plasmid and that segment of the R plasmid which controls the switch in Res-Mod specificity which has been observed (Glover et al. 1983) is responsible for the production of restriction-deficiency.     

Gradual Drought Under Field Conditions Influences the Glutathione Metabolism,Redox Balance and Energy Supply in Spring Wheat

Glutathione (GSH) metabolism, redox balance and energy supply in spring wheat (Triticum aestivum L.) during gradual drought stress under field conditions were investigated. Although levels of total and reduced GSH were decreased, the ratio of GSH/GSSG (glutathione disulfide) was markedly increased by drought. Levels of GSH biosynthetic precursors, cysteine (Cys) and -glutamylcysteine (-GC), and the activities of their biosynthetic enzymes, -glutamylcysteine synthetase (-GCS) and glutathione synthetase (GSHS) were also significantly increased in stressed plants. Glutathione reductase (GR) activity, which is responsible for the conversion of GSSG to GSH, was also increased under this field stress. However, two other important enzymes in GSH metabolism, glutathione peroxidase (GP) and glutathione S-transferase (GST), showed decreased activity in the droughted plants. These results suggest that the higher ratio of GSH/GSSG, the rate of GSH biosynthesis and the capacity of its redox cycling rather than GSH accumulation might be essential for drought resistance of plants. Activities of the two key Calvin-cycle enzymes possessing exposed sulfhydryl groups, NADP⁺-dependent glyceraldehydes-3-phosphate dehydrogenase (G3PD) and fructose-1,6-bisphosphatase (FBPase) were not affected by drought stress, whereas, activity of the key enzyme in the pentose-phosphate pathway (PPP), 6-phosphogluconate dehydrogenase (6-PGD), increased in the droughted plants. The ratios of NADPH/NADP⁺, NADH/NAD⁺ and ATP/ADP increased in the droughted plants, indicating that an up-regulation of the reduced redox state and the energy supply in the plant cells might be an important physiological strategy for plants responding to drought stress. A simple correlation between the high ratio of GSH/GSSG, the rate of GSH biosynthesis and the redox cycle and the high reduction states of redox status in the plant cells was also observed under field drought.     

The fairytale of the GSSG/GSH redox potential

Background

The term GSSG/GSH redox potential is frequently used to explain redox regulation and other biological processes.

Scope of review

The relevance of the GSSG/GSH redox potential as driving force of biological processes is critically discussed. It is recalled that the concentration ratio of GSSG and GSH reflects little else than a steady state, which overwhelmingly results from fast enzymatic processes utilizing, degrading or regenerating GSH.

Major conclusions

A biological GSSG/GSH redox potential, as calculated by the Nernst equation, is a deduced electrochemical parameter based on direct measurements of GSH and GSSG that are often complicated by poorly substantiated assumptions. It is considered irrelevant to the steering of any biological process. GSH-utilizing enzymes depend on the concentration of GSH, not on [GSH]², as is predicted by the Nernst equation, and are typically not affected by GSSG. Regulatory processes involving oxidants and GSH are considered to make use of mechanistic principles known for thiol peroxidases which catalyze the oxidation of hydroperoxides by GSH by means of an enzyme substitution mechanism involving only bimolecular reaction steps.

General significance

The negligibly small rate constants of related spontaneous reactions as compared with enzyme-catalyzed ones underscore the superiority of kinetic parameters over electrochemical or thermodynamic ones for an in-depth understanding of GSH-dependent biological phenomena. At best, the GSSG/GSH potential might be useful as an analytical tool to disclose disturbances in redox metabolism. This article is part of a Special Issue entitled Cellular Functions of Glutathione.     

The glycerol utilization operon of Streptomyces coelicolor: genetic mapping of gyl mutations and the analysis of cloned gylDNA

Summary Glycerol-3-phosphate dehydrogenase (gylB) mutations (which cause glycerol sensitivity), and presumed gylcerol kinase (gylA) and/or regulatory mutations eliminating both glycerol-3-phosphate dehydrogenase and glcerol kinase activities, map close to the argA locus of Streptomyces coelicolor A3(2). Using the plasmid vector pIJ702 and restriction enzymes Bg/II and SstI, extensively overlapping S. coelicolor DNA fragments of 2.74 kb and 2.84 kb were isolated, either of which could restore the wild-type phenotype to gylB and some gylA mutants. Genetic and biochemical analyses of mutants carrying the cloned gylDNA suggested that a functional gyl promoter had not been cloned, and that restoration of the Gyl⁺ phenotype was achieved by recombination between the cloned and chromosomal gyl DNA sequences. After subcloning parts of this DNA into the phage vector C31 KC400, gene disruption analysis was carried out, which confirmed the absence of the gyl promoter, and indicated that a polycistronic mRNA traverses gylA and then gylB.     

Petite deletion map of the mitochondrial oxi3 region in Saccharomyces cerevisiae.

Summary Fifty eight mitochondrial mutants (p ⁺ mit^- mutants), all deficient in cytochrome oxidase activity and previously assigned to the genetic region oxi3 on the mitochondrial DNA, were mapped by the method of petite deletion mapping.This procedure resulted in the identification of at least twenty one different classes of oxi3 mutants, which could be arranged in a linear order.Moreover, it provided a set of twenty three p ^- petite mutants, each containing a differentially deleted mit DNA segment included in the oxi3 region. The two sets of mutants, p ⁺ oxi3 ^- and p ^- oxi3 ⁺, will be of interest for a further genetic and physical analysis of this mitochondrial DNA segment which spans over about ten thousand base pairs and controls the subunit I of cytochrome oxidase.     

Antibodies to guanylic acid: Fractionation and specificities

Guanylic-acid-specific antibodies were elicited in rabbits) using as immunogen pG linked through 5-phosphate to thyroglobulin. Specificity and affinity of antibodies to nucleotides) nucleosides, DNA, and RNA were studied by their binding to radioactive ligands and competition experiments . Guanylic-acid-specific antibodies do not bind to deoxyguanylic acid and have an average association constant of 10⁷ M^–1 at 4°C Binding of the antibodies to³H-RNA is G-specifiC. The antibodies do not bind to³²P-ssDNA or³²P-dsDNA. The pG-specific antibodies could be separated into different fractions by affinity chromatography. These fractions) though specific to pG) differ in their cross-reactivities to nucleosides and nucleotides.Abbreviations used G guanosine - pG guanosine 5-phosphate (similarly for other nucleotides) - dpG deoxyriboguanosine 5-phosphate - ssDNA single-stranded DNA - dsDNA double-stranded DNA - Tg thyroglobulin - BSA bovine serum albumin - RSA rabbit serum albumin - EDC 1-ethyl-1-3 (3-dimethylisopropyl) carbodiimide - Ac-Lys-NHMe N--acetyl L-lysine N-methylamide - Ac-Lys-(pG)-NHMe pG coupled through the phosphate to the -amino group of Ac-Lys-NHMe - AH-Sepharose-pG aminohexyl-Sepharose-pG - TBS Tris-buffered saline - SLE systemic lupus erythematosus     

Protective Role of Glutathione Synthesis on Radiation-Induced DNA Damage in Rabbit Brain

1. Radiotherapy has attracted increasing interest in recent years. It is known that ionizing radiation induces oxygen radical injury, whereas oxidative stress by the radiation can cause cellular responses to defense cellular injury. In this study, the metabolism of antioxidants in response to ionizing radiation to the brain was studied in the brain using experimental rabbits.2. Ionizing radiation to the hemicerebrum caused an increase in the levels of glutathione (GSH) and the activity of a GSH synthesizing enzyme, -glutamylcysteine synthetase (-GCS), and Cu,Zn-superoxide dismutase (Cu,Zn-SOD). Ionizing radiation also induced DNA-damage estimated by the formation of 8-hydroxydeoxyguanosine. These changes were dependent on the radiation dose.3. Previous intrathecal-administration of buthionine sulfoximine (100 M), a specific inhibitor of -GCS, increased DNA damage by radiation in the radiated hemicerebrum. That of S-methyl GSH, on the other hand, resulted in a significant reduction of DNA damage by radiation.4. These results suggest that synthesis of GSH and Cu,Zn-SOD is responsive to ionizing radiation and this induction of antioxidants may play a role in reducing tissue damage in radiotherapy.