Reporter gene transactivation by human p53 is inhibited in thioredoxin reductase null yeast by a mechanism associated with thioredoxin oxidation and independent of changes in the redox state of glutathione.

Reporter gene transactivation by human p53 is compromised in S. cerevisiae lacking the TRR1 gene encoding thioredoxin reductase. The basis for p53 inhibition was investigated by measuring the redox state of thioredoxin and glutathione in wild-type and Deltatrr1 yeast. The Deltatrr1 mutation affected the redox state of both molecules. About 34% of thioredoxin was in the disulfide form in wild-type yeast and increased to 70% in Deltatrr1 yeast. About 18% of glutathione was in the GSSG form in wild-type yeast and increased to 32% in Deltatrr1 yeast. The Deltatrr1 mutation also resulted in a 2.9-fold increase in total glutathione per mg extract protein. Highcopy expression of the GLR1 gene encoding glutathione reductase in Deltatrr1 yeast restored the GSSG:GSH ratio to wild-type levels, but did not restore p53 activity. Also, p53 activity was shown to be unaffected by a Deltaglr1 mutation, even though the mutation was known to result in glutathione oxidation. In summary, the results show that, although glutathione becomes more oxidized in Deltatrr1 cells, glutathione oxidation is neither sufficient nor necessary for p53 inhibition. The results indicate that p53 activity has a specific requirement for an intact thioredoxin system, rather than a general dependence on the intracellular reducing environment.

A glutathione reductase mutant of yeast accumulates high levels of oxidized glutathione and requires thioredoxin for growth.

A glutathione reductase null mutant of Saccharomyces cerevisiae was isolated in a synthetic lethal genetic screen for mutations which confer a requirement for thioredoxin. Yeast mutants that lack glutathione reductase (glr1 delta) accumulate high levels of oxidized glutathione and have a twofold increase in total glutathione. The disulfide form of glutathione increases 200-fold and represents 63% of the total glutathione in a glr1 delta mutant compared with only 6% in wild type. High levels of oxidized glutathione are also observed in a trx1 delta, trx2 delta double mutant (22% of total), in a glr1 delta, trx1 delta double mutant (71% of total), and in a glr1 delta, trx2 delta double mutant (69% of total). Despite the exceptionally high ratio of oxidized/reduced glutathione, the glr1 delta mutant grows with a normal cell cycle. However, either one of the two thioredoxins is essential for growth. Cells lacking both thioredoxins and glutathione reductase are not viable under aerobic conditions and grow poorly anaerobically. In addition, the glr1 delta mutant shows increased sensitivity to the thiol oxidant diamide. The sensitivity to diamide was suppressed by deletion of the TRX2 gene. The genetic analysis of thioredoxin and glutathione reductase in yeast runs counter to previous studies in Escherichia coli and for the first time links thioredoxin with the redox state of glutathione in vivo.

A redox-dependent function of thioredoxin is necessary to sustain a rapid rate of DNA synthesis in yeast.

DNA replication is impaired in mutants of Saccharomyces cerevisiae which lack the two thioredoxin genes TRX1 and TRX2. Trx1p supports a normal rate of DNA replication only if the active site contains the redox active cysteines. Two mutant forms of Trx1p, one containing a Cys30Ser mutation and a second containing the Cys30Ser mutation in combination with a Cys33Ser mutation, were unable to sustain normal rates of DNA synthesis. The thioredoxin active-site mutants completed a round of replication in 66 min as opposed to 18 min observed for an isogenic wild type culture. Western blot analysis, using antibody generated against purified 6 x His-tagged Trx1p, showed that both mutant forms of Trx1p were present at the same levels as the wild-type protein. Thus the inability of the mutant proteins to promote DNA synthesis is not caused by degradation or poor expression, but rather by the loss of their reductive capacity. The results show that an optimal rate of DNA synthesis requires a redox function of thioredoxin. Since the measured levels of deoxyribonucleotides are normal in the thioredoxin mutants, thioredoxin either participates with ribonucleotide reductase in channeling a small subset of deoxyribonucleotides to sites of replication, or thioredoxin reduces and thereby activates an unidentified component of the replication machinery.

A dosage-dependent suppressor of a temperature-sensitive calmodulin mutant encodes a protein related to the fork head family of DNA-binding proteins.

The cmd1-1 mutation of calmodulin causes temperature-sensitive growth in Saccharomyces cerevisiae. We have isolated a dosage-dependent suppressor of cmd1-1, designated HCM1. Twentyfold overexpression of HCM1 permits strains carrying cmd1-1 to grow at temperatures up to and including 34 degrees C but does not suppress the lethality of either cmd1-1 at higher temperatures or the deletion of CMD1. Thus, overexpression of HCM1 does not bypass the requirement for calmodulin but enhances the ability of the mutant calmodulin to function. HCM1 is not essential for growth, but deletion of HCM1 exacerbates the phenotype of a strain carrying cmd1-1. HCM1 is located on chromosome III, which was recently sequenced. Our results correct errors in the published DNA sequence. The putative polypeptide encoded by HCM1 is 564 amino acids long and has a predicted molecular weight of 63,622. Antisera prepared against Hcm1p detect a protein that is overproduced in yeast strains overexpressing HCM1 and has an apparent molecular mass of 65 kDa. Eighty-six amino acid residues in the N terminus of Hcm1p show 50% identity with a DNA-binding region of the fork head family of DNA-binding proteins. When fused to the DNA-binding domain of Gal4p, residues 139 to 511 of Hcm1p can act as a strong activator of transcription. However, overexpression of HCM1 does not affect the expression of calmodulin. Furthermore, Hcm1p does not bind to calmodulin in a gel overlay assay. Thus, overexpression of HCM1 enhances calmodulin function by an apparently indirect mechanism.

Sponge cell aggregation.

Dissociated sponge cell system has proved to be a useful model to study the process of cell aggregation both on cellular and subcellular level. The purpose of this review is to discuss recent results obtained from experiments with the marine sponge Geodia cydonium. Dissociated cells form functional aggregates during a process which can be sub-divided into three phases: first, formation of small primary aggregates in the presence of Ca2+; second, formation of secondary aggregates in the presence of an aggregation factor and third, reconstitution of a functional system of water-containing channels by rearrangement in the secondary aggregates. On subcellular level a series of macromolecules are known which are involved in the control of aggregation and separation of sponge cells: Aggregation factor, aggregation receptor, anti-aggregation receptor, beta-glucuronidase, beta-glucuronosyltransferase, beta-galactosyltransferase, beta-galactosidase and a lectin. These components might be linked in the following sequence: (a) Activation of the aggregation receptor by its enzymic glucuronylation; (b) Adhesive recognition of the cells, mediated by the aggregation factor and the glucuronylated aggregation receptor; (c) Inactivation of the aggregation receptor by its deglucuronylation with the membrane-associated beta-glucuronidase; (d) Cell separation due to either the loss of the recognition site (glucuronic acid) of the aggregation receptor for the aggregation factor or to an inactivation of the aggregation factor by the anti-aggregation receptor. The activity of the anti-aggregation receptor is most likely controlled by the Geodia lectin. The events leading to cell-cell recognition cause a change in the following metabolic events: Increase of oxygen uptake, decrease of cyclic AMP level, increase of cyclic GMP level and stimulation of programmed syntheses.