Transcript analysis of 203 novel genes from Saccharomyces cerevisiae in hap1 and rox1 mutant backgrounds.

Hap1 and Rox1 are transcriptional regulators that bind regulatory sites in the promoters of oxygen-regulated genes in Saccharomyces cerevisiae. Hap1 is a heme-responsive activator of genes induced in aerobic conditions and Rox1 is a repressor of hypoxic genes in aerobic conditions. We have studied transcriptional regulation of a pool of 203 open reading frames (ORFs) from chromosomes IV, VII, and XIV in wild-type, hap1, and rox1 mutant genetic backgrounds in an attempt to extend the family of oxygen and heme regulated genes. Only three ORFs are significantly repressed by Rox1 but they cannot be considered as typical hypoxic genes because they are not overexpressed during hypoxia.

Disruption of six novel Saccharomyces cerevisiae genes reveals that YGL129c is necessary for growth in non-fermentable carbon sources, YGL128c for growth at low or high temperatures and YGL125w is implicated in the biosynthesis of methionine.

Six open reading frames (ORFs) from chromosome, VII, YGL131c, YGL129c, YGL128c, YGL125w, YGL124c and YGL121c, were disrupted by deletion cassettes with short flanking regions homologous to the target locus (SFH). YGL129c is necessary for growth in non-fermentable carbon sources, YGL128c for growth at low or high temperatures and YGL125w is implicated in the biosynthesis of methionine. With regard to the other ORFs, basic phenotypic analyses did not reveal any significant clues about their function.

Approaches to the study of Rox1 repression of the hypoxic genes in the yeast Saccharomyces cerevisiae.

The yeast Saccharomyces cerevisiae is a facultative aerobe that responds to changes in oxygen tension by changing patterns of gene expression. One set of genes that responds to this environmental cue is the hypoxic genes. Oxygen levels are sensed by changes in heme biosynthesis, which controls the transcription of the ROX1 gene, encoding a protein that binds to the regulatory region of each hypoxic gene to repress transcription. Several experimental molecular and genetic approaches are described here to study Rox1 repression. Derepression of the hypoxic genes is rapid, and one model for such a response requires that Rox1 have a short half-life. This was demonstrated to be the case by immunoblotting using a c-myc epitope-tagged protein. Rox1 repression is mediated through the general repressors Ssn6 and Tup1. To explore possible interactions among these proteins, all three were expressed and partially purified using a baculovirus expression system and histidine-tagged proteins. The effect of Ssn6 and Tup1 on the formation of Rox1-DNA complexes was explored using these purified proteins by both electrophoretic mobility shift and DNase I protection assays. We found that Rox1 DNA-binding activity decayed rapidly and that Ssn6 could stabilize and restore lost activity. Finally, genetic selections are described for the isolation of loss-of-function mutations in Rox1. Also, schemes are proposed for the reversion of such mutations. These selections have been extended to genetic analyses of the TUP1 and SSN6 genes.

PICDI, a simple program for codon bias calculation.

PICDI is a very simple program designed to calculate the Intrinsic Codon Deviation Index (ICDI). The program is available in Macintosh as well a PC format. Requirements for correct input of the sequences have been kept to a minimum and the analysis of sequences up to 2000 codons is very quick. The ICDI is very useful for estimation of codon bias of genes from species in which optimal codons are not known. The availability of a computer program for its calculation will increase its usefulness in the fields of Molecular Biology and Biotechnology.

Rox3 and Rts1 function in the global stress response pathway in baker's yeast.

Yeast respond to a variety of stresses through a global stress response that is mediated by a number of signal transduction pathways and the cis-acting STRE DNA sequence. The CYC7 gene, encoding iso-2-cytochrome c, has been demonstrated to respond to heat shock, glucose starvation, approach-to-stationary phase, and, as we demonstrate here, to osmotic stress. This response was delayed in a the hog1-delta 1 strain implicating the Hog1 mitogen-activated protein kinase cascade, a known component of the global stress response. Deletion analysis of the CYC7 regulatory region suggested that three STRE elements were each capable of inducing the stress response. Mutations in the ROX3 gene prevented CYC7 RNA accumulation during heat shock and osmotic stress. ROX3 RNA levels were shown to be induced by stress through a novel regulatory element. A selection for high-copy suppressors of a ROX3 temperature-sensitive allele resulted in the isolation of RTS1, encoding a protein with homology to the B' regulatory subunit of protein phosphatase 2A0. Deletion of RTS1 caused temperature and osmotic sensitivity and increased accumulation of CYC7 RNA under all conditions. Over-expression of this gene caused increased CYC7 RNA accumulation in rox3 mutants but not in wild-type cells.

Sequence analysis of a 10 kb DNA fragment from yeast chromosome VII reveals a novel member of the DnaJ family.

We report the sequence analysis of a 10 kb DNA fragment of Saccharomyces cerevisiae chromosome VII. This sequence contains four complete open reading frames (ORFs) of greater than 100 amino acids. There are also two incomplete ORFs flanking the extremes: one of these, G2868, is the 5' part of the SCS3 gene (Hosaka et al., 1994). ORFs G2853 and G2856 correspond to the genes CEG1, coding for the alfa subunit of the mRNA guanylyl transferase and a 3' gene of unknown function previously sequenced (Shibagaki et al., 1992). G2864 is identical to SOH1 also reported (Fan and Klein, 1994).

Mutational analysis of Rox1, a DNA-bending repressor of hypoxic genes in Saccharomyces cerevisiae.

Rox1 is a repressor of the hypoxic genes of Saccharomyces cerevisiae. It binds to a specific hypoxic consensus sequence in the upstream region of these genes and represses transcription in conjunction with the general repression complex Tup1-Ssn6. In this study, we demonstrated that the first 100 amino acids comprising the HMG domain of Rox1 were responsible for DNA binding and that when bound, Rox1 bent DNA at an angle of 90 degrees. A mutational analysis resulted in the isolation of seven missense mutations, all located within the HMG domain, that caused loss of DNA binding. The effect of these mutations on the structure of Rox1 was evaluated on the basis of the homology between Rox1 and the human male sex-determining protein SRY, for which a structural model is available. The failure to isolate missense mutations in the carboxy-terminal three-quarters of the protein prompted a deletion analysis of this region. The results suggested that this region was responsible for the repression function of Rox1 and that the repression information was redundant. This hypothesis was confirmed by using a set of fusions between sequences encoding the GAL4 DNA-binding domain and portions of ROX1. Those fusions containing either the entire carboxy-terminal region or either half of it were capable of repression. Repression by selected fusions was demonstrated to be dependent on Ssn6.

Yeast phylogenetic relationships based on cytochrome c sequences.

The availability of the KICYC1 sequence was used to establish homologies with other cytochrome c genes from yeasts and the fungus Neurospora crassa. In terms of nucleotide composition, the cytochrome c gene from Kluyveromyces lactis showed a higher homology with Schwanniomyces occidentalis than with Saccharomyces cerevisiae, and this point is discussed in regard to the differences found in the codon usage of these yeasts. The deduced amino acidic composition of the protein facilitated comparison of its sequence with other cytochrome c protein sequences and new assignments of phylogenetic relationships. In this context Kluyveromyces lactis was most closely related to Candida krusei.

Codon usage in Kluyveromyces lactis and in yeast cytochrome c-encoding genes.

Codon usage (CU) in Kluyveromyces lactis has been studied. Comparison of CU in highly and lowly expressed genes reveals the existence of 21 optimal codons; 18 of them are also optimal in other yeasts like Saccharomyces cerevisiae or Candida albicans. Codon bias index (CBI) values have been recalculated with reference to the assignment of optimal codons in K. lactis and compared to those previously reported in the literature taking as reference the optimal codons from S. cerevisiae. A new index, the intrinsic codon deviation index (ICDI), is proposed to estimate codon bias of genes from species in which optimal codons are not known; its correlation with other index values, like CBI or effective number of codons (Nc), is high. A comparative analysis of CU in six cytochrome-c-encoding genes (CYC) from five yeasts is also presented and the differences found in the codon bias of these genes are discussed in relation to the metabolic type to which the corresponding yeasts belong. Codon bias in the CYC from K. lactis and S. cerevisiae is correlated to mRNA levels.

Sequence of a cytochrome c gene from Kluyveromyces lactis and its upstream region.

The complete sequence of a cytochrome c gene from Kluyveromyces lactis including its upstream region is reported. Sequence of the translated open reading frame is discussed in terms of cytochrome c structural requirements. Putative regulatory signals in the upstream region are described and compared with reported sequences which modulate the expression of respiratory-related yeast genes.

[Characterization of an inhibitor of glucose-6-phosphate dehydrogenase]. / Caracterización de un inhibidor de la G6PDH.

A strong inhibitor of G6PDH has been detected in rat liver homogenates. The inhibitor, isolated by ultrafiltration methods, proved to be very stable under incubation with trypsin and high temperatures. Gel-filtration through Sephadex G-75 showed it to have a molecular weight of 3,500 daltons, though perchloric acid treatment produced a light form of 900 daltons. Both forms of inhibitor act as competitive inhibitor with respect to G6P and exhibit non-competitive inhibition pattern with respect to NADP+. Physical and kinetic properties, and the increase of G6PDH activity at low NADP+ concentrations, in the presence of NADPH and inhibitor or palmitoyl-CoA, in relation to the G6PDH activity in presence of NADPH, lead to the identification of the low-molecular weight inhibitor as palmitoyl-CoA.