0000000000021885

AUTHOR

J. E. Perez-ortin

showing 7 related works from this author

In vivo assembly of chromatin on pBR322 sequences cloned into yeast plasmids

1989

Abstract In order to study the in vivo assembly of chromatin on prokaryotic DNA templates, we have transformed yeast cells with plasmids pAJ50 and pRB58, which contain pBR322 sequences. In both cases nucleosomes are assembled in vivo on pBR322 DNA, although the nucleosomes are not homogeneous in size. To explore whether there is any preference for nucleosome assembly along pBR322 sequences, we have used an indirect end labeling method. The results indicate that most nucleosomes are placed at random on pBR322, although the probability for histone octamers to interact with some short regions is somewhat reduced. These regions coincide with sequences in which the frequency distribution of nucl…

biologyNucleosome assemblyRestriction MappingSaccharomyces cerevisiaeSaccharomyces cerevisiaeTemplates GeneticMolecular cloningbiology.organism_classificationMolecular biologyChromatinNucleosomesChromatinCell biologyBlotting SouthernRestriction mapHistonePlasmidDNA Transposable Elementsbiology.proteinNucleosomeCloning MolecularMolecular BiologyPlasmidsPlasmid
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A new glucose-repressible gene identified from the analysis of chromatin structure in deletion mutants of yeast SUC2 locus.

1991

We have previously shown that some changes occur in the chromatin structure of the 3' flank of the yeast SUC2 gene in going from a repressed to an active state. In an attempt to find out the causes of these changes, we have carried out experiments in which mutant copies of SUC2 locus lacking either 5' or 3' flanks have been analysed for their transcriptional activity and chromatin structure. These experiments allowed us to discard any relationship between SUC2 transcription and chromatin changes within its 3'flank. Sequencing of this flank and mRNA analysis, however, resulted in the location of a putative peroxisomal 3-oxoacyl-CoA thiolase gene (POT1), which is repressible by glucose. The d…

Transcription GeneticSaccharomyces cerevisiaeMutantGenes FungalMolecular Sequence DataBioengineeringLocus (genetics)Saccharomyces cerevisiaeApplied Microbiology and BiotechnologyBiochemistryOpen Reading FramesGene Expression Regulation FungalGeneticsAmino Acid SequenceDNA FungalGeneChIA-PETRegulation of gene expressionGeneticsbiologyBase SequenceNucleic acid sequencebiology.organism_classificationAcetyl-CoA C-AcyltransferaseBlotting NorthernChromatinChromatinGlucoseMutagenesisBiotechnologyPlasmidsYeast (Chichester, England)
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Sequencing analysis of a 4·1 kb subtelomeric region from yeast chromosome IV identifiesHXT15, a new member of the hexose transporter family

1996

The DNA sequence of a 4·1 kb region of Saccharomyces cerevisiae chromosome IV was determined. This region contains a single open reading frame which codes for a member of the hexose transporter family. This new gene has been named HXT15 according to yeast gene data bases. The sequence has been entered in the EMBL data library under Accession Number X92891.

GeneticsbiologyAccession number (library science)Saccharomyces cerevisiaeChromosomeBioengineeringbiology.organism_classificationSubtelomereApplied Microbiology and BiotechnologyBiochemistryDNA sequencingYeastOpen reading frameGeneticsGeneBiotechnologyYeast
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Chromatin structure of transposon Tn903 cloned into a yeast plasmid

1989

Transposon Tn903 contains the APH gene for kanamycin resistance, which is active in yeast [A. Jiménez and J. Davies (1980) Nature (London) 287, 869-871] and is flanked by two inverted repeats (IR) 1057 bp long. When plasmid pAJ50, carrying Tn903 and the 2-microns circle origin of replication, is cloned into Saccharomyces cerevisiae, nucleosomes are assembled in vivo on the prokaryotic DNA of the transposon. Indirect end labeling revealed that three nucleosomes are preferentially positioned on symmetrical sequences from both IRs. DNase I digestion also confirmed that the chromatin structure is symmetrical in both IRs. This suggests that sequence determinants are decisive for chromatin struct…

Transposable elementGeneticsInverted repeatGenes FungalRestriction MappingSaccharomyces cerevisiaeSpheroplastsBiologyOrigin of replicationChromatinNucleosomesChromatinchemistry.chemical_compoundTransformation GeneticPlasmidchemistryDNA Transposable ElementsDeoxyribonuclease INucleosomeCloning MolecularDNA FungalDeoxyribonuclease IMolecular BiologyDNAPlasmidsPlasmid
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Phylogenetic analysis of the thiolase family. Implications for the evolutionary origin of peroxisomes

1992

The thiolase family is a widespread group of proteins present in prokaryotes and three cellular compartments of eukaryotes. This fact makes this family interesting in order to study the evolutionary process of eukaryotes. Using the sequence of peroxisomal thiolase from Saccharomyces cerevisiae recently obtained by us and the other known thiolase sequences, a phylogenetic analysis has been carried out. It shows that all these proteins derived from a primitive enzyme, present in the common ancestor of eubacteria and eukaryotes, which evolved into different specialized thiolases confined to various cell compartments. The evolutionary tree obtained is compatible with the endosymbiotic theory fo…

SymbiogenesisMolecular Sequence DataSequence alignmentSaccharomyces cerevisiaeBiologyMicrobodiesHomology (biology)PhylogeneticsMolecular evolutionGeneticsAmino Acid SequenceAcetyl-CoA C-AcetyltransferaseSymbiosisThiolaseMolecular BiologyGenePhylogenyEcology Evolution Behavior and SystematicsGeneticsPhylogenetic treeThiolasePeroxisome evolutionBiological EvolutionEvolutionary biologyBootstrap analysisSequence Alignment
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Fine analysis of the chromatin structure of the yeast SUC2 gene and of its changes upon derepression. Comparison between the chromosomal and plasmid-…

1987

Micrococcal nuclease digestion has been used to investigate some fine details of the chromatin structure of the yeast SUC2 gene for invertase. Precisely positioned nucleosomes have been found on a 2 kb sequence from the 3' non-coding region, and four nucleosomes also seem to occupy fixed positions on the 5' flank. Eleven nucleosomes lie on the coding region, although their positioning is not as precise as in the flanks. When the gene is derepressed, these latter nucleosomes adopt a more open conformation and so do two of the nucleosomes positioned on the 5' flank. A dramatic change occurs in the 3' flank, whose involvement in the structural transitions of chromatin upon gene activation is p…

Regulation of gene expressionGeneticsbiologyGlycoside Hydrolasesbeta-FructofuranosidaseGenes FungalChromosomeDNA Restriction EnzymesSaccharomyces cerevisiaeChromatinChromatinNucleosomesPlasmidGenesGeneticsbiology.proteinNucleosomeCoding regionMicrococcal NucleaseEnzyme RepressionDerepressionMicrococcal nuclease
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Functional analysis of 12 ORFs fromSaccharomyces cerevisiae chromosome II

1999

Twelve different ORFs have been deleted from the right arm of Saccharomyces cerevisiae chromosome II; namely YBR193c, YBR194w, YBR197c, YBR198c, YBR201w, YBR203w, YBR207w, YBR209w, YBR210w, YBR211c, YBR217w and YBR228w. Tetrad analysis of heterozygous deletant strains revealed that YBR193c, YBR198c and YBR211c are essential genes for vegetative growth. No effects were detected in any of the haploid deletion mutants for the rest of the ORFs with respect to growth, gross morphology or mating.

GeneticsFunctional analysisbiologySaccharomyces cerevisiaeChromosomeBioengineeringbiology.organism_classificationApplied Microbiology and BiotechnologyBiochemistryGeneticsORFSPloidyTetradGeneFunctional genomicsBiotechnologyYeast
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