Search results for "Saccharomyce"

showing 10 items of 875 documents

A Comparative Study of Different Methods of Yeast Strain Characterization

1992

Summary An extensive survey of different methods of yeast strain identification (classical microbiological tests, whole-cell protein electrophoresis, chromosomal patterns, DNA hybridization and mitochondrial DNA restriction analysis) has been carried out in order to differentiate, with industrial purposes, strains present in the Alicante wine ecosystem. Only chromosomal patterns and mitochondrial DNA (mtDNA) restriction analysis show differences between strains. Both techniques are very complex to be used in bio technological industries. For this reason, we have developed a new, simple, unexpensive and rapid method based on mtDNA restriction analysis.

Gel electrophoresisGeneticsMitochondrial DNAbiologyDNA–DNA hybridizationSaccharomyces cerevisiaebiology.organism_classificationApplied Microbiology and BiotechnologyMicrobiologyYeastRestriction fragmentYeast in winemakingRestriction mapbiology.proteinEcology Evolution Behavior and SystematicsSystematic and Applied Microbiology
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A rapid and simple method for the preparation of yeast mitochondrial DNA

1990

Gel electrophoresisMitochondrial DNAbiologySaccharomyces cerevisiaeSaccharomyces cerevisiaeSpheroplastsMitochondrionSpheroplastbiology.organism_classificationDNA MitochondrialMolecular biologyYeastMitochondriachemistry.chemical_compoundBiochemistrychemistryCentrifugation Density GradientGeneticsCentrifugationDNA FungalDNA
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Effect of α-factor on individual wall mannoproteins fromSaccharomyces cerevisiae acells

1985

Treatment of Saccharomyces cerevisiae a cells with α-factor partially inhibits mannosylation of the high Mr mannoproteins, although there is an increase in the total amount of these molecules present in the wall. They show a similar mobility in SDS-acrylamide gels to those from untreated mnn2 cells. No other significant effects on wall mannoproteins have been observed, except a decrease in the amount of the 29 kDa species.

Gel electrophoresisbiologySaccharomyces cerevisiaebiology.organism_classificationMicrobiologyYeastcarbohydrates (lipids)Cell wallAgglutination (biology)Endoglycosidase Hchemistry.chemical_compoundBiochemistrychemistryMannosylationAcrylamideGeneticsbiology.proteinMolecular BiologyFEMS Microbiology Letters
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Yeast dsRNA viruses: replication and killer phenotypes

1991

The cytoplasmic L-A dsRNA virus of Saccharomyces cerevisiae consists of a 4.5 kb dsRNA and the two gene products it encodes; the capsid (cap) and at least one copy of the capsid-polymerase (cap-pol) fusion protein. Virion cap-pol catalyses transcription of the plus (sense)-strand; this is extruded from the virus and serves as messenger for synthesis of cap and cap-pol. Nascent cap-pol binds to a specific domain in the plus strand to initiate encapsidation and then catalyses minus-strand synthesis to complete the replication cycle. Products of at least three host genes are required for replication, and virus copy number is kept at tolerable levels by the SKI antivirus system. S. cerevisiae k…

Genes ViralbiologyDNA synthesisvirusesSaccharomyces cerevisiaeRNA virusSaccharomyces cerevisiaeSpheroplastsVirus Replicationbiology.organism_classificationModels BiologicalMicrobiologyVirologyVirusPhenotypeDNA Topoisomerases Type ICapsidViral replicationTranscription (biology)VirusesRNA ViralMolecular BiologyGeneRNA Double-StrandedVirus Physiological PhenomenaMolecular Microbiology
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Basic phenotypic analysis of six novel yeast genes reveals two essential genes and one which affects the growth rate

1999

Phenotypic analysis was performed on six mutants of Saccharomyces cerevisiae deleted in one of the following open reading frames (ORFs), located on chromosome II: YBR254c, YBR255w, YBR257w, YBR258c, YBR259w and YBR266c. Disruption of the ORFs was carried out in the diploid strain FY1679 using the kanMX4 marker flanked by short sequences homologous to the target locus. Tetrad analysis following sporulation of the heterozygous disruptants showed that YBR254c and YBR257w are essential genes. YBR257w was later characterized and renamed POP4, its gene product being involved in 5.8S rRNA and tRNA processing (Chu et al., 1997). The tetrad analysis performed for the heterozygous disruptant for YBR2…

Genetic MarkersGeneticsGenes FungalMutantSaccharomyces cerevisiaeTRNA processingBioengineeringLocus (genetics)Saccharomyces cerevisiaeBiologybiology.organism_classificationPolymerase Chain ReactionApplied Microbiology and BiotechnologyBiochemistryComplementationOpen Reading FramesOpen reading framePhenotypeGeneticsChromosomes FungalORFSGeneGene DeletionBiotechnologyYeast
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Molecular Characterization of a Chromosomal Rearrangement Involved in the Adaptive Evolution of Yeast Strains

2002

Wine yeast strains show a high level of chromosome length polymorphism. This polymorphism is mainly generated by illegitimate recombination mediated by Ty transposons or subtelomeric repeated sequences. We have found, however, that the SSU1-R allele, which confers sulfite resistance to yeast cells, is the product of a reciprocal translocation between chromosomes VIII and XVI due to unequal crossing-over mediated by microhomology between very short sequences on the 5' upstream regions of the SSU1 and ECM34 genes. We also show that this translocation is only present in wine yeast strains, suggesting that the use for millennia of sulfite as a preservative in wine production could have favored …

Genetic MarkersSaccharomyces cerevisiae ProteinsLetterChromosomal rearrangementsAnion Transport ProteinsGenes FungalMolecular Sequence DataSaccharomyces cerevisiaeSaccharomyces cerevisiaeChromosomal rearrangementSaccharomycesGenètica molecularTranslocation GeneticEvolution MolecularSaccharomycesGene FrequencySpecies SpecificityGeneticsVinificationDNA FungalGeneGenetics (clinical)Wine yeastsGene RearrangementRecombination GeneticGeneticsBase SequencebiologyGene rearrangementbiology.organism_classificationYeastYeast in winemakingChromosomes FungalGenome FungalPloidyGenome Research
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PARTIAL SEQUENCING OF THE BETA-GLUCOSIDASE-ENCODING GENE FROM YEAST STRAINS ISOLATED FROM MUSTS AND WINES

2008

The aim of the present work was the identification of the gene encoding for β-glucosidase and its partial sequencing in the strainsPichia anomala AL112,Hanseniaspora uvarum Y8 andSaccharomyces cerevisiae AL41. To this aim degenerated primers, designed on the basis of aminoacid similarities of four known yeast β-glucosidases, have been used in PCR amplifications. An expected fragment of about 200 bp was amplified from all the DNAs, cloned and sequenced. Sequence homology demonstrated for the first time the presence of a β-glucosidase encoding gene inHanseniaspora uvarum andSaccharomyces cerevisiae.

GeneticsBETA-GLUCOSIDASEbiologyPichia anomalaAscomycotaGENE PARTIAL SEQUENCINGSaccharomyces cerevisiaeSICILIAN MUSTSbiology.organism_classificationHanseniasporaSettore BIO/19 - Microbiologia GeneraleApplied Microbiology and BiotechnologyYeastGENE PARTIAL SEQUENCING; BETA-GLUCOSIDASE; SICILIAN MUSTSDNA glycosylaseβ-glucosidase gene partial sequencing Hanseniaspora uvarum Pichia anomala Saccharomyces cerevisiaeGenePichia
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A Gene-Specific Requirement for FACT during Transcription Is Related to the Chromatin Organization of the Transcribed Region

2006

The FACT complex stimulates transcription elongation on nucleosomal templates. In vivo experiments also involve FACT in the reassembly of nucleosomes traversed by RNA polymerase II. Since several features of chromatin organization vary throughout the genome, we wondered whether FACT is equally required for all genes. We show in this study that the in vivo depletion of Spt16, one of the subunits of Saccharomyces cerevisiae FACT, strongly affects transcription of three genes, GAL1, PHO5, and Kluyveromyces lactis LAC4, which exhibit positioned nucleosomes at their transcribed regions. In contrast, showing a random nucleosome structure, YAT1 and Escherichia coli lacZ are only mildly influenced …

GeneticsChromatin ImmunoprecipitationSaccharomyces cerevisiae ProteinsTranscription GeneticbiologyHigh Mobility Group ProteinsRNA polymerase IIPromoterArticlesSaccharomyces cerevisiaeCell BiologyFACT complexChromatinChromatin remodelingChromatinDNA-Binding ProteinsHistone methylationProtein FACTEscherichia colibiology.proteinTranscriptional Elongation FactorsTranscription factor II DMolecular BiologyRNA polymerase II holoenzymePlasmidsMolecular and Cellular Biology
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Comparative Genomics of the RBR Family, Including the Parkinson's Disease–Related Gene Parkin and the Genes of the Ariadne Subfamily

2002

Genes of the RBR family are characterized by the RBR signature (two RING finger domains separated by an IBR/DRIL domain). The RBR family is widespread in eukaryotes, with numerous members in animals (mammals, Drosophila, Caenorhabditis) and plants (Arabidopsis). But yeasts, such as Saccharomyces cerevisiae or Schizosaccharomyces pombe, contain only two RBR genes. We determined the phylogenetic relationships and the most likely orthologs in different species of several family members for which functional data are available. These include: (1) parkin, whose mutations are involved in forms of familial Parkinson's disease; (2) the ariadne genes, recently characterized in Drosophila and mammals;…

GeneticsComparative genomicsSubfamilyUbiquitin-Protein LigasesGenomicsBiologybiology.organism_classificationParkinLigasesCaenorhabditismedicine.anatomical_structureSchizosaccharomyces pombeGeneticsRing fingermedicinebiology.proteinAnimalsHumansButterfliesMolecular BiologyGenePhylogenyEcology Evolution Behavior and SystematicsCullinMolecular Biology and Evolution
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Chromatin structure of yeast genes.

1989

GeneticsDeoxyribonucleasesBioengineeringSaccharomyces cerevisiaeBiologyApplied Microbiology and BiotechnologyBiochemistryChromatin remodelingYeastChromatinChromatinCell biologyHistoneGeneticsbiology.proteinNucleosomeDNA FungalGeneChIA-PETBiotechnologyBivalent chromatinYeast (Chichester, England)
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