0000000000414894

AUTHOR

Ana C. Adam

showing 4 related works from this author

Self-diploidization in Saccharomyces cerevisiae kar2 heterokaryons

1993

Zygotes isolated by micromanipulation from crosses of Saccharomyces cerevisiae strains, one of which carries a kar mutation, give rise most frequently to cytoductant colonies showing the nuclear constitution of either one of the two haploid parental strains. In crosses of kar2-1 strains to wild-type, about 10% of the cytoductants of both mating types are homozygous autodiploids. There is evidence indicating that self-diploidization occurs by fusion between sibling nuclei in the heterokaryotic zygote. Here we describe this phenomenon and propose to take advantage of it for the construction of genotypically-defined diploids able to mate, and of polyploid strains, which are useful tools in gen…

GeneticsHeterokaryonMating typeZygoteGenotypebiologyZygoteGenes FungalSaccharomyces cerevisiaeSaccharomyces cerevisiaeGeneral Medicinebiology.organism_classificationDiploidyKaryogamyPhenotypePolyploidKaryotypingMutationGeneticsMatingPloidyCrosses GeneticCurrent Genetics
researchProduct

Convergent adaptation of Saccharomyces uvarum to sulfite, an antimicrobial preservative widely used in human-driven fermentations

2021

Different species can find convergent solutions to adapt their genome to the same evolutionary constraints, although functional convergence promoted by chromosomal rearrangements in different species has not previously been found. In this work, we discovered that two domesticated yeast species, Saccharomyces cerevisiae, and Saccharomyces uvarum, acquired chromosomal rearrangements to convergently adapt to the presence of sulfite in fermentation environments. We found two new heterologous chromosomal translocations in fermentative strains of S. uvarum at the SSU1 locus, involved in sulfite resistance, an antimicrobial additive widely used in food production. These are convergent events that …

Metabolic ProcessesCancer ResearchAdaptation BiologicalYeast and Fungal ModelsArtificial Gene Amplification and ExtensionWineChromosomal translocationQH426-470BiochemistryGenomeTranslocation Geneticchemistry.chemical_compoundAnti-Infective AgentsMedicine and Health SciencesPromoter Regions GeneticPhylogenyGenetics (clinical)GeneticsChromosome BiologyAlcoholic BeveragesEukaryotaGenomicsChromosomal AberrationsPolymerase chain reactionChemistryExperimental Organism SystemsPhysical SciencesChromosomes FungalResearch ArticleSaccharomyces cerevisiae ProteinsAnion Transport ProteinsSaccharomyces cerevisiaeLocus (genetics)Saccharomyces cerevisiaeChromosomal translocationsBiologyResearch and Analysis MethodsBeveragesSaccharomycesModel OrganismsSulfiteGeneticsHumansSulfitesMolecular Biology TechniquesMolecular BiologyGeneEcology Evolution Behavior and SystematicsNutritionChemical CompoundsOrganismsFungiBiology and Life SciencesCell Biologybiology.organism_classificationYeastYeastDietMetabolismchemistryFermentationFood PreservativesAnimal StudiesAdaptationPLOS Genetics
researchProduct

Genomic instability in an interspecific hybrid of the genus Saccharomyces: a matter of adaptability

2020

Ancient events of polyploidy have been linked to huge evolutionary leaps in the tree of life, while increasing evidence shows that newly established polyploids have adaptive advantages in certain stress conditions compared to their relatives with a lower ploidy. The genus Saccharomyces is a good model for studying such events, as it contains an ancient whole-genome duplication event and many sequenced Saccharomyces cerevisiae are, evolutionary speaking, newly formed polyploids. Many polyploids have unstable genomes and go through large genome erosions; however, it is still unknown what mechanisms govern this reduction. Here, we sequenced and studied the natural S. cerevisiae × Saccharomyces…

Genome instabilityNuclear geneDNA Copy Number VariationsPopulationGene DosageHybridsWineGenome instabilityadaptationSaccharomyces cerevisiaeBiologyGenomeGenomic InstabilityPolyploidy03 medical and health sciencesSaccharomycesCopy-number variationAdaptationeducation030304 developmental biologyhybridsresequencing0303 health scienceseducation.field_of_study030306 microbiologyChimeraGeneral MedicineGenomicsSequence Analysis DNAbiology.organism_classificationgenome instabilityEvolutionary biologyEpistasisPloidyMicrobial evolution and epidemiology: Mechanisms of evolutionSaccharomyces kudriavzeviiGenome FungalSaccharomyces kudriavzeviiResequencingResearch ArticleMicrobial Genomics
researchProduct

Aneuploidy and Ethanol Tolerance in Saccharomyces cerevisiae

2019

Response to environmental stresses is a key factor for microbial organism growth. One of the major stresses for yeasts in fermentative environments is ethanol. Saccharomyces cerevisiae is the most tolerant species in its genus, but intraspecific ethanol-tolerance variation exists. Although, much effort has been done in the last years to discover evolutionary paths to improve ethanol tolerance, this phenotype is still hardly understood. Here, we selected five strains with different ethanol tolerances, and used comparative genomics to determine the main factors that can explain these phenotypic differences. Surprisingly, the main genomic feature, shared only by the highest ethanol-tolerant st…

0301 basic medicineChromosome IIIlcsh:QH426-470Saccharomyces cerevisiaeAneuploidycomparative genomicsSaccharomyces cerevisiaeEthanol toleranceBiologyTranscriptome03 medical and health sciences0302 clinical medicineGeneticsmedicineaneuploidyGenetics (clinical)Wine yeastsGeneticsComparative genomicsComparative genomicsStrain (biology)chromosome IIIChromosomewine yeastsAneuploidybiology.organism_classificationmedicine.diseasePhenotypeethanol tolerancelcsh:Genetics030104 developmental biology030220 oncology & carcinogenesisMolecular MedicinePloidyFrontiers in Genetics
researchProduct