Project description:Mitochondrial DNA (mtDNA) in budding yeast is biparentally inherited, but colonies rapidly lose one type of parental mtDNA, becoming homoplasmic. Therefore, hybrids between different yeast species possess two homologous nuclear genomes, but only one type of mitochondrial DNA. We hypothesise that the choice of mtDNA retention is influenced by its contribution to hybrid fitness in different environments, and that the allelic expression of the two nuclear sub-genomes is affected by the presence of different mtDNAs in hybrids. Here, we crossed Saccharomyces cerevisiae with S. uvarum under different environmental conditions and examined the plasticity of the retention of mtDNA in each hybrid.

Project description:This is parallel comparison of gene regulation by Gcn5 in evolutionarily divergent yeasts S. pombe and S. cerevisiae. Our study showed Gcn5 is required for a similar spectrum of stress responses in both organisms, including the response to KCl. This DNA microarray studies is to find conserved or diverged gene regulation pattern under KCl stress condition in the two yeasts. There are 6 subsets in total, 3 subsets in each evolutionarily divergent yeasts including the following: 1 gcn5 mutant compared to wt under rich medium without treatment, 2 gcn5 mutant compared to wild type both under KCl treatment, 3 wild type strains under KCl treatment compared to wild type without treatment. Keywords: stress response, Gcn5, Comparative genomics, Transcriptional co-activator Gene expression profiling experiment in which gene expression in logarithmically growing cultures of test groups was compared to that of the control groups in rich medium at 25C. There are 6 subsets in total, 3 subsets in each yeast including the following: 1 gcn5 mutant compared to wt under rich medium without treatment, 2 gcn5 mutant compared to wild type both under KCl treatment, 3 wild type strains under KCl treatment compared to wild type without treatment. RNA was extracted and subjected to cDNA expression profiling analysis using the established protocols (Xue et al, 2004). Independent RNA preparations were used to hybridize to microarray slides with dye swap. Data normalized with 'Lowess' per chip per spot normalization.

Project description:We did transcription profiling on the effect of rlm1 (MAPK Slt2 transcription factor) deletion and swi3 (component of SWI/SNF complex involved in chromatin remodeling) deletion in genes involved in cell wall stress (Congo Red) response. Three biological samples were analyzed for each condition, and a microarray experiment were carried out for each sample 1. absence of the drug 2. presence of 30 µg/ml of Congo Red

Project description:Mitochondria contain ~1,000 different proteins that may assemble into larger entities such as respiratory (super)complexes and preprotein translocases. The molecular/structural organization of major parts of the mitochondrial proteome, however, has not yet been resolved. We report a quantitative mapping of mitochondrial protein assemblies by high-resolution complexome-profiling of >90% of the yeast mitochondrial proteome, termed MitCOM. Analysis of MitCOM unraveled an unexpected complexity of protein assemblies with each protein found in an average of at least six assemblies. Organization of proteins was distinct between the major classes of mitochondrial function, but independent of their biochemical properties. We detected interactions of the mitochondrial receptor for cytosolic ribosomes, of prohibitin scaffolds and respiratory complexes. Identification of quality control factors operating at the mitochondrial protein entry gate uncovered pathways for preprotein ubiquitylation, deubiquitylation and degradation. MitCOM, made accessible through an interactive viewer on the CEDAR database, may serve as a comprehensive resource for analyzing functional organization and interaction of mitochondrial protein machineries and pathways.

Project description:This experiment was performed in order to assess the specificity of Rad9 binding to S. cerevisiae genome. In another ChIP-chip experiment in SC BCS BPS growth conditions we have found Rad9 present to a significant number of genomic loci with a bias to transcriptionally active regions. In order to see if that pattern was random and depended or not on the activity state of the genes, we conducted a Rad9 ChIP on chip experiment with the strain grown in medium with galactose instead of glucose, where it is known that particular gene groups are transcriptionally activated. We then compared to the results of our previous experiment where the strain was grown in glucose.

Project description:Wild type (BY4741) Saccharomyces cerevisiae strains and their isogenic slt2 deficient counterparts, were treated for 2 hours with sodium arsenate 100 micromolar. Control (untreated) cells were also collected. Total RNA was extracted and analyzed by microarray hybridization. The data obtained from these experiments allows to determine those genes that are regulated by Slt2 activity after arsenate treatment. The experiments was designed as follows: Four types of samples were used: untreated wild type cells, treated wild type cells, untreated slt2- cells and treated slt2- cells. 3 independent replicates were performed for each experiment.

Project description:Meiotic recombination hotspots are associated with histone post-translational modifications and open chromatin. However, it remains unclear how histone modifications and chromatin structure directly regulate meiotic recombination. Here, we identify acetylation of histone H4 at Lys44 (H4K44ac) as a new histone modification, occurring on the nucleosomal lateral surface. We show that H4K44ac is specific to yeast sporulation, rising during yeast meiosis and displaying genome-wide enrichment at recombination hotspots in meiosis. The H4K44 residue is required for normal meiotic recombination, for normal levels of double strand breaks during meiosis, and for optimal sporulation. Non-modifiable substitution H4K44R results in reduced MNase digestion and decreased binding of recombination-associated proteins at hotspots. Our results show that H4K44ac creates an accessible chromatin environment for key proteins to facilitate meiotic recombination. One sample, H4K44ac chIP from 4hrs sporulation yeast and one background H4 chIP from the same, two replicates each Two replicates each of H3K4me3 and H3K56ac chIP-seq in WT and H4K44->R mutant yeast, with two replicates of H3 chIP-seq in each genetic background Two replicates each of Rad51 chIP-seq in WT and H4K44->R mutant yeast with a single replicate of accompanying input DNA in each genetic background

Project description:The experiment describes the transcriptional response of Saccharomyces cerevisiae BY4741 and of the deletion mutant Δhaa1 following an incubation in the presence of 50 mM acetic acid (at pH 4.0)

Project description:To identify mutations that occurred in the nuclear and mitochondrial DNA of the yeast subjected to mtDNA base editing or Mito-BE screen, we performed whole-genome sequencing of cultured yeast cells after isolation of mitochondrial DNA.

Project description:Investigation of whole genome gene expression level changes in three S. cerevisiae Y55 mutants, compared to the wild-type strain. The UV-induced mutations enable the mutant strains to ferment high-gravity maltose faster than the WT. The mutants analyzed in this study are further described in Baerends, R.J.S., J.L. Qiu, L. Gautier, and A. Brandt. A high-throughput system for screening of fast-fermenting Saccharomyces cerevisiae strains. Manuscript in preparation. A single-dye 12-plex array chip study using double-stranded DNA prepared from messenger RNA purified from total RNA recovered from three separate Saccharomyces cerevisiae Y55 wild-type cultures and 3x three separate cultures each corresponding to a fast-fermenting UV-induced mutant (mutant 1, 2 and 3), during fermentation of high-gravity maltose at day 2. Each array on the 12-plex chip measures the expression level of 5,777 genes from Saccharomyces cerevisiae S288C with eight 60-mer probes per gene, with three-fold technical redundancy.