Project description:In order to investigate the biology of chlamydospores, we compared global gene expression in C. dubliniensis yeast cells and chlamydospores. This revealed that 11% of the genes greater than 2-fold upregulated in chlamydospores were genes regulated by the transcriptional repressor Nrg1. These mainly included genes involved in glucose metabolism and glucose transport. Other upregulated genes included genes involved in stress response, cell cycle control, chromatin regulation, chromosome rearrangements, DNA repair-recombination and pheromone response. Genes related to mitochondrial respiratory functions and biogenesis were found to be downregulated in chlamydospores. Our data confirm that chlamydospores represent a specialised growth form of C. albicans and C. dubliniensis. 2 experimental parameters were analysed (chlamydospores, yeast cells). Three biological replicates each, one technical replicate.

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. Two samples, one WT MNase-seq and one MNase-seq from yeast with a lysine->arginine mutation at H4K44, no replicates Two replicates each of MNase-seq in WT and H4K44->R mutant yeast grown in YPD or YPA.

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 expression of a large proportion of the fission yeast genome changes periodically with the cell cycle. Several key transcription factors have been identified that regulate these oscillating and interdependent waves of gene expression. However, for a significant number of cell cycle-regulated genes the regulator(s) driving these oscillations remain unknown. Cbf11 and Cbf12, the fission yeast CSL transcription factors, have been implicated in the regulation of cell cycle progression, yet the details of their functioning are poorly understood. Using a combination of transcriptome profiling and genome-wide mapping of CSL-DNA interactions we have identified a comprehensive set of CSL-regulated genes. Our data indicate that Cbf11 and Cbf12 contribute directly and indirectly to the regulation of periodically expressed genes in fission yeast. We show that during S phase/cytokinesis Cbf11 directly activates the transcription of several periodic genes required in the cell to prevent catastrophic mitosis. In agreement with these findings, multiple aspects of cell cycle progression are perturbed when CSL cellular levels are genetically manipulated. We have identified Cbf11 as a novel cell cycle phase-specific activator of genes required for proper coordination of cell and nuclear division, and prevention of catastrophic mitosis in fission yeast.

Project description:Asf1, through its histone chaperone activity, helps chromatin closing/opening during DNA replication, repair, recombination and transcription. Despite extensive research on Asf1-mediated physiological functions, a genome-wide localization map is lacking, limiting our knowledge of chromosomal features targeted by Asf1. We present a high-resolution genome-wide map of Asf1, localizing at essentially all pol III-transcribed genes, highly active pol II-transcribed genes and heterochromatic features. Pol III-transcribed genes are negatively regulated by Asf1, whereas pol II genes are regulated indirectly by Asf1-dependent H3K56 acetylation. Interestingly, Asf1 localization along yeast chromosomes shows nearly identical distribution to that of the condensin complex, predicting a functional overlap in chromosome architecture and genome organization. ChIP-seq analysis of Asf1 targets using a yeast strain that expresses an 18-Myc tag fused to the C-terminus of ASF1. Two biological replicates and one mock/control were performed. The Illumina GAII was used. ChIP-seq reads are aligned to the budding yeast sacCer3 (2011) assembly.

Project description:We isolated the glucose-inhibited root elongation1 (gir1) mutant from a genetic screen of activation T-DNA tagged seeds grown on 6% glucose agar plates. The gir1 mutant showed short swollen root phenotype at the presence of glucose and had a sever sterility when grown in soil. To better understand the molecular basis of GIR1-mediated gene expression, the Affymetrix ATH1 GeneChip was used to analyze the gene expression profiling in the gir1 mutant. The results showed that cell wall, carbohydrate, and lipid metabolic or transporter-related genes were altered expression pattern. These data suggest that GIR1 regulates root and flower growth and development through cell wall modification and, perhaps, membrane trafficking. For root microarray assay [Samples GSM402178-GSM402183], wild type and the gir1 mutant plants were vertically grown on 0% glucose agar plates for 11 days, then transferred to 4% glucose plates for another ten days. Subsequently, the root tissues were excised for GeneChip analysis. In the case of inflorescence microarray assay [Samples GSM402184-GSM402191], plants were grown in soil for 33 days. The opened and opening flowers were discarded and the remaining inflorescence was harvested for GeneChip analysis.

Project description:Cancer cells display an altered metabolism with increased glycolysis and glucose uptake. Anti-cancer strategies targeting glycolysis through metabolic inhibitors have been considered. The glucose analog 2-deoxyglucose (2DG) is imported into cells and after phosphorylation becomes 2DG-6-phosphate, a toxic by-product that inhibits glycolysis. 2DG has other cellular effects and can induce resistance. Using yeast as a model, we performed an unbiased, mass-spectrometry-based approach to probe the cellular effects of 2DG on the proteome and study resistance mechanisms. We found that two 2DG-6-phosphate phosphatases, Dog1 and Dog2, were induced upon exposure to 2DG and participated in 2DG detoxication. 2DG induced Dog2 by activating several signaling pathways, such as the MAPK (the p38 ortholog Hog1)-based stress-responsive pathway, the unfolded protein response (UPR) triggered by 2DG-induced ER stress, and the MAPK (Slt2)-based cell wall integrity (CWI) pathway. Thus, 2DG-induced interference with cellular signaling rewired the expression of these endogenous phosphatases to promote 2DG resistance. Consequently, loss of the UPR or CWI pathways led to 2DG hypersensitivity. In contrast, DOG2 was transcriptionally repressed by glucose availability through the inhibition of the Snf1/AMPK pathway, and glucose-repression mutants were 2DG-resistant. The characterization and genome resequencing of spontaneous 2DG-resistant mutants revealed that DOG2 overexpression was a common strategy to achieve 2DG resistance. A human Dog2 homolog, HDHD1, also displays 2DG-6-phosphate phosphatase activity in vitro, and its overexpression conferred 2DG resistance in HeLa cells, suggesting potential interference with chemotherapies involving 2DG.

Project description:In plants, sugars such as glucose act as signaling molecules that promote changes in gene expression programs impacting on growth and development. Recent evidences have revealed the potential participation of mRNA decay control in some aspects of glucose-mediated regulatory responses suggesting a role of microRNAs (miRNAs) in these responses. In order to get a better understanding of glucose-mediated development modulation involving miRNA-related regulatory pathways, early seedling development of mutants impaired in miRNA biogenesis (hyl1-2) and miRNA-activity (ago1-25) were evaluated. Both mutants exhibited a glucose hyposensitive phenotype from germination up to seedling establishment, indicating that miRNA regulatory pathways may be involved in the glucose-mediated delay of early seedling development. The expression profile of 200 primary miRNA transcripts (pri-miRs) were evaluated by large-scale quantitative real-time polymerase chain reaction (qRT-PCR) profiling revealing that 38 pri-miRs were regulated by glucose. For several of them, the corresponding mature miRNAs are known to participate directly or indirectly in plant development, and their accumulation was shown to be co-regulated with the pri-miRNA by glucose. These data indicate that deficiency in miRNA machinery leads to a deregulated expression of several miRNA target genes in response to glucose. Also, such deficiencies result in glucose-promoted misexpression of genes for the three Abscisic Acid signaling elements ABI3, ABI4 and ABI5. Thus, miRNA-regulatory pathways play a role in the adjustments of growth and development triggered by glucose signaling. Three samples, including untreated control, 2% glucose-treated and 2% mannitol-treated samples.

Project description:Genome-wide binding of the histone chaperone Rtt106 was analysed by ChIP-seq. Rtt106 binding was analysed in WT and the mutant backgrounds lacking transcription factors Pdr1 and Pdr3, the HIR histone chaperone subunit Hir1, or the boundary protein Yta7. Two biological replicates had been submitted. mRNA profiles in WT and the mutants lacking Rtt106, Pdr1, Pdr3 or the SWI/SNF subunit Snf2 were analysed by RNA-seq. mRNA profiles in those yeast cells grown in rich media (YPD) and in the glucose-starved condition (YEP) and in response to ketoconazole (YEP+ket) were analysed. Three biological samples for each condition had been submitted.

Project description:For yeast cells, tolerance to high levels of ethanol is vital both in their natural environment and in industrially relevant conditions. We recently genotyped experimentally evolved yeast strains, tolerant to high levels of ethanol. In this study, we elucidate how the genotype and phenotype are related to each other on the molecular level through an integrated analysis of mutation data with protein abundance profiles from six evolved, ethanol-tolerant clones. We constructed a protein network of regulatory proteins, mutated and differentially regulated proteins. This resulted in the identification of a rewired regulatory network after adaptation to high levels of ethanol.