Project description:Mitotic entry is accompanyed by the expression of a cluster of so called mitotic genes, whose activation is critical for mitosis in human and yeast cells. We found a link between the transcription machinery and cell cycle control network at mitosis in fission yeast, involving the Cdk8 kinase dependent phosphorylation of the fork head transcription factor Fkh2. We have generated a non-phosphorylatable fkh2 mutant (fkh2-S2A) also. We have used microarrays to study the gene expression changes in fkh2 deletion and phosphomutants vs Wt in exponentially growing fission yeast cells to detect how the phosphorylation may affect global and mitotic gene expression.

Project description:Mitotic entry is accompanyed by the expression of a cluster of so called mitotic genes, whose activation is critical for mitosis in human and yeast cells. We found a link between the transcription machinery and cell cycle control network at mitosis in fission yeast, involving the Cdk8 kinase dependent phosphorylation of the fork head transcription factor Fkh2. We have generated a non-phosphorylatable fkh2 mutant (fkh2-S2A) also. We have used microarrays to study the gene expression changes in fkh2 deletion and phosphomutants vs Wt in exponentially growing fission yeast cells to detect how the phosphorylation may affect global and mitotic gene expression. RNA samples were taken from exponentially growing fission yeast cells and hybridized to affymetrix microarrays: wild type, fkh2delta and fkh2-S2A mutants

Project description: Not available

Project description:Our genetic screen reveals that deletion of CTM1, which abolishes the lysine trimethylation of cytochrome c (Cyc1), results in inhibition of hyphal morphogenesis in Candida albicans. Similar results are observed in the unmethylatable Cyc1 mutant (cyc1K79A). To elucidate how unmethylated Cyc1 inhibits hyphal growth, we performed RNA-Seq analysis by comparing WT (BWP17), ctm1∆/∆, and cyc1K79A cells grown in yeast and hyphal condition. Consistent with previous published data, many hyphal specific genes (HSGs), such as ALS3, ECE1, HWP1, and UME6, are upregulated while three major hyphal suppressor genes, TUP1, NRG1, and RFG1, are downregulated when WT cells switch from yeast to hyphal growth. Similar changes are observed in ctm1Δ/Δ and cyc1K79A cells upon hyphal induction, even though most mutant cells maintain yeast morphology throughout the induction. Further comparisons reveal that the basal transcriptional levels of HSGs are much lower in ctm1Δ/Δ and cyc1K79A cells than those in WT cells. Upon hyphal induction, the levels of HSGs in ctm1Δ/Δ and cyc1K79A cells increase but still remain lower than their basal levels in WT cells. In contrast, the hyphal suppressor genes (especially NRG1) exhibit much higher basal transcriptional levels in ctm1Δ/Δ and cyc1K79A cells than in WT cells. Their transcriptional levels reduce upon hyphal induction but still remain higher than the basal levels in WT cells. Together, these data suggest that unmethylated Cyc1 inhibits hyphal morphogenesis via transcriptional regulation of HSGs and hyphal suppressor genes.

Project description:Penicillium marneffei (Talaromyces marneffei) is an opportunistic human pathogen that can grow in a multicellular hyphal form at 25°C or a unicellular fission yeast form at 37°C, and can switch between these two forms in response to temperature. The yeast form is found in infected individuals and represents the pathogenic phase. In response to specific environmental cues, the hyphal form can undergo asexual development (conidiation) the produce a differentiated multicellular structure called a conidiophore which produces dormant spores (conidia). Inhaled conidia initiate infection. To identify genes that are ‘phase or cell-state specific’ transcriptional profiling was performed with a custom microarray consisting of ~42% of the predicted P. marneffei genes and RNA from P. marneffei hyphal, yeast and conidiation cell types.

Project description:Penicillium marneffei (Talaromyces marneffei) is an opportunistic human pathogen that can grow in a multicellular hyphal form at 25M-BM-0C or a unicellular fission yeast form at 37M-BM-0C, and can switch between these two forms in response to temperature. The yeast form is found in infected individuals and represents the pathogenic phase. In response to specific environmental cues, the hyphal form can undergo asexual development (conidiation) the produce a differentiated multicellular structure called a conidiophore which produces dormant spores (conidia). Inhaled conidia initiate infection. To identify genes that are M-bM-^@M-^Xphase or cell-state specificM-bM-^@M-^Y transcriptional profiling was performed with a custom microarray consisting of ~42% of the predicted P. marneffei genes and RNA from P. marneffei hyphal, yeast and conidiation cell types. A custom microarray consisting of short, random genomic fragments from P. marneffei (~42% of the predicted genes) was generated using PCR products of the inserts from two independent DNA libraries constructed from genomic DNA of the P. marneffei type strain FRR2161. PCR products from previously cloned P. marneffei genes with known expression profiles were included as controls on the microarray. Total RNA from hyphal, yeast or conidiation cell types was prepared and used in pairwise combinations (conidiation versus hyphal cells, conidiation versus yeast cells and hyphal versus yeast cells) on the microarrays. Three biological replicate cultures were prepared for each experiment.

Project description:Forkhead box (FOX) transcription factors regulate a wide variety of cellular functions in higher eukaryotes, including cell cycle control and developmental regulation. In Saccharomyces cerevisiae, Forkhead proteins Fkh1 and Fkh2 perform analogous functions, regulating genes involved in cell cycle control, while also regulating matingtype silencing and switching involved in gamete development. Recently, we revealed a novel role for Fkh1 and Fkh2 in the regulation of replication origin initiation timing, which, like donor preference in mating-type switching, appears to involve long-range chromosomal interactions, suggesting roles for Fkh1 and Fkh2 in chromatin architecture and organization. To elucidate how Fkh1 and Fkh2 regulate their target DNA elements and potentially regulate the spatial organization of the genome, we undertook a genome-wide analysis of Fkh1 and Fkh2 chromatin binding by ChIP-chip using tiling DNA microarrays. Our results confirm and extend previous findings showing that Fkh1 and Fkh2 control the expression of cell cycle-regulated genes. In addition, the data reveal hundreds of novel loci that bind Fkh1 only and exhibit a distinct chromatin structure from loci that bind both Fkh1 and Fkh2. The findings also show that Fkh1 plays the predominant role in the regulation of a subset of replication origins that initiate replication early, and that Fkh1/2 binding to these loci is cell cycleregulated. Finally, we demonstrate that Fkh1 and Fkh2 bind proximally to a variety of genetic elements, including centromeres and Pol III-transcribed snoRNAs and tRNAs, greatly expanding their potential repertoire of functional targets, consistent with their recently suggested role in mediating the spatial organization of the genome.

Project description:The S. cerevisiae Forkhead Box (FOX) proteins, Fkh1 and Fkh2, regulate diverse cellular processes including transcription, long-range DNA interactions during homologous recombination, and replication origin timing and long-range origin clustering. As stimulators of early origin activation, we hypothesized that Fkh1 and Fkh2 abundance limits the rate of origin activation genome-wide. Existing methods, however, were not well suited to quantitative, genome-wide measurements of origin firing between strains and conditions. To overcome this limitation, we developed qBrdU-seq, a quantitative method for BrdU incorporation analysis of replication dynamics, and applied it to show that overexpression of Fkh1 and Fkh2 advance the initiation timing of many origins throughout the genome resulting in a higher total level of origin initiations in early S phase. The higher initiation rate is accompanied by slower replication fork progression, thereby maintaining a normal length of S phase without causing detectable Rad53 checkpoint kinase activation. The advancement of origin firing time, including that of origins in heterochromatic domains, was established in late G1 phase, indicating that origin timing can be reset subsequently to origin licensing. These results provide novel insights into the mechanisms of origin timing regulation by identifying Fkh1 and Fkh2 as rate-limiting factors for origin firing that determine the ability of replication origins to accrue limiting factors and have the potential to reprogram replication timing late in G1 phase.

Project description:The S. cerevisiae Forkhead Box (FOX) proteins, Fkh1 and Fkh2, regulate diverse cellular processes including transcription, long-range DNA interactions during homologous recombination, and replication origin timing and long-range origin clustering. As stimulators of early origin activation, we hypothesized that Fkh1 and Fkh2 abundance limits the rate of origin activation genome-wide. Existing methods, however, were not well suited to quantitative, genome-wide measurements of origin firing between strains and conditions. To overcome this limitation, we developed qBrdU-seq, a quantitative method for BrdU incorporation analysis of replication dynamics, and applied it to show that overexpression of Fkh1 and Fkh2 advance the initiation timing of many origins throughout the genome resulting in a higher total level of origin initiations in early S phase. The higher initiation rate is accompanied by slower replication fork progression, thereby maintaining a normal length of S phase without causing detectable Rad53 checkpoint kinase activation. The advancement of origin firing time, including that of origins in heterochromatic domains, was established in late G1 phase, indicating that origin timing can be reset subsequently to origin licensing. These results provide novel insights into the mechanisms of origin timing regulation by identifying Fkh1 and Fkh2 as rate-limiting factors for origin firing that determine the ability of replication origins to accrue limiting factors and have the potential to reprogram replication timing late in G1 phase.

Project description:Whole cell lysates from yeast or hyphal Candida albicans cells were obtained and proteins were analysed by MS in order to have a global view of proteome differences between both fungal morphologies. This analysis constitute an interesting approach to decipher proteomic differences underlying morphological switch intimately related to Candida albicans virulence. A total of 811 different proteins were identified from hyphal whole cell lysates and 976 from yeast whole cell lysates. In terms of biological significance, we only took into consideration proteins that were identified in at least two biological replicates with at least two peptides and a q-value< 0.01.