Project description:The phytopathogenic fungus Fusarium fujikuroi is the causal agent of bakanae disease on rice due to its ability to produce gibberellins. Besides these phytohormones, F. fujikuroi is able to produce a wide range of other secondary metabolites (SMs), such as mycotoxins and pigments. Although much progress has been made in the field of secondary metabolism over the last years, the transcriptional regulation of SM biosynthetic genes is complex and far from being fully understood. Environmental conditions (e.g. nitrogen availability and pH), global and pathway-specific regulators as well as chromatin remodeling were shown to play major roles in this regulation. Here, the role of FfSge1, a homolog of the morphological switch regulators Wor1 and Ryp1 in Candida albicans and Histoplasma capsulatum, respectively, is explored with emphasis on secondary metabolism. FfSge1 is not required for conidia formation and pathogenicity, but is involved in vegetative growth. Genome-wide transcriptome analysis of the Δffsge1 deletion mutant compared to the wild type revealed that FfSge1 is a global regulator of secondary metabolism in F. fujikuroi that activates the expression of several SMs. In addition, FfSge1 is also required for expression of a yet uncharacterized SM gene cluster containing a noncanonical non-ribosomal peptide synthetase. Investigation of whole genome gene expression of the Fusarium fujikuroi wild type IMI58289, Δffsge1 mutant under nitrogen starvation and nitrogen sufficient conditions.

Project description:The phytopathogenic fungus Fusarium fujikuroi is the causal agent of bakanae disease on rice due to its ability to produce gibberellins. Besides these phytohormones, F. fujikuroi is able to produce a wide range of other secondary metabolites (SMs), such as mycotoxins and pigments. Although much progress has been made in the field of secondary metabolism over the last years, the transcriptional regulation of SM biosynthetic genes is complex and far from being fully understood. Environmental conditions (e.g. nitrogen availability and pH), global and pathway-specific regulators as well as chromatin remodeling were shown to play major roles in this regulation. Here, the role of FfSge1, a homolog of the morphological switch regulators Wor1 and Ryp1 in Candida albicans and Histoplasma capsulatum, respectively, is explored with emphasis on secondary metabolism. FfSge1 is not required for conidia formation and pathogenicity, but is involved in vegetative growth. Genome-wide transcriptome analysis of the M-NM-^Tffsge1 deletion mutant compared to the wild type revealed that FfSge1 is a global regulator of secondary metabolism in F. fujikuroi that activates the expression of several SMs. In addition, FfSge1 is also required for expression of a yet uncharacterized SM gene cluster containing a noncanonical non-ribosomal peptide synthetase. Investigation of whole genome gene expression of the Fusarium fujikuroi wild type IMI58289, M-NM-^Tffsge1 mutant under nitrogen starvation and nitrogen sufficient conditions. In this study we hybridized in total 8 microarrays using total RNA recovered from a wild-type culture of F. fujikuroi IMI58289 and M-NM-^Tffsge1 mutant culture. All cultures were grown on a 6 mM Gln (10%) and a 60 mM Gln medium (100%). For each combination of culture and medium a biological replicate was created. Each chip measures the expression level of 14,397 genes from F. fujikuroi IMI58289 with eight 60-mer probes. Please note that the wild type samples have been published as part of the GEO accession GSE43745, but re-analyzed with the M-NM-^Tffsge1 mutant samples in the current study.

Project description:Ada1, Spt-Ada-Gcn5 Acetyltransferase (SAGA) complex component, was isolated as boundary factor that separated silenced chromatin and euchromatin by previous screening, and Ada1 maintains SAGA complex integrity. SAGA complex is one of a histone modification complex that has multiple functions contributing to transcriptional activation. In Saccharomyces cerevisiae, silencing is occurred by Sir protein complex, which deacetylates histones and form high-order chromatin structure. Gcn5, SAGA complex component, has histone acetyltransferase activity, which is considered that antagonize to silencing by the screening. Ada1 and Gcn5 might have different functions in SAGA complex, we performed microarray analysis to find different functions of gene regulations by using ada1Δ and gcn5Δ strains. As the results, Ada1-regulated genes include more than halves of Gcn5-regelated genes, which occupied only a part of Ada1 regulated genes. These suggest that the differences of contribution to SAGA functions. When SAGA complex have a loss of Ada1, almost function was lost. On the other hand, Gcn5 play a role only as acetyltransferase in SAGA complex.

Project description:Although the conserved histone acetyltransferase HAG1/GCN5-containing complex SAGA (Spt-Ada-Gcn5 acetyltransferase) has been extensively studied in plants, whether HAG1 forms a plant-specific complex is unknown. Here, we identified a plant-specific GCN5-containing complex, PAGA (plant-ADA2A-GCN5-acetyltransferase), in Arabidopsis thaliana; the complex consists of two conserved subunits (HAG1/GCN5 and ADA2A) and four plant-specific subunits (SPC, ING1, SDRL, and EAF6). In the PAGA complex, SPC functions as a scaffold protein that is responsible for integrating the other subunits. SPC also enhances the binding of ING1 to histone H3 with methylated lysine 4 and promotes the histone acetylation activity of HAG1. Chromatin immunoprecipitation followed by sequencing indicated that PAGA not only shares target genes with SAGA but also has its specific target genes. While PAGA and SAGA promote transcription by mediating moderate and high levels of histone acetylation, respectively, at different sets of genes, PAGA can also function antagonistically against SAGA to prevent excessive transcription of PAGA- and SAGA-shared target genes. Unlike SAGA, which regulates multiple biological processes, PAGA is mainly involved in plant height and branch growth by regulating the transcription of genes involved in hormone biosynthesis and response. These results indicate that the HAG1-containing SAGA and PAGA complexes are coordinated to regulate gene transcription and development.

Project description:Although the conserved histone acetyltransferase HAG1/GCN5-containing complex SAGA (Spt-Ada-Gcn5 acetyltransferase) has been extensively studied in plants, whether HAG1 forms a plant-specific complex is unknown. Here, we identified a plant-specific GCN5-containing complex, PAGA (plant-ADA2A-GCN5-acetyltransferase), in Arabidopsis thaliana; the complex consists of two conserved subunits (HAG1/GCN5 and ADA2A) and four plant-specific subunits (SPC, ING1, SDRL, and EAF6). In the PAGA complex, SPC functions as a scaffold protein that is responsible for integrating the other subunits. SPC also enhances the binding of ING1 to histone H3 with methylated lysine 4 and promotes the histone acetylation activity of HAG1. Chromatin immunoprecipitation followed by sequencing indicated that PAGA not only shares target genes with SAGA but also has its specific target genes. While PAGA and SAGA promote transcription by mediating moderate and high levels of histone acetylation, respectively, at different sets of genes, PAGA can also function antagonistically against SAGA to prevent excessive transcription of PAGA- and SAGA-shared target genes. Unlike SAGA, which regulates multiple biological processes, PAGA is mainly involved in plant height and branch growth by regulating the transcription of genes involved in hormone biosynthesis and response. These results indicate that the HAG1-containing SAGA and PAGA complexes are coordinated to regulate gene transcription and development.

Project description:to find functional relevance between SMC5/6 complex and SAGA histone acetyltransferase complex in Schizosaccharomyces pombe by chromatin immunoprecipitation of Nse4-FLAG tagged protein from gcn5, ubp8 and ada2 deletion strains and 2 control strains (WT - Nse4-FLAG, 501 - no tag).

Project description:The SAGA complex is a conserved multifunctional coactivator known to play broad roles in eukaryotic transcription. To gain new insights into its functions, we have performed biochemical and genetic analyses of SAGA in the fission yeast, Schizosaccharomyces pombe. Purification of the S. pombe SAGA complex showed that its subunit composition is identical to that of Saccharomyces cerevisiae. Analysis of S. pombe SAGA mutants revealed that SAGA has two opposing roles regulating sexual differentiation. First, in nutrient rich conditions, the SAGA histone acetyltransferase, Gcn5, represses ste11+, which encodes the master regulator of the mating pathway. In contrast, the SAGA subunit Spt8 is required for the induction of ste11+ upon nutrient starvation. Chromatin immunoprecipitation experiments suggest that these regulatory effects are direct, as SAGA is physically associated with the ste11+ promoter independent of nutrient levels. Genetic tests suggest that nutrient levels do cause a switch in SAGA function, as spt8? suppresses gcn5? with respect to ste11+ derepression in rich medium, whereas the opposite relationship, gcn5? suppression of spt8?, occurs during starvation. Thus, SAGA plays distinct roles in the control of the switch from proliferation to differentiation in S. pombe through the dynamic and opposing activities of Gcn5 and Spt8.

Project description:Filamentous fungi produce a vast array of secondary metabolites (SMs) and some of them are applied in agriculture or pharmacology. Recent sequencing of the rice pathogen Fusarium fujikuroi revealed the presence of far more SM-encoding genes than known products. SM production is energy-consuming and thus tightly regulated, leaving the majority of SM gene clusters silent under laboratory conditions. It is now well established that one important regulatory layer in SM biosynthesis involves histone modifications that render the genes either silent or poised for transcription. In this study, we show that the majority of the putative SM gene clusters in F. fujikuroi are located within facultative heterochromatin marked by H3K27me3. In this study, we performed comparative transcriptomics of a knock-down mutant of the responsible methyltransferase Kmt6 involved in H3K27 methylation grown on either solid complete medium or solid synthetic ICI medium. Overall four so far cryptic and otherwise silent putative SM gene clusters were significantly induced in the KMT6kd strain accompanied by reduced H3K27me3 levels at the respective gene loci and accumulation of novel metabolites. One of the four putative SM gene clusters, the STC5 gene cluster, was analysed in detail and heterologous expression of the key enzyme allowed for the identification of the first pathway-specific intermediate (1R,4R,5S)-guaia-6,10(14)-diene. 2 strains were analysed in overall two conditions, and each with 3 biological replicates

Project description:Investigation of whole genome gene expression level differences of Fusarium fujikuroi between wild-type and a Ffvel1 (velvet) deletion mutant in liquid medium with minimal nitrogen between 24 hr, 72 hr and 120 hr of growth using an array based on a F. verticillioides gene call set. Fusarium fujikuroi produces a number of secondary metabolites including gibberellins, bikaverin, fumonisin and fusarin C that are influenced by nitrogen availability and the velvet global regulatory complex. A twelve chip study using total RNA recovered from six cultures of wild-type Fusarium fujikuroi and six cultures of Ffvel1 F. fujikuroi deletion mutant. Each chip measures the expression level of over 13,000 putative genes with twelve 60-mer probes per sequence.

Project description:Investigation of whole genome gene expression level differences of Fusarium fujikuroi between wild-type and a Ffvel1 (velvet) deletion mutant in liquid medium with minimal nitrogen between 24 hr, 72 hr and 120 hr of growth using an array based on a F. verticillioides gene call set. Fusarium fujikuroi produces a number of secondary metabolites including gibberellins, bikaverin, fumonisin and fusarin C that are influenced by nitrogen availability and the velvet global regulatory complex.