Project description:DNA Immunoprecipitation was performed using purified, naked, genomic DNA and purified recombinant DNA binding domains for S. cerevisiae transcription factors (Cbf1, Leu3, Pho2, Pho4, Rap1, Rox1, and Swi5) and then competitively hybridized against input DNA on NimbleGen 385k whole-genome, 32bp, tiling arrays to identify the consensus sequence for each transcription factor as a whole in the genome.

Project description:DIP-chip from Cbf1, Leu3, Pho2, Pho4, Rap1, Rox1, and Swi5

Project description:The sequence specificity of DNA-binding proteins is the primary mechanism by which the cell recognizes genomic features. Here, we describe systematic determination of yeast transcription factor DNA-binding specificities. We obtained binding specificities for 112 DNA-binding proteins representing 19 distinct structural classes. One-third of the binding specificities have not been previously reported. Several binding sequences have striking genomic distributions relative to transcription start sites, supporting their biological relevance and suggesting a role in promoter architecture. Among these are Rsc3 binding sequences, containing the core CGCG, which are found preferentially ~100 bp upstream of transcription start sites. Mutation of RSC3 results in a dramatic increase in nucleosome occupancy in hundreds of proximal promoters containing a Rsc3 binding element, but has little impact on promoters lacking Rsc3 binding sequences, indicating that Rsc3 plays a broad role in targeting nucleosome exclusion at yeast promoters. Keywords: Protein binding microarrays, DNA, proteins Protein binding microarray (PBM), ChIP-chip and DIP-chip experiments of yeast transcription factor DNA-binding domains were performed. Briefly, the PBMs involved binding GST-tagged DNA-binding proteins to custom-designed, double-stranded 44K Agilent microarrays in order to determine their sequence preferences. The method is described in Berger et al., Nature Biotechnology 2006. A key feature is that the microarrays are composed of de Bruijn sequences that contain each 10-base sequence once and only once, providing an evenly balanced sequence distribution. Individual de Bruijn sequences have different properties, including representation of gapped patterns. Here we provide the data transformed into median intensities for all 32,896 8-base sequences, Z-scores for these intensities, and E-scores. E-scores are a modified version of AUC, and describe how well each 8-mer ranks the intensities of the spots. In general the E-scores are slightly more reproducible than Z-scores, but contain less information about relative binding affinity. Additional experimental details are found in Berger et al., Nature Biotechnology 2006, Berger et al., Cell 2008, and the accompanying Supplementary information. Raw 35-mer array data is available on the web link provided. For the DIP-chip experiments [GSM345371, GSM345403, GSM345414-GSM345421, GSM345429-GSM345432], genomic DNA isolated from S288C yeast was incubated with 40nM of the MBP-tagged DNA binding domain (DBD) of either Cbf1, Pho2, Pho4, Leu3, Rap1, or Swi5 and incubated for 30 minutes prior to purification of protein-DNA complexes. The bound DNA was then isolated, amplified via Invitrogen's WGA protocol, and hybridized against input DNA on NimbleGen 385k 32bp-tiling whole genome arrays. ChIPOTle was used to identify peaks of binding from the data and motifs were identified by BioProspector and MDScan and then scored for their ability to predict the identified peaks by GOMER. Motifs with the best ROC AUC are reported in the paper. For the ChIP-chip experiments [GSM346493 and GSM346494], isogenic wildtype and rsc3-1 strains carrying Rsc8-TAP were grown in parallel under rsc3-1 restrictive growth conditions (37°C). Following formaldehyde crosslinking, cells were homogenized and extracts were sonicated to shear the chromatin to an average size of ~500 bp. A single pulldown was then performed with IgG sepharose beads and after decrosslinking and LM-PCR amplification of purified IP DNA, samples were labeled and hybridized on Nimblegen 32bp whole genome tiling arrays, comparing the pulled-down DNA to input genomic DNA.

Project description:In S. cerevisiae, the phosphate starvation (PHO) responsive transcription factors Pho4 and Pho2 are jointly required for induction of phosphate response genes and survival in phosphate starvation conditions. In the related human commensal and pathogen C. glabrata, Pho4 is required but Pho2 is dispensable for survival in phosphate-limited conditions and is only partially required for inducing the phosphate response genes. This reduced dependence on Pho2 evolved in C. glabrata and closely related species. Pho4 orthologs that are less dependent on Pho2 induce more genes when introduced into the S. cerevisiae background, and Pho4 in C. glabrata both binds to more sites and induces more genes with expanded functional roles compared to Pho4 in S. cerevisiae. We used RNA-seq to profile the transcriptome of wild type and mutants of Pho4 / Pho2 in C. glabrata, to identify genes induced by Pho4.

Project description:In S. cerevisiae, the phosphate starvation (PHO) responsive transcription factors Pho4 and Pho2 are jointly required for induction of phosphate response genes and survival in phosphate starvation conditions. In the related human commensal and pathogen C. glabrata, Pho4 is required but Pho2 is dispensable for survival in phosphate-limited conditions and is only partially required for inducing the phosphate response genes. This reduced dependence on Pho2 evolved in C. glabrata and closely related species. Pho4 orthologs that are less dependent on Pho2 induce more genes when introduced into the S. cerevisiae background, and Pho4 in C. glabrata both binds to more sites and induces more genes with expanded functional roles compared to Pho4 in S. cerevisiae. We used RNA-seq to profile the transcriptome of wild type and mutants of Pho4 / Pho2, or Pho4 ortholog swap in S. cerevisiae, to identify genes induced by Pho4 or its orthologs in S. cerevisiae background.

Project description:In S. cerevisiae, the phosphate starvation (PHO) responsive transcription factors Pho4 and Pho2 are jointly required for induction of phosphate response genes and survival in phosphate starvation conditions. In the related human commensal and pathogen C. glabrata, Pho4 is required but Pho2 is dispensable for survival in phosphate-limited conditions and is only partially required for inducing the phosphate response genes. This reduced dependence on Pho2 evolved in C. glabrata and closely related species. Pho4 orthologs that are less dependent on Pho2 induce more genes when introduced into the S. cerevisiae background, and Pho4 in C. glabrata both binds to more sites and induces more genes with expanded functional roles compared to Pho4 in S. cerevisiae. We used Chromatin-ImmunoPrecipitation with exonucleas followed by high-throughput sequencing (BioChIP-seq) to identify the binding locations of Pho4 from both S. cerevisiae and C. glabrata in the S. cerevisiae background lacking the negative regulator Pho80, and either with or without Pho2.

Project description:In S. cerevisiae, the phosphate starvation (PHO) responsive transcription factors Pho4 and Pho2 are jointly required for induction of phosphate response genes and survival in phosphate starvation conditions. In the related human commensal and pathogen C. glabrata, Pho4 is required but Pho2 is dispensable for survival in phosphate-limited conditions and is only partially required for inducing the phosphate response genes. This reduced dependence on Pho2 evolved in C. glabrata and closely related species. Pho4 orthologs that are less dependent on Pho2 induce more genes when introduced into the S. cerevisiae background, and Pho4 in C. glabrata both binds to more sites and induces more genes with expanded functional roles compared to Pho4 in S. cerevisiae. We used Biotin-assisted Chromatin-ImmunoPrecipitation followed by high-throughput sequencing (BioChIP-seq) to identify the binding locations of Pho4 from both S. cerevisiae and C. glabrata in the S. cerevisiae background lacking the negative regulator Pho80, and either with or without Pho2.

Project description:Binding of transcription factors to DNA is a key regulatory step in the control of gene expression. DNA sequences with high affinity for transcription factors occur more frequently in the genome than instances of genes bound or regulated by these factors. How specific gene regulation is achieved by transcription factors remains unclear. We used genome-wide approaches to study how trans factors shape the binding and regulatory landscape of Pho4, a budding yeast transcription factor that activates gene expression in response to phosphate limitation. In no phosphate (0mM phosphate) medium, Pho4 is transported into the nucleus and activates transcription of a set of genes (PHO) that are necessary for cell survival in phosphate limited environment. In high phosphate (10mM phosphate) medium, Pho4 is transported outside of the nucleus and the transcription program of PHO genes are turned off. Here we examined the transcription profiling of S. cerevisiae (W303) in various strains treated in media with 10mM or 0mM inorganic phosphate, to study the the transcription activation by Pho4 its cooperative binding factor Pho2, and its competitive binding factor Cbf1. (I) To infer how much Pho4 itself, Pho2 itself, and the interaction between Pho2 and Pho4 contribute to transcriptional activation in response to Pi starvation, we applied mutant cycle analysis to compare wild type, pho2Δ, pho4Δ and pho2Δ pho4Δ strains in both 10 mM and 0 mM Pi conditions. Mutant cycle analysis is a cyclic comparison among all various mutants. For example, by comparing pho2Δ and pho2Δ pho4Δ, we can directly infer the contribution from Pho4 alone to gene activation. And by comparing wild type and pho2Δ, we can infer the contribution from Pho2 alone together with that from the interaction between Pho2 and Pho4. (II) Compare two strains or one strain in two treatments in multiple replicates with dye-swap method. wt no vs high Pi, to identify genes that are induced in response to Pi starvation. cbf1Δ vs wt in high Pi, to identify the influence of Cbf1 on gene expression in high Pi condition. cbf1Δpho4Δ vs wt in high Pi, to identify the influence of Cbf1 on gene expression that is mediated through Pho4, in high Pi condition. rtg3Δtye7Δ vs wt in high Pi, to identify the influence of Rtg3 and Tye7 on gene expression in high Pi condition. pho80Δ vs pho80Δpho4Δ, to identify the genes that are activated Pho4 when Pho4 is fully nuclear localized. pho80Δcbf1Δ vs pho80Δcbf1Δpho4Δ, to identify the influence of Cbf1 on gene expression that is mediated through Pho4, when Pho4 is fully nuclear localized.

Project description:Binding of transcription factors to DNA is a key regulatory step in the control of gene expression. DNA sequences with high affinity for transcription factors occur more frequently in the genome than instances of genes bound or regulated by these factors. Although several mechanisms have been identified that influence the specificity of transcriptional regulation, it is not known if these can explain the observed genome-wide pattern of binding or regulation for a given transcription factor. We used genome-wide approaches to study how trans influences shape the binding and regulatory landscape of Pho4, a budding yeast transcription factor that activates gene expression in response to phosphate limitation. We find that nucleosomes significantly restrict the sites to which Pho4 binds. At nucleosome-depleted sites, competition between Pho4 and another transcription factor, Cbf1, determines Pho4 occupancy, raising the threshold for transcriptional activation by Pho4 in phosphate replete conditions and preventing Pho4 activation of genes outside the phosphate regulon during phosphate starvation. Pho4 binding is not sufficient for transcriptional activation - a cooperative interaction between the transcription factor Pho2 and Pho4 occurs specifically at genes that are activated. Combining these experimental observations, we are able to globally predict Pho4 binding and its functionality. Our study provides insights into the mechanisms of global control by sequence-specific transcription factors. ChIP-Seq experiments of Pho4, Pho2 and Cbf1 samples and paired-end nucleosome sequencing in no Pi conditions.

Project description:Binding of transcription factors to DNA is a key regulatory step in the control of gene expression. DNA sequences with high affinity for transcription factors occur more frequently in the genome than instances of genes bound or regulated by these factors. Although several mechanisms have been identified that influence the specificity of transcriptional regulation, it is not known if these can explain the observed genome-wide pattern of binding or regulation for a given transcription factor. We used genome-wide approaches to study how trans influences shape the binding and regulatory landscape of Pho4, a budding yeast transcription factor that activates gene expression in response to phosphate limitation. We find that nucleosomes significantly restrict the sites to which Pho4 binds. At nucleosome-depleted sites, competition between Pho4 and another transcription factor, Cbf1, determines Pho4 occupancy, raising the threshold for transcriptional activation by Pho4 in phosphate replete conditions and preventing Pho4 activation of genes outside the phosphate regulon during phosphate starvation. Pho4 binding is not sufficient for transcriptional activation - a cooperative interaction between the transcription factor Pho2 and Pho4 occurs specifically at genes that are activated. Combining these experimental observations, we are able to globally predict Pho4 binding and its functionality. Our study provides insights into the mechanisms of global control by sequence-specific transcription factors.