Discrimination of yeast genes involved in methionine and phosphate metabolism on the basis of upstream motifs

MOTIVATION: In yeast, methionine and phosphate metabolism are regulated by the complexes Met4p/Met28p/Cbf1p and Pho4p, respectively. The binding sites for these factors share a common core CACGTG. We evaluate our capability to discriminate phosphate- and methionine-responding genes on the basis of putative regulatory elements, despite the similarity between Met4p/Met28p/Cbf1p and Pho4p consensus. RESULTS: We scanned upstream regions of methionine, phosphate and control genes with position-specific weight matrices for Pho4p, Met4p/Met28p/Cbf1p and Met31p/Met32p, and applied discriminant analysis to classify genes according to matrix matching scores. This analysis showed that matrix scores provided a good discrimination between phosphate, methionine and control genes. The optimal parameters have then been used to predict phosphate and methionine regulation at a genome scale. The genome-scale analysis predicts 37 genes as methionine-regulated and 40 as phosphate-regulated. We compare the predictive results with high throughput data and discuss the difference. AVAILABILITY: The programs for sequence retrieval and analysis, as well as the complete data and results, are available on the website on regulatory sequence analysis tools (http://rsat.scmbb.ulb.ac.be/rsat/). CONTACT: jvanheld@scmbb.ulb.ac.be SUPPLEMENTARY INFORMATION: The complete datasets and results are available at http://rsat.scmbb.ulb.ac.be/rsat/data/published_data/Gonze_MET_PHO/     

Cbf1p is required for chromatin remodeling at promoter-proximal CACGTG motifs in yeast

Cbf1p is a basic-helix-loop-helix-zipper protein of Saccharomyces cerevisiae required for the function of centromeres and MET gene promoters, where it binds DNA via the consensus core motif CACRTG (R = A or G). At MET genes Cbf1p appears to function in both activator recruitment and chromatin-remodeling. Cbf1p has been implicated in the regulation of other genes, and CACRTG motifs are common in potential gene regulatory DNA. A recent genome-wide location analysis showed that the majority of intergenic CACGTG palindromes are bound by Cbf1p. Here we tested whether all potential Cbf1p binding motifs in the yeast genome are likely to be bound by Cbf1p using chromatin immunoprecipitation. We also tested which of the motifs are actually functional by assaying for Cbf1p-dependent chromatin remodeling. We show that Cbf1p binding and activity is restricted to palindromic CACGTG motifs in promoter-proximal regions. Cbf1p does not function through CACGTG motifs that occur in promoter-distal locations within coding regions nor where CACATG motifs occur alone except at centromeres. Cbf1p can be made to function at promoter-distal CACGTG motifs by overexpression, suggesting that the concentration of Cbf1p is normally limiting for binding and is biased to gene regulatory DNA by interactions with other factors. We conclude that Cbf1p is required for normal nucleosome positioning wherever the CACGTG motif occurs in gene regulatory DNA. Cbf1p has been shown to interact with the chromatin-remodeling ATPase Isw1p. Here we show that recruitment of Isw1p by Cbf1p is likely to be general but that Isw1p is only partially required for Cbf1p-dependent chromatin structures.