Transcriptomics

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Meiosis timecourse Rap1-depletion expression profile


ABSTRACT: To investigate the impact of Rap1 binding on nearby gene expression during the transition from vegetative growth to meiosis, we measured RNA abundance in cells depleted (plus doxycycline) or not depleted (minus doxycycline) of Rap1. RNA abundance was measured in depleted and non-depleted condition in respiratory cells (pre-meiotic/YPA 20 hours) and in cells undergoing synchronous meiosis/sporulation in the budding yeast Saccharomyces cerevisiae. There is growing recognition that the binding of a transcription factor near a gene does not always indicate regulatory function, and further that a single factor may function to either activate or repress its targets depending on the cellular context. We examined these issues through a series of experiments involving the S. cerevisiae transcription factor Rap1, and its function throughout critical metabolic and developmental transitions between vegetative growth, respiratory growth, meiosis and sporulation. We simultaneously monitored the expression of all genes and the genomic binding locations of Rap1 throughout the timecourse. Genes downstream of Rap1 binding were activated and repressed dynamically, but a change - or lack of change - in Rap1 binding status was not predictive of activation, repression, or no change in regulation. Despite this, we show that Rap1 is required, at a given point in time, for both activation and repression of different gene targets, within the same cell. Specification of the transcriptional consequences of Rap1 binding is thus highly promoter-specific. The presence of other transcription factor binding motifs, the subtype of Rap1 motif, and the underlying chromatin structure of the promoter cannot fully account for the observed transcriptional outcomes. There is a better accounting for the dynamic binding behavior of Rap1 including specification of an expanded meiotic target set through a Tup1- dependent nucleosome-loss mechanism. The variable and dynamic association between binding and transcription in this simple unicellular system portends a similarly volatile relationship in more complex eukaryotes. Biological interpretations of transcription factor occupancy should be made cautiously and in conjunction with supporting data obtained under the precise condition of interest.

ORGANISM(S): Saccharomyces cerevisiae Saccharomyces cerevisiae SK1

PROVIDER: GSE75259 | GEO | 2016/09/01

SECONDARY ACCESSION(S): PRJNA302919

REPOSITORIES: GEO

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