Measuring the precise position of transitions in transcription with PRO‐IP‐seq

Abstract

Transcription is a fundamental process for all known organisms. Transcription by RNA Polymerase II (Pol II), the enzyme responsible for mRNA synthesis, is highly regulated by protein factors at every step. In multicellular eukaryotes, Pol II pauses 20‐60 bases downstream of the transcription start site in nearly all genes. This promoter‐proximal pausing is established as an important step in transcription regulation and is dependent on several pausing and elongation factors. The protein complexes DSIF (DRB Sensitivity Inducing Factor) and NELF (Negative Elongation Factor) bind to Pol II early in transcription to induce pausing. Pause release occurs upon phosphorylation of Pol II, DSIF and NELF by the Cdk9, Cyclin T1 heterodimer P‐TEFb (Positive Transcription Elongation Factor b). Although Pol II pausing is a key step in transcription regulation and has been extensively studied, the molecular mechanisms of pause and pause release are incompletely understood. Furthermore, recent studies have implicated controlled termination early in the gene as a mechanism to control transcription. A challenge to studying these key regulatory steps is that they occur in a narrow window: from initiation to Pol II pausing and release occurs in 20‐60 base range. Current approaches to study transcription factor interactions are unable to provide high enough resolution or sensitivity to address precisely where key transitions in transcription occur.To address this problem, I am developing an assay to measure the exact position of Pol II, when it is bound by a factor of interest. The technique couples our lab’s Precision Run‐on sequencing technique (PRO‐seq), which measures the position of active Pol II with single base‐pair resolution, and an immunoprecipitation enrichment step. Initial PRO‐IP‐seq (Precision Run‐on Immunoprecipitation sequencing) data shows that we can enrich for populations of Pol II bound by specific transcription factors. Utilizing this tool, we will be able to measure genomically where both stable and more transient transcription factors interact with Pol II at near single‐base resolution.