Philip Versluis scite author profile

24Tracking active transcription with the nuclear run-on (NRO) assays has been instrumental in 25 uncovering mechanisms of gene regulation. The coupling of NROs with high-throughput 26 sequencing has facilitated the discovery of previously unannotated or undetectable RNA classes 27 genome-wide. Precision run-on sequencing (PRO-seq) is a run-on variant that maps polymerase 28 active sites with nucleotide or near-nucleotide resolution. One main drawback to this and many 29 other nascent RNA detection methods is the somewhat intimidating multi-day workflow 30 associated with creating the libraries suitable for high-throughput sequencing. Here, we present 31an improved PRO-seq protocol where many of the enzymatic steps are carried out while the 32 biotinylated NRO RNA remains bound to streptavidin-coated magnetic beads. These 33 adaptations reduce time, sample loss and RNA degradation, and we demonstrate that the 34 resulting libraries are of the same quality as libraries generated using the original published 35protocol. The assay is also more sensitive which permits reproducible, high-quality libraries from 36 10 4 -10 5 cells instead of 10 6 -10 7 . Altogether, the improved protocol is more tractable allows for 37 nascent RNA profiling from small samples, such as rare samples or FACS sorted cell 38populations. 39 40

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PRO-IP-seq Tracks Molecular Modifications of Engaged Pol II Complexes at Nucleotide Resolution

Vihervaara

Versluis

Lis

2023

Preprint

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RNA Polymerase II (Pol II) is a multi-subunit complex that undergoes covalent modifications as transcription proceeds through genes and enhancers. Rate-limiting steps of transcription control Pol II recruitment, site and degree of initiation, pausing duration, productive elongation, nascent transcript processing, transcription termination, and Pol II recycling. Here, we developed Precision Run-On coupled to Immuno-Precipitation sequencing (PRO-IP-seq) and tracked phosphorylation of Pol II C-terminal domain (CTD) at nucleotide-resolution. We uncovered precise positional control of Pol II CTD phosphorylation as transcription proceeds from the initiating nucleotide, through early and late promoter-proximal pause, and into productive elongation. Pol II CTD was predominantly unphosphorylated in the early pause-region, whereas serine-2- and serine-5-phosphorylations occurred preferentially in the later pause-region. Serine-7-phosphorylation dominated after the pause-release in a region where Pol II accelerates to its full elongational speed. Interestingly, tracking transcription upon heat-induced reprogramming demonstrated that Pol II with phosphorylated CTD remains paused on heat-repressed genes.

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

2022

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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.

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Philip Versluis

A rapid, sensitive, scalable method for Precision Run-On sequencing (PRO-seq)

PRO-IP-seq Tracks Molecular Modifications of Engaged Pol II Complexes at Nucleotide Resolution

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

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