The Non-Coding B2 RNA Binds to the DNA Cleft and Active-Site Region of RNA Polymerase II

The B2 family of short interspersed elements is transcribed into non-coding RNA by RNA polymerase III. The ~ 180-nt B2 RNA has been shown to potently repress mRNA transcription by binding tightly to RNA polymerase II (Pol II) and assembling with it into complexes on promoter DNA, where it keeps the polymerase from properly engaging the promoter DNA. Mammalian Pol II is an ~ 500-kDa complex that contains 12 different protein subunits, providing many possible surfaces for interaction with B2 RNA. We found that the carboxy-terminal domain of the largest Pol II subunit was not required for B2 RNA to bind Pol II and repress transcription in vitro. To identify the surface on Pol II to which the minimal functional region of B2 RNA binds, we coupled multi-step affinity purification, reversible formaldehyde cross-linking, peptide sequencing by mass spectrometry, and analysis of peptide enrichment. The Pol II peptides most highly recovered after cross-linking to B2 RNA mapped to the DNA binding cleft and active-site region of Pol II. These studies determine the location of a defined nucleic acid binding site on a large, native, multi-subunit complex and provide insight into the mechanism of transcriptional repression by B2 RNA.

Graphical AbstractFigure optionsDownload full-size imageDownload high-quality image (209 K)Download as PowerPoint slideHighlights► The non-coding B2 RNA potently represses mRNA transcription by binding tightly to mammalian RNA Pol II; however, the precise sites on Pol II to which B2 RNA binds was unknown. ► We used reversible formaldehyde cross-linking coupled to mass spectrometry to identify the Pol II peptides that bind directly to the minimal functional region of B2 RNA. ► A label-free peptide quantitation approach revealed which of the cross-linked peptides were most highly enriched. ► Mapping these peptides onto a crystal structure of yeast Pol II showed that B2 RNA associates with a surface of Pol II containing the DNA binding cleft and active-site region, providing fundamental insight into how B2 RNA represses transcription.