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Screening thousands of transcribed coding and non-coding regions reveals sequence determinants of RNA polymerase II elongation potential.

Hanneke VlamingClaudia A MimosoAndrew R FieldBenjamin J E MartinKaren Adelman
Published in: Nature structural & molecular biology (2022)
Precise regulation of transcription by RNA polymerase II (RNAPII) is critical for organismal growth and development. However, what determines whether an engaged RNAPII will synthesize a full-length transcript or terminate prematurely is poorly understood. Notably, RNAPII is far more susceptible to termination when transcribing non-coding RNAs than when synthesizing protein-coding mRNAs, but the mechanisms underlying this are unclear. To investigate the impact of transcribed sequence on elongation potential, we developed a method to screen the effects of thousands of INtegrated Sequences on Expression of RNA and Translation using high-throughput sequencing (INSERT-seq). We found that higher AT content in non-coding RNAs, rather than specific sequence motifs, drives RNAPII termination. Further, we demonstrate that 5' splice sites autonomously stimulate processive transcription, even in the absence of polyadenylation signals. Our results reveal a potent role for the transcribed sequence in dictating gene output and demonstrate the power of INSERT-seq toward illuminating these contributions.
Keyphrases
  • genome wide
  • rna seq
  • single cell
  • amino acid
  • high throughput sequencing
  • transcription factor
  • dna methylation
  • high throughput
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  • human health
  • copy number
  • anti inflammatory
  • climate change