Intrinsically disordered regions of transcription factor encode multiple functions using interwoven sequence grammars (RNA-Seq)

Intrinsically disordered regions (IDRs) are abundant within eukaryotic proteins, but their sequence-function relationship remains poorly understood. IDRs of transcription factors (TFs) can direct promoter selection and recruit coactivators, as exemplified by the budding-yeast TF- Msn2. To examine how low-complexity IDRs encode multiple functions, we compared genomic binding preferences, gene induction, and coactivator recruitment amongst a large set of designed Mns2-IDR mutants. We show that multiple regions across the >500AA IDR contribute to both functions. Yet, transcription activity was readily disrupted by variants having no consequences on Msn2 binding. Our data attribute this differential sensitivity to the integration of relaxed, composition-based code directing binding preferences with a more stringent, motif-based code controlling the recruitment of coactivators and transcription activity. Interwoven sequence grammar may present a general paradigm through which low-complexity IDRs encode multiple functions. The experimetns here are RNA-seq samples, collection of samples was performed at OD600 of 0.4 after treatment with 0.3 mM of H2O2 to induce stress, for controls we used the expresion profiling of non-genetically modified yeast strain (BY4741) or ΔMsn2