Insight into the intrinsically disordered transactivation domain of NFkB as a regulator of DNA binding using UV-induced unnatural amino acid crosslinking.

Abstract

Within our vast genome, specific transcription factors like NFkB manage to find target sequences amongst overwhelming nonspecific options and help elicit timely cellular responses. A transcription factor's binding affinity for specific vs. nonspecific DNA must therefore be in a delicate balance to facilitate this search. Key in vitro experiments that described these binding affinities for the dominant NFkB dimer RelA/p50 were carried out with a truncated version of RelA - excluding a large intrinsically disordered transactivation domain (TAD) that was believed to be important for transcription activation through cofactor interactions but not impactful for DNA binding. This fit with a traditional view of protein domains acting as modular units. More recently, however, we discovered a novel function of the TAD: binding experiments revealed that the TAD's presence increased RelA/p50's affinity for DNA, with the strongest increase in binding affinity observed for non-specific DNA sequences lacking kB consensus sites. Here we follow up these findings with an investigation of the TAD's mechanism of action. We present preliminary results using an unnatural amino acid crosslinker (p-benzoyl-l-phenylalanine or pBpF) in combination with mass spectrometry to probe TAD interactions that lead to the observed changes in DNA binding affinity and specificity. pBpF is incorporated into specific positions in the TAD using AMBER codon suppression, and crosslinking is initiated by UV light. Interactions are analyzed by mass spectrometry to identify key sites of contact between the TAD and the natively folded Rel-Homology Domain.