Phage-Assisted, Active Site-Directed Ligand Evolution with a Genetically Encoded Nε-Butyryl-L-Lysine to Identify a Cellularly Potent and Selective Inhibitor for the ENL YEATS Domain as an Anti-Leukemia Agent

Eleven-nineteen leukemia protein (ENL) plays pivotal roles in the leukemogenesis. As a YEATS domain protein, ENL reads histone acylation marks and recruits key transcription factors to leukemic drivers such as HOXA9, MEIS1 , and MYB and therefore promotes leukemia development. The histone-reading function of ENL has been proven essential in the onset and progression of several acute leukemias, suggesting a putative therapeutic window for ENL inhibition. In this study, we developed a phage-assisted, active site-directed ligand evolution (PADLE) approach for the identification of potent and selective ENL inhibitors, where N ε-butyryl-l-lysine (BuK) that possesses known target-protein interactions with the ENL YEATS domain was genetically incorporated into a phage display library to serve as a warhead to direct displayed peptides to the active site of ENL YEATS for enrichment. Using this novel strategy in combination with structure-activity relationship that replaced BuK with other ncAAs for de novo π-π-π stacking interactions with two aromatic residues in ENL YEATS, selective and potent ENL inhibitors with a K d value as low as 2.0 nM were identified. One pentapeptide inhibitor tENL-S1f displayed selective inhibition of ENL over other YEATS domains as well as strong cellular target engagement and on-target effects in inhibiting leukemia cell growth and suppressing the expression of ENL target genes. As the first of its kind study, the current work opens a large avenue of research of using PADLE to develop selective and potent peptidyl inhibitors for a large variety of epigenetic reader proteins. ### Competing Interest Statement The authors have declared no competing interest.