MICRO-TAG enzyme complementation enables quantification of cellular drug-target engagement in temperature series

Drug discovery for challenging drug targets necessitates the proteomic complexities of the cellular milieu for contextual target folding and function. Conventional biophysical methods for assessing drug interaction with a target are often not sufficiently suited for drug discovery as they impose acellular environment on the target and rely on recombinant purified protein material. In contrast, cell target engagement offers a powerful paradigm for drug discovery, through measurement of transitions in the thermodynamic state of a target protein, as it engages with drug molecules in the cell. Split-enzyme cell target engagement methods offer scaled utility during early drug discovery. Here, we describe a novel highly sensitive and scalable fluorescence-based cell target engagement method that leverages complementation of split-RNase S. This offers a unique combination of procedural and biophysical advantages, enabling its seamless integration with various instruments and applications designed for fluorescence detection. Most importantly, this new method allows for quantitation of cell target engagement in programmable temperature series format, consistent with conventional thermal shift assays, rather than at a single melting temperature. We demonstrate the sensitivity and versatility of this approach for drug discovery using targets MAPK1, KRAS, and UBE2N.