Abstract
Proteolysis-targeting chimeras (PROTACs) represent a promising therapeutic modality, but their clinical translation is often hindered by poor pharmacokinetic properties associated with their location in the "beyond Rule of 5" chemical space. Using the BRD4 degrader dBET1 as a model, this study explored a dual approach to improve the cellular permeability of PROTACs by combining amide-to-ester substitution with the strategic linker methylation to induce stereochemistry-driven conformational modulation. Substitution with ester enhanced both permeability and degradation potency, while methylation afforded two diastereomers with different permeability profiles. Steered molecular dynamics and enhanced conformational sampling in polar and nonpolar environments revealed distinct chameleonic behaviors, with the more permeable diastereomer 2b adopting folded conformations with a lower solvent-accessible 3D polar surface area in the nonpolar environment. These findings were supported by 2D NMR and hydrogen-bond acidity analyses (A(NMR)). Notably, low-energy "congruent conformation" accessible in both environments was identified for 2b. This work establishes a viable strategy for the design of membrane-permeable PROTACs.