Mimicking H3 Substrate Arginine in the Design of G9a
Lysine Methyltransferase Inhibitors for Cancer Therapy: A Computational
Study for Structure-Based Drug Design
G9a protein methyltransferase
is a potential epigenetic drug target
in different cancers and other disease conditions overexpressing the
enzyme. G9a is responsible for the H3K9 dimethylation mark, which
epigenetically regulates gene expression. Arg8 and Lys9 of the H3
substrate peptide are the two crucial residues for substrate-specific
recognition and methylation. Several substrate competitive inhibitors
are reported for the potent inhibition of G9a by incorporating lysine
mimic groups in the inhibitor design. In this study, we explored the
concept of arginine mimic strategy. The hydrophobic segment of the
reported inhibitors BIX-01294 and UNC0638 was replaced by a guanidine
moiety (side-chain moiety of arginine). The newly substituted guanidine
moieties of the inhibitors were positioned similar to the Arg8 of
the substrate peptide in molecular docking. Additionally, improved
reactivity of the guanidine-substituted inhibitors was observed in
density functional theory studies. Molecular dynamics, molecular mechanics
Poisson–Boltzmann surface area binding free energy, linear
interaction energy, and potential mean force calculated from steered
molecular dynamics simulations of the newly designed analogues show
enhanced conformational stability and improved H-bond potential and
binding affinity toward the target G9a. Moreover, the presence of
both lysine and arginine mimics together shows a drastic increase
in the binding affinity of the inhibitor towards G9a. Hence, we propose
incorporating a guanidine group to imitate the substrate arginine’s
side chain in the inhibitor design to improve the potency of G9a inhibitors.