Characterization of the Human Cytomegalovirus Protease As an Induced-Fit Serine Protease and the Implications to the Design of Mechanism-Based Inhibitors

Abstract

The conformational properties of the N-tert-butylacetyl-l-tert-butylglycyl-l-Nδ,Nδ-dimethylasparagyl-l-alanyl methyl ketone (MK) 1 and its terminal N-isopropylacetyl analogue 2 were investigated. Whereas these compounds are weak (mM IC50 range) inhibitors of the human cytomegalovirus (HCMV) protease, their activated carbonyl analogues are >1000-fold more potent (e.g., trifluoromethyl ketone 3, IC50 = 1.1 μM). A combination of NMR techniques demonstrated that MK 2 exists in solution as a relatively rigid and extended peptide structure and that the bulky side chains, notably the P3 tert-butyl group, greatly contribute to maintaining this solution conformation. Furthermore, transferred nuclear Overhauser effect (TRNOE) studies provided an enzyme-bound conformation of MK 2 that was found to be similar to its free solution structure and compares very well to the X-ray crystallographic structure of a related peptidyl inhibitor complexed to the enzyme. The fact that ligands such as MK 2 exist in solution in the bioactive conformation accounts, in part, for the observed inhibitory activity of activated ketone inhibitors bearing comparable peptidyl sequences. Comparison of the X-ray structures of HCMV protease apoenzyme and that of its complex with a related peptidyl α-ketoamide inhibitor allowed for a detailed analysis of the previously reported conformational change of the enzyme upon complexation of inhibitors such as 1 and 3. The above observations indicate that HCMV protease is a novel example of a serine protease that operates by an induced-fit mechanism for which complexation of peptidyl ligands results in structural changes which bring the enzyme to a catalytically active (or optimized) form. Kinetic and fluorescence studies are also consistent with an induced-fit mechanism in which a considerable proportion of the intrinsic ligand-binding energy is used to carry out the conformational reorganization of the protease. Issues related to the rational design of both mechanism- and nonmechanism-based inhibitors of HCMV protease, notably in light of the peptidyl ligand-induced optimization of its catalytic functioning, are discussed.