Investigation of the induced-fit mechanism and catalytic activity of the human cytomegalovirus protease homodimer via molecular dynamics simulations.

Human cytomegalovirus (HCMV) is a highly species-specific DNA virus infecting up to 80% of the general population. The viral genome contains the open reading frame UL80, which encodes the full-length 80 kDa HCMV serine protease and its substrate. Full-length HCMV protease is composed of an N-terminal 256-amino-acid proteolytic domain, called assemblin, a linker region, and a C-terminal structural domain, the assembly protein precursor. Biochemical studies have shown that dimerization activates assemblin because of an induced stabilization of the oxyanion hole (Arg166). Thus, we performed here molecular dynamics (MD) simulations on HCMV protease models to study the induced-fit mechanism of the enzyme upon the binding of substrates and peptidyl inhibitors, and structural and energetic factors that are responsible for the catalytic activity of the enzyme dimer. Long and stable trajectories were obtained for the models of the monomeric and dimeric states, free in solution and bound to a peptidyl-activated carbonyl inhibitor, with very good agreement between theoretical and experimental results. Our results suggest that HCMV protease is indeed a novel example of serine protease that operates by an induced-fit mechanism. Also, in agreement with mutagenesis studies, our MD simulations suggest that the dimeric form is necessary to activate the enzyme because of an induced stabilization of the oxyanion hole.

Human Cytomegalovirus Protease: Why is the Dimer Required for Catalytic Activity?

Human cytomegalovirus (HCMV) is a pathogenic agent responsible for morbidity and mortality in immunocompromised and immunosuppressed individuals. HCMV encodes a serine protease that is essential for the production of infectious virions. In this work, we applied molecular dynamics (MD) simulations on HCMV protease models in order to investigate the experimentally observed (i) catalytic activity of the enzyme homodimer and (ii) induced-fit mechanism upon the binding of substrates and peptidyl inhibitors. Long and stable trajectories were obtained for models of the monomeric and dimeric states, free in solution and bound covalently and noncovalently to a peptidyl-activated carbonyl inhibitor, with very good agreement between theoretical and experimental results. The MD results suggest that HCMV protease indeed operates by an induced-fit mechanism. Also, our analysis indicates that the catalytic activity of the dimer is a result of more favorable interactions between the oxyanion in the covalently bound state and the backbone nitrogen of Arg165, resulting in a reaction that is 7.0 kcal/mol more exergonic and a more significant thermodynamic driving force. The incipient oxyanion in the transition state should also benefit from the stronger interactions with Arg165, reducing in this manner the intrinsic activation barrier for the reaction in the dimeric state.

Synthetic and theoretical studies on the reduction of electron withdrawing group conjugated olefins using the Hantzsch 1,4-dihydropyridine ester.

The Hantzsch 1,4-dihydropyridine ester (1) has been observed to be a useful selective reducing agent for the reduction of electron-withdrawing conjugated double bonds. The rate of this reaction was observed to be dependent upon the nature of the conjugated substituents and, consequently, the electronic nature of the unsaturated double bond. Theoretical calculations confirmed the importance of the HOMO-LUMO gap for this reaction and implicated a hydride transfer, agreeing with the experimentally observed reaction rate order. The calculations also revealed the importance of a boatlike structure of the 1,4-dihydropyridine nucleus as well as a trans arrangement of the ester groups to facilitate the hydride transfer.