Theoretical Approximation to the Reaction Mechanism of Adenosine Deaminase

Effects of substitutions at the 4' and 2 positions on the bioactivity of 4'-ethynyl-2-fluoro-2'-deoxyadenosine

Nucleos(t)ide reverse transcriptase inhibitors (NRTIs) form the backbone of most anti-HIV therapies. We have shown that 4'-ethynyl-2-fluoro-2'-deoxyadenosine (EFdA) is a highly effective NRTI; however, the reasons for the potent antiviral activity of EFdA are not well understood. Here, we use a combination of structural, computational, and biochemical approaches to examine how substitutions in the sugar or adenine rings affect the incorporation of dA-based NRTIs like EFdA into DNA by HIV RT and their susceptibility to deamination by adenosine deaminase (ADA). Nuclear magnetic resonance (NMR) spectroscopy studies of 4'-substituted NRTIs show that ethynyl or cyano groups stabilize the sugar ring in the C-2'-exo/C-3'-endo (north) conformation. Steady-state kinetic analysis of the incorporation of 4'-substituted NRTIs by RT reveals a correlation between the north conformation of the NRTI sugar ring and efficiency of incorporation into the nascent DNA strand. Structural analysis and the kinetics of deamination by ADA demonstrate that 4'-ethynyl and cyano substitutions decrease the susceptibility of adenosine-based compounds to ADA through steric interactions at the active site. However, the major determinant for decreased susceptibility to ADA is the 2-halo substitution, which alters the pKa of N1 on the adenine base. These results provide insight into how NRTI structural attributes affect their antiviral activities through their interactions with the RT and ADA active sites.

Molecular recognition of modified adenine nucleotides by the P2Y(1)-receptor. 2. A computational approach

The molecular recognition of C2- or C8-substituted ATP derivatives by the P2Y(1)-receptor (P2Y(1)-R) is analyzed using ab initio quantum mechanical calculations. Parameters that may determine ligand specificity toward P2Y(1)-R were examined on reduced models and correlated with the biochemical data for the parent compounds. These include tautomerism and protonation energy in the gas and aqueous phases, as well as molecular electrostatic potential (MEP) and dipole moment vector. The calculated electronic parameters cannot explain the inactivity of the C8-substituted ATP derivatives, nor the difference in activity among the C2-substituted ATP analogues. These results indicate that neither tautomerism nor changes in the electronic distribution of the adenine ring play a major role in determining binding specificity of adenine nucleotides to the receptor. It is suggested that the higher potency of the C2-substituted ATP derivatives, compared to ATP, might be due to interaction between the C2 side chain heteroatom and the receptor. Furthermore, the interaction of the C2 alkyl side chain with a hydrophobic pocket at the receptor binding site is suggested. In addition, NMR data in the companion paper indicate that the inactivity of the C8-substituted ATP analogues may be due to steric and conformational, rather than electronic, effects.

Experimental and modelling studies on the DNA cleavage by elsamicin A

The ability of elsamicin A, an antitumour antibiotic, to cleave DNA in the presence of ferrous iron and reducing agents, has been analysed using experimental and theoretical approaches. Experimentally, the antibiotic causes DNA breakage in the presence of ferrous ions and a reducing agent. The DNA-cleaving activity appears to be partially blocked by the action of superoxide dismutase and catalase. These results indicate that the elsamicin aglycone moiety (chartarin) can be involved in the production of free radicals. We have performed a broad theoretical study based in the quantum-mechanical framework, which allow us to determine the redox properties of elsamicin that lead to the generation of radical species. Our results clearly show that elsamicin acts as a true catalyst in the production of superoxide radicals. Moreover, it is suggested that the oxidation/reduction mechanism of the aglycone moiety of elsamicin (a lactone), leading to DNA breakage, is different from the mechanism followed by other well-known anti-cancer drugs, whose chromophore is a quinone.

Biological activity of 3-deazauridine nucleoside analogue: a theoretical study

The incorporation model of Sanyal et al. has been used to understand the biological activity of the cytostatic compound 3-deazauridine. The interaction energies of various types of binding pattern of the enterant molecule with nucleic acid fragments have been computed. The energy values and the sites of association of the analogous base, obtained by optimization of energy values as well as the sites of association of nucleic acid bases during the transcription process have been compared. The specificity of the binding of the interacting molecule has been discussed, along with the inhibitory effect of 3-deazauridine. They are in agreement with the experimentally observed evidence.

A quantum chemical study of the enzymatic deamination of benzoadenine derivatives. A theoretical model of the interactions occurring between nucleosides and the active site of adenosine deaminase

A theoretical study is presented, where, by using both ab initio and semi-empirical methodologies, the properties of benzoadenine derivatives as substrates of adenosine deaminase are discussed. The results suggest that lin-benzoadenine and lin-benzoadenosine can be recognized with an affinity similar to that of adenosine, but only if they are introduced about 0.12 nm deeper inside the active site of the enzyme than the natural substrate adenosine. This fact implies the existence of non-linear hydrogen bonds inside the active site of adenosine deaminase. Ab initio molecular electrostatic potential values suggest that these hydrogen bonds can exist, and have stability similar to that of linear hydrogen bonds. Finally, the great rate of deamination of lin-benzoadenine, comparable with that of adenosine despite the absence of the ribose, is explained in the context of the hypothesis that the protonation at the N1 atom is the rate-determining step of the whole deamination reaction.

Quantum chemical study of the electronic and conformational characteristics of adenosine and 8-substituted derivatives: functional implications in the mechanism of reaction of adenosine deaminase

A quantum chemical study of 10 substrates of adenosine deaminase is performed. The conformational preference around the glycosidic bond of several 8-substituted derivatives of adenosine is studied using semiempirical modified neglect of diatomic overlap (MNDO) and Austin model 1 (AM1) methods. All the compounds studied show preference for the anti conformation; the syn - anti energetic differences calculated are small and in excellent agreement with experimental data. A relationship between the ab initio molecular electrostatic potential minimum energy of N3 and the syn - anti energetic difference is found. A highly significant relationship is also found between the ab initio net charge over the purine and pyrimidine rings and the logarithm of the maximum rate of deamination (log Vm) of the nucleosides by adenosine deaminase. In contrast, no significant relationship is found between the anti preference of 8-substituted derivatives of adenosine and their log Vm of deamination.