Drug resistance of herpes simplex virus type 1--structural considerations at the molecular level of the thymidine kinase.

Several drug-resistant strains of herpes simplex virus type 1 (HSV1) isolated in vivo or from tissue culture, have exhibited a mutated thymidine kinase (TK). Moreover, various site-directed-mutagenesis experiments conducted on HSV1 TK allowed the assignment of specific amino acid residues to specific functional properties. From this, a range of hypotheses was generated related to substrate binding of TK at the molecular level. A site-directed-mutagenesis study on Q125 was performed to clarify the contribution of this residue to the binding of thymidine or aciclovir beyond the hydrogen-bonding pattern observed in the crystal structure. While Q125L is only able to phosphorylate thymidine, Q125N accepts thymidine and aciclovir as substrates. Q125E shows no phosphorylation activity. Several mutations identified previously as relevant in drug resistance were studied in an attempt to further understand their role in these processes. Four amino acid positions are described (T63, A168, R176 and C336) that confer drug resistance when mutated; however, the molecular mechanisms are considerably different in each case. Analysis of the crystal structures and the molecular modeling presented in this paper suggest that T63 is essential for the binding of Mg2+ and thus the catalytic activity of the enzyme, while A168 limits steric accessibility and if mutated to a bulkier residue will exclude binding of larger substrate analogues. R176 appears to be essential for electrostatic balance within the active site, and C336, which is located at the surface of TK and directed toward the ATP-binding site, disrupts the three-dimensional structure of the whole active site by shifting the LID-domain. The present work contributes to a detailed understanding of nucleoside binding to TK, thereby facilitating the rational design of substrates for HSV1 TK and of drug-specific TK for gene therapy.

Density functional studies on herpes simplex virus type 1 thymidine kinase-substrate interactions: the role of Tyr-172 and Met-128 in thymine fixation.

The enzyme herpes simplex virus type 1 thymidine kinase (HSV1 TK) salvages thymidine into the DNA metabolism of the virus. In the active site, the thymine ring of the nucleoside binds in a pocket, formed by two residues, Tyr-172 and Met-128, in a sandwich-type orientation. To investigate the nature of the thymine-enzyme pocket interactions, we have carried out density functional theory calculations with gradient-corrected exchange-correlation functionals of models of the thymine-HSV1 TK adduct. Our calculations indicate that the role of Met-128 in the substrate fixation is purely steric and hydrophobic, while the substrate-Tyr-172 interaction is essentially electrostatic in nature. These findings are completely consistent with the available catalytic properties of mutants on the 128 position.

Fine specificity of antigen binding to two class I major histocompatibility proteins (B*2705 and B*2703) differing in a single amino acid residue.

Starting from the X-ray structure of a class I major histocompatibility complex (MHC)-encoded protein (HLA-B*2705), a naturally presented self-nonapeptide and two synthetic analogues were simulated in the binding groove of two human leukocyte antigen (HLA) alleles (B*2703 and B*2705) differing in a single amino acid residue. After 200 ps molecular dynamics simulations of the solvated HLA-peptide pairs, some molecular properties of the complexes (distances between ligand and protein center of masses, atomic fluctuations, buried versus accessible surface areas, hydrogen-bond frequencies) allow a clear discrimination of potent from weak MHC binders. The binding specificity of the three nonapeptides for the two HLA alleles could be explained by the disruption of one hydrogen-bonding network in the binding pocket of the HLA-B*2705 protein where the single mutation occurs. Rearrangements of interactions in the B pocket, which binds the side chain of peptide residue 2, and a weakening of interactions involving the C-terminal end of the peptide also took place. In addition, extension of the peptide backbone using a beta-Ala analogue did not abolish binding to any of the two HLA-B27 subtypes, but increased the selectivity for B*2703, as expected from the larger peptide binding groove in this subtype. A better understanding of the atomic details involved in peptide selection by closely related HLA alleles is of crucial importance for unraveling the molecular features linking particular HLA alleles to autoimmune diseases, and for the identification of antigenic peptides triggering such pathologies.

Integrated homology modelling and X-ray study of herpes simplex virus I thymidine kinase: a case study.

Knowledge-based homology modelling together with site-directed mutagenesis, epitope and conformational mapping is an approach to predict the structures of proteins and for the rational design of new drugs. In this study we present how this procedure has been applied to model the structure of herpes simplex virus type 1 thymidine kinase (HSV1 TK, HSV1 ATP-thymidine-5'-phosphotransferase, EC 2.7.1.21). We have used, and evaluated, several secondary structure prediction methods, such as the classical one based on Chou and Fastman algorithm, neural networks using the Kabsch and Sander classification, and the PRISM method. We have validated the algorithms by applying them to the porcine adenylate kinase (ADK), whose three-dimensional structure is known and that has been used for the alignment of the TKs as well. The resulting first model of HSV1-TK consisted of the first beta-strand connected to the phosphate binding loop and its subsequent alpha-helix, the fourth beta-strand connected to the conserved FDRH sequence and two alpha-helix with basic amino acids. The 3D structure was built using the X-ray structure of ADK as template and following the general procedure for homology modelling. We extended the model by means of COMPOSER, an automatic process for protein modelling. Site-directed mutagenesis was used to experimentally verify the predicted active-site model of HSV1-TK. The data measured in our lab and by others support the suggestion that the FDRH motif is part of the active site and plays an important role in the phosphorylation of substrates. The structure of HSV1 TK, recently solved in collaboration with Prof. G. Schulz at 2.7 A resolution, includes 284 of 343 residues of the N-terminal truncated TK. The secondary structures could be clearly assigned and fitted to the density. The comparison between crystallographically determined structure and the model shows that nearly 70% of the HSV1 TK structure has been correctly modelled by the described integrated approach to knowledge based ligand protein complex structure prediction. This indicate that computer assisted methods, combined with "manual" correction both for alignment and 3D construction are useful and can be successful.