Analysis of the structure of chemically synthesized HIV-1 protease complexed with a hexapeptide inhibitor. Part I: Crystallographic refinement of 2 Å data

Miller, Maria; Geller, Maciej; Gribskov, Michael; Kent, Stephen B. H.

doi:10.1002/(sici)1097-0134(199702)27:2<184::aid-prot4>3.0.co;2-g

Cited by 17 publications

(11 citation statements)

References 40 publications

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“…Partial atomic charges and the all‐hydrogens parameters for van der Waals and bonded energy terms for the 16 ligands have been previously determined 7. Depending on the inhibitor, either residue Asp25 or Asp25′ of the HIV‐I protease can be protonated in a complex 16, 26–28. In our work, to facilitate comparisons, protonation of Asp25 for all protein–ligand complexes is assumed.…”

Section: Theoretical Methodsmentioning

confidence: 99%

How inaccuracies in protein structure models affect estimates of protein–ligand interactions: Computational analysis of HIV‐I protease inhibitor binding

et al. 2006

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The influence of possible inaccuracies that can arise during homology modeling of protein structures used for ligand binding studies were investigated with the molecular mechanics generalized Born surface area (MM-GBSA) method. For this, a family of well-characterized HIV-I protease-inhibitor complexes was used. Validation of MM-GBSA led to a correlation coefficient ranging from 0.72 to 0.93 between calculated and experimental binding free energies DeltaG. All calculated DeltaG values were based on molecular dynamics simulations with explicit solvent. Errors introduced into the protein structure through misplacement of side-chains during rotamer modeling led to a correlation coefficient between DeltaG(calc) and DeltaG(exp) of 0.75 compared with 0.90 for the correctly placed side chains. This is in contrast to homology models for members of the retroviral protease family with template structures ranging in sequence identity between 32% and 51%. For these protein models, the correlation coefficients vary between 0.84 and 0.87, which is considerably closer to the original protein (0.90). It is concluded that HIV-I low sequence identity with the template structure still allows creating sufficiently reliable homology models to be used for ligand-binding studies, although placement of the rotamers is a critical step during the modeling.

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Section: Theoretical Methodsmentioning

confidence: 99%

How inaccuracies in protein structure models affect estimates of protein–ligand interactions: Computational analysis of HIV‐I protease inhibitor binding

et al. 2006

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“…Accordingly, the present study uses the PB method to compute the protonation states of the aspartyl dyad of free HIV-1 PR and of HIV-1 PR complexed with four inhibitors that interact intimately with the aspartyl dyad. One inhibitor, MVT-101~Miller et al, 1989!~Fig. 1A!, contains a basic secondary amine that lies within 3-4 Å of the carboxyl oxygens of the aspartyl dyad~Miller et Miller et al, 1997!. This inhibitor has been studied previously by MD simulations, as noted above~Harte Geller et al, 1997!.…”

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confidence: 99%

“…Harte & Beveridge, 1993!. Crystal structures are available for both complexes~Miller et al, 1989;Jaskolski et al, 1991;Miller et al, 1997!. For both complexes, a separate simulation was carried out for each of the four possible protonation states of the aspartyl dyad,~0, 0!,~Ϫ1, 0!,~0, Ϫ1!, and~Ϫ1, Ϫ1!, and for each complex, a single protonation state led to a trajectory that preserved the crystallographically determined conformation of the active site particularly well.…”

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confidence: 99%

Thermodynamic linkage between the binding of protons and inhibitors to HIV‐1 protease

et al. 1999

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The aspartyl dyad of free HIV-1 protease has apparent pK(a)s of approximately 3 and approximately 6, but recent NMR studies indicate that the aspartyl dyad is fixed in the doubly protonated form over a wide pH range when cyclic urea inhibitors are bound, and in the monoprotonated form when the inhibitor KNI-272 is bound. We present computations and measurements related to these changes in protonation and to the thermodynamic linkage between protonation and inhibition. The Poisson-Boltzmann model of electrostatics is used to compute the apparent pK(a)s of the aspartyl dyad in the free enzyme and in complexes with four different inhibitors. The calculations are done with two parameter sets. One assigns epsilon = 4 to the solute interior and uses a detailed model of ionization; the other uses epsilon = 20 for the solute interior and a simplified representation of ionization. For the free enzyme, both parameter sets agree well with previously measured apparent pK(a)s of approximately 3 and approximately 6. However, the calculations with an internal dielectric constant of 4 reproduce the large pKa shifts upon binding of inhibitors, but the calculations with an internal dielectric constant of 20 do not. This observation has implications for the accurate calculation of pK(a)s in complex protein environments. Because binding of a cyclic urea inhibitor shifts the pK(a)s of the aspartyl dyad, changing the pH is expected to change its apparent binding affinity. However, we find experimentally that the affinity is independent of pH from 5.5 to 7.0. Possible explanations for this discrepancy are discussed.

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“…Our selection of structural variables was made regarding several previously reported X‐ray crystallographic structure of HIV‐1 protease inhibitor complexes that revealed a binding mode in which the central hydroxyl group and the amino groups interact with the catalytic Asp25 and Asp25′ residues of the enzyme, while the carbonyl groups of the inhibitors accepted additional hydrogen bonds 20–27. This set of chemical variables gave good results in a previous work of ours, a chemometric multivariate analysis of hidroxyethylene‐like HIV‐1 protease inhibitors 9.…”

Section: Discussionmentioning

confidence: 99%

EURADIA, the European Research Area in Diabetes

Brendel

2004

European Diabetes Nursing

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Analysis of the structure of chemically synthesized HIV-1 protease complexed with a hexapeptide inhibitor. Part I: Crystallographic refinement of 2 Å data

Cited by 17 publications

References 40 publications

How inaccuracies in protein structure models affect estimates of protein–ligand interactions: Computational analysis of HIV‐I protease inhibitor binding

How inaccuracies in protein structure models affect estimates of protein–ligand interactions: Computational analysis of HIV‐I protease inhibitor binding

Thermodynamic linkage between the binding of protons and inhibitors to HIV‐1 protease

EURADIA, the European Research Area in Diabetes

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