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Query: EC:3.4.23.16 (
HIV-1 protease
)
2,107
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We present the first solution structure of the
HIV-1 protease
monomer spanning the region Phe1-Ala95 (PR1-95). Except for the terminal regions (residues 1-10 and 91-95) that are disordered, the tertiary fold of the remainder of the protease is essentially identical to that of the individual subunit of the dimer. In the monomer, the side chains of buried residues stabilizing the active site interface in the dimer, such as Asp25, Asp29, and Arg87, are now exposed to solvent. The flap dynamics in the monomer are similar to that of the free protease dimer. We also show that the protease domain of an optimized precursor flanked by 56 amino acids of the N-terminal transframe region is predominantly monomeric, exhibiting a tertiary fold that is quite similar to that of
PR1
-95 structure. This explains the very low catalytic activity observed for the protease prior to its maturation at its N terminus as compared with the mature protease, which is an active stable dimer under identical conditions. Adding as few as 2 amino acids to the N terminus of the mature protease significantly increases its dissociation into monomers. Knowledge of the protease monomer structure and critical features of its dimerization may aid in the screening and design of compounds that target the protease prior to its maturation from the Gag-Pol precursor.
...
PMID:Solution structure of the mature HIV-1 protease monomer: insight into the tertiary fold and stability of a precursor. 1293 91
Purification and in vitro protein-folding schemes were developed to produce monodisperse samples of the mature wild-type
HIV-2 protease
(PR2), enabling a comprehensive set of biochemical and biophysical studies to assess the dissociation of the dimeric protease. An E37K substitution in PR2 significantly retards autoproteolytic cleavage during expression. Furthermore, it permits convenient measurement of the dimer dissociation of PR2(E37K) (elevated K(d) approximately 20 nM) by enzyme kinetics. Differential scanning calorimetry reveals a T(m) of 60.5 for PR2 as compared with 65.7 degrees C for
HIV-1 protease
(
PR1
). Consistent with weaker binding of the clinical inhibitor darunavir (DRV) to PR2, the T(m) of PR2 increases by 14.8 degrees C in the presence of DRV as compared with 22.4 degrees C for
PR1
. Dimer interface mutations, such as a T26A substitution in the active site (PR2(T26A)) or a deletion of the C-terminal residues 96-99 (PR2(1-95)), drastically increase the K(d) (>10(5)-fold). PR2(T26A) and PR2(1-95) consist predominantly of folded monomers, as determined by nuclear magnetic resonance (NMR) and size-exclusion chromatography coupled with multiangle light scattering and refractive index measurements (SMR), whereas wild-type PR2 and its active-site mutant PR2(D25N) are folded dimers. Addition of twofold excess active-site inhibitor promotes dimerization of PR2(T26A) but not of PR2(1-95), indicating that subunit interactions involving the C-terminal residues are crucial for dimer formation. Use of SMR and NMR with PR2 facilitates probing for potential inhibitors that restrict protein folding and/or dimerization and, thus, may provide insights for the future design of inhibitors to circumvent drug resistance.
...
PMID:Revealing the dimer dissociation and existence of a folded monomer of the mature HIV-2 protease. 1979 42
Clinical inhibitors Darunavir (DRV) and Amprenavir (APV) are less effective on
HIV-2 protease
(PR2) than on
HIV-1 protease
(
PR1
). To identify molecular basis associated with the lower inhibition, molecular dynamics (MD) simulations and molecular mechanics Poisson-Boltzmann surface area (MM-PBSA) calculations were performed to investigate the effectiveness of the
PR1
inhibitors DRV and APV against
PR1
/PR2. The rank of predicted binding free energies agrees with the experimental determined one. Moreover, our results show that two inhibitors bind less strongly to PR2 than to
PR1
, again in agreement with the experimental findings. The decrease in binding free energies for PR2 relative to
PR1
is found to arise from the reduction of the van der Waals interactions induced by the structural adjustment of the triple mutant V32I, I47V and V82I. This result is further supported by the difference between the van der Waals interactions of inhibitors with each residue in PR2 and in
PR1
. The results from the principle component analysis suggest that inhibitor binding tends to make the flaps of PR2 close and the one of
PR1
open. We expect that this study can theoretically provide significant guidance and dynamics information for the design of potent dual inhibitors targeting
PR1
/PR2.
...
PMID:Revealing origin of decrease in potency of darunavir and amprenavir against HIV-2 relative to HIV-1 protease by molecular dynamics simulations. 2536 63
HIV-2 protease
(PR2) is naturally resistant to most FDA (Food and Drug Administration)-approved
HIV-1 protease
inhibitors (PIs), a major antiretroviral class. In this study, we compared the
PR1
and PR2 binding pockets extracted from structures complexed with 12 ligands. The comparison of
PR1
and PR2 pocket properties showed that bound PR2 pockets were more hydrophobic with more oxygen atoms and fewer nitrogen atoms than
PR1
pockets. The structural comparison of
PR1
and PR2 pockets highlighted structural changes induced by their sequence variations and that were consistent with these property changes. Specifically, substitutions at residues 31, 46, and 82 induced structural changes in their main-chain atoms that could affect PI binding in PR2. In addition, the modelling of
PR1
mutant structures containing V32I and L76M substitutions revealed a cooperative mechanism leading to structural deformation of flap-residue 45 that could modify PR2 flexibility. Our results suggest that substitutions in the
PR1
and PR2 pockets can modify PI binding and flap flexibility, which could underlie PR2 resistance against PIs. These results provide new insights concerning the structural changes induced by
PR1
and PR2 pocket variation changes, improving the understanding of the atomic mechanism of PR2 resistance to PIs.
...
PMID:Exploration of the effect of sequence variations located inside the binding pocket of HIV-1 and HIV-2 proteases. 2963 21
