1 research outputs found
A Model of Peptide Triazole Entry Inhibitor Binding to HIVâ1 gp120 and the Mechanism of Bridging Sheet Disruption
Peptide
triazole (PT) entry inhibitors prevent HIV-1 infection by blocking
the binding of viral gp120 to both the HIV-1 receptor and the coreceptor
on target cells. Here, we used all-atom explicit solvent molecular
dynamics (MD) to propose a model for the encounter complex of the
peptide triazoles with gp120. Saturation transfer difference nuclear
magnetic resonance (STD NMR) and single-site mutagenesis experiments
were performed to test the simulation results. We found that docking
of the peptide to a conserved patch of residues lining the âF43
pocketâ of gp120 in a bridging sheet naiÌve gp120 conformation
of the glycoprotein led to a stable complex. This pose prevents formation
of the bridging sheet minidomain, which is required for receptorâcoreceptor
binding, providing a mechanistic basis for dual-site antagonism of
this class of inhibitors. Burial of the peptide triazole at the gp120
inner domainâouter domain interface significantly contributed
to complex stability and rationalizes the significant contribution
of hydrophobic triazole groups to peptide potency. Both the simulation
model and STD NMR experiments suggest that the I-X-W [where X is (2<i>S</i>,4<i>S</i>)-4-(4-phenyl-1<i>H</i>-1,2,3-triazol-1-yl)Âpyrrolidine]
tripartite hydrophobic motif in the peptide is the major contributor
of contacts at the gp120âPT interface. Because the model predicts
that the peptide Trp side chain hydrogen bonding with gp120 S375 contributes
to the stability of the PTâgp120 complex, we tested this prediction
through analysis of peptide binding to gp120 mutant S375A. The results
showed that a peptide triazole KR21 inhibits S375A with 20-fold less
potency than WT, consistent with predictions of the model. Overall,
the PTâgp120 model provides a starting point for both the rational
design of higher-affinity peptide triazoles and the development of
structure-minimized entry inhibitors that can trap gp120 into an inactive
conformation and prevent infection