Structure-Based Design and Synthesis of an HIV‑1 Entry Inhibitor Exploiting X‑ray and Thermodynamic Characterization

Abstract

The design, synthesis, thermodynamic and crystallographic characterization of a potent, broad spectrum, second-generation HIV-1 entry inhibitor that engages conserved carbonyl hydrogen bonds within gp120 has been achieved. The optimized antagonist exhibits a submicromolar binding affinity (110 nM) and inhibits viral entry of clade B and C viruses (IC₅₀ geometric mean titer of 1.7 and 14.0 μM, respectively), without promoting CD4-independent viral entry. The thermodynamic signatures indicate a binding preference for the (<i>R</i>,<i>R</i>)- over the (<i>S</i>,<i>S</i>)-enantiomer. The crystal structure of the small-molecule/gp120 complex reveals the displacement of crystallographic water and the formation of a hydrogen bond with a backbone carbonyl of the bridging sheet. Thus, structure-based design and synthesis targeting the highly conserved and structurally characterized CD4–gp120 interface is an effective tactic to enhance the neutralization potency of small-molecule HIV-1 entry inhibitors