| Structural highlights
Publication Abstract from PubMed
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 sub-micromolar binding affinity (110 nM) and inhibits viral entry of clade B and C viruses (IC50 geometric mean titer of 1.7 and 14.0 muM, respectively), without promoting CD4-independent viral entry. thermodynamic signatures indicate a binding preference for the (R,R)-over the (S,S)-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.
Structure-Based Design and Synthesis of an HIV-1 Entry Inhibitor Exploiting X-Ray and Thermodynamic Characterization.,Lalonde JM, Le-Khac M, Jones DM, Courter JR, Park J, Schon A, Princiotto AM, Wu X, Mascola JR, Freire E, Sodroski J, Madani N, Hendrickson WA, Smith AB 3rd ACS Med Chem Lett. 2013 Mar 14;4(3):338-343. PMID:23667716[1]
From MEDLINE®/PubMed®, a database of the U.S. National Library of Medicine.
References
- ↑ Lalonde JM, Le-Khac M, Jones DM, Courter JR, Park J, Schon A, Princiotto AM, Wu X, Mascola JR, Freire E, Sodroski J, Madani N, Hendrickson WA, Smith AB 3rd. Structure-Based Design and Synthesis of an HIV-1 Entry Inhibitor Exploiting X-Ray and Thermodynamic Characterization. ACS Med Chem Lett. 2013 Mar 14;4(3):338-343. PMID:23667716 doi:10.1021/ml300407y
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