Nature Communications (Nov 2023)

Antibody-directed evolution reveals a mechanism for enhanced neutralization at the HIV-1 fusion peptide site

  • Bailey B. Banach,
  • Sergei Pletnev,
  • Adam S. Olia,
  • Kai Xu,
  • Baoshan Zhang,
  • Reda Rawi,
  • Tatsiana Bylund,
  • Nicole A. Doria-Rose,
  • Thuy Duong Nguyen,
  • Ahmed S. Fahad,
  • Myungjin Lee,
  • Bob C. Lin,
  • Tracy Liu,
  • Mark K. Louder,
  • Bharat Madan,
  • Krisha McKee,
  • Sijy O’Dell,
  • Mallika Sastry,
  • Arne Schön,
  • Natalie Bui,
  • Chen-Hsiang Shen,
  • Jacy R. Wolfe,
  • Gwo-Yu Chuang,
  • John R. Mascola,
  • Peter D. Kwong,
  • Brandon J. DeKosky

DOI
https://doi.org/10.1038/s41467-023-42098-5
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 17

Abstract

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Abstract The HIV-1 fusion peptide (FP) represents a promising vaccine target, but global FP sequence diversity among circulating strains has limited anti-FP antibodies to ~60% neutralization breadth. Here we evolve the FP-targeting antibody VRC34.01 in vitro to enhance FP-neutralization using site saturation mutagenesis and yeast display. Successive rounds of directed evolution by iterative selection of antibodies for binding to resistant HIV-1 strains establish a variant, VRC34.01_mm28, as a best-in-class antibody with 10-fold enhanced potency compared to the template antibody and ~80% breadth on a cross-clade 208-strain neutralization panel. Structural analyses demonstrate that the improved paratope expands the FP binding groove to accommodate diverse FP sequences of different lengths while also recognizing the HIV-1 Env backbone. These data reveal critical antibody features for enhanced neutralization breadth and potency against the FP site of vulnerability and accelerate clinical development of broad HIV-1 FP-targeting vaccines and therapeutics.