Intra-Spike Crosslinking Overcomes Antibody Evasion by HIV-1
Abstract
Antibodies developed during HIV-1 infection lose efficacy as the viral spike mutates. We postulated that anti-HIV-1 antibodies primarily bind monovalently because HIV's low spike density impedes bivalent binding through inter-spike crosslinking, and the spike structure prohibits bivalent binding through intra-spike crosslinking. Monovalent binding reduces avidity and potency, thus expanding the range of mutations permitting antibody evasion. To test this idea, we engineered antibody-based molecules capable of bivalent binding through intra-spike crosslinking. We used DNA as a "molecular ruler" to measure intra-epitope distances on virion-bound spikes and construct intra-spike crosslinking molecules. Optimal bivalent reagents exhibited up to 2.5 orders of magnitude increased potency (>100-fold average increases across virus panels) and identified conformational states of virion-bound spikes. The demonstration that intra-spike crosslinking lowers the concentration of antibodies required for neutralization supports the hypothesis that low spike densities facilitate antibody evasion and the use of molecules capable of intra-spike crosslinking for therapy or passive protection.
Additional Information
© 2015 Elsevier Inc. Published by Elsevier Inc. Received: October 16, 2014. Revised: November 21, 2014. Accepted: December 16, 2014. Published: January 29, 2015. We thank Martin Witte, Jessica Ingram, Chris Theile, and Hidde Ploegh for advice and help with sortase/click chemistry experiments; Sriram Subramaniam for helpful discussions, coordinates, and files to make schematic figures; David Baltimore, Bil Clemons, Ron Diskin, Jennifer Keeffe, Sarkis Mazmanian, Stuart Sievers, Louise Scharf, and Kai Zinn for suggestions; Jost Vielmetter and the Caltech Protein Expression Center for assistance with protein production and neutralization assay development; Priyanthi Gnanapragasam for doing in-house neutralization assays; the NIH AIDS Reagent Program, the Fraunhofer Institut IBMT, and Rene Mares for pseudoviruses; Erin Isaza, Siduo Jiang, and Jennifer Keeffe for reagents; and Sonal N. Patel and Marta Murphy for help with figures. This work was supported by the Director's Pioneer Award (1DP1OD006961-01 to P.J.B.), National Institutes of Health HIVRAD (P01Al100148 to P.J.B.), and Collaboration for AIDS Vaccine Discovery (CAVD) grants with support from the Bill and Melinda Gates Foundation (grant 38660 [P.J.B.] and grant 1032144 [M.S.S.]). P.J.B. and M.C.N. are HHMI Investigators. Author Contributions: R.P.G. and P.J.B. conceived the study; J.S.K. performed simulations to assess avidity effects; R.P.G. and M.S.P. prepared dsDNA-Fab reagents; R.P.G., M.S.P., J.S.K., S.B., and A.P.W. perfected methods to attach dsDNA to Fabs; R.P.G. and M.S.S. performed neutralization assays; R.P.G., A.P.W., and P.J.B. analyzed the data; and R.P.G., M.C.N, and P.J.B. wrote the paper with contributions from all co-authors.Attached Files
Accepted Version - nihms655341.pdf
Supplemental Material - mmc1.pdf
Supplemental Material - mmc2.pdf
Files
Additional details
- PMCID
- PMC4401576
- Eprint ID
- 54316
- DOI
- 10.1016/j.cell.2015.01.016
- Resolver ID
- CaltechAUTHORS:20150203-085327952
- 1DP1OD006961-01
- NIH
- P01Al100148
- NIH
- 38660
- Bill and Melinda Gates Foundation
- 1032144
- Bill and Melinda Gates Foundation
- Created
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2015-02-03Created from EPrint's datestamp field
- Updated
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2021-11-10Created from EPrint's last_modified field