Computationally restoring the potency of a clinical antibody against Omicron

Thomas A Desautels; Kathryn T Arrildt; Adam T Zemla; Edmond Y Lau; Fangqiang Zhu; Dante Ricci; Stephanie Cronin; Seth J Zost; Elad Binshtein; Suzanne M Scheaffer; Bernadeta Dadonaite; Brenden K Petersen; Taylor B Engdahl; Elaine Chen; Laura S Handal; Lynn Hall; John W Goforth; Denis Vashchenko; Sam Nguyen; Dina R Weilhammer; Jacky Kai-Yin Lo; Bonnee Rubinfeld; Edwin A Saada; Tracy Weisenberger; Tek-Hyung Lee; Bradley Whitener; James B Case; Alexander Ladd; Mary S Silva; Rebecca M Haluska; Emilia A Grzesiak; Christopher G Earnhart; Svetlana Hopkins; Thomas W Bates; Larissa B Thackray; Brent W Segelke; Tri-lab COVID-19 Consortium; Antonietta Maria Lillo; Shivshankar Sundaram; Jesse D Bloom; Michael S Diamond; James E Crowe Jr; Robert H Carnahan; Daniel M Faissol

doi:10.1038/s41586-024-07385-1

Computationally restoring the potency of a clinical antibody against Omicron

Nature. 2024 May;629(8013):878-885. doi: 10.1038/s41586-024-07385-1. Epub 2024 May 8.

Authors

Thomas A Desautels¹, Kathryn T Arrildt², Adam T Zemla³, Edmond Y Lau², Fangqiang Zhu², Dante Ricci², Stephanie Cronin⁴, Seth J Zost⁴, Elad Binshtein⁴, Suzanne M Scheaffer⁵, Bernadeta Dadonaite⁶, Brenden K Petersen¹, Taylor B Engdahl⁴, Elaine Chen⁴, Laura S Handal⁴, Lynn Hall⁴, John W Goforth³, Denis Vashchenko⁷, Sam Nguyen^{1

8}, Dina R Weilhammer², Jacky Kai-Yin Lo², Bonnee Rubinfeld², Edwin A Saada², Tracy Weisenberger², Tek-Hyung Lee², Bradley Whitener^{5

9}, James B Case⁵, Alexander Ladd¹, Mary S Silva³, Rebecca M Haluska⁷, Emilia A Grzesiak³, Christopher G Earnhart¹⁰, Svetlana Hopkins¹¹, Thomas W Bates¹, Larissa B Thackray⁵, Brent W Segelke²; Tri-lab COVID-19 Consortium; Antonietta Maria Lillo¹², Shivshankar Sundaram¹³, Jesse D Bloom^{6

14}, Michael S Diamond^{5

15

16}, James E Crowe Jr^{4

17}, Robert H Carnahan^{4

17}, Daniel M Faissol¹⁸

Collaborators

Affiliations

¹ Computational Engineering Division, Lawrence Livermore National Laboratory, Livermore, CA, USA.
² Biosciences and Biotechnology Division, Lawrence Livermore National Laboratory, Livermore, CA, USA.
³ Global Security Computing Applications Division, Lawrence Livermore National Laboratory, Livermore, CA, USA.
⁴ Vanderbilt Vaccine Center, Vanderbilt University Medical Center, Nashville, TN, USA.
⁵ Department of Medicine, Washington University School of Medicine, St. Louis, MO, USA.
⁶ Basic Sciences Division and Computational Biology Program, Fred Hutchinson Cancer Center, Seattle, WA, USA.
⁷ Applications Simulations and Quality Division, Lawrence Livermore National Laboratory, Livermore, CA, USA.
⁸ Google, Alphabet Inc., Mountain View, CA, USA.
⁹ Vir Biotechnology, San Francisco, CA, USA.
¹⁰ Joint Program Executive Office for Chemical, Biological, Radiological, and Nuclear Defense, US Department of Defense, Frederick, MD, USA.
¹¹ Joint Rsearch and Development Inc., Stafford, VA, USA.
¹² Los Alamos National Laboratory, Bioscience Division, Los Alamos, NM, USA.
¹³ Center for Bioengineering, Lawrence Livermore National Laboratory, Livermore, CA, USA.
¹⁴ Howard Hughes Medical Institute, Seattle, WA, USA.
¹⁵ Molecular Microbiology, Washington University School of Medicine, St. Louis, MO, USA.
¹⁶ Pathology and Immunology, Washington University School of Medicine, St. Louis, MO, USA.
¹⁷ Department of Pediatrics, Vanderbilt University Medical Center, Nashville, TN, USA.
¹⁸ Computational Engineering Division, Lawrence Livermore National Laboratory, Livermore, CA, USA. faissol1@llnl.gov.

Abstract

The COVID-19 pandemic underscored the promise of monoclonal antibody-based prophylactic and therapeutic drugs^1-3 and revealed how quickly viral escape can curtail effective options^4,5. When the SARS-CoV-2 Omicron variant emerged in 2021, many antibody drug products lost potency, including Evusheld and its constituent, cilgavimab^4-6. Cilgavimab, like its progenitor COV2-2130, is a class 3 antibody that is compatible with other antibodies in combination⁴ and is challenging to replace with existing approaches. Rapidly modifying such high-value antibodies to restore efficacy against emerging variants is a compelling mitigation strategy. We sought to redesign and renew the efficacy of COV2-2130 against Omicron BA.1 and BA.1.1 strains while maintaining efficacy against the dominant Delta variant. Here we show that our computationally redesigned antibody, 2130-1-0114-112, achieves this objective, simultaneously increases neutralization potency against Delta and subsequent variants of concern, and provides protection in vivo against the strains tested: WA1/2020, BA.1.1 and BA.5. Deep mutational scanning of tens of thousands of pseudovirus variants reveals that 2130-1-0114-112 improves broad potency without increasing escape liabilities. Our results suggest that computational approaches can optimize an antibody to target multiple escape variants, while simultaneously enriching potency. Our computational approach does not require experimental iterations or pre-existing binding data, thus enabling rapid response strategies to address escape variants or lessen escape vulnerabilities.

MeSH terms

Animals
Antibodies, Monoclonal / immunology
Antibodies, Monoclonal / pharmacology
Antibodies, Monoclonal / therapeutic use
Antibodies, Neutralizing* / immunology
Antibodies, Neutralizing* / pharmacology
Antibodies, Neutralizing* / therapeutic use
Antibodies, Viral* / immunology
Antibodies, Viral* / pharmacology
Antibodies, Viral* / therapeutic use
COVID-19* / immunology
COVID-19* / virology
Female
Humans
Mice
Mutation
Neutralization Tests
SARS-CoV-2* / immunology
Spike Glycoprotein, Coronavirus / chemistry
Spike Glycoprotein, Coronavirus / immunology

Substances

Antibodies, Viral
Antibodies, Neutralizing
Antibodies, Monoclonal
Spike Glycoprotein, Coronavirus
spike protein, SARS-CoV-2

Supplementary concepts

SARS-CoV-2 variants

Abstract

MeSH terms

Substances

Supplementary concepts

Grants and funding