Inhibition of H1 and H5 Influenza A Virus Entry by Diverse Macrocyclic Peptides Targeting the Hemagglutinin Stem Region: ACS Chemical Biology
Pascha, Mirte N.; Thijssen, Vito; Egido, Julia E.; Linthorst, Mirte W.; van Lanen, Jipke H.; van Dongen, David A. A.; Hopstaken, Antonius J. P.; van Kuppeveld, Frank J. M.; Snijder, Joost; de Haan, Cornelis A. M.; Jongkees, Seino A. K.
(2022) ACS Chemical Biology, volume 17, issue 9, pp. 2425 - 2436
(Article)
Abstract
Influenza A viruses pose a serious pandemic risk, while generation of efficient vaccines against seasonal variants remains challenging. There is thus a pressing need for new treatment options. We report here a set of macrocyclic peptides that inhibit influenza A virus infection at low nanomolar concentrations by binding to hemagglutinin,
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selected using ultrahigh-Throughput screening of a diverse peptide library. The peptides are active against both H1 and H5 variants, with no detectable cytotoxicity. Despite the high sequence diversity across hits, all tested peptides were found to bind to the same region in the hemagglutinin stem by HDX-MS epitope mapping. A mutation in this region identified in an escape variant confirmed the binding site. This stands in contrast to the immunodominance of the head region for antibody binding and suggests that macrocyclic peptides from in vitro display may be well suited for finding new druggable sites not revealed by antibodies. Functional analysis indicates that these peptides stabilize the prefusion conformation of the protein and thereby prevent virus-cell fusion. High-Throughput screening of macrocyclic peptides is thus shown here to be a powerful method for the discovery of novel broadly acting viral fusion inhibitors with therapeutic potential.
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Keywords: Antibodies, Viral/genetics, Hemagglutinin Glycoproteins, Influenza Virus/metabolism, Hemagglutinins, Influenza A virus/chemistry, Peptide Library, Molecular Medicine, Biochemistry
ISSN: 1554-8929
Publisher: American Chemical Society
Note: Funding Information: The present work was part of the research program of the Netherlands Centre for One Health ( www.ncoh.nl ) and was financially supported by the One Health Investment Fund from the Faculty of Veterinary Medicine of Utrecht University. M.L. and J.S. would like to thank D. Hagemans for technical assistance and everyone in the Biomolecular Mass Spectrometry and Proteomics group at Utrecht University for support and helpful discussions. M.L. and J.S. are funded by the Dutch Research Council NWO Gravitation 2013 BOO, Institute for Chemical Immunology (ICI; 024.002.009). S.A.K.J. and V.T. are grateful for financial support from the Chemical Biology and Drug Discovery group at Utrecht University and would like to thank J. Kruitzer for technical support in peptide synthesis. S.A.K.J. and C.A.M.H. are grateful for financial support from a 3Rs stimulus fund from the Animal Welfare Body Utrecht. The H3N1 virus was kindly provided by R. Fouchier (Erasmus Medical Center, the Netherlands). The authors thank the Utrecht Sequencing Facility for providing sequencing service and data. Utrecht Sequencing Facility is subsidized by the University Medical Center Utrecht, Hubrecht Institute, Utrecht University, and The Netherlands X-omics Initiative (NWO project 184.034.019). Publisher Copyright: © 2022 American Chemical Society.
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