Structure of RSV Fusion Glycoprotein Trimer Bound to a Prefusion-Specific Neutralizing Antibody

Jason S. McLellan(National Institutes of Health), Man Chen(National Institutes of Health), Sherman S. Leung(National Institutes of Health), Kevin W. Graepel(National Institutes of Health), Xiulian Du(National Institutes of Health), Yongping Yang(National Institutes of Health), Tongqing Zhou(National Institutes of Health), Ulrich Baxa(Frederick National Laboratory for Cancer Research), Etsuko Yasuda(Amsterdam UMC Location University of Amsterdam), Tim Beaumont(Amsterdam UMC Location University of Amsterdam), Azad Kumar(National Institutes of Health), Kayvon Modjarrad(National Institutes of Health), Zizheng Zheng(Xiamen University), Min Zhao(Xiamen University), Ningshao Xia(Xiamen University), Peter D. Kwong(National Institutes of Health), Barney S. Graham(National Institutes of Health)
Science
April 26, 2013
10.1126/science.1234914
Cited by 856Open Access
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Abstract

The prefusion state of respiratory syncytial virus (RSV) fusion (F) glycoprotein is the target of most RSV-neutralizing activity in human sera, but its metastability has hindered characterization. To overcome this obstacle, we identified prefusion-specific antibodies that were substantially more potent than the prophylactic antibody palivizumab. The cocrystal structure for one of these antibodies, D25, in complex with the F glycoprotein revealed D25 to lock F in its prefusion state by binding to a quaternary epitope at the trimer apex. Electron microscopy showed that two other antibodies, AM22 and 5C4, also bound to the newly identified site of vulnerability, which we named antigenic site Ø. These studies should enable design of improved vaccine antigens and define new targets for passive prevention of RSV-induced disease.

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