Human antibody response to Zika targets type-specific quaternary structure epitopes
Matthew H. Collins, Huy A. Tu, Ciara Gimblet-Ochieng, Guei-Jiun Alice Liou, Ramesh S. Jadi, Stefan W. Metz, Ashlie Thomas, Benjamin D. McElvany, Edgar Davidson, Benjamin J. Doranz, Yaoska Reyes, Natalie M. Bowman, Sylvia Becker-Dreps, Filemón Bucardo, Helen M. Lazear, Sean A. Diehl, Aravinda M. de Silva
Matthew H. Collins, Huy A. Tu, Ciara Gimblet-Ochieng, Guei-Jiun Alice Liou, Ramesh S. Jadi, Stefan W. Metz, Ashlie Thomas, Benjamin D. McElvany, Edgar Davidson, Benjamin J. Doranz, Yaoska Reyes, Natalie M. Bowman, Sylvia Becker-Dreps, Filemón Bucardo, Helen M. Lazear, Sean A. Diehl, Aravinda M. de Silva
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Research Article Immunology Virology

Human antibody response to Zika targets type-specific quaternary structure epitopes

Abstract

The recent Zika virus (ZIKV) epidemic in the Americas has revealed rare but serious manifestations of infection. ZIKV has emerged in regions endemic for dengue virus (DENV), a closely related mosquito-borne flavivirus. Cross-reactive antibodies confound studies of ZIKV epidemiology and pathogenesis. The immune responses to ZIKV may be different in people, depending on their DENV immune status. Here, we focus on the human B cell and antibody response to ZIKV as a primary flavivirus infection to define the properties of neutralizing and protective antibodies generated in the absence of preexisting immunity to DENV. The plasma antibody and memory B cell response is highly ZIKV type–specific, and ZIKV-neutralizing antibodies mainly target quaternary structure epitopes on the viral envelope. To map viral epitopes targeted by protective antibodies, we isolated 2 type-specific monoclonal antibodies (mAbs) from a ZIKV case. Both mAbs were strongly neutralizing in vitro and protective in vivo. The mAbs recognize distinct epitopes centered on domains I and II of the envelope protein. We also demonstrate that the epitopes of these mAbs define antigenic regions commonly targeted by plasma antibodies in individuals from endemic and nonendemic regions who have recovered from ZIKV infections.

Authors

Matthew H. Collins, Huy A. Tu, Ciara Gimblet-Ochieng, Guei-Jiun Alice Liou, Ramesh S. Jadi, Stefan W. Metz, Ashlie Thomas, Benjamin D. McElvany, Edgar Davidson, Benjamin J. Doranz, Yaoska Reyes, Natalie M. Bowman, Sylvia Becker-Dreps, Filemón Bucardo, Helen M. Lazear, Sean A. Diehl, Aravinda M. de Silva

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Figure 5

Epitope mapping of ZIKV-neutralizing mAb.

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Epitope mapping of ZIKV-neutralizing mAb. (A–C) Escape mutants for A9E w...
(AC) Escape mutants for A9E were generated from PRVABC59. (A) Binding of indicated mAb (left) and plasma (right) against A9E escape mutants from 2 independent experiments is shown. (B) Neutralization of 2 A9E escape mutants from 2 independent experiments by indicated mAb (top) and plasma (bottom) is shown. (C) ZIKV E homodimer with escape mutations indicated. (D) Amino acid residues critical for A9E mAb and G9E Fab binding were determined by alanine scanning shotgun mutagenesis. Plots show the binding of A9E and G9E versus control mAbs. The data point in red corresponds to the alanine mutant that significantly reduces probe mAb binding compared with loading control mAbs. (E) Critical residues (green spheres) discovered in alanine mutagenesis mapping are represented on a 3-dimensional model from a ZIKV cryo-EM structure (PDB ID: 5IRE). The fusion loop of E domain II is in cyan, domain I is in red, domain II is in yellow, and domain III is in blue.