Oligomeric state of the ZIKV E protein defines protective immune responses

Metz, Stefan W.; Thomas, Ashlie; Brackbill, Alex; Forsberg, John; Miley, Michael J.; Lopez, Cesar A.; Lazear, Helen M.; Tian, Shaomin; de Silva, Aravinda M.

Oligomeric state of the ZIKV E protein defines protective immune responses

Stefan W. Metz (), Ashlie Thomas, Alex Brackbill, John Forsberg, Michael J. Miley, Cesar A. Lopez, Helen M. Lazear, Shaomin Tian and Aravinda M. de Silva ()
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Stefan W. Metz: University of North Carolina at Chapel Hill
Ashlie Thomas: University of North Carolina at Chapel Hill
Alex Brackbill: University of North Carolina at Chapel Hill
John Forsberg: University of North Carolina at Chapel Hill
Michael J. Miley: University of North Carolina at Chapel Hill
Cesar A. Lopez: University of North Carolina at Chapel Hill
Helen M. Lazear: University of North Carolina at Chapel Hill
Shaomin Tian: University of North Carolina at Chapel Hill
Aravinda M. de Silva: University of North Carolina at Chapel Hill

Nature Communications, 2019, vol. 10, issue 1, 1-7

Abstract: Abstract The current leading Zika vaccine candidates in clinical testing are based on live or killed virus platforms, which have safety issues, especially in pregnant women. Zika subunit vaccines, however, have shown poor performance in preclinical studies, most likely because the antigens tested do not display critical quaternary structure epitopes present on Zika E protein homodimers that cover the surface of the virus. Here, we produce stable recombinant E protein homodimers that are recognized by strongly neutralizing Zika specific monoclonal antibodies. In mice, the dimeric antigen stimulate strongly neutralizing antibodies that target epitopes that are similar to epitopes recognized by human antibodies following natural Zika virus infection. The monomer antigen stimulates low levels of E-domain III targeting neutralizing antibodies. In a Zika challenge model, only E dimer antigen stimulates protective antibodies, not the monomer. These results highlight the importance of mimicking the highly structured flavivirus surface when designing subunit vaccines.

Date: 2019
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DOI: 10.1038/s41467-019-12677-6

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