Intradermal delivery of a synthetic DNA vaccine protects macaques from Middle East respiratory syndrome coronavirus
Ami Patel, Emma L. Reuschel, Ziyang Xu, Faraz I. Zaidi, Kevin Y. Kim, Dana P. Scott, Janess Mendoza, Stephanie Ramos, Regina Stoltz, Friederike Feldmann, Atsushi Okumura, Kimberly Meade-White, Elaine Haddock, Tina Thomas, Rebecca Rosenke, Jamie Lovaglio, Patrick W. Hanley, Greg Saturday, Kar Muthumani, Heinz Feldmann, Laurent M. Humeau, Kate E. Broderick, David B. Weiner
Ami Patel, Emma L. Reuschel, Ziyang Xu, Faraz I. Zaidi, Kevin Y. Kim, Dana P. Scott, Janess Mendoza, Stephanie Ramos, Regina Stoltz, Friederike Feldmann, Atsushi Okumura, Kimberly Meade-White, Elaine Haddock, Tina Thomas, Rebecca Rosenke, Jamie Lovaglio, Patrick W. Hanley, Greg Saturday, Kar Muthumani, Heinz Feldmann, Laurent M. Humeau, Kate E. Broderick, David B. Weiner
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Research Article Infectious disease Vaccines

Intradermal delivery of a synthetic DNA vaccine protects macaques from Middle East respiratory syndrome coronavirus

Abstract

Emerging coronaviruses from zoonotic reservoirs, including severe acute respiratory syndrome coronavirus (SARS-CoV), Middle East respiratory syndrome coronavirus (MERS-CoV), and severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), have been associated with human-to-human transmission and significant morbidity and mortality. Here, we study both intradermal and intramuscular 2-dose delivery regimens of an advanced synthetic DNA vaccine candidate encoding a full-length MERS-CoV spike (S) protein, which induced potent binding and neutralizing antibodies as well as cellular immune responses in rhesus macaques. In a MERS-CoV challenge, all immunized rhesus macaques exhibited reduced clinical symptoms, lowered viral lung load, and decreased severity of pathological signs of disease compared with controls. Intradermal vaccination was dose sparing and more effective in this model at protecting animals from disease. The data support the further study of this vaccine for preventing MERS-CoV infection and transmission, including investigation of such vaccines and simplified delivery routes against emerging coronaviruses.

Authors

Ami Patel, Emma L. Reuschel, Ziyang Xu, Faraz I. Zaidi, Kevin Y. Kim, Dana P. Scott, Janess Mendoza, Stephanie Ramos, Regina Stoltz, Friederike Feldmann, Atsushi Okumura, Kimberly Meade-White, Elaine Haddock, Tina Thomas, Rebecca Rosenke, Jamie Lovaglio, Patrick W. Hanley, Greg Saturday, Kar Muthumani, Heinz Feldmann, Laurent M. Humeau, Kate E. Broderick, David B. Weiner

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Figure 2

Postchallenge pathology prevented by MERS DNA vaccine.

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Postchallenge pathology prevented by MERS DNA vaccine. (A) Clinical scor...
(A) Clinical scores for each group after challenge. Animals were scored for visible signs of disease daily following challenge, with increasing scores indicating more severe symptoms. (B) Viral loads in vaccinated versus naive animals. (C and D) Viral loads in various tissues for each group after challenge. The viral load at day 6 after challenge in respiratory tissues and lymph nodes was measured by RT-PCR. Individual animals are included in the box-and-whisker plots, with whiskers showing the minimum and maximum values. (E) Representative H&E-stained and IHC-stained lung tissue sections from animals in each vaccination group day 6 after challenge. Vaccinated animals demonstrate essentially normal lung parenchyma. The naive animal shows moderate interstitial pneumonia. Viral antigen was detected by IHC (pink stain) in 4 of 6 control animals, but none of the immunized animals. Original magnification, ×40 (H&E, left); ×200 (H&E, right); ×400 (IHC).