论文信息 - SARS-CoV-2 infection leads to acute infection with dynamic cellular and inflammatory flux in the lung that varies across nonhuman primate species - 字舞流文

SARS-CoV-2 infection leads to acute infection with dynamic cellular and inflammatory flux in the lung that varies across nonhuman primate species

There are no known cures or vaccines for COVID-19, the defining pandemic of this era. Animal models are essential to fast track new interventions and nonhuman primate (NHP) models of other infectious diseases have proven extremely valuable. Here we compare SARS-CoV-2 infection in three species of experimentally infected NHPs (rhesus macaques, baboons, and marmosets). During the first 3 days, macaques developed clinical signatures of viral infection and systemic inflammation, coupled with early evidence of viral replication and mild-to-moderate interstitial and alveolar pneumonitis, as well as extra-pulmonary pathologies. Cone-beam CT scans showed evidence of moderate pneumonia, which progressed over 3 days. Longitudinal studies showed that while both young and old macaques developed early signs of COVID-19, both groups recovered within a two-week period. Recovery was characterized by low-levels of viral persistence in the lung, suggesting mechanisms by which individuals with compromised immune systems may be susceptible to prolonged and progressive COVID-19. The lung compartment contained a complex early inflammatory milieu with an influx of innate and adaptive immune cells, particularly interstitial macrophages, neutrophils and plasmacytoid dendritic cells, and a prominent Type I-interferon response. While macaques developed moderate disease, baboons exhibited prolonged shedding of virus and extensive pathology following infection; and marmosets demonstrated a milder form of infection. These results showcase in critical detail, the robust early cellular immune responses to SARS-CoV-2 infection, which are not sterilizing and likely impact development of antibody responses. Thus, various NHP genera recapitulate heterogeneous progression of COVID-19. Rhesus macaques and baboons develop different, quantifiable disease attributes making them immediately available essential models to test new vaccines and therapies.

C. Hallam | M. Mitreva | C. Ross | A. Baum | R. Copin | C. Kyratsous | Ayan Chatterjee | R. N. Platt | T. Anderson | D. Kaushal | M. Gazi | S. Khader | K. Alfson | R. Carrion | J. Patterson | L. Martínez-Sobrido | L. Schlesinger | K. Brasky | J. Turner | E. Dick | J. Torrelles | V. Hodara | L. Parodi | L. Giavedoni | Bindu Singh | D. Ajithdoss | J. Scordo | Mushtaq Ahmed | A. Oyejide | D. Singh | Shashank R. Ganatra | R. Sharan | X. Alvarez | E. Clemmons | John W Dutton | P. Frost | Ken Sayers | H. Staples | Rajesh Thippeshappa | A. Voges | Olga Gonzalez | Anna E Goodroe | Maya Gough | Tae-Hyung Lee | J. Cole | Shannan Hall-Ursone | Yenny Goez-Gazi | Benjamin Klaffke | Carmen Bartley | John W. Dutton | Priscilla Escareno | Christopher Chen | Ruby Escobedo | Cynthia Alvarez | Alyssa Blakley | Justin Ferdin | J. Callery | A. Mannino | Bruce Rosas | S. Ganatra | O. Gonzalez | K. Sayers | Hilary M Staples | Riti Sharan | Julia M. Scordo | T. Anderson

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