par Van Damme, Karel KFA;Hoste, Levi;Declercq, Jozefien;De Leeuw, Elisabeth;Maes, Bastiaan;Martens, Liesbeth;Colman, Roos;Browaeys, Robin;Bosteels, Cedric;Verwaerde, Stijn;Vermeulen, Nicky;Lameire, Sahine;Debeuf, Nincy;Deckers, Julie;Stordeur, Patrick 
;Depuydt, Pieter;Van Braeckel, Eva;Vandekerckhove, Linos;Guilliams, Martin;Schetters, Sjoerd;Haerynck, Filomeen;Tavernier, Simon S.J.;Lambrecht, Bart
Référence Science Translational Medicine, 15, 710, eadi0252
Publication Publié, 2023
;Depuydt, Pieter;Van Braeckel, Eva;Vandekerckhove, Linos;Guilliams, Martin;Schetters, Sjoerd;Haerynck, Filomeen;Tavernier, Simon S.J.;Lambrecht, BartRéférence Science Translational Medicine, 15, 710, eadi0252
Publication Publié, 2023
Article révisé par les pairs
| Résumé : | Improvements in COVID-19 treatments, especially for the critically ill, require deeper understanding of the mechanisms driving disease pathology. The complement system is not only a crucial component of innate host defense but can also contribute to tissue injury. Although all complement pathways have been implicated in COVID-19 pathogenesis, the upstream drivers and downstream effects on tissue injury remain poorly defined. We demonstrate that complement activation is primarily mediated by the alternative pathway, and we provide a comprehensive atlas of the complement alterations around the time of respiratory deterioration. Proteomic and single-cell sequencing mapping across cell types and tissues reveals a division of labor between lung epithelial, stromal, and myeloid cells in complement production, in addition to liver-derived factors. We identify IL-6 and STAT1/3 signaling as an upstream driver of complement responses, linking complement dysregulation to approved COVID-19 therapies. Furthermore, an exploratory proteomic study indicates that inhibition of complement C5 decreases epithelial damage and markers of disease severity. Collectively, these results support complement dysregulation as a key druggable feature of COVID-19. |
