Influenza vaccination reveals and partly reverses sex dimorphic immune imprints associated with prior mild COVID-19 (preprint)

Viral infections can have profound and durable functional impacts on the immune system. There is an urgent need to characterize the long-term immune effects of SARS-CoV-2 infection given the persistence of symptoms in some individuals and the continued threat of novel variants including the recent rapid acceleration in infections. As the majority of COVID-19 patients experienced mild disease, here we use systems immunology approaches to comparatively assess the post-infection immune status (mean: 151 [5th - 95th percentile: 58 - 235] days after diagnosis) and subsequent innate and adaptive responses to seasonal influenza vaccination (as an "immune challenge") in 33 previously healthy individuals after recovery from mild, non-hospitalized COVID-19, as compared to 40 age- and sex-matched healthy controls with no history of COVID-19. Sex-specific, temporally stable shifts in signatures of metabolism, T-cell activation, and innate immune/inflammatory processes suggest that mild COVID-19 can establish new post-infection immunological set-points. COVID-19-recovered males had an increase in CD71hi B-cells (including influenza-specific subsets) before vaccination and more robust innate, influenza-specific plasmablast, and antibody responses after vaccination compared to healthy males. Intriguingly, by day 1 post-vaccination in COVID-19-recovered subjects, the expression of numerous innate defense/immune receptor genes (e.g., Toll-like receptors) in monocytes increased and moved away from their post-COVID-19 repressed state toward the pre-vaccination baseline of healthy controls, and these changes tended to persist to day 28 in females, hinting that the acute inflammatory responses induced by vaccination could partly reset the immune states established by prior mild COVID-19. Our study reveals sex-dimorphic immune imprints and in vivo functional impacts of mild COVID-19 in humans, suggesting that prior COVID-19 could change future responses to vaccination and in turn, vaccines could help reset the immune system after COVID-19, both in an antigen-agnostic manner.

Multi-omics approach identifies novel age-, time- and treatment-related immunopathological signatures in MIS-C and pediatric COVID-19 (preprint)

Pediatric COVID-19 (pCOVID-19) is rarely severe, however a minority of SARS-CoV-2-infected children may develop MIS-C, a multisystem inflammatory syndrome with significant morbidity. In this longitudinal multi-institutional study, we used multi-omics to identify novel time- and treatment-related immunopathological signatures in children with COVID-19 (n=105) and MIS-C (n=76). pCOVID-19 was characterized by enhanced type I IFN responses, and MIS-C by type II IFN- and NF-{kappa}B dependent responses, matrisome activation, and increased levels of Spike protein. Reduced levels of IL-33 in pCOVID-19, and of CCL22 in MIS-C suggested suppression of Th2 responses. Expansion of TRBV11-2 T-cell clonotypes in MIS-C was associated with inflammation and signatures of T-cell activation, and was reversed by glucocorticoids. The association of MIS-C with the combination of HLA A*02, B*35, C*04 alleles suggests genetic susceptibility. MIS-C B cells showed higher mutation load. Use of IVIG was identified as a confounding factor in the interpretation of autoantibody levels.

Post-infectious inflammatory disease in MIS-C features elevated cytotoxicity signatures and autoreactivity that correlates with severity (preprint)

Multisystem inflammatory syndrome in children (MIS-C) is a life-threatening post-infectious complication occurring unpredictably weeks after mild or asymptomatic SARS-CoV2 infection in otherwise healthy children. Here, we define immune abnormalities in MIS-C compared to adult COVID-19 and pediatric/adult healthy controls using single-cell RNA sequencing, antigen receptor repertoire analysis, unbiased serum proteomics, and in vitro assays. Despite no evidence of active infection, we uncover elevated S100A-family alarmins in myeloid cells and marked enrichment of serum proteins that map to myeloid cells and pathways including cytokines, complement/coagulation, and fluid shear stress in MIS-C patients. Moreover, NK and CD8 T cell cytotoxicity genes are elevated, and plasmablasts harboring IgG1 and IgG3 are expanded. Consistently, we detect elevated binding of serum IgG from severe MIS-C patients to activated human cardiac microvascular endothelial cells in culture. Thus, we define immunopathology features of MIS-C with implications for predicting and managing this SARS-CoV2-induced critical illness in children.