Project description:The local and systemic symptoms that follow vaccination -collectively referred to as reactogenicity- are common, yet the mechanisms underlying individual variability remain poorly understood. Through longitudinal immune profiling of vaccinated individuals and mechanistic studies in mice, we identified key immunological determinants of reactogenicity induced by mRNA vaccines. Systemic adverse events were associated with stronger interferon and pro-inflammatory responses following the second dose of COVID-19 vaccine, which were also correlated with the magnitude of the antigen-specific adaptive responses. This heightened inflammation occurred within 24 hours of vaccination and originated primarily from the injection site and was characterized by enhanced recruitment and activation of myeloid cells, particularly monocytes. Two mechanisms contributed to this response: (1) early interferon production by muscle T cells generated after the first dose and (2) FcγR-dependent chemokine induction by antigen-specific antibodies. Consistently, serum antibody levels prior to vaccination correlated positively with reactogenicity. In addition to this local amplification mechanism, variability in reactogenicity was influenced by the baseline immune state, as individuals with a pre-existing interferon-stimulated gene signature in monocytes, detectable at both transcriptomic and epigenetic levels, were more prone to systemic symptoms. Our findings reveal molecular and cellular mechanisms driving vaccine reactogenicity, providing a framework for the design of less reactogenic vaccines.

Project description:Adenoviral (Ad) vectors and mRNA vaccines exhibit distinct patterns of immune responses, with reactogenicity influencing their use during and beyond the COVID-19 pandemic. However, despite the clinical significance, the underpinning mechanisms remain unclear. Innate and innate-like lymphocytes, such as mucosal-associated invariant T cells, are highly sensitive to cytokines and can enhance both innate and adaptive vaccine responses. We compared longitudinal human immune responses and reactogenicity following homologous ChAdOx1 nCoV-19 and BNT162b2 vaccination to define the interactions between innate-like lymphocytes and adaptive immunity – and their in vivo consequences. Specifically, Ad vector priming elicited robust early type I interferon (IFN)-mediated activation of innate-like T cells, augmenting T cell responses (innate to adaptive signalling), which diminished upon boosting in the presence of anti-vector immunity. In contrast, mRNA vaccine responses in innate-like cells were markedly enhanced after boosting. This was initiated by IFN-γ signalling from spike-specific memory T cells and amplified by IFN-γR+ innate-like lymphocyte networks (adaptive to innate signalling). Importantly, extending the interval between doses reduced inflammatory responses to mRNA vaccination. In an independent clinical trial, spike-specific T cells predicted severe reactogenicity to mRNA vaccine boosting regardless of the dosing interval and vaccine type. These findings reveal a close integration of innate-like and adaptive responses to novel vaccines, including an IFN-γ-mediated function of innate-like T cells in orchestrating critical early responses to mRNA vaccines which may have significant implications for optimising future vaccine regimens.

Project description:Adenoviral (Ad) vectors and mRNA vaccines exhibit distinct patterns of immune responses, with reactogenicity influencing their use during and beyond the COVID-19 pandemic. However, despite the clinical significance, the underpinning mechanisms remain unclear. Innate and innate-like lymphocytes, such as mucosal-associated invariant T cells, are highly sensitive to cytokines and can enhance both innate and adaptive vaccine responses. We compared longitudinal human immune responses and reactogenicity following homologous ChAdOx1 nCoV-19 and BNT162b2 vaccination to define the interactions between innate-like lymphocytes and adaptive immunity – and their in vivo consequences. Specifically, Ad vector priming elicited robust early type I interferon (IFN)-mediated activation of innate-like T cells, augmenting T cell responses (innate to adaptive signalling), which diminished upon boosting in the presence of anti-vector immunity. In contrast, mRNA vaccine responses in innate-like cells were markedly enhanced after boosting. This was initiated by IFN-γ signalling from spike-specific memory T cells and amplified by IFN-γR+ innate-like lymphocyte networks (adaptive to innate signalling). Importantly, extending the interval between doses reduced inflammatory responses to mRNA vaccination. In an independent clinical trial, spike-specific T cells predicted severe reactogenicity to mRNA vaccine boosting regardless of the dosing interval and vaccine type. These findings reveal a close integration of innate-like and adaptive responses to novel vaccines, including an IFN-γ-mediated function of innate-like T cells in orchestrating critical early responses to mRNA vaccines which may have significant implications for optimising future vaccine regimens.

Project description:Systems vaccinology approaches have been used to successfully define early signatures of the vaccine-induced immune response. However, the possibility that transcriptomics can also predict vaccine reactogenicity has not been fully explored. We have compared four licensed vaccines that have a demonstrated safety profile, as well as three agonists of TLRs that have a known inflammatory potential, to elucidate the transcriptomic profile of an acceptable response to a vaccination versus those which push the inflammatory envelope. In mice, we looked at the transcriptomic changes in the injected muscle, the lymph node that drained the muscle and the PBMC isolated from the circulating blood from the very early timepoint of 4 hours to over the period of one week. A detailed examination and comparative analysis of the transcriptome from each of these tissues, at all the timepoints of 4, 8, 24, 48, 72 and 168 hr and with these eight different vaccines, TLR or saline control injections, revealed a set of novel biomarkers that are reflective of inflammation after vaccination. These biomarkers are easily sampled and readily measurable in the peripheral blood, providing a useful tool to predict levels of reactogenicity, as a way to select candidates with acceptable immunogenicity and safety profiles.

Project description:We longitudinally profiled plasma proteomes in 54 adults vaccinated with the BNT162b2 (Pfizer-BioNTech) or ChAdOx1-S (Oxford-AstraZeneca) vaccines. Blood was collected pre-vaccination (V0) and 1-7 days after the 1st doses (BNT162b2 or mRNA-1273, V1) to assess innate and early adaptive responses. We identified key differences in the immune responses induced by the ChAdOx1-S and BNT162b2 vaccines that were correlated with subsequent antigen-specific antibody and T cell responses or vaccine reactogenicity. We observed that vaccination with ChAdOx1-S but not BNT162b2 induced a memory-like response after the first dose, which was correlated with the expression of several proteins involved in complement and coagulation. The COVID-19 Vaccine Immune Responses Study (COVIRS) thus represents a major resource to understand the immunogenicity and reactogenicity of these COVID-19 vaccines.

Project description:Squalene-based adjuvants are widely utilized in various vaccines because of their effectiveness in enhancing immune responses. Among these, A-910823 and AS03 are recognized squalene-based adjuvants containing α-tocopherol. Although α-tocopherol-containing squalene-based adjuvants are known to enhance humoral immune responses and inflammatory cytokine production, their underlying mechanisms remain unclear. Here, we found that A-910823 regulated IL-1 signaling pathway gene expression and IL-1α and IL-1β protein expressions in an α-tocopherol-dependent manner. While the source of IL-1α was mainly from eosinophils, IL-1β was from wide range of myeloid cells. Mechanistically, IL-1β/CD11c+ cell-IL-1R1/MyD88 axis mediated adjuvant efficacy, however, systemic reactogenicity was induced by the IL-1β/IL-1R1/MyD88/IL-6/cyclooxygenase 2 axis which was unexpectedly distinct mechanism from the local reactogenicity that was mediated by the eosinophil-derived IL-1α/IL-1R1/MyD88 axis. These findings demonstrate that adjuvant efficacy and reactogenicity are regulated by distinct pathways and cell types. This study thus provides novel insights into the mechanisms of adjuvants, providing valuable information to support the future development of effective and safe vaccines.

Project description:Identification of Biomarkers of Vaccine Reactogenicity

Project description:While dendritic cells (DCs) are known to play a major role in the process of vaccination, the mechanisms by which vaccines induce protective immunity in humans remain elusive. Herein, we used gene microarrays to characterize the transcriptional programs induced over time in human monocyte-derived DCs (moDCs) in vitro in response to influenza H1N1 Brisbane, Salmonella enterica and Staphylococcus aureus. We built a data-driven modular analytical framework focused on 204 pathogen-induced gene clusters. The expression of these modules was analyzed in response to 16 well-defined ligands, targeting TLRs, cytoplasmic PAMP receptors and cytokine receptors. This multi-dimensional framework covers the major biological functions of APC, including the IFN response, inflammation, DC maturation, T cell activation, antigen processing, cell motility and histone regulation. This framework was used to characterize the response of monocytes and moDCs to 14 commercially available vaccines. These vaccines displayed quantitatively and qualitatively distinct modular signatures in monocytes and DCs, in particular Fluzone and Pneumovax, highlighting the functional and phenotypic differences between APC subsets. This modular framework allows the application of systems immunology approaches to study early transcriptional changes in human APC subsets in response to pathogens and vaccines, which might guide the development of improved vaccines. 64 samples of IL4 DC, and 64 samples of monocytes stimulated by media (controls, designated 1 and 2 to indicate biological replicates), Menomune (Neisseiria meningitis vaccine, MGL), Fluzone 09-10 (Influenza vaccine, FZ), Havrix (Hepatitis A vaccine, HEPA), Ixiaro (Japanese encephalitis vaccine, JPE), ActHib (Haemophilus influenza vaccine, HIB) and Pneumovax (Pneumococcus vaccine, PVX), Engerix-B (Hepatitis B vaccine, HEPB), Zostavax (Herpes Zoster vaccine, HER), and Gardasil (Human Papilloma virus vaccine, HPV), LPS, Ipol (Polio vaccine, POL), Rabies vaccine (RAB), toxoid-based vaccine (TDAP), Varivax (Varicella vaccine, VAR)

Project description:Despite the widespread use of adenovirus, mRNA, and protein-based vaccines during the COVID-19 pandemic, their relative immunological profiles and protective efficacies remain incompletely defined. Here, we compared antigen kinetics, innate and adaptive immune responses, and protective efficacy following Ad5, mRNA, and protein vaccination in mice. Ad5 induced the most sustained antigen expression, but mRNA induced the most potent interferon responses, associated with robust antigen presentation and costimulation. Unlike Ad5 vaccines, which were hindered by pre-existing vector immunity, mRNA vaccines retained efficacy after repeated use. As a single-dose regimen, Ad5 vaccines elicited superior immune responses. However, as a prime-boost regimen, and particularly in Ad5 seropositive mice, mRNA vaccines outperformed the other vaccine platforms. These findings highlight strengths of each vaccine platform and underscore the importance of vaccination context in determining optimal vaccine performance.

Project description:The objective of this study is to: 1) Characterize the cellular origin of transciptional signatures observed on day 1 after vaccination with 2009/10 seasonal influenza and pneumococcal vaccine discovered by transcriptional profiling of whole blood samples in data set “WholeBlood_SysVax”. 2) Discover potential biomarkers for immune-responsiveness to non-live vaccines. In this Series, a total of 72 samples of leukocyte subsets (neutrophils, monocytes, CD4+ T and CD8+ T lymphocytes) were isolated before and 24 hours after vaccination from 6 healthy adult individuals receiving seasonal influenza and 4 healthy adult individuals receiving pneumococcal vaccine. From each subject, neutrophils and peripheral blood mononuclear cells were obtained by Ficoll gradient separation and then CD14+ monocytes, CD4+ T and CD8+ T cells were purified by sequential positive bead selection. Cells were transferred into RLT buffer and stored at -80ºC until mRNA extraction.