Project description:The mRNA vaccines against COVID-19 are highly effective yet associated with rare myocarditis cases, particularly in young males post-second dose. Here we explore the mediators of this adverse effect and its potential solutions, aiming to enhance the safety of future mRNA vaccines. Analysis of post-vaccination plasma highlighted a substantial increase in CXCL10 and IFN-γ levels in patients. Correspondingly, human iPSC-derived macrophages exposed to COVID-19 mRNA vaccines exhibited increased production of these two cytokines. iPSC-derived cardiomyocytes subjected to these cytokines exhibited impaired contractility, arrhythmogenicity, and myocarditis-like gene expression patterns. Genistein, an anti-inflammatory phytoestrogen, notably mitigated these effects, reducing cytokine-induced proteasomal degradation of cardiac proteins and preserving contractile function. In vivo, genistein significantly decreased cardiac injury markers and immune cell infiltration in a mouse model of cytokine-induced myocarditis. These findings underscore CXCL10 and IFN-γ as key mediators of myocarditis post-mRNA vaccination and propose genistein as a potential therapeutic to mitigate associated cardiovascular risks.

Project description:CXCL10 and IFN-γ Mediate Myocarditis Post-COVID19 mRNA Vaccination.

Project description:CXCL10 and IFN-γ Mediate Myocarditis Post-COVID19 mRNA Vaccination [mouse]

Project description:CXCL10 and IFN-γ Mediate Myocarditis Post-COVID19 mRNA Vaccination [human]

Project description:The COVID-19 pandemic has prompted vaccine development efforts on an unprecedented scale. Vaccines based on mRNA technology have emerged as particularly attractive due to their high efficacy and short development timelines. However, relatively little is known about the factors contributing to the development of protective immunity by this new class of vaccines. We employed a high-temporal-resolution transcriptome profiling approach to investigate responses to COVID-19 mRNA vaccination. A cohort of 23 subjects was recruited and changes in blood transcript abundance were measured daily for 9 days post-priming and post-booster vaccination via RNA sequencing. Antibody responses were measured on days 7 and 14 post-vaccination using a custom multiplex assay. Marked differences were observed between responses to the priming and booster doses, with the latter inducing widespread changes in blood transcript abundance consistent with those found in patients with acute viral respiratory infections. The delineation of interferon responses at a high-temporal frequency also suggested that the priming and booster doses elicited distinct types of responses that peaked on day 2 post-priming dose and day 1 post-booster dose. The booster dose also induced inflammation on day 1 and erythroid cell signatures as well as an atypical plasmablast signature on day 4. Notably, this plasmablast signature, together with the post-booster interferon response signature, correlated with the antibody response levels induced on day 14 after the booster dose. Taken together, this work provides a detailed map of the antibody and transcriptional responses to the first and second doses of a new class of vaccine and yields important insights into the mechanisms underlying their immunogenicity. Furthermore, our results suggest that implementing high-temporal-frequency immune profiling protocols may provide an opportunity to better resolve the immune responses elicited by the growing number of available COVID-19 vaccines.

Project description:mRNA vaccines have played a crucial role in combating the COVID-19 pandemic, but the long-term dynamics of immune responses to repeated vaccination remain poorly understood. In this study, we extend our previous work on first and second dose responses by characterizing the immune signatures elicited by a third dose of COVID-19 mRNA vaccines. Using high-resolution temporal profiling of blood transcriptomes, we analyzed samples collected daily for 9 days post-vaccination across all three doses. We observed distinct patterns of gene expression related to interferon responses, inflammation, erythroid cell signatures, and plasmablast activity. While the first dose elicited a modest response primarily characterized by interferon signaling, the second dose induced a robust, polyfunctional response. Surprisingly, the third dose, administered months later, showed a response pattern that shared similarities with both previous doses but also exhibited unique features. The interferon response following the third dose mirrored the timing of the first dose, peaking on day 2, but matched the amplitude of the second dose. Notably, we observed a progressive amplification of the plasmablast response across the three doses, with an earlier peak (day 4) compared to other vaccines, potentially a unique feature of mRNA vaccines. These findings provide crucial insights into how the immune system adapts to repeated mRNA vaccination over extended periods. They demonstrate that the heightened responsiveness induced by initial doses is maintained months later, suggesting effective immune memory. Our results contribute to a more comprehensive understanding of mRNA vaccine-induced immunity, with implications for optimizing booster strategies and developing next-generation vaccines.

Project description:mRNA vaccines have demonstrated efficacy against COVID-19. However, concerns regarding waning immunity and breakthrough infections have motivated the development of next-generation vaccines with enhanced efficacy. In this study, we investigated the impact of 4-1BB costimulation on immune responses elicited by mRNA vaccines in mice. We first vaccinated mice with an mRNA vaccine encoding the SARS-CoV-2 spike antigen like the Moderna and Pfizer-BioNTech vaccines, followed by administration of 4-1BB costimulatory antibodies at various times post-vaccination. Administering 4-1BB costimulatory antibodies during the priming phase did not enhance immune responses. However, administering 4-1BB costimulatory antibodies after 96 hours elicited a significant improvement in CD8 T cell responses, leading to enhanced protection against breakthrough infections. A similar improvement in immune responses was observed with multiple mRNA vaccines, including vaccines against common cold coronavirus, human immunodeficiency virus (HIV), and arenavirus. These findings demonstrate a time-dependent effect by 4-1BB costimulation and provide insights for developing improved mRNA vaccines.

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: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:This study investigates the innate immune response to COVID-19 mRNA and vector-based vaccines in 15 patients with chronic lymphocytic leukemia (CLL). It assessed the innate and adaptive immune response of CLL patients after booster vaccination and generated a comprehensive transcriptome (mRNA-seq) analysis of peripheral blood mononuclear cells (PBMCs). Specifically, this investigation on a ‘3-dose’ cohort of heavily pretreated CLL patients, who had tested seronegative following a two-dose homologous vaccination (either BNT162b2 or ChAdOx1) and had received a third heterologous dose. A ‘2-dose’ cohort encompassed treatment-naïve or minimal pretreated CLL patients, who showed a serological immune response after the first vaccination and had received a second dose. Bulk mRNA-seq was conducted on PBMCs harvested prior to the vaccination and at days 2 and 7 post vaccination. The innate immune response observed in all patients was independent of the IgG antibody response. Expression of interferon-regulated genetic pathways was induced within two days after vaccination.