Project description:We developed prototype LNP-mRNA vaccine candidates against SARS-CoV-2 Delta, SARS-CoV and MERS-CoV, and test how multiplexing LNP-mRNAs can induce effective immune responses in animal models. Triplex and Duplex LNP-mRNA vaccination induced antigen-specific antibody responses against SARS-CoV-2, SARS-CoV and MERS-CoV. Single cell RNA-seq profiled the global systemic immune repertoires and respective transcriptome signatures of vaccinated animals, revealing systemic increase in activated B cells, and differential gene expression across major adaptive immune cells. Sequential vaccination showed potent antibody responses against all three species, significantly stronger than simultaneous vaccination in mixture. These data demonstrated feasibility, antibody responses and single cell immune profiles of multi-species coronavirus vaccination. The direct comparison between simultaneous and sequential vaccination offers insights on optimization of vaccination schedules to provide broad and potent antibody immunity against three major pathogenic coronavirus species.

Project description:Prototype LNP-mRNA vaccine candidates [SC_RNAseq]

Project description:Targeting the Cancer-Retina Antigen PDE6G with mRNA-LNP Vaccine Elicits Potent Anti-Tumor Immunity Against Breast Cancer

Project description:The soaring global monkeypox cases lead to a surge in demand for monkeypox vaccine, which far exceeds the supply. mRNA vaccine has achieved great success in prevention of coronavirus disease and holds promise against diverse pathogens. In this study, we generate a polyvalent lipid nanoparticle (LNP) mRNA vaccine candidate for monkeypox virus (MPXV) and evaluate its immunogenicity in animal models. This polyvalent MPXV mRNA vaccine candidate, MPXVac-097, encodes five 2022 MPXV targets that are important surface antigens. Three-dose (prime-boost-booster) MPXVac-097 vaccination elicits strong antibody response to A35R and E8L antigens, moderate response to M1R, but not B6R or A29, highlighting the differences in immunogenicity. Bulk T cell receptor (TCR) sequencing reveals preferential usage of VJ combinations and clonal expansion of peripheral T cells after MPXVac-097 vaccination. These data demonstrate initial feasibility of developing MPXV mRNA vaccine and pave the way for its future optimization.

Project description:A universal influenza vaccine that elicits a strong and lasting stalk-specific antibody response is advantageous. We utilize nucleoside-modified mRNA in lipid nanoparticles (mRNA-LNP) and unmodified self-amplifying mRNA in modified dendritic nanoparticles (sam-MDNP), expressing chimeric hemagglutinin (cHA) antigens to induce stalk-specific humoral immunity in non-human primates (NHPs) with preexisting influenza virus immunity. mRNA-LNP immunization induces strong stalk-specific binding antibodies, protecting mice from lethal heterologous influenza virus challenges, along with bone marrow plasma cells (BMPC) that persist for up to 8 months. sam-MDNP vaccine induces lower humoral immunity, despite showing strong innate activation. Transcriptomic and cytokine analyses reveal a more persistent induction of interferon responses, IL-1β signaling, and IL-6 production in the mRNA-LNP group, correlating with the induction of serum antibody responses and BMPC. We identify a transcriptional signature associated with induction of BMPC following mRNA vaccination and highlight the utility of cHA-based mRNA-LNP vaccines in inducing persistent stalk-directed protective antibody responses.

Project description:Lipid nanoparticles (LNPs) for mRNA delivery have advanced significantly, but LNP-mediated DNA delivery still faces clinical challenges. This study compared various LNP formulations for delivering DNA-encoded biologics, assessing their expression efficacy and the protective immunity generated by LNP-encapsulated DNA in different models. The LNP formulation used in Moderna’s Spikevax mRNA vaccine (LNP-M) demonstrated a stable nanoparticle structure, high expression efficiency, and low toxicity. Notably, a DNA vaccine encoding the spike protein, delivered via LNP-M, induced stronger antigen-specific antibody and T cell immune responses compared to electroporation. Single-cell RNA sequencing (scRNA-seq) analysis revealed that the LNP-M/pSpike vaccine enhanced CD80 activation signaling in CD8+ T cells, NK cells, macrophages, and DCs, while reducing the immunosuppressive signals. The enrichment of TCR and BCR by LNP-M/pSpike suggested an increase in immune response specificity and diversity. Additionally, LNP-M effectively delivered DNA-encoded antigens, such as mouse PD-L1 and p53R172H, or monoclonal antibodies targeting mouse PD-1 and human p53R282W. This approach inhibited tumor growth or metastasis in several mouse models. The long-term anti-tumor effects of LNP-M-delivered anti-p53R282W antibody relied on memory CD8+ T cell responses and enhanced MHC-I signaling from APCs to CD8+ T cells. These results highlight LNP-M as a promising and effective platform for delivering DNA-based vaccines and cancer immunotherapies.

Project description:Crimean-Congo hemorrhagic fever (CCHF), caused by Crimean-Congo hemorrhagic fever virus (CCHFV), is on the World Health Organizations list over emerging pathogens and prioritized diseases. With global distribution, high fatality rate and no approved treatment or vaccine, CCHF constitute a treat against the global health. In the current study we show full protection of mice against lethal CCHFV infection due to mRNA-LNP vaccination. IFNAR-/- mice received two immunizations with either mRNA-LNP encoding for the CCHFV nucleoprotein, glycoproteins or a combination of both. While unvaccinated mice showed clear signs of severe disease, vaccinated mice was significantly protected. Vaccine induced immune responses due to vaccination was evaluated both in IFNAR-/- and immunocompetent mice and a strong humoral and cellular immune response was observed in both mouse models with high titers of neutralizing antibodies and primed T-cells. In addition, we conducted a proteomic analysis on liver samples from vaccinated and unvaccinated mice after CCHFV infection to determine the effect of vaccination on the protein profile. Similar to what has been observed in humans due to vaccination, there was an effect on metabolic pathways. In conclusion, this study shows very promising results regarding development of a vaccine against CCHFV.

Project description:Vaccines comprised of mRNA and lipid nanoparticles (LNP) activate B and T cells by inducing in vivo production of specific protein antigens. While B cells can be activated directly by antigens, activation of T cells requires antigen processing and presentation by MHC molecules on specialized antigen presenting cells (APCs). In response to viral infections, tumors and current vaccines, antigen presentation to CD8 T cells is particularly dependent on type 1 conventional dendritic cells (cDC1s) which are specialized for efficient antigen cross-presentation of exogenous antigens. However, whether similar mechanisms are employed by mRNA-LNP vaccination is currently unknown. Here, we show that mRNA LNP vaccines do not depend on cDC1 to induce CD8 T cell responses but engage cDC1 and cDC2 redundantly. In addition, these responses do not involve the normal WDFY4-dependent cross-presentation pathway. Rather, cDC2 are a prominent component driving CD8 T cells response against mRNA-LNP vaccination and engage cross-dressing of peptide-MHC-I complexes derived from non-hematopoietic cells. Notably, multimodal single cells analysis revealed that CD8 T cells primed either by cDC1 or cDC2 exhibit phenotypical differences. These results suggest that mRNA-LNP vaccination should be further evaluated for its ability to sustain normal functional memory that emerges from natural infections or vaccines that engage cDC1 for CD8 T cell priming.

Project description:Heterologous vaccination regimens are increasingly recommended for their potential benefits, including reduced side effects and enhanced immunogenicity. In this study, we investigated the innate and adaptive immune responses elicited by heterologous prime-boost vaccination using adenoviral vector and mRNA vaccines against SARS-CoV-2 in a mouse model. Our findings show that heterologous vaccination induced superior serum neutralizing and binding antibody titers, as well as enhanced cellular immune responses against the Delta and Omicron (BA.5) variants, compared to homologous vaccination. Single-cell transcriptomic analysis at the injection site, conducted 16 hours post-vaccination, revealed that the lipid nanoparticle (LNP)-based mRNA vaccine—and even empty LNP injection—triggered significant immune cell infiltration, while adenoviral vector vaccination caused minimal changes in injection-site cell composition following the first dose. Notably, spike mRNA was predominantly expressed in fibroblasts and macrophages across both vaccine platforms, suggesting these cells’ role in local immune responses. Further analysis demonstrated that the adenoviral vector booster induced amplified immune responses, marked by increased transcriptional changes, particularly in stromal pro-inflammatory pathways. Heterologous vaccination (adenoviral prime, mRNA boost) further intensified these responses compared to homologous mRNA vaccination, indicating that adenoviral priming enhances inflammatory responses when followed by an mRNA boost. In summary, our results demonstrate that heterologous vaccination strategies elicit stronger innate and adaptive immune responses compared to homologous regimens, supporting their use as an effective approach for enhanced protection against variants.

Project description:Functional T cell responses are crucial for protective immunity induced by COVID-19 vaccination, but factors influencing the quality of these responses are incompletely understood. We employ an activation induced marker (AIM) assay and single-cell transcriptomic sequencing to analyze SARS-CoV-2 spike-responsive T cells following mild SARS-CoV-2 infection or following one or two doses of mRNA-LNP or adenoviral vectored COVID-19 vaccines. Our findings reveal broad functional and clonal heterogeneity in T cells generated by vaccination or infection, including multiple distinct effector populations. T cell function was largely conserved between COVID-19 vaccine platforms but was distinct compared to SARS-CoV-2 infection. Notably, the dosing interval greatly influenced the quality of T cells after two vaccine doses, particularly after mRNA-LNP vaccination, where a longer interval led to reduced inflammatory signaling and increased secondary proliferation. These insights enhance our understanding of SARS-CoV-2 specific T cells and inform the optimization of mRNA vaccination remens.