Project description:Cance vaccines have become a milestone in immunotherapy, but inadequate activation rate of antigen presenting cells (APCs) and low delivery efficiency of specific antigen have widely limited their clinical application. Here we design an engineered vaccine platform based on targeted delivery of specific antigens to activated APCs. This vaccine platform is implemented by loading stimulator of interferon genes agonist and tumor lysate protein with calcium phosphate as adjuvants, and coating the surface with mannose-modified liposomes. By loading different types of tumor antigen proteins, this nanovaccine platform successfully achieves tumor immunotherapy in breast and colon cancer bearing mice. In addition, personalized nanovaccine prepared from surgically removed tumor lysate proteins also significantly suppresses postsurgical distant tumor. Through the design of nanovaccine platform, we provide an efficient multi-adjuvant delivery platform for multiple types of tumor antigens, and also offer more ideas for personalized vaccine immunization. This nanovaccine platform has great prospects for transformation due to the designability and simplicity for the preparation.

Project description:mRNA vaccines are emerging as a powerful vaccine platform as they are well-tolerated and scalable. Modified non-replicating mRNA encoding Influenza hemagglutinin and encapsulated in lipid nanoparticles (LNP) induced robust antibody and CD4 T cell responses after intramuscular or intradermal delivery in rhesus macaques. We investigated the local innate immune responses modulating such vaccine-induced immunity at the sites of immunization (skeletal muscle and skin) and their draining lymph nodes (LNs). Rapid mobilization of antigen presenting cells was found at the LNP/mRNA-injection sites and LNs. Dendritic cells efficiently internalized the LNPs, translated the mRNA cargo and upregulated co-stimulatory molecules. In addition, several type I interferon-inducible genes were expressed at the immunization sites and draining LNs. The innate immune activation was transient and resulted in priming of antigen-specific CD4+ T cells exclusively in the vaccine-draining LNs. Collectively, mRNA-based vaccines induce type I interferon-polarized innate immunity and antigen production by antigen presenting cells, which resulted potent vaccine-specific responses.

Project description:Attempts to develop a therapeutic vaccine against human papillomavirus (HPV)-induced malignancies have not been clinically successful to date. One reason may be the hypoxic microenvironment present in most tumors, including cervical cancer. Hypoxia dysregulates the levels of human leukocyte antigen (HLA) class I molecules in different tumor entities, impacts function of cytotoxic T cells, and leads to decreased protein levels of the oncoproteins E6 and E7 in HPV-transformed cells. Therefore, we investigated the effect of hypoxia on the presentation of HPV16 E6- and E7-derived epitopes in cervical cancer cells and its effect on epitope-specific T cell cytotoxicity. Hypoxia induced downregulation of E7 protein levels in all analyzed cell lines, as assessed by Western blotting. However, contrary to previous reports, no perturbation of antigen presentation machinery (APM) components and HLA-A2 surface expression upon hypoxia treatment was detected by mass spectrometry and flow cytometry, respectively. Cytotoxicity assays performed in hypoxic conditions showed differential effects on the specific killing of HPV16-positive cervical cancer cells by epitope-specific CD8+ T cell lines in a donor- and peptide-specific manner. Effects of hypoxia on the expression of PD-L1 were ruled out by flow cytometry analysis. Altogether, our results suggest an intact APM, and cytotoxicity despite the decreased expression of E6 and E7, suggesting that successful immunotherapies can be developed for HPV-induced cervical cancer, especially if combined with hypoxia-alleviating measures.

Project description:CD4 T cells promote innate and adaptive immune responses, but how vaccine-elicited CD4 T cells contribute to immune protection remains unclear. Here we evaluated whether induction of virus-specific CD4 T cells by vaccination would protect mice against infection with chronic lymphocytic choriomeningitis virus (LCMV). Immunization with vaccines that selectively induced CD4 T cell responses resulted in catastrophic inflammation and mortality following challenge with a persistent form of LCMV. Immunopathology required antigen-specific CD4 T cells and was associated with a cytokine storm, generalized inflammation, and multi-organ system failure. Virus-specific CD8 T cells or antibodies abrogated the pathology. These data demonstrate that vaccine-elicited CD4 T cells in the absence of effective antiviral immune responses can trigger lethal immunopathology. Splenic GP66-specific CD4 T cells from mice immunized with either a LMwt vaccine (sham) or LMgp61 vaccine (CD4 vaccine) were purified by FACS on day 8 post-infection with LCMV clone 13

Project description:Nanoparticles, including virus-like particles (VLP), are attractive candidates as carriers for vaccines and drug delivery. However, little is known about how they are targeted to the immune system in vivo. Using RNA phage Qb-derived VLP (Qb-VLP) as a model antigen, we found surprisingly that antigen-specific B cells, instead of dendritic cells (DCs), were the dominant antigen presenting cells that initiate the naïve CD4 T cell activation, and were sufficient to induce T follicular helper cell development in the absence of DCs. Qb-specific B cells promoted CD4 T cell proliferation by providing cognate interactions and cell differentiation by generating cytokine milieu which depended on the Toll-like receptor signaling in B cells. Moreover, antigen-specific B cells were also involved in initiating CD4 T cell response to influenza virus. The mechanism revealed here will advance the rational design of nanoparticles as vaccine candidates, especially for therapeutic vaccines that aim to break immune tolerance.

Project description:New universal prophylactic vaccine platforms are needed to prevent or reduce the impact of future respiratory viral infections. While the attribute of T memory cells is particularly attractive in the context of vaccine design for viral infection, the efficiency of T and B memory cell-mediated protection generated under the adenoviral vector was tested. We studied the mechanism using the platform/ immunological factor combination (AdV1+rRBD): adenovirus AdV1 (adjuvant) armed with inducible co-stimulator ICOS and CD40 ligand in combination with recombinant spike protein rRBD (antigen) to promote the differentiation of memory T and B cells. Additionally, adenovirus AdV2 (adjuvant) without ICOS and CD40 ligand in combination with rRBD was tested. Investigating ex vivo T cell responses to the platform-specific stimuli, we found higher frequencies of CD8+ than CD4+ platform-specific T cells vs mock. The cytometric analysis showed that T cells confer protection against SARS-CoV-2 via elevated T cell subsets: CD8+TEMRA (57.6% ± SD 3.3 vs mock 39.6% ± SD 4.83) and CD4+TNAÏVE (59.6% ± SD 0.4 vs mock 50.8% ± SD 1.9). We found that CD8+TEM, CD8+TSCM, and CD8+TCM are antigen-experienced subpopulations generated via the platform after 7 days. When stimulated with the immunological factors, B cells changed from the production of IgM and IgD to isotype IgG. The CD40 gene was significantly expressed (RT-qPCR) in VERO E6 after stimulation with the platform. RNA-seq profiling identified Th1, Th2, and Th17 cell differentiation gene expression patterns that effectively protect against different pathogens. RNA-seq analysis determined signaling pathways that control immunological mechanisms by which the platform induces protective immunity: MAPK cascade, adipocytokine, cAMP, TNF, and Toll-like receptor (TLR) signaling pathway. The formulation (AdV1+rRBD) increased the production of IL-6, IL-8, and TNF vs the mock (P<0.0001). The whole-genome sequencing of VERO E6 showed differences in the expression of apoptosis gene stimulated with the platforms vs mock. Moreover, apoptotic hallmarks were identified and quantified using flow cytometry. We proved that immunogenic factors compromised plasma membrane integrity (RNA-seq). To sum up, the proposed adenoviral platform generated innate and adaptive immunity for the complex and robust regulatory system to prevent SARS-CoV-2 infections.

Project description:The preference of HIV to infect activated CD4 T cells has been proposed to contribute to a numerical reduction of antigen-specific T cells and the loss of T cell-mediated immunity. To date, our understanding of how HIV impact on vaccine-induced cellular immunity is limited. Moreover, the influence of chronic inflammation, that persist in treated HIV infection, is still unclear. Here, we investigated inflammation, immune activation and antigen-specific T cell responses in HIV-uninfected and cART-treated HIV people with prior measles virus and tetanus toxoid immunity. Our findings highlight lower antigen-induced T cell activation and lower cytokine production of antigen-specific CD4 T cells in the HIV group. These lower recall CD4 T cell responses associated with high plasma levels of multiple cytokines and with T cell hyperactivation. Transcriptome analysis of sorted antigen-specific CD4 T cells revealed that upon antigen reencounter, HIV people on cART had a reduced expression of gene sets previously reported to associate with vaccine-induced protective immunity against various pathogens. We further identified a consistent impairment of the IFN and IFN signaling pathways as a mechanism for the functional loss of antigen-specific CD4 T cell responses in cART-treated people with HIV. Together, our findings suggest that vaccine-induced cellular immunity may benefit from strategies to counteract inflammation in HIV infection.pecific

Project description:While memory T-cells (Tmem) represent a hallmark of adaptive immunity, and despite extensive characterization of CD8+ Tmem, little is known about regulation of CD4+ Tmem cell survival. In this study, we analyzed antigen-specific CD4+T cell memory populations in mice and human to characterize their unique genetic and surface phenotypes. First, using microarray technology, we studied dynamic gene expression of antigen specific CD4+ T cells during infection, memory differentiation, and survival up to nearly a year. In murine CD4+T cells, we observed reduced expression of genes that induce cell proliferation and increased expression of anti-apoptotic and pro-survival genes. Importantly, these genetic programs revealed multiple transmembrane markers enriched in the murine CD4+ Tmem population. We verified the ability of these markers to denote CD4+ Tmem populations using influenza vaccination, and observed enrichment of these surface markers in antigen-specific cells. Finally, we tested the ability of these markers to denote human memory CD4+ T cells. We found that their expression exclusively co-localized with existing human memory marker CD45R0, and that sorting of cells positive for these markers recovered more responding antigen-specific CD4+T cells than the general CD4+T cell population. In sum, this study presents unique gene signatures of long-lived murine CD4+ Tmem cells along with new surface markers some of which were validated in human. The new information can improve our assessment of CD4 memory T cells can be incorporated for novel therapeutics and vaccine design.

Project description:Tumour-infiltrating lymphocytes are a major predictor for overall survival and response to immunotherapy for several malignancies. However, while tumour-infiltrating CD8 T cells have been extensively studied, little is known about the role of the humoral immune system within the tumour microenvironment (TME). Here we show that plasma cells are present in the TME and actively secrete human papillomavirus (HPV)-specific IgG antibodies in HPV-positive head and neck squamous cell carcinoma patients. Compared to circulating memory B cells, plasma cells in the TME were enriched for HPV-reactivity with little bystander recruitment of influenza-specific cells. HPV-specific plasma cells in the TME correlated with the antibody titres in peripheral blood and produced antibodies with a high degree of somatic hypermutation directed against HPV E2, E6 and E7 antigens. A striking proportion of HPV-specific antibodies produced in situ were directed against E2, which might thus be a promising target for immunotherapies in HPV-associated cancers. Overall, we show that antigen-specific activated and germinal centre B cells as well as plasma cells can be found in the TME, with plasma cells producing antibodies specific for tumour-associated antigens in situ. These findings provide a better understanding of humoral immune responses in human cancer and suggest that tumour-infiltrating B cells could be harnessed for the development of novel therapeutic agents.

Project description:The transplacental transfer of maternal IgG to the developing fetus is critical for infant protection against infectious pathogens in the first year of life. However, factors that modulate the transplacental transfer efficiency of maternal IgG that could be harnessed for maternal vaccine design remain largely undefined. HIV-infected women have impaired placental IgG transfer, yet the mechanism underlying this impaired transfer is unknown, presenting an opportunity to explore factors that contribute to the efficiency of placental IgG transfer. We measured the transplacental transfer efficiency of maternal HIV and other pathogen-specific IgG in historical U.S. (n=120) and Malawian (n=47) cohorts of HIV-infected mothers and their HIV58 exposed uninfected and HIV-infected infants. We then examined the role of maternal HIV disease progression, infant factors, placental Fc receptor expression, and IgG Fc region subclass and glycan signatures and their association with transplacental transfer efficiency of maternal antigen-specific IgG. We established 3 distinct phenotypes of placental IgG transfer efficiency in HIV-infected women, including: 1) efficient transfer of the majority of antigen-specific IgG populations; 2) generally poor IgG transfer phenotype that was strongly associated with maternal CD4+ T cell counts, hypergammaglobulinemia, and frequently yielded non-protective levels of vaccine-specific IgG; and 3) variable transfer of IgG across distinct antigen specificities. Interestingly, maternal IgG characteristics, such as binding to placentally expressed Fc receptors FcgRIIa and FcgRIIIa, IgG subclass frequency, and Fc region glycan profiles were associated with placental IgG transfer efficiency. These maternal IgG transplacental transfer determinants were distinct among different antigen-specific IgG populations. Our findings suggest that in HIV-infected women, both maternal disease progression and Fc region characteristics modulate the selective placental transfer of distinct IgG subpopulations, with implications for both the health of HIV-exposed uninfected infants and maternal vaccine design.