Project Details
Development of new multiepitope DNA vaccines for active immunotherapy against neuroblastoma combined with immune checkpoint blockade
Applicant
Dr. Nikolai Siebert
Subject Area
Pediatric and Adolescent Medicine
Hematology, Oncology
Immunology
Hematology, Oncology
Immunology
Term
since 2022
Project identifier
Deutsche Forschungsgemeinschaft (DFG) - Project number 501758171
Neuroblastoma (NB) is a still challenging cancer of childhood with poor prognosis. Recently, GD2-directed immunotherapies improved survival of high-risk NB patients by 15%. As with most passive immunotherapies, such a strategy does not induce a long-lasting immune response and repeated Ab applications are necessary. This obstacle can be avoided by DNA vaccination.In the present project, we aim to generate a new mutiepitope DNA vaccine against NB. We previously successfully generated a bicistronic IL-15-based DNA vaccine against the tumor-associated antigen (TAA) tyrosine hydroxylase (TH) overexpressed in NB. Evaluation of this vaccine in our syngeneic mouse model clearly showed increased antitumor efficacy by IL-15 compared to the IL-15-free control TH vaccine. Our expertise and new knowledge in the field of DNA vaccination will be used for the generation of a more effective new generation multiepitope DNA vaccine against NB. To increase immunogenicity, further NB-specific TAAs (ALK, MYCN, survivin) will be integrated into the vaccine additionally to TH. This allows antitumor effects even after loss of some TAAs by tumor cells. To induce long-lasting effects, additional activation of T helper cells stimulating antigen presenting cells (APCs) and thereby activating tumor-specific cytotoxic T cells (CTLs) will be performed. For that, DNA sequences encoding universal T helper cell epitopes will be integrated into the vaccine. Furthermore, for effective loading of TAA- and T helper epitopes onto MHC-I and –II molecules, respectively, both lysosomal and proteasomal antigen presentation pathways will be induced by the DNA vaccine-dependent synthesis of the mutated ubiquitin with increased stability (polyubiquitination). An additional stimulation of APCs will be achieved by the vaccine-mediated synthesis of IL-15. After generation and characterization, antitumor efficacy of the new DNA vaccine will be evaluated in our preclinical NB model. For that, a new non-viral liposome-based nanoparticle vaccination strategy will be utilized. To overcome a tumor-mediated inhibition of immune response, an additional blockade of two immune checkpoints (PD-L1 + TIGIT) that have been shown to play an important role in cancer will be performed.In summary, we aim to generate a new generation cytokine-based DNA vaccine against different NB-specific TAAs that will be tested in combination with immune checkpoint blockade for induction of a long-lasting immune response against NB.
DFG Programme
Research Grants