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A Synthetic DNA, Multi-Neoantigen Vaccine Drives Predominately MHC Class I CD8+ T-cell Responses, Impacting Tumor Challenge.

ABSTRACT: T-cell recognition of cancer neoantigens is important for effective immune-checkpoint blockade therapy, and an increasing interest exists in developing personalized tumor neoantigen vaccines. Previous studies utilizing RNA and long-peptide neoantigen vaccines in preclinical and early-phase clinical studies have shown immune responses predominantly driven by MHC class II CD4+ T cells. Here, we report on a preclinical study utilizing a DNA vaccine platform to target tumor neoantigens. We showed that optimized strings of tumor neoantigens, when delivered by potent electroporation-mediated DNA delivery, were immunogenic and generated predominantly MHC class I-restricted, CD8+ T-cell responses. High MHC class I affinity was associated specifically with immunogenic CD8+ T-cell epitopes. These DNA neoantigen vaccines induced a therapeutic antitumor response in vivo, and neoantigen-specific T cells expanded from immunized mice directly killed tumor cells ex vivo These data illustrate a unique advantage of this DNA platform to drive CD8+ T-cell immunity for neoantigen immunotherapy.

SUBMITTER: Duperret EK 

PROVIDER: S-EPMC6622455 | biostudies-literature | 2019 Feb

REPOSITORIES: biostudies-literature

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A Synthetic DNA, Multi-Neoantigen Vaccine Drives Predominately MHC Class I CD8<sup>+</sup> T-cell Responses, Impacting Tumor Challenge.

Duperret Elizabeth K EK   Perales-Puchalt Alfredo A   Stoltz Regina R   G H Hiranjith H   Mandloi Nitin N   Barlow James J   Chaudhuri Amitabha A   Sardesai Niranjan Y NY   Weiner David B DB  

Cancer immunology research 20190124 2

T-cell recognition of cancer neoantigens is important for effective immune-checkpoint blockade therapy, and an increasing interest exists in developing personalized tumor neoantigen vaccines. Previous studies utilizing RNA and long-peptide neoantigen vaccines in preclinical and early-phase clinical studies have shown immune responses predominantly driven by MHC class II CD4<sup>+</sup> T cells. Here, we report on a preclinical study utilizing a DNA vaccine platform to target tumor neoantigens. W  ...[more]

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