Redirection of anti-virus immunity towards anti-tumor immunity using nanoparticle-induced immune tolerance for oncolytic adenovirus therapy

ABSTRACT

Recent clinical observations that some coronavirus infections induced complete remissions in lymphoma patients emphasized again the potential of cancer virotherapy. Infection of cancer cells with oncolytic viruses reshapes the tumor microenvironment by activating anti-viral and anti-tumor immunity. A phase 1 clinical trial using oncolytic adenovirus Delta-24-RGD (DNX-2401) to treat recurrent malignant gliomas demonstrated activation of CD8+ T-cells and significant clinical benefits for a subset of patients. However, both anti-virus and anti-tumor immune responses are contingent on the activation of respective clones of CD8+ T-cells, which compete for clonal expansion. Thus, overexpansion of T-cells against viral antigens reduces the frequency of subdominant clones against tumor antigens. We hypothesized that inducing immune tolerance for viral antigens will decrease anti-viral immunity and in turn derepress anti-tumor immunity, resulting in enhanced efficacy of cancer virotherapy. In this work, we used nanoparticles encapsulating adenoviral antigens E1A, E1B and hexon that distributed to liver resident macrophages (P<0.0001) and induced peripheral immune tolerance. Functional experiments to restimulate immune cells with viral or tumor antigens showed that injection of nanoparticles induced virus-specific immune tolerance and redirected the focus of the immune response towards tumor peptides as measured by interferon-gamma secretion (P<0.0001). Co-culture experiments also showed increased activation of immune cells against fixed tumor cells after nanoparticle treatment (P<0.0001). Reduction of virus-specific T-cells and concurrent expansion of tumor-specific T-cell clones were further confirmed with E1A or OVA tetramers (P<0.05). Flow cytometry analysis suggested increased anti-tumor responses were due to differences in T-cell clones and not due to other immune populations including natural killer cells or myeloid-derived suppressor cells (P=0.3). Importantly, virotherapy in combination with nanoparticle-induced immune tolerance towards viral antigens in tumor-bearing mice increased the overall survival and doubled the percentage of long-term survivors compared to virus treatment alone. Our data should propel the development of a future clinical trial aiming to maximize the potential of anti-tumor immunity during cancer virotherapies.