Remediation of the p53/Arf and Interferon-beta pathways as a cancer immunotherapy strategy: a gene transfer approach

Cancer cells thrive as a consequence of resisting cell death mechanisms and escaping from immune surveillance. We propose that, in cancers that harbor the wild-type tumor suppressor p53, remediation of both of these defenses can be achieved by harnessing the adenoviral vector mediated gene transfer of p19Arf (tumor suppressor protein, p53 functional partner) together with interferon-beta (IFNbeta, immunomodulatory cytokine). Indeed, in our initial observations, it was noticed that combined-transduction (p19Arf/IFNbeta), but not the individual treatments, of B16F10 mouse melanoma cells results in massive cell death levels. Yet, the capability of these dying cells to unleash antitumor immunity was not investigated. Here in this thesis and in complementary studies, we sought to investigate the molecular mechanisms of cell death involved in the p19Arf/IFNbeta immune stimulation and explore its potential as a mediator of cancer immunotherapy. First, in a prophylactic B16F10 vaccine model, we revealed that the dual treatment led to the up-regulation of IL-15, ULBP1, FAS/APO1 and KILLER/DR5 death receptors, plus a natural killer cell response that completely rejects treated cells when inoculated in syngeneic immunocompetent mice. Whereas, upon a contralateral tumor challenge, progression was strongly reduced by engaging both CD4+ and CD8+ T cells, which displayed augmented production of IFN-? and TNF-alpha cytokines and provided long term antitumor protection. Next, exploring different immunization context, in situ gene transfer in a heterotopic lung carcinoma exhibited significant protection against a secondary tumor challenge only when the primary tumor was treated with p19Arf/IFNbeta. Transcriptome analysis of these treated tumors indicated a chemotaxic signature of neutrophils and CD8+ T cells with the involvement of CCL3, CXCL3 chemokines and IL-1beta. Moreover, in support of this evidence, mechanistic in vitro studies revealed that p19Arf/IFNbeta treated cells reactivate p53 apoptotic and IFNbeta antiviral programs, while succumbing to a necroptosis cell death processes that also releases immunogenic cell death (ICD) molecules, calreticulin, ATP and HMGB1. Yet, aiming to potentiate therapeutic benefit of our vectors, we explored their association with doxorubicin (Dox) immunogenic chemotherapy, which is also an inducer of ICD. And in this setting, this association with Dox enhances not only cell death levels but also immunogenicity of treated cells, providing superior tumor control in a therapeutic vaccine model, where mice were already bearing B16F10 tumors or MCA205 sarcomas before vaccination. Moreover, associated use of these therapies in situ rescued efficacy of a sub-therapeutic dose of Dox, which in contrast to its therapeutic dose, does not impair cardiac function. Finally, we also evaluated the association with PD-1 or CTLA-4 checkpoint blockade immunotherapy, which in the therapeutic vaccine model induced full tumor rejection in a greater number of mice. In sum, here we provide compelling evidence for the ability of the p19Arf/IFNbeta combined gene transfer to promote cell death and immunogenic stimuli and underscored its potential to be applied as a cancer immunotherapy strategy (AU)