Vaccines, drugs, and modified human cells that activate the immune system against tumor can improve the outcomes and prolong the lives of patients diagnosed with some type of cancers, but have failed to provide survival benefits for patients with glioblastoma (GBM). Activation of the Stimulator of Interferon Genes (STING) pathway represents one of the main innate immune sensing pathway to enable natural killer (NK) and T cell priming against tumor. Intratumoral administration of STING agonists, in particular cyclic dinucleotides (CDNs), was shown to have significant anti-tumor effects in multiple cancer models, including orthotopic GBM models, and is currently being tested in a phase 1 clinical trial in advanced cancer patients (NCT0267754339). Limited bioavailability and stability, however, are limiting factors for clinical CDN development. We have shown that the formulation of oligonucleotides into SNA structures, i.e., the presentation of oligonucleotides at high density on the surface of nanoparticles, leads to biochemical and biological properties that are radically different from those of linear (“free”) oligonucleotides. These include the cellular uptake of SNAs by a wide variety of cells, the gene regulatory activity of SNAs functionalized with siRNA or antisense DNA oligonucleotides, and the TLR-agonistic activity of SNAs conjugated with immunostimulatory oligonucleotides. Importantly, clinical trials with first generation siRNA-based SNAs (NCT03020017; GBM), and toll-like receptor 9 (TLR9)-agonsitic SNAs (NCT03086278; solid cancers) have recently been completed. Our proposed research is to develop a first-in-class immunotherapy by targeting cGAS – the sensor of cytosolic dsDNA upstream of STING – with SNAs presenting interferon-stimulating DNA (ISD) oligonucleotides at high surface density, and to evaluate the potential of SNAcGAS for use in clinical neuro-oncology. This approach is distinct from other current approaches that target the STING pathway with CDNs and small molecules. By targeting cGAS, the strategy of using SNAsISD exploits the ability of cGAS to raise STING responses by delivering dsDNA and inducing the catalytic production of endogenous CDNs. Our use of SNAs addresses the challenges of delivery of therapeutic nucleic acids through the enhanced uptake of nucleic acids formulated as SNAs, and furthermore, exploits the polyvalent presentation of oligonucleotides at high density on a nanoparticle template. Here, the binding of closely-spaced, neighboring dsDNA molecules on the surfaces of SNAs should enhance the formation of 2:2 dimers of cGAS:DNA and thus lead to potent cGAS activation. In three Specific Aims, we will optimize the SNA platform for maximum cGAS-STING pathway activation in vitro and in vivo (Aim 1), assess anti-tumor effect of our lead SNAcGAS architectures together with additional high-activity SNA constructs in vivo (Aim 2), and evaluate treatment regimens combining SNAcGAS with prioritized immunotherapies,...