In the case of cancer immunotherapy, nanostructures are attractive because they can carry all of the necessary components of a vaccine, including both antigen and adjuvant. Herein, we explore how spherical nucleic acids (SNAs), an emerging class of nanotherapeutic materials, can be used to deliver peptide antigens and nucleic acid adjuvants to raise immune responses that kill cancer cells, reduce (or eliminate) tumor growth, and extend life in three established mouse tumor models. Three SNA structures that are compositionally nearly identical but structurally different markedly vary in their abilities to cross-prime antigen-specific CD8+ T cells and raise subsequent antitumor immune responses. Importantly, the most effective structure is the one that exhibits synchronization of maximum antigen presentation and costimulatory marker expression. In the human papillomavirus-associated TC-1 model, vaccination with this structure improved overall survival, induced the complete elimination of tumors from 30% of the mice, and conferred curative protection from tumor rechallenges, consistent with immunological memory not otherwise achievable. The antitumor effect of SNA vaccination is dependent on the method of antigen incorporation within the SNA structure, underscoring the modularity of this class of nanostructures and the potential for the deliberate design of new vaccines, thereby defining a type of rational cancer vaccinology.
miR-155 is a regulator of immune cell development and function that is generally thought to be immunostimulatory. However, we report here that genetic ablation of miR-155 renders mice resistant to chemical carcinogenesis and the growth of several transplanted tumors, suggesting that miR-155 functions in immunosuppression and tumor promotion. Host miR-155 deficiency promoted overall antitumor immunity despite the finding of defective responses of miR-155-deficient dendritic cells and antitumor T cells. Further analysis of immune cell compartments revealed that miR-155 regulated the accumulation of functional myeloid-derived suppressive cells (MDSC) in the tumor microenvironment. Specifically, miR-155 mediated MDSC suppressor activity through at least two mechanisms, including SOCS1 repression and a reduced ability to license the generation of CD4+Foxp3+ regulatory T cells (Treg). Importantly, we demonstrated that miR-155 expression was required for MDSC to facilitate tumor growth. Thus, our results revealed a contextual function for miR-155 in antitumor immunity, with a role in MDSC support that appears to dominate in tumor-bearing hosts. Overall, the balance of these cellular effects appears to be a root determinant of whether miR-155 promotes or inhibits tumor growth.
The role of IL-33 particularly in tumor growth and tumor immunity remains ill defined. We show here that exogenous IL-33 can induce robust antitumor effect through a CD8+ T cell-dependent mechanism. Systemic administration of recombinant IL-33 (rIL-33) alone was sufficient to inhibit growth of established tumors in both transplant and de novo melanoma tumorigenesis models. Notably, in addition to a direct action on CD8+ T cell expansion and IFN-γ production, rIL-33 therapy activated myeloid dendritic cells (mDCs) in tumor-bearing mice, restored antitumor T cell activity and increased antigen cross-presentation within the tumor microenvironment. Furthermore, combination therapy with rIL-33 and agonistic anti-CD40 antibodies demonstrated synergistic antitumor activity. Specifically, MyD88, an essential component of the IL-33 signaling pathway, was required for the IL-33-mediated increase in mDC number and upregulation of costimulatory molecule expression. Importantly, we identified that the IL-33 receptor ST2, MyD88 and STAT1 cooperate to induce costimulatory molecule expression on mDCs in response to rIL-33. Our study has thus revealed a novel IL-33-ST2-MyD88-STAT1 axis that restores mDC activation and maturation in established cancer, and thereby the magnitude of anti-tumor immune responses, suggesting a potential use of rIL-33 as a new immunotherapy option to treat established cancer.
Although a number of studies have recently explored the contribution of the adaptive immunity in interleukin 33 (IL-33)-mediated antitumor effects, innate immune involvement has been poorly characterized. Utilizing Rag1−/− mice (lacking T and B lymphocytes), we show here that either systemic administration of recombinant IL-33 or ectopic expression of IL-33 in melanoma cells is sufficient to inhibit tumor growth independent of adaptive antitumor immunity. We have demonstrated that IL-33-mediated antitumor effects depend on expansion and activation of NK cells. Interestingly, IL-33 also promoted the expansion of active type 2 innate lymphoid cells (ILC2s) via its receptor, ST2, which in turn inhibited NK activation and cytotoxicity. This IL-33-induced ILC2 activity coincided with greater expression of the immunosuppressive ecto-enzyme CD73. Removal of CD73 from ILC2s in culture with NK cells resulted in markedly increased activation levels in NK cells, offering a potential mechanism by which ILC2s might suppress NK cell-mediated tumor killing. Thus, our data reveal an important contribution of IL-33-induced ILC2 to tumor growth by weakening NK cell activation and tumor killing, regardless of adaptive immunity.
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