Bladder cancer is one of the most common malignancies and has poor prognosis for patients with locally advanced, muscle-invasive, disease despite the efficacy of immune checkpoint blockade. To develop more effective immunotherapy strategies, we studied a genetic mouse model carrying deletion of Tp53 and Pten in the bladder, which recapitulates bladder cancer tumorigenesis and gene expression patterns found in patients. We discovered that tumor cells became more malignant and the tumor immune microenvironment evolved from an inflammatory to an immunosuppressive state. Accordingly, treatment with anti-PD1 was ineffective, but resistance to anti-PD1 therapy was overcome by combination with a CD40 agonist (anti-CD40), leading to strong antitumor immune responses. Mechanistically, this combination led to CD8+ T-cell recruitment from draining lymph nodes. CD8+ T cells induced an IFNγ-dependent repolarization toward M1-like/IFNβ-producing macrophages. CD8+ T cells, macrophages, IFN I, and IFN II were all necessary for tumor control, as demonstrated in vivo by the administration of blocking antibodies. Our results identify essential cross-talk between innate and adaptive immunity to control tumor development in a model representative of anti-PD1–resistant human bladder cancer and provide scientific rationale to target CD40 in combination with blocking antibodies, such as anti-PD1/PD-L1, for muscle-invasive bladder cancer.
Chemotherapeutic agents can induce accelerated senescence in tumor cells, an irreversible state of cell cycle arrest. Paclitaxel, a microtubule-stabilizing agent used to treat solid tumors of the breast, ovary, and lung and discodermolide, another stabilizing agent from a marine sponge, induce senescence in cultured cancer cells. The aim of this study was to determine if the microtubule-stabilizing agent peloruside A, a polyketide natural product from a marine sponge, can induce accelerated senescence in a breast cancer cell line MCF7. Doxorubicin, a DNA-damaging agent, paclitaxel, and discodermolide were used as positive controls. Senescence-associated-β-galactosidase activity was increased by peloruside A, similar to paclitaxel, discodermolde, and doxorubicin, with a potency heirarchy of doxorubicin > paclitaxel > discodermolide > peloruside, based on IC concentrations that inhibit proliferation. Clonogenic survival was significantly decreased by peloruside A, similar to doxorubicin and the two other microtubule-stabilizing agents. The tumor suppressor protein p53 increased after treatment, whereas pRb decreased in response to all four compounds. It was concluded that in addition to apoptosis, peloruside A causes accelerated senescence in a subpopulation of MCF7 cells that contributes to its potential anticancer activity in a breast cancer cell line.
It is known that for achieving high affinity antibody responses, vaccines must be optimized for antigen dose/density, and the prime/boost interval should be at least 4 weeks. Similar knowledge is lacking for generating high avidity T‐cell responses. The functional avidity (FA) of T cells, describing responsiveness to peptide, is associated with the quality of effector function and the protective capacity in vivo. Despite its importance, the FA is rarely determined in T‐cell vaccination studies. We addressed the question whether different time intervals for short‐term homologous vaccinations impact the FA of CD8 T‐cell responses. Four‐week instead of 2‐week intervals between priming and boosting with potent subunit vaccines in C57BL/6 mice did not improve FA. Equally, similar FA was observed after vaccination with virus‐like particles displaying low versus high antigen densities. Interestingly, FA was stable in vivo but not in vitro, depending on the antigen dose and the time interval since T‐cell activation, as observed in murine monoclonal T cells. Our findings suggest dynamic in vivo modulation for equal FA. We conclude that low antigen density vaccines or a minimal 4‐week prime/boost interval are not crucial for the T‐cell's FA, in contrast to antibody responses.
In the steady state, tumors harbor several populations of dendritic cells (DCs) and myeloid cells that are key regulators of the intratumoral immune environment. Among these cells, migratory CD103 cross-presenting DCs are thought to be critical for tumor-specific CTL responses and tumor resistance. However, it is unclear whether this prominent role also extends to immunotherapy. We used a murine orthotopic mammary tumor model, as well as Clec9A-diphtheria toxin receptor mice that can be depleted of the specialized cross-presenting CD8α and CD103 DC1 subsets, to investigate the role of these DCs in immunotherapy. Treatment with monosodium urate crystals and mycobacteria at the tumor site delayed tumor growth and required DC1s for efficacy. In contrast, treatment with poly I:C was equally effective regardless of DC1 depletion. Neither treatment affected myeloid-derived suppressor cell numbers in the spleen or tumor. Similar experiments using subcutaneous B16 melanoma tumors in BATF3-knockout mice confirmed that CD103 DCs were not necessary for successful poly I:C immunotherapy. Nevertheless, adaptive immune responses were essential for the response to poly I:C, because mice depleted of CD8 T cells or all DC subsets were unable to delay tumor growth. In vivo experiments showed that DC1 and DC2 subsets were able to take up tumor Ags, with DC2s making up the larger proportion of lymph node DCs carrying tumor material. Both DC subsets were able to cross-present OVA to OT-I T cells in vitro. Thus, immunotherapy with poly I:C enables multiple DC subsets to cross-present tumor Ag for effective antitumor immune responses.
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