Soft tissue sarcomas (STS) are rare, aggressive malignancies derived from connective tissues such as muscle and fat. Undifferentiated pleomorphic sarcoma (UPS) is one of the most common STS in adults. UPS is an aggressive, highly metastatic sarcoma, and is resistant to chemotherapy. New therapies for UPS are desperately needed. STS have an immune desert tumour immune microenvironment (TIME), characterized by a paucity of tumour infiltrating lymphocytes and subsequent resistance to immunotherapies such as immune checkpoint inhibitors. Strategies capable of creating an immune-rich, inflamed TIME may improve immunotherapy efficacies for sarcoma. Activation of the STING (stimulator of interferon genes) receptor can induce potent innate and adaptive immune responses within immunogenic solid tumours. However, this approach has never been attempted in immune-inert sarcomas.

Purpose: To determine the therapeutic anti-tumour effects of STING activation in UPS tumours.

We have developed an inducible, immune-competent mouse model of UPS. We evaluated intra-tumoural injection of the murine STING receptor agonist, DMXAA, into UPS-bearing immune-competent mice. DMXAA was injected into palpable UPS tumours of the hindlimb. Tumour volume and bioluminescence imaging was recorded bi-weekly. DMXAA treated UPS tumours were also evaluated for necrosis and immune infiltration at defined time points.

UPS tumours developed necrosis and lymphocytic infiltration 72 hours after DMXAA treatment. A single intra-tumoural dose of DMXAA into UPS tumours resulted in durable cure in 50% of mice. All survivors rejected a re-challenge of the UPS tumours in both the contralateral hindlimb and lung, suggesting adaptive immunity. The therapeutic effects of DMXAA were mitigated in lymphocyte deficient Rag2 knockout mice.

STING therapy is a promising immunotherapeutic opportunity for immune-inert sarcomas. Our data warrants further preclinical investigations in other sarcoma models and in combination with other immune-based therapies.

Soft tissue sarcomas (STS) have not demonstrated favourable clinical responses to emerging immunotherapies such as checkpoint inhibitors. Studies in carcinomas and melanoma have demonstrated that tumours lacking T-cell infiltrates are associated with poor responses to immunotherapies. It is postulated that STS lack tumour asscoiated lymphocytes which renders these tumours insensitive to checkpoint inhibitors. Our objective was to develop a novel syngeneic mouse model of STS and characterize the immune phenotype of these tumours. Additionally, we sought to evaluate the therapeutic responses of these sarcomas to checkpoint inhibitors and a Type I interferon agonist.

K-ras mutagenesis and p53 deletion was induced using a Lenti-Cre-recombinase injection into the hindlimb of 3 week old C57BL/6 mice. Tumours were harvested and characterized using standard histopathology techniques and whole trascriptome sequencing (RNAseq). Full body necrospy and histopathology was performed to identify metastases. Flow cytometry and immunohistochemistry was used to evaluate tumour immune phenotypes. Tumours were implanted into syngeneic C57BL/6 mice and the therapeutic responses to anti-CTLA4, anti-PD1 and DMXAA (Type I interferon agonist) were performed. Tumour responses were evaluated using bioluminescent imaging and caliper measurements.

Soft tissue sarcomas developed in mice within 2–3 months of Lenti-Cre injection with 90% penetrance. Histologic analyses of tumours was consistent with a high-grade myogenic sarcoma characterized by smooth muscle actin, Desmin and Myogenin D positive immunostaining. Using crossplatform normalization protocols, geneexpression signatures of the mouse tumours most closely correlated with human undifferentiated pleomorphic sarcoma (UPS). Collectively, gene expression signatures of this murine sarcoma correlated with all muscle-derived human sarcomas (ERMS, ARMS, Synovial sarcoma, UPS). No lung or other visceral metastases were observed in all mice who developed spontaneous tumours. Immune phenotyping demonstrated a paucity of tumour-infiltrating lymphocytes (TILs, (TAMs). 50% of identified TILs in these murine sarcomas expressed PD-1, yet tumours were not responsive to anti-PD1 therapy or anti-CTLA4 therapy. A single intra tumoural (i.t.) injection of the Type I interferon agonist, DMXAA resulted in 80–90% tumour necrosis 72 hrs post-injection, decreased tumour viability up to 2 weeks post-injection and a marked infiltration of CD8+ T-cells and anitgen presenting dendritic cells and macrophages. Additional longitudinal experiments demonstrate a sustained and progressive anti-tumour effect in 83% (5/6) mice up to 6weeks following a single i.t. injection of DMXAA. All control treated mice (6/6) reached humane endpoint within 14 days. At 3 months post-DMXAA treatment, 4/6 mice were free of disease. We re-injected UPS tumours into these mice and tumours did not grow, suggesting abscopal effects after DMXAA treatment of primary tumours.

We have characterized a new orthotopic and syngeneic mouse model of a myogenic soft tissue sarcoma. Like most human STS sub-types, these tumours have an immune inert tumour microenvironment and are not sensitive to checkpoint inhibitors. This model, syngeneic to C56BL/6 mice will enable future opportunities to investigate how various branches of the immune system can be targetted or manipulated to unearth new immunotherapeutic strategies for sarcoma. Using this model we have demonstrated that a single, intra-tumoural injection of a Type I interferon agonist can result in anti-tumour effects, recruit cytotoxic lymphocytes and antigen presenting cells with into the the tumour microenvironment. Abscopal tumour rejection after DMXAA treatement suggest adaptive T-cell responses against UPS are active in this model. Future work is needed to determine if upregulation of Type I inferferon pathways can be used as a therapeutic strategy for sarcoma or as a sensitization strategy for checkpoint inhibitors.