Overcome the challenge for intratumoral injection of STING agonist for pancreatic cancer by systemic administration

Abstract

Due to the challenge for intratumoral administration, innate agonists have not made it beyond preclinical studies for efficacy testing in most tumor types. Pancreatic ductal adenocarcinoma (PDAC) has a hostile tumor microenvironment that renders T cells dysfunctional. Innate agonist treatments may serve as a T cell priming mechanism to sensitize PDACs to anti-PD-1 antibody (a-PD-1) treatment. Using a transplant mouse model with spontaneously formed liver metastasis, a genetically engineered KPC mouse model that spontaneously develops PDAC, and a human patient-derived xenograft model, we compared the antitumor efficacy between intrahepatic/intratumoral and intramuscular systemic administration of BMS-986301, a next-generation STING agonist. Flow cytometry, Nanostring, and cytokine assays were used to evaluate local and systemic immune responses. This study demonstrated that administration of STING agonist systemically via intramuscular injection is equivalent to its intratumoral injection in inducing both effector T cell response and antitumor efficacy. Compared to intratumoral administration, T cell exhaustion and immunosuppressive signals induced by systemic administration were attenuated. Nonetheless, either intratumoral or systemic treatment of STING agonist was associated with increased expression of CTLA-4 on tumor-infiltrating T cells. However, the combination of a-PD-1 and anti-CTLA-4 antibody with systemic STING agonist demonstrated the antitumor efficacy in the KPC mouse spontaneous PDAC model. The mouse pancreatic and liver orthotopic model of human patient-derived xenograft reconstituted with PBMC also showed that antitumor and abscopal effects of both intratumoral and intramuscular STING agonist are equivalent. Taken together, this study supports the clinical development of innate agonists via systemic administration for treating PDAC.

Keywords: Immune checkpoint inhibitor; Immunotherapy; Pancreatic ductal adenocarcinoma; Stimulator of interferon genes; Tumor microenvironment.

Fig. 1

Intramuscular injection of STING agonist in combination with anti-PD-1 antibody prolonged the survival of liver metastasis mice and induces both systemic and intratumoral immune response. Preclinical PDAC metastatic model using Kras/p53/pdx1-Cre (KPC) cells was established in syngeneic C57Bl/6 mice. On day 0, 7.5 × 10⁵ KPC cells were injected by the hemisplenetomy procedure to establish the liver metastatic lesions (Figure S1A). On day 7, 5 × 10⁵ KPC cells were subcutaneously injected into the bilateral flanks of the postoperative mice to establish the SubQ tumors. Mice meeting the prespecified inclusion criteria were randomly assigned to the vehicle and treatment groups: (1) containing at least one target liver metastatic lesion between 3–5 mm in diameter as measured by ultrasonography because target lesions with such a size are easily separated from other metastases and are also larger enough to be feasible for intratumoral (IT) injection; (2) absence of peritoneal implants; (3) presence of palpable bilateral SubQ tumors. STING agonist (BMS986301) was administered intramuscularly (IM) at 5 mg/kg once weekly for three doses, starting on day 14. Anti-PD-1 antibody (BMS936558) was given intraperitoneally twice weekly at 10 mg/kg for five doses, starting on day 14 (Figure S1C). Tumor volumes were measured by ultrasound and tumor growth inhibition (TGI) was calculated using the formula %TGI=(1–[Tt/T0/Ct/C0]/1–[C0/Ct]) ×100, with a TGI > 50% considered significant. (A) Kaplan-Meier’s survival curves compare the survival in different IM treatment groups. Systemic administration did not show any obvious toxicity including bleeding, unhealed wound, paralysis, weight loss, etc. All the mice following the hemisplenectomy procedure were candidates for IM injection although only those feasible for IT injection were chosen for the purpose of experimental comparison. Mice in the IM-Combo group had a significantly prolonged survival when compared to other treatment groups. (B) TGI on distant SubQ tumors. The dashed line at -50% indicates statistically significant inhibition. The TGI rate for SubQ tumors also exhibited a significant increase in the IM-Combo group (maximum TGI = 58.86 ± 49.12%, p < 0.05). Although this study did not demonstrate a significant difference in the treatment response between IM and IT injections of STING agonist, mice who received IM injections of STING agonist in combination with anti-PD-1 antibody survived longer than 6 weeks were observed, whereas none of the mice who received IT injection of STING agonist in combination with anti-PD-1 antibody survived longer than 6 weeks (Figure S8A). Therefore, it might be possible to see the survival benefit of the IM injection of STING agonist if the sample size would potentially be larger; however, the sample size in each experiment was limited by the technical difficulty of IT injection. (C) Comparison of serum concentrations of TNF-α and IFN-γ collected 6 h after the first IM injection between treatment groups. The results demonstrated that several cytokines especially those associated with inflammation had a significantly increased level in the sera of mice from the IM-Combo treatment group, including TNF-α and IFN-γ. (D) Comparison of serum concentrations of CXCL9, CXCL10, IL-2, and IL-12 collected 6 h after the first IM injection between treatment groups. Interestingly, several T lymphocytes trafficking chemokines including CXCL9 and CXCL10, and type I cytokines including IL-2 and IL-12 were significantly increased in the sera from mice in the combo treatment group compared to other treatment groups, suggesting that IM injection of STING agonist in combination with anti-PD-1 antibody is potentially able to induce an anti-tumor systemic immune response. Percentages of the CD8⁺, CD8⁺PD-1⁺, CD4⁺, and CD4⁺PD-1⁺ T cells among CD45⁺ leucocytes in the pre-selected, target single liver metastatic lesions (E) and non-target liver metastases (F) are presented. The single target liver lesion was pre-selected as it would be selected for the IT treatment, but without any IT treatment to be given. IM injection of STING agonist alone significantly enhanced the infiltration of CD8⁺ and CD4⁺ T cells in both the pre-selected liver metastatic lesion and other liver metastases. The enhancement of the T cell infiltration was not as high in the IM-Combo group as the IM STING agonist monotherapy group. Percentages of the MHCII⁺CD11c⁺DC and CD11b⁻CD103⁺ subtype among CD45⁺ leucocytes, respectively, in the pre-selected single liver metastatic lesion (G) and non-target liver metastases (H) are presented. CD103⁺DCs showed a similar profile in the tumors with the IM injection of STING agonist compared to those shown above with the IT injection of STING agonist (Figure S2B and S2D), suggesting that systemic IM injection of STING agonist is able to activate the desired antigen-presenting process in the liver metastases. Taken together, these results suggest that IM injection of STING agonist is able to induce similar systemic immune responses as the IT injection of STING agonist. Systemic IM injection of STING agonist is also able to activate the desired antigen-presenting process in the liver metastases. Although the effector T cell responses appear to be slightly weaker in the IM injection of STING agonist, the increase in the T cell exhaustion and immune checkpoint signals and myeloid cell-recruiting cytokine/chemokine signals that were observed with the IT-Combo treatment (Figure S4D-E) were not observed in the IM-combo group. NC, vehicle/isotype antibody control; STING A, STING agonist; a-PD-1 Ab, anti-PD-1 antibody; IM, intramuscular. Data shown as mean ± SD; comparison by Log-rank test for A and by unpaired t test for others; *p < 0.05; **p < 0.01; ***p < 0.001; ****p < 0.0001

Fig. 2

STING agonist exert antitumor efficacy in both the KPC mouse model and the PDX mouse model. (A) Treatment schema for genetically engineered KPC mouse model that develops invasive PDAC spontaneously in a manner resembling human PDAC pathogenesis. KPC mice were subjected to weekly to twice weekly ultrasonic screening starting at 3 months of age and enrolled in the experiment randomly once either the length, width, or height of the pancreatic tumor reached 2 mm to ensure that eligible mice had equivalent tumor burdens. As CTLA-4 remains one of the immunosuppressive signals present in tumors treated by the IM STING agonist, the anti-CTLA-4 antibody was included in the immune checkpoint inhibitor regimen. (B) Kaplan-Meier survival curves compare overall survival between different treatment groups in the KPC mouse model. Eligible KPC mice were randomized into the three treatment groups to receive a total of seven injections. Treatment toxicity and mouse survival were monitored for 3 months following the first treatment. No treatment related toxicity including local toxicity related to IM injection sites was observed. The STING agonist monotherapy did not show any antitumor activity in a later experiment (manuscript in preparation). Dual checkpoint inhibitors failed to improve the overall survival of KPC mice when compared with control group; however, the co-administration of IM STING agonist with dual checkpoint inhibitors significantly prolonged the survival of the KPC mice. As it would be a challenge to breed a large number of the KPC transgenic mice for being randomized to multiple treatment groups, the combination of anti-PD-1 antibody and anti-CTLA-4 antibody instead of two immune checkpoint inhibitors by itself was tested. Future studies comparing the combination of anti-PD-1 antibody and anti-CTLA-4 antibody with either anti-PD-1 antibody alone or anti-CTLA-4 antibody alone are warranted. (C) Schema for the treatment of STING agonist or DPBS control and the reconstitution of ex vivo activated T cells and freshly thawed PBMCs, as indicated, in mice implanted with human PDX. In this PDX model, one piece of tumor was orthotopically implanted in the pancreas of the immunodeficient NOD scid gamma (NSG) mice, then a second piece of the tumor was implanted orthotopically in the liver of the same mice to simulate liver metastasis for IT injection. (D) Ultrasound measurement of tumor volumes of the orthotopic liver- and pancreas-implanted tumors treated with STING agonist or DPBS control via IT or IM, as indicated. NSG mice were reconstituted weekly with an ex vivo activated T cell fraction from peripheral blood mononuclear cells (PBMCs) as well as a whole fraction of PBMCs to provide myeloid cells including dendritic cells as described previously for the anti-human PD-1 antibody study and innate agonists on the PDX models, respectively. The implanted primary pancreatic tumors were evaluated for antitumor abscopal effects of IT injection of STING agonist. Tumor volumes in the pancreas and liver were monitored using small-animal ultrasound. The results demonstrated a significant growth suppression on both tumors in pancreas and liver regardless of the routes of administration of STING agonist. (E) Kaplan-Meier survival curves of mice with the orthotopic liver- and pancreas-implanted tumors treated with STING agonist or DPBS control via IT or IM, as indicated. IT injection of STING agonist significantly inhibited the growth of implanted tumors in the pancreas, supporting the antitumor abscopal effect of IT injection of STING agonist. These results demonstrated a significant and profound antitumor activity with either IT or IM injection of STING agonist alone in the human PDX model reconstituted with ex vivo activated T cells and the whole PBMC to provide myeloid cells including DCs. It is possible that reconstituted T cells and DCs in the PDX model were in a larger quantity than those infiltrating the tumors in the genetically engineered KPC model or the syngeneic model; therefore, STING agonist became more effective in the PDX model. (F) Schema for the treatments of STING agonist alone or in combination with a-PD-1 Ab and the reconstitution of ex vivo activated T cells and freshly thawed PBMCs, as indicated, in mice implanted with human PDX. Considering the potent tumor suppression observed after three doses of STING agonist in NSG mice with reconstituted immune systems, the doses of STING agonist and PBMCs were reduced in subsequent experiments. The modified experimental design involved a single infusion of STING agonist and freshly thawed PBMCs while ex vivo activated T cells were still infused three times, each together with each administration of anti-PD-1 antibody. Here, freshly thawed PBMC was only infused once because the effect of STING agonist would be carried over if PBMC continued to be infused for multiple times. (G) Ultrasound measurement of tumor volumes of the orthotopic liver- and pancreas-implanted tumors treated with STING agonist alone via IT or IM, as indicated, or in combination with a-PD-1 Ab. Results indicated that a single injection of STING agonist with freshly thawed PBMC infused once in combination with three weekly treatments of anti-PD-1 antibody together with three weekly infusions of ex vivo activated T cells led to a significant tumor suppression after Day 18, when compared to a single injection of STING agonist. NC, vehicle/isotype antibody control; STING A, STING agonist; a-PD-1 Ab, anti-PD-1 antibody; a-CTLA-4 Ab, anti-CTLA-4 antibody; PBMC, peripheral blood mononuclear cell; PDX, patient-derived xenograft; IT, intratumoral; IM, intramuscular; IP, intra-peritoneal. Data shown as mean ± SD; comparison by two-way ANOVA and Log-rank test; *p < 0.05; **p < 0.01; ***p < 0.001; ****p < 0.0001; NS, not significant