STING activation reprograms tumor vasculatures and synergizes with VEGFR2 blockade (original) (raw)
Endothelial STING expression correlates with intratumoral CD8+ T cell infiltration and favorable prognosis in human cancers. To explore the clinical relevance of endothelial STING expression in human malignancies, we assessed the STING expression pattern in tumor tissues from 173 breast and 160 colorectal cancer patients. We detected distinct STING expression in tumor endothelial cells and immune cells (Figure 1, A and B, and Supplemental Table 1; supplemental material available online with this article; https://doi.org/10.1172/JCI125413DS1). Intriguingly, CD8+ T cell infiltration was increased near STING-expressing tumor vessels and was significantly correlated with endothelial STING expression levels (Figure 1, C and D). Moreover, compared with those with low STING expression, patients with high endothelial STING expression had better overall survival after cancer diagnosis (Figure 1, E and F, and Supplemental Figure 1, A and B). High endothelial STING expression was also correlated with decreased prevalence of lymphovascular invasion within tumor tissues (Supplemental Table 2). This prognostic significance remained true even in multivariate Cox regression analysis using various clinical and molecular characteristics (Supplemental Table 3).
Endothelial STING expression correlates with intratumoral CD8+ T cell infiltration and favorable prognosis in human cancers. Clinical implications of endothelial STING expression (Endo STING) in breast cancer (n = 173) and colorectal cancer (n = 160). (A and B) Representative images of STING and CD8 expression in human breast cancer (A) and colorectal cancer (B). (C and D) Correlation between endothelial STING expression and intratumoral CD8+ cells in breast cancer (C) and colorectal cancer (D). R and P values by Pearson’s correlation test. (E and F) Kaplan-Meier survival curves of breast cancer patients (E) and colorectal cancer patients (F) using endothelial STING expression. P values by the log-rank test.
To gain deeper understanding of the role of endothelial STING in tumor growth, we utilized several mouse models. STING was expressed in CD31+ tumor endothelial as well as in hematopoietic cells, such as dendritic cells and macrophages (Supplemental Figure 2A); however, the level of STING expression in endothelial cells varied among different tumor models, with the CT26 colon cancer and Lewis lung carcinoma (LLC) models showing stronger endothelial STING expression compared with the MMTV-PyMT breast cancer model (Supplemental Figure 2, B and C). Intriguingly, consistent with the findings from human cancers, levels of endothelial STING expression were also significantly correlated with intratumoral CD8+ T cells in mouse tumor models (P = 0.001, R = 0.601) (Supplemental Figure 2D). Moreover, CT26, the tumor with modest STING expression and the most abundant intratumoral CD8+ T cells, showed the best response to treatment with STING agonists, while MMTV-PyMT, the tumor with the weakest STING expression, did not respond as well to treatment with a STING agonist alone (Supplemental Figure 2E). Therefore, the levels of baseline STING expression and intratumoral CD8+ T cells may be predictors of therapeutic response to STING agonist monotherapy. Collectively, these findings suggest that endothelial STING signaling is associated with the prognosis of cancer patients and may play an important role during CD8+ T cell–mediated anticancer immunity.
STING agonists promote CD8+ T cell responses and tumor vascular normalization. We next examined the temporal changes of tumor vasculatures and CD8+ T cells after intratumoral injection of STING agonist into LLC tumors (Figure 2, A and B). A single injection of RR-CDA (also called MIW815 or ADU-S100) led to dramatic changes in TME compared with that seen in PBS-injected control tumors. Whereas consistent angiogenesis was observed in control tumors, RR-CDA–treated tumors showed an abrupt decrease in CD31+ tumor vessels at 1 day after RR-CDA treatment, followed by a gradual recovery. In addition, control tumors showed a slow decline in NG2+ pericyte coverage and a gradual decrease in CD8+ T cells, while RR-CDA–treated tumors showed increased pericyte coverage and a dramatic influx of CD8+ T cells at 7 days after RR-CDA treatment. Of note, increased pericyte coverage, one of the hallmarks of tumor vessel normalization, coincided with the time of peak CD8+ T cell infiltration into the TME.
Intratumoral injection of STING agonist induces dramatic changes in TME. LLC tumor cells were implanted subcutaneously into mice and treated with intratumoral injections of PBS or STING agonists (S). (A) Serial images of LLC tumors after a single injection of PBS or STING agonist (RR-CDA, 25 μg). Arrowheads indicate disrupted tumor vessels. (B) Temporal changes in CD31+ blood vessels, NG2+ pericyte coverage, and CD8+ T cells after a single injection of PBS or STING agonist treatment. Pooled data from 2 independent experiments with n = 5 to 6 per group. Scale bars: 50 μm.
To further dissect the effects of intratumoral STING activation on TME, LLC tumor–bearing mice were treated with repeated injections of the STING agonists cGAMP or RR-CDA. After 3 consecutive intratumoral cGAMP injections, tumor growth was reduced by 46% compared with that in controls (Figure 3A). TME analyses revealed that cGAMP treatment led to a 6.4-fold increase in intratumoral CD8+ T cells, 40% reduction in CD31+ blood vessel density, a 1.7-fold increase in NG2+ pericyte coverage, and a 1.5-fold increase in COL4+ basement membrane coverage. Additionally, intratumoral hypoxia was alleviated by 46% in cGAMP-treated tumors compared with controls (Figure 3, B and C). Two injections of RR-CDA induced similar changes in the TME of LLC tumors: 41% delayed tumor growth, a 16.5-fold increase in intratumoral CD8+ T cells, a 51% decrease in CD31+ blood vascular density, a 4.4-fold increase in NG2+ pericyte coverage, and a 3.1-fold increase in COL4+ basement membrane coverage compared with controls. Moreover, glucose transporter 1 (GLUT1) levels were analyzed as hypoxia markers, as previously described (21, 27), revealing a 46% decrease in intratumoral hypoxia after RR-CDA injection compared with that in controls (Figure 3, D–F).
STING agonists promote CD8+ T cell responses and tumor vascular normalization. LLC tumor cells were implanted subcutaneously into mice and treated with intratumoral injections of PBS or STING agonists (S). Red arrows indicate treatment, and black arrows indicate sacrifice. (A) Comparison of LLC tumor growth in mice treated with PBS or STING agonist (cGAMP, 10 μg). (B and C) Representative images (B) and comparisons (C) of CD8+ T cells, CD31+ blood vessels, NG2+ pericyte coverage, COL4+ basement membrane (BM) coverage, and hypoxic area. (D) Comparison of LLC tumor growth in mice treated with PBS or STING agonist (RR-CDA, 25 μg). (E and F) Representative images (E) and comparisons (F) of CD8+ T cells, CD31+ blood vessels, NG2+ pericyte coverage, COL4+ basement membrane coverage, and GLUT1+ hypoxic area. Pooled data from 2 independent experiments with n = 8 to 9 per group. Values are shown as mean ± SD. *P < 0.05 versus PBS. Two-tailed Student’s t test. Scale bars: 50 μm.
In order to define the dose-ranging effect of STING agonist, we intratumorally injected 1 to 100 μg of RR-CDA into LLC tumors. RR-CDA effectively suppressed tumor growth even with a dose of 1 μg (Supplemental Figure 3, A and B), but its antiangiogenic and vascular normalizing effect was seen at a dose of 5 μg or more (Supplemental Figure 3, C and D). When the dose of intratumoral RR-CDA was increased up to 100 μg, all tumors had completely regressed. Overall, these findings indicate that STING activation can augment intratumoral CD8+ T cell infiltration, normalize tumor vessels, and alleviate hypoxia within the tumor.
STING signaling pathway regulates tumor vascular and immune microenvironment. To examine how STING signaling is involved in tumor vascular normalization, we investigated how STING agonist affected the TME in STING-deficient (STINGgt/gt, KO) and WT mice (Figure 4). In WT mice, intratumoral administration of cGAMP suppressed LLC tumor growth by 47%, reduced tumor vessel density by 48% and the number of vascular sprouts by 55%, and increased pericyte coverage by 1.7-fold. However, no changes in tumor growth or tumor vessels were observed in KO mice, indicating that the cGAMP-induced antiangiogenic effects were STING dependent. Moreover, in the absence of cGAMP treatment, tumors of KO mice showed 1.4-fold higher blood vessel density, 1.5-fold increased number of vascular sprouts, and 47% decreased pericyte coverage compared with tumors of WT mice (Figure 4, A–C). Collectively, these findings suggest that STING signaling acts as a suppressor of sprouting tumor angiogenesis and an inducer of tumor vessel maturation.
STING signaling pathway regulates tumor angiogenesis. LLC tumor cells were implanted subcutaneously into WT or STING-deficient mice (STINGgt/gt, KO) and treated with intratumoral injections of PBS or STING agonist (S). (A) Comparison of tumor growth in mice treated with PBS or STING agonist. Red arrows indicate treatment, and black arrow indicates sacrifice. (B and C) Representative images (B) and comparisons (C) of CD31+ blood vessels, tumor vessel sprouts, and NG2+ pericyte coverage. Pooled data from 2 experiments with n = 8 per group. Values are shown as mean ± SD. *P < 0.05 versus PBS. ANOVA with Tukey’s post hoc test (A and C). Scale bars: 50 μm.
To elucidate the transcriptional changes upon STING activation, we used the NanoString PanCancer panel to compare 750 immune microenvironment–related genes in cGAMP-treated tumors in WT mice and tumors in KO mice. The results revealed dramatic differences between the STING-activated and STING-deficient TMEs (Figure 5A). At first, intratumoral STING activation strongly induced both type I IFNs and type II IFNs within TME (Figure 5B). Next, vascular stabilizing genes (e.g., Cdh5, Angpt1, Pdgfrb, Mcam, and Col4a) were also increased after STING activation, but were decreased or unchanged in KO mice (Figure 5C). On the other hand, vascular destabilizing genes did not differ significantly between groups (Figure 5D). We also compared various adhesion molecules that are critical in endothelial-lymphocyte interactions and lymphocyte transmigration and found that STING activation significantly upregulated adhesion molecules, including Icam, Vcam, and Sell (Figure 5E). The full list of other gene changes is provided in Supplemental Table 4 and Supplemental Figure 3, E and F.
STING signaling pathway regulates tumor vascular and immune microenvironment. WT or STING-deficient mice (STINGgt/gt, KO) were injected with LLC tumor cells and treated with intratumoral injections of PBS or STING agonist. (A) Volcano plot showing gene-expression changes in STING agonist–treated tumors of WT mice (red) and PBS-treated tumors of STING-deficient mice (blue). (B–E) Comparison of gene expression related to type I/II IFNs (B), vascular stabilization (C), vascular destabilization (D), and endothelial cell (EC) and lymphocyte interaction (E). (F) Comparison of gene expression related to inhibitory and agonistic immune checkpoints in tumors treated with STING agonist. (G) Flow cytometric analyses of immune checkpoints in tumors. Pooled data from 2 experiments with n = 4 to 9 per group. Values are shown as mean ± SD. *P < 0.05 versus PBS. Two-tailed Student’s t test (B–G).
Since STING signaling is critical for myeloid cell activation (8), we also analyzed genes involved in macrophage polarization (Supplemental Figure 4, A and B). STING activation was associated with marked increases in genes specific for M1-like macrophages, while genes for M2-like macrophages were not significantly altered. This was confirmed by treating tumors with cGAMP or RR-CDA, and we found an increase in NOS2+ M1-like macrophages, while CD206+ M2-like macrophages were not significantly altered compared with control (Supplemental Figure 4, C–E). Consistently, flow cytometric analysis also revealed an accumulation of M1-like macrophages, but no changes in M2-like macrophages, yielding an increasing trend in the M1/M2 ratio (Supplemental Figure 4F). We then examined the role of macrophages after intratumoral STING agonist treatment by selectively depleting macrophages with clodronate liposome (Supplemental Figure 4G) (28). Intriguingly, the antitumor efficacy of RR-CDA did not change significantly even after macrophage depletion (Supplemental Figure 4, H and I). Therefore, although intratumoral STING agonist treatment stimulates the accumulation of M1-like macrophages within the TME, macrophages seem to be dispensable for the overall antitumor effect of STING agonists.
Finally, we found that intratumoral STING activation triggered an increase in inhibitory (e.g., Pd-1, Pd-l1, Ctla-4, Lag-3, and Tim-3) and agonistic (e.g., Icos, Ox40, Gitr, Hvem, and Cd27) immune checkpoint genes (Figure 5F). We also confirmed increases in PD-1+CD8+ T cells, CTLA-4+CD8+ T cells, TIM-3+CD8+ T cells, and PD-L1+CD45– cells in TME of STING-treated tumors (Figure 5G). Collectively, our findings indicate that activation of STING signaling negatively regulates tumor angiogenesis in the TME and upregulates genes involved in vascular normalization, endothelial-lymphocyte interaction, and immune checkpoints.
STING in nonhematopoietic cells is as important as STING in hematopoietic cells during therapy with exogenous STING agonist. Although the roles of STING signaling are mostly well delineated in hematopoietic immune cells, its role in nonhematopoietic stromal cells is not so well defined, even though these cells also express STING. To investigate the roles of hematopoietic-derived cells or nonhematopoietic stromal cells, such as endothelial cells, in the therapeutic efficacy of STING agonists, we generated chimeric mice by transferring WT or KO bone marrow into lethally irradiated WT or KO mice into which we subcutaneously implanted LLC tumor cells (Figure 6A). When the tumors were intratumorally treated with RR-CDA, tumor growths were significantly suppressed in WT → WT (bone marrow donor, WT; recipient, WT) mice and partially suppressed in KO → WT or WT → KO mice, but not suppressed in KO → KO mice (Figure 6, B and C), indicating that both hematopoietic and nonhematopoietic STING is important for the anticancer effects of STING agonist treatment. Intriguingly, KO → WT mice showed decreased tumor angiogenesis and increased pericyte coverage, with less intratumoral CD8+ T cells. On the other hand, WT → KO mice showed more intratumoral CD8+ T cells, with less pronounced suppression of tumor angiogenesis and decrease in pericyte coverage (Figure 6, D and E). Therefore, it seems that STING in nonhematopoietic cells is more important in the regulation of tumor vessels, whereas STING in hematopoietic cells is more important in determining the magnitude of anticancer immune response by CD8+ T cells within the tumor. Taken together, these results suggest that STING in nonhematopoietic cells is as important as STING in hematopoietic cells for inducing a maximal therapeutic efficacy of exogenous STING agonist treatment.
STING in nonhematopoietic cells is as important as STING in hematopoietic cells during therapy with exogenous STING agonist. LLC tumor cells were implanted subcutaneously into bone marrow chimeric mice and treated with intratumoral injections of STING agonist (RR-CDA, 25 μg). Red arrows indicate treatment, and black arrow indicates sacrifice. (A) Diagram depicting the generation of chimeric mice. (B and C) Comparison of LLC tumor growth in bone marrow chimeric mice. Mean (B) and individual (C) tumor growth curves over time. (D and E) Representative images (D) and comparisons (E) of CD8+ T cells, CD31+ blood vessels, and NG2+ pericyte coverage. Pooled data from 2 experiments with n = 6 to 10 per group. Values are shown as mean ± SD. *P < 0.05 versus WT → WT; #P < 0.05 versus KO → WT; §P < 0.05 versus WT → KO. ANOVA with Tukey’s post hoc test (B and E). Scale bars: 50 μm.
TME regulation by STING activation is dependent on type I IFN signaling and CD8+ T cells. To determine which immune system elements were responsible for STING-induced TME remodeling, we treated tumors with neutralizing antibodies against IFNAR or CD8. IFNAR depletion completely negated and CD8 depletion partially (~40%) abrogated the antitumor efficacy of STING agonist treatment (Figure 7, A and B, and Supplemental Figure 5, A and B). Notably, blockade of type I IFN signaling or depletion of CD8+ T cells also abrogated STING agonists’ antiangiogenic and vascular normalizing effects (Figure 7, C and D). This also nullified the STING-induced upregulation of genes involved in vascular normalization and endothelial-lymphocyte interaction (Figure 7, E–G) and countervailed the beneficial effects of STING agonist against intratumoral hypoxia (Supplemental Figure 5, C and D). Furthermore, depletion of either IFNAR or CD8 with a neutralizing antibody almost negated the upregulation of M1-specific genes (Supplemental Figure 5, E and F).
TME regulation by STING activation is dependent on type I IFN signaling and CD8+ T cells. Mice were subcutaneously implanted with LLC tumor cells and treated with STING agonist (S) and depleting antibodies for IFNAR (αIFNAR) or CD8+ T cells (αCD8). (A and B) Comparison of tumor growth in mice. Mean (A) and individual (B) tumor growth curves over time. Red arrows indicate injections of cGAMP (10 μg), blue arrows indicate injections of depleting antibodies, and black arrow indicates sacrifice. (C and D) Representative images (C) and comparisons (D) of CD8+ T cells, CD31+ blood vessels, NG2+ pericyte coverage, and COL4+ BM coverage. §P < 0.05 versus S + αIFNAR. (E–G) Comparison of gene expression involved in vascular stabilization (E), vascular destabilization (F), and endothelial-lymphocyte interaction (G). Pooled data from 2 experiments with n = 6 per group. Values are shown as mean ± SD. *P < 0.05 versus PBS; #P < 0.05 versus S. ANOVA with Tukey’s post hoc test (A and D–G). Scale bars: 50 μm.
These results indicate that type I IFN signaling and CD8+ T cells are indispensable for the STING-induced remodeling of tumor vasculatures. Since the impact of IFNAR depletion seems more powerful than that of CD8 depletion and the degree of vascular remodeling mediated by IFNAR and CD8 seems comparable, it seems that IFNAR signaling provides more widespread effects on the immune cells, probably through innate immune cells rather than CD8+ T cells.
STING agonist treatment combined with VEGFR2 blockade induces complete tumor regression and enhances vascular normalization in established tumors. Type I IFN signaling is negatively regulated by VEGF signaling (29). Thus, we questioned whether blocking VEGF signaling could further enhance STING-induced type I IFN activation and reinforce STING-induced vascular normalization and antitumor immunity. To explore this combinatorial potential, we examined the effects of VEGFR2 blockade with or without cGAMP treatment in LLC tumors. Treatment with cGAMP and the VEGFR2 antibody DC101 (25 mg/kg) led to 73% reduced tumor growth compared with control, which showed 45% or 61% reduced tumor growth compared with cGAMP or DC101 monotherapy, respectively (Figure 8, A and B). Combined treatment with cGAMP and DC101 also led to a 47% reduction in CD31+ blood vascular density and a 1.3-fold increase in NG2+ pericyte coverage compared with cGAMP monotherapy (Figure 8, C and D). Of note, combination treatment with RR-CDA (25 μg, twice) instead of cGAMP and DC101 induced complete tumor regression in all LLC tumor–bearing mice (Figure 8, E–G). Accordingly, the mice treated with both RR-CDA and DC101 did not die, while the control, DC101 monotherapy, and RR-CDA monotherapy groups had median survival rates of 26, 25, and 38 days, respectively (Figure 8H). These results were recapitulated in the CT26 colon cancer model, in which we observed comparable synergistic anticancer effects. Most of the CT26 tumors completely regressed after combination therapy of RR-CDA and DC101 (Supplemental Figure 6, A and B); these also exhibited similar tumor vessel normalization and increased CD8+ T cell infiltration (Supplemental Figure 6C).
STING agonist treatment combined with VEGFR2 blockade induces complete tumor regression and enhances vascular normalization in established tumors. Mice were subcutaneously implanted with LLC tumor cells and treated with STING agonist (S) and/or DC101 (V). Red arrows indicate injections of STING agonists, blue arrows indicate injections of DC101, and black arrow indicates sacrifice. (A and B) Comparison of LLC tumor growth in mice treated with cGAMP (10 μg) and/or DC101. Mean (A) and individual (B) tumor growth curves over time. The number of tumor-free mice is indicated for each group. (C and D) Representative images (C) and comparisons (D) of CD31+ blood vessels and NG2+ pericyte coverage. (E and F) Comparison of LLC tumor growth in mice treated with RR-CDA (25 μg) and/or DC101. Mean (E) and individual (F) tumor growth curves over time. The number of tumor-free mice is indicated for each group. (G) Waterfall plots showing the maximal percentage of changes of each tumor at the end of the experiment compared with baseline volume. (H) Kaplan-Meier survival curves for overall survival. *P < 0.05, log-rank test. Unless otherwise denoted, pooled data from 2 experiments with n = 6 to 8 per group. Values are shown as mean ± SD. *P < 0.05 versus PBS; #P < 0.05 versus S; §P < 0.05 versus V. ANOVA with Tukey’s post hoc test (A, D, and E). Scale bars: 50 μm.
To delineate the mediators of the response to combination therapy of STING agonists and DC101, we depleted either IFNAR, CD8+ T cells, or macrophages. Intriguingly, while neutralization of either IFNAR or CD8 almost completely negated the efficacy of RR-CDA and DC101 treatment and the tumor no longer showed complete regression, the antitumor effects of this combination therapy was maintained after the depletion of macrophages (Supplemental Figure 7, A and B).
Taken together, these data show that the combination of STING agonist and VEGFR2 blockade can induce complete tumor regression and durable anticancer immunity, with further enhancement of tumor vascular normalization. Moreover, the efficacy of dual combination therapy of STING agonist and VEGFR2 blockade largely depend on type I IFN signaling and CD8+ T cells, while macrophages are dispensable.
Triple combination immunotherapy of STING agonist, immune checkpoint inhibitor (αPD-1 or αCTLA-4), and anti-VEGFR2 antibody induces tumor regression. Although STING activation triggered potent antitumor T cell responses, it also led to a parallel induction of immune checkpoints in the TME, which would presumably generate a negative feedback loop (Figure 5, F and G). Since this could potentially restrain STING -induced anticancer immunity, we evaluated the effects of combining immune checkpoint inhibitors with STING agonist treatment and VEGFR2 blockade to maximize anticancer efficacy (Figure 9A). Since the previous dose of RR-CDA (25 μg, 3 times) already induced complete tumor regression in combination with DC101, its dose was decreased to 40 μg (20 μg, twice) for the following experiments. Although LLC tumors were completely resistant to immune checkpoint inhibitor (αPD-1 or αCTLA-4) monotherapy, combining RR-CDA with either αPD-1 (S + P) or αCTLA-4 (S + C) improved the antitumor effects compared with monotherapy, showing more than 35% complete response rates. Furthermore, when LLC tumors were treated with a triple combination immunotherapy with RR-CDA, αVEGFR2, and either αPD1 or αCTLA4 (S + V + P or S + V + C), more than half of tumor-bearing mice exhibited complete tumor regression (Figure 9, B and C) and consequently had improved overall survival (Figure 9D). Moreover, we found that the mice that experienced complete regression were immune to rechallenge with LLC tumor cells, but were vulnerable to MC38 tumor cells, suggesting the establishment of long-lasting tumor-specific immunological memory (Figure 9E). In summary, concurrent administration of immune checkpoint inhibitors can counteract STING-induced upregulation of immune checkpoints and potentiate the therapeutic efficacy of STING-targeted cancer immunotherapy, eventually leading to complete tumor regression and long-lasting immune memory against immunotherapy-resistant tumors.
Triple combination immunotherapy of STING agonist, immune checkpoint inhibitor (αPD-1 or αCTLA-4), and anti-VEGFR2 antibody induces tumor regression. Mice were subcutaneously implanted with LLC tumor cells and treated with STING agonist (S), DC101 (V), and αPD-1 (P) or αCTLA-4 (C). (A) Diagram depicting treatment schedule. (B) Comparison of LLC tumor growth in mice. The number of tumor-free mice is indicated for each group. PBS (black) or IgG (gray) was used as control. (C) Waterfall plots showing the maximal percentage changes of each tumor at the end of the experiment compared with baseline volume. (D) Kaplan-Meier survival curves for overall survival. (E) Comparison of tumor growth after injection of LLC or MC38 tumor cells into naive mice or mice with complete tumor regression. Pooled data from 2 experiments with n = 8 to 16 per group. Values are shown as mean ± SD. *P < 0.05, log-rank test (D). ANOVA with Tukey’s post hoc test (E).
Triple combination immunotherapy efficiently delays tumor growth and suppresses distant metastasis in a spontaneous breast cancer model. Because subcutaneously implanted tumor models have poor and immature vasculatures and lack appropriate tumor stroma, they may not fully represent the biology of a real tumor immune microenvironment. Therefore, we employed a spontaneous breast cancer model, MMTV-PyMT, which has more mature tumor vasculatures and abundant stromal cells and is therefore a reliable representative of human breast cancer (30, 31), to further validate the efficacy of STING activation in combination with VEGFR2 blockade and immune checkpoint inhibition (Figure 10A). After 3 weeks of treatment, RR-CDA alone remarkably delayed tumor growth, not just in the STING-injected tumor, but also in the noninjected tumors, suggesting abscopal antitumor effects upon STING activation; this was further strengthened by adding VEGFR2 blockade (S + V), and the triple combination therapy of RR-CDA, DC101, and anti-PD1 antibody (S + V + P) displayed the most potent tumor growth inhibition effect (Figure 10, B and C). Similarly to our previous observations, both dual and triple combination therapy led to a remarkable increase in intratumoral CD8+ T cell infiltration, a decrease in tumor vessel density, and enhanced pericyte coverage (Figure 10, D and E). Moreover, triple combination immunotherapy markedly reduced hematogenous lung metastases (Figure 11, A and B) and prolonged the overall survival of MMTV-PyMT mice (Figure 11C). Taken together, these results demonstrate that STING agonist treatment, combined with VEGFR2 and PD-1 inhibition, can effectively inhibit tumor progression and metastasis through vascular normalization and bolster anticancer immune response (Figure 11D).
Triple combination immunotherapy efficiently delays tumor growth in both injected and noninjected tumors of a spontaneous breast cancer model. Tumor growth was measured twice a week in a spontaneous breast tumor model, MMTV-PyMT mice, starting from 9 weeks after birth. Mice were treated with STING agonist (S), DC101 (V), and/or αPD-1 (P). (A) Diagram depicting the treatment schedule. Red arrows indicate treatment, and black arrow indicates sacrifice. (B) Representative images showing gross appearances of tumors. Dotted lines demarcate palpable tumor nodules. Asterisks indicate PBS or STING-injected lesion. Red arrows indicate lesions with complete tumor regression. (C) Comparison of the growth of STING-injected or noninjected tumors in MMTV-PyMT mice. (D and E) Representative images (D) and comparisons (E) of CD8+ T cells, CD31+ blood vessels, and NG2+ pericyte coverage. n = 5 to 7 per group. Values are shown as mean ± SD. *P < 0.05, ANOVA with Tukey’s post hoc test (E). Scale bars: 50 μm.
Triple combination immunotherapy suppresses lung metastases and provides survival benefit in a spontaneous breast cancer model. Tumor growth was measured twice a week in a spontaneous breast tumor model, MMTV-PyMT mice, starting from 9 weeks after birth. Mice were treated with STING agonist (S), DC101 (V), and/or αPD-1 (P). (A) Lung sections stained with H&E. Arrows indicate pulmonary metastatic lesions. Scale bars: 2 mm. n = 5 to 6 per group. (B) Comparison of the number of metastatic colonies per lung section. Values are shown as mean ± SD. *P < 0.05, ANOVA with Tukey’s post hoc test. (C) Kaplan-Meier survival curves for overall survival. n = 5 to 7 per group. Values are shown as mean ± SD. *P < 0.05 versus PBS; #P < 0.05 versus S; §P < 0.05 versus V; †P < 0.05 versus S + V, log-rank test. (D) Diagram depicting the mechanism by which STING activation reprograms TME and the rationale for STING-based combination immunotherapy.