CD4+ T helper 2 cell–macrophage crosstalk induces IL-24–mediated breast cancer suppression
Bo Wang, Yun Xia, Can Zhou, Yuhan Zeng, Heehwa G. Son, Shadmehr Demehri
Bo Wang, Yun Xia, Can Zhou, Yuhan Zeng, Heehwa G. Son, Shadmehr Demehri
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Research Article Immunology Oncology

CD4+ T helper 2 cell–macrophage crosstalk induces IL-24–mediated breast cancer suppression

Abstract

CD4+ T cells contribute to antitumor immunity and are implicated in the efficacy of cancer immunotherapies. In particular, CD4+ T helper 2 (Th2) cells were recently found to block spontaneous breast carcinogenesis. However, the antitumor potential of Th2 cells in targeting established breast cancer remains uncertain. Herein, we demonstrate that Th2 cells induced by the topical calcipotriol/thymic stromal lymphopoietin cytokine axis suppressed the growth of established mammary tumors in mice. Interleukin-24 (IL-24), an anticancer cytokine, was highly upregulated in macrophages infiltrating calcipotriol-treated mammary tumors. Macrophages expressed IL-24 in response to IL-4 signaling in combination with Toll-like receptor 4 (TLR4) agonists (e.g., HMGB1) in vitro. Calcipotriol treatment significantly increased HMGB1 release by tumor cells in vivo. CD4+ T cell depletion reduced HMGB1 and IL-24 expression, reversing calcipotriol’s therapeutic efficacy. Macrophage depletion and TLR4 inhibition also reduced the therapeutic efficacy of calcipotriol. Importantly, calcipotriol treatment failed to control mammary tumors lacking the IL-24 receptor on tumor cells. Collectively, our findings reveal that Th2 cell–macrophage crosstalk leads to IL-24–mediated tumor cell death, highlighting a promising therapeutic strategy to tackle breast cancer.

Authors

Bo Wang, Yun Xia, Can Zhou, Yuhan Zeng, Heehwa G. Son, Shadmehr Demehri

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Figure 4

IL-24 is mainly expressed by TAMs in mammary tumors treated with calcipotriol.

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IL-24 is mainly expressed by TAMs in mammary tumors treated with calcipo...
(A) Representative IF images of IL-24–, F4/80-, Ly6G-, and CD3-stained mammary tumor in WT mice treated with topical calcipotriol. (B) Quantification of IL-24+ F4/80+ TAMs versus IL-24+ F4/80- cells in PyMt mammary tumors treated with calcipotriol. Each dot represents a high-power field (HPF) image. Five HPF images from 3 tumors are included in each group. (C) Representative images of HMGB1- and cytokeratin-stained (CK-stained) PyMt mammary tumor in WT mice treated with EtOH + IgG, calcipotriol + IgG, or calcipotriol + αCD4 Ab. (D) Distribution of HMGB1hi-expressing cells in CK and CK+ cells in PyMt mammary tumors of WT mice treated with EtOH + IgG (n = 6), calcipotriol + IgG (n = 7), or calcipotriol + αCD4 Ab (n = 7). (E) The serum HMGB1 levels in PyMt mammary tumor-bearing WT mice treated with EtOH + IgG (n = 5), calcipotriol + IgG (n = 9), or calcipotriol + αCD4 Ab (n = 5). (F) Schematic diagram outlining the experimental design used to test Il24 induction in BMDMs generated from WT mice stimulated with IL-4, HMGB1, and a TLR4 antagonist, RKH, alone or in combination. (G) Il24 mRNA levels 3 hours after exposure to the indicated stimulations (n = 4 in each group). (H and I) PyMt mammary tumor volume in WT animals treated by topical calcipotriol with PBS (control) versus RKH. 150 mg/kg RKH was injected intraperitoneally into mice twice a week, starting a day before tumor inoculation. Data are presented as (H) mean tumor volumes + SD and (I) spider plot (n = 10 in each group). Bar graphs show mean + SD, Mann-Whitney U test (B), 1-way ANOVA (E and G), Fisher’s exact test (D), and 2-way ANOVA (H and I). Scale bars: 100 μm (A and C).