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β-Catenin signaling in alveolar macrophages enhances lung metastasis through a TNF-dependent mechanism
Elliot D. Kramer, Stephanie L. Tzetzo, Sean H. Colligan, Mary L. Hensen, Craig M. Brackett, Björn E. Clausen, Makoto M. Taketo, Scott I. Abrams
Elliot D. Kramer, Stephanie L. Tzetzo, Sean H. Colligan, Mary L. Hensen, Craig M. Brackett, Björn E. Clausen, Makoto M. Taketo, Scott I. Abrams
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Research Article Oncology

β-Catenin signaling in alveolar macrophages enhances lung metastasis through a TNF-dependent mechanism

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Abstract

The main cause of malignancy-related mortality is metastasis. Although metastatic progression is driven by diverse tumor-intrinsic mechanisms, there is a growing appreciation for the contribution of tumor-extrinsic elements of the tumor microenvironment, especially macrophages, which correlate with poor clinical outcomes. Macrophages consist of bone marrow–derived and tissue-resident populations. In contrast to bone marrow–derived macrophages, the transcriptional pathways that govern the pro-metastatic activities of tissue-resident macrophages (TRMs) remain less clear. Alveolar macrophages (AMs) are a TRM population with critical roles in tissue homeostasis and metastasis. Wnt/β-catenin signaling is a hallmark of cancer and has been identified as a pathologic regulator of AMs in infection. We tested the hypothesis that β-catenin expression in AMs enhances metastasis in solid tumor models. Using a genetic β-catenin gain-of-function approach, we demonstrated that (a) enhanced β-catenin in AMs heightened lung metastasis; (b) β-catenin activity in AMs drove a dysregulated inflammatory program strongly associated with Tnf expression; and (c) localized TNF-α blockade abrogated this metastatic outcome. Last, β-catenin gene CTNNB1 and TNF expression levels were positively correlated in AMs of patients with lung cancer. Overall, our findings revealed a Wnt/β-catenin/TNF-α pro-metastatic axis in AMs with potential therapeutic implications against tumors refractory to the antineoplastic actions of TNF-α.

Authors

Elliot D. Kramer, Stephanie L. Tzetzo, Sean H. Colligan, Mary L. Hensen, Craig M. Brackett, Björn E. Clausen, Makoto M. Taketo, Scott I. Abrams

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Figure 6

Intranasal delivery of anti–TNF-α neutralizing antibody rescues the pro-metastatic effects of AM β-catenin activation, and TNF expression correlates with CTNNB1 in human AMs.

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Intranasal delivery of anti–TNF-α neutralizing antibody rescues the pro-...
(A) Schematic of intranasal anti–TNF-α treatments in Lyz2-Cre+/+ YFP+/– Ctnnb1Ex3Δ/wt or Lyz2-Cre+/+ YFP+/– hosts injected with E0771.ML-1 via tail vein 36 hours after treatment. (B) Relative abundance of CD45+Ly6G–CD24–CD64+CD11bloCD11c+ AMs of E0771.ML-1 tumor–bearing mice described in A. (C) Bioluminescence images, representative of 2 independent experiments and (D) quantification of data at endpoint represented. (E) Expression of CTNNB1 in human AMs from Travaglini et al. by scRNA-Seq (European Genome-phenome Archive [EGA], EGAS00001004344); n = 3. (F) Scatterplot of TNF and CTNNB1 expression from D; n = 3, pooled; positive Pearson correlation P = 0.0470. (B and D) The mean ± SEM values are shown and represent 4–5 individual mice. Statistical analysis is based on 1-way ANOVA with the Holm-Šídák correction applied for multiple comparisons (B and D); * = P < 0.05.

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