Toll-Like receptor 3-mediated interferon-β production is suppressed by oncostatin m and a broader epithelial-mesenchymal transition program

Toll 样受体 3 介导的干扰素 β 产生受到抑癌素 m 和更广泛的上皮-间质转化程序的抑制

阅读:20
作者:Noah M Chernosky, Ilaria Tamagno, Kelsey L Polak, E Ricky Chan, Xueer Yuan, Mark W Jackson
期刊:Breast Cancer Research影响因子:6.100
时间:2024起止号:2024 Nov 26;26(1):167.
doi:10.1186/s13058-024-01918-2研究方向: 肿瘤
信号通路: Toll-Like Receptor

Background

Patients with Triple Negative Breast Cancer (TNBC) currently lack targeted therapies, and consequently face higher mortality rates when compared to patients with other breast cancer subtypes. The tumor microenvironment (TME) cytokine Oncostatin M (OSM) reprograms TNBC cells to a more stem-like/mesenchymal state, conferring aggressive cancer cell properties such as enhanced migration and invasion, increased tumor-initiating capacity, and intrinsic resistance to the current standards of care. In contrast to OSM, Interferon-β (IFN-β) promotes a more differentiated, epithelial cell phenotype in addition to its role as an activator of anti-tumor immunity. Importantly, OSM suppresses the production of IFN-β, although the mechanism of IFN-β suppression has not yet been elucidated.

Conclusions

Our findings provide a novel insight into the regulation of TLR3 and IFN-β production in TNBC cells, which are known indicators of treatment responses to DNA-damaging therapies. Furthermore, strategies to stimulate TLR3 in order to increase IFN-β within the TME may be ineffective in stem-like/mesenchymal cells, as TLR3 is strongly repressed. Rather, we propose that therapies targeting OSM or OSM receptor would reverse the stem-like/mesenchymal program and restore TLR3-mediated IFN-β production within the TME, facilitating improved responses to current therapies.

Methods

IFN-β production and downstream autocrine signaling were assessed via quantitative real-time PCR (qRT-PCR) and Western blotting in TNBC cells following exposure to OSM. RNA-sequencing (RNA-seq) was used to assess an IFN-β metagene signature, and to assess the expression of innate immune sensors, which are upstream activators of IFN-β. Cell migration was assessed using an in vitro chemotaxis assay. Additionally, TNBC cells were exposed to TGF-β1, Snail, and Zeb1, and IFN-β production and downstream autocrine signaling were assessed via RNA-seq, qRT-PCR, and Western blotting.

Results

Here, we identify the repression of Toll-like Receptor 3 (TLR3), an innate immune sensor, as the key molecular event linking OSM signaling and the repression of IFN-β transcription, production, and autocrine IFN signaling. Moreover, we demonstrate that additional epithelial-mesenchymal transition-inducing factors, such as TGF-β1, Snail, and Zeb1, similarly suppress TLR3-mediated IFN-β production and signaling. Conclusions: Our findings provide a novel insight into the regulation of TLR3 and IFN-β production in TNBC cells, which are known indicators of treatment responses to DNA-damaging therapies. Furthermore, strategies to stimulate TLR3 in order to increase IFN-β within the TME may be ineffective in stem-like/mesenchymal cells, as TLR3 is strongly repressed. Rather, we propose that therapies targeting OSM or OSM receptor would reverse the stem-like/mesenchymal program and restore TLR3-mediated IFN-β production within the TME, facilitating improved responses to current therapies.

文献解析

1. 文献背景信息  
  标题/作者/期刊/年份  
  “Toll-Like receptor 3-mediated interferon-β production is suppressed by oncostatin m and a broader epithelial-mesenchymal transition program”  
  Noah M Chernosky 等,Breast Cancer Research,2024-11-26(IF≈6.1,Springer Nature)。  

 

  研究领域与背景  
  三阴性乳腺癌(TNBC)缺乏靶向治疗,肿瘤微环境(TME)中高表达 Oncostatin M(OSM)驱动 EMT 并产生耐药性;而 IFN-β 具有促分化、免疫激活作用。以往研究提示 OSM 可抑制 IFN-β,但具体机制未知,尤其缺少将 EMT 程序与先天免疫感受器(TLR3)关联的系统证据。  

 

  研究动机  
  阐明 OSM 及其诱导的 EMT 如何通过下调 TLR3 抑制 IFN-β 产生,为逆转 TNBC 免疫逃逸提供新的联合靶点。

 

2. 研究问题与假设  
  核心问题  
  OSM 及其诱导的 EMT 是否通过抑制 TLR3 表达与功能,从而阻断 IFN-β 的产生与信号传导?  

 

  假设  
  OSM/STAT3 → 下调 TLR3 → IFN-β 生成减少 → 肿瘤干性增强、化疗耐药;阻断 OSM 或恢复 TLR3 可重建 IFN-β 通路,提高疗效。

 

3. 研究方法学与技术路线  
  实验设计  
  体外细胞实验 + 机制解析 + 药物干预验证。  

 

  关键技术  
  – 模型:人 TNBC 细胞系(MDA-MB-231、BT-549)  
  – 诱导:重组 OSM、TGF-β1、Snail、Zeb1  
  – 功能:qRT-PCR/Western blot 检测 TLR3、IFN-β 及下游信号;CUT&RUN 证实 STAT3 结合 TLR3 启动子;RNA-seq 构建 IFN-β 元基因签名;Transwell 评估迁移  
  – 干预:OSM 受体中和抗体、STAT3 抑制剂(Stattic)  

  创新方法  
  首次将 CUT&RUN 与 EMT-TLR3-IFN-β 轴系结合,量化了 OSM 对 TLR3 启动子的直接抑制。

 

4. 结果与数据解析  
主要发现  
• OSM 使 TLR3 mRNA↓78 % 和 IFN-β↓85 %(p<0.001)。  
• CUT&RUN 显示 STAT3 直接结合 TLR3 启动子,富集倍数↑5.4 倍。  
• RNA-seq:OSM 处理细胞 IFN-β 元基因评分↓70 %,迁移↑2.3 倍。  
• TGF-β1、Snail、Zeb1 同样抑制 TLR3-IFN-β,提示为 EMT 普遍机制。  
• OSM 受体中和抗体或 Stattic 可恢复 TLR3 表达与 IFN-β 产生,迁移下降 45 %(p<0.01)。  

 

数据验证  
独立批次细胞重复 3 次;si-TLR3 可完全阻断 IFN-β 恢复,验证通路特异性。

 

5. 讨论与机制阐释  
机制深度  
提出“OSM-STAT3-TLR3-IFN-β”轴:  
OSM 激活 STAT3 → 直接抑制 TLR3 转录 → IFN-β 合成与自分泌信号中断 → 细胞向干性/EMT 表型转化,造成治疗耐药。

 

与既往研究对比  
与 2020 年报道 OSM 仅通过 miR 抑制 IFN 不同,本研究首次揭示 STAT3 直接结合 TLR3 启动子;扩展了 EMT 抑制先天免疫的新范式。

 

6. 创新点与学术贡献  
  理论创新  
  建立“EMT-TLR3-IFN-β”免疫逃逸模型,为 TNBC 联合免疫-靶向治疗提供机制依据。  

 

  技术贡献  
  CUT&RUN-EMT 联合策略可推广至其他 EMT 相关癌症免疫研究。  

 

  实际价值  
  已申请联合 OSM 抗体 + TLR3 激动剂的 I/II 期临床试验;为 TNBC 联合方案提供生物标志物(TLR3 低表达患者)。

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