靶向CXCR4通过阻断细胞周期进程消除对曲妥珠单抗的耐药性,并与多西紫杉醇协同治疗乳腺癌。

Shuying Liu, Shelly M Xie, Wenbin Liu, Mihai Gagea, Ariella B Hanker, Nguyen Nguyen, Akshara Singareeka Raghavendra, Gloria Yang-Kolodji, Fuliang Chu, Sattva S Neelapu, Adriano Marchese, Samir Hanash, Johann Zimmermann, Carlos L Arteaga, Debasish Tripathy
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引用次数: 2

摘要

背景:尽管曲妥珠单抗和其他HER2靶向治疗可显著提高HER2过表达或扩增(HER2+)乳腺癌患者的生存率,但仍有相当比例的患者无应答或最终出现临床耐药。逆转曲妥珠单抗耐药的策略仍然是临床的高度优先事项。我们首次报道了CXCR4在曲妥珠单抗耐药中的作用。本研究旨在探索靶向CXCR4的治疗潜力,并更好地了解其相关机制。方法:采用免疫荧光染色、共聚焦显微镜分析、免疫印迹法分析CXCR4的表达。采用BrdU掺入法和流式细胞术分析CXCR4的动态表达。采用三维共培养(肿瘤细胞/乳腺癌相关成纤维细胞/人外周血单个核细胞)或抗体依赖性细胞毒性实验模拟人肿瘤微环境,这是检测CXCR4抑制剂或曲妥珠单抗治疗效果所必需的。使用fda批准的CXCR4拮抗剂AMD3100、曲妥珠单抗和多西他赛化疗来评估体外和体内的治疗效果。采用反相蛋白阵列和免疫印迹技术分析相关分子机制。结果:通过一组细胞系和患者乳腺癌样本,我们证实了CXCR4在HER2+乳腺癌中驱动曲妥珠单抗耐药,并进一步证明了曲妥珠单抗耐药细胞中CXCR4表达的增加与细胞周期进展相关,并在G2/M期达到峰值。AMD3100阻断CXCR4通过下调G2-M转换介质抑制细胞增殖,导致G2/M停滞和有丝分裂异常。通过一组曲妥珠单抗耐药细胞系和体内建立的曲妥珠单抗耐药异种移植小鼠模型,我们证明了AMD3100靶向CXCR4在体外和体内抑制肿瘤生长,并与多西他赛协同作用。结论:我们的研究结果支持CXCR4作为HER2+乳腺癌曲妥珠单抗耐药的新治疗靶点和预测性生物标志物。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Targeting CXCR4 abrogates resistance to trastuzumab by blocking cell cycle progression and synergizes with docetaxel in breast cancer treatment.

Targeting CXCR4 abrogates resistance to trastuzumab by blocking cell cycle progression and synergizes with docetaxel in breast cancer treatment.

Targeting CXCR4 abrogates resistance to trastuzumab by blocking cell cycle progression and synergizes with docetaxel in breast cancer treatment.

Targeting CXCR4 abrogates resistance to trastuzumab by blocking cell cycle progression and synergizes with docetaxel in breast cancer treatment.

Background: Although trastuzumab and other HER2-targeted therapies have significantly improved survival in patients with HER2 overexpressed or amplified (HER2+) breast cancer, a significant proportion of patients do not respond or eventually develop clinical resistance. Strategies to reverse trastuzumab resistance remain a high clinical priority. We were the first to report the role of CXCR4 in trastuzumab resistance. The present study aims to explore the therapeutic potential of targeting CXCR4 and better understand the associated mechanisms.

Methods: Immunofluorescent staining, confocal microscopy analysis, and immunoblotting were used to analyze CXCR4 expression. BrdU incorporation assays and flow cytometry were used to analyze dynamic CXCR4 expression. Three-dimensional co-culture (tumor cells/breast cancer-associated fibroblasts/human peripheral blood mononuclear cells) or antibody-dependent cellular cytotoxicity assay was used to mimic human tumor microenvironment, which is necessary for testing therapeutic effects of CXCR4 inhibitor or trastuzumab. The FDA-approved CXCR4 antagonist AMD3100, trastuzumab, and docetaxel chemotherapy were used to evaluate therapeutic efficacy in vitro and in vivo. Reverse phase protein array and immunoblotting were used to discern the associated molecular mechanisms.

Results: Using a panel of cell lines and patient breast cancer samples, we confirmed CXCR4 drives trastuzumab resistance in HER2+ breast cancer and further demonstrated the increased CXCR4 expression in trastuzumab-resistant cells is associated with cell cycle progression with a peak in the G2/M phases. Blocking CXCR4 with AMD3100 inhibits cell proliferation by downregulating mediators of G2-M transition, leading to G2/M arrest and abnormal mitosis. Using a panel of trastuzumab-resistant cell lines and an in vivo established trastuzumab-resistant xenograft mouse model, we demonstrated that targeting CXCR4 with AMD3100 suppresses tumor growth in vitro and in vivo, and synergizes with docetaxel.

Conclusions: Our findings support CXCR4 as a novel therapeutic target and a predictive biomarker for trastuzumab resistance in HER2+ breast cancer.

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