Division of Oncology, Department of Clinical Sciences Lund, Lund University, Lund, Sweden.
Department of Cancer and Inflammation Research, Institute of Molecular Medicine, University of Southern Denmark, Odense, Denmark.
Breast Cancer Res. 2021 Feb 18;23(1):26. doi: 10.1186/s13058-021-01402-1.
Resistance to endocrine treatment in metastatic breast cancer is a major clinical challenge. Clinical tools to predict both drug resistance and possible treatment combination approaches to overcome it are lacking. This unmet need is mainly due to the heterogeneity underlying both the mechanisms involved in resistance development and breast cancer itself.
To study the complexity of the mechanisms involved in the resistance to the selective estrogen receptor degrader (SERD) fulvestrant, we performed comprehensive biomarker analyses using several in vitro models that recapitulate the heterogeneity of developed resistance. We further corroborated our findings in tissue samples from patients treated with fulvestrant.
We found that different in vitro models of fulvestrant resistance show variable stability in their phenotypes, which corresponded with distinct genomic alterations. Notably, the studied models presented adaptation at different cell cycle nodes to facilitate progression through the cell cycle and responded differently to CDK inhibitors. Cyclin E2 overexpression was identified as a biomarker of a persistent fulvestrant-resistant phenotype. Comparison of pre- and post-treatment paired tumor biopsies from patients treated with fulvestrant revealed an upregulation of cyclin E2 upon development of resistance. Moreover, overexpression of this cyclin was found to be a prognostic factor determining resistance to fulvestrant and shorter progression-free survival.
These data highlight the complexity of estrogen receptor positive breast cancer and suggest that the development of diverse resistance mechanisms dictate levels of ER independence and potentially cross-resistance to CDK inhibitors.
转移性乳腺癌对内分泌治疗的耐药性是一个主要的临床挑战。目前缺乏预测耐药性和可能的治疗联合方法的临床工具来克服这一挑战。这种未满足的需求主要是由于耐药性发展和乳腺癌本身所涉及的机制的异质性。
为了研究参与选择性雌激素受体降解剂(SERD)氟维司群耐药的机制的复杂性,我们使用几种体外模型进行了全面的生物标志物分析,这些模型再现了耐药性发展的异质性。我们进一步在接受氟维司群治疗的患者的组织样本中验证了我们的发现。
我们发现,氟维司群耐药的不同体外模型表现出不同的表型稳定性,这与不同的基因组改变相对应。值得注意的是,所研究的模型在不同的细胞周期节点适应,以促进细胞周期的进展,并对 CDK 抑制剂有不同的反应。细胞周期蛋白 E2 的过表达被确定为持久氟维司群耐药表型的生物标志物。对接受氟维司群治疗的患者的治疗前和治疗后配对肿瘤活检进行比较,发现耐药性发展时细胞周期蛋白 E2 的表达上调。此外,发现这种细胞周期蛋白的过表达是决定氟维司群耐药和无进展生存期较短的预后因素。
这些数据突出了雌激素受体阳性乳腺癌的复杂性,并表明不同耐药机制的发展决定了 ER 独立性的水平,并可能对 CDK 抑制剂产生交叉耐药性。
