用于测试腺样囊性癌治疗药物的 MYB 激活模型。
MYB-activated models for testing therapeutic agents in adenoid cystic carcinoma.
机构信息
Department Medicine, University of Florida, Gainesville, FL 32608, USA.
Department Genetics, UT MD Anderson Cancer Center, Houston, TX 77030, USA.
出版信息
Oral Oncol. 2019 Nov;98:147-155. doi: 10.1016/j.oraloncology.2019.09.005. Epub 2019 Oct 10.
OBJECTIVE
There are no effective systemic therapies for adenoid cystic cancer (ACC) and lack of tumor lines and mouse models have hindered drug development.We aim to develop MYB-activated models for testing new therapeutic agents.
MATERIALS AND METHODS
We studied new ACC patient-derived xenograft (PDX) models and generated a matched cell line from one patient. In addition, we generated a genetically-engineered MYB-NFIB mouse model (GEMM) that was crossed with Ink4a/Arf mice to study tumor spectrum and obtain tumor lines. Using human and murine ACC-like tumor lines, we analyzed MYB expression by RNA-Seq and immunoblot and tested efficacy of new MYB inhibitors.
RESULTS
We detected MYB-NFIB transcripts in both UFH1 and UFH2 PDX and observed tumor inhibition by MYB depletion using shRNA in vivo. We observed rapid loss of MYB expression when we cultured UFH1 in vitro, but were able to generate a UFH2 tumor cell line that retained MYB expression for 6 months. RNA-Seq expression detected an ACC-like mRNA signature in PDX samples and we confirmed an identical KMT2A/MLL variant in UFH2 PDX, matched cell line, and primary biopsy. Although the predominant phenotype of the MYB-NFIB GEMM was B-cell leukemia, we also generated a MYB-activated ACC-like mammary tumor cell line. We observed tumor inhibition using a novel MYB peptidomimetic in both human and murine tumor models.
CONCLUSIONS
We generated and studied new murine and human MYB-activated tumor samples and detected growth inhibition with MYB peptidomimetics. These data provide tools to define treatment strategies for patients with advanced MYB-activated ACC.
目的
目前尚无有效的系统性疗法用于腺样囊性癌(ACC),并且缺乏肿瘤系和小鼠模型,这阻碍了药物的开发。我们旨在建立 MYB 激活模型以测试新的治疗剂。
材料和方法
我们研究了新的 ACC 患者来源的异种移植(PDX)模型,并从一位患者中生成了匹配的细胞系。此外,我们生成了一种基因工程的 MYB-NFIB 小鼠模型(GEMM),该模型与 Ink4a/Arf 小鼠杂交以研究肿瘤谱并获得肿瘤系。使用人源和鼠源 ACC 样肿瘤系,我们通过 RNA-Seq 和免疫印迹分析了 MYB 表达,并测试了新型 MYB 抑制剂的疗效。
结果
我们在 UFH1 和 UFH2 PDX 中均检测到 MYB-NFIB 转录本,并观察到体内使用 shRNA 耗竭 MYB 可抑制肿瘤。当我们在体外培养 UFH1 时,我们观察到 MYB 表达迅速丧失,但我们能够生成一种保留 MYB 表达长达 6 个月的 UFH2 肿瘤细胞系。RNA-Seq 表达在 PDX 样本中检测到 ACC 样 mRNA 特征,并且我们在 UFH2 PDX、匹配的细胞系和原发活检中证实了相同的 KMT2A/MLL 变体。尽管 MYB-NFIB GEMM 的主要表型是 B 细胞白血病,但我们还生成了一种 MYB 激活的 ACC 样乳腺肿瘤细胞系。我们在人源和鼠源肿瘤模型中均观察到使用新型 MYB 肽模拟物的肿瘤抑制作用。
结论
我们生成并研究了新的鼠源和人源 MYB 激活肿瘤样本,并检测到 MYB 肽模拟物的生长抑制作用。这些数据为患有晚期 MYB 激活 ACC 的患者提供了治疗策略的工具。
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