Mitsutake Norisato, Knauf Jeffrey A, Mitsutake Shin, Mesa Cleo, Zhang Lei, Fagin James A
Division of Endocrinology and Metabolism, University of Cincinnati College of Medicine, Cincinnati, OH 45267-0547, USA.
Cancer Res. 2005 Mar 15;65(6):2465-73. doi: 10.1158/0008-5472.CAN-04-3314.
The activating mutation BRAF(T1796A) is the most prevalent genetic alteration in papillary thyroid carcinomas (PTC). It is associated with advanced PTCs, suggesting that this oncoprotein confers thyroid cancers with more aggressive properties. BRAF(T1796A) is also observed in thyroid micropapillary carcinomas and may thus be an early event in tumor development. To explore its biological consequences, we established doxycycline-inducible BRAF(V600E)-expressing clonal lines derived from well-differentiated rat thyroid PCCL3 cells. Expression of BRAF(V600E) did not induce growth in the absence of thyrotropin despite increasing DNA synthesis, which is likely explained because of a concomitant increase in apoptosis. Thyrotropin-dependent cell growth and DNA synthesis were reduced by BRAF(V600E) because of decreased thyrotropin responsiveness associated with inhibition of thyrotropin receptor gene expression. These results are similar to those obtained following conditional expression of RET/PTC. However, in contrast to RET/PTC, BRAF activation did not impair key activation steps distal to the thyrotropin receptor, such as forskolin-induced adenylyl cyclase activity or cyclic AMP-induced DNA synthesis. We reported previously that acute RET/PTC expression in PCCL3 cells did not induce genomic instability. By contrast, induction of BRAF(V600E) expression increased the frequency of micronuclei by both clastogenic and aneugenic events. These data indicate that BRAF(V600E) expression confers thyroid cells with little growth advantage because of concomitant activation of DNA synthesis and apoptosis. However, in contrast to RET/PTC, BRAF(V600E) may facilitate the acquisition of secondary genetic events through induction of genomic instability, which may account for its aggressive properties.
激活突变BRAF(T1796A)是甲状腺乳头状癌(PTC)中最常见的基因改变。它与晚期PTC相关,提示这种癌蛋白赋予甲状腺癌更具侵袭性的特性。BRAF(T1796A)也见于甲状腺微小乳头状癌,因此可能是肿瘤发生的早期事件。为探究其生物学后果,我们建立了源自分化良好的大鼠甲状腺PCCL3细胞的强力霉素诱导型BRAF(V600E)表达克隆系。尽管DNA合成增加,但在无促甲状腺激素的情况下,BRAF(V600E)的表达并未诱导生长,这可能是由于凋亡同时增加所致。由于与促甲状腺激素受体基因表达受抑制相关的促甲状腺激素反应性降低,BRAF(V600E)使促甲状腺激素依赖性细胞生长和DNA合成减少。这些结果与条件性表达RET/PTC后获得的结果相似。然而,与RET/PTC不同,BRAF激活并未损害促甲状腺激素受体远端的关键激活步骤,如福斯高林诱导的腺苷酸环化酶活性或环磷酸腺苷诱导的DNA合成。我们先前报道,PCCL3细胞中急性RET/PTC表达不会诱导基因组不稳定。相比之下,BRAF(V600E)表达的诱导通过致断裂和非整倍体事件增加了微核频率。这些数据表明,BRAF(V600E)表达因DNA合成和凋亡同时激活而赋予甲状腺细胞的生长优势很小。然而,与RET/PTC不同,BRAF(V600E)可能通过诱导基因组不稳定促进继发性遗传事件的发生,这可能解释了其侵袭性特性。
