Department of Urology, NYU Cancer Institute, New York University School of Medicine, New York, NY 10016, USA.
Carcinogenesis. 2012 Apr;33(4):770-80. doi: 10.1093/carcin/bgs025. Epub 2012 Jan 27.
Although formation of urothelial carcinoma of the bladder (UCB) requires multiple steps and proceeds along divergent pathways, the underlying genetic and molecular determinants for each step and pathway remain undefined. By developing transgenic mice expressing single or combinatorial genetic alterations in urothelium, we demonstrated here that overcoming oncogene-induced compensatory tumor barriers was critical for urothelial tumor initiation. Constitutively active Ha-ras (Ras*) elicited urothelial hyperplasia that was persistent and did not progress to tumors over a 10 months period. This resistance to tumorigenesis coincided with increased expression of p53 and all pRb family proteins. Expression of a Simian virus 40 T antigen (SV40T), which disables p53 and pRb family proteins, in urothelial cells expressing Ras* triggered early-onset, rapidly-growing and high-grade papillary UCB that strongly resembled the human counterpart (pTaG3). Urothelial cells expressing both Ras* and SV40T had defective G(1)/S checkpoint, elevated Ras-GTPase and hyperactivated AKT-mTOR signaling. Inhibition of the AKT-mTOR pathway with rapamycin significantly reduced the size of high-grade papillary UCB but hyperactivated mitogen-activated protein kinase (MAPK). Inhibition of AKT-mTOR, MAPK and STAT3 altogether resulted in much greater tumor reduction and longer survival than did inhibition of AKT-mTOR pathway alone. Our studies provide the first experimental evidence delineating the combinatorial genetic events required for initiating high-grade papillary UCB, a poorly defined and highly challenging clinical entity. Furthermore, they suggest that targeted therapy using a single agent such as rapamycin may not be highly effective in controlling high-grade UCB and that combination therapy employing inhibitors against multiple targets are more likely to achieve desirable therapeutic outcomes.
尽管膀胱尿路上皮癌(UCB)的形成需要多个步骤,并沿着不同的途径进行,但每个步骤和途径的潜在遗传和分子决定因素仍未确定。通过开发在尿路上皮中表达单一或组合遗传改变的转基因小鼠,我们在这里证明了克服致癌基因诱导的代偿性肿瘤障碍对于尿路上皮肿瘤的起始至关重要。组成型激活的 Ha-ras(Ras*)引发了持续的尿路上皮增生,并且在 10 个月的时间内不会进展为肿瘤。这种对肿瘤发生的抵抗力与 p53 和所有 pRb 家族蛋白的表达增加相一致。在表达 Ras的尿路上皮细胞中表达猿猴病毒 40 型 T 抗原(SV40T),该抗原使 p53 和 pRb 家族蛋白失活,会引发早期、快速生长和高级别乳头状 UCB 的发生,其强烈类似于人类对应物(pTaG3)。同时表达 Ras和 SV40T 的尿路上皮细胞具有有缺陷的 G1/S 检查点、升高的 Ras-GTPase 和过度激活的 AKT-mTOR 信号。用雷帕霉素抑制 AKT-mTOR 通路可显著减少高级别乳头状 UCB 的大小,但过度激活丝裂原激活的蛋白激酶(MAPK)。与单独抑制 AKT-mTOR 通路相比,同时抑制 AKT-mTOR、MAPK 和 STAT3 可导致更大的肿瘤减少和更长的生存时间。我们的研究提供了第一个实验证据,阐明了起始高级别乳头状 UCB 所需的组合遗传事件,这是一种定义不明确且极具挑战性的临床实体。此外,它们表明,使用单一药物(如雷帕霉素)的靶向治疗可能无法高度有效地控制高级别 UCB,并且使用针对多个靶点的抑制剂联合治疗更有可能实现理想的治疗效果。