Gain of function mutant p53 in telomere uncapping-driven breast tumorigenesis

端粒脱帽驱动的乳腺肿瘤发生中功能突变体 p53 的获得

• 批准号: 8153821
• 负责人: YIBIN DENG
• 金额: $ 30.77万
• 依托单位: UNIVERSITY OF MINNESOTA
• 依托单位国家: 美国
• 财政年份: 2011
• 资助国家: 美国
• 起止时间: 2011-09-01 至 2015-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8153821
• 关键词: Accounting; Address; Advanced Development; Apoptosis; Apoptotic; Automobile Driving; Biological Models; Breast; Breast Cancer Model; Breast Cancer Treatment; Breast Carcinoma; Cancer Patient; Cell Death; Chemopreventive Agent; Chromosomal Instability; Chromosome abnormality; Chromosomes; Complex; DNA; DNA Damage; DNA Repair; DNA-Binding Proteins; Data; Defect; Development; Engineering; Epithelial; Epithelial Cells; Epithelium; Event; Experimental Models; Functional disorder; Genes; Genetic; Genetic Predisposition to Disease; Genome; Genomics; Goals; Hot Spot; Human; In Vitro; Incidence; Knockout Mice; Knowledge; Lymphoma; Malignant Neoplasms; Mammary Neoplasms; Mammary Tumorigenesis; Mammary gland; Mediating; Metastatic Carcinoma; Missense Mutation; Modeling; Molecular; Molecular Abnormality; Molecular Genetics; Molecular Target; Mus; Mutate; Mutation; Neoplasm Metastasis; Neoplastic Cell Transformation; Oncogenic; Pathway interactions; Pharmaceutical Preparations; Play; Polymerase; Prevention strategy; Protein p53; Research Personnel; Role; Series; Stretching; TFR2 gene; TP53 gene; Telomerase; Telomere Shortening; Testing; Therapeutic Effect; base; breast lesion; breast tumorigenesis; cancer genome; caspase-2; cell transformation; cohort; design; gain of function; human TERF2 protein; improved; in vivo; insight; malignant breast neoplasm; mouse model; mutant; new therapeutic target; novel; research study; response; sarcoma; sound; telomere; tool; tumor; tumor initiation; tumor progression; tumorigenesis

DESCRIPTION (provided by applicant): Human sporadic breast carcinomas are characterized by the presence of complex cytogenetic aberrations. This complexity represents one of the foremost challenges for breast cancer researchers developing the experimental model systems to identify the molecular genetic etiology of breast tumor development. Our long term goal is to establish "chromosomal instability" mouse breast cancer models that recapitulate the salient features of highly rearranged and mutated human breast cancer genomes and discover the "causal" genomic events involved in mammary carcinogenesis in vivo. One important mechanism that can give rise to the unstable genome in breast cancer is the dysfunction of telomeres, the physical termini of chromosomes that protect natural chromosomal ends from being recognized as damaged DNA and inhibit inappropriate DNA repair. On the other hand, recent systematic genomic analyses in human breast carcinomas have revealed that tumor suppressor p53 is the most commonly alerted gene, predominantly through missense mutations that result in accumulation of mutant p53 protein to acquire oncogenic gain-of-function. To faithfully resemble these two important features observed in human breast carcinomas, chromosomal instability and expression of gain- of-function mutant p53, we have been engineering a novel mouse breast cancer model bearing dysfunctional telomere-induced chromosomal instability and expression of "hot spot" gain-of-function mutant p53 in breast epithelium. Our preliminary results suggest that telomere uncapping causes dysfunctional telomeres that activate DNA Damage Response (DDR)-mediated apoptotic pathway to suppress chromosomal instability- driven tumorigenesis in the absence of p53, while "hot spot" mutant p53 inhibits telomere uncapping-induced cell death and promotes cell transformation. Furthermore, we observe that mutant p53 cooperates with dysfunctional telomeres in breast epithelium to promote tumor progression to invasive breast carcinomas in vivo. In this application, we will test our hypothesis that gain-of-function mutant p53 inhibits telomere uncapping-induced DDR-mediated apoptosis to enhance chromosomal instability-driven mammary carcinogenesis in vivo. The two specific aims are designed to test the hypothesis. In Aim 1, we will generate mouse models to test the possibility that gain-of-function mutant p53 cooperates with telomere uncapping- initiated chromosomal instability to promote mammary carcinogenesis in vivo. In Aim 2, we will investigate the molecular mechanism underlying gain-of-function mutant p53 promotes chromosomal instability-driven breast tumor development. We anticipate that our engineered chromosomal instability mouse models will faithfully recapitulate the complex cytogenetic aberrations of human breast cancer and help us identify novel molecular targets to improve strategies for the prevention and treatment of breast cancer. PUBLIC HEALTH RELEVANCE: The breast cancer mouse model systems generated by creating in vivo telomere dysfunction in the presence of telomerase and "hot spot" gain-of-function mutant p53 will faithfully represent the genetic alterations commonly observed in breast cancer patients. Knowledge obtained from the proposed studies will help us understand the pathogenetic events driving breast tumor development and metastasis, and potentially provide sound rational and novel therapeutic targets for breast cancer patients bearing chromosomal instability and mutant p53 that account for 20% to 30% of breast cancers.

描述（由申请人提供）：人类散发性乳腺癌的特征是存在复杂的细胞遗传畸变。这种复杂性代表了乳腺癌研究人员开发实验模型系统以确定乳腺肿瘤发展的分子遗传病因的首要挑战之一。我们的长期目标是建立“染色体不稳定性”小鼠乳腺癌模型，该模型概括了高度重排和突变的人类乳腺癌基因组的显著特征，并发现体内乳腺癌发生过程中涉及的“因果”基因组事件。导致乳腺癌基因组不稳定的一个重要机制是端粒功能障碍。端粒是染色体的物理末端，保护自然染色体末端不被识别为受损的DNA，并抑制不适当的DNA修复。另一方面，最近对人类乳腺癌的系统基因组分析表明，肿瘤抑制基因p53是最常见的警报基因，主要是通过错义突变导致突变p53蛋白积累以获得致癌功能获得。为了忠实地模拟在人类乳腺癌中观察到的这两个重要特征，染色体不稳定性和功能增益突变p53的表达，我们已经设计了一种新的小鼠乳腺癌模型，该模型具有端粒功能失调诱导的染色体不稳定性和乳腺上皮中“热点”功能增益突变p53的表达。我们的初步结果表明，端粒脱帽导致功能失调的端粒激活DNA损伤反应（DDR）介导的凋亡途径，以抑制染色体不稳定性驱动的肿瘤发生，而“热点”突变p53抑制端粒脱帽诱导的细胞死亡并促进细胞转化。此外，我们观察到p53突变体与乳腺上皮中功能失调的端粒合作，促进肿瘤在体内发展为浸润性乳腺癌。在本应用中，我们将验证我们的假设，即功能获得突变型p53抑制端粒脱帽诱导的ddr介导的细胞凋亡，从而增强染色体不稳定性驱动的体内乳腺癌发生。这两个具体目标的设计是为了验证这一假设。在Aim 1中，我们将建立小鼠模型来测试功能获得突变型p53与端粒脱帽引发的染色体不稳定性合作在体内促进乳腺癌发生的可能性。在Aim 2中，我们将研究功能获得突变体p53促进染色体不稳定性驱动的乳腺肿瘤发展的分子机制。我们期望我们的基因工程小鼠染色体不稳定性模型将忠实地再现人类乳腺癌复杂的细胞遗传学畸变，并帮助我们确定新的分子靶点，以改进乳腺癌的预防和治疗策略。