Understanding the role of SKP2 in small cell lung cancer progression

了解 SKP2 在小细胞肺癌进展中的作用

• 批准号: 8537740
• 负责人: Brandon Nicolay
• 金额: $ 5.22万
• 依托单位: MASSACHUSETTS GENERAL HOSPITAL
• 依托单位国家: 美国
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-09-01 至 2015-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8537740
• 关键词: Affect; Apoptosis; Biological Assay; Bypass; Cancer Center; Cancer cell line; Cell Death; Cell Survival; Cells; Cellular Stress; Complement; Data; Development; Diagnosis; Gene Expression; Genome; Genomics; Housing; Human; Lead; Malignant Neoplasms; Molecular; Molecular Profiling; Mus; Mutation; Pathway interactions; Patients; Pharmaceutical Preparations; Pituitary Neoplasms; Play; RB1 gene; Recurrence; Research Design; Resistance; Retinoblastoma; Retinoblastoma Protein; Role; SKP2 gene; Skp2 Proteins; Stress; Survival Rate; Susceptibility Gene; Testing; Therapeutic; Treatment Protocols; Work; base; biological adaptation to stress; cancer cell; clinically relevant; design; effective therapy; inhibitor/antagonist; killings; lung small cell carcinoma; neoplastic cell; research study; response; small hairpin RNA; thyroid neoplasm; tumor; tumor progression

DESCRIPTION (provided by applicant): Background: Small cell lung cancer (SCLC) affects ~50,000 people a year. A lack of effective treatment options offers many of these patients a less than 5% survival rate five years after diagnosis. Identifying ways to kill SCLC tumor cells is clearly an imperative. Like many tumors, SCLC tumors display recurrent copy number alterations (CNA) in specific parts of the genome. Studies of other tumor types have shown that discovering what recurrent genomic abnormalities drive tumor survival can lead to more effective treatment protocols and patient survival. Under this pretense two recurrent genomic changes in SCLC stand alone, a near universal mutation (~95%) of the retinoblastoma susceptibility gene (RB1) and genomic amplification of the Skp2 locus (~65%). Previous work demonstrated that in Rb-/- pituitary and thyroid tumors in mice, loss of Skp2 was synthetic lethal. Therefore, the combinations of mutations that contribute to SCLC development may be exploited to promote SCLC cell death. Objective/Hypothesis: I hypothesize that a significant portion of SCLC cells will be sensitive to Skp2 targeted therapy. My preliminary studies support this notion. I propose to define the molecular profile of a Skp2- sensitive SCLC cell and to identify the mechanism by which loss of Skp2 initiates apoptosis in these cells. Specific Aims: (1.) To determine which SCLC cell lines require Skp2 for proliferation and survival. (2.) To identify the mechanism of synthetic lethality between loss of pRB and Skp2 in tumor cells. (3.) To elucidate the compensatory survival pathways in SCLC cells that promote viability following loss of Skp2. Study Design: Cell viability assays will be done in a panel of 58 SCLC cell lines housed at Center for Molecular Therapeutics at the MGH Cancer Center following lentiviral shRNA knockdown of Skp2 or a Scramble shRNA control. Gene expression profiles will be used to identify signatures that distinguish Skp2- dependent lines, from Skp2-independent SCLC cells. Gene expression profiles will be compiled following Skp2 knockdown in lines both sensitive and resistant to loss of Skp2. Previous work has suggested that loss of Skp2 induces apoptosis through a mechanism involving p27 function; alternatively, other work has shown that previous work demonstrated that loss of Skp2 promotes ER-stress. High levels of ER-stress are known to lead to apoptosis. Therefore the role of p27 and the ER-stress response will be assessed in the context of the synthetic lethality following loss of Skp2 in SCLC cells. The gene expression profiles will provide a basis for understanding why some cells and not others are sensitive to loss of Skp2. For cells tolerant of Skp2 loss alone, assessment of response to cellular stress will be determined in the presence and absence of Skp2. This will lead to identification of combined approaches that together with Skp2 knockdown will lead to SCLC cell death.

描述（由申请人提供）：背景：小细胞肺癌（SCLC）每年影响约5万人。由于缺乏有效的治疗方案，许多患者在诊断后五年的生存率不到5%。确定杀死SCLC肿瘤细胞的方法显然是当务之急。像许多肿瘤一样，SCLC肿瘤在基因组的特定部分显示复发性拷贝数改变（CNA）。对其他肿瘤类型的研究表明，发现什么样的复发性基因组异常驱动肿瘤存活可以导致更有效的治疗方案和患者存活。在这种假设下，SCLC中的两个复发性基因组变化是独立的，视网膜母细胞瘤易感基因（RB 1）的近普遍突变（~95%）和Skp 2基因座的基因组扩增（~65%）。先前的工作表明，在小鼠Rb-/-垂体和甲状腺肿瘤中，Skp 2的丢失是合成致死的。因此，有助于SCLC发展的突变的组合可以被利用来促进SCLC细胞死亡。目的/假设：我假设很大一部分SCLC细胞对Skp 2靶向治疗敏感。我的初步研究支持这一观点。我建议定义Skp 2敏感的小细胞肺癌细胞的分子特征，并确定Skp 2的丢失在这些细胞中启动凋亡的机制。具体目标：（1.）确定哪些SCLC细胞系需要Skp 2来增殖和存活。（2.）目的：探讨肿瘤细胞中pRB和Skp 2缺失之间的综合致死机制。（3.）阐明SCLC细胞在Skp 2缺失后促进活力的代偿性存活途径。研究设计：在慢病毒shRNA敲除Skp 2或Scramble shRNA对照后，将在MGH癌症中心分子治疗中心的一组58个SCLC细胞系中进行细胞活力试验。基因表达谱将用于鉴定区分Skp 2依赖性细胞系与Skp 2非依赖性SCLC细胞的特征。在Skp 2敲低后，将在对Skp 2丢失敏感和抗性的品系中编辑基因表达谱。先前的工作表明，Skp 2的丢失通过涉及p27功能的机制诱导细胞凋亡;或者，其他工作表明，先前的工作表明，Skp 2的丢失促进ER应激。已知高水平的ER应激会导致细胞凋亡。因此，将在SCLC细胞中Skp 2丢失后的合成致死率的背景下评估p27和ER应激反应的作用。基因表达谱将为理解为什么一些细胞而不是其他细胞对Skp 2的丢失敏感提供基础。对于仅耐受Skp 2损失的细胞，将在存在和不存在Skp 2的情况下确定对细胞应激的应答的评估。这将导致鉴定与Skp 2敲低一起将导致SCLC细胞死亡的组合方法。