Heat Shock Directed Drug Discovery For The Treatment Of Gliomas

热休克定向治疗神经胶质瘤的药物发现

• 批准号: 7937847
• 负责人: Sandro Santagata
• 金额: $ 17.79万
• 依托单位: BRIGHAM AND WOMEN'S HOSPITAL
• 依托单位国家: 美国
• 财政年份: 2008
• 资助国家: 美国
• 起止时间: 2008-09-01 至 2013-07-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7937847
• 关键词: Address; Anatomy; Area; Biological; Biological Assay; Biology; Biosensor; Blood - brain barrier anatomy; Brain Neoplasms; Cell Proliferation; Cell model; Cell physiology; Cells; Central Nervous System Diseases; Chemical Modifier; Chemicals; Clinical Protocols; Collaborations; Dana-Farber Cancer Institute; Development; Development Plans; Disease; Doctor of Medicine; Doctor of Philosophy; Excision; Future; Gene Targeting; Genetic; Glioma; Gliomagenesis; Goals; Growth; Heat-Shock Proteins 90; Heat-Shock Response; Homeostasis; Human; In Vitro; Lead; Life; Malignant Neoplasms; Malignant Peripheral Nerve Sheath Tumor; Mediator of activation protein; Mentorship; Modeling; Molecular; Molecular Chaperones; Mus; Mutate; Mutation; Nature; Nerve Degeneration; Neuraxis; Oncogenes; PDGFRB gene; Patients; Pharmaceutical Preparations; Prion Diseases; Proteasome Inhibitor; Proteins; Reagent; Refractory; Research; Resources; Signal Pathway; Specimen; Stem cells; Structure; System; TP53 gene; Techniques; Testing; Therapeutic; Therapeutic Intervention; Tissues; Training; Tumor Cell Line; Work; addiction; base; biobank; biological adaptation to stress; career development; chaperone machinery; drug development; drug discovery; glioma cell line; heat-shock factor 1; human stem cells; improved; in vivo; inhibitor/antagonist; insight; member; multicatalytic endopeptidase complex; neuropathology; novel; outcome forecast; programs; protein folding; protein phosphatase inhibitor-2; small molecule; small molecule libraries; stem cell biology; transcription factor; tumor; tumorigenesis

DESCRIPTION (provided by applicant): Project Summary: Gliomas constitute the most lethal class of primary CNS malignancies. Many therapeutic approaches seek to target specific components of signaling pathways that are aberrantly activated by mutation, yet mounting evidence demonstrates that tumor survival is also critically dependent on non-mutated, non-oncogene systems that impact global cellular processes; a phenomenon termed non-oncogene addiction. The cellular components that regulate protein homeostasis are among the most prominent mediators of non-oncogene addiction and targeting these functions with HSP90 and proteasome inhibitors results in robust anti-glioma activity. Moreover, our group has revealed another unexpected mediator of non-oncogene addiction, Heat Shock Factor 1 (HSF1), the main transcription factor regulating the heat shock response (HSR), which acts a powerful multifaceted regulator of signaling pathways relevant to gliomagenesis. In this proposal, I will test the hypothesis that modulating protein homeostasis by high-throughput techniques will provide a powerful strategy for identifying lead compounds to drive the development of effective anti-glioma therapeutics. To explore this, we have used the HSR as a biosensor in two high-throughput cell-based phenotypic screens of 100,000 compounds and have identified 100 compounds that induce and 50 that inhibit the HSR. The following specific aims are proposed to test our hypothesis: Aim 1: to determine the effects of pharmacological modulation of the HSR on proliferation and survival in 'stem cell' based models of glioma; Aim 2: to characterize the mechanism of action of active compounds to identify those with novel targets; Aim 3: to assess the potential of active compounds to cross the blood brain barrier; Aim 4: to assess the potential of small molecule modulators of protein homeostasis to inhibit glioma growth in vivo. The candidate is an M.D., Ph.D. trained in Anatomic/Neuropathology who seeks mentorship in the chemical biology of gliomas from Dr. Susan Lindquist. Outlined in the proposal is a research plan using the extensive resources of the Whitehead, Broad and Dana Farber Cancer Institutes and a career development plan for achieving academic independence. Relevance: High-grade gliomas are among the most aggressive forms of cancer and current treatments do not markedly improve patient prognosis. By characterizing the chemical biology of the HSR in gliomas we aim to identify lead molecules with anti-glioma activity. Of additional relevance, some of these HSR modulating drugs may have application in classic protein folding CNS disorders such as neurodegenerative and prion diseases.

描述（由申请方提供）：项目总结：胶质瘤是原发性CNS恶性肿瘤中最致命的一类。许多治疗方法寻求靶向突变异常激活的信号通路的特定组分，但越来越多的证据表明，肿瘤存活也严重依赖于影响全球细胞过程的非突变的非癌基因系统;这种现象称为非癌基因成瘾。调节蛋白质稳态的细胞组分是非癌基因成瘾的最突出的介质之一，并且用HSP 90和蛋白酶体抑制剂靶向这些功能导致稳健的抗胶质瘤活性。此外，我们的研究小组还发现了另一种意想不到的非癌基因成瘾介质，热休克因子1（HSF 1），调节热休克反应（HSR）的主要转录因子，它是与胶质瘤形成相关的信号通路的强大多方面调节剂。在这个建议中，我将测试的假设，即通过高通量技术调节蛋白质稳态将提供一个强大的战略，确定先导化合物，以推动有效的抗胶质瘤治疗的发展。为了探索这一点，我们使用HSR作为生物传感器，在两个高通量的基于细胞的100，000种化合物的表型筛选中，并鉴定了100种诱导和50种抑制HSR的化合物。提出了以下具体目的来检验我们的假设：目的1：确定HSR的药理学调节对基于“干细胞”的神经胶质瘤模型中增殖和存活的影响;目的2：表征活性化合物的作用机制以鉴定具有新靶点的化合物;目的3：评估活性化合物穿过血脑屏障的潜力;目的4：评估蛋白质稳态的小分子调节剂在体内抑制胶质瘤生长的潜力。候选人是医学博士博士在解剖学/神经病理学方面接受过培训，她向Susan Lindquist博士寻求神经胶质瘤化学生物学方面的指导。提案中概述了一项利用怀特黑德、布罗德和达纳法伯癌症研究所广泛资源的研究计划，以及一项实现学术独立的职业发展计划。相关性：高级别胶质瘤是最具侵袭性的癌症之一，目前的治疗方法不能显著改善患者的预后。通过表征神经胶质瘤中HSR的化学生物学特性，我们的目标是鉴定具有抗神经胶质瘤活性的先导分子。另外相关的是，这些HSR调节药物中的一些可能在经典的蛋白质折叠CNS病症如神经变性和朊病毒疾病中具有应用。