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Slow cycling brain tumor cancer stem cells

慢循环脑肿瘤干细胞

基本信息

批准号：
7706547
负责人：
Brent Reynolds
金额：
$ 16.12万
依托单位：
UNIVERSITY OF FLORIDA
依托单位国家：
美国
项目类别：
财政年份：
2009
资助国家：
美国
起止时间：
2009-07-01 至 2011-06-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/7706547
关键词：
Accounting Activities of Daily Living Acute Acute Myelocytic Leukemia Adult Advocate Aftercare Age Anaplasia Anaplastic astrocytoma Arts Astrocytoma Automobile Driving Behavior Benign Brain Brain Neoplasms Breast CD34 gene Cancer Biology Cancerous Cell Cycle Cell Cycle Arrest Cell division Cells Central Nervous System Neoplasms Characteristics Cytotoxic Chemotherapy Cytotoxic agent Diffuse Disease Drug Delivery Systems Dyes Elderly Exhibits Flow Cytometry Frequencies Gene Expression Generations Genotype Glioblastoma Glioma Growth Head Heart Human Image In Situ In Vitro Incidence Intervention Life Light Lung Maintenance Malignant - descriptor Malignant Glioma Malignant Neoplasms Mean Survival Times Mesenchymal Mesenchymal Cell Neoplasm Methods Microvascular Proliferation Mitosis Modeling Molecular Morphology Myelogenous Names Nature Necrosis Neoplasm Metastasis Neuraxis Neurodegenerative Disorders Neuroglia Neurons Nuclear Atypia Oligodendroglioma-Astrocytoma Operative Surgical Procedures Organism Outcome Study Patients Pattern Phase Pilocytic Pilocytic Astrocytoma Population Positioning Attribute Primary Brain Neoplasms Process Property Prostate Radiation Radiation therapy Recovery Recurrence Refractory Relative (related person)Resistance Rest Role Severities Signal Pathway Solid Stem cells Techniques Testing Therapeutic Time Tissues Transplantation Tumor Stem Cells Tumor-Derived Work adult stem cell aggressive therapy base cancer cell cancer stem cell chemotherapy conventional therapy cytotoxic drug development implantation in vivo insight irradiation neoplastic cell nerve stem cell neuron loss outcome forecast precursor cell premature prevent public health relevance radiation effect research study resistance mechanism response self-renewal stem cell population therapeutic target therapy development therapy resistant tumor tumor growth

项目摘要

DESCRIPTION (provided by applicant): Malignant gliomas are the most common primary brain tumour, accounting for the majority of cancers in the adult central nervous system. The incidence of malignant gliomas is increasing world-wide, particularly among the elderly. In general, malignant gliomas are not curable tumours. Traditional pathological approaches grade malignant gliomas into three grades of malignancy. Grade II low grade astrocytoma, with a mean patient survival of 5-15 years. Grade III anaplastic astrocytoma, with a mean patient survival of 3 years. Grade IV glioblastoma multiforme (GBM), the most malignant and common glioma, with a mean survival time of less than 1 year despite aggressive therapy that combines state-of- the-art imaging with surgery, radiotherapy and chemotherapy. Although a transient response to therapy is often observed, tumour recurrence is almost inevitable and usually occurs within tissue that has received intensive cytotoxic therapy, suggesting a sub-population of resistant cells are responsible for tumour regrowth. One of the most prominent topics in the field of cancer biology is that tumour-initiating cells, which phenotypically mimic the cardinal properties of stem cells, are responsible for the origin and maintenance of solid tissue malignancies. The idea that tumor-initiating cells (TICs) may exhibit stem cell characteristics was first confirmed in the 1990s, based on studies of acute myeloid leukaemia and has since been strengthened by findings related to breast, prostate, lung and mesenchymal tumours. The ability of cells derived from human glioma tissue to generate neurospheres in culture suggests the presence of tumour cells with neural stem cell properties (tNSCs) within CNS tumours, as neurosphere generation is one indicator of the presence of neural stem cells. Furthermore, work from ourselves and colleagues have demonstrated the isolation, propagation and serial transplantation of tNSCs that exhibit very similar functional properties as neural stem cells. Importantly, following implantation of tNSCs, the resulting tumours exhibit the classic in vivo features of human glioblastoma multiforme; recapitulating the morphology, genotype and gene expression patterns as primary GBMs, as well as having extensive migratory and infiltrative capacity. This indicates that the in vitro defined brain tumour stem cells faithfully preserve the key in vivo features of human glioblastoma multiforme (hGBM). One of the defining characteristics of somatic stem cells is their infrequent cell division due to cell cycle arrest, which is essential to prevent premature stem cell depletion over the lifetime of the organism. As it is well established that cell cycle arrest protects cells from irradiation and cytotoxic agents, it follows that the slow-cycling TICs will be resistant to conventional therapeutic approaches. In light of these observations, we hypothesise that post-therapy tumour regrowth is initiated from a small population of slow cycling chemo/irradiation-resistant TICs that exhibit the basic stem cell property of self-renewal. TICs then generate a separate and transient population of rapidly dividing progeny cells that are responsible for repopulating the tumour bulk, much like somatic stem cells generate a rapidly dividing pool of precursor cells to replace damaged tissue. Importantly, this model predicts that the elimination of the TICs is required for the long-term recovery of glioma patients. The underlying hypothesis of this proposal is that hGBM tumours contain a population of slow- cycling cells, which can initiate secondary tumour formation and are resistant to conventional treatment. The specific aims will establish the existence of slow cycling hGBM cells in vitro and in vivo, characterize the effects of irradiation and chemotherapy on this sub-population, and investigate the mechanisms underlying this resistance. The outcome of this study will likely define relevant targets, detail its mechanism of resistance and initiate a new avenue for drug development. PUBLIC HEALTH RELEVANCE: Malignant gliomas are the most common primary brain tumor, accounting for the majority of cancers in the adult central nervous system. They are increasing worldwide and carry a poor prognosis with most patients succumbing to their disease regardless of treatment. We are investigating the role of the cells responsible for driving long-term tumor growth and resistance to treatment using methods and techniques commonly used to study normal adult stem cells. The project should unveil the stem cell characteristics of brain tumor cells and provide insight in how to regulate the behavior of the cancer cells.

描述（由申请人提供）：恶性神经胶质瘤是最常见的原发性脑肿瘤，占成人中枢神经系统癌症的大多数。恶性神经胶质瘤的发病率在世界范围内不断增加，特别是在老年人中。一般来说，恶性神经胶质瘤是不可治愈的肿瘤。传统的病理学方法将恶性胶质瘤分为三个级别。II级低级别星形细胞瘤，患者平均生存期为5-15年。III级间变性星形细胞瘤，患者平均生存期为3年。IV级多形性胶质母细胞瘤（GBM）是最恶性和最常见的胶质瘤，尽管采用了将最先进的成像技术与手术、放疗和化疗相结合的积极治疗，但平均生存时间仍不到1年。虽然经常观察到对治疗的短暂反应，但肿瘤复发几乎是不可避免的，并且通常发生在接受过强化细胞毒性治疗的组织中，这表明耐药细胞亚群负责肿瘤再生长。肿瘤起始细胞是肿瘤生物学领域最重要的研究课题之一，它在表型上模仿干细胞的基本特性，负责实体组织恶性肿瘤的起源和维持。肿瘤起始细胞（TIC）可能表现出干细胞特征的想法在20世纪90年代首次得到证实，基于对急性髓性白血病的研究，并且此后通过与乳腺，前列腺，肺和间叶肿瘤相关的发现得到加强。来源于人神经胶质瘤组织的细胞在培养物中产生神经球的能力表明在CNS肿瘤中存在具有神经干细胞特性（tNSC）的肿瘤细胞，因为神经球产生是神经干细胞存在的一个指标。此外，我们和同事的工作已经证明了tNSCs的分离，繁殖和连续移植，表现出与神经干细胞非常相似的功能特性。重要的是，在植入tNSC后，所得肿瘤表现出人多形性胶质母细胞瘤的经典体内特征;再现了原发性GBM的形态、基因型和基因表达模式，以及具有广泛的迁移和浸润能力。这表明体外确定的脑肿瘤干细胞忠实地保留了人多形性胶质母细胞瘤（hGBM）的关键体内特征。体干细胞的定义特征之一是它们由于细胞周期停滞而不频繁的细胞分裂，这对于防止在生物体的一生中干细胞过早耗尽是必不可少的。由于已充分确定细胞周期停滞保护细胞免受辐射和细胞毒性剂的影响，因此慢循环TIC将对常规治疗方法具有抗性。根据这些观察结果，我们假设治疗后肿瘤再生长是从一小群慢循环化疗/辐射抗性TIC开始的，这些TIC表现出自我更新的基本干细胞特性。然后，TIC产生一个单独的和短暂的快速分裂的后代细胞群体，这些细胞负责重新填充肿瘤块，就像体干细胞产生一个快速分裂的前体细胞池来取代受损的组织一样。重要的是，该模型预测，胶质瘤患者的长期恢复需要消除TIC。该提议的基本假设是hGBM肿瘤含有慢循环细胞群，其可以引发继发性肿瘤形成并且对常规治疗具有抗性。具体的目标将建立在体外和体内的慢循环hGBM细胞的存在，表征辐射和化疗对这个亚群的影响，并调查这种阻力的机制。这项研究的结果可能会定义相关的目标，详细说明其耐药机制，并为药物开发开辟新的途径。公共卫生关系：恶性神经胶质瘤是最常见的原发性脑肿瘤，占成人中枢神经系统癌症的大多数。它们在世界范围内不断增加，并且预后不良，大多数患者无论如何治疗都会死于疾病。我们正在使用通常用于研究正常成体干细胞的方法和技术来研究负责驱动长期肿瘤生长和治疗抗性的细胞的作用。该项目将揭示脑肿瘤细胞的干细胞特征，并提供如何调节癌细胞行为的见解。