The Mechanisms Underlying How Oxidative Stress Influences Neural Stem Cell Fate

氧化应激影响神经干细胞命运的机制

• 批准号: 8926844
• 负责人: Jihye Paik
• 金额: $ 33.71万
• 依托单位: WEILL MEDICAL COLL OF CORNELL UNIV
• 依托单位国家: 美国
• 财政年份: 2014
• 资助国家: 美国
• 起止时间: 2014-09-15 至 2019-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8926844
• 关键词: Acetylation; Adult; Age; Aging; Alzheimer' s Disease; Antioxidants; Automobile Driving; Binding; Brain; Cell Aging; Cell Culture Techniques; Cell Maintenance; Chromatin; Cobalamin; DNA; DNA Methylation; Data; Defect; Disabled Persons; Elderly; Epigenetic Process; Equilibrium; Family; Folic Acid; Functional disorder; Gene Expression; Genes; Glutamine; Glutathione; Health; Histones; Homeostasis; Huntington Disease; Impaired cognition; Injury; Insulin; Intervention; Knowledge; Learning; Link; Longevity; Maintenance; Mediating; Memory; Metabolic; Metabolic Pathway; Metabolism; Methionine; Methylation; Modification; Molecular; Molecular Target; Natural regeneration; Neurodegenerative Disorders; Nucleotides; Oligodendroglia; Organ; Oxidation-Reduction; Oxidative Stress; Parkinson Disease; Pathway interactions; Production; Protein Isoforms; Proto-Oncogene Proteins c-akt; Reactive Oxygen Species; Reporting; Role; Signal Transduction; Sorting - Cell Movement; Stem cells; Stress; Stroke; Testing; Therapeutic Intervention; Tissues; Translating; Work; adult stem cell; aging brain; base; cell age; cell growth; cofactor; cognitive function; epigenome; functional restoration; histone methylation; human FRAP1 protein; in vivo; insight; methylation pattern; nerve stem cell; neurogenesis; novel strategies; prevent; prevention evaluation; programs; promoter; regenerative; relating to nervous system; self-renewal; stem; stem cell fate; transcription factor

DESCRIPTION (provided by applicant): In this proposal we seek to understand how oxidative stress influences neural stem/progenitor cell fate. Growing evidence indicates that decreased neurogenic potential of neural stem/progenitor cells (NPCs) contributes to a deficit in cognitive functions such as learning and memory, serving as a basis for accelerated brain aging. In the long term we want to define the mechanisms by which maintenance of functional NPCs is perturbed in old age. The FoxO-family of transcription factors is a key modulator of longevity. Our work, and that of others, has demonstrated that FoxO is crucial for maintaining adult stem cell pools by suppressing oxidative stress, thereby connecting longevity with regenerative potential of aging tissues. Oxidative stress is increasingly recognized as a driving cause of aging-associated dysfunction of organ stem cells. However, direct cellular consequences of reactive oxygen species (ROS) that is translated as molecular aging of stem cells remain as broad and non-specific. Such knowledge gap is an important problem as lack of reliable molecular targets of ROS prevents evaluation and prevention of aging-associated NPC dysfunction. We hypothesize that FoxO suppresses ROS by regulating metabolic pathways and accumulation of ROS inhibits methionine re-methylation cycle that causes epigenetic changes and aberrant differentiation in FoxO-/- NPC. We will test our hypothesis by following specific aims: 1) Characterize the metabolic defects associated with increased oxidative stress in FoxO-/- NPC; 2) Investigate methionine synthase as a target of deregulated ROS in NPC; and 3) Define epigenetic changes associated with differentiation defects in FoxO- /- NPC. Completion of this aim will substantiate the role of FoxO in the balance between NPC self-renewal and differentiation and provide a tangible target of ROS that could be exploited as an intervention point for the aging brain. The findings will also have direct relevance to understanding conserved mechanisms of stem cell maintenance that are perturbed in old age and contribute globally to acquired deficits in tissue function. Application of these findings ultimately may help to delay or reverse the detrimental age- progressive cognitive decline and neurodegenerative diseases.

描述（由申请人提供）：在本提案中，我们试图了解氧化应激如何影响神经干/祖细胞的命运。越来越多的证据表明，神经干/祖细胞（NPC）的神经原性潜能降低导致认知功能（如学习和记忆）的缺陷，这是加速脑老化的基础。从长远来看，我们希望确定功能性NPC的维持在老年时受到干扰的机制。转录因子FoxO家族是长寿的关键调节因子。我们和其他人的工作已经证明，FoxO通过抑制氧化应激，从而将长寿与衰老组织的再生潜力联系起来，对维持成体干细胞库至关重要。氧化应激越来越被认为是器官干细胞衰老相关功能障碍的驱动因素。然而，被翻译为干细胞分子老化的活性氧（ROS）的直接细胞后果仍然是广泛和非特异性的。这种知识缺口是一个重要的问题，因为缺乏可靠的ROS分子靶点阻碍了衰老相关NPC功能障碍的评估和预防。我们推测FoxO通过调节代谢途径抑制ROS，ROS的积累抑制了导致FoxO-/- NPC表观遗传变化和异常分化的甲硫氨酸再甲基化循环。我们将通过以下具体目的来检验我们的假设：1）表征与FoxO-/- NPC中氧化应激增加相关的代谢缺陷; 2）研究甲硫氨酸合酶作为NPC中ROS失调的靶点;和3）定义与FoxO- /- NPC中分化缺陷相关的表观遗传变化。这一目标的实现将证实FoxO在NPC自我更新和分化之间的平衡中的作用，并提供一个可以作为衰老大脑干预点的ROS的有形靶点。这些发现也将与理解干细胞维持的保守机制直接相关，这些机制在老年时受到干扰，并在全球范围内导致组织功能的获得性缺陷。这些发现的应用最终可能有助于 以延缓或逆转有害的年龄-渐进性认知衰退和神经退行性疾病。