Gene-Expression Patterns During Hair-Cell Regeneration

毛细胞再生过程中的基因表达模式

• 批准号: 7933790
• 负责人: ALBERT JAMES HUDSPETH
• 金额: $ 22.76万
• 依托单位: ROCKEFELLER UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-09-17 至 2011-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7933790
• 关键词: Address; Affect; Age; Aminoglycoside Antibiotics; Area; Biological Assay; Biological Models; Cell Death; Cell Separation; Cells; Cochlea; Confocal Microscopy; Data; Depressed mood; Development; Elderly; Enhancers; Equilibrium; Event; Feedback; Fluorescence-Activated Cell Sorting; Gene Chips; Gene Expression; Genes; Hair Cells; Hearing; Hearing problem; Human; Individual; Infant; Label; Labyrinth; Maintenance; Messenger RNA; Mitosis; Molecular; Natural regeneration; Organ; Pathway interactions; Pattern; Peripheral; Population; Preparation; Production; Regenerative Medicine; Side; Signal Pathway; Signal Transduction; Societies; Speech; Stem cells; Stimulus; Structure; Supporting Cell; Time; United States; Vertebrates; Vestibule; Zebrafish; base; cell type; cost; deafness; hair cell regeneration; hearing impairment; killings; lateral line; neuromast; operation; progenitor; public health relevance; receptor; response; restoration; stem cell division; stem cell population; therapeutic target

DESCRIPTION (provided by applicant): This application addresses broad Challenge Area 11, entitled Regenerative Medicine. The specific Challenge Topic is 11-DC-101, Hair Cell Regeneration and Maintenance. Deafness and lesser degrees of hearing impairment have an enormous impact on modern societies. Throughout the industrialized world, about one-tenth of the population suffers from functionally significant hearing and balance problems. The societal impact of hearing loss is immense. In addition to its annual cost in the United States of more than $80 billion, hearing disease delays the acquisition of speech in infants, isolates the elderly, and depresses affected individuals of all ages. A promising avenue to the alleviation of deafness is the restoration of normal hearing by regeneration of hair cells in the human cochlea. We wish to determine the particular genes whose activation underlies the renewal of hair cells in species whose receptors normally turn over. In particular, we hope to investigate the lateral-line organ of the larval zebrafish, a preparation in which hair-cell regeneration has been described in detail. We shall begin by ascertaining which molecular signals are activated by hair-cell death, the stimulus for regeneration. We next plan to determine the particular signaling pathways that are activated when quiescent stem cells and amplifying progenitors transition to their mitotically active states. Finally, we intend to understand what pathways are upregulated as immature cells differentiate into functional hair cells. The structure, development, and operation of hair cells are conserved throughout the vertebrates. We accordingly anticipate that a detailed understanding of the molecular events underlying hair-cell regeneration in a model system will be useful in restoring human hearing. Identifying the changes in gene expression by stem cells and hair-cell progenitors will provide clues about the signaling pathways that are activated at the outset of hair-cell regeneration. Because pharmacological manipulation of the relevant molecular signals may restore the activity of stem cells in the mammalian inner ear, these pathways constitute logical targets for therapeutic approaches to the regeneration of hair cells in the human cochlea and vestibular apparatus. Gene-expression patterns during hair-cell regeneration PUBLIC HEALTH RELEVANCE: Deafness and lesser degrees of hearing impairment have an enormous impact on modern societies: about one-tenth of our population suffers from functionally significant hearing and balance problems. A promising avenue to the alleviation of deafness is the restoration of normal hearing by regeneration of hair cells in the human cochlea. We wish to determine the signaling pathways that underlie the renewal of hair cells, for these pathways constitute logical targets for therapeutic approaches to the regeneration of hair cells in the human cochlea and vestibular apparatus.

描述（由申请人提供）：本申请涉及广泛的挑战领域11，标题为再生医学。具体的挑战主题是11-DC-101，毛细胞再生和维护。耳聋和较轻程度的听力障碍对现代社会有着巨大的影响。在整个工业化世界中，大约十分之一的人口患有功能性严重的听力和平衡问题。听力损失的社会影响是巨大的。除了在美国每年花费超过800亿美元之外，听力疾病还延迟了婴儿获得语言能力，使老年人孤立，并使所有年龄段的受影响个体感到沮丧。一个有希望的减轻耳聋的途径是通过人类耳蜗毛细胞的再生来恢复正常听力。我们希望确定特定的基因，其激活是受体正常转换的物种中毛细胞更新的基础。特别是，我们希望调查的侧线器官的幼斑马鱼，准备在毛细胞再生已被详细描述。我们将开始确定哪些分子信号是由毛细胞死亡激活的，毛细胞死亡是再生的刺激。我们接下来计划确定当静止干细胞和扩增祖细胞转变为有丝分裂活跃状态时激活的特定信号通路。最后，我们打算了解当未成熟细胞分化为功能性毛细胞时哪些途径被上调。毛细胞的结构、发育和运作在脊椎动物中是保守的。因此，我们预计，在模型系统中毛细胞再生的分子事件的详细了解将有助于恢复人类的听力。确定干细胞和毛细胞祖细胞基因表达的变化将为毛细胞再生开始时激活的信号通路提供线索。由于药理学操作的相关分子信号可以恢复干细胞在哺乳动物内耳的活性，这些途径构成了合理的目标，在人类耳蜗和前庭器官的毛细胞再生的治疗方法。毛细胞再生过程中的基因表达模式 公共卫生相关性：耳聋和较轻程度的听力障碍对现代社会产生巨大影响：大约十分之一的人口患有功能性严重的听力和平衡问题。一个有希望的减轻耳聋的途径是通过人类耳蜗毛细胞的再生来恢复正常听力。我们希望确定毛细胞更新的信号通路，因为这些通路构成了人类耳蜗和前庭器官毛细胞再生治疗方法的逻辑目标。