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Fluid transport in inner ear development

内耳发育中的液体运输

基本信息

批准号：
8703069
负责人：
A. Philine Wangemann
金额：
$ 37.74万
依托单位：
KANSAS STATE UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2012
资助国家：
美国
起止时间：
2012-08-01 至 2017-07-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8703069
关键词：
Address Affect Age Auditory Bicarbonates Birth Brain Stem Carbon Dioxide Child Childhood Cochlea Code Development Embryo Embryonic Development Endolymph Epithelial Cells Epithelium Equilibrium Etiology Fluids and Secretions Fossils Gene Mutation Genes Genetic Goals Hearing Hearing Impaired Persons Histology Homeostasis Human Impairment In Situ Hybridization Incidence Individual Inherited Ion Transport Ion-Selective Electrodes Labyrinth Language Development Liquid substance Location Measurement Measures Mediating Modeling Monitor Mus Mutant Strains Mice Mutation Orthologous Gene Patients Phenotype Population Prevention Proteins Role Speech Testing Time Ursidae Family Vestibular Aqueduct Vestibular Labyrinth absorption apical membrane base deafness endolymphatic sac hearing impairment immunocytochemistry membranous labyrinth mouse model novel postnatal prevent public health relevance restoration therapy development treatment strategy

项目摘要

DESCRIPTION (provided by applicant): About 1 in 1000 children has hereditary hearing loss with mutations of SLC26A4 being one of the most prevalent known causes of hereditary deafness. The high incidence provides an imperative to investigate the etiology of SLC26A4-related deafness with the ultimate goal to develop strategies to restore and preserve hearing in afflicted individuals. The human gene SLC26A4 and the mouse ortholog Slc26a4 code for pendrin. Studies in mouse have demonstrated that pendrin is a Cl-/HCO3- exchanger in the cochlea, vestibular labyrinth and the endolymphatic sac. Lack of pendrin during embryonic development causes an acidification of endolymph and a mismatch between fluid secretion in the vestibular labyrinth and pendrin-dependent fluid absorption in the endolymphatic sac that leads to an enlargement of the membranous labyrinth and an impairment of cochlear development. The enlarged vestibular aqueduct, frequently associated with mutations of SLC26A4, appears to be a fossil-like record of such an enlargement that was present during embryonic development. Mechanisms of fluid secretion and fluid absorption in the embryonic inner ear are virtually unknown. Filling this gap in our understanding of inner ear development is critical toward the development of treatments to protect hearing in individuals afflicted with mutations of SLC26A4. We have developed four Specific Aims that address the most salient questions in mouse models: Aim1) - what is the ionic composition of endolymph in the embryonic cochlea and the endolymphatic sac? This aim will be addressed by measuring the composition of inner ear fluids with ion-selective electrodes. Aim2) what mechanisms mediate fluid secretion? Aim3) what mechanisms mediate fluid absorption? These aims will be addressed by testing hypothetical models of fluid secretion and fluid absorption. The onset and location of expression of candidate channels and transporters will be determined by qRT-PCR and immunocytochemistry or in-situ hybridization. Selected models will be tested in compound-mutant mice. Deficient expression of channels or transporters implicated in fluid secretion is expected to curb cochlear enlargement and possibly restore normal cochlear development in the absence of pendrin. Conversely, deficient expression of channels or transporters implicated in fluid absorption is expected to cause cochlear enlargement in the presence of pendrin. Aim4) is restoration of pendrin expression solely to the endolymphatic sac sufficient to prevent cochlear enlargement and deafness? This aim will be addressed by generating mice with pendrin expression limited to the endolymphatic sac of the inner ear. Studies will include monitoring cochlear lumen formation by histology, measurements of the endocochlear potential and endolymphatic pH with ion-selective electrodes and evaluating hearing by auditory brain stem recordings. Completion of these four Aims will establish an understanding of fluid homeostasis in cochlear development which holds the promise to reveal treatment strategies that are suitable to prevent deafness in individuals that bear mutations of SLC26A4.

描述（由申请人提供）：大约千分之一的儿童患有遗传性听力损失，SLC26A4 突变是遗传性耳聋最常见的已知原因之一。高发病率迫切需要调查 SLC26A4 相关耳聋的病因，最终目标是制定恢复和保留患病个体听力的策略。人类基因 SLC26A4 和小鼠直系同源基因 Slc26a4 编码 pendrin。小鼠研究表明，pendrin 是耳蜗、前庭迷路和内淋巴囊中的 Cl-/HCO3- 交换剂。胚胎发育过程中缺乏 pendrin 会导致内淋巴酸化，以及前庭迷路中的液体分泌与内淋巴囊中依赖于 pendrin 的液体吸收之间的不匹配，从而导致膜迷路扩大和耳蜗发育受损。增大的前庭导水管通常与 SLC26A4 突变相关，似乎是胚胎发育过程中存在的这种增大的化石记录。胚胎内耳中液体分泌和液体吸收的机制实际上是未知的。填补我们对内耳发育理解的这一空白对于开发保护患有 SLC26A4 突变的个体听力的治疗方法至关重要。我们制定了四个具体目标来解决小鼠模型中最突出的问题：目标1) - 胚胎耳蜗和内淋巴囊中内淋巴的离子组成是什么？这一目标将通过使用离子选择性电极测量内耳液体的成分来实现。目标2）什么机制介导液体分泌？目标3）什么机制介导液体吸收？这些目标将通过测试液体分泌和液体吸收的假设模型来实现。候选通道和转运蛋白表达的起始和位置将通过 qRT-PCR 和免疫细胞化学或原位杂交来确定。选定的模型将在复合突变小鼠中进行测试。与液体分泌有关的通道或转运蛋白的表达缺陷预计会抑制耳蜗增大，并可能在缺乏 pendrin 的情况下恢复正常的耳蜗发育。相反，在存在 pendrin 的情况下，与液体吸收有关的通道或转运蛋白的表达缺陷预计会导致耳蜗增大。目标 4) 仅恢复内淋巴囊的 pendrin 表达是否足以预防耳蜗增大和耳聋？这一目标将通过产生pendrin表达仅限于内耳内淋巴囊的小鼠来实现。研究将包括通过组织学监测耳蜗腔的形成、使用离子选择性电极测量耳蜗内电位和内淋巴 pH 值以及通过听觉脑干记录评估听力。完成这四个目标将建立对耳蜗发育中液体稳态的理解，这有望揭示适合预防携带 SLC26A4 突变的个体耳聋的治疗策略。