Neurotoxicity and neuroprotection in the DBA/2J spontaneous model of glaucoma

DBA/2J 自发性青光眼模型的神经毒性和神经保护

基本信息

批准号：
8389866
负责人：
MEREDITH GREGORY-KSANDER
金额：
$ 46.08万
依托单位：
SCHEPENS EYE RESEARCH INSTITUTE
依托单位国家：
美国
项目类别：
财政年份：
2011
资助国家：
美国
起止时间：
2011-12-01 至 2015-11-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8389866
关键词：
Apoptosis Apoptotic Backcrossings Binding Binding Proteins Blindness Brain CD95 Antigens Cell Death Cell Surface Proteins Cells Cessation of life Chronic Disease Cleaved cell Clinical Coculture Techniques Development Disease Disease Progression Eye Glaucoma Immune In Vitro Inflammatory Infiltrate Knock-in Mouse Lead Mediating Mediator of activation protein Membrane Metalloproteases Microglia Modeling Molecular Mouse Strains Mus Mutate Mutation Neuroglia Pathogenesis Patients Physiologic Intraocular Pressure Predisposition Primary Open Angle Glaucoma Problem Solving Research Retina Retinal Retinal Ganglion Cells Scientist Site System Testing Therapeutic Intervention Time Tissues Tumor Necrosis Factor Ligand Superfamily Member 6 Work base cell type in vivo interest neuroprotection neurotoxic neurotoxicity novel pressure prevent pro-apoptotic protein response to injury retinal apoptosis retinal neuron stem

项目摘要

DESCRIPTION (provided by applicant): Glaucoma is one of the most common causes of blindness worldwide and, while there are many different forms of glaucoma that differ significantly in clinical presentation and disease progression, they all share a common endpoint which is the loss of retinal ganglion cells (RGCs). New treatments are needed, since current therapies can delay, but not stop disease progression. One of the major barriers to the development of novel treatments is the incomplete understanding of the disease pathogenesis. Recent evidence indicates the loss of RGCs is due to apoptosis, nevertheless, the actual molecular mechanism that triggers apoptosis is still controversial. Fas Ligand (FasL) is a pro-apoptotic protein that is constitutively expressed in the retina where it is thought to protect tissue from destruction by maintaining immune privilege, either by inducing apoptosis of infiltrating inflammatory cells or by preventing neoangeogenesis. However, there are two forms of FasL, a membrane-bound form (mFasL) and a soluble form (sFasL) that is produced by metalloproteinase cleavage of the membrane-bound protein. Our previous studies on the function of mFasL and sFasL indicate that mFasL is pro-apoptotic, while sFasL is anti-apoptotic. We recently developed a unique knock-in mouse strain in which the FasL metalloproteinase cleavage sites were mutated to prevent cleavage of the membrane-bound protein. In these mice, FasL is expressed and regulated normally, but they are unable to cleave FasL and therefore, can only express mFasL (termed ? CS mice). For the first time, these mice have allowed us to study the in vivo function of membrane FasL in the absence of soluble FasL. In order to determine the function of mFasL in the development of glaucoma, we backcrossed the ? CS knock-in mutation into the DBA/2J strain (D2. ? CS mice) that develops spontaneous elevated intraocular pressure (IOP) and loss of RGCs. Our preliminary results indicate that mFasL is a critical mediator of RGC apoptosis during the development of glaucoma. Moreover, sFasL has an important neuroprotective effect that not only prevents loss of RGCs, but also protects other retinal neurons in hypertensive eyes. We hypothesize that in response to injury caused by elevated IOP, there is increased expression of Fas and FasL within the retina. However, the extent of retinal apoptosis is determined by the ratio of membrane / soluble FasL expressed by microglia. Neurotoxic microglia express higher levels of mFasL, while neuroprotective microglia express higher levels of sFasL. This hypothesis will be tested in three Specific Aims: (Aim 1) Demonstrate that elevated IOP in D2. ? CS mice that are unable to cleave FasL triggers increased retinal neurotoxicity. (Aim 2) Determine whether increased retinal neurotoxicity in D2. ? CS mice is due to increased mFasL expression and/or the absence of sFasL. (Aim 3) Determine the mechanisms of microglia-mediated neurotoxicity in vitro using a co-culture system with immortalized retinal microglia from D2. ? CS mice and primary RGCs.

描述（由申请人提供）：青光眼是全世界最常见的致盲原因之一，虽然有许多不同形式的青光眼，在临床表现和疾病进展方面存在显着差异，但它们都有一个共同的终点，即视网膜丧失神经节细胞（RGC）。需要新的治疗方法，因为当前的治疗方法可以延迟但不能阻止疾病进展。开发新疗法的主要障碍之一是对疾病发病机制的不完全了解。最近的证据表明RGCs的损失是由于细胞凋亡引起的，然而，触发细胞凋亡的实际分子机制仍然存在争议。 Fas 配体 (FasL) 是一种促凋亡蛋白，在视网膜中组成型表达，人们认为它可以通过诱导浸润炎症细胞凋亡或防止新生血管生成来维持免疫特权，从而保护组织免受破坏。然而，FasL 有两种形式：膜结合形式 (mFasL) 和可溶形式 (sFasL)，后者是由膜结合蛋白的金属蛋白酶裂解产生的。我们前期对mFasL和sFasL功能的研究表明，mFasL具有促凋亡作用，而sFasL具有抗凋亡作用。我们最近开发了一种独特的敲入小鼠品系，其中 FasL 金属蛋白酶切割位点发生突变，以防止膜结合蛋白的切割。在这些小鼠中，FasL 正常表达和调节，但它们无法裂解 FasL，因此只能表达 mFasL（称为 ? CS 小鼠）。这些小鼠首次使我们能够在缺乏可溶性 FasL 的情况下研究膜 FasL 的体内功能。为了确定 mFasL 在青光眼发展中的功能，我们回交了 ? CS 敲入突变进入 DBA/2J 品系（D2.CS 小鼠），导致自发性眼内压 (IOP) 升高和 RGC 损失。我们的初步结果表明，mFasL 是青光眼发展过程中 RGC 凋亡的关键介质。此外，sFasL具有重要的神经保护作用，不仅可以防止RGC丢失，还可以保护高血压眼中的其他视网膜神经元。我们假设，为了应对眼压升高引起的损伤，视网膜内 Fas 和 FasL 的表达增加。然而，视网膜凋亡的程度是由小胶质细胞表达的膜/可溶性FasL的比率决定的。神经毒性小胶质细胞表达较高水平的 mFasL，而神经保护性小胶质细胞表达较高水平的 sFasL。该假设将在三个具体目标中进行检验：（目标 1）证明 D2 中 IOP 升高。？无法裂解 FasL 的 CS 小鼠会引发视网膜神经毒性增加。（目标 2）确定 D2 中的视网膜神经毒性是否增加。？ CS 小鼠是由于 mFasL 表达增加和/或 sFasL 缺乏所致。（目标 3）使用来自 D2 的永生化视网膜小胶质细胞的共培养系统确定体外小胶质细胞介导的神经毒性机制。？ CS 小鼠和原代 RGC。