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Inflammatory Gene Transcription in the Retina

视网膜中的炎症基因转录

基本信息

批准号：
10077560
负责人：
ALEXANDER G BASSUK
金额：
$ 38.15万
依托单位：
STANFORD UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2020
资助国家：
美国
起止时间：
2020-01-01 至 2024-12-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10077560
关键词：
Affect Age Amino Acids Animals Automobile Driving Binding Biochemical Biological Assay Blindness C-terminal Calcium Calpain Cell Death Cell Fractionation Cell Nucleus Cells Cleaved cell Cyclic Peptides Cytoplasm DNA Data Disease Excision Extracellular Space Eye Eye diseases Fibrosis Gene Expression Genes Genetic Genetic Transcription Goals Histology Hyperactivity In Vitro Inflammation Inflammatory Inherited Injections Interleukin-6 Knockout Mice Knowledge Legal Blindness Mass Spectrum Analysis Modeling Molecular Molecular Genetics Mus Mutation N-terminal Nuclear Ocular Physiology Pathway interactions Peptide Hydrolases Peptides Pharmacology Phenocopy Phenotype Physiological Prevalence Proteins Reporter Research Resistance Retina Role Severities Site Testing Therapeutic Intervention Uveitis Work base cytokine experimental study functional genomics genetic approach in vivo inhibitor/antagonist innovation insight legal cases mouse model mutant neovascular new therapeutic target novel novel therapeutics promoter targeted treatment therapeutic target transcription factor

项目摘要

Project Summary Uveitis is a difficult-to-treat inflammatory eye disorder. Treatment options for uveitis are limited by an incomplete understanding of molecular causes of the disease. This proposal builds on our exciting discovery that Autosomal Dominant Neovascular Inflammatory Vitreoretinopathy (ADNIV), an inherited uveitis, is caused by mutations to the gene CAPN5. The CAPN5 gene produces the Calpain-5 (CAPN5) protease, which cleaves off regions of other proteins to regulate their functions. Our data show that CAPN5 becomes hyperactive in ADNIV. We identified Iroquois-3 (IRX3) as a new cleavage target of CAPN5 in the retina. IRX3 is a potent transcription factor implicated in inflammatory disease states. Identification of CAPN5 uveitis and a new CAPN5 target make possible a highly innovative molecular-genetic approach to identifying factors responsible for uveitis. The long-term goal of our research is to identify new therapeutic targets for the treatment of uveitis. This proposal’s objective is to determine the role of IRX3 cleavage in ADNIV. Our central hypothesis is that hyperactive ADNIV CAPN5 hyper-cleaves regulatory domains from IRX3, over-activating IRX3 transcriptional activity at inflammatory genes and driving destructive inflammation in ADNIV. Our rationale is that by studying the newly-identified CAPN5-IRX3 pathway, we will identify new disease mechanisms and therapeutic targets. Our data indicate that CAPN5 cleaves IRX3 toward its C-terminus. Additionally, we generated peptide substrates and a potential inhibitor compound for CAPN5 based on IRX3. Our data also show that IRX3 regulates a subset of ADNIV inflammatory genes in vitro. When comparing wild-type IRX3 to CAPN5-cleaved (“cut”) IRX3, our assays found that cut-IRX3 shows greater nuclear localization and increased binding to the IL- 6 promoter (a key ADNIV inflammatory gene). Our specific aims are to use biochemical, molecular, and physiologic studies in cells and animals to test the hypotheses that: (1) CAPN5 targets a specific domain on IRX3 for cleavage and physical interaction which can be isolated and developed into peptide substrates; (2) CAPN5 cleavage of IRX3 increases IRX3 nuclear localization and activity, contributing to uveitis in mice; and (3) Irx3-null mice will show resistance to developing ADNIV and intraocular inflammation phenotypes. We expect this work to have a significant positive impact on identifying new molecular mechanisms for therapeutic intervention in uveitis. At the completion of this project, we expect to have: (1) Isolated the IRX3 cleavage site and developed peptide substrates and potential inhibitor compounds; (2) Determined the consequences of CAPN5 cleavage on IRX3, identifying new molecular pathways which might be targeted therapeutically; and (3) Determined the significance of the Irx3 pathway in intraocular inflammation. As ADNIV mimics other eye diseases, our work promises to have a broad impact beyond ADNIV and uveitis.

项目摘要葡萄膜炎是一种难以治疗的炎症性眼部疾病。葡萄膜炎的治疗选择受到对疾病的分子原因的不完全理解。这个提议建立在我们激动人心的发现上常染色体显性遗传性新生血管炎性玻璃体视网膜病变（ADNIV）是一种遗传性葡萄膜炎，是由CAPN 5基因突变引起的。CAPN 5基因产生Calpain-5（CAPN 5）蛋白酶，该蛋白酶切割关闭其他蛋白质的区域来调节它们的功能。我们的数据显示，CAPN 5在 ADNIV.我们鉴定Iroquois-3（IRX 3）为视网膜中CAPN 5的新切割靶标。IRX 3是一种有效的转录因子参与炎症性疾病状态。CAPN 5葡萄膜炎的鉴定和一种新的 CAPN 5靶点使高度创新的分子遗传学方法成为可能，以确定相关因素治疗葡萄膜炎我们研究的长期目标是确定治疗葡萄膜炎的新的治疗靶点。该提案的目的是确定IRX 3切割在ADNIV中的作用。我们的核心假设是，超活性ADNIV CAPN 5超切割IRX 3的调节结构域，过度激活IRX 3转录在ADNIV中，炎症基因的活性和驱动破坏性炎症。我们的理论是通过研究新发现的CAPN 5-IRX 3通路，我们将确定新的疾病机制和治疗靶点。我们的数据表明CAPN 5将IRX 3向其C末端切割。此外，我们还生成了底物和基于IRX 3的CAPN 5的潜在抑制剂化合物。我们的数据还表明，IRX 3 在体外调节ADNIV炎性基因的子集。当比较野生型IRX 3与CAPN 5切割的对于切割的IRX 3，我们的测定发现切割的IRX 3显示出更大的核定位和增加的与IL-10的结合。 6启动子（一个关键的ADNIV炎性基因）。我们的具体目标是利用生物化学，分子，在细胞和动物中的生理学研究以测试以下假设：（1）CAPN 5靶向细胞上的特定结构域。用于切割和物理相互作用的IRX 3，其可以被分离并开发成肽底物;（2） IRX 3的CAPN 5切割增加IRX 3核定位和活性，导致小鼠的葡萄膜炎;和 (3)Irx 3缺失小鼠将显示出对发展中的ADNIV和眼内炎症表型的抗性。我们希望这项工作对确定新的分子机制产生重大的积极影响，葡萄膜炎的治疗干预。在本项目完成后，我们期望：（1）隔离IRX 3 切割位点和开发的肽底物和潜在的抑制剂化合物;（2）确定了 CAPN 5切割IRX 3的后果，确定可能靶向的新分子途径（3）确定Irx 3通路在眼内炎症中的意义。作为ADNIV 类似于其他眼部疾病，我们的工作有望产生广泛的影响，超越ADNIV和葡萄膜炎。