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Genetic Analysis of Organ Patterning Defects in Ciliopathies

纤毛病器官模式缺陷的遗传分析

基本信息

批准号：
10011885
负责人：
ZHAOXIA SUN
金额：
$ 39.12万
依托单位：
YALE UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2018
资助国家：
美国
起止时间：
2018-09-01 至 2023-08-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10011885
关键词：
Affect Alleles Animal Model Animals Biology Birth CRISPR/Cas technology Cardiovascular system Cells Characteristics Chromosome 4 Cilia Complex Coupled Cyst Defect Development Diagnosis Diagnostic Disease Etiology Event Future Gait Gene Expression Profiling Genes Genetic Genetic Techniques Genome Health High-Throughput Nucleotide Sequencing Histologic Human Human Development Image Incidence Individual Infertility Kidney Length Light Link Live Birth Longitudinal Studies Lung Male Sterility Maps Mediating Mental Retardation Modeling Modification Mus Mutant Strains Mice Mutation Neonatal Nonsense Mutation Obesity Organ Organelles Organogenesis Other Genetics Pathology Pathway Analysis Patients Pattern Perinatal mortality demographics Phenocopy Phenotype Play Polydactyly Proteins Proteomics Regulation Role Set protein Severities Shapes Signal Pathway Signal Transduction Situs Inversus Stains Sterility Syndrome System Targeted Resequencing Testing Therapeutic Tissues VATER (vertebral defects-anal atresia-tracheoesophageal fistula-esophageal atresia-radial and renal dysplasia) association or syndrome base cell motility cell type ciliopathy cilium biogenesis craniofacial defined contribution experimental study genetic analysis genetic variant genomic locus human disease insight microCT microscopic imaging mutant novel skeletal trafficking vertebrate embryos

项目摘要

Abstract: Ciliopathies are an expanding group of human disorders whose cellular basis can be traced to defects in the formation or function of small, cellular organelles called cilia. Cilia are found on almost every cell type in the vertebrate body and thus ciliopathies can encompass defects in multiple organs and tissues. Strikingly, ciliopathies span a spectrum, ranging from infertility to neonatal lethality but the genetics underlying these divergent phenotypes are poorly understood. Defining the genes and genetic interactions that regulate cilia function is essential to understanding the etiology of these diseases as well as for developing future therapies. We have developed mice carrying a spontaneous mutation (hop) in the Ift56 gene into a new model for defining the genetic control of ciliopathy severity. Ift56 is a highly conserved cilia-localized protein that is required for cilia function in several model organisms. We recently discovered that while the Ift56hop phenotype is viable and mild on the Balb mouse background, it is lethal on the B6 background. The phenotype of the hop-B6 mutant models VACTERL Association in humans and overlaps with the Ift27 mutant ciliopathy phenotype. Our objectives are to 1) utilize the hop-B6 mutant as a means to understand VACTERL disorders, 2) define the function of Ift56 in mammalian cilia, and 3) isolate genetic loci that interact with the Ift56 mutation in order to elucidate the genetic landscape underlying ciliopathies. Our First Aim focuses on analyzing the tissue defects in Ift56-B6 mutants. Histological approaches coupled with gene expression analysis and microCT imaging will provide key insight into signaling and developmental patterning events controlled by Ift56 and the VACTERL-associated defects in hop-B6 mutants Aim2 explores the ciliary roles of Ift56, and how these are altered in the B6 and Balb backgrounds. Using candidate and proteomic approaches, we will determine the set of proteins that require Ift56 function for their localization and trafficking within cilia. Finally, we test the requirement of Ift56 for IFTB complex integrity. In our Third Aim we map, isolate and validate modifiers of the hop phenotype in the B6 and Balb backgrounds. We will also examine genetic interactions between Ift27 and hop mutants as well as the effects of the Balb modifier background on the Ift27 phenotype. These experiments will identify key genetic modifiers of ciliopathy severity and provide new targets for resequencing in ciliopathy patients. Together, the proposed studies will uncover the conserved functions of Ift56, a key cilia protein, by defining how Ift56 regulates cilia and organogenesis. More broadly, these studies have the opportunity to uncover unique insights into how genetic variants across the genome modify ciliopathy severity. Results from this study will shed key and novel insights into cilia biology and ciliopathies, and lay the groundwork for future diagnostic and therapeutic strategies.

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