Genetic Disease Clinical Trial
Official title:
Studies of Structural Chromosome Rearrangements to Identify Genes Involved in Congenital Brain Disorders
The project is focused on the detailed study of structural genomic variants (SVs). Such genetic mutations are in fact alterations in the DNA molecule structure and include copy number variants, inversions and translocations. A single event may affect many genes as well as regulatory regions and the specific phenotypic consequences will depend on the location, genetic content and type of SV. Many times, the specific disease-causing mechanism is not known. Here, we plan to study the molecular genetic behavior of structural variants as well as the underlying mutational mechanisms involved. First, we will use genome sequencing to pinpoint the chromosomal breakpoints at the nucleotide level, characterize the genomic architecture at the breakpoints and study the relationship between structural variants and SNVs. Second, we will study how structural variants impact gene expression. Finally, we will functionally explore the disease mechanisms in vivo using zebrafish and in vitro using primary patient cells and induced pluripotent stem cells. Our studies will focus on the origin, structure and impact of structural variation on human disease. The results will directly lead to a higher mutation detection rate in genetic diagnostics. Through a better understanding of disease mechanisms our findings will also assist in the development of novel biomarkers and therapeutic strategies for patients with rare genetic disorders.
PROJECT DESCRIPTION Aim 1) What are the molecular mechanisms of formation for structural genomic variants? We already have WGS data from more than 500 individual SVs. To understand underlying mutational and disease mechanisms, we will combine structural variant detection with positional information for the rearrangement. This will be particularly important for duplications (the location of the duplicated genomic segment is key to a correct clinical interpretation) and for complex rearrangements. Second, the exact breakpoint will be established and breakpoint junctions analyzed for sequence motifs. Aim 2) What are the molecular mechanisms involved in disease pathology? First we will use WGS to identify and characterize structural variants. Next, to understand how the candidate disease gene(s) affected by the SVs cause clinical symptoms, we will study the cellular mechanisms involved in disease pathology in three ways: Part 1. In vitro studies of primary cells: Effects on expression and splicing, will be evaluated in patient cells (fibroblasts or B cell lines) with RT-PCR, qPCR and Western blot. Part 2. In vitro studies in patient-derived models: In selected cases, we will generate induced-pluripotent stem cells and neural progenitor cells (NES cells), which will provide an opportunity to directly study the effects of early neurogenesis in cells from the patient and compare to cells derived from normal controls. We are interested in studying both early neurogenesis in 2D culture using the NES cells, as well as generating another developmentally relevant model, brain organoids (mini brains), in 3D culture directly from iPS cell lines. Organoid 3D culture recapitulates development of various brain regions and is therefore a unique tool to investigate brain disorders. Furthermore, the 3D neural culture could improve cell maturity and stimulate expression of disease phenotypes that facilitate better understanding the disease mechanisms. Part 3. In vivo studies in a zebrafish model: Zebrafish (Danio rerio) is a well-functioning in vivo system for studies of normal and abnormal embryological development. Duplications are simulated by RNA overexpression and deletion through CRISPR/Cas9 induced gene disruption or morpholino knock down. Assessment of the phenotypes is designed in accordance with the those observed in patients (e.g. head size, craniofacial defects, cardiovascular malformations, cilia defects). Aim 3) How does structural genomic variants impact gene expression? We plan to study long range effects in three ways. Part 1. To assess the clinical impact of TAD disruptions we will search for such events in the CNV data from the Clinical Genetics array database (data from over 6200 children with rare NDDs), LocusDB SV (SV calls from >1000 patients with rare diseases analyzed by WGS at Clinical Genomics SciLifeLab) and publicly available databases (DECIPHER, ICCG and SWEGEN). The Bioinformatic analysis will combine information on phenotypic overlap between known-disease genes surrounding the SV and the patients' characteristics, as well as on physical overlap with tissue-specific enhancers and TAD regions. Novel computational approaches will be designed for the discovery of genes disrupted by similar mechanisms. Follow-up studies will involve further patient characterization and customized RNA studies. Part 2. Transcriptome analysis of patient samples is done by RNA-seq. Since not every gene is transcriptionally active in every cell, a key to successfully achieving this aim is access to biologically relevant samples. Often biopsies are not available therefore, in those cases, iPS cells are an alternative way to study biologically relevant effects on RNA expression. In cases with paired WGS and RNA-seq data, we will integrate changes in transcription levels and ASE as a readout for the SVs effect on neighboring genes. Part 3. Cell and animal studies: Introduction of specific SVs with CRISPR/Cas9 in human cell lines will be done when the primary cells are unavailable and zebrafish lines created under goal 2 may also be used to evaluate global effects of SVs on an organism level. ;
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