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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Using Phased Whole Genome Sequence Data to Better Understand the Role of Compound-Heterozygous Variants in Pediatric Diseases

Miller, Dustin B. 14 July 2021 (has links)
A compound-heterozygous variant occurs when a child inherits a variant from each parent, with these variants occurring at a different position within the same gene and on opposite homologous chromosomes. These inherited variants may result in two nonfunctional versions of the same gene. Compound-heterozygous variants cannot be identified unless a patients' DNA sequence data is phased. Phasing is a computationally demanding process that requires the use of multiple software tools in order to determine which nucleotide was inherited from which parent. First, in Chapter 1, we review the literature to better understand what research has been conducted on the role of compound-heterozygous variants in pediatric cancers and what methods are being used to identify them. In Chapter 2, we develop a pipeline to make it easier for us and other researchers to phase and identify compound-heterozygous variants using VCF files from trios or individuals. We then use this pipeline in Chapter 3 to survey the prevalence of compound-heterozygous variants across 7 pediatric disease types. We show the importance of identifying compound heterozygous and what information would be missed if this variant type was not included in study design. In Chapter 4, we develop a software tool to phase trio data using a combination of Mendelian inheritance logic and an existing phasing software program. We show that our software tool increases the total number of variants that can be phased. Finally, in Chapter 5, we use phased data of three nuclear families, each family having one child with pediatric cancer, to evaluate the potential to use inherited genomic variants to inform diagnostic decisions. The work contained within this dissertation shows the importance of not overlooking compound-heterozygous variants when trying to identify potentially causal genes in pediatric disease. In addition, this work provides software tools that are openly available for other researchers to use; these tools make it easier to phase patient DNA sequence data and to identify compound-heterozygous variants.

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