Genome-wide variation in human germline and postzygotic mutation rates
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Abstract
De novo mutations (DNMs) are new variants that arise in the parental germline or early
embryo. In this dissertation, I apply long-read sequencing technology to quads and a multi
generational pedigree to discover DNMs across the genome and quantify the de novo mutation
rate. First, I demonstrate that long reads enable DNM discovery in previously inaccessible
regions of the genome. These newly accessible regions, largely marked by repetitive sequence,
have a significantly higher mutation rate than their unique counterparts, including an approx
imately 66% enrichment in segmental duplications. I was able to trace the origins of DNMs
to either the parental germline or early rounds of embryogenesis, revealing that at least 15%
of single nucleotide DNMs arise postzygotically, a 50% increase from earlier studies. Further,
I found that 60% of postzygotic mutations are transmitted to the next generation, mean
ing that they contribute to segregating variation in the population. Finally, I estimate the
de novo mutation rate to be approximately 1.2-1.3×10-8 substitutions/base pair/generation
for 30 year old parents, and the postzygotic mutation rate to be approximately 0.23×10-8
substitutions/base pair/generation. My analyses reveal that repetitive regions are in fact
hypermutable, and that more variation arises postzygotically than previously thought. This
work also lays the foundation for the next frontier in DNM discovery: comparing assembled
parent and child genomes to reveal variation in the most complex and mutable parts of the
genome.
Description
Thesis (Ph.D.)--University of Washington, 2024
