@article{Bohaczuk01122024,
author = {Bohaczuk, Stephanie C. and Amador, Zachary J. and Li, Chang and Mallory, Benjamin J. and Swanson, Elliott G. and Ranchalis, Jane and Vollger, Mitchell R. and Munson, Katherine M. and Walsh, Tom and Hamm, Morgan O. and Mao, Yizi and Lieber, Andre and Stergachis, Andrew B.}, 
title = {Resolving the chromatin impact of mosaic variants with targeted Fiber-seq},
volume = {34}, 
number = {12}, 
pages = {2269-2278}, 
year = {2024}, 
doi = {10.1101/gr.279747.124}, 
abstract ={Accurately quantifying the functional consequences of noncoding mosaic variants requires the pairing of DNA sequences with both accessible and closed chromatin architectures along individual DNA molecules—a pairing that cannot be achieved using traditional fragmentation-based chromatin assays. We demonstrate that targeted single-molecule chromatin fiber sequencing (Fiber-seq) achieves this, permitting single-molecule, long-read genomic, and epigenomic profiling across targeted >100 kb loci with ∼10-fold enrichment over untargeted sequencing. Targeted Fiber-seq reveals that pathogenic expansions of the DMPK CTG repeat that underlie Myotonic Dystrophy 1 are characterized by somatic instability and disruption of multiple nearby regulatory elements, both of which are repeat length-dependent. Furthermore, we reveal that therapeutic adenine base editing of the segmentally duplicated γ-globin (HBG1/HBG2) promoters in primary human hematopoietic cells induced toward an erythroblast lineage increases the accessibility of the HBG1 promoter as well as neighboring regulatory elements. Overall, we find that these non–protein coding mosaic variants can have complex impacts on chromatin architectures, including extending beyond the regulatory element harboring the variant.}, 
URL = {http://genome.cshlp.org/content/34/12/2269.abstract}, 
eprint = {http://genome.cshlp.org/content/34/12/2269.full.pdf+html}, 
journal = {Genome Research} 
}