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Main Authors: Moosman, Owen W, Kelley, Joanna L, Bogan, Samuel N
Format: Artículo científico
Language:en
Published: Heredity 2026
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/41168433/
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author Moosman, Owen W
Kelley, Joanna L
Bogan, Samuel N
author_facet Moosman, Owen W
Kelley, Joanna L
Bogan, Samuel N
Moosman, Owen W
Kelley, Joanna L
Bogan, Samuel N
collection PubMed - marine biology
contents Mitigating assembly and switch errors in phased genomes of polar fishes reveals haplotype diversity in copy number of antifreeze protein genes. Moosman, Owen W Kelley, Joanna L Bogan, Samuel N Animals Haplotypes DNA Copy Number Variations Genome Fishes Antifreeze Proteins Genetic Variation Phased genomes and pangenomes are enhancing our understanding of genetic variation. Accurate phasing and assembly in repetitive regions of the genome remain challenging, however. Addressing this obstacle is crucial for studying structural genomic variation, such as copy number variations (CNVs) common to repetitive regions. Polar fishes, for example, evolved repetitive tandem arrays of antifreeze protein (AFP) genes that facilitate adaptation to freezing and expanded in copy number in colder environments. AFP CNVs remain poorly characterized in polar fishes and may be illuminated by haplotype-aware approaches. We performed long-read sequencing for two polar fishes in the suborder Zoarcoidei and leveraged additional published long-read data to assemble phased genomes. We developed a workflow to measure haplotype diversity in CNV while controlling for misassembly and switch errors-a change from one parental haplotype to another in a contiguous assembly. We present gfa_parser, which computes and extracts all possible contiguous sequences for phased or primary assemblies from graphical fragment assembly (GFA) files, and switch_error_screen, which flags potential switch errors. gfa_parser revealed that assembly uncertainty was ubiquitous across AFP array haplotypes and that standard processing of graphical fragment assemblies can bias measurement of haplotype CNVs. We detected no switch errors in AFP arrays. After controlling for misassembly and switch error, we detected haplotype diversity of AFP CNVs in all studied polar Zoarcoidei species and in 60% of AFP arrays. Intraindividual haplotype diversity spanned differences of 3-16 copies. Our workflow revealed intraspecific genomic diversity in zoarcoids that likely fueled the evolution of AFP copy number across temperature.
format Artículo científico
id pubmed_41168433
institution PubMed
language en
publishDate 2026
publisher Heredity
record_format pubmed
spellingShingle Mitigating assembly and switch errors in phased genomes of polar fishes reveals haplotype diversity in copy number of antifreeze protein genes.
Moosman, Owen W
Kelley, Joanna L
Bogan, Samuel N
Animals
Haplotypes
DNA Copy Number Variations
Genome
Fishes
Antifreeze Proteins
Genetic Variation
Mitigating assembly and switch errors in phased genomes of polar fishes reveals haplotype diversity in copy number of antifreeze protein genes. Moosman, Owen W Kelley, Joanna L Bogan, Samuel N Animals Haplotypes DNA Copy Number Variations Genome Fishes Antifreeze Proteins Genetic Variation Phased genomes and pangenomes are enhancing our understanding of genetic variation. Accurate phasing and assembly in repetitive regions of the genome remain challenging, however. Addressing this obstacle is crucial for studying structural genomic variation, such as copy number variations (CNVs) common to repetitive regions. Polar fishes, for example, evolved repetitive tandem arrays of antifreeze protein (AFP) genes that facilitate adaptation to freezing and expanded in copy number in colder environments. AFP CNVs remain poorly characterized in polar fishes and may be illuminated by haplotype-aware approaches. We performed long-read sequencing for two polar fishes in the suborder Zoarcoidei and leveraged additional published long-read data to assemble phased genomes. We developed a workflow to measure haplotype diversity in CNV while controlling for misassembly and switch errors-a change from one parental haplotype to another in a contiguous assembly. We present gfa_parser, which computes and extracts all possible contiguous sequences for phased or primary assemblies from graphical fragment assembly (GFA) files, and switch_error_screen, which flags potential switch errors. gfa_parser revealed that assembly uncertainty was ubiquitous across AFP array haplotypes and that standard processing of graphical fragment assemblies can bias measurement of haplotype CNVs. We detected no switch errors in AFP arrays. After controlling for misassembly and switch error, we detected haplotype diversity of AFP CNVs in all studied polar Zoarcoidei species and in 60% of AFP arrays. Intraindividual haplotype diversity spanned differences of 3-16 copies. Our workflow revealed intraspecific genomic diversity in zoarcoids that likely fueled the evolution of AFP copy number across temperature.
title Mitigating assembly and switch errors in phased genomes of polar fishes reveals haplotype diversity in copy number of antifreeze protein genes.
topic Animals
Haplotypes
DNA Copy Number Variations
Genome
Fishes
Antifreeze Proteins
Genetic Variation
url https://pubmed.ncbi.nlm.nih.gov/41168433/