1. Identifying, understanding, and correcting technical artifacts on the sex chromosomes in next-generation sequencing data
- Author
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Timothy H. Webster, Whitney Whitford, Madeline Couse, Eric Karlins, Tanya N. Phung, Melissa A. Wilson Sayres, Bruno M. Grande, and Phillip A. Richmond
- Subjects
Male ,Population ,Aneuploidy ,Health Informatics ,Genomics ,Computational biology ,Biology ,Y chromosome ,Deep sequencing ,DNA sequencing ,X chromosome ,03 medical and health sciences ,Contig Mapping ,0302 clinical medicine ,Sequence Homology, Nucleic Acid ,medicine ,Technical Note ,genomics ,Humans ,aneuploidy ,mapping ,education ,Exome sequencing ,030304 developmental biology ,0303 health sciences ,education.field_of_study ,Chromosomes, Human, X ,Chromosomes, Human, Y ,variant calling ,ploidy ,High-Throughput Nucleotide Sequencing ,Sequence Analysis, DNA ,medicine.disease ,Computer Science Applications ,030220 oncology & carcinogenesis ,Female ,Artifacts ,Sequence Alignment ,Reference genome - Abstract
BackgroundMammalian X and Y chromosomes share a common evolutionary origin and retain regions of high sequence similarity. Similar sequence content can confound the mapping of short next-generation sequencing reads to a reference genome. It is therefore possible that the presence of both sex chromosomes in a reference genome can cause technical artifacts in genomic data and affect downstream analyses and applications. Understanding this problem is critical for medical genomics and population genomic inference.ResultsHere, we characterize how sequence homology can affect analyses on the sex chromosomes and present XYalign, a new tool that (1) facilitates the inference of sex chromosome complement from next-generation sequencing data; (2) corrects erroneous read mapping on the sex chromosomes; and (3) tabulates and visualizes important metrics for quality control such as mapping quality, sequencing depth, and allele balance. We find that sequence homology affects read mapping on the sex chromosomes and this has downstream effects on variant calling. However, we show that XYalign can correct mismapping, resulting in more accurate variant calling. We also show how metrics output by XYalign can be used to identify XX and XY individuals across diverse sequencing experiments, including low- and high-coverage whole-genome sequencing, and exome sequencing. Finally, we discuss how the flexibility of the XYalign framework can be leveraged for other uses including the identification of aneuploidy on the autosomes. XYalign is available open source under the GNU General Public License (version 3).ConclusionsSex chromsome sequence homology causes the mismapping of short reads, which in turn affects downstream analyses. XYalign provides a reproducible framework to correct mismapping and improve variant calling on the sex chromsomes.
- Published
- 2019