SVLearn: a dual-reference machine learning approach enables accurate cross-species genotyping of structural variants

SVLearn: a dual-reference machine learning approach enables accurate cross-species genotyping of structural variants

Abstract Structural variations (SVs) are diverse forms of genetic alterations and drive a wide range of human diseases. Accurately genotyping SVs, particularly occurring at repetitive genomic regions, from short-read sequencing data remains challenging. Here, we introduce SVLearn, a machine-learning...

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Main Authors: Qimeng Yang, Jianfeng Sun, Xinyu Wang, Jiong Wang, Quanzhong Liu, Jinlong Ru, Xin Zhang, Sizhe Wang, Ran Hao, Peipei Bian, Xuelei Dai, Mian Gong, Zhuangbiao Zhang, Ao Wang, Fengting Bai, Ran Li, Yudong Cai, Yu Jiang
Format: Article
Language:English
Published: Nature Portfolio 2025-03-01
Series:Nature Communications
Online Access:https://doi.org/10.1038/s41467-025-57756-z
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Summary:Abstract Structural variations (SVs) are diverse forms of genetic alterations and drive a wide range of human diseases. Accurately genotyping SVs, particularly occurring at repetitive genomic regions, from short-read sequencing data remains challenging. Here, we introduce SVLearn, a machine-learning approach for genotyping bi-allelic SVs. It exploits a dual-reference strategy to engineer a curated set of genomic, alignment, and genotyping features based on a reference genome in concert with an allele-based alternative genome. Using 38,613 human-derived SVs, we show that SVLearn significantly outperforms four state-of-the-art tools, with precision improvements of up to 15.61% for insertions and 13.75% for deletions in repetitive regions. On two additional sets of 121,435 cattle SVs and 113,042 sheep SVs, SVLearn demonstrates a strong generalizability to cross-species genotype SVs with a weighted genotype concordance score of up to 90%. Notably, SVLearn enables accurate genotyping of SVs at low sequencing coverage, which is comparable to the accuracy at 30× coverage. Our studies suggest that SVLearn can accelerate the understanding of associations between the genome-scale, high-quality genotyped SVs and diseases across multiple species.
ISSN:2041-1723

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