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Inference of Chromosome-Length Haplotypes Using Genomic Data of Three or a Few More Single Gametes

Ruidong Li, Han Qu, Jinfeng Chen, Shibo Wang, John M. Chater, Le Zhang, Julong Wei, Yuan‐Ming Zhang, Chenwu Xu, Weide Zhong, Jianguo Zhu, Jianming Lü, Yuanfa Feng, Weiming Chen, Renyuan Ma, Sergio Ferrante, Mikeal L. Roose, Zhenyu Jia

2020Molecular Biology and Evolution21 citationsDOIOpen Access PDF

Abstract

Compared with genomic data of individual markers, haplotype data provide higher resolution for DNA variants, advancing our knowledge in genetics and evolution. Although many computational and experimental phasing methods have been developed for analyzing diploid genomes, it remains challenging to reconstruct chromosome-scale haplotypes at low cost, which constrains the utility of this valuable genetic resource. Gamete cells, the natural packaging of haploid complements, are ideal materials for phasing entire chromosomes because the majority of the haplotypic allele combinations has been preserved. Therefore, compared with the current diploid-based phasing methods, using haploid genomic data of single gametes may substantially reduce the complexity in inferring the donor's chromosomal haplotypes. In this study, we developed the first easy-to-use R package, Hapi, for inferring chromosome-length haplotypes of individual diploid genomes with only a few gametes. Hapi outperformed other phasing methods when analyzing both simulated and real single gamete cell sequencing data sets. The results also suggested that chromosome-scale haplotypes may be inferred by using as few as three gametes, which has pushed the boundary to its possible limit. The single gamete cell sequencing technology allied with the cost-effective Hapi method will make large-scale haplotype-based genetic studies feasible and affordable, promoting the use of haplotype data in a wide range of research.

Topics & Concepts

BiologyHaplotypePloidyGeneticsChromosomeGametePhaserGenomeHaplotype estimationComputational biologyAlleleGeneSpermOpticsPhysicsGenetic Mapping and Diversity in Plants and AnimalsEvolution and Genetic DynamicsGenetic and phenotypic traits in livestock