Genome-wide Definition of Selective Sweeps Reveals Molecular Evidence of Trait-driven Domestication Among Elite Goat (Capra Species) Breeds for the Production of Dairy, Cashmere, and Meat

Overview

Journal Gigascience

Publisher Oxford University Press

Specialties Biology
Genetics

Date 2018 Aug 31

PMID 30165633

Citations 22

Authors

Bao Zhang

Liao Chang

Xianyong Lan

Nadeem Asif

Fanglin Guan

DongKe Fu

Bo Li

Chunxia Yan

Hongbo Zhang

Xiaoyan Zhang

Yongzhen Huang

Hong Chen

Jun Yu

Shengbin Li

Affiliations

Soon will be listed here.

Abstract

Background: The domestication of wild goats and subsequent intensive trait-driven crossing, inbreeding, and selection have led to dramatic phenotypic purification and intermediate breeds for the high-quality production of dairy, cashmere wool, and meat. Genomic resequencing provides a powerful means for the direct identification of trait-associated sequence variations that underlie molecular mechanisms of domestication.

Results: Here, we report our effort to define such variations based on data from domestic goat breeds (Capra aegagrus hircus; five each) selected for dairy, cashmere, and meat production in reference to their wild ancestors, the Sindh ibex (Capra aegagrus blythi; two) and the Markhor (Capra falconeri; two). Using ∼24 million high-quality single nucleotide polymorphisms (SNPs), ∼1.9 million insertions/deletions, and 2,317 copy number variations, we define SNP-desert-associated genes (SAGs), domestic-associated genes (DAGs), and trait-associated genes (TAGs) and attempt to associate them with quantitative trait loci (QTL), domestication, and agronomic traits. A greater majority of SAGs shared by all domestic breeds are classified into Gene Ontology categories of metabolism and cell cycle. DAGs, together with some SAGs, are most relevant to behavior, immunity, and trait specificity. Whereas, TAGs such as growth differentiation factor 5 and fibroblast growth factor 5 for bone and hair growth, respectively, appear to be directly involved in growth regulation.

Conclusions: When investigating the divergence of Capra populations, the sequence variations and candidate function-associated genes we have identified provide valuable molecular markers for trait-driven genetic mapping and breeding.

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