De Novo Assembly of the Goldfish () Genome and the Evolution of Genes After Whole-genome Duplication

Overview

Journal Sci Adv

Specialties Biology
Science

Date 2019 Jun 29

PMID 31249862

Citations 78

Authors

Zelin Chen

Yoshihiro Omori

Sergey Koren

Takuya Shirokiya

Takuo Kuroda

Atsushi Miyamoto

Hironori Wada

Asao Fujiyama

Atsushi Toyoda

Suiyuan Zhang

Tyra G Wolfsberg

Koichi Kawakami

Adam M Phillippy

James C Mullikin

Shawn M Burgess

Affiliations

Soon will be listed here.

Abstract

For over a thousand years, the common goldfish () was raised throughout Asia for food and as an ornamental pet. As a very close relative of the common carp (), goldfish share the recent genome duplication that occurred approximately 14 million years ago in their common ancestor. The combination of centuries of breeding and a wide array of interesting body morphologies provides an exciting opportunity to link genotype to phenotype and to understand the dynamics of genome evolution and speciation. We generated a high-quality draft sequence and gene annotations of a "Wakin" goldfish using 71X PacBio long reads. The two subgenomes in goldfish retained extensive synteny and collinearity between goldfish and zebrafish. However, genes were lost quickly after the carp whole-genome duplication, and the expression of 30% of the retained duplicated gene diverged substantially across seven tissues sampled. Loss of sequence identity and/or exons determined the divergence of the expression levels across all tissues, while loss of conserved noncoding elements determined expression variance between different tissues. This assembly provides an important resource for comparative genomics and understanding the causes of goldfish variants.

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