Genome and Population Sequencing of a Chromosome-level Genome Assembly of the Chinese Tapertail Anchovy (Coilia Nasus) Provides Novel Insights into Migratory Adaptation

Overview

Journal Gigascience

Publisher Oxford University Press

Specialties Biology
Genetics

Date 2020 Jan 3

PMID 31895412

Citations 11

Authors

Gangchun Xu

Chao Bian

Zhijuan Nie

Jia Li

Yuyu Wang

Dongpo Xu

Xinxin You

Hongbo Liu

Jiancao Gao

Hongxia Li

Kai Liu

Jian Yang

Quanjie Li

Nailin Shao

Yanbing Zhuang

Dian Fang

Tao Jiang

Yunyun Lv

Yu Huang

Ruobo Gu

Junmin Xu

Wei Ge

Qiong Shi

Pao Xu

Affiliations

Soon will be listed here.

Abstract

Background: Seasonal migration is one of the most spectacular events in nature; however, the molecular mechanisms related to this phenomenon have not been investigated in detail. The Chinese tapertail, or Japanese grenadier anchovy, Coilia nasus, is a valuable migratory fish of high economic importance and special migratory dimorphism (with certain individuals as non-migratory residents).

Results: In this study, an 870.0-Mb high-quality genome was assembled by the combination of Illumina and Pacific Biosciences sequencing. Approximately 812.1 Mb of scaffolds were linked to 24 chromosomes using a high-density genetic map from a family of 104 full siblings and their parents. In addition, population sequencing of 96 representative individuals from diverse areas along the putative migration path identified 150 candidate genes, which are mainly enriched in 3 Ca2+-related pathways. Based on integrative genomic and transcriptomic analyses, we determined that the 3 Ca2+-related pathways are critical for promotion of migratory adaption. A large number of molecular markers were also identified, which distinguished migratory individuals and non-migratory freshwater residents.

Conclusions: We assembled a chromosome-level genome for the Chinese tapertail anchovy. The genome provided a valuable genetic resource for understanding of migratory adaption and population genetics and will benefit the aquaculture and management of this economically important fish.

Citing Articles

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Phased chromosome-level genome provides insights into the molecular adaptation for migratory lifestyle and population diversity for Pacific saury, Cololabis saira.

Liu Y, Luo Y, Wang P, Li W, Tian H, Cao C Commun Biol. 2024; 7(1):1513.

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Decoding the fish genome opens a new era in important trait research and molecular breeding in China.

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Yu Y, Wan S, Huang C, Zhang S, Sun A, Liu J Zool Res. 2024; 45(3):491-505.

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