Genetic diversity patterns in farmed rainbow trout (Oncorhynchus mykiss) populations using genome-wide SNP and haplotype data

IF 1.8 3区生物学 Q2 AGRICULTURE, DAIRY & ANIMAL SCIENCE

Animal genetics Pub Date : 2023-11-23 DOI:10.1111/age.13378

Alessio Longo, Khrystyna Kurta, Tytti Vanhala, Henrik Jeuthe, Dirk-Jan de Koning, Christos Palaiokostas

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Abstract

Rainbow trout is one of the most popular aquaculture species worldwide, with a long history of domestication. However, limited information exists about the genetic diversity of farmed rainbow trout populations globally, with most available reports relying on low-throughput genotyping technologies. Notably, no information exists about the genetic diversity status of farmed rainbow trout in Sweden. Double-digest restriction-site-associated DNA sequencing was performed on more than 500 broodfish from two leading producers in Sweden and from the country's national breeding program. Following the detection of single nucleotide polymorphisms (SNPs), genetic diversity was studied by using either individual SNPs (n = 8680; one SNP retained per 300 bp sequence reads) or through SNP haplotypes (n = 20 558; all SNPs retained in 300 bp sequence reads). Similar amounts of genetic diversity were found amongst the three populations when individual SNPs were used. Furthermore, principal component analysis and discriminant analysis of principal components suggested two genetic clusters with the two industry populations grouped together. Genetic differentiation based on the F_ST fixation index was ~0.01 between the industry populations and ~0.05 when those were compared with the breeding program. Preliminary estimates of effective population size (N_e) and inbreeding (based on runs of homozygosity; F_ROH) were similar amongst the three populations (N_e ≈ 50–80; median F_ROH ≈ 0.11). Finally, the haplotype-based analysis suggested that animals from the breeding program had higher shared coancestry levels than those from the other two populations. Overall, our study provides novel insights into the genetic diversity and structure of Sweden's three main farmed rainbow trout populations, which could guide their future management.

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利用全基因组SNP和单倍型数据研究养殖虹鳟鱼群体的遗传多样性模式。

虹鳟鱼是世界上最受欢迎的水产养殖品种之一，具有悠久的驯化历史。然而，关于全球养殖虹鳟鱼种群遗传多样性的信息有限，大多数现有报告依赖于低通量基因分型技术。值得注意的是，没有关于瑞典养殖虹鳟鱼遗传多样性状况的信息。对来自瑞典两家主要生产商和该国国家育种计划的500多条亲鱼进行了双消化限制性位点相关DNA测序。在单核苷酸多态性(SNPs)检测之后，利用单个SNPs (n = 8680;每300 bp序列读取保留一个SNP)或通过SNP单倍型(n = 20558;所有SNPs保留在300 bp序列中)。当使用单个snp时，在三个种群中发现了相似数量的遗传多样性。主成分分析和判别分析表明，两个产业群体聚在一起，形成了两个遗传集群。产业群体间以FST固定指数为基础的遗传分化为~0.01，与育种方案比较的遗传分化为~0.05。有效种群大小(Ne)和近交的初步估计(基于纯合子的运行);3个种群间的净净比值(Ne≈50 ~ 80;中位FROH≈0.11)。最后，基于单倍型的分析表明，来自育种计划的动物比来自其他两个种群的动物具有更高的共同祖先水平。总的来说，我们的研究为瑞典三个主要养殖虹鳟鱼种群的遗传多样性和结构提供了新的见解，这可以指导他们未来的管理。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Animal genetics 生物-奶制品与动物科学

CiteScore

4.60

自引率

4.20%

发文量

115

审稿时长

5 months

期刊介绍： Animal Genetics reports frontline research on immunogenetics, molecular genetics and functional genomics of economically important and domesticated animals. Publications include the study of variability at gene and protein levels, mapping of genes, traits and QTLs, associations between genes and traits, genetic diversity, and characterization of gene or protein expression and control related to phenotypic or genetic variation. The journal publishes full-length articles, short communications and brief notes, as well as commissioned and submitted mini-reviews on issues of interest to Animal Genetics readers.