Genome-wide association and genomic prediction of growth traits in the European flat oyster (<i>Ostrea edulis</i>)

Peñaloza, Carolina; Barría, Agustín; Papadopoulou, Athina; Hooper, Chantelle; Preston, Joanne; Green, Matthew; Helmer, Luke; Hammerson, Jacob Kean; Schulze, Jennifer Nascimento; Minardi, Diana; Gundappa, Manu Kumar; Macqueen, Daniel J.; Hamilton, John; Houston, Ross D.; Bean, Tim P.

doi:10.1101/2022.06.10.495672

Cited by 1 publication

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“…In this regard, the genome reported here is proving useful already, with a recent study revealing that SNP markers previously associated with Bonamia resistance (Vera et al, 2019) are located in high linkage-disequilibrium across a large region of super-scaffold 8, which contains many candidate immune genes (Martinez et al 2022). Another recent study from has mapped variants genotyped with an existing medium density SNP array (Gutierrez et al, 2017) against our new O. edulis genome, identifying QTLs underpinning variation in growth traits on super-scaffold 4 (Peñaloza et al, 2022).…”

Section: Discussionmentioning

confidence: 99%

Chromosome level reference genome for European flat oyster (Ostrea edulis L.)

Gundappa

Peñaloza

Regan

et al. 2022

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The European flat oyster (Ostrea edulis L.) is a bivalve naturally distributed across Europe that was an integral part of human diets for centuries, until anthropogenic activities and disease outbreaks severely reduced wild populations. Despite a growing interest in genetic applications to support population management and aquaculture, a reference genome for this species is lacking to date. Here we report a chromosome-level assembly and annotation for the European Flat oyster genome, generated using Oxford Nanopore, Illumina, Dovetail OmniC™ proximity ligation and RNA sequencing. A contig assembly (N50: 2.38Mb) was scaffolded into the expected karyotype of 10 pseudo-chromosomes. The final assembly is 935.13 Mb, with a scaffold-N50 of 95.56 Mb, with a predicted repeat landscape dominated by unclassified elements specific to O. edulis. The assembly was verified for accuracy and completeness using multiple approaches, including a novel linkage map built with ddRAD-Seq technology, comprising 4,016 SNPs from four full-sib families (8 parents and 163 F1 offspring). Annotation of the genome integrating multi-tissue transcriptome data, comparative protein evidence and ab-initio gene prediction identified 35,699 protein-coding genes. Chromosome level synteny was demonstrated against multiple high-quality bivalve genome assemblies, including an O. edulis genome generated independently for a French O. edulis individual. Comparative genomics was used to characterize gene family expansions during Ostrea evolution that potentially facilitated adaptation. This new reference genome for European flat oyster will enable high-resolution genomics in support of conservation and aquaculture initiatives, and improves our understanding of bivalve genome evolution.

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Section: Discussionmentioning

confidence: 99%