Rescue of germ cells in dnd crispant embryos opens the possibility to produce inherited sterility in Atlantic salmon

Güralp, Hilal; Skaftnesmo, Kai Ove; Kjærner-Semb, Erik; Straume, Anne Hege; Kleppe, Lene; Schulz, Rüdiger; Edvardsen, Rolf B.; Wargelius, Anna

doi:10.1038/s41598-020-74876-2

Cited by 52 publications

(49 citation statements)

References 52 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This approach has successfully produced sterile embryos in various species including zebrafish ( Saito et al, 2008 ), masu salmon, rainbow trout ( Yoshizaki et al, 2016 ), Atlantic salmon ( Wargelius et al, 2016 ), sterlet ( A. ruthenus ; Linhartová et al, 2015 ), grass puffer ( Yoshikawa et al, 2020 ) and Chinese rosy bitterling ( Octavera and Yoshizaki, 2019 ). Furthermore, germ cells in dnd1 KO salmon could be rescued by co-injecting the salmon dnd1 mRNA together with Cas9/gRNA targeting dnd1 ( Güralp et al, 2020 ). This strategy would allow fertile surrogate broodstocks that produce sterile offspring.…”

Section: Surrogate Broodstock Technologymentioning

confidence: 99%

Surrogate broodstock to enhance biotechnology research and applications in aquaculture

Jin

Robledo

Hickey

et al. 2021

Biotechnology Advances

View full text Add to dashboard Cite

Aquaculture is playing an increasingly important role in meeting global demands for seafood, particularly in low and middle income countries. Genetic improvement of aquaculture species has major untapped potential to help achieve this, with selective breeding and genome editing offering exciting avenues to expedite this process. However, limitations to these breeding and editing approaches include long generation intervals of many fish species, alongside both technical and regulatory barriers to the application of genome editing in commercial production. Surrogate broodstock technology facilitates the production of donor-derived gametes in surrogate parents, and comprises transplantation of germ cells of donors into sterilised recipients. There are many successful examples of intra- and inter-species germ cell transfer and production of viable offspring in finfish, and this leads to new opportunities to address the aforementioned limitations. Firstly, surrogate broodstock technology raises the opportunity to improve genome editing via the use of cultured germ cells, to reduce mosaicism and potentially enable in vivo CRISPR screens in the progeny of surrogate parents. Secondly, the technology has pertinent applications in preservation of aquatic genetic resources, and in facilitating breeding of high-value species which are otherwise difficult to rear in captivity. Thirdly, it holds potential to drastically reduce the effective generation interval in aquaculture breeding programmes, expediting the rate of genetic gain. Finally, it provides new opportunities for dissemination of tailored, potentially genome edited, production animals of high genetic merit for farming. This review focuses on the state-of-the-art of surrogate broodstock technology, and discusses the next steps for its applications in research and production. The integration and synergy of genomics, genome editing, and reproductive technologies have exceptional potential to expedite genetic gain in aquaculture species in the coming decades.

show abstract

Section: Surrogate Broodstock Technologymentioning

confidence: 99%

Surrogate broodstock to enhance biotechnology research and applications in aquaculture

Jin

Robledo

Hickey

et al. 2021

Biotechnology Advances

View full text Add to dashboard Cite

show abstract

“…DNA was extracted from caudal fins using DNeasy Blood & Tissue kit (Qiagen). DNA extracted from the fin has previously been shown to be broadly representative for the whole fish 5,25 . A fragment covering the entire CRISPR target sites for slc45a2 and dnd1 was amplified with a two-step fusion PCR (as described in Gagnon et.al 2014) to prepare for Illumina MiSeq.…”

Section: Analysis Of Mutantsmentioning

confidence: 99%

“…Moreover, this could also be an advantage for aquaculture species in general (e.g trout, sea bass, tilapia). This technology offers an exciting opportunity to insert traits of interest into the recently demonstrated fertile but genetically sterile salmon 25 . This fish will produce sterile offspring and may therefore represent the future salmon aquaculture by combining sterility and other favorable traits induced by HDR, such as disease resistance.…”

Section: Fig 4: Variation In Indel Locationsmentioning

confidence: 99%

See 1 more Smart Citation

A refinement to gene editing in Atlantic salmon using asymmetrical oligonucleotide donors

Kjærner-Semb

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

Selective breeding programs in aquaculture are limited by the heritability of the trait and long generation time in most fish species. New breeding technology (NBT) using CRISPR/Cas9-induced homology directed repair (HDR) have the potential to expedite genetic improvement in aquaculture, but the method requires optimization. Here we show that asymmetrical oligonucleotide (ODN) donors induce highly efficient and precise edits in individual Atlantic salmon founder animals. We performed single nucleotide replacement (SNR) in dnd with up to 59.2% efficiency, and inserted FLAG elements into slc45a2 and dnd, with up to 36.7 % and 32.7% efficiency, respectively. We found HDR efficiency to be dependent on template concentration, but a trade-off with respect to toxicity was observed. Using this NBT in salmon we demonstrate that precise modification of the genome can be achieved in a single generation, allowing efficient introgression of favorable alleles and bypassing challenges associated with traditional selective breeding.

show abstract

“…The farming of sterile salmon has been proposed as a possible solution to minimize the impacts on wild populations and thus a way to make the salmon aquaculture industry more sustainable (Aarset et al 2020;Benfey 2016). Although there exist several different sterilization techniques (Güralp et al 2020), to date, the only commercially available method of producing sterile salmon is to triploidise newly fertilized eggs (Golpour et al 2016).…”

Section: Introductionmentioning

confidence: 99%

A comparison of triploid and diploid Atlantic salmon (Salmo salar) performance and welfare under commercial farming conditions in Norway

Madaro

Kjøglum

Hansen

et al. 2021

Journal of Applied Aquaculture

View full text Add to dashboard Cite

Avoiding genetic interactions between wild and farmed Atlantic salmon is regarded as one of the major requirements for a sustainable salmon aquaculture industry. For this reason, farming functional sterile triploids has been suggested as a possible solution. However, knowledge about how triploids cope under commercial conditions is lacking. In the present study, we compared the performance of diploid and triploid Atlantic salmon among four Norwegian aquaculture companies. Diploid and triploid groups of the same genetic line were farmed in western, mid, and northern Norway under commercial conditions from seawater transfer until slaughter.Overall, triploid salmon exhibited reduced survival, higher incidence of emaciated fish, and scored, on average, a lower quality rating during primary processing. The results highlight the need for further research on how to improve the welfare and performance of triploid salmon in commercial aquaculture operations.

show abstract

Rescue of germ cells in dnd crispant embryos opens the possibility to produce inherited sterility in Atlantic salmon

Cited by 52 publications

References 52 publications

Surrogate broodstock to enhance biotechnology research and applications in aquaculture

Surrogate broodstock to enhance biotechnology research and applications in aquaculture

A refinement to gene editing in Atlantic salmon using asymmetrical oligonucleotide donors

A comparison of triploid and diploid Atlantic salmon (Salmo salar) performance and welfare under commercial farming conditions in Norway

Contact Info

Product

Resources

About