Back

Discover CALS

See how our current work and research is bringing new thinking and new solutions to some of today's biggest challenges.

|
By Vanessa Greenlee
Share
  • School of Integrative Plant Science
  • Plant Biology Section
  • Plant Breeding and Genetics Section
  • Genomics
  • Genetics
  • Food
  • Fish

Innovative genetic tools to speed the breeding of North American Atlantic salmon are being made available to breeders in the United States for the first time, with help from Breeding Insight, a new program funded by the U.S. Department of Agriculture (USDA) through Cornell.

North American Atlantic salmon are the primary marine finfish grown for aquaculture in the United States, representing nearly $88 million in economic activity. Until now, uniquely developed genomic resources for researching and breeding them were not publicly available, due to intellectual property constraints from competing commercial interests.

That’s about to change.

Breeding Insight recently assisted scientists from the USDA Agricultural Research Service (ARS) in the development of single nucleotide polymorphism (SNP) markers, which are important tools for breeders.

“SNP markers are like milestones on the highway,” said Yniv Palti, USDA ARS research geneticist and lead on the project. “These navigation points dramatically increase the speed at which breeders can select and introduce genes for traits that benefit fish farmers and consumers alike.”

The goal is to bring the power of predictive breeding to salmon breeders by enabling researchers to pinpoint sections of the genome associated with particular traits.

North American Atlantic salmon traits of interest range from sea lice and disease resistance to fillet color and composition of beneficial fatty acids. But designing the genomic resources required to accelerate breeding takes time, and ARS research groups must balance competing priorities to develop aquacultural technologies for breeders.

“By combining traditional breeding approaches with genomics and informatics, it is now possible to accurately predict some of the traits and performance of an individual long before it matures,” said Moira Sheehan, director of Breeding Insight. “But the challenges facing specialty species such as salmon too often hamper technology adoption and limit program efficiency. Our goal at Breeding Insight is to level the playing field and create new opportunities for specialty crop and animal breeders to take value out of the genomics era.”

Breeding Insight played a critical role in the salmon SNP marker project by providing expertise at the intersection of molecular biology and computing technology – a field more commonly known as bioinformatics.

“Bioinformatics is in such high demand. It’s the bottleneck for everything we do,” Palti said.

Early indications point to successful uptake of the SNP markers by the salmon breeding industry. Palti said a consortium organized through The Center for Aquaculture Technologies, a biotechnology company, has committed to processing 50,000 copies of the SNP set (assembled on microscope slide-sized chips) as part of a genotyping service it offers.

“Our primary goal is to generate resources that are being adopted by the aquaculture industry,” Palti said. “If breeders are adopting the technologies that we’re developing, and using them to deliver more healthy, nutritious and sustainable fish, then that’s where we are succeeding.”

A version of this story also appeared on the Breeding Insight website.

Vanessa Greenlee is communications and training lead for Breeding Insight.

This story first appeared in the Cornell Chronicle.

Keep Exploring

transposons

News

Eventually, these findings could lead to a reliable CRISPR-Cas system that allows scientists to insert larger cargoes of genetic information into cells with more precision than current techniques allow, with far-reaching implications for...
  • Molecular Biology and Genetics
  • Genomics
  • Biology
Two people exchanging money at a farmers market

News

Farmers markets and roadside stands are more successful in communities with more nonprofits, social enterprises and creative industries, according to a new study.
  • Charles H. Dyson School of Applied Economics and Management
  • Agriculture
  • Applied Economics