Historic Genome Sequencing Will Unlock Potential for Agriculture, Conservation

Rachel O’Neill, director of UConn’s Institute for Systems Genomics, and her lab are contributing to a groundbreaking new ruminant genome sequencing effort

Two cows on a grassy meadow

Cows on Horsebarn Hill. Sept. 3, 2022. (Sean Flynn/UConn Photo)

A multi-institutional, international effort known as the Ruminant Telomere-to-Telomere consortium, or RT2T, is aiming to make scientific history by publishing the complete genomes of over 300 species of ruminant animals, ranging from narwhals to dairy cows. 

This initiative builds on other recent T2T consortium successes, such as the June 2024 publication of the complete sequencing of six ape species genomes and the August 2023 publication of the first-ever complete human Y chromosome sequence. 

At UConn, Rachel O’Neill, director of the Institute for Systems Genomics, Board of Trustees Distinguished Professor of molecular and cell biology, and John and Donna Krenicki Professor in Genomics and Personalized Healthcare, has had a hand in all these victories. 

For the RT2T, O’Neill explains, “My lab is generating some of the data, and we’re doing quite a bit of biobanking of cell lines – establishing cell lines for many of the endangered or critically endangered species, where there isn’t a repository that exists already.” 

The O’Neill lab will also be responsible for performing the repeat analysis – detangling and decoding many thousands of repeated, short sequences of DNA – for each species. 

“That’s kind of a giant task, because the largest amount we’ve ever done before is what we just completed for the primates – six species,” O’Neill says. 

Historically, studying ruminant animal genetics has been challenging due to missing, incomplete and/or fragmented reference genome sequences. The RT2T project aims to use cutting-edge sequencing technologies and collaborative expertise to eliminate many of these barriers.

In Nature Genetics, the T2T team describes how they will leverage advanced sequencing technologies to analyze the genomes of ruminant species. These methods provide a comprehensive view of the genome, including previously hard-to-sequence chromosomal regions like centromeres and telomeres, creating complete genetic blueprints of these animals.

Without those genetic blueprints, O’Neill explains, “conservation management strategies become impossible; understanding genome biology becomes impossible, because we’re literally blind. It’s like having a book with every third word cut out randomly and having to decipher its meaning.” 

Scientists worldwide can access data from the RT2T to conduct further studies, multiplying the project’s potential impact on agriculture and conservation efforts.

The Future of Genomic Research in Agriculture

For livestock ruminants (sheep and cattle), genomic research can help enable more efficient dairy and meat production and help reduce the risk of infectious diseases spreading from livestock to humans. 

This “dovetails quite well” with UConn’s strengths in research agriculture, according to O’Neill. 

“It’s quite fortuitous that this is happening,” she says. “I’ve collaborated with several labs over the past 10 to 15 years where Ph.D. students were desperate for a good genome assembly, and it’s refreshing to be able to say one is really coming and to invite those teams to play with that genome as it comes out.” 

As the RT2T project advances, its research is anticipated to also shed light on the evolutionary biology of ruminants. This will allow breeders to implement strategies to help conserve valuable genetic traits and ensure animals can successfully adapt to changing environmental conditions.

Applications in Conservation and Biodiversity Management

In addition to agricultural benefits, the comprehensive genome data produced by the RT2T can play a critical role in conservation efforts. High-quality genomic information is essential for managing the genetic diversity of endangered ruminant species and developing strategies to improve their populations’ survival chances. 

Genome sequencing can unlock the entire genetic history of a population. For example, O’Neill says, conservation managers can use it to determine whether a population has undergone inbreeding, which can harm its long-term survival, and help re-diversify it by translocating individual animals from other populations. 

If a group of animals is discovered to have inbreeding depression, O’Neill explains, “That means they’ve gone through some sort of population decline at some point. And we can, from one genome, look into the past and actually model population density over time and figure out, is that population crash recent? Is it because of the Anthropocene, or is it more ancient? Those are the kinds of things conservation managers are looking for.” 

Research associates in O’Neill’s lab working on the RT2T include Jessica Storer, Gabrielle Hartley, Patrick Grady, Emry Brannan, Savannah Hoyt, Nicole Pauloski, Christine McCann, and Vel Johnston. 

 

This research was supported by the intramural research program of the U.S. Department of Agriculture, National Institute of Food and Agriculture, Grant Number 2023-67015-39000. 

Other participating organizations in the RT2T include the University of Kentucky, the University of Missouri, the University of Idaho, the University of Adelaide (Australia), Universidad de la República (Uruguay), Purdue University, Virginia Polytechnic Institute and State University, the University of Colorado Boulder, the University of Edinburgh (UK), AgResearch Ltd (New Zealand), Utah State University, the Livestock Improvement Corporation (New Zealand), Texas A&M University, Université de Toulouse (France), the Animal Genomics and Improvement Laboratory (Maryland, US), the University of California Davis, Oklahoma State University, the U.S. Meat Animal Research Center (Nebraska, US), Michigan State University, The Rockefeller University, the University of Wisconsin-Madison, Iowa State University, the National Human Genome Research Institute (Maryland, US), Friedrich-Loeffler-Institute (Germany), the University of Bern (Switzerland), ETH Zurich (Switzerland), the University of California Santa Cruz, Washington State University, the University of Southern California, the Stowers Institute for Medical Research (Missouri, US), Pennsylvania State University, the University of Alberta (Canada), the University of Louisville (Kentucky, US), and the Research Institute for Farm Animal Biology (Germany).