Published: 15:00 EDT, 14 September 2020 | Updated: 05:06 EDT, 15 September 2020
Scientists have created the first gene-edited livestock that can produce sperm with the traits of donor animals, allowing them to act as ‘surrogate sires’.
The breakthrough could result in ‘elite’ offspring that are bigger, healthier and meatier, helping to meet the food demands of a growing global population.
The technique was developed by researchers from Washington State University and Edinburgh University’s Roslin Institute, which is famous for creating the world’s first cloned mammal, Dolly the Sheep.
It involves breeding sterile male animals and then transplanting stem cells from donor animals into their testes, causing them to produce sperm that only carries the genetic material of the selected donor.
Project leader Professor Jon Oatley said the new technique could improve the efficiency of food production – or even save species from extinction.
This is a gene-edited surrogate bull. It can’t produce its own genetic offspring but in future its sperm will carry the genetic material of another bull and will pass it on to cows
‘With this technology, we can get better dissemination of desirable traits and improve the efficiency of food production,’ said Professor Oatley.
When they can reproduce – stem cells from a donor animal are transplanted into their testes.
Artificial insemination is rarely used with beef cattle who need to roam freely to feed and in pigs the animals have to be nearby as their sperm doesn’t last long.
Donors and surrogates do not need to be near each other since either frozen sperm or the animal itself can be shipped to different places.
‘If we can tackle this genetically, then that means less water, less feed and fewer antibiotics we have to put into the animals.’
The researchers used a gene editing (GIVE) tool called CRISPR-Cas9, which has been described as a pair of ‘molecular scissors’ – snipping DNA using a harmless virus.
Unlike genetic modification, nothing is added from another species – it is just the selection of the best DNA from other members of the same species.
Oatley and colleagues removed a male fertility gene called NANOS2 in the embryos of pigs, goats, cattle and mice that would be raised as ‘surrogate sires’.
These mammals then grew up sterile, but otherwise healthy. They began producing sperm after stem cells from donor animals were transplanted into their testes.
It held only the genetic material of the selected creatures – nothing from the surrogate sire.
The groundbreaking procedure only seeks to bring about changes that could occur naturally – such as infertility, according to the transatlantic team.
Oatley’s lab is now refining the system before the next step – getting offspring from the surrogate pigs, goats and cattle. They will not be their own, but the donor’s.
Dr Harry Leitch, an expert in genetics and reproduction from Imperial College London, not involved in the study, said the research is an important step forward.
‘The next step in pigs and goats will be to demonstrate that this sperm is functional – meaning that it can fertilise an egg and make healthy offspring,’ he said.
Experts have been searching for a way to create surrogate sires for decades to overcome selective breeding and artificial insemination.
The latter is common in dairy cattle who are often confined and so their reproductive behaviour is relatively easy to control, the team explained.
However, artificial insemination is rarely used with beef cattle, which need to roam freely to feed, and in pigs the animals have to be nearby as their sperm doesn’t last long.
Surrogates deliver the donor genetic material the natural way – through normal reproduction – enabling farmers to let their animals interact normally.
Donors and surrogates do not need to be near each other, since either frozen sperm or the animal itself can be shipped to different places.
Goats are particularly difficult to artificially inseminate but this new technique allows the healthiest males to pass their genetic material to animals via a donor sire
The change in the genetic material doesn’t render females infertile – it only affects male fertility – so a female interacting with a donor sire could still have fertile female offspring.
It has great potential to help food supply in places in the developing world where herders have to rely on selective breeding to improve their stock.
Co-author Prof Irina Polejaeva, of Utah State University, said: ‘Goats are the number one source of protein in a lot of developing countries.
‘This technology could allow faster dissemination of specific traits in goats, whether it’s disease resistance, greater heat tolerance or better meat quality.’
The technology also opens the door to genetic conservation of endangered species whose dwindling numbers leave animals isolated – limiting their genetic diversity.
Prof Oatley added: ‘Even if all science is finished, the speed at which this can be put into action in livestock production anywhere in the world is going to be influenced by societal acceptance and federal policy.
‘By working with policymakers and the public, we can help to provide information assuring the public that this science does not carry the risks that other methods do.’
It is defined as: ‘The study of changes in organisms caused by modification of gene expression rather than alteration of the genetic code itself.’
Instead of changing the genes present in a living thing, it changes which of its genes are ‘turned on’.
Although it is the genetic code which forms the foundations for every living organism, it is the combination of activated genes which defines it.
This gene expression can be complex or simple and can control a wide range of features.
As some features and behaviours are controlled by single genes, these can be easily altered by turning this gene off, for example.
Some genes inhibit growth and limit cell proliferation, by deactivating these genes things can be grown which do not have the same natural limitations as before.
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Genome editing, CRISPR, Gene, Genetics
World news – GB – Stem cell breakthrough lets male livestock serve as ‘surrogate sires’