A service that digitally weaves together the DNA of prospective parents to check for potential disease in thousands of “virtual babies” is set to launch in the US by December.
New York start-up Genepeeks will initially focus on donor sperm, simulating before pregnancy how the genetic sequence of a female client might combine with those of different males.
Donors that more often produce “digital children” with a higher risk of inherited disorders will be filtered out, leaving those who are better genetic matches.
Everything happens in a computer, but experts have raised ethical questions.
“We are just in the business right now of giving prospective mothers, who are using donor sperm to conceive, a
filtered catalogue of donors based on their own underlying genetic profile,” Genepeeks co-founder Anne Morriss told BBC News.
“We are filtering out the donor matches with an elevated risk of rare recessive paediatric conditions.”
Ms Morriss, an entrepreneur, gave a presentation on the company at the Consumer Genetics Conference in Boston last week.
She was motivated in part by her own experience of starting a family. Her son was conceived with a sperm donor who happened to share with Morriss the gene for an inherited disorder called MCADD.
MCADD (medium-chain acyl-CoA dehydrogenase deficiency) prevents those affected from converting fats to sugar. It can be fatal if it is not diagnosed early. Luckily, in Ms Morriss’s case, the condition was picked up in newborn screening tests.
“My son has a pretty normal life,” Ms Morriss said, “but about 30% of children with rare genetic diseases don’t make it past the age of five.”
Genepeeks has formalised a partnership with a sperm bank – the Manhattan Cryobank – and has a patent pending on the DNA screening technology.
The start-up benefits from the rapid pace of change in genetic technology.
Indeed, six months ago, Genepeeks’ founders decided it was able to use a superior system for DNA analysis (called
“targeted exon sequencing”) than the one originally envisaged – a result, says Anne Morriss, of falling costs and
For couples planning babies, other companies already screen one or both partners for genes that could cause disease
if combined with a similar variant – so-called “carrier screening”.
One academic who studies the use of genetic technology commented: “This is like that, but ramped up 100,000 times.”
Ms Morriss’s business partner, Prof Lee Silver, a geneticist and expert on bioethics at Princeton University, New
Jersey, told BBC News: “We get the DNA sequence from two prospective parents. We simulate the process of
reproduction, forming virtual sperm and virtual eggs. We put them together to form a hypothetical child genome.
“Then we can look at that hypothetical genome and – with all the tools of modern genetics – determine the risk that the genome will result in a child with disease. We’re looking directly for disease and not carrier status. For each pair of people that we’re going to analyse, we make 10,000 hypothetical children.”
The process will be run for the client and each potential donor one by one, scanning for some 600 known single-gene recessive conditions. In this way, the highest-risk pairings can be filtered out.
Anne Morriss added: “At this stage our clients won’t be receiving any genetic information back. We’re very much focused on the practical utility of helping prospective parents who want to protect their future kids, giving them the option of additional analysis to what is currently being offered in the industry.”
But the company’s founders have plans to expand the screening beyond single-gene recessive disorders to more complex conditions in which multiple genes play a part.
Indeed, going to the trouble of simulating thousands of digital children deliberately lays the ground for this: “[It’s] impossible to get towards an accurate risk calculation in any other way,” said Anne Morriss.
And in a video produced by the company, Prof Silver says: “My hope for the future is that any people who want to have a baby can use this technology to greatly reduce the risk of disease being expressed in their child.”
To some, such a prospect might appear like a step towards designer babies – until now the preserve of science fiction literature and films such as Gattaca, which envisaged a future of genetic “haves” and “have-nots”.
Bio-ethicists approached by the BBC said Genepeeks was a logical outcome of the increasing demand for more information when making reproductive decisions.
However, some raised potential concerns about risk communication and the expansion of screening beyond rare single-gene disorders. But they suggested there were few, if any, regulatory barriers.
One ethicist told BBC News: “The biggest question for me, just from the outset, is the understanding of uncertainty. Even people who have been doing genomics for years still have a hard time figuring out exactly what a risk for a particular genetic predisposition really means for a family.
“Gene-environment interactions can lead to people either having disease or not having disease.”
Dr Ewan Birney, associate director of the European Bioinformatics Institute in Hinxton, UK, echoed the point: “It’s good that they’re focusing on the carrier status of these rare Mendelian disorders where it’s potentially more clear-cut. That said, these things are more complex than they first seem,” he said.
“I’m sure the scientists appreciate that complexity. But when transmitting that complexity to everyday people, these things can sound more absolute than they really are.”
He added: “The thing I would want to stress here is just how complex this is. It’s great that people are thinking of using this technology in lots of different ways, but our knowledge gap is very large.”
Risk communication to clients was, said Anne Morriss, “absolutely critical to anyone in this industry”.
“We have to be crystal clear about what we’re testing for, what risks we’re helping to reduce; that there’s no guarantee you won’t give birth to a sick child,” she said.
Prof Mildred Cho, associate director of the Stanford Center for Biomedical Ethics in California, raised questions
over whether the sperm donor should also receive information about their genome gleaned from the screening process.
“Unlike hair colour, occupation or family history – those are things, presumably, the donor already knows – the thing
that’s different about this that I see is it could create information that the donor doesn’t already have. It also has implications for the donor’s other biological family members,” Prof Cho told BBC News.