Tag Archives: GeneEdited

Gene-Edited Babies: The Future of Genetics, but Not All CRISPR Startups Will Lead the Way

Posted on by
1

Babies Crawling in Diapers

Every Baby Has About 100 New Genetic Mutations

Mood board – Mike Watson / Getty Images

Let me share some eye-opening news. Every child embodies genetic experimentation, with nature exhibiting indifference if things don’t go as planned. Our genomes present a complex tapestry shaped by conflicting evolutionary forces, and each of us carries roughly one hundred novel mutations.Each birth introduces a unique mutation into the genetic pool.

Thus, I anticipate that in the future, gene editing of embryos will become commonplace once humanity confronts various daunting challenges, including climate change. There may come a time when natural conception is perceived as reckless.

Reaching that future is no trivial task. However, if you’ve been following the buzz from the tech community this year, it’s no surprise you feel optimistic. By 2025, we discovered at least three startups focused on creating gene-edited babies.

So, is the dawn of CRISPR on the horizon, or could these startups potentially face backlash?

Preventing Genetic Diseases

Among these startups, Manhattan Genomics and Preventive aim not for enhancement but to avert severe genetic disorders. This noble objective is commendable, but it’s important to note that many of these conditions can already be forestalled through existing screening techniques, such as genetic testing of IVF embryos prior to implantation, a process with a high rate of success.

So why pursue the development of gene-edited embryos, a complex and legally challenging endeavor, when IVF screening already provides a viable solution?

Preventive did not respond to inquiries, but a spokesperson from Manhattan Genomics noted that couples undergoing IVF often don’t have enough viable embryos to choose from. By editing disease-carrying embryos instead of discarding them, the likelihood of having a healthy child increases. The company believes that gene editing could enhance the chances for approximately ten embryos affected by Huntington’s disease and thirty-five embryos affected by sickle cell disease annually for couples using IVF.

However, this translates to a very limited number of births. Approximately one-third of IVF embryos lead to viable births, and this percentage may drop further post-editing. Furthermore, significant challenges accompany this approach. Although CRISPR technology has advanced, there’s still a risk of introducing harmful mutations as unintended consequences.

Moreover, the editing process often fails to initiate or can continue even after the embryo has begun dividing. This results in various genetic alterations within the same embryo, a phenomenon known as mosaicism. The illegal CRISPR children from China come to mind, announced in 2018.

Consequently, it becomes uncertain whether the mutation causing the disease was indeed corrected in the edited embryo and whether any harmful mutations emerged as a result.

Doing It Right

Solutions do exist. For instance, some gene-edited animals have been developed by modifying stem cells and then cloning them once the desired alterations have been confirmed. However, I previously explained that cloned animals often exhibit various health issues and unexpected traits, underscoring the necessity for foundational research and rigorous oversight should this approach be pursued for humans.

We have two strong examples of responsibly introducing embryonic gene editing through mitochondrial donation initiatives in the UK and Australia. Mitochondria are cellular energy producers that contain their own small genomes. Mutated mitochondria can lead to severe health issues if passed down to offspring, but this risk can be mitigated by substituting them with healthy donor mitochondria.

A version of mitochondrial technology emerged in private fertility clinics in the US during the 1990s, during which humanity witnessed the first genetically modified human. Initial attempts led to the banning of this technology in the US.

While mitochondrial donation was previously prohibited in the UK, changes in the law came about following advocacy from patient groups, extensive dialogue, and consultation. It now receives approvals on a trial basis as needed.Australia is pursuing a similar path.

What Is the Real Objective?

This is the ideal framework for introducing new reproductive technologies: transparently, legally, and under independent supervision. Yet, at least two startups are reportedly conducting experiments in countries with laxer gene editing laws.

This does not advance science, as trust in the claims made by private companies acting without regulatory oversight diminishes. Conversely, this approach could prompt a backlash, leading to more countries tightening regulations against gene editing.

For these billionaires – with Preventive’s investors including notable figures like OpenAI’s Sam Altman and Coinbase’s Brian Armstrong – if your genuine intention is to combat severe genetic diseases, investing in nonprofit research organizations could yield significantly greater results.

Or is the ultimate aim to engineer your own child instead of assisting other couples in achieving healthy pregnancies? This is clearly the mission of the third startup, Bootstrap Bio.

In next month’s column, we will explore whether gene editing can truly be utilized to enhance our children.

Topics:

Source: www.newscientist.com

Gene-Edited Pigs Resistant to Swine Fever: A Potential Advancement for Animal Welfare

Posted on by
Reply

Gene-edited pigs exhibit resistance to swine fever

Simon Lillico

By making a few genetic modifications, pigs can be rendered entirely resistant to swine fever, a significant issue for farmers globally. This gene editing could also confer resistance to related viruses in cattle and sheep.

The widespread adoption of gene-edited pigs resistant to swine fever is expected to enhance animal welfare, boost productivity, reduce greenhouse gas emissions, and lower retail prices. “This will foster sustainable livestock production and promote the well-being of pigs,” asserts Helen Crook from the UK Animal and Plant Health Agency.

Swine fever is a highly contagious viral illness that can lead to symptoms ranging from fever to diarrhea and miscarriage, often resulting in significant pig mortality.

While the disease has been eliminated in many regions, it can resurface. For instance, in 1997, the Netherlands culled 6 million pigs to contain an outbreak, and Japan has faced ongoing challenges since 2018.

Typically, when outbreaks occur, livestock are protected using vaccines containing live, weakened virus strains, which is a complex and costly process. “Vaccination demands extensive coordination and oversight,” mentions Christine Tate-Burkard from the University of Edinburgh, UK.

Countries utilizing vaccinations face restrictions when exporting to disease-free areas. Interruptions in vaccination programs can also lead to outbreaks, as seen recently in the Philippines, explains Tate-Burkard.

Nevertheless, the classic swine fever virus has a vulnerability. The viral protein bundles formed from long chains of amino acids must be cleaved into functional pieces, relying on specific pig proteins for this process.

By altering a single amino acid in this pig protein, referred to as DNAJC14, it may be possible to obstruct this cleavage. Tait-Burkard and colleagues employed CRISPR gene editing to create pigs with this minor modification.

Subsequently, the team sent some of these pigs to a secure facility, where Crook’s group introduced the live swine virus intranasally. All typical pigs fell ill, while the gene-edited pigs showed no signs of infection. There were no symptoms, antibodies, nor detectable virus.

“These pigs demonstrated complete resistance to viral replication and remained healthy and content throughout the experiment,” states Crook.

This research was partially sponsored by Genus, a major international breeding company currently evaluating the commercialization of these pigs.

Genus has previously developed gene-edited pigs resistant to another significant disease, porcine reproductive and respiratory syndrome, which are already approved in the United States, Brazil, and other nations. The company awaits approvals in Mexico, Canada, and Japan—key export markets for the U.S.—before it can start selling semen to farmers.

When used to implement small changes that can naturally occur, gene editing often faces less stringent regulations compared to traditional genetic engineering. Japan has already sanctioned three types of gene-edited fish.

The UK is anticipated to begin approving gene-edited plants soon, although regulations for livestock are yet to be finalized. It is expected that these regulations will prioritize animal welfare.

The research team observed no adverse effects in the swine fever-resistant pigs, according to Simon Lillico and colleagues from the University of Edinburgh, although further research is necessary to confirm these findings.

He emphasizes that traditional breeding lacks such welfare considerations. “It would be beneficial to ensure a level playing field,” he remarks. “We are aware that some conventionally reared animals experience low welfare standards.”

A virus closely related to classical swine fever is responsible for causing bovine viral diarrhea in cattle and borderline disease in sheep. While these diseases are not lethal, they still impact welfare and productivity. The Edinburgh research team is presently examining whether modifications made to pigs will also benefit cattle and sheep.

Topics:

Source: www.newscientist.com