Gene editing helped an ill baby thrive — may someday treat millions
Researchers described the case in a new study, saying he's among the first to be successfully treated with a custom therapy that seeks to fix a tiny but critical error in his genetic code that kills half of affected infants.
Though it may be a while before similar personalised treatments are available for others, doctors hope the technology can someday help the millions left behind even as genetic medicine has advanced because their conditions are so rare.
"This is the first step towards the use of gene editing therapies to treat a wide variety of rare genetic disorders for which there are currently no definitive medical treatments," said Dr Kiran Musunuru, a University of Pennsylvania gene editing expert who co-authored the study published Thursday (local time) in the New England Journal of Medicine.
The baby, KJ Muldoon of Clifton Heights, Pennsylvania, is one of 350 million people worldwide with rare diseases, most of which are genetic. He was diagnosed shortly after birth with severe CPS1 deficiency, estimated by some experts to affect around one in a million babies.
The infants lack an enzyme needed to help remove ammonia from the body, so it can build up in their blood and become toxic. A liver transplant is an option for some.
Knowing KJ's odds, parents Kyle and Nicole Muldoon, both 34, worried they could lose him.
"We were, like, you know, weighing all the options, asking all the questions for either the liver transplant, which is invasive, or something that's never been done before," Nicole said.
"We prayed, we talked to people, we gathered information, and we eventually decided that this was the way we were going to go," her husband added.
Within six months, the team at Children's Hospital of Philadelphia and Penn Medicine, along with their partners, created a therapy designed to correct KJ's faulty gene.
They used CRISPR, the gene editing tool that won its inventors the Nobel Prize in 2020. Instead of cutting the DNA strand like the first CRISPR approaches, doctors employed a technique that flips the mutated DNA "letter" — also known as a base — to the correct type. Known as "base editing," it reduces the risk of unintended genetic changes.
It's "very exciting" that the team created the therapy so quickly, said gene therapy researcher Senthil Bhoopalan at St Jude Children's Research Hospital in Memphis, who wasn't involved in the study. "This really sets the pace and the benchmark for such approaches."
In February, KJ got his first IV infusion with the gene editing therapy, delivered through tiny fatty droplets called lipid nanoparticles that are taken up by liver cells.
While the room was abuzz with excitement that day, "he slept through the entire thing," recalled study author Dr Rebecca Ahrens-Nicklas, a gene therapy expert at CHOP.
After follow-up doses in March and April, KJ has been able to eat more normally and has recovered well from illnesses like colds, which can strain the body and exacerbate symptoms of CPS1.
Considering his poor prognosis earlier, "any time we see even the smallest milestone that he's meeting – like a little wave or rolling over – that's a big moment for us," his mother said.
Still, researchers caution that it's only been a few months. They'll need to watch him for years.
"We're still very much in the early stages of understanding what this medication may have done for KJ," Ahrens-Nicklas said. "But every day, he's showing us signs that he's growing and thriving."
Researchers hope what they learn from KJ will help other rare disease patients.
Gene therapies, which can be extremely expensive to develop, generally target more common disorders in part for simple financial reasons: more patients mean potentially more sales, which can help pay the development costs and generate more profit.
The first CRISPR therapy approved by the US Food and Drug Administration, for example, treats sickle cell disease, a painful blood disorder affecting millions worldwide.
Musunuru said his team's work — funded in part by the National Institutes of Health — showed that creating a custom treatment doesn't have to be prohibitively expensive. The cost was "not far off" from the US$800,000-plus (NZ$1.3 million) for an average liver transplant and related care, he said.
"As we get better and better at making these therapies and shorten the time frame even more, economies of scale will kick in and I would expect the costs to come down," Musunuru said.
Scientists also won't have to redo all the initial work every time they create a customised therapy, Bhoopalan said, so this research "sets the stage" for treating other rare conditions.
Carlos Moraes, a neurology professor at the University of Miami who wasn't involved with the study, said research like this opens the door to more advances.
"Once someone comes with a breakthrough like this, it will take no time" for other teams to apply the lessons and move forward, he said. "There are barriers, but I predict that they are going to be crossed in the next five to 10 years. Then the whole field will move as a block because we're pretty much ready."
Hashtags
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
1News
4 days ago
- 1News
New mRNA vaccines saved millions — so why is the US pulling funding?
So-called mRNA vaccines saved millions of lives during the Covid-19 pandemic — and now scientists are using that Nobel Prize-winning technology to try to develop vaccines and treatments against a long list of diseases including cancer and cystic fibrosis. But this week, US Health Secretary Robert F. Kennedy Jr., a longtime vaccine critic, cancelled US$500 million (NZ$842 million) in government-funded research projects to create new mRNA vaccines against respiratory illnesses that might trigger another health emergency. That dismays infectious disease experts who note that mRNA allows faster production of shots than older vaccine-production methods, buying precious time if another pandemic were to emerge. Using older technology to target a pandemic flu strain would take 18 months to 'make enough vaccine to vaccinate only about one-fourth of the world", said Michael Osterholm of the University of Minnesota, an expert on pandemic preparation. But using mRNA technology 'could change that dramatically, such that by the end of the first year, we could vaccinate the world'. How mRNA technology works ADVERTISEMENT Traditionally, making vaccines required growing viruses or pieces of viruses called proteins — often in giant vats of cells or, like most flu shots, in chicken eggs — and then purifying them. Injecting a small dose as a vaccine trains the body how to recognize when a real infection hits so it's ready to fight back. But that technology takes a long time. Using mRNA is a faster process. The 'm' stands for messenger, meaning mRNA carries instructions for our bodies to make proteins. Scientists figured out how to harness that natural process by making mRNA in a lab. They take a snippet of that genetic code that carries instructions for making the protein they want the vaccine to target. Injecting that snippet instructs the body to become its own mini-vaccine factory, making enough copies of the protein for the immune system to recognise and react. The morning's headlines in 90 seconds, including a cold weekend on the way, Israel reveals a new plan in Gaza, and what not do when driving over a rail crossing. (Source: 1News) The Covid-19 vaccines aren't perfect Years of research show protection from Covid-19 vaccines — both the types made with mRNA and a type made with traditional technology — does wane over time. The vaccinations provide the strongest protection against severe infection and death, even if people still become infected. ADVERTISEMENT But that's a common feature with both the coronavirus and flu because both viruses continually mutate. That's the reason we're told to get a flu vaccine every year — using vaccines made with traditional methods, not mRNA. Today's Covid-19 vaccines made with mRNA by Pfizer and Moderna can be updated more quickly each year than traditional types, an advantage that now has multiple companies developing other vaccines using the technology. Traditional vaccines aren't the only use for mRNA Osterholm counts about 15 infectious disease vaccines that could benefit from mRNA technology, but that's not the only potential. Many disease therapies take aim at proteins, making mRNA a potential technique for developing new treatments. Researchers already are testing an mRNA-based therapeutic vaccine for pancreatic cancer. Genetic diseases are another target, such as an experimental inhaled therapy for cystic fibrosis.
RNZ News
12-07-2025
- RNZ News
Using toxic fungus to fight cancer
Dr Sherry Gao. Photo: Supplied / Dr Sherry Gao Toxic fungus has been in the headlines this week - Australian woman Erin Patterson was found guilty of murdering her three in-laws by poisoning them with death cap mushrooms. But there's a toxic fungus that researchers have been able to use to fight cancer. The same mould that has been linked to deaths, in the excavations of ancient tombs - has the capability of fighting leukemia cells. Dr Sherry Gao, an associate professor at the University of Pennsylvania speaks to Mihingarangi Forbes about the significance of this discovery. Photo: 123rf
Scoop
12-07-2025
- Scoop
Toxic Fungus Enlisted In Fight Against Leukemia
Researchers say they have been able to modify toxic fungus cells to fight cancer - specifically, leukaemia. The same mould that has been linked to deaths in the excavations of ancient tombs and found on old bread has the capability of fight leukemia cells. The fungus is known as aspergillus flavus fungus. Associate professor at the University of Pennsylvania, Dr Sherry Gao, told Saturday Morning the discovery was significant. Gao said they found a new class of compound which was produced by the fungus. But how does the compound fight cancer? "We isolated and define the chemical structure of those new compounds," Gao said. "By making some small chemical tweaks we actually modified the structure a bit, we've found those modified compounds can enter leukaemia cells very selectively. "Once it's entered the cell, its able to prevent cell division - that's why it could possibly lead to a cure for leukaemia." This was not the first fungus that has led to a breakthrough in medicine. Penicillin was also created using a fungus. Gao said her lab was also experimenting with other fungi, aiming to kill other cancer cell lines.
