Genetically Sequencing Healthy Babies Yielded Surprising Results
Today in Melrose, Massachusetts, Cora Stetson is the picture of good health, a bubbly precocious 2-year-old. But Cora has two separate mutations in the gene that produces a critical enzyme called biotinidase and her body produces only 40 percent of the normal levels of that enzyme.
In the last few years, the dream of predicting and preventing diseases through genomics, starting in childhood, is finally within reach.
That's enough to pass conventional newborn (heelstick) screening, but may not be enough for normal brain development, putting baby Cora at risk for seizures and cognitive impairment. But thanks to an experimental study in which Cora's DNA was sequenced after birth, this condition was discovered and she is being treated with a safe and inexpensive vitamin supplement.
Stories like these are beginning to emerge from the BabySeq Project, the first clinical trial in the world to systematically sequence healthy newborn infants. This trial was led by my research group with funding from the National Institutes of Health. While still controversial, it is pointing the way to a future in which adults, or even newborns, can receive comprehensive genetic analysis in order to determine their risk of future disease and enable opportunities to prevent them.
Some believe that medicine is still not ready for genomic population screening, but others feel it is long overdue. After all, the sequencing of the Human Genome Project was completed in 2003, and with this milestone, it became feasible to sequence and interpret the genome of any human being. The costs have come down dramatically since then; an entire human genome can now be sequenced for about $800, although the costs of bioinformatic and medical interpretation can add another $200 to $2000 more, depending upon the number of genes interrogated and the sophistication of the interpretive effort.
Two-year-old Cora Stetson, whose DNA sequencing after birth identified a potentially dangerous genetic mutation in time for her to receive preventive treatment.
(Photo courtesy of Robert Green)
The ability to sequence the human genome yielded extraordinary benefits in scientific discovery, disease diagnosis, and targeted cancer treatment. But the ability of genomes to detect health risks in advance, to actually predict the medical future of an individual, has been mired in controversy and slow to manifest. In particular, the oft-cited vision that healthy infants could be genetically tested at birth in order to predict and prevent the diseases they would encounter, has proven to be far tougher to implement than anyone anticipated.
But in the last few years, the dream of predicting and preventing diseases through genomics, starting in childhood, is finally within reach. Why did it take so long? And what remains to be done?
Great Expectations
Part of the problem was the unrealistic expectations that had been building for years in advance of the genomic science itself. For example, the 1997 film Gattaca portrayed a near future in which the lifetime risk of disease was readily predicted the moment an infant is born. In the fanfare that accompanied the completion of the Human Genome Project, the notion of predicting and preventing future disease in an individual became a powerful meme that was used to inspire investment and public support for genomic research long before the tools were in place to make it happen.
Another part of the problem was the success of state-mandated newborn screening programs that began in the 1960's with biochemical tests of the "heel-stick" for babies with metabolic disorders. These programs have worked beautifully, costing only a few dollars per baby and saving thousands of infants from death and severe cognitive impairment. It seemed only logical that a new technology like genome sequencing would add power and promise to such programs. But instead of embracing the notion of newborn sequencing, newborn screening laboratories have thus far rejected the entire idea as too expensive, too ambiguous, and too threatening to the comfortable constituency that they had built within the public health framework.
"What can you find when you look as deeply as possible into the medical genomes of healthy individuals?"
Creating the Evidence Base for Preventive Genomics
Despite a number of obstacles, there are researchers who are exploring how to achieve the original vision of genomic testing as a tool for disease prediction and prevention. For example, in our NIH-funded MedSeq Project, we were the first to ask the question: "What can you find when you look as deeply as possible into the medical genomes of healthy individuals?"
Most people do not understand that genetic information comes in four separate categories: 1) dominant mutations putting the individual at risk for rare conditions like familial forms of heart disease or cancer, (2) recessive mutations putting the individual's children at risk for rare conditions like cystic fibrosis or PKU, (3) variants across the genome that can be tallied to construct polygenic risk scores for common conditions like heart disease or type 2 diabetes, and (4) variants that can influence drug metabolism or predict drug side effects such as the muscle pain that occasionally occurs with statin use.
The technological and analytical challenges of our study were formidable, because we decided to systematically interrogate over 5000 disease-associated genes and report results in all four categories of genetic information directly to the primary care physicians for each of our volunteers. We enrolled 200 adults and found that everyone who was sequenced had medically relevant polygenic and pharmacogenomic results, over 90 percent carried recessive mutations that could have been important to reproduction, and an extraordinary 14.5 percent carried dominant mutations for rare genetic conditions.
A few years later we launched the BabySeq Project. In this study, we restricted the number of genes to include only those with child/adolescent onset that could benefit medically from early warning, and even so, we found 9.4 percent carried dominant mutations for rare conditions.
At first, our interpretation around the high proportion of apparently healthy individuals with dominant mutations for rare genetic conditions was simple – that these conditions had lower "penetrance" than anticipated; in other words, only a small proportion of those who carried the dominant mutation would get the disease. If this interpretation were to hold, then genetic risk information might be far less useful than we had hoped.
Suddenly the information available in the genome of even an apparently healthy individual is looking more robust, and the prospect of preventive genomics is looking feasible.
But then we circled back with each adult or infant in order to examine and test them for any possible features of the rare disease in question. When we did this, we were surprised to see that in over a quarter of those carrying such mutations, there were already subtle signs of the disease in question that had not even been suspected! Now our interpretation was different. We now believe that genetic risk may be responsible for subclinical disease in a much higher proportion of people than has ever been suspected!
Meanwhile, colleagues of ours have been demonstrating that detailed analysis of polygenic risk scores can identify individuals at high risk for common conditions like heart disease. So adding up the medically relevant results in any given genome, we start to see that you can learn your risks for a rare monogenic condition, a common polygenic condition, a bad effect from a drug you might take in the future, or for having a child with a devastating recessive condition. Suddenly the information available in the genome of even an apparently healthy individual is looking more robust, and the prospect of preventive genomics is looking feasible.
Preventive Genomics Arrives in Clinical Medicine
There is still considerable evidence to gather before we can recommend genomic screening for the entire population. For example, it is important to make sure that families who learn about such risks do not suffer harms or waste resources from excessive medical attention. And many doctors don't yet have guidance on how to use such information with their patients. But our research is convincing many people that preventive genomics is coming and that it will save lives.
In fact, we recently launched a Preventive Genomics Clinic at Brigham and Women's Hospital where information-seeking adults can obtain predictive genomic testing with the highest quality interpretation and medical context, and be coached over time in light of their disease risks toward a healthier outcome. Insurance doesn't yet cover such testing, so patients must pay out of pocket for now, but they can choose from a menu of genetic screening tests, all of which are more comprehensive than consumer-facing products. Genetic counseling is available but optional. So far, this service is for adults only, but sequencing for children will surely follow soon.
As the costs of sequencing and other Omics technologies continue to decline, we will see both responsible and irresponsible marketing of genetic testing, and we will need to guard against unscientific claims. But at the same time, we must be far more imaginative and fast moving in mainstream medicine than we have been to date in order to claim the emerging benefits of preventive genomics where it is now clear that suffering can be averted, and lives can be saved. The future has arrived if we are bold enough to grasp it.
Funding and Disclosures:
Dr. Green's research is supported by the National Institutes of Health, the Department of Defense and through donations to The Franca Sozzani Fund for Preventive Genomics. Dr. Green receives compensation for advising the following companies: AIA, Applied Therapeutics, Helix, Ohana, OptraHealth, Prudential, Verily and Veritas; and is co-founder and advisor to Genome Medical, Inc, a technology and services company providing genetics expertise to patients, providers, employers and care systems.
When Are We Obligated To Edit Wild Creatures?
Combining CRISPR genome editing with the natural phenomenon of gene drive allows us to rewrite the genomes of wild organisms. The benefits of saving children from malaria by editing mosquitoes are obvious and much discussed, but humans aren't the only creatures who suffer. If we gain the power to intervene in a natural world "red in tooth and claw," yet decline to use it, are we morally responsible for the animal suffering that we could have prevented?
Given the power to alter the workings of the natural world, are we morally obligated to use it?
The scenario that may redefine our relationship with the natural world begins with fine clothing. You're dressed to the nines for a formal event, but you arrived early, and it's such a beautiful day that you decided to take a stroll by the nearby lake. Suddenly, you hear the sound of splashing and screams. A child is drowning! Will you dive in to save them? Or let them die, and preserve your expensive outfit?
The philosopher Peter Singer posited this scenario to show that we are all terrible human beings. Just about everyone would save the child and ruin the outfit... leading Singer to question why so few of us give equivalent amounts of money to save children on the other side of the world. The Against Malaria Foundation averages one life saved for every $7000.
But despite having a local bias, our moral compasses aren't completely broken. You never even considered letting the child drown because the situation wasn't your fault. That's because the cause of the problem simply isn't relevant: as the one who could intervene, the consequences are on your head. We are morally responsible for intervening in situations we did not create.
There is a critical difference between Singer's original scenario and the one above: in his version, it was a muddy pond. Any adult can rescue a child from a muddy pond, but a lake is different; you can only save the child if you know how to swim. We only become morally responsible when we acquire the power to intervene.
Few would disagree with either of these moral statements, but when they are combined with increasingly powerful technologies, the implications are deeply unsettling. Given the power to alter the workings of the natural world, are we morally obligated to use it? Recent developments suggest we had best determine the answer soon because, technologically, we are learning to swim. What choices will we make?
Gene drive is a natural phenomenon that occurs when a genetic element reliably spreads through a population even though it reduces the reproductive fitness of individual organisms. Nature has evolved many different mechanisms that result in gene drive, so many that it's nearly impossible to find an organism that doesn't have at least one driving element somewhere in its genome. More than half of our own DNA comprises the broken remnants of gene drives, plus a few active copies.
Scientists have long dreamed of harnessing gene drive to block mosquito-borne disease, with little success. Then came CRISPR genome editing, which works by cutting target genes and replacing them with a new sequence. What happens if you replace the original sequence with the edited version and an encoded copy of the CRISPR system? Gene drive.
CRISPR is a molecular scalpel that we can use to cut, and therefore replace, just about any DNA sequence in any cell. Encode the instructions for the CRISPR system adjacent to the new sequence, and genome editing will occur in the reproductive cells of subsequent generations of heterozygotes, always converting the original wild-type version to the new edited version. By ensuring that offspring will all be born of one sex, or by arranging for organisms that inherit two copies of the gene drive to be sterile, it's theoretically possible to cause a population crash.
(Credit: Esvelt)
When my colleagues and I first described this technology in 2014, we initially focused on the imperative for early transparency. Gene drive research is more like civic governance than traditional technology development: you can decline a treatment recommended by your doctor, but you can’t opt out when people change the shared environment. Applying the traditional closeted model of science to gene drive actively denies people a voice in decisions intended to affect them - and reforming scientific incentives for gene drive could be the first step to making all of science faster and safer.
But open gene drive research is clearly aligned with virtually all of our values. It's when technology places our deepest moral beliefs in conflict that we struggle, and learn who we truly are.
Two of our strongest moral beliefs include our reverence for the natural world and our abhorrence of suffering. Yet some natural species inherently cause tremendous suffering. Are we morally obligated to alter or even eradicate them?
To anyone who doubts that the natural world can inflict unimaginable suffering, consider the New World screwworm.
Judging by history, the answer depends on who is doing the suffering. We view the eradication of smallpox as one of our greatest triumphs, clearly demonstrating that we value human lives over the existence of disease-causing microorganisms. The same principle holds today for malaria: few would argue against using gene drive to crash populations of malarial mosquitoes to help eradicate the disease. There are more than 3500 species of mosquitoes, only three of which would be affected, and once malaria is gone, the mosquitoes could be allowed to recover. It would be extremely surprising if African nations decided not to eradicate malaria.
The more interesting question concerns our moral obligations to animals in the state of nature.
To anyone who doubts that the natural world can inflict unimaginable suffering, consider the New World screwworm, Cochyliomyia hominivorax. Female screwworm flies lay their eggs in open wounds, generating maggots that devour healthy tissue, gluttonously burrowing into the flesh of their host until they drop, engorged and sated, to metamorphose. Yet before they fall, the maggots in a wound emit a pheromone attracting new females, thereby acting as both conductors and performers in a macabre parade that consumes the host alive. The pain is utterly excruciating, so much so that infested people often require morphine before doctors can even examine the wound. Worst of all, the New World screwworm specializes in devouring complex mammals.
Every second of every day, hundreds of millions of animals suffer the excruciating agony of being eaten alive. It has been so throughout North and South America for millions of years. Until 2001, when humanity eradicated the last screwworm fly north of Panama using the “sterile insect techniqueâ€. This was not done to protect wild animals or even people, but for economic reasons: the cost of the program was small relative to the immense damage wrought by the screwworm on North American cattle, sheep, and goats. There were no obvious ecological effects. Despite being almost completely unknown even among animal rights activists, the screwworm elimination campaign may well have been one of the greatest triumphs of animal well-being.
Unfortunately, sterile insect technique isn't powerful enough to eradicate the screwworm from South America, where it is more entrenched and protected by the rougher terrain. But gene drive is.
Contrary to news hype, gene drive alone can't cause extinction, but if combined with conventional measures it might be possible to remove targeted species from the wild. For certain species that cause immense suffering, we may be morally obligated to do just that.
(Credit: Esvelt)
South Americans may well decide to eradicate screwworm for the same economic reasons that it was eradicated from North America: the fly inflicts $4 billion in annual damages on struggling rural communities that can least afford it. It need not go extinct, of course; the existence of the sterile insect facility in Panama proves that we can maintain the screwworm indefinitely in captivity on already dead meat.
Yet if for some reason humanity chooses to leave the screwworm as it is - even for upstanding moral reasons, whatever those may be - the knowledge of our responsibility should haunt us.
Tennyson wrote,
Are God and Nature then at strife,
That Nature lends such evil dreams?
So careful of the type she seems,
So careless of the single life.
Evolution by natural selection cares nothing for the single life, nor suffering, nor euphoria, save for their utility in replication. Theoretically, we do. But how much?
[Editor's Note: This story was originally published in May 2018. We are resurfacing archive hits while our staff is on vacation.]
A Fierce Mother vs. a Fatal Mutation
Editor's Note: In the year 2000, Amber Salzman was a 39-year-old mom from Philadelphia living a normal life: working as a pharmaceutical executive, raising an infant son, and enjoying time with her family. But when tragedy struck in the form of a ticking time bomb in her son's DNA, she sprang into action. Her staggering triumphs after years of turmoil exemplify how parents today can play a crucial role in pushing science forward. This is her family's story, as told to LeapsMag's Editor-in-Chief Kira Peikoff.
For a few years, my nephew Oliver, suffered from symptoms that first appeared as attention deficit disorder and then progressed to what seemed like Asperger's, and he continued to worsen and lose abilities he once had. After repeated misdiagnoses, he was finally diagnosed at age 8 with adrenoleukodystrophy, or ALD – a degenerative brain disease that puts kids on the path toward death. We learned it was an X-linked disease, so we had to test other family members. Because Oliver had it, that meant his mother, my sister, was carrier, which meant I had a 50-50 chance of being a carrier, and if I was, then my son had a 50-50 chance of getting the bad gene.
You know how some people win prizes all the time? I don't have that kind of luck. I had a sick feeling when we drew my son's blood. It was almost late December in the year 2000. Spencer was 1 and climbing around like a monkey, starting to talk—a very rambunctious kid. He tested positive, along with Oliver's younger brother, Elliott.
"The only treatment at the time was an allogenic stem cell transplant from cord blood or bone marrow."
You can imagine the dreadful things that go through your mind. Everything was fine then, but he had a horrific chance that in about 3 or 4 years, a bomb would go off. It was so tough thinking that we were going to lose Oliver, and then Spencer and Elliott were next in line. The only treatment at the time was an allogenic stem cell transplant from cord blood or bone marrow, which required finding a perfect match in a donor and then undergoing months of excruciating treatment. The mortality rate can be as high as 40 percent. If your kid was lucky enough to find a donor, he would then be lucky to leave the hospital 100 days after a transplant with a highly fragile immune system.
At the time, I was at GlaxoSmithKline in Research and Development, so I did have a background in working with drug development and I was fortunate to report to the chairman of R&D, Tachi Yamada.
I called Tachi and said, "I need your advice, I have three or four years to find a cure. What do I do?" He did some research and said it's a monogenic disease—meaning it's caused by only one errant gene—so my best bet was gene therapy. This is an approach to treatment that involves taking a sample of the patient's own stem cells, treating them outside the body with a viral vector as a kind of Trojan Horse to deliver the corrected gene, and then infusing the solution back into the patient, in the hopes that the good gene will proliferate throughout the body and stop the disease in its tracks.
Tachi said to call his friend Jim Wilson, who was a leader in the field at UPenn.
Since I live in Philadelphia I drove to see Jim as soon as possible. What I didn't realize was how difficult a time it was. This was shortly after Jesse Gelsinger died in a clinical trial for gene therapy run by UPenn—the first death for the field—and research had abruptly stopped. But when I met with Jim, he provided a road map for what it would take to put together a gene therapy trial for ALD.
Meanwhile, in parallel, I was dealing with my son's health.
After he was diagnosed, we arranged a brain MRI to see if he had any early lesions, because the only way you can stop the disease is if you provide a bone marrow transplant before the disease evolves. Once it is in full force, you can't reverse it, like a locomotive that's gone wild.
"He didn't recover like other kids because his brain was not a normal brain; it was an ALD brain."
We found he had a brain tumor that had nothing to do with ALD. It was slow growing, and we would have never found it otherwise until it was much bigger and caused symptoms. Long story short, he ended up getting the tumor removed, and when he was healing, he didn't recover like other kids because his brain was not a normal brain; it was an ALD brain. We knew we needed a transplant soon, and the gene therapy trial was unfortunately still years away.
At the time, he was my only child, and I was thinking of having additional kids. But I didn't want to get pregnant with another ALD kid and I wanted a kid who could provide a bone marrow transplant for my son. So while my son was still OK, I went through 5 cycles of in vitro fertilization, a process in which hormone shots stimulated my ovaries to produce multiple eggs, which were then surgically extracted and fertilized in a lab with my husband's sperm. After the embryos grew in a dish for three to five days, doctors used a technique called preimplantation genetic diagnosis, screening those embryos to determine which genes they carry, in order to try to find a match for Spencer. Any embryo that had ALD, we saved for research. Any that did not have ALD but were not a match for Spencer, we put in the freezer. We didn't end up with a single one that was a match.
So he had a transplant at Duke Children's Hospital at age 2, using cord blood donated from a public bank. He had to be in the hospital a long time, infusing meds multiple times a day to prevent the donor cells from rejecting his body. We were all excited when he made it out after 100 days, but then we quickly had to go back for an infection he caught.
We were still bent on moving forward with the gene therapy trials.
Jim Wilson at Penn explained what proof of concept we needed in animals to go forward to humans, and a neurologist in Paris, Patrick Aubourg, had already done that using a vector to treat ALD mice. But he wasn't sure which vector to use in humans.
The next step was to get Patrick and a team of gene therapy experts together to talk about what they knew, and what needed to be done to get a trial started. There was a lot of talk about viral vectors. Because viruses efficiently transport their own genomes into the cells they infect, they can be useful tools for sending good genes into faulty cells. With some sophisticated tinkering, molecular biologists can neuter normally dangerous viruses to make them into delivery trucks, nothing more. The biggest challenge we faced then was: How do we get a viral vector that would be safe in humans?
Jim introduced us to Inder Verma, chair of the scientific advisory board of Cell Genesys, a gene therapy company in California that was focused on oncology. They were the closest to making a viral vector that could go into humans, based on a disabled form of HIV. When I spoke to Inder, he said, "Let's review the data, but you will need to convince the company to give you the vector." So I called the CEO and basically asked him, "Would you be willing to use the vector in this horrific disease?" I told him that our trial would be the fastest way to test their vector in humans. He said, "If you can convince my scientists this is ready to go, we will put the vector forward." Mind you, this was a multi-million-dollar commitment, pro bono.
I kept thinking every day, the clock is ticking, we've got to move quickly. But we convinced the scientists and got the vector.
Then, before we could test it, an unrelated clinical trial in gene therapy for a severe immunodeficiency disease, led to several of the kids developing leukemia in 2003. The press did a bad number and scared everyone away from the field, and the FDA put studies on hold in the U.S. That was one of those moments where I thought it was over. But we couldn't let it stop. Nothing's an obstacle, just a little bump we have to overcome.
Patrick wanted to do the study in France with the vector. This is where patient advocacy is important in providing perspective on the risks vs. benefits of undergoing an experimental treatment. What nobody seemed to realize was that the kids in the 2003 trial would have died if they were not first given the gene therapy, and luckily their leukemia was a treatable side effect.
Patrick and I refused to give up pushing for approval of the trial in France. Meanwhile, I was still at GSK, working full time, and doing this at night, nonstop. Because my day job did require travel to Europe, I would stop by Paris and meet with him. Another sister of mine who did not have any affected children was a key help and we kept everything going. You really need to continually stay engaged and press the agenda forward, since there are so many things that pop up that can derail the program.
Finally, Patrick was able to treat four boys with the donated vector. The science paper came out in 2009. It was a big deal. That's when the venture money came in—Third Rock Ventures was the first firm to put big money behind gene therapy. They did a deal with Patrick to get access to the Intellectual Property to advance the trial, brought on scientists to continue the study, and made some improvements to the vector. That's what led to the new study reported recently in the New England Journal of Medicine. Of 17 patients, 15 of them are still fine at least two years after treatment.
You know how I said we felt thrilled that my son could leave the hospital after 100 days? When doing the gene therapy treatment, the hospital stay needed is much quicker. Shortly after one kid was treated, a physician in the hospital remarked, "He is fine, he's only here because of the trial." Since you get your own cells, there is no risk of graft vs. host disease. The treatment is pretty anticlimactic: a bag of blood, intravenously infused. You can bounce back within a few weeks.
Now, a few years out, approximately 20 percent of patients' cells have been corrected—and that's enough to hold off the disease. That's what the data is showing. I was blown away when it worked in the first two patients.
The formerly struggling field is now making a dramatic comeback.
Just last month, the first two treatments involving gene therapy were approved by the FDA to treat a devastating type of leukemia in children and an aggressive blood cancer in adults.
Now I run a company, Adverum Biotechnologies, that I wish existed back when my son was diagnosed, because I want people who are like me, coming to me, saying: "I have proof of concept in an animal, I need to get a vector suitable for human trials, do the work needed to file with the FDA, and move it into humans." Our company knows how to do that and would like to work with such patient advocates.
Often parents feel daunted to partake in similar efforts, telling me, "Well, you worked in pharma." Yes, I had advantages, but if you don't take no for an answer, people will help you. Everybody is one degree of separation from people who can help them. You don't need a science or business background. Just be motivated, ask for help, and have your heart in the right place.
Having said that, I don't want to sound judgmental of families who are completely paralyzed. When you get a diagnosis that your child is dying, it is hard to get out of bed in the morning and face life. My sister at a certain point had one child dying, one in the hospital getting a transplant, and a healthy younger child. To expect someone like that to at the same time be flying to an FDA meeting, it's hard. Yet, she made critical meetings, and she and her husband graciously made themselves available to talk to parents of recently diagnosed boys. But it is really tough and my heart goes out to anyone who has to live through such devastation.
Tragically, my nephew Oliver passed away 13 years ago at age 12. My other nephew was 8 when he had a cord blood transplant; our trial wasn't available yet. He had some bad graft vs. host disease and he is now navigating life using a wheelchair, but thank goodness, it stopped the disease. He graduated Stanford a year ago and is now a sports writer for the Houston Chronicle.
As for my son, today he is 17, a precocious teenager applying to colleges. He also volunteers for an organization called the Friendship Circle, providing friends for kids with special needs. He doesn't focus on disability and accepts people for who they are – maybe he would have been like that anyway, but it's part of who he is. He lost his cousin and knows he is alive today because Oliver's diagnosis gave us a head start on his.
My son's story is a good one in that he had a successful transplant and recovered.
Once we knew he would make it and we no longer needed our next child to be a match, we had a daughter using one of our healthy IVF embryos in storage. She is 14 now, but she jokes that she is technically 17, so she should get to drive. I tell her, they don't count the years in the freezer. You have to joke about it.
I am so lucky to have two healthy kids today based on advances in science.
And I often think of Oliver. We always try to make him proud and honor his name.
[Editor's Note: This story was originally published in November 2017. We are resurfacing archive hits while our staff is on vacation.]
Salzman and her son Spencer, 17, who is now healthy.
(Courtesy of Salzman)