Monica Coenraads had a terrible feeling something was wrong with her 14-month-old baby, Chelsea. She had not learned to walk. She had one word, duck, and then lost it.
During a family vacation to Barbados more than 20 years ago, Chelsea cried the whole time. She bit her parents so hard they bled. She was only happy in the hotel room with the shades drawn.
“I got home and said, ‘That’s it. We have to figure out what is wrong.’”
What happened upended Ms. Coenraads’s life.
Chelsea, it turned out, had a rare genetic disease, Rett Syndrome. It’s one of about 7,000 rare or orphan diseases — defined in the U.S. as an illness that affects fewer than 200,000 people nationwide — with more such diseases being identified every day. Ninety-five percent of them have no known therapies. They are overlooked by most scientists, and some illnesses may be untreatable, even if they are understood. And what research there was has largely been halted as labs closed in response to coronavirus fears.
Ms. Coenraads, 57, who lives in Trumbull, Conn., has encouraged research into Rett Syndrome where there had been none, providing hope for her daughter and the small number of people who live with the disease, and showing one way that a determined person can succeed against such odds.
When frantic parents of children with other rare disorders ask how she did it and what they can do, Ms. Coenraads recognizes the fear in their voices.
“We have no choice,” she said. “We are desperate parents. We have children with horrible diseases.”
She talks to every parent who calls, but, she said, “I always get off the phone thinking, ‘You don’t know what you’re up against. It is daunting, and it will consume your life.’”
What follows are the stories of Ms. Coenraads and three people who have succeeded in promoting research on uncommon diseases, but in very different ways.
‘Single-Minded Advocacy’
Ms. Coenraads is not extraordinarily wealthy and had no science background when she started searching for help for Chelsea, who is now 23. She ran a small Italian restaurant in Stamford, Conn., but sold it when she was pregnant with Chelsea, intending to be a full-time mother for a year or two.
She was, and then some.
The Coenraads had never heard of Rett Syndrome when they received that diagnosis for Chelsea, at age 2. It is a neurological disorder caused by a mutated gene on the X chromosome that destroys a child’s abilities to walk, talk, eat and even breathe easily. There was no treatment, no cure. And because it is so rare — it affects only 1 in 10,000 girls and almost no boys — it seemed destined to languish as a research curiosity, not something companies would pursue.
Ms. Coenraads refused to accept that situation.
“I just had to believe there was hope, and if we could get the right people involved with sufficient funding, we could move therapeutics forward,” she said.
Ms. Coenraads knew she needed money to attract scientists, so she started the Rett Syndrome Research Trust in 2007. It has since raised $70 million, nearly all from private donations and galas with silent and live auctions — “typical nonprofit fund-raising,” Ms. Coenraads said.
But money was not enough.
“I wasn’t going to sit back and assume research was happening and things would work out,” she said. She wanted to figure out the bottlenecks and what would be needed to move the work forward.
She began by looking for scientists who knew about Rett and calling them.
“Everyone helped,” she said. “Everyone gave me the names of a few others. Within six months, I had a plan.”
She explained what was involved:
“You have to get up to speed on the science, which is no easy feat,” she said. “And after that, you must understand what has been done and, more important, what has to be done.”
If that weren’t daunting enough, she said, “you have to learn the basics of drug development and how to recruit scientists and companies to work on your disease.” And she cautioned that with academic researchers, “you have to recognize when a project sure is interesting but isn’t necessarily going to move the needle closer to a cure.”
Even after a breakthrough, academics usually are not able to initiate the sort of clinical studies that are needed to show a research discovery can help patients.
“Ninety-nine percent of the time, the discovery will languish,” she said. “Scientists will move on to their next discovery.”
Once she had gathered enough academic research, she was able to “hit the ground running,” she said, contacting companies and telling them what they wanted to hear: Yes, there was a mouse model of the disease. Yes, there were so-called natural history studies that illustrate what to expect if the disease was not treated.
One scientist, Sir Adrian Bird at the University of Edinburgh, described Ms. Coenraads’s work in a ceremony when his university conferred her an honorary degree: “For what started as a tiny charity to inspire world-class research on a disorder that initially languished in obscurity and ignorance, and take it all the way to the brink of clinical application in less than 20 years is an amazing achievement.”
He added: “There is no doubt that it would not have happened without Monica’s single-minded advocacy.”
At 23, Chelsea is in a wheelchair, unable to speak, stand, eat or use her hands, and she needs a feeding tube. She has scoliosis and intractable seizures, as well as tight, painful muscles. But Chelsea is aware and loving, Ms. Coenraads said, with, “a beautiful and engaging personality.”
The coronavirus has presented new challenges for her care. Because she’s at such high risk, caregivers cannot enter the Coenraads’ home. Ms. Coenraads’s husband, Pieter, who owns a store that sells uniforms and medical scrubs, has to go to work every day so Ms. Coenraads is now on her own to care for Chelsea.
She helps her daughter stretch every day and exercise on a treadmill, using a device that supports her and holds her upright.
“It was very hard in the beginning, but we found our rhythm,” Ms. Coenraads said. “Now I can get work done and care for her.”
She Became Her Own Expert
Most seeking a cure for a rare genetic disease hope to recruit scientists and companies to do the work. But one determined couple took another route. They went back to school and became scientists themselves.
The journey of Sonia Vallabh, 36, and her husband, Eric Minikel, began in December 2011. She was living in Cambridge, Mass, and had just graduated from Harvard Law School. Her mother died the year before, at age 52, from Gerstmann-Sträussler-Scheinker syndrome, a degenerative and uniformly fatal brain disease caused by misfolded prion proteins.
It is estimated that about one to ten out of every 100 million people has G.S.S. Symptoms begin subtly, progressing from clumsiness to an inability to walk and developing slurred speech that eventually inhibits talking. Late stages often result in dementia.
Knowing there was a 50-50 chance, Dr. Vallabh took a genetic test that gave her the bad news that she was going to develop G.S.S., and probably around the same age as her mother.
Dr. Vallabh had just started work at a small consulting company, and her husband, now 36, had recently gotten a degree in urban planning from M.I.T. The couple decided they had to learn more. They knew there was no treatment or cure for G.S.S. Was there any promising research?
They realized they didn’t understand enough about the science to ask the right questions.
“There was a certain amount of vocabulary needed,” Dr. Vallabh said. “I didn’t want to call people and have them say, ‘Oh yeah, we’re working on a cure. We will call you in five years.’”
She started night classes in molecular biology, biochemistry, cell biology and genetics at the Harvard Extension School and audited courses at M.I.T.
Then she decided she needed to see how things were done in a lab. So she got a job as a research technician at Massachusetts General Hospital, quitting her day job as a lawyer. Her husband soon followed, quitting his urban-planning job and starting a position there in bioinformatics.
Soon they decided they had to study prion diseases, so they enrolled as Ph.D. students at Harvard. After receiving their degrees, they were hired at the Broad Institute in Cambridge with a laser focus on finding a treatment that might work in Dr. Vallabh’s lifetime.
They decided their best bet was molecules that can block the production of prion proteins called antisense oligonucleotides. Drugs based on the molecules work in other genetic disorders; they enter the brain by being injected into the spinal fluid, and appear to be safe.
In October 2014, the couple met with Ionis, a small biotechnology firm, to see if the company would develop a prion antisense oligonucleotide.
Dr. Vallabh learned from the meeting that the rules are different for rare diseases. For common diseases, companies do the preliminary work. But with rare diseases, “the burden shifts,” she said.
It is not enough to have data supporting an idea for an effective treatment. Dr. Vallabh and Dr. Minikel had to develop a test to show the drug was working. They had to do studies showing the treatment changed the disease’s course in animals. They had to sign up more than 200 people willing to participate in research or clinical trials. And they had to meet with the Food and Drug Administration.
“We took on a lot,” Dr. Vallabh said.
But in 2018, Ionis agreed to work toward a clinical trial.
A preparatory step was to recruit and study people who have the gene but do not yet have symptoms and others without the gene. The aim was to see if those with the gene have subtle markers of disease progression. That study began in 2017, but recruitment was suspended in March because of coronavirus.
“I believe in the drug. I believe in the strategy,” Dr. Vallabh. And, she said, once the trial starts, “I do think we can get a rigorous answer in a relatively short time frame, within a year.”
But is it really feasible for others to take the path Dr. Vallabh and Dr. Minikel took?
“I know, I know,” Dr. Vallabh said. “We are and aren’t all in the same boat. Every disease has its own landscape.”
It is almost, but not quite, unheard-of for people with a rare disease mutation to do their own research, Dr. Vallabh said.
People like her, “are rare, but not an n of 1,” she adds.
‘Working Against the Clock’
Neena Nizar, 42, grew up in Dubai knowing something was wrong with her, but unable to find out what. One doctor after another proposed an incorrect diagnosis. She was told she had rickets, then that she had polio. She had a series of useless surgeries.
She eventually learned the diagnosis: Jansen’s metaphyseal chondrodysplasia, a genetic disease so rare only about 30 cases have been reported since it was first described in 1970. Patients have deformed bones, short limbs, small hands with clubbed fingers, dwarfism and a large upper face but a tiny jaw.
Today, Dr. Nizar has a Ph.D. in educational leadership and lives in Elkhorn, Neb., a suburb of Omaha, where she is married and has two boys, now 11 and 9. Her search for a diagnosis began when she realized her sons, as they were growing up, shared her affliction.
“I sent X-rays around the world of my kids and myself,” she said. “I sent them to all of the skeletal dysplasia experts, but no one knew what it was.”
She also contacted more than 50 geneticists.
Most didn’t know what their condition was. But a pediatric geneticist in India, Dr. Sheela Nampoothiri, figured it out after taking one look at Dr. Nizar’s sons’ X-rays. She remembered seeing a slide in a medical school class. The professor said he was going to skip right over that slide, the doctor told Dr. Nizar, explaining to students that “you will never see this.”
The doctor sent Dr. Nizar’s DNA for genetic testing. She had chondrodysplasia, and by then, the boys’ bones were already badly bent.
“I knew we had to get the kids treatment,” she said.
Dr. Harald Jueppner, a pediatric nephrologist at Massachusetts General, was the researcher who first identified the mutation that caused the condition. Dr. Nizar learned that he had been studying the mutated gene, called a PTH/PTHrP receptor, for 20 years out of scientific interest. But he had never seen a patient. She told him he could now see three — herself and her two sons.
She also learned that Dr. Jueppner and a colleague, Thomas Gardella, had found in lab experiments that certain peptides, or short chains of amino acids, looked promising as possible treatments for Jansen’s. At that point Dr. Nizar latched onto the researchers, urging them to study the peptides for Jansen’s. They tried one of them in animal experiments. It partially reversed some of the bone abnormalities, Dr. Jeuppner said, but, he added, “remember, this mouse model of Jansen’s is far from being ideal.”
Dr. Nizar stayed in constant contact with Dr. Jueppner and Dr. Gardella prodding them to not lose sight of the work.
“Working with Neena has been an incredible experience.” Dr. Jueppner said. “She is a force of nature.”
In 2017, Dr. Nizar set up a foundation to support research. But she was not in a good position to fund raise. “We only had eight patients, and I couldn’t go to GoFundMe. My family and friends are tired of giving me money,” she said.
So Dr. Nizar spoke to experts at conferences hosted by the National Institutes of Health, hoping to find a way to receive research funds. With her enthusiastic prodding, Dr. Jueppner and Dr. Gardella received a grant to study and improve the peptides they’d found as a possible Jansen’s treatment
In 2018, Dr. Nizar asked the F.D.A. for guidance. “They were surprised we didn’t have a drug company, ” she said. “I told the lady at the F.D.A. that, at this point, I am the drug company.”
The researchers at Massachusetts General, she said, “have something we can try, and I want to get it to our kids.” Time is limited, she stressed. “Once they hit puberty, some of their bones set. We are working against the clock.”
The F.D.A. told her and the researchers at Massachusetts General what preclinical data would be required before testing in patients would be allowed.
At the time, Dr. Jueppner estimated that the data might be available in a year or two. But the coronavirus changed all that. The lab shut down on March 20 and is slowly reopening, he said.
If the research does proceed and if all goes well, Dr. Nizar said, she will be faced with a new set of problems.
“How can we make it in the absence of a pharmaceutical company?” she asks. Her tiny foundation certainly cannot manufacture the drug, and no one even holds patent rights.
“No matter how good your science is, you or your scientists can only take it so far,” Dr. Nizar said.
Building His Own Company
Matt Wilsey knew a lot about what it takes for a company to succeed. The 42-year-old tech entrepreneur and investor had a wide array of friends in California’s Silicon Valley. But he never thought he’d have to use his business savvy to try to save his own child.
When Grace Wilsey was born in 2009, Mr. Wilsey and his wife, Kristen, now 39, knew right away she had some problems. She was floppy and did not seem to be alert. She did not develop normally — she did not sit up, or crawl. She did not learn to walk or talk.
When Grace was three, Mr. and Mrs. Wilsey found out why — Grace had a genetic disorder so rare only one other child in the world, a little boy in Utah, was known to have it. It was caused by a mutation in a gene, NGLY1, but scientists did not know what that gene did or why a mutation would result in such devastating effects. They didn’t know how the disease would progress or if Grace would die young.
Mr. Wilsey sprung into action. He asked Stanford physicians for guidance and was told he needed a foundation with a good advisory committee. Having money is great, they said, but you have to know whom and what to spend it on.
He started a foundation and began cold calling and emailing scientific luminaries, asking if they would talk to him and agree to work on the project. So far, the foundation has raised $9 million, mostly from friends and family.
Carolyn Bertozzi, a chemist at Stanford, was one of his initial recruits.
“He is really good at forming personal relationships,” Dr. Bertozzi said. “That allowed him to convince total strangers to join his team and work on his cause.”
She was also touched by Mr. Wilsey’s story and intrigued by the scientific challenge.
“Imagine you are a parent. No one had ever had this diagnosis before, and you have no idea what to expect.”
She was not alone. Mr. Wilsey managed to recruit about 150 eminent scientists as advisers, with some actively working on the research problem. They include Jennifer Doudna, the Crispr gene-editing pioneer; Dr. Shinya Yamanaka, the 2012 Nobel laureate; and Rusty Gage, an expert on nerve development.
Mr. Wilsey understands that it might appear his success is a result of his money and connections. But, he said, they have little to do with it. “Many of the people we work with don’t even receive funding from us,” he said. The “magic sauce,” he said, is “hard work, time and constant relationship building.”
In 2017 he also invited patients from around the world to come to Palo Alto for a conference, and 21 families attended. He hopes to repeat the conferences every few years for the growing number of identified NGLY1 patients, now up to 70.
The scientific team finally figured out that the mutated gene controls the way other genes function. Now they hope to develop a treatment — gene therapy, or anything else that works.
To move along whatever treatment looks promising, Mr. Wilsey and Dr. Bertozzi formed a company, Grace Science, LLC.
Mr. Wilsey realizes he has advantages others do not. He and his wife have the luxury of being able to work full time on their project. He has wealthy friends and relatives who donated generously to their foundation.
And they can afford intensive therapy for Grace, who is now 10 years old. Mr. Wilsey said Grace’s doctors told him his daughter probably is at the level of an 18 month old. But he thinks she understands more than that. She can’t talk, but he thinks she can communicate with her hands and eyes.
Mr. Wilsey knows the disease seems to accelerate once children hit puberty, with an increase in seizures and greater risk of aspiration and choking, as well as more sleep disturbances. Children die, although he tries not to think about that.
“That’s a constant reminder that the clock is ticking,” Mr. Wilsey said. “You really can’t give up. Even if the idea creeps into your mind, you push it right out.”