Researchers studied the lack of functional CLN3 protein, which underlies Batten disease. They found lack of the protein leads to a breakdown of the M6PR receptor (green) in the lysosomes and subsequent disruption of needed lysosomal enzymes and the formation of normal lysosomes. Credit: Donny Bliss, NIH
A common theme among parents and family members caring for a child with the rare Batten disease is “love, hope, cure.” While inspiring levels of love and hope are found among these amazing families, a cure has been more elusive. One reason is rooted in the need for more basic research. Although researchers have identified an altered gene underlying Batten disease, they’ve had difficulty pinpointing where and how the gene’s abnormal protein product malfunctions, especially in cells within the nervous system.
Now, this investment in more basic research has paid off. In a paper just published in the journal Nature Communications, an international research team pinpointed where and how a key cellular process breaks down in the nervous system to cause Batten disease, sometimes referred to as CLN3 disease [1]. While there’s still a long way to go in learning exactly how to overcome the cellular malfunction, the findings mark an important step forward toward developing targeted treatments for Batten disease and progress in the quest for a cure.
The research also offers yet another excellent example of how studying rare diseases helps to advance our fundamental understanding of human biology. It shows that helping those touched by Batten disease can shed a brighter light on basic cellular processes that drive other diseases, rare and common.
Batten disease affects about 14,000 people worldwide [2]. For those with the juvenile form of this inherited disease of the nervous system, parents may first notice their seemingly healthy child has difficulty saying words, sudden problems with vision or movement, and changes in behavior. Tragically for parents, with no approved treatments to reverse these symptoms, the disease will worsen, leading to severe vision loss, frequent seizures, and impaired motor skills. The disease can be fatal as early as late childhood or the teenage years.
Batten disease also goes by the more technical name of juvenile neuronal ceroid lipofuscinosis. Using this technical name, it represents one of the more than 70 medically recognized lysosomal storage disorders.
These disorders share a breakdown in the ability of membrane-bound cellular components, known as lysosomes, to degrade the molecular waste products of normal cell biology. As a result, all this undegraded material builds up and eventually kills affected cells. In people with Batten disease, the lost and damaged cells cause progressive dysfunction within the nervous system.
Researchers have known for a while that the most common cause of this breakdown in people with Batten disease is the inheritance of two defective copies of a gene called CLN3. As mentioned above, what’s been missing is a more detailed understanding of what exactly a working copy of the CLN3 gene does and how its loss leads to the changes seen in those with this condition.
Hoping to solve this puzzle was an NIH-supported basic research team led by Alessia Calcagni and Andrea Ballabio, Baylor College of Medicine and Texas Children’s Hospital, Houston, and Telethon Institute of Genetics and Medicine, Naples, Italy.
As described in their latest paper, the researchers first generated an antibody that allowed them to visualize where in cells the protein encoded by CLN3 is found. Their studies unexpectedly showed that this protein has a role outside, not inside, the cell’s estimated 50-to-1,000 lysosomes. Before reaching the lysosomes, the protein first moves through another cellular component called the Golgi body, where many proteins are packaged.
They then identified all the other proteins that interact with the CLN3 protein in the Golgi body and elsewhere in the cell. Their data showed that CLN3 interacts with proteins known for transporting other proteins within the cell and forming new lysosomes.
That gave them a valuable clue: the CLN3 gene must be a player in these fundamentally important cellular processes of protein transport and lysosome formation. Among the proteins CLN3 interacts with in the Golgi body is a particular receptor called M6PR. The receptor known for its role in recognizing lysosomal enzymes and delivering them to the lysosomes, where they go to work inside these bubble-like structures degrading cellular waste products.
The researchers found that loss of CLN3 led this important M6PR receptor to be broken down within lysosomes. The breakdown, in turn, altered the normal shape of new lysosomes, and that limits their functionality. The researchers also showed that restoring CLN3 in cells that lacked this gene also restored the production of more functional lysosomes and lysosomal enzymes.
Overall, the findings point to a major role for CLN3 in the formation of lysosomes and their ability to function. Importantly, the findings also offer clues for understanding the mechanisms that underlie other forms of lysosomal storage disease, which collectively affect as many as one in every 40,000 people [3]. The work also may have broader implications for common neurodegenerative diseases, such as Parkinson’s and Alzheimer’s disease.
Most of all, this paper demonstrates the power of basic research to define needed molecular targets. It shows how these fundamental studies are helping families affected by Batten disease and supporting their love, hope, and quest for a cure.
Caption: Mila with researcher Timothy Yu and her mother Julia Vitarello. Mila’s head is covered in gauze because she’s undergoing EEG monitoring to determine if her seizures are responding to treatment. Credit: Boston Children’s Hospital
Starting about the age of 3, Mila Makovec’s parents noticed that their young daughter was having a little trouble with words and one of her feet started turning inward. Much more alarmingly, she then began to lose vision and have frequent seizures. Doctors in Colorado diagnosed Mila with a form of Batten disease, a group of rare, rapidly progressive neurological disorders that are often fatal in childhood or the teenage years. Further testing in Boston revealed that Mila’s disease was caused by a genetic mutation that appears to be unique to her.
No treatment existed for Mila’s condition. So, in an effort to meet that urgent need, Timothy Yu and his colleagues at Boston Children’s Hospital set forth on a bold and unprecedented course of action. In less than a year, they designed a drug that targeted Mila’s unique mutation, started testing the tailor-made drug for efficacy and safety on cells derived from her skin, and then began giving Mila the drug in her own personal clinical trial.
The experimental drug, which has produced no adverse side effects to date, hasn’t proved to be a cure for Mila’s disease [1]. But it’s helped to reduce Mila’s seizures and also help her stand and walk with assistance, though she still has difficulty communicating. Still, the implications of this story extend far beyond one little girl: this work demonstrates the promise of precision medicine research for addressing the unique medical challenges faced by individuals with extremely rare diseases.
Mila’s form of Batten disease usually occurs when a child inherits a faulty copy of a gene called CLN7 from each parent. What surprised doctors is Mila seemed to have inherited just one bad copy of CLN7. Her mother reached out online in search of a lab willing to look deeper into her genome, and Yu’s lab answered the call.
Yu suspected Mila’s second mutation might lie buried in a noncoding portion of her DNA. The lab’s careful analysis determined that was indeed the case. The second mutation occurred in a stretch of the gene that normally doesn’t code for the CLN7 protein at all. Even more unusual, it consisted of a rogue snippet of DNA that had inserted itself into an intron (a spacer segment) of Mila’s CLN7 gene. As a result, her cells couldn’t properly process an RNA transcript that would produce the essential CLN7 protein.
What might have been the end of the story a few years ago was now just the beginning. In 2016, the Food and Drug Administration (FDA) approved a novel drug called nusinersen for a hereditary neurodegenerative disease called spinal muscular atrophy (SMA), caused by another faulty protein. As I’ve highlighted before, nusinersen isn’t a typical drug. It’s made up of a small, single-stranded snippet of synthetic RNA, also called an oligonucleotide. This drug is designed to bind to faulty RNA transcripts in just the right spot, “tricking” cells into producing a working version of the protein that’s missing in kids with SMA.
Yu’s team thought the same strategy might work to correct the error in Mila’s cells. They reasoned that an appropriately designed oligonucleotide could block the effect of the rogue snippet in her CLN7 gene, allowing her cells to restore production of working protein.
The team produced candidate oligonucleotides and tested them on Mila’s cells growing in a lab dish. They found three candidates that worked. The best, which they named milasen after Mila, was just 22-nucleotides long. They designed it to have some of the same structural attributes as nusinersen, given its established safety and efficacy in kids with SMA.
Further study suggested that milasen corrected abnormalities in Mila’s cells in a lab dish. The researchers then tested the drug in rats and found that it appeared to be safe.
A month later, with FDA approval, they delivered the drug to Mila, administered through a spinal tap (just like nusinersen). That’s because the blood-brain barrier would otherwise prevent the drug from reaching Mila’s brain. Beginning in January 2018, she received gradually escalating doses of milasen every two weeks for about three months. After that, she received a dose every two to three months to maintain the drug in her system.
When Mila received the first dose, her condition was rapidly deteriorating. But it has since stabilized. The number of seizures she suffers each day has declined from about 30 to 10 or less. Their duration has also declined from 1 or 2 minutes to just seconds.
Milasen remains an investigational drug. Because it was designed specifically for Mila’s unique mutation, it’s not a candidate for use in others with Batten disease. But the findings do show that it’s now possible to design, test, and deploy a novel therapeutic agent for an individual patient with an exceedingly rare condition on the basis of a thorough understanding of the underlying genetic cause. This is a sufficiently significant moment for the development of “n = 1 therapeutics” that senior leaders of the Food and Drug Administration (FDA) published an editorial to appear along with the clinical report [2].
Yu’s team suspects that a similar strategy might work in other cases of people with rare conditions. That tantalizing possibility raises many questions about how such individualized therapies should be developed, evaluated, and tested in the months and years ahead.
My own lab is engaged in testing a similar treatment strategy for kids with the very rare form of premature aging called Hutchinson-Gilford progeria, and we were heartened by this report. As we grapple with those challenges, we can all find hope and inspiration in Mila’s smile, her remarkable story, and what it portends for the future of precision medicine.
References:
[1] Patient-customized oligonucleotide therapy for a rare genetic disease. Kim J, Hu C, Moufawad El Achkar C, Black LE, Douville J, Larson A, Pendergast MK, Goldkind SF, Lee EA, Kuniholm A, Soucy A, Vaze J, Belur NR, Fredriksen K, Stojkovska I, Tsytsykova A, Armant M, DiDonato RL, Choi J, Cornelissen L, Pereira LM, Augustine EF, Genetti CA, Dies K, Barton B, Williams L, Goodlett BD, Riley BL, Pasternak A, Berry ER, Pflock KA, Chu S, Reed C, Tyndall K, Agrawal PB, Beggs AH, Grant PE, Urion DK, Snyder RO, Waisbren SE, Poduri A, Park PJ, Patterson A, Biffi A, Mazzulli JR, Bodamer O, Berde CB, Yu TW. N Engl J Med. 2019 Oct 9 [Epub ahead of print]