Disease-causing repeats help human neurons function, study finds
Over half of our genomes are made of repeating elements within DNA. In rare cases, these repeats can become unstable and grow in size. These repeat “expansions” cause neurodegenerative diseases such as ALS and dementia as well as learning disorders and autism in Fragile X syndrome.
Research to date has focused on how these expanded repeats cause disease, but little attention has been given to the repeats themselves and whether they might have normal functions in genes.
By focusing on the biology of healthy nerve cells, a Michigan Medicine team found that repeats in the gene that causes Fragile X Syndrome normally regulate how and when proteins are made in neurons. This process may be important for learning and memory in these nerve cells and potentially in people.
“The repeats function like a switch, slowing down protein production and then quickly turning things back on,” explains principal investigator Peter Todd, M.D., Ph.D., associate professor of neurology at Michigan Medicine.
This study first used rodents and then created human neurons from patient stem cells. The scientists found that the repeat and its translation in the beginning of the Fragile X gene slow down production of the Fragile X protein, which is important in learning and memory. However, when neurons are stimulated, this repeat translation goes away and the Fragile X protein levels increase at synapses (the connections between nerve cells), suggesting that the repeat and its translation regulate this local protein production.
Armed with this discovery about how the repeat functions normally, the team worked with Ionis Pharmaceuticals to develop an antisense oligonucleotide (ASO), a short strand of modified DNA that can specifically target the transcripts of a defective gene to correct an abnormality. Ionis’ ASOs are designed to bind precisely with RNA, halting the process of creating a disease-causing protein which could block translation of expanded Fragile X repeats that are toxic to neurons and cause human disease.
This ASO has produced two remarkable results. First, it decreased the toxicity that these repeats caused in rodent and human neurons. Second, this blockade of repeat translation triggered a big increase in the Fragile X protein, whose loss causes Fragile X syndrome. “The results suggest that we have simultaneously corrected two of the big problems that happen in Fragile X-associated disorders,” Todd says.
This research offers a novel pathway forward to treatments in this class of neurological diseases.
“To develop a new treatment strategy, we really needed to understand the native biology of how these repeats work and why they are there in the first place,” says Todd. “The study was done in dishes, and so there is still a long way before it can be tried in patients, but advancing our understanding of normal nerve cell biology is a crucial step to find cures.”
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