Genomic analysis pinpoints a potential target for treatment of Down syndrome

A study of changes in the patterns of gene activity in the brains of people with Down syndrome reveals that the formation of the brain’s white matter is affected throughout life, a finding that suggests treatment might be possible for the condition that affects 400,000 Americans.
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Fluorescent images of myelinated nerve connections in Down Syndrome brain (right) compared to those in non-affected brain.

A study of changes in the patterns of gene activity in the brains of people with Down syndrome reveals that the formation of the brain’s white matter is affected throughout life, a finding that suggests treatment might be possible for the condition that affects 400,000 Americans.

Researchers at Yale University and Boston University found abnormal patterns of gene expression in the developing brain of individuals with Down syndrome that influence the maturation of oligodendrocytes — the cells that make the fatty myelin coating that insulates nerve fibers and make rapid transmission of nerve impulses possible. These expression patterns continue into adulthood and are not limited to early development as previously believed, according to the study published Feb. 25 in the journal Neuron.

“Defective myelination may be one of the factors causing the intellectual disability that is a hallmark of Down syndrome,” said John Silbereis, postdoctoral fellow in the Department of Neuroscience and the Kavli Institute for Neuroscience at Yale, and co-first author of the paper.

It may be possible that individuals with Down syndrome might benefit from myelin-regenerating drugs under development to treat conditions like multiple sclerosis, which are also marked by altered myelination of nerve cells, the authors say.

Typically, people are all born with pairs of 23 chromosomes but all people with Down syndrome have a third copy of chromosome 21. However, the exact mechanisms that cause intellectual disabilities have been difficult to pin down. Under the direction of senior authors Nenad Sestan, professor of neuroscience, genetics and psychiatry at Yale, and Tarik F. Haydar at Boston University, researchers did a comprehensive genomic analysis of brain tissue across ages — from prenatal to 40-year-old adults. This analysis identified over 1,300 genes that were disrupted at some point in the development of individuals with Down syndrome. They found 95% of these genes were in regions of the genome other than chromosome 21.

These results indicate that triplication of chromosome 21 have large and widespread effects on gene expression patterns in individuals with Down syndrome, say the scientists.

Hyo Jung Kang of Yale is a co-first author of the paper. Sestan also holds posts at the Kavli Institute, Section of Comparative Medicine, Program in Cellular Neuroscience, Neurodegeneration and Repair, and the Child Study Center.

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Bill Hathaway: william.hathaway@yale.edu, 203-432-1322