Spontaneous Mutations Raise Autism Risk
Spontaneous Mutations Raise Autism Risk
A trio of new studies has revealed several genes and biological pathways that may contribute to autism spectrum disorders (ASD). Among other insights, the findings may help explain earlier evidence linking autism risk to older fathers.
ASD includes several related brain disorders, with symptoms ranging from mild to severe. People with ASD generally have trouble with social interactions and communication. Over the past few years, large research efforts have linked many rare mutations with ASD. But for at least 70% of ASD cases, there are still no known underlying genetic causes.
Three separate research teams set out to examine de novo DNA variations, which are found in a child’s DNA but not in either parent’s. These spontaneous mutations arise during the creation of germ cells (egg or sperm). While less frequent than the types of genetic variations that past studies have examined, they can be very harmful. The scientists believed these variations might offer new insights into ASD risk.
All 3 teams focused on exomes—the complete set of protein-coding regions in the genome. The exome represents only about 1.5% of the genome but harbors most disease-causing mutations. The researchers sequenced the exomes of affected children and their parents. One team also compared healthy siblings. In all, the scientists drew upon samples from 549 families. Two of the teams received substantial NIH funding, and all are members of the Autism Sequencing Consortium, which NIH helped to develop. The reports appeared together in the early online edition ofNature on April 4, 2012.
The studies showed that, while a single de novo mutation is unlikely to fully explain disease in a given patient, sporadic mutations widely distributed across the genome can raise the risk for ASD. Many of the genes implicated in the new studies were previously tied to ASD, but some weren’t. The genes tend to be related. Many are involved in fundamental developmental pathways, particularly in the brain.
Notably, one of the studies found an explanation for the previous discovery that fathers of children with autism were much more likely to be older. Fathers turned out to be 4 times more likely than mothers to transmit de novo mutations that increase ASD risk to their children—and the number of these mutations increased with the father’s age. This can be explained by the higher turnover in sperm cells. Each time DNA is copied, there’s a chance that errors will become part of an offspring’s DNA makeup.
“These results confirm that it’s not necessarily the size of a genetic anomaly that confers risk, but its location—specifically in biochemical pathways involved in brain development and neural connections. Ultimately, it’s this kind of knowledge that will yield potential targets for new treatments,” says Dr. Thomas R. Insel, director of NIH’s National Institute of Mental Health (NIMH).
“These studies begin to tell a more comprehensive story about the molecular underpinnings of autism that integrates previously disparate pieces of evidence,” says Dr. Thomas Lehner, chief of the NIMH Genomics Research Branch.
There are many forms of autism under the umbrella of ASD. Given the complexities, larger studies will be needed to fully understand the genetic events that affect ASD risk.
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* The above story is reprinted from materials provided by National Institutes of Health (NIH)
** The National Institutes of Health (NIH) , a part of the U.S. Department of Health and Human Services, is the nation’s medical research agency—making important discoveries that improve health and save lives. The National Institutes of Health is made up of 27 different components called Institutes and Centers. Each has its own specific research agenda. All but three of these components receive their funding directly from Congress, and administrate their own budgets.