CHICAGO (Reuters) – A sweeping study of hundreds of families with autism has found that spontaneous mutations can occur in a parent’s sperm or eggs that increase a child’s risk for autism, and fathers are four times more likely than mothers to pass these mutations on to their children, researchers said on Wednesday.
The results of three new studies, published in the journal Nature, suggest mutations in parts of genes that code for proteins – called the exome – play a significant role in autism.
And while many of these genetic mistakes are harmless, they can cause big problems when they occur in parts of the genome needed for brain development. One of the three teams found these glitches may result in a five- to 20-fold higher risk of autism.
“These results confirm that it’s not the size of the genetic anomaly that confers risk, but its location,” said Dr. Thomas Insel, director of the National Institute of Mental Health, which funded one of the studies.
Among the other findings, the teams – led by Dr. Mark Daly of the Broad Institute at Harvard and Massachusetts Institute of Technology, Dr. Matthew State of Yale University and Dr. Evan Eichler of the University of Washington in Seattle – identified several hundred new suspect genes that could eventually lead to new targets for autism treatments.
Many of the researchers were part of the Autism Sequencing Collaborative, the largest effort of its kind to use advanced gene sequencing technology to identify the genetic underpinnings of autism.
Scientists previously have found dozens of genes that may raise the risk of autism. But genetic causes only explain about 10% of cases, and recent studies have pointed to environmental factors, possibly arising at conception, as a potential trigger.
For this study, researchers sequenced data from 549 families with an autistic child and both parents available. In most of these families, only one child had autism.
They identified at least three genes using this approach, and a fourth using a different approach.
Dr. Joseph Buxbaum, director of the Seaver Autism Center at Mount Sinai School of Medicine in New York and a co-author of one of the studies, said the combined results from the three studies suggest some 600 to 1,200 genes may contribute the risk of developing autism.
The trick will be identifying specific networks in the brain in which these genes interact, so that researchers can begin to develop new treatments.
“We now have a good sense of the large number of genes involved in autism,” Dr. Buxbaum said.
One of the studies by Dr. Evan Eichler and colleagues at the University of Washington in Seattle suggested how environmental factors might influence genetics.
They looked specifically to see where these spontaneously occurring genetic mistakes were coming from: the sperm or the egg.
They found that new mutations occurred four times more frequently in sperm than in eggs, and the older the father, the more likely he was to have sperm with these spontaneous mutations.
One possible reason for this, Dr. Buxbaum said, is that men make sperm every day, and this high turnover rate increases the chance for errors to occur in the genetic code that could be passed on to their offspring.
“It tells us that sperm production is an imperfect process,” Dr. Buxbaum said in a telephone interview.
“It’s primarily driven by a dad’s age. That makes sense. As you get older, there are more and more chances for problems.”
He said these findings support other studies that show older fathers have a slightly increased risk of having a child with an autism spectrum disorder.
Dr. Kevin Mitchell, a geneticist at Trinity College Dublin who was not involved in the research, said in a statement the studies help explain how autism can be an inherited disorder but not always run in families.
“The explanation is that many cases are caused by new mutations – ones that arise in the germline (eggs and sperm). The studies reported in Nature are trying to find those mutations and see which genes are affected,” he said.
The researchers say the studies just scratch the surface of what will be needed to fully understand the genetic causes of autism. But the new approach, sequencing genetic changes in the region where genes code for proteins, appears to be the best place to look.
“Prior to the advent of new DNA sequencing technology, we were largely wandering in the dark searching for autism genes,” said Dr. Matthew State, co-director of the Yale Program on Neurogenetics and a senior author of one the three papers.
“Now we are getting a clear view of the genetic landscape and finally have the tools in hand to find a large proportion of the many genes contributing to autism.”