A potential new strategy for treating fragile X syndrome, the most common inherited cause of intellectual disability has been identified by researchers at Emory University School of Medicine.
The researchers have found that a class of drugs called phosphoinositide-3 (PI3) kinase inhibitors can correct defects in the anatomy of neurons seen in a mouse model of fragile X syndrome. In experiments with cultured neurons from the hippocampus, a brain region involved in learning and memory, the drugs could restore normal appearance and levels of protein production at synapses, the junctions between cells where chemical communication occurs. The results, published online this week in the Journal of Neuroscience, suggest that PI3 kinase inhibitors could help improve learning and cognition in individuals with fragile X syndrome.
"This is an important first step toward having a new therapeutic strategy for fragile X syndrome that treats the underlying molecular defect, and it may be more broadly applicable to other forms of autism," says senior author Gary Bassell, professor of cell biology and neurology at Emory University School of Medicine. He adds that his group has recently begun experiments in the mouse model to assess PI3 kinase inhibitors' effects on behaviors associated with fragile X syndrome.
In the United States, fragile X syndrome is the most common known one-gene cause of autism, accounting for between two and five percent of cases. Mutations in the PTEN gene and tuberous sclerosis genes, which in humans can lead to autism, also perturb the signaling of the PI3 kinase pathway, Bassell says. This connection suggests that PI3 kinase inhibition might be a viable strategy for treating individuals with mutations affecting this pathway.
While clinical trials in humans testing the effectiveness of another class of drugs, metabotropic glutamate receptor antagonists, against fragile X are well underway, Bassell says "the new approach may offer a different way to calm the overactive signaling, and also restore the glutamate receptor sensitivity that is lost in fragile X."
The genetic mutation responsible for fragile X prevents production of an RNA binding protein, FMRP, which regulates the production of many other proteins at synapses of brain cells. FMRP's absence leads to overactive signaling and protein production at synapses.
"The focus in the field has been on glutamate receptor antagonists," Bassell says. "The effects on glutamate receptor signaling are a big piece of fragile X, but they're not the only piece."
At their synapses, fragile X neurons produce proteins indiscriminately compared to unaffected neurons, he says. The "overexuberant" protein production leads to structural changes at their synapses, including a hyperabundance of dendritic spines. These spines are small protrusions that transmit electrical signals to adjacent neurons, and contribute to the communication between individual neurons in the brain.
Gross and Bassell discovered that in cells from mice where the FMRP gene has been deleted, the PI3 kinase enzyme is three times more active. PI3 kinase regulates protein synthesis in response to the electrochemical signals neurons send each other. The authors showed that tamping down PI3 kinase activity in fragile X neurons can restore normal levels of both protein synthesis and dendritic spine density.
PI3 kinase inhibitors are already under investigation for their anti-cancer properties, and some drugs of this type, such as wortmannin, can be toxic to normal cells. Bassell notes that this type of drugs would need to be used at low doses to only dampen excess signaling of protein production caused by fragile x. The drugs his team tested were effective in correcting fragile X molecular defects at levels five times lower than those usually employed, and did not reduce protein production in normal cells.
Bassell anticipates that drugs that preferentially inhibit the subtype of PI3 kinase present only in neurons hold greater promise as a novel therapeutic strategy."A few of these subtype-specific drugs are already available for researchers, and we are involved in efforts to test these more specific drugs in the fragile x mouse model," he says.
"This is a really exciting time for fragile x research because progress is occurring at a fast pace," Gross says. "I look forward to testing our theory of this mechanistic link between fragile x and autism, which suggests that a specific drug treatment could be broadly applicable."