Lithium rescues synaptic plasticity and memory in Down syndrome mice

Down syndrome (DS) patients exhibit abnormalities of hippocampal-dependent explicit memory, a feature that is replicated in relevant mouse models of the disease. Adult hippocampal neurogenesis, which is impaired in DS and other neuropsychiatric diseases, plays a key role in hippocampal circuit plasticity and has been implicated in learning and memory. However, it remains unknown whether increasing adult neurogenesis improves hippocampal plasticity and behavioral performance in the multifactorial context of DS. We report that, in the Ts65Dn mouse model of DS, chronic administration of lithium, a clinically used mood stabilizer, promoted the proliferation of neuronal precursor cells through the pharmacological activation of the Wnt/β-catenin pathway and restored adult neurogenesis in the hippocampal dentate gyrus (DG) to physiological levels. The restoration of adult neurogenesis completely rescued the synaptic plasticity of newborn neurons in the DG and led to the full recovery of behavioral performance in fear conditioning, object location, and novel object recognition tests. These findings indicate that reestablishing a functional population of hippocampal newborn neurons in adult DS mice rescues hippocampal plasticity and memory and implicate adult neurogenesis as a promising therapeutic target to alleviate cognitive deficits in DS patients.

Autism Blood Test Shows Promise

Diagnosing autism could soon be much simpler, with researchers saying this week that they’ve developed a blood test that appears to identify those with the disorder even before symptoms are apparent.

The early-stage test developed at Boston Children’s Hospital may be able to flag about two-thirds of those with autism, researchers reported in the journal PLOS ONE.

Currently, clinicians rely on observation to screen children for autism. Most kids are not diagnosed until after age 4, according to the U.S. Centers for Disease Control and Prevention.

But a blood test offers the promise of flagging kids and potentially enrolling them in early intervention programs even before symptoms appear.

In order to develop the test, researchers analyzed blood samples from 66 boys with autism and 33 without the developmental disorder in an effort to establish patterns. Ultimately, the scientists were able to focus on a group of 55 genes that they used to successfully identify autism with 68 percent accuracy in a second test group made up of 104 people with autism and 82 controls.

“It’s clear that no single mutation or even a single pathway is responsible for all cases,” said Isaac Kohane of Boston Children’s Hospital who worked on the research. “By looking at this 55-gene signature, which can capture disruptions in multiple pathways at once, we can say with about 70 percent accuracy, ‘this child does not have autism,’ or ‘this child could be at risk,’ putting him at the head of the queue for early intervention and evaluation. And we can do it relatively inexpensively and quickly.”

The blood test is not yet ready for prime time, researchers said, but it has been licensed to the company SynapDx for further exploration and potential commercialization.