Mouse Model of Autism Offers Insights For Human Patients

A new mouse model of a genetically-linked type of autism reveals more about the role of genes in the disorder and the underlying brain changes associated with autism’s social and learning problems.

Scientists at Duke Health who developed the new model also discovered that targeting a brain receptor in mice with this type of autism could ease repetitive behaviors and improve learning in some animals.

Their report, published May 10 in the journal Nature Communications, suggests that among more than a dozen different lines of mice developed around the world to mirror autism caused by mutations to the SHANK3 gene, Duke researchers are the first to create a mouse in which that gene has been completely eliminated.

The total “knockout” of the gene makes the model more effective for studying SHANK3-related autism and Phelan-McDermid syndrome in humans, many of whom are missing the gene completely, said senior author Yong-hui Jiang, M.D., Ph.D., an associate professor of pediatrics and neurobiology

“This is an important first step in understanding the process of the disorder in humans,” Jiang said. “For many families affected by autism, this is something that could provide hope and potentially lead to a treatment.”

Image shows two mice.
The knockout mice would vocalize less, groom obsessively to the point of losing fur, fail to heed the established social hierarchy in groups, and were often unable to locate their own homes, wandering into strangers’ nests. Credit: Duke Health.

SHANK3 is essential to the function of synapses in the brain and communication between neurons.

Jiang said autism researchers worldwide could use the mouse model to study ways to compensate for the gene and improve symptoms in people with autism spectrum disorders and Phelan-McDermid Syndrome, a more profound developmental condition caused by mutations to SHANK3 and other genes in chromosome 22.

Over the past five years, researchers observed abnormal brain activity in the SHANK3 knockout mice when compared to controls. The knockout mice would vocalize less, groom obsessively to the point of losing fur, fail to heed the established social hierarchy in groups, and were often unable to locate their own homes, wandering into strangers’ nests.

“Some of the repetitive behaviors, inability to read social cues, and restricted interests copy many of the symptoms we see in people with autism,” said co-lead author Alexandra Bey, an M.D./Ph.D. candidate at the Duke University School of Medicine. Scientists at the University of North Carolina-Chapel Hill and Fudan University in Shanghai also contributed to the report.

In one experiment, mice were placed in a box with numerous holes and paths to explore. Curious control mice roamed while knockout mice often stuck to a small area and repeated the same routes.

“This replicates what see in many children with autism,” Bey said. “In children, perseveration is a behavior such as playing with the same toy over and over again in the same way, and not exploring new ways to interact with it.”


A new mouse model of a genetically-linked type of autism reveals more about the role of the SHANK3 gene in the disorder and the underlying brain changes associated with autism’s social and learning problems.

As they studied brain activity in the knockout mice, the researchers also found prominent changes in a receptor in the brain known as mGluR5 and other proteins that support the function of neurons and synapses, said co-lead author Xiaoming Wang, M.D., Ph.D., senior research associate in Duke’s department of pediatrics. The team tested two chemical compounds that target the mGluR5 receptor and found they could actually relieve the animals of some of their repetitive habits or enhance their learning.

“The regulation of this receptor is complex and gives rise to other behavioral challenges, but this is a clue for further research,” Wang said. “In the future, it’s possible that a similar class of drug could be tried on humans. We are interested to see our study help others around the world better understand this gene and how it affects synapses and hope the model can be generalized to other autism genes.”

About this autism research

Funding: The authors disclosed no conflicts of interest and acknowledged funding from the National Institutes of Health (MH098114, HD077197, MH104316, NS039444, AA021074, K01 AG041211-01A1, 2P41 EB015897-25), Autism Speaks, the Phelan-McDermid Syndrome Foundation, the Ruth K. Broad Foundation, the Autism Science Foundation, Roche, the North Carolina Biotechnology Center, the Duke Institute for Brain Sciences, and the Duke Medical Scientist Training Program (T32 GM007171).

Source: Samiha Khanna – Duke University Medical Center
Image Source: The image is credited to Duke Health and is adapted from the video.
Video Source: The video is credited to Duke Health.
Original Research: Full open access research for “Altered mGluR5-Homer scaffolds and corticostriatal connectivity in a Shank3 complete knockout model of autism” by Xiaoming Wang, Alexandra L. Bey, Brittany M. Katz, Alexandra Badea, Namsoo Kim, Lisa K. David, Lara J. Duffney, Sunil Kumar, Stephen D. Mague, Samuel W. Hulbert, Nisha Dutta, Volodya Hayrapetyan, Chunxiu Yu, Erin Gaidis, Shengli Zhao, Jin-Dong Ding, Qiong Xu, Leeyup Chung, Ramona M. Rodriguiz, Fan Wang, Richard J. Weinberg, William C. Wetsel, Kafui Dzirasa, Henry Yin & Yong-hui Jiang in Nature Structural and Molecular Biology. Published online May10 2016 doi:10.1038/ncomms11459


Abstract

Altered mGluR5-Homer scaffolds and corticostriatal connectivity in a Shank3 complete knockout model of autism

Human neuroimaging studies suggest that aberrant neural connectivity underlies behavioural deficits in autism spectrum disorders (ASDs), but the molecular and neural circuit mechanisms underlying ASDs remain elusive. Here, we describe a complete knockout mouse model of the autism-associated Shank3 gene, with a deletion of exons 4–22 (Δe4–22). Both mGluR5-Homer scaffolds and mGluR5-mediated signalling are selectively altered in striatal neurons. These changes are associated with perturbed function at striatal synapses, abnormal brain morphology, aberrant structural connectivity and ASD-like behaviour. In vivo recording reveals that the cortico-striatal-thalamic circuit is tonically hyperactive in mutants, but becomes hypoactive during social behaviour. Manipulation of mGluR5 activity attenuates excessive grooming and instrumental learning differentially, and rescues impaired striatal synaptic plasticity in Δe4–22−/− mice. These findings show that deficiency of Shank3 can impair mGluR5-Homer scaffolding, resulting in cortico-striatal circuit abnormalities that underlie deficits in learning and ASD-like behaviours. These data suggest causal links between genetic, molecular, and circuit mechanisms underlying the pathophysiology of ASDs.

“Altered mGluR5-Homer scaffolds and corticostriatal connectivity in a Shank3 complete knockout model of autism” by Xiaoming Wang, Alexandra L. Bey, Brittany M. Katz, Alexandra Badea, Namsoo Kim, Lisa K. David, Lara J. Duffney, Sunil Kumar, Stephen D. Mague, Samuel W. Hulbert, Nisha Dutta, Volodya Hayrapetyan, Chunxiu Yu, Erin Gaidis, Shengli Zhao, Jin-Dong Ding, Qiong Xu, Leeyup Chung, Ramona M. Rodriguiz, Fan Wang, Richard J. Weinberg, William C. Wetsel, Kafui Dzirasa, Henry Yin & Yong-hui Jiang in Nature Structural and Molecular Biology. Published online May10 2016 doi:10.1038/ncomms11459

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