Summary: A new study reveals how a mutation in the Shank3 gene, associated with autism, alters social behavior by disrupting vasopressin release in the brain. In mice, this mutation reduced sociability and defensive aggression by limiting vasopressin reaching the lateral septum.
Researchers showed that vasopressin acts through two distinct receptors: AVPR1a for sociability and AVPR1b for aggression. By selectively targeting AVPR1a, they restored social interaction without triggering unwanted aggressive responses, opening the door to personalized therapies for autism.
Key Facts:
- Mechanism Identified: Shank3 mutation reduces vasopressin release in the lateral septum, impairing sociability and aggression.
- Receptor Pathways: AVPR1a receptor regulates sociability, while AVPR1b controls aggression.
- Therapeutic Potential: Selective AVPR1a activation improved social behavior in mice without increasing aggression.
Source: UMH
The Cognition and Social Interactions laboratory, led by Félix Leroy at the Institute for Neurosciences, a joint center of the Spanish National Research Council (CSIC) and the Miguel Hernández University (UMH) of Elche, has identified for the first time the mechanism linking a mutation in the Shank3 gene with alterations in social behavior.
Using a mouse model carrying this autism-associated mutation, the study shows that vasopressin, a brain hormone essential for social relationships, is not properly released in the lateral septum.
The work, published in Nature Communications, demonstrates that the proper release of vasopressin in this region regulates social behaviors through two distinct receptor pathways: one controlling sociability and the other controlling social aggression, and that selective activation of these receptors can reverse deficits in social interaction without triggering unwanted aggressive responses.
The findings provide the first detailed explanation of how a genetic mutation linked to autism leads to problems in social interaction. Until now, the Shank3 gene had been associated with the disorder, but the biological mechanism underlying this connection remained unclear.
The key, as this study demonstrates, lies in vasopressin: a brain hormone that acts as a messenger between neurons and is essential for regulating sociability and aggression in male mice.
The researchers observed that in animals with the mutation, part of the population of vasopressin-releasing neurons in the bed nucleus of the stria terminalis (BNST) was lost. In addition, they confirmed that these neurons release vasopressin in the lateral septum. As a result, little vasopressin reached the lateral septum.
This alteration explains why the mutant mice showed reduced sociability and a marked decrease in defensive aggression, a behavior that, under normal conditions, allows males to defend their territory.
The study also shows that vasopressin acts in the lateral septum through two different receptors, each responsible for a specific aspect of behavior: receptor AVPR1a controls sociability, while receptor AVPR1b regulates social aggression.
When the researchers manipulated these receptors, they were able to restore each behavior independently.
“We managed to improve sociability without increasing aggression, which is fundamental if we are thinking about a future treatment”, explains Leroy.
To achieve this, the team used a new vasopressin biosensor developed in collaboration with Yulong Li’s laboratory at Peking University. This tool, never before applied to this hormone, made it possible to visualize in real time how vasopressin was released in the brain.
“Thanks to this technology, we were able to demonstrate that the alteration was not present across the entire nervous system, but in a very specific circuit,” emphasizes María Helena Bortolozzo-Gleich, first author of the study.
In addition, collaboration with researchers at the University of Zurich made it possible to validate the reliability of the results through computational data analysis.
The results of this research are protected by a patent application aimed at developing drugs capable of selectively activating the AVPR1a receptor, which is responsible for sociability. The goal is to design therapies that improve social deficits in people with autism without inducing side effects related to aggression.
The study was carried out in male mice because the vasopressin pathway is more developed in males, and only they display the territorial aggression under study.
This sex difference could help explain, at least in part, why autism is more frequent in males, although it is also possible that in females the disorder manifests differently or is underdiagnosed.
“Our results suggest that future treatments could be personalized, taking these differences into account,” adds Leroy.
Funding: This study has been supported by funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation program, the CIDEGENT fellowship program of the Generalitat Valenciana, the Severo Ochoa Foundation, and the “la Caixa” Foundation. It was also supported by grants from the National Institutes of Health (NIH, USA), the National Natural Science Foundation of China, and the Swiss National Science Foundation.
The research is part of the MotivatedBehaviors project (H2020-ERC-STG/0784, n°949652), which aims to study the role of the lateral septum in regulating motivated behaviors to uncover the changes that occur in disorders associated with social behavior deficits.
In this line, Leroy has developed extensive expertise in studying this brain region. In 2023, his group published in Cell a study showing how corticotropin-releasing hormone signaling from the prefrontal cortex to the lateral septum suppresses interaction with familiar individuals.
This scientific trajectory has consolidated Leroy as a reference in the field, a recognition further reinforced by the EBBS Mid Career Award, recently granted by the European Brain and Behaviour Society.
About this autism and genetics research news
Author: Angeles Gallar
Source: UMH
Contact: Angeles Gallar – UMH
Image: The image is credited to Neuroscience News
Original Research: Open access.
“Impaired vasopressin neuromodulation of the lateral septum leads to social behavior deficits in Shank3B+/- male mice” by Félix Leroy et al. Nature Communications
Abstract
Impaired vasopressin neuromodulation of the lateral septum leads to social behavior deficits in Shank3B+/- male mice
The neuropeptide arginine-vasopressin (AVP) has been repeatedly associated with the autism spectrum disorder (ASD) but the underlying mechanisms remain unclear.
As Shank3B+/- male mice, a model of ASD, exhibit deficits in sociability and social aggression, we focused on the lateral septum (LS), a brain region involved in the regulation of motivated behaviors and observed reduced AVP inputs from the bed nucleus of the stria terminalis (BNST) to LS.
Manipulating AVP release from the BNST to LS of wild-type male mice, we found that AVP promotes both sociability and social aggression.
Blocking the vasopressin receptor 1a (AVPR1a) in LS impaired sociability, while blocking the receptor 1b (AVPR1b) disrupted social aggression.
Consequently, selective activation of AVPR1a or AVPR1b rescued the respective behavioral deficits in Shank3B+/- male mice.
These findings reveal that AVP release in LS modulates two distinct social behaviors via different receptors and highlight a possible strategy to rescue sociability during ASD.
