Females React Differently To Social Isolation Than Males

Summary: Researchers report females feel more stressed when the are socially isolated.

Source: eLife.

While male and female mice have similar responses to physical stress, research from the Hotchkiss Brain Institute at the University of Calgary, Canada, suggests females, not males, feel stressed when alone.

The findings, to be published in the journal eLife, provide further proof that strategies for coping with stress are sex-specific. They also highlight the importance of a social network for females in particular and pave the way for future research into whether females befriend others as a coping mechanism during stressful situations.

“Many species, including humans, use social interaction to reduce the effects of stress. In fact, the lack of a social network may itself be stressful,” says senior author Jaideep Bains, PhD, Professor of Physiology & Pharmacology at the University of Calgary, Cumming School of Medicine.

“Recent research suggests that young girls are more sensitive to social stress than boys. This could mean that social networks are more important for females in general, and that young females from different species, such as mice, may be more sensitive towards social isolation than males.”

To test whether isolating individuals from their social group impacts on the brain in sex-specific ways, Bains and his team studied preadolescent mice that had been housed in same-sex groups after weaning. These mice were either left in their same-sex groups, housed in pairs, or were isolated altogether from their littermates for 16 to 18 hours. Following this period, the team examined the effects on the animals’ brain cells that control the release of stress hormones.

“Isolating the female mice from their littermates for less than a day led to the release of a signalling chemical called corticosterone, which is produced in response to stressful situations and decreases the excitability of the brain cells,” says medical student Laura Senst, lead author of the study. “This reaction was not evident in their male counterparts.”

This led the team to believe that only young female mice, and not males, interpret social isolation as a type of stress. If this were true, it would mean that males should experience physical stress in a similar way to the isolated females through activities such as swimming.

Image shows a woman sitting alone by a tree.
“Our findings also raise the interesting question of whether social and environmental changes during the crucial preadolescent stage of development could have long-term consequences for how males and females respond to stressful events later in life.” NeuroscienceNews.com image is for illustrative purposes only.

After both sexes of mice experienced a 20-minute swim, the researchers indeed discovered that the activity elicited the same reaction in males as that seen in the females that had been isolated and also swam. This suggests both sexes have the same sensitivity towards physical stress.

“By showing that males and females react differently to some types of stress but not others, our study highlights the importance of considering carefully the sex of animals when investigating how stress affects the brain,” says Research Associate Dinara Baimoukhametova, co-lead author of the paper.

“Our findings also raise the interesting question of whether social and environmental changes during the crucial preadolescent stage of development could have long-term consequences for how males and females respond to stressful events later in life.”

About this neuroscience and genetics research article

Funding: Funding provided by Canadian Institutes of Health Research, Fondation Brain Canada, Alberta Innovates — Health Solutions.

Source: Emily Packer – eLife
Image Source: NeuroscienceNews.com image is in the public domain.
Original Research: Full open access research for “Sexually dimorphic neuronal responses to social isolation” by Laura Senst, Dinara Baimoukhametova, Toni-Lee Sterley, and Jaideep Singh Bains in eLife. Published online October 11 2016 doi:10.7554/eLife.18726

Cite This NeuroscienceNews.com Article

[cbtabs][cbtab title=”MLA”]eLife. “Females React Differently To Social Isolation Than Males.” NeuroscienceNews. NeuroscienceNews, 11 October 2016.
<https://neurosciencenews.com/sex-differences-social-isolation-5262/>.[/cbtab][cbtab title=”APA”]eLife. (2016, October 11). Females React Differently To Social Isolation Than Males. NeuroscienceNews. Retrieved October 11, 2016 from https://neurosciencenews.com/sex-differences-social-isolation-5262/[/cbtab][cbtab title=”Chicago”]eLife. “Females React Differently To Social Isolation Than Males.” https://neurosciencenews.com/sex-differences-social-isolation-5262/ (accessed October 11, 2016).[/cbtab][/cbtabs]


Abstract

Sexually dimorphic neuronal responses to social isolation

Many species use social networks to buffer the effects of stress. The mere absence of a social network, however, may also be stressful. We examined neuroendocrine, PVN CRH neurons and report that social isolation alters the intrinsic properties of these cells in sexually dimorphic fashion. Specifically, isolating preadolescent female mice from littermates for <24 hr increased first spike latency (FSL) and decreased excitability of CRH neurons. These changes were not evident in age-matched males. By contrast, subjecting either males (isolated or grouped) or group housed females to acute physical stress (swim), increased FSL. The increase in FSL following either social isolation or acute physical stress was blocked by the glucocorticoid synthesis inhibitor, metyrapone and mimicked by exogenous corticosterone. The increase in FSL results in a decrease in the excitability of CRH neurons. Our observations demonstrate that social isolation, but not acute physical stress has sex-specific effects on PVN CRH neurons.

“Sexually dimorphic neuronal responses to social isolation” by Laura Senst, Dinara Baimoukhametova, Toni-Lee Sterley, and Jaideep Singh Bains in eLife. Published online October 11 2016 doi:10.7554/eLife.18726

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