Stress Hormone Amygdala Function Flips In Maturing Brain

Contrary to evidence that the amygdala stimulates stress responses in adults, researchers at Yerkes National Primate Research Center, Emory University have found that the amygdala has an inhibitory effect on stress hormones during the early development of nonhuman primates.

The amygdala is a brain region known to be important for responses to threatening situations and learning about threats. Changes in the amygdala have been reported in psychiatric disorders such as depression, anxiety disorders like PTSD, schizophrenia and autism spectrum disorder. However, much of what is known about the amygdala comes from research on adults.

Said neuroscience researcher Mar Sanchez, PhD, associate professor of psychiatry and behavioral sciences at Emory University School of Medicine:

“Our findings fit into an emerging theme in neuroscience research: that during childhood, there is a switch in amygdala function and connectivity with other brain regions, particularly the prefrontal cortex.”

The first author of the paper is postdoctoral fellow Jessica Raper, PhD.

Studying Amygdala Damage

The findings are part of a larger longitudinal study at Yerkes National Primate Research Center, examining how amygdala damage within the first month of life affects the development of social and emotional behaviors and neuroendocrine systems in rhesus monkeys from infancy through adulthood. The laboratories of Sanchez and Yerkes researchers Jocelyne Bachevalier, PhD and Kim Wallen, PhD are collaborating on this project.

Earlier investigations at Yerkes found that as infants, monkeys with amygdala damage showed higher levels of the stress hormone cortisol. This surprising result contrasted with previous research on adults, which showed that amygdala damage results in lower levels of cortisol.

The team hypothesized that damage to the amygdala generated changes in the HPA axis: a network of endocrine interactions between the hypothalamus within the brain, the pituitary and the adrenal glands, critical for reactions to stress.

“We wanted to examine whether the alterations in stress hormones seen during infancy persisted, and what brain changes were responsible for them,” Sanchez says. “In studies of adults, the amygdala and its connections are fully formed at the time of the manipulation, but here neither the amygdala or its connections were fully matured when the damage occurred.”

Cortisol Levels Increase

In the current paper, the authors demonstrated that in contrast with adult animals with amygdala damage, juvenile monkeys with early amygdala damage had increased levels of cortisol in the blood, compared to controls.

In their cerebrospinal fluid, they also had elevated levels of corticotropin releasing factor (CRF), the neuropeptide that initiates the stress response in the brain. Elevated CRF and cortisol are linked to anxiety and emotional dysregulation in patients with mood disorders.

Despite the increased levels of stress hormones, monkeys with early amygdala damage exhibit a blunted emotional reactivity to threats, including decreased fear and aggression, and reduced anxiety in response to stress.

Still, monkeys with neonatal amygdala damage remain competent in interacting with others in their large social groups. These findings are consistent with reports of human patients with damage to the amygdala, Raper says:

“We speculate that the rich social environment provided to the monkeys promotes compensatory mechanisms in cortical regions implicated in the regulation of social behavior. But neonatal amygdala damage seems more detrimental for the development of stress neuroendocrine circuits in other areas of the brain.”

The investigators plan to follow the animals into adulthood to investigate the long-term effects of early amygdala damage on stress hormones, behavior and physiological systems possibly affected by chronically high cortisol levels, such as immune, growth and reproductive functions.

Jessica Raper et al.
Neonatal Amygdala Lesions Lead to Increased Activity of Brain CRF Systems and Hypothalamic-Pituitary-Adrenal Axis of Juvenile Rhesus Monkeys.
Journal of Neuroscience, August 2014 DOI: 10.1523/JNEUROSCI.0269-14.2014