The researchers modified the virus to light up its pathway, leaving a trail of fluorescent breadcrumbs as it traveled from the neurons in the mouse brain that induce stress hormones to the cells that send signals to those stress-response neurons. They saw multiple different areas of the brain where the viral tracer had blazed its backwards path.
To pinpoint which of those areas was involved in the specific fear response to predator odors, Kondoh exposed mice in the lab to smells — the aforementioned bobcat urine, purchased from a hunting supply store, or a chemical from fox feces — and looked for olfactory neurons activated in response to those noxious scents. The researchers then looked at the cross-section of the two experiments — those nerve cells that send signals to the stress-response cells of the brain and that also light up when mice smell traces of their predators — and found them to be concentrated in one area of the olfactory cortex, the AmPir.
The AmPir is a small region of the rodent brain and, like most parts of the brain involved in sensing and responding to odors, it’s fairly mysterious, Buck said.
“We had actually never even heard of the AmPir. It’s a very tiny area and nothing was known about it,” she said. “We don’t know whether it even exists in humans.”
What is known about the AmPir is that it sits right next to the amygdala, a part of the brain that in humans and other animals plays a role in some emotions — including fear.
Kondoh also found that stimulating the AmPir directly boosted stress hormone levels, and that blocking this brain region’s activity blocked the hormone surge when animals were exposed to predator odors. (Animals with an inactive AmPir still froze when they smelled predator odors, though, suggesting to the researchers that the stress hormone response and behavior changes may be controlled by different parts of the brain.)
The next steps
The next steps for the research team are to uncover the molecules involved in the neural circuits they found, Buck said. The researchers would like to identify genetic signatures in the neurons involved in fear responses. If they find unique molecular signatures for those neurons and if those signatures occur in humans too, such discoveries could lead to a better understanding of stress disorders, such as PTSD and depression, Buck said — and perhaps even point to novel targets for therapeutics.
There’s also evidence suggesting that other scents, like rose oil, can block the fear response to predator odors. Buck’s research team is currently working to uncover the neurons that could suppress stress hormones and the fear response in rodents.
“We’re just beginning to scratch the surface,” Buck said. “By pursuing these various connections, I think there is the potential to identify neural circuits that would be relevant to humans and to the treatment of human psychiatric disorders.”
The study was funded by the Howard Hughes Medical Institute, the National Institutes of Health and the Japan Society for the Promotion of Science.