Smells and Emotions Tug on the Brain’s Habenula

Summary: The habenula relays external information, such as sight and smell, along with internal states associated with emotion and learning to brain regions that govern adaptive behaviors.

Source: NTNU

A tiny region in the middle of the brain plays a far more important role than previously known in helping it respond to changes in the environment, a new study shows.

This region is called the habenula, a name that reflects its directional role. Habenula means “little rein” in Latin, and a rein, of course, is the leather strap on a horse’s bridle used to direct it.

The study, conducted by researchers at the Norwegian University of Science and Technology’s Kavli Institute for Systems Neuroscience, was published Friday in the scientific journal Current Biology.

The researchers, with first author Ewelina Bartoszek, did their experiments in zebrafish, but the habenula is so important that evolution has ensured it is found in all vertebrates, from fish to mammals to humans. In fact, earlier studies in humans have found links between dysfunctions in the habenula to neurological conditions such as mood disorders and addiction.

Kavli Institute researchers showed that the habenula relays information from the outside world, such as smell and sight, along with internal states associated with emotions and learning, to the brain regions that control adaptive behaviors.

“It turns out that the habenula is an information hub,” said Emre Yaksi, a professor at NTNU’s Kavli Institute for Systems Neuroscience and head of the research group that did the study. “It integrates information about odors from the environment with the information from the limbic system, which is involved in emotional behaviors and learning.”

Credit: NTNU

Translating signals from the outside into alerts

In other words, the brain may be in one state when the smell of a predator—or food, or a mate —wafts into the nose and reaches the habenula. The habenula translates that smell into a kind of alert or saliency signal to shift the brain into a different state, Yaksi said.

“We argue that the habenula helps the brain to stop certain actions and communications across brain regions, in order to shift it to another mode that is better suited to the situation that the scent warns of,” he said. “The brain’s different modes involve different dynamic networks that best enable the animal to solve the challenges that it is about to experience.”

The study highlights how important our sense of smell—or in more scientific terms, the olfactory system—is in regulating what happens in the habenula and the limbic system, during these sensory-induced state changes in the brain.

Finding ‘ancestral’ structures

Another important aspect of the study, Yaksi said, is that the experiments allowed the researchers to identify parts of the zebrafish brain that are “ancestral” to the hippocampus and amygdala in mammals.

This shows the habenula
The image shows the forebrain (top half) and midbrain (bottom half) or a juvenile zebrafish. The habenula (cyan) are the tiny nuclei in the middle of the two big structures. Credit: Stephanie Fore

In humans, the hippocampus is known to play a key role in our sense of where we are and our memory, while the amygdala is the area that helps process memories and emotional responses, such as fear.

“We also showed that these are the major cortico-limbic systems that drive the habenula,” Yaksi said. The researchers were actually able to observe this connection in zebrafish by stimulating the structures and seeing activity in the habenula, he said. This finding is particularly important as researchers continue to unravel the different roles that different parts of the brain play in cognition.

The researchers suggest that given the role of the habenula in regulating moods and brain states, sensory experiences might provide a non-invasive pathway to modify habenular activity, perhaps even in humans.

About this neuroscience research news

Author: Nancy Bazilchuk
Source: NTNU
Contact: Nancy Bazilchuk – NTNU
Image: The image is credited to Stephanie Fore

Original Research: Open access.
Ongoing habenular activity is driven by forebrain networks and modulated by olfactory stimuli” by Ewelina Magdalena Bartoszek et al. Current Biology


Abstract

Ongoing habenular activity is driven by forebrain networks and modulated by olfactory stimuli

Highlights

  • Ongoing habenular activity is structured into robust functional clusters
  • Amygdala and hippocampus homologs in zebrafish drive ongoing habenular activity
  • Activating amygdala and hippocampus recruits partially overlapping habenula neurons
  • Odors modulate the activity of habenula and its forebrain input regions

Summary

Ongoing neural activity, which represents internal brain states, is constantly modulated by the sensory information that is generated by the environment.

In this study, we show that the habenular circuits act as a major brain hub integrating the structured ongoing activity of the limbic forebrain circuitry and the olfactory information.

We demonstrate that ancestral homologs of amygdala and hippocampus in zebrafish forebrain are the major drivers of ongoing habenular activity. We also reveal that odor stimuli can modulate the activity of specific habenular neurons that are driven by this forebrain circuitry.

Our results highlight a major role for the olfactory system in regulating the ongoing activity of the habenula and the forebrain, thereby altering brain’s internal states.

Join our Newsletter
I agree to have my personal information transferred to AWeber for Neuroscience Newsletter ( more information )
Sign up to receive our recent neuroscience headlines and summaries sent to your email once a day, totally free.
We hate spam and only use your email to contact you about newsletters. You can cancel your subscription any time.