Pupil Size Regulated by Orexin, Not Stress Hormones

Summary: Researchers have discovered that the neurotransmitter orexin, not the stress hormone noradrenaline alone, regulates pupil size, challenging prior understanding. Orexin neurons affect pupil size in response to emotional states and mental strain, not just light exposure.

The findings link orexin activity to several neurological conditions, including narcolepsy and Alzheimer’s, offering new diagnostic avenues. This research may also illuminate our understanding of consciousness and attention regulation.

Key Facts:

  1. Orexin neurons, not noradrenaline, are primarily responsible for the regulation of pupil size, challenging long-standing scientific belief.
  2. Researchers found a dose-dependent relationship between orexin neuron activity and pupil diameter, providing a direct method of measuring orexin activity.
  3. These findings link orexin to several neurological conditions such as Alzheimer’s, narcolepsy, stroke, and Prader-Willi syndrome, potentially simplifying and improving diagnosis methods.

Source: ETH Zurich

The way the brain regulates pupil size is different from previously thought: fundamentally responsible is the neurotransmitter orexin, as researchers at ETH Zurich have now shown.

This discovery could well alter our understanding of consciousness and illnesses such as narcolepsy and Alzheimer’s.

This shows a woman's eye.
They also encountered some cells that both influenced pupil size and responded to rewards, as well as others that were connected to just one of the two factors.Credit: Neuroscience News

“The effect was so strong, we knew immediately that we were onto something important,” recalls Nikola Grujic, a postdoc in the Neurobehavioural Dynamics Laboratory at ETH Zurich.

Through a series of initial experiments on mice, he studied what are known as orexin neurons, one of the lab’s main areas of research. He observed that stimulating nerve cells caused the pupils of the mice to expand noticeably.

“Quite often, the effects of neurostimulation get lost in the noise of measurement data, which we then have to painstakingly filter in order to find them. This time was different. The effect was plain to see,” he says.

First described in 1998, the orexin neurons stretch from the hypothalamus to all other brain areas, including those controlling consciousness and autonomic functions. These neurons are involved in regulating sleep-​wake switching, attention span, the reward system, appetite and energy consumption, among others.

Essential for normal pupil state

As Grujic’s measurements showed, orexin neurons directly influence a central characteristic of an individual’s emotional state: it is not only light stimuli that cause the pupils to change in size but also mental strain and emotional impressions.

Fittingly referred to in the vernacular as the windows to the soul, the pupils are routinely used in both medical and psychological examinations: pupil size can provide a metric for attention and other unconsciously controlled functions of the organism.

Up to now, the main determinant of pupil size alongside light was considered to be noradrenaline – known as a stress hormone – and its receptor system.

But now, the ETH researchers have shown that instead, this role should be credited to the neurotransmitter orexin and its system of receptors.

Noradrenaline neurons are in fact unable to maintain normal pupil state without orexin nerve cells. If the orexin system is switched off, the pupils remain far too constricted.

“Essentially, noradrenaline neurons are slaves to orexin neurons,” says ETH Professor Denis Burdakov, colourfully describing this dependent relationship.

Link to narcolepsy

In their experiments, the researchers also established a dose-​dependent link between nerve cell activity and pupil diameter. “The pupils show us precisely how active the orexin neurons in the hypothalamus are,” Burdakov says.

In addition to providing brain researchers with a new way of measuring orexin activity, this opens up new avenues for medical treatment. There is a long-​established link between a disruption in orexin regulation and the sleep disorder narcolepsy.

Recently, however, links have also been observed to other neurological conditions such as Alzheimer’s, stroke and the genetic disorder Prader-​Willi syndrome.

In this last condition, a malfunction in the diencephalon, or interbrain – where the hypothalamus is situated – leads to severe physical, cognitive and metabolic symptoms.

All four of these conditions have a sleep disorder component. In the future, examining pupil size could help more precisely research the influence of orexin on these conditions – and possibly even simplify and improve diagnosis, Burdakov says. At the present time, diagnosing narcolepsy still requires a lumbar puncture, which is an invasive procedure.

Unlocking consciousness regulation

As a neuroscientist, Grujic sees his discovery mainly as a key to better understanding how core functions of our consciousness are regulated.

“Achieving the balance between focusing on the familiar and allowing our thoughts to wander and explore the world around us is an essential part of our ability to adapt to new situations,” he says.

The prevalence and range of attention deficit disorders being diagnosed today shows just how difficult maintaining this balance can be, Grujic says.

Orexin is one of several neuromodulatory systems (others include noradrenaline and serotonin) that regulate this balance. These systems tip the balance one way or another depending on the organism’s needs.

In the early days of human evolution, for instance, hungry hunter-​gatherers had to cast around in search of a food source. If they were rewarded by the discovery of something to eat, they had then to shift their focus to their surroundings in order to be able to spy more of the food.

And when the early humans were finally satiated, they could turn their attention to meeting their other needs.

Multiple neuron subsets for specific functions

In their study of orexin neurons, Burdakov’s research group managed to identify subsets that are involved in a variety of neural functions and thus in different components of this balance.

Using a special kind of fluorescence microscopy, the scientists observed the response of individual orexin neurons in mice and compared this with fluctuations in pupil size. They used two-​photon microscopy, which makes it possible to observe the activities of individual cells in the brain.

The researchers discovered neurons whose activity positively correlated with pupil size – and thus with the mouse’s level of arousal – and others whose activity negatively correlated.

They also encountered some cells that both influenced pupil size and responded to rewards, as well as others that were connected to just one of the two factors.

Candidate for higher-​level regulation

The identification of these specialised subsets within orexin neurons provides an initial insight into the ways in which these are wired to support central functions of our consciousness.

What’s more, Grujic says that orexin’s influence on a host of different behavioural states – from attention, sleep-​wake switching and reward-​seeking to appetite and energy consumption – makes it a prime candidate for their higher-​level regulation.

The ETH researchers’ findings throw open the door to many more avenues of scientific enquiry concerning the identification of additional neuron subsets and how they interact – both with each other and with the serotonin and noradrenaline systems.

The researchers assume that answering such questions will lead not only to a far more detailed understanding of how our vital functions are regulated.

They also foresee benefits in the diagnosis and treatment of attention and sleep disorders and of related conditions. And as the examples of Alzheimer’s and stroke suggest, these benefits could be greater than they at first seem. 

About this neuroscience research news

Author: Daniel Meierhans
Source: ETH Zurich
Contact: Daniel Meierhans – ETH Zurich
Image: The image is credited to Neuroscience News

Original Research: Open access.
Control and coding of pupil size by hypothalamic orexin neurons” by Grujic N et al. Nature Neuroscience


Control and coding of pupil size by hypothalamic orexin neurons

Brain orexin (hypocretin) neurons are implicated in sleep–wake switching and reward-seeking but their roles in rapid arousal dynamics and reward perception are unclear.

Here, cell-specific stimulation, deletion and in vivo recordings revealed strong correlative and causal links between pupil dilation—a quantitative arousal marker—and orexin cell activity.

Coding of arousal and reward was distributed across orexin cells, indicating that they specialize in rapid, multiplexed communication of momentary arousal and reward states.

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  1. It’s becoming clear that with all the brain and consciousness theories out there, the proof will be in the pudding. By this I mean, can any particular theory be used to create a human adult level conscious machine. My bet is on the late Gerald Edelman’s Extended Theory of Neuronal Group Selection. The lead group in robotics based on this theory is the Neurorobotics Lab at UC at Irvine. Dr. Edelman distinguished between primary consciousness, which came first in evolution, and that humans share with other conscious animals, and higher order consciousness, which came to only humans with the acquisition of language. A machine with primary consciousness will probably have to come first.

    What I find special about the TNGS is the Darwin series of automata created at the Neurosciences Institute by Dr. Edelman and his colleagues in the 1990’s and 2000’s. These machines perform in the real world, not in a restricted simulated world, and display convincing physical behavior indicative of higher psychological functions necessary for consciousness, such as perceptual categorization, memory, and learning. They are based on realistic models of the parts of the biological brain that the theory claims subserve these functions. The extended TNGS allows for the emergence of consciousness based only on further evolutionary development of the brain areas responsible for these functions, in a parsimonious way. No other research I’ve encountered is anywhere near as convincing.

    I post because on almost every video and article about the brain and consciousness that I encounter, the attitude seems to be that we still know next to nothing about how the brain and consciousness work; that there’s lots of data but no unifying theory. I believe the extended TNGS is that theory. My motivation is to keep that theory in front of the public. And obviously, I consider it the route to a truly conscious machine, primary and higher-order.

    My advice to people who want to create a conscious machine is to seriously ground themselves in the extended TNGS and the Darwin automata first, and proceed from there, by applying to Jeff Krichmar’s lab at UC Irvine, possibly. Dr. Edelman’s roadmap to a conscious machine is at https://arxiv.org/abs/2105.10461

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