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Scientists Discover a Unique Group of Neurons With a Remarkable Ability

Scientists Discover a Unique Group of Neurons With a Remarkable Ability

Aug 2, 2023


Neuron Brain Cell Disease

Researchers have identified a unique group of nerve cells in the midbrain that can pause all movement, resembling a ‘pause-and-play’ pattern, and restart precisely where it ceased. This discovery, unrelated to fear but potentially associated with attention, might aid in understanding Parkinson’s disease mechanisms.

A group of nerve cells in the brain displays a remarkable ability to halt all forms of movement, as revealed by a recent study conducted on mice. This finding contributes significantly to our understanding of how the nervous system exercises control over our movements.

When a hunting dog detects the scents of a deer, it sometimes completely freezes. This phenomenon can also be observed in humans who must focus intently on a complex task.

Now, a recent discovery contributes to our understanding of what happens in the brain when we abruptly stop moving.

“We have found a group of nerve cells in the midbrain which, when stimulated, stop all movement. Not just walking; all forms of motor activity. They even make the mice stop breathing or breathe more slowly, and the heart rate slows down,” explains Professor Ole Kiehn, who is a co-author of the study.

“There are various ways to stop movement. What is so special about these nerve cells is that once activated they cause the movement to be paused or freeze. Just like setting a film on pause. The actors’ movement suddenly stops on the spot,” says Ole Kiehn.

When the researchers ended activating the nerve cells, the mice would start the movement exactly where it stopped. Just like when pressing “play” again.

“This ‘pause-and-play pattern’ is very unique; it is unlike anything we have seen before. It does not resemble other forms of movement or motor arrest we or other researchers have studied. There, the movement does not necessarily start where it stopped, but may start over with a new pattern,” says Ph.D. Haizea Goñi-Erro, who is first author of the study.

The nerve cells stimulated by the researchers are found in the midbrain in an area called the pedunculopontine nucleus (PPN), and they differ from other nerve cells thereby expressing a specific molecular marker called Chx10. The PPN is common to all vertebrates including humans. So even though the study was performed in mice, the researchers expect the phenomenon to apply to humans too.

Not related to fear

Some might suggest that the nerve cells are activated by fear. Most people are familiar with the phenomenon of “freezing” caused by extreme fear. But that is not the case.

“We have compared this type of motor arrest to motor arrest or freezing caused by fear, and they are not identical. We are very sure that the movement arrest observe here is not related to fear. Instead, we believe it has something to do with attention or alertness, which is seen in certain situations,” says Assistant Professor Roberto Leiras, who is co-author of the study.

The researchers believe it is an expression of a focused attention. However, they stress that the study has not revealed if this is indeed the case. It is something that requires more research to demonstrate.

May be able to understand Parkinson’s symptoms

The new study may be able to help us understand some of the mechanisms of Parkinson’s disease.

“Motor arrest or slow movement is one of the cardinal symptoms of Parkinson’s disease. We speculate that these special nerve cells in PPN are over-activated in Parkinson’s disease. That would inhibit movement. Therefore, the study, which primarily has focused on the fundamental mechanisms that control movement in the nervous system, may eventually help us to understand the cause of some of the motor symptoms in Parkinson’s disease,” Ole Kiehn concludes.

Reference: “Pedunculopontine Chx10+ neurons control global motor arrest in mice” by Haizea Goñi-Erro, Raghavendra Selvan, Roberto Leiras and Ole Kiehn, 27 July 2023, Nature Neuroscience.
DOI: 10.1038/s41593-023-01396-3

The study was funded by the Novo Nordisk Foundation, the Lundbeck Foundation, and the Swedish Research Council.


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