by Nancy Fliesler, Children’s Hospital Boston
Researchers have now mapped all the neurons that project from the brain to the spinal cord and characterized them at the molecular level — adding to a larger cell-by-cell “atlas” of the mouse brain. Credit: Sebastian Stankiewicz, Boston Children’s Hospital
Only a fraction of people who sustain a spinal cord injury fully regain their motor function. While rehabilitation can help, scientists have long looked for ways to regenerate injured nerve fibers—including, at Boston Children’s Hospital, Zhigang He, Ph.D., BM.
As part of a collaborative effort by the BRAIN Initiative Cell Census Network, which just published a cell-by-cell “atlas” of the mouse brain, He’s lab took on the ambitious task of profiling those neurons in the brain that send projections to the spinal cord. These neurons, of multiple types, control a variety of bodily functions, including movement. The detailed findings were published in Nature.
“Now, we can look at these neurons in terms of their molecular profile and get more insight into what strategy to use to promote regeneration,” He says. “That was one of the major motivations for us to study this.”
A three-pronged system
The researchers, led by Carla Winter, an MD-Ph.D. candidate in He’s lab, characterized about 65,000 individual spinal-projecting neurons. They used tools including whole brain imaging, cell labeling techniques, and single-nucleus RNA sequencing to see what genes the cells use and what proteins they make (the transcriptome). They then mapped the identified cell types onto an anatomic and transcriptomic brain atlas created by the Allen Institute for Brain Science.
In all, the team identified 76 types of spinal projecting neurons across the brain. Their functions range from controlling voluntary and involuntary movement to processing sensory inputs to governing autonomic functions like blood pressure, heart rate, and fear responses.
“Molecularly, we’re seeing three divisions of spinal-projecting neurons—three systems for governing different types of movements and functions,” says Winter. These are:
Division 1 neurons, with just seven cell types arising from three brain regions (the cortex, red nucleus, and cerebellum). All are excitatory, and each projects from a precise brain location to a specific location in the spinal cord, giving these neurons a wide range of functions. “Even though the neurons look similar to one another on a molecular level, we think their functions differ based on their wiring,” says Winter.
Division 2 neurons, with nearly 50 distinct cell types, are a mix of excitatory and inhibitory. These neurons are scattered throughout the brain, so their projections don’t come in discrete bundles or tracts, and they project to multiple spinal cord locations. The researchers think they may be involved in integrating and coordinating movements.
Division 3 neurons, a little-known group of neurons with a modulatory function, amplifying or quieting down entire brain-spinal circuits. The researchers documented 20 different neuron types in the hypothalamus, midbrain, and brainstem. “These are different from typical neurons, and act via slow neurotransmission or neuropeptides,” says Winter.
More information: Carla C. Winter et al, A transcriptomic taxonomy of mouse brain-wide spinal projecting neurons, Nature (2023). DOI: 10.1038/s41586-023-06817-8
Zizhen Yao et al, A high-resolution transcriptomic and spatial atlas of cell types in the whole mouse brain, Nature (2023). DOI: 10.1038/s41586-023-06812-z
Journal information: Nature
Provided by Children’s Hospital Boston
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