image: Resected human brain tissue, frozen 100 ms after stimulation, shows an endocytic structure. scale bar = 100 nm.
Credit: Chelsy Eddings
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Researchers at Johns Hopkins Medicine say they have used a “zap-and-freeze” technology to watch hard-to-see brain cell communications in living brain tissue from mice and humans.
Findings from the new experiments, supported by the National Institutes of Health and published Nov. 24 in Neuron, could potentially help scientists find the root causes of nonheritable forms of Parkinson’s disease, the researchers say.
Sporadic cases of Parkinson’s disease account for most cases of the neurodegenerative disorder, according to the Parkinson’s Foundation. The condition is marked by disruptions to the signaling point between two brain cells. That connection point, known as a synapse, is notoriously difficult to study, says Shigeki Watanabe, Ph.D., associate professor of cell biology at Johns Hopkins Medicine, who led the research.
“We hope this new technique of visualizing synaptic membrane dynamics in live brain tissue samples can help us understand similarities and differences in nonheritable and heritable forms of the condition,” Watanabe says. Eventually, he says, this approach could help lead to the development of treatments for the neurodegenerative disorder.
Understanding root causes of Parkinson’s disease
In healthy brains, synaptic vesicles, or message-carrying bubbles within brain cells, help transfer information from cell to cell in a process key to information processing, learning and forming memories. Understanding this process is critical for identifying where cellular communication breaks down in neurodegenerative conditions, Watanabe says.
Previously, Watanabe helped develop the zap-and-freeze technique to allow for a closer look at synaptic membrane movements (these results were published in 2020 in Nature Neuroscience). Essentially, the technique involves using an electrical pulse to stimulate living brain tissue and then freezing the tissues rapidly to capture cell movement for electron microscopy observation.
In a study published earlier this year in Nature Neuroscience, Watanabe used the approach in the brains of genetically engineered mice to understand how a key protein, intersectin, keeps synaptic vesicles in a particular location within a brain cell until they are ready to be released to activate a neighboring brain cell.
For the new study, the researchers used samples from the brains of normal mice as well as living cortical brain tissue sampled with permission from six individuals undergoing surgical treatment for epilepsy at The Johns Hopkins Hospital. The surgical procedures were medically necessary to remove lesions from the brain’s hippocampus.
Working with scientists Jens Eilers and Kristina Lippmann at Leipzig University in Germany, the researchers first validated the zap-and-freeze approach by observing calcium signaling, a process that triggers neurons to release neurotransmitters in living mouse brain tissues.
Next, the scientists stimulated neurons in mouse brain tissue with the zap-and-freeze approach and observed where synaptic vesicles fuse with brain cell membranes and then release chemicals called neurotransmitters that reach other brain cells. The scientists then observed how mouse brain cells recycle synaptic vesicles after they are used for neuronal communication, a process known as endocytosis that allows material to be taken up by neurons.
The researchers then applied the zap-and-freeze technique to brain tissue samples from people with epilepsy, and observed the same synaptic vesicle recycling pathway operating in human neurons.
In both mouse and human brain samples, the protein Dynamin1xA, which is essential for ultrafast synaptic membrane recycling, was present where endocytosis is thought to occur on the membrane of the synapse.
“Our findings indicate that the molecular mechanism of ultrafast endocytosis is conserved between mice and human brain tissues,” Watanabe says, suggesting that the investigations in these models are valuable for understanding human biology.
In future experiments, Watanabe says he hopes to leverage the zap-and-freeze technique to study synaptic vesicle dynamics in brain tissue samples taken with permission from patients with Parkinson’s disease undergoing deep brain tissue stimulation.
Funding support for this research was provided by the National Institutes of Health (U19 AG072643, 1DP2 NS111133-01, 1R01 NS105810-01A1, R35 NS132153, S10RR026445), Howard Hughes Medical Institute, Kazato Foundation, American Lebanese Syrian Associated Charities, Marine Biological Laboratory, Leipzig University, Roland Ernst Stiftung, Johns Hopkins Medicine, Chan Zuckerberg Initiative, Brain Research Foundation, Helis Foundation, Robert J Kleberg Jr and Helen C Kleberg Foundation, McKnight Foundation, Esther A. & Joseph Klingenstein Fund, and the Vallee Foundation.
In addition to Watanabe, other scientists who contributed to this work include Chelsy Eddings, Minghua Fan, Yuuta Imoto, Kie Itoh, Xiomara McDonald, William Anderson, Paul Worley and David Nauen from Johns Hopkins, and Jens Eilers and Kristina Lippmann from Leipzig University, Germany.
DOI: 10.1016/j.neuron.2025.10.03
Journal
Neuron