Scientists have uncovered a crucial pathway that links brain cell activity to the activation of genes responsible for learning and memory.
This study highlights how neurons communicate over long distances within the brain, solving a mystery about how signals from distant synapses reach the nucleus to trigger gene expression.
Unlocking the Secrets of Brain Cell Communication
A new study published in the Journal of Neuroscience reveals how brain cells transmit vital signals from their outer branches to their nucleus, triggering the activation of genes essential for learning and memory.
Researchers have discovered a key pathway that connects neuron-to-neuron communication, known as synaptic activity, to the expression of genes that drive long-term changes in the brain. This discovery provides important insights into the molecular processes that support memory formation.
Understanding the Relay System Behind Learning and Memory
“These findings illuminate a critical mechanism that connects local synaptic activity to the broader gene expression changes necessary for learning and memory,” said Mark Dell’Acqua, professor of pharmacology at the University of Colorado Anschutz Medical Campus and senior author of the study. “This paper is mainly a basic science finding of a fundamental process of what nerve cells do. Understanding this relay system not only enhances our knowledge of brain function but could also better inform therapeutic treatments for cognitive disorders.”
Bridging the Gap: How Signals Travel Within Neurons
The nucleus where the genes that modify neuron function are controlled is a long distance away from where neurons receive input from their synapses, which are located in distant dendrites that extend like branches from the trunk of a tree. This research focuses on the cAMP-response element binding protein (CREB), a transcription factor known to regulate genes vital for dynamic changes at synapses which is essential for neuronal communication. Despite CREB’s well-documented role in supporting learning and memory, the exact mechanisms leading to CREB activation during neuronal activity remain unclear.
Advanced Microscopy Reveals a Critical Relay Mechanism
Using advanced microscopy techniques, graduate student Katlin Zent in Dr. Dell’Acqua’s research group revealed a crucial relay mechanism involving the activation of receptors and ion channels generating calcium signals that rapidly communicates from synapses in remote dendrite branches to the nucleus in the neuron cell body.
Potential for Treating Memory Disorders
“Going forward, this research will enable us to better examine the way these pathways are utilized in different disease states,” said Dell’Acqua. “We could see exactly what parts of this new mechanism are interfered with and where, giving us a better idea of how this pathway affecting learning and memory is impacted. This research highlights potential targets for interventions aimed at conditions like Alzheimer’s disease and other memory-related disorders.”
Reference: “Synapse-to-Nucleus ERK→CREB Transcriptional Signaling Requires Dendrite-to-Soma Ca2+ Propagation Mediated by L-Type Voltage–Gated Ca2+ Channels” by Katlin H. Zent and Mark L. Dell’Acqua, 21 January 2025, Journal of Neuroscience.
DOI: 10.1523/JNEUROSCI.1216-24.2024
