December 23, 2024

Astrocytes in the Brain Help Orchestrate Synaptic Activity in Learning and Memory

Figure 1: A micrograph revealing an identified astrocyte. Yukiko Goda and her group have actually shown how astrocytes play a popular part in tuning the modifications in neuronal activity that make it possible for memory formation. Credit: © 2022 RIKEN Center for Brain Science (Thomas Chater).
Brain cells referred to as astrocytes play a popular part in tuning the changes in neuronal activity that allow memories to be stored.
RIKEN neuroscientists have found a surprising system for how neuronal activity in mice is dynamically tuned– with signaling at some synapses increasing, while other synapses go quiet– so as to promote the procedure of knowing and memory formation1. This finding provides new insights into the function brain cells called astrocytes play in memory production.
A team led by Yukiko Goda of the RIKEN Center for Brain Science has actually been looking for to understand the neural procedures underlying knowing and memory development. “One of our major objectives is to understand how the strengths of individual synapses are set and dynamically customized,” says Goda.

Figure 1: A micrograph revealing an identified astrocyte. Yukiko Goda and her team have shown how astrocytes play a popular part in tuning the modifications in neuronal activity that make it possible for memory development. In the present research study, Goda and colleagues used various interventions to selectively interfere with NMDA receptor activity in mouse astrocytes. Synaptic activity between input and recipient neurons became more uniform overall, rather than moving dynamically to favor activity at some synapses relative to others.

In a 2016 study, Godas group used cell cultures originated from rat brains to study the habits of basic systems in which multiple input nerve cells formed synaptic connections with the dendrite of a single recipient nerve cell. They figured out that astrocytes (Figure 1)– an extremely abundant population of cells that play different necessary supporting functions in the brain– helped with the fortifying of active synapses, while weakening less-active synaptic connections.
Now, the team has probed this regulative system more deeply. In particular, they focused on the function of receptors for the neurotransmitter N-methyl-D-aspartate (NMDA) in the mouse hippocampus, the brain area where memories are formed.
” NMDA is a reputable part of neuronal signaling in the hippocampus,” discusses Goda. “But the concept of astrocyte NMDA receptors has satisfied with some apprehension.” Nevertheless, her teams prior work used compelling evidence that such receptors are straight included in tuning the connections in between neighboring neurons.
In the present study, Goda and coworkers used various interventions to selectively disrupt NMDA receptor activity in mouse astrocytes. These treatments plainly affected activity on the presynaptic side of synapses, regulating the terminals of input neurons, instead of the dendrites of the neurons that got those signals. Consequently, synaptic activity in between input and recipient neurons ended up being more consistent total, instead of moving dynamically to prefer activity at some synapses relative to others.
Mathematical modeling, performed in cooperation with Tomoki Fukais team at the Okinawa Institute of Science and Technology Graduate University (OIST), exposed that these modifications in synaptic function considerably decreased neural plasticity in the hippocampus, namely the selective reinforcement of memories through the fortifying and weakening of synapses in between neurons.
” Our work shows that astrocyte signaling assists ensure the broad circulation of presynaptic strengths,” says Goda.
The group is now attempting to better understand the company, activity, and circulation of NMDA receptors in hippocampal astrocytes, and the broader influence of these non-neuronal receptors on animal habits. “We want to discover whether mice with impaired astrocyte NMDA receptors reveal transformed hippocampal network activity, and, if so, whether those changes connect to contextual and spatial knowing,” states Goda.
Recommendation: “Astrocyte GluN2C NMDA receptors control basal synaptic strengths of hippocampal CA1 pyramidal nerve cells in the stratum radiatum” by Peter H Chipman, Chi Chung Alan Fung, Alejandra Pazo Fernandez, Abhilash Sawant, Angelo Tedoldi, Atsushi Kawai, Sunita Ghimire Gautam, Mizuki Kurosawa, Manabu Abe, Kenji Sakimura, Tomoki Fukai and Yukiko Goda, 25 October 2021, eLife.DOI: 10.7554/ eLife.70818.