The scientific community knows microglia as the main immune cell of the central nervous system and as the main regulator of inflammatory processes in the brain. The role of inflammatory processes and microglia is also increasingly recognized in neurodevelopmental disorders. The investigation of the role of microglia in physiological and pathological conditions has become a dynamically developing research field in recent years.
The research group has accumulated a significant amount of knowledge in the field of microglia-neuron cell communication, and several of their publications on this subject have received international attention. They have discovered a novel form of communication established by direct contacts between microglia and the cell body of nerve cells, named somatic microglia-neuron junctions, and revealed the role of these specialized contact sites in microglia-mediated protection of injured neurons.
Although the important role played by microglia during brain development had been suggested by many previous studies, the exact cellular communication pathways enabling microglia to influence the development of neurons and the formation of neural networks in the brain has been unclear. In particular, it was not well understood how and through what types of connections developing neurons that have not yet established interaction with other neurons in the absence of synapses may recieve guidance from microglial cells to develop into complex networks in the developing neocortex.
During their investigations, the researchers used both high-resolution molecular anatomy techniques, combined light and electron microscopy, and ex vivo imaging studies. Using a multifaceted approach, the researchers proved the presence of direct connections between microglia and developing neurons both during embryonic development and after birth.
The special, dynamically changing anatomical connections between microglia and developing, immature neurons are similar to the previously discovered somatic microglial junctions in many ways, and their special molecular composition and ultrastructure enable microglia to continuously monitor and effectively influence the development and integration of neurons into complex networks,” said the first author of the work.
When the researchers inhibited the communication through the key microglial receptors that are highly enriched at these sites, the development of the normal structure of the cerebral cortex was disturbed. Therefore, microglia should be considered an important regulatory cell type of brain development via these special interaction sites and beyond.
More thorough understanding of microglial mechanisms that are required for the proper development of the brain may help to find novel therapies for neurodevelopmental disorders and other forms of brain diseases that represent an unresolved challenge worldwide,” concluded the last author of the publication.
Microglial control of neuronal development
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