Resting microglia directly monitor the functional state of synapses in vivo and determine the fate of ischemic terminals

H Wake, AJ Moorhouse, S Jinno… - Journal of …, 2009 - Soc Neuroscience
H Wake, AJ Moorhouse, S Jinno, S Kohsaka, J Nabekura
Journal of Neuroscience, 2009Soc Neuroscience
Recent studies have identified the important contribution of glial cells to the plasticity of
neuronal circuits. Resting microglia, the primary immune effector cells in the brain,
dynamically extend and retract their processes as if actively surveying the
microenvironment. However, just what is being sampled by these resting microglial
processes has not been demonstrated in vivo, and the nature and function of any
interactions between microglia and neuronal circuits is incompletely understood. Using in …
Recent studies have identified the important contribution of glial cells to the plasticity of neuronal circuits. Resting microglia, the primary immune effector cells in the brain, dynamically extend and retract their processes as if actively surveying the microenvironment. However, just what is being sampled by these resting microglial processes has not been demonstrated in vivo, and the nature and function of any interactions between microglia and neuronal circuits is incompletely understood. Using in vivo two-photon imaging of fluorescent-labeled neurons and microglia, we demonstrate that the resting microglial processes make brief (∼5 min) and direct contacts with neuronal synapses at a frequency of about once per hour. These contacts are activity-dependent, being reduced in frequency by reductions in neuronal activity. After transient cerebral ischemia, the duration of these microglia–synapse contacts are markedly prolonged (∼1 h) and are frequently followed by the disappearance of the presynaptic bouton. Our results demonstrate that at least part of the dynamic motility of resting microglial processes in vivo is directed toward synapses and propose that microglia vigilantly monitor and respond to the functional status of synapses. Furthermore, the striking finding that some synapses in the ischemic areas disappear after prolonged microglial contact suggests microglia contribute to the subsequent increased turnover of synaptic connections. Further understanding of the mechanisms involved in the microglial detection of the functional state of synapses, and of their role in remodeling neuronal circuits disrupted by ischemia, may lead to novel therapies for treating brain injury that target microglia.
Soc Neuroscience