Imaging microglia in brain slices and slice cultures.

Here we describe a method for imaging fluorescently labeled parenchymal microglia (MG) in excised neonatal or adult rodent brain tissue slices. Using multichannel confocal or two-photon time-lapse imaging, the approach affords real-time analyses of MG behaviors, including motility, migration, chemotaxis, proliferation, and phagocytosis in live brain tissues. The method is applicable to acutely prepared tissue slices from developing and adult rodents and to slice cultures derived from neonatal rodents, including transgenic and green fluorescent protein reporter mice. A variety of fluorescent tags can be used to study the structure and physiology of MG in these preparations. Moreover, bath application of reagents (such as ATP) can establish spatial and temporal gradients that induce chemokinesis- and chemotaxis-like MG migration in tissue slices. Thus, the approach is useful for dissecting the molecular basis of MG behaviors and testing whether candidate reagents alter MG behavior and function in semi-intact central nervous system tissue preparations.

Purines induce directed migration and rapid homing of microglia to injured pyramidal neurons in developing hippocampus.

Traumatic CNS injury activates and mobilizes resident parenchymal microglia (MG), which rapidly accumulate near injured neurons where they transform into phagocytes. The mechanisms underlying this rapid 'homing' in situ are unknown. Using time-lapse confocal imaging in acutely excised neonatal hippocampal slices, we show that rapid accumulation of MG near somata of injured pyramidal neurons in the stratum pyramidale (SP) results from directed migration from tissue regions immediately adjacent to (<200 microm from) the SP. Time-lapse sequences also reveal a 'spreading activation wave' wherein MG situated progressively farther from the SP begin to migrate later and exhibit less directional migration toward the SP. Because purines have been implicated in MG activation and chemotaxis, we tested whether ATP/ADP released from injured pyramidal neurons might account for these patterns of MG behavior. Indeed, application of apyrase, which degrades extracellular ATP/ADP, inhibits MG motility and homing to injured neurons in the SP. Moreover, bath application of exogenous ATP/ADP disrupts MG homing by inducing directional migration toward the slice exterior and away from injured neurons. These results indicate that extracellular ATP/ADP is both necessary and sufficient to induce directional migration and rapid homing of neonatal MG to injured neurons in situ. Rapid, ATP/ADP-dependent MG homing may promote clearance of dead and dying cells and help limit secondary damage during the critical first few hours after neuronal injury.

Imaging microglia in live brain slices and slice cultures.

INTRODUCTIONThis protocol describes methods for fluorescence labeling and time-lapse confocal imaging of microglia in acutely prepared tissue slices from developing and adult animals, and to slice cultures derived from early post-natal day 7 (

The P2Y12 receptor regulates microglial activation by extracellular nucleotides.

Microglia are primary immune sentinels of the CNS. Following injury, these cells migrate or extend processes toward sites of tissue damage. CNS injury is accompanied by release of nucleotides, serving as signals for microglial activation or chemotaxis. Microglia express several purinoceptors, including a G(i)-coupled subtype that has been implicated in ATP- and ADP-mediated migration in vitro. Here we show that microglia from mice lacking G(i)-coupled P2Y(12) receptors exhibit normal baseline motility but are unable to polarize, migrate or extend processes toward nucleotides in vitro or in vivo. Microglia in P2ry(12)(-/-) mice show significantly diminished directional branch extension toward sites of cortical damage in the living mouse. Moreover, P2Y(12) expression is robust in the 'resting' state, but dramatically reduced after microglial activation. These results imply that P2Y(12) is a primary site at which nucleotides act to induce microglial chemotaxis at early stages of the response to local CNS injury.

Early activation, motility, and homing of neonatal microglia to injured neurons does not require protein synthesis.

Neuronal injury in CNS tissues induces a rapid activation and mobilization of resident microglia (MG). It is widely assumed that changes in gene expression drive the morphological transformation of MG and regulate their mobilization during activation. Here, we used acutely excised neonatal rat brain slices to test whether the morphological transformation and homing of MG to injured neurons requires gene expression and de novo protein synthesis. Traumatic injury during excision of live brain tissue slices induces a rapid and transient translocation of a transcription factor, NF-kappaB, to nuclei in MG. This is followed within 4-8 h by an increase in immunolabeling for cell adhesion molecules and lysosomal proteins, accompanied by changes in cell morphology. Application of anisomycin, a protein synthesis inhibitor, prevents the increase in immunolabeling for markers of MG activation but not the morphological transformation. Confocal time-lapse imaging in live tissue slices indicates that MG cell motility (branch extension and retraction) and locomotion are unaffected by anisomycin at early postinjury time-points (<4 h), while at later time-points (4-8 h postinjury) MG locomotion but not motility is inhibited. Thus, activated MG rapidly localize to injured pyramidal neuron cell bodies by 4-h postinjury, even in the presence of anisomycin. Moreover, this early MG activation and homing to injured neurons is unaffected in tissue slices from beta2 integrin deficient mice. These results indicate that gene activation and new protein synthesis coincide with, but are not necessary for, the rapid morphological transformation and early migration-dependent homing of activated MG to injured neurons in CNS tissues.