Abstract
The first electron microscope was constructed in 1931. Several decades later, techniques were developed to allow the first ultrastructural analysis of microglia by transmission electron microscopy (EM). In the 50 years that followed, important roles of microglia have been identified, specifically due to the ultrastructural resolution currently available only with EM. In particular, the addition of electron-dense staining using immunohistochemical EM methods has allowed the identification of microglial cell bodies, as well as processes, which are difficult to recognize in EM, and to uncover their complex interactions with neurons and synapses. The ability to recognize neuronal, astrocytic, and oligodendrocytic compartments in the neuropil without any staining is another invaluable advantage of EM over light microscopy for studying intimate cell–cell contacts. The technique has been essential in defining microglial interactions with neurons and synapses, thus providing, among other discoveries, important insights into their roles in synaptic stripping and pruning via phagocytosis of extraneous synapses. Recent technological advances in EM including serial block-face imaging and focused-ion beam scanning EM have also facilitated automated acquisition of large tissue volumes required to reconstruct neuronal circuits in 3D at nanometer-resolution. These cutting-edge techniques which are now becoming increasingly available will further revolutionize the study of microglia across stages of the lifespan, brain regions, and contexts of health and disease. In this mini-review, we will focus on defining the distinctive ultrastructural features of microglia and the unique insights into their function that were provided by EM.
Highlights
Microglia are the only immune cells that permanently reside in the brain
In addition to technological advances in both scanning electron microscope (SEM) and transmission electron microscope (TEM), the rapid development of cryoEM techniques described here could uncover native protein structures within microglia. It could pave the way for discoveries into the snapshot of microglial–neuron and microglia–glia interactions without requiring fixatives, and without the corresponding tissue deformation that occurs with rapid fixation currently required to preserve ultrastructure
While fixatives and ultrathin sections required for electron microscopy (EM) are not compatible with post-imaging analysis of RNA or proteins, future iterations of CORRELATIVE LIGHT AND ELECTRON MICROSCOPY (CLEM) and advances in single-cell mRNA isolation may be able to isolate subcellular tissue fractions for further analysis
Summary
Distinctive Features, Phenotypes, and Functions Discovered Over the Past 60 Years by Electron Microscopy. Recent technological advances in EM including serial block-face imaging and focused-ion beam scanning EM have facilitated automated acquisition of large tissue volumes required to reconstruct neuronal circuits in 3D at nanometer-resolution These cutting-edge techniques which are becoming increasingly available will further revolutionize the study of microglia across stages of the lifespan, brain regions, and contexts of health and disease. In this mini-review, we will focus on defining the distinctive ultrastructural features of microglia and the unique insights into their function that were provided by EM
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