Integrin-Kindlin3 requirements for microglial motility in vivo are distinct from those for macrophages
Julia Meller, … , Bruce D. Trapp, Tatiana V. Byzova
Julia Meller, … , Bruce D. Trapp, Tatiana V. Byzova
Published June 2, 2017
Citation Information: JCI Insight. 2017;2(11):e93002. https://doi.org/10.1172/jci.insight.93002.
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Research Article Cell biology Neuroscience

Integrin-Kindlin3 requirements for microglial motility in vivo are distinct from those for macrophages

Abstract

Microglia play a critical role in the development and homeostasis of the CNS. While mobilization of microglia is critical for a number of pathologies, understanding of the mechanisms of their migration in vivo is limited and often based on similarities to macrophages. Kindlin3 deficiency as well as Kindlin3 mutations of integrin-binding sites abolish both integrin inside-out and outside-in signaling in microglia, thereby resulting in severe deficiencies in cell adhesion, polarization, and migration in vitro, which are similar to the defects observed in macrophages. In contrast, while Kindlin3 mutations impaired macrophage mobilization in vivo, they had no effect either on the population of microglia in the CNS during development or on mobilization of microglia and subsequent microgliosis in a model of multiple sclerosis. At the same time, acute microglial response to laser-induced injury was impaired by the lack of Kindlin3-integrin interactions. Based on 2-photon imaging of microglia in the brain, Kindlin3 is required for elongation of microglial processes toward the injury site and formation of phagosomes in response to brain injury. Thus, while Kindlin3 deficiency in human subjects is not expected to diminish the presence of microglia within CNS, it might delay the recovery process after injury, thereby exacerbating its complications.

Authors

Julia Meller, Zhihong Chen, Tejasvi Dudiki, Rebecca M. Cull, Rakhilya Murtazina, Saswat K. Bal, Elzbieta Pluskota, Samantha Stefl, Edward F. Plow, Bruce D. Trapp, Tatiana V. Byzova

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Figure 14

Kindlin3 is involved in microglial response to laser-induced brain injury.

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Kindlin3 is involved in microglial response to laser-induced brain injur...
(A) Selected projections from a stack of multiphoton images taken 80–100 μm below the pia, acquired through the cranial window in vivo. Microglia projections labeled in green by GFP expressed under Cx3cr1 promoter coalesce around laser injury (center). Blood vessels are labeled in red by retro-orbital injection of fluorescently conjugated dextran. Numbers above images represent time in minutes. Scale bar: 20 μm. (B) Representative kymographs showing dynamics of microglial processes toward the ablation site (indicated by arrow). The x axis represents the distance (75-μm field); the y axis represents the time from top to bottom (90 minutes, starting at 45 seconds after the injury). (C) Velocity of microglial process toward the site of injury was determined from kymographs, as described in Methods (n = 8 kymographs per group from total 6 animals). Box-and-whisker plots show median (line within box), upper and lower quartiles (bounds of box), and minimum and maximum values (bars). ***P < 0.001, 1-tailed Student’s t test.