A novel preparation for histological analyses of intraventricular macrophages in the embryonic brain.
Futoshi MurayamaHisa AsaiArya Kirone PatraHiroaki WakeTakaki MiyataYuki HattoriPublished in: Development, growth & differentiation (2024)
Microglia colonize the brain starting on embryonic day (E) 9.5 in mice, and their population increases with development. We have previously demonstrated that some microglia are derived from intraventricular macrophages, which frequently infiltrate the pallium at E12.5. To address how the infiltration of intraventricular macrophages is spatiotemporally regulated, histological analyses detecting how these cells associate with the surrounding cells at the site of infiltration into the pallial surface are essential. Using two-photon microscopy-based in vivo imaging, we demonstrated that most intraventricular macrophages adhere to the ventricular surface. This is a useful tool for imaging intraventricular macrophages maintaining their original position, but this method cannot be used for observing deeper brain regions. Meanwhile, we found that conventional cryosection-based and naked pallial slice-based observation resulted in unexpected detachment from the ventricular surface of intraventricular macrophages and their mislocation, suggesting that previous histological analyses might have failed to determine their physiological number and location in the ventricular space. To address this, we sought to establish a methodological preparation that enables us to delineate the structure and cellular interactions when intraventricular macrophages infiltrate the pallium. Here, we report that brain slices pretreated with agarose-embedding maintained adequate density and proper positioning of intraventricular macrophages on the ventricular surface. This method also enabled us to perform the immunostaining. We believe that this is helpful for conducting histological analyses to elucidate the mechanisms underlying intraventricular macrophage infiltration into the pallium and their cellular properties, leading to further understanding of the process of microglial colonization into the developing brain.
Keyphrases
- resting state
- heart failure
- white matter
- high resolution
- left ventricular
- induced apoptosis
- functional connectivity
- inflammatory response
- cerebral ischemia
- metabolic syndrome
- adipose tissue
- multiple sclerosis
- magnetic resonance imaging
- cell cycle arrest
- signaling pathway
- high throughput
- transcription factor
- brain injury
- computed tomography
- photodynamic therapy
- cell proliferation
- fluorescence imaging
- subarachnoid hemorrhage
- wild type