All-optical visualization of specific molecules in the ultrastructural context of brain tissue

Understanding the molecular anatomy and neural connectivity of the brain requires imaging technologies that can map the 3D nanoscale distribution of specific proteins in the context of brain ultrastructure. Light and electron microscopy (EM) enable visualization of either specific labels or anatomic...

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Published inbioRxiv
Main Authors Ons M'saad, Kasula, Ravikiran, Kondratiuk, Ilona, Kidd, Phylicia, Falahati, Hanieh, Gentile, Juliana E, Niescier, Robert F, Watters, Katherine, Sterner, Robert C, Lee, Seong, Liu, Xinran, De Camilli, Pietro, Rothman, James E, Koleske, Anthony J, Biederer, Thomas, Bewersdorf, Joerg
Format Paper
LanguageEnglish
Published Cold Spring Harbor Cold Spring Harbor Laboratory Press 17.04.2022
Cold Spring Harbor Laboratory
Edition1.2
Subjects
Bassoon protein
Electron microscopy
Glial fibrillary acidic protein
Microscopy
Myelin
Myelin basic protein
Neural networks
Neuroimaging
Neuropil
Neuroscience
Organelles
Patent applications
Postsynaptic density proteins
Protein folding
Proteins
Synaptophysin
Ultrastructure
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Summary:Understanding the molecular anatomy and neural connectivity of the brain requires imaging technologies that can map the 3D nanoscale distribution of specific proteins in the context of brain ultrastructure. Light and electron microscopy (EM) enable visualization of either specific labels or anatomical ultrastructure, but combining molecular specificity with anatomical context is challenging. Here, we present pan-Expansion Microscopy of tissue (pan-ExM-t), an all-optical mouse brain imaging method that combines ~24-fold linear expansion of biological samples with fluorescent pan-staining of protein densities (providing EM-like ultrastructural context), and immunolabeling of protein targets (for molecular imaging). We demonstrate the versatility of this approach by imaging the established synaptic markers Homer1, Bassoon, PSD-95, Synaptophysin, the astrocytic protein GFAP, myelin basic protein (MBP), and anti-GFP antibodies in dissociated neuron cultures and mouse brain tissue sections. pan-ExM-t reveals these markers in the context of ultrastructural features such as pre and postsynaptic densities, 3D nanoarchitecture of neuropil, and the fine structures of cellular organelles. pan-ExM-t is adoptable in any neurobiological laboratory with access to a confocal microscope and has therefore broad applicability in the research community. Competing Interest Statement J.B. has financial interests in Bruker Corp. and Hamamatsu Photonics. O.M., J.E.R. and J.B. filed patent applications with the U.S. patent office covering the presented method. O.M. and J.B. are co-founders of panluminate Inc. which is developing related products. Footnotes * Supplemental Videos have been added
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Competing Interest Statement: J.B. has financial interests in Bruker Corp. and Hamamatsu Photonics. O.M., J.E.R. and J.B. filed patent applications with the U.S. patent office covering the presented method. O.M. and J.B. are co-founders of panluminate Inc. which is developing related products.
ISSN:2692-8205
2692-8205
DOI:10.1101/2022.04.04.486901