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Cell-type and subcellular compartment-specific APEX2 proximity labeling reveals activity-dependent nuclear proteome dynamics in the striatum

Vasin Dumrongprechachan, Ryan Salisbury, Giulia Soto, Manish Kumar, Matthew L. MacDonald, Yevgenia Kozorovitskiy

2021Nature Communications84 citationsDOIOpen Access PDF

Abstract

Abstract The vertebrate brain consists of diverse neuronal types, classified by distinct anatomy and function, along with divergent transcriptomes and proteomes. Defining the cell-type specific neuroproteomes is important for understanding the development and functional organization of neural circuits. This task remains challenging in complex tissue, due to suboptimal protein isolation techniques that often result in loss of cell-type specific information and incomplete capture of subcellular compartments. Here, we develop a genetically targeted proximity labeling approach to identify cell-type specific subcellular proteomes in the mouse brain, confirmed by imaging, electron microscopy, and mass spectrometry. We virally express subcellular-localized APEX2 to map the proteome of direct and indirect pathway spiny projection neurons in the striatum. The workflow provides sufficient depth to uncover changes in the proteome of striatal neurons following chemogenetic activation of Gα q -coupled signaling cascades. This method enables flexible, cell-type specific quantitative profiling of subcellular proteome snapshots in the mouse brain.

Topics & Concepts

ProteomeCell typeProtein subcellular localization predictionSubcellular localizationBiologyCell biologyComputational biologyMedium spiny neuronProteomicsCompartment (ship)CellTranscriptomeNeuroscienceStriatumBioinformaticsGene expressionGeneBiochemistryCytoplasmGeologyOceanographyDopamineBiotin and Related StudiesClick Chemistry and ApplicationsUbiquitin and proteasome pathways
Cell-type and subcellular compartment-specific APEX2 proximity labeling reveals activity-dependent nuclear proteome dynamics in the striatum | Litcius