Giulia Soto scite author profile

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 Gαq-coupled signaling cascades. This method enables flexible, cell-type specific quantitative profiling of subcellular proteome snapshots in the mouse brain.

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Pathway-specific dysregulation of striatal excitatory synapses by LRRK2 mutations

Chen

Soto

Dumrongprechachan

et al. 2020

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LRRK2 is a kinase expressed in striatal spiny projection neurons (SPNs), cells which lose dopaminergic input in Parkinson’s disease (PD). R1441C and G2019S are the most common pathogenic mutations of LRRK2. How these mutations alter the structure and function of individual synapses on direct and indirect pathway SPNs is unknown and may reveal pre-clinical changes in dopamine-recipient neurons that predispose towards disease. Here, R1441C and G2019S knock-in mice enabled thorough evaluation of dendritic spines and synapses on pathway-identified SPNs. Biochemical synaptic preparations and super-resolution imaging revealed increased levels and altered organization of glutamatergic AMPA receptors in LRRK2 mutants. Relatedly, decreased frequency of miniature excitatory post-synaptic currents accompanied changes in dendritic spine nano-architecture, and single-synapse currents, evaluated using 2-photon glutamate uncaging. Overall, LRRK2 mutations reshaped synaptic structure and function, an effect exaggerated in R1441C dSPNs. These data open the possibility of new neuroprotective therapies aimed at SPN synapse function, prior to disease onset.

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Pathway-specific deregulation of striatal excitatory synapses in LRRK2 mutations

Chen

Soto

Bannon

et al. 2020

Preprint

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ABSTRACTLRRK2 is a kinase expressed in striatal spiny projection neurons (SPNs), cells which lose dopaminergic input in Parkinson’s disease (PD). R1441C and G2019S are the most common pathogenic mutations of LRRK2. How these mutations alter the structure and function of individual synapses on direct and indirect pathway SPNs is unknown and may reveal pre-clinical changes in dopamine-recipient neurons that predispose towards disease. Here, R1441C and G2019S knock-in mice enabled thorough evaluation of dendritic spines and synapses on pathway-identified SPNs. Biochemical synaptic preparations and super-resolution imaging revealed increased levels and altered organization of glutamatergic AMPA receptors in LRRK2 mutants. Relatedly, decreased frequency of excitatory post-synaptic currents accompanied changes in dendritic spine nano-architecture, and single-synapse currents, evaluated using 2-photon glutamate uncaging. Overall, LRRK2 mutations reshaped synaptic structure and function, an effect exaggerated in R1441C dSPNs. These data open the possibility of new neuroprotective therapies aimed at SPN synapse function, prior to disease onset.

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Cell type and subcellular compartment specific APEX2 proximity labeling proteomics in the mouse brain

Dumrongprechachan¹,

Soto

MacDonald

et al. 2021

Preprint

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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 neuroproteome 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 proteome in the mouse brain. Using adenoassociated viral transduction, we express subcellular-localized APEX2 to map the proteome of the nucleus, cytosol, and cell membrane of Drd1 receptor-positive striatal neurons. We show that each APEX2 construct can differentially and rapidly biotinylate proteins in situ across various subcellular compartments, confirmed by imaging, electron microscopy, and mass spectrometry. This method enables flexible, cell-type specific quantitative profiling of subcellular proteome in the mouse brain.

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Author response: Pathway-specific dysregulation of striatal excitatory synapses by LRRK2 mutations

Chen

Soto

Dumrongprechachan

et al. 2020

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Giulia Soto

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

Pathway-specific dysregulation of striatal excitatory synapses by LRRK2 mutations

Pathway-specific deregulation of striatal excitatory synapses in LRRK2 mutations

Cell type and subcellular compartment specific APEX2 proximity labeling proteomics in the mouse brain

Author response: Pathway-specific dysregulation of striatal excitatory synapses by LRRK2 mutations

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