Lauren Kershberg scite author profile

Dopamine controls essential brain functions through volume transmission. Different from fast synaptic transmission, where neurotransmitter release and receptor activation are tightly coupled by an active zone, dopamine transmission is widespread and may not necessitate these organized release sites. Here, we determine whether striatal dopamine secretion employs specialized machinery for release. Using super resolution microscopy, we identified co-clustering of the active zone scaffolding proteins bassoon, RIM and ELKS in ∼30% of dopamine varicosities. Conditional RIM knockout disrupted this scaffold and, unexpectedly, abolished dopamine release, while ELKS knockout had no effect. Optogenetic experiments revealed that dopamine release was fast and had a high release probability, indicating the presence of protein scaffolds for coupling Ca influx to vesicle fusion. Hence, dopamine secretion is mediated by sparse, mechanistically specialized active zone-like release sites. This architecture supports spatially and temporally precise coding for dopamine and provides molecular machinery for regulation.

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Molecular and functional architecture of striatal dopamine release sites

Banerjee

Imig

Balakrishnan

et al. 2022

Neuron

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Molecular and functional architecture of striatal dopamine release sites

Banerjee

Imig

Balakrishnan

et al. 2020

Preprint

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Dopamine controls striatal circuit function, but its transmission mechanisms are not well understood. We recently showed that dopamine secretion requires RIM, suggesting that it occurs at active zone-like sites similar to conventional synapses. Here, we establish using a systematic conditional gene knockout approach that Munc13 and Liprin-α, active zone proteins for vesicle priming and release site organization, are important for dopamine secretion. Correspondingly, RIM zinc finger and C2B domains, which bind to Munc13 and Liprin-α, respectively, are needed to restore dopamine release in RIM knockout mice. In contrast, and different from conventional synapses, the active zone scaffolds RIM-BP and ELKS, and the RIM domains that bind to them, are expendable. Hence, dopamine release necessitates priming and release site scaffolding by RIM, Munc13, and Liprin-α, but other active zone proteins are dispensable. Our work establishes that molecularly simple but efficient release site architecture mediates fast dopamine exocytosis.

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Protein composition of axonal dopamine release sites in the striatum

Kershberg

Banerjee

Kaeser

2022

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Dopamine is an important modulator of cognition and movement. We recently found that evoked dopamine secretion is fast and relies on active zone-like release sites. Here, we used in vivo biotin-identification (iBioID) proximity proteomics in mouse striatum to assess which proteins are present at these sites. Using three release site baits, we identified proteins that are enriched over the general dopamine axonal protein content, and they fell into categories including active zone, Ca2+ regulatory and synaptic vesicle proteins. We also detected many proteins not previously associated with vesicular exocytosis. Knockout of the presynaptic organizer protein RIM strongly decreased the hit number obtained with iBioID, while Synaptotagmin-1 knockout did not. α-Synuclein, a protein linked to Parkinson's disease, was enriched at release sites, and its enrichment was lost in both tested mutants. We conclude that RIM organizes scaffolded dopamine release sites and provide a proteomic assessment of the composition of these sites.

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Protein composition of axonal dopamine release sites in the striatum

Kershberg

Banerjee

Kaeser

2022

Preprint

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Mechanisms of neuromodulatory transmission in the brain remain ambiguous. Dopamine is a prototypical neuromodulator, and it was recently found that its secretion relies on active zone-like release site assemblies. Here, we use in vivo biotin-identification (iBioID) proximity proteomics in mouse striatum to isolate dopamine release site proteins enriched over the general dopamine axonal protein content. Using three bait proteins, we identified 527 proteins that fall into several synaptic protein classes, including active zone, calcium regulatory and synaptic vesicle proteins. We also detected many proteins not previously associated with synaptic exocytosis. Knockout of the presynaptic organizer protein RIM profoundly disrupted dopamine release site composition assessed by iBioID, while Synaptotagmin-1 knockout did not. Alpha-synuclein, a protein linked to Parkinson's disease, was enriched at release sites, and this enrichment was lost in both tested mutants. We conclude that RIM organizes scaffolded dopamine release sites and we define the protein composition of these sites.

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