Literature DB >> 30769276

Mechanisms and regulation of dopamine release.

Changliang Liu1, Pascal S Kaeser2.   

Abstract

Dopamine controls motor functions, motivation, and reward-related learning through G-protein coupled receptor signaling. The current working model is that upon release, dopamine diffuses to influence many target cells via wide-spread receptors. Recent studies, however, suggest that dopamine release is fast and generates small signaling hotspots. In this review, we summarize progress on the understanding of the dopamine release apparatus and evaluate how its properties may shape dopamine signaling during firing. We discuss how mechanisms of regulation may act through this machinery and propose that striatal architecture for dopamine signaling may have evolved to support rapid dopamine coding.
Copyright © 2019 Elsevier Ltd. All rights reserved.

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Year:  2019        PMID: 30769276      PMCID: PMC6629510          DOI: 10.1016/j.conb.2019.01.001

Source DB:  PubMed          Journal:  Curr Opin Neurobiol        ISSN: 0959-4388            Impact factor:   6.627


  28 in total

1.  Editorial overview: Molecular neuroscience.

Authors:  Timothy A Ryan; Yishi Jin
Journal:  Curr Opin Neurobiol       Date:  2019-06-30       Impact factor: 6.627

2.  History-dependent dopamine release increases cAMP levels in most basal amygdala glutamatergic neurons to control learning.

Authors:  Andrew Lutas; Kayla Fernando; Stephen X Zhang; Abhijeet Sambangi; Mark L Andermann
Journal:  Cell Rep       Date:  2022-01-25       Impact factor: 9.423

3.  Molecular and functional architecture of striatal dopamine release sites.

Authors:  Aditi Banerjee; Cordelia Imig; Karthik Balakrishnan; Lauren Kershberg; Noa Lipstein; Riikka-Liisa Uronen; Jiexin Wang; Xintong Cai; Fritz Benseler; Jeong Seop Rhee; Benjamin H Cooper; Changliang Liu; Sonja M Wojcik; Nils Brose; Pascal S Kaeser
Journal:  Neuron       Date:  2021-11-11       Impact factor: 17.173

4.  Iron commensalism of mesenchymal glioblastoma promotes ferroptosis susceptibility upon dopamine treatment.

Authors:  Vu T A Vo; Sohyun Kim; Tuyen N M Hua; Jiwoong Oh; Yangsik Jeong
Journal:  Commun Biol       Date:  2022-06-16

5.  Prefrontal Cortex-Driven Dopamine Signals in the Striatum Show Unique Spatial and Pharmacological Properties.

Authors:  Martín F Adrover; Jung Hoon Shin; Cesar Quiroz; Sergi Ferré; Julia C Lemos; Veronica A Alvarez
Journal:  J Neurosci       Date:  2020-08-28       Impact factor: 6.167

6.  A Novel Dop2/Invertebrate-Type Dopamine Signaling System Potentially Mediates Stress, Female Reproduction, and Early Development in the Pacific Oyster (Crassostrea gigas).

Authors:  Julie Schwartz; Emilie Réalis-Doyelle; Lorane Le Franc; Pascal Favrel
Journal:  Mar Biotechnol (NY)       Date:  2021-08-07       Impact factor: 3.619

Review 7.  Spatial and temporal scales of dopamine transmission.

Authors:  Changliang Liu; Pragya Goel; Pascal S Kaeser
Journal:  Nat Rev Neurosci       Date:  2021-04-09       Impact factor: 34.870

8.  Molecular Features of Parkinson's Disease in Patient-Derived Midbrain Dopaminergic Neurons.

Authors:  Yong Ren; Houbo Jiang; Jiali Pu; Li Li; Jianbo Wu; Yaping Yan; Guohua Zhao; Thomas J Guttuso; Baorong Zhang; Jian Feng
Journal:  Mov Disord       Date:  2021-09-26       Impact factor: 10.338

9.  Prenatal THC Does Not Affect Female Mesolimbic Dopaminergic System in Preadolescent Rats.

Authors:  Francesco Traccis; Valeria Serra; Claudia Sagheddu; Mauro Congiu; Pierluigi Saba; Gabriele Giua; Paola Devoto; Roberto Frau; Joseph Francois Cheer; Miriam Melis
Journal:  Int J Mol Sci       Date:  2021-02-07       Impact factor: 5.923

Review 10.  Dopamine, Updated: Reward Prediction Error and Beyond.

Authors:  Talia N Lerner; Ashley L Holloway; Jillian L Seiler
Journal:  Curr Opin Neurobiol       Date:  2020-11-14       Impact factor: 6.627
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