Rapid signaling in distinct dopaminergic axons during locomotion and reward

Dopaminergic projection axons from the midbrain to the striatum are crucial for motor control, as their degeneration in Parkinson disease results in profound movement deficits. Paradoxically, most recording methods report rapid phasic dopamine signalling (~100-ms bursts) in response to unpredicted rewards, with little evidence for movement-related signalling. The leading model posits that phasic signalling in striatum-targeting dopamine neurons drives reward-based learning, whereas slow variations in firing (tens of seconds to minutes) in these same neurons bias animals towards or away from movement. However, current methods have provided little evidence to support or refute this model. Here, using new optical recording methods, we report the discovery of rapid phasic signalling in striatum-targeting dopaminergic axons that is associated with, and capable of triggering, locomotion in mice. Axons expressing these signals were largely distinct from those that responded to unexpected rewards. These results suggest that dopaminergic neuromodulation can differentially impact motor control and reward learning with sub-second precision, and indicate that both precise signal timing and neuronal subtype are important parameters to consider in the treatment of dopamine-related disorders.

[1]  O. Hornykiewicz [Dopamine (3-hydroxytyramine) in the central nervous system and its relation to the Parkinson syndrome in man]. , 1962, Deutsche medizinische Wochenschrift.

[2]  O. Hornykiewicz Dopamin (3-Hydroxytyramin) im Zentralnervensystem und seine Beziehung zum Parkinson-Syndrom des Menschen , 1962 .

[3]  J. Woodward,et al.  Calcium-dependent and -independent release of endogenous dopamine from rat striatal synaptosomes , 1988, Brain Research.

[4]  W. Schultz,et al.  Dopamine neurons of the monkey midbrain: contingencies of responses to active touch during self-initiated arm movements. , 1990, Journal of neurophysiology.

[5]  W. Schultz,et al.  Dopamine neurons of the monkey midbrain: contingencies of responses to stimuli eliciting immediate behavioral reactions. , 1990, Journal of neurophysiology.

[6]  W. Schultz,et al.  Importance of unpredictability for reward responses in primate dopamine neurons. , 1994, Journal of neurophysiology.

[7]  Peter Dayan,et al.  A Neural Substrate of Prediction and Reward , 1997, Science.

[8]  J. Hollerman,et al.  Dopamine neurons report an error in the temporal prediction of reward during learning , 1998, Nature Neuroscience.

[9]  D. Tank,et al.  Action potentials reliably invade axonal arbors of rat neocortical neurons. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[10]  R. Wightman,et al.  Detecting subsecond dopamine release with fast-scan cyclic voltammetry in vivo. , 2003, Clinical chemistry.

[11]  W. Dauer,et al.  Parkinson's Disease Mechanisms and Models , 2003, Neuron.

[12]  T. Turner Nicotine Enhancement of Dopamine Release by a Calcium-Dependent Increase in the Size of the Readily Releasable Pool of Synaptic Vesicles , 2004, The Journal of Neuroscience.

[13]  K. Deisseroth,et al.  Millisecond-timescale, genetically targeted optical control of neural activity , 2005, Nature Neuroscience.

[14]  W. Pan,et al.  Dopamine Cells Respond to Predicted Events during Classical Conditioning: Evidence for Eligibility Traces in the Reward-Learning Network , 2005, The Journal of Neuroscience.

[15]  W. Schultz,et al.  Adaptive Coding of Reward Value by Dopamine Neurons , 2005, Science.

[16]  Prof. Dr. A. Carlsson Evidence for a role of dopamine in extrapyramidal functions , 1964, Acta Neurovegetativa.

[17]  K. Berridge The debate over dopamine’s role in reward: the case for incentive salience , 2007, Psychopharmacology.

[18]  Elyssa B. Margolis,et al.  The ventral tegmental area revisited: is there an electrophysiological marker for dopaminergic neurons? , 2006, The Journal of physiology.

[19]  P. Dayan,et al.  Tonic dopamine: opportunity costs and the control of response vigor , 2007, Psychopharmacology.

[20]  W. Schultz Multiple dopamine functions at different time courses. , 2007, Annual review of neuroscience.

[21]  D. Tank,et al.  Imaging Large-Scale Neural Activity with Cellular Resolution in Awake, Mobile Mice , 2007, Neuron.

[22]  S. Ikemoto Dopamine reward circuitry: Two projection systems from the ventral midbrain to the nucleus accumbens–olfactory tubercle complex , 2007, Brain Research Reviews.

[23]  M. Roesch,et al.  Dopamine neurons encode the better option in rats deciding between differently delayed or sized rewards , 2007, Nature Neuroscience.

[24]  R. Wightman,et al.  Associative learning mediates dynamic shifts in dopamine signaling in the nucleus accumbens , 2007, Nature Neuroscience.

[25]  J. Krakauer,et al.  Why Don't We Move Faster? Parkinson's Disease, Movement Vigor, and Implicit Motivation , 2007, The Journal of Neuroscience.

[26]  F. Fujiyama,et al.  Single Nigrostriatal Dopaminergic Neurons Form Widely Spread and Highly Dense Axonal Arborizations in the Neostriatum , 2009, The Journal of Neuroscience.

[27]  D. Tank,et al.  Intracellular dynamics of hippocampal place cells during virtual navigation , 2009, Nature.

[28]  Mark J. Schnitzer,et al.  Automated Analysis of Cellular Signals from Large-Scale Calcium Imaging Data , 2009, Neuron.

[29]  O. Hikosaka,et al.  Two types of dopamine neuron distinctly convey positive and negative motivational signals , 2009, Nature.

[30]  S. Mizumori,et al.  Conjunctive encoding of movement and reward by ventral tegmental area neurons in the freely navigating rodent. , 2010, Behavioral neuroscience.

[31]  Xin Jin,et al.  Start/stop signals emerge in nigrostriatal circuits during sequence learning , 2010, Nature.

[32]  Lin Tian,et al.  Functional imaging of hippocampal place cells at cellular resolution during virtual navigation , 2010, Nature Neuroscience.

[33]  Aristides B. Arrenberg,et al.  Spatial gradients and multidimensional dynamics in a neural integrator circuit , 2011, Nature Neuroscience.

[34]  Hongkui Zeng,et al.  Differential tuning and population dynamics of excitatory and inhibitory neurons reflect differences in local intracortical connectivity , 2011, Nature Neuroscience.

[35]  Lin Tian,et al.  Activity in motor-sensory projections reveals distributed coding in somatosensation , 2012, Nature.

[36]  Anne E Carpenter,et al.  Neuron-type specific signals for reward and punishment in the ventral tegmental area , 2011, Nature.

[37]  K. Deisseroth,et al.  Striatal Dopamine Release Is Triggered by Synchronized Activity in Cholinergic Interneurons , 2012, Neuron.

[38]  B. Sabatini,et al.  Dopaminergic neurons inhibit striatal output via non-canonical release of GABA , 2012, Nature.

[39]  J. Salamone,et al.  The Mysterious Motivational Functions of Mesolimbic Dopamine , 2012, Neuron.

[40]  K. Deisseroth,et al.  Input-specific control of reward and aversion in the ventral tegmental area , 2012, Nature.

[41]  Jason Chung,et al.  Long-term channelrhodopsin-2 (ChR2) expression can induce abnormal axonal morphology and targeting in cerebral cortex , 2013, Front. Neural Circuits.

[42]  P. Janak,et al.  Establishing causality for dopamine in neural function and behavior with optogenetics , 2013, Brain Research.

[43]  Stefan R. Pulver,et al.  Ultra-sensitive fluorescent proteins for imaging neuronal activity , 2013, Nature.

[44]  J. Roeper Dissecting the diversity of midbrain dopamine neurons , 2013, Trends in Neurosciences.

[45]  A. Graybiel,et al.  Prolonged Dopamine Signalling in Striatum Signals Proximity and Value of Distant Rewards , 2013, Nature.

[46]  F. Cicchetti,et al.  Defining midbrain dopaminergic neuron diversity by single-cell gene expression profiling. , 2014, Cell reports.

[47]  Bin Liu,et al.  Modulation of dopamine release in the striatum by physiologically relevant levels of nicotine , 2014, Nature Communications.

[48]  Raag D. Airan,et al.  Natural Neural Projection Dynamics Underlying Social Behavior , 2014, Cell.

[49]  James G. Heys,et al.  The Functional Micro-organization of Grid Cells Revealed by Cellular-Resolution Imaging , 2014, Neuron.

[50]  Talia N. Lerner,et al.  Intact-Brain Analyses Reveal Distinct Information Carried by SNc Dopamine Subcircuits , 2015, Cell.

[51]  Daniel A. Dombeck,et al.  Calcium transient prevalence across the dendritic arbor predicts place field properties , 2014, Nature.

[52]  Liqun Luo,et al.  Diversity of Transgenic Mouse Models for Selective Targeting of Midbrain Dopamine Neurons , 2015, Neuron.

[53]  Liqun Luo,et al.  Circuit Architecture of VTA Dopamine Neurons Revealed by Systematic Input-Output Mapping , 2015, Cell.

[54]  Joseph W. Barter,et al.  Beyond reward prediction errors: the role of dopamine in movement kinematics , 2015, Front. Integr. Neurosci..

[55]  Karl Deisseroth,et al.  Optogenetics enables functional analysis of human embryonic stem cell–derived grafts in a Parkinson's disease model , 2015, Nature Biotechnology.

[56]  Ilana B. Witten,et al.  Reward and choice encoding in terminals of midbrain dopamine neurons depends on striatal target , 2016, Nature Neuroscience.

[57]  Vaughn L. Hetrick,et al.  Mesolimbic Dopamine Signals the Value of Work , 2015, Nature Neuroscience.

[58]  Jakob K. Dreyer,et al.  Representation of spontaneous movement by dopaminergic neurons is cell-type selective and disrupted in parkinsonism , 2016, Proceedings of the National Academy of Sciences.