Dichotomous Dopaminergic Control of Striatal Synaptic Plasticity

Shen, Weisen; Flajolet, Marc; Greengard, Paul; Surmeier, D. James

doi:10.1126/science.1160575

Cited by 1,064 publications

(1,445 citation statements)

References 30 publications

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“…The resulting transient activity increase in those NoGo cells that are concurrently excited by corticostriatal glutamatergic input is associated with activity-dependent synaptic strengthening (LTP), such that the system is more likely to suppress the maladaptive action in future encounters with the same sensory event. This effect is also consistent with studies in which a lack of D2 receptor stimulation (a ''pause'' in DA release) was associated with LTP in striatopallidal cells (Shen et al 2008). The model has been used to simulate the effects of Parkinson's disease and pharmacological manipulations on learning and decision making processes in humans, and predicted that learning from positive and negative outcomes would be modulated in opposite directions by such treatments, as confirmed empirically (Frank et al 2004; for review see Cohen and Frank 2009).…”

Section: Models Of the Effects Of Dopamine Releasesupporting

confidence: 79%

“…DA bursts during positive prediction errors increase synaptic connection weights in subpopulations of Go-D1 cells that are concurrently excited by corticostriatal glutamatergic input, while also decreasing weights in NoGo-D2 cells. This enables the network to be more likely to repeat actions that are associated with positive reward prediction errors (Frank 2005), and is consistent with recent studies of synaptic plasticity showing D1-dependent LTP in striatonigral cells and D2-dependent LTD in striatopallidal cells (Shen et al 2008). Moreover, in the model, DA pauses during negative prediction errors releasing NoGo cells from the tonic inhibition of DA onto highaffinity D2 receptors.…”

Section: Models Of the Effects Of Dopamine Releasesupporting

confidence: 74%

“…The influence of dopamine on synaptic plasticity depends on numerous factors including the targeted cell type, the specific receptors activated and the brain region under consideration (Bissière et al 2003;Calabresi et al 2007;Otani et al 2003;Shen et al 2008;Wickens 2009;Yao et al 2008). Reinforcement learning results from the dynamical interaction between numerous brain networks mediating the acquisition of conditioning tasks and action selection.…”

Section: Models Of the Effects Of Dopamine Releasementioning

confidence: 99%

“…Of course, several biophysical details are omitted in these models of corticostriatal circuitry. For example, future modeling work should incorporate STDP within the context of the basal ganglia circuitry to examine the role of spike-timing, together with the roles of other neurochemicals, such as adenosine, on corticostriatal plasticity (Shen et al 2008).…”

Section: Models Of the Effects Of Dopamine Releasementioning

confidence: 99%

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Computational models of reinforcement learning: the role of dopamine as a reward signal

2010

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Reinforcement learning is ubiquitous. Unlike other forms of learning, it involves the processing of fast yet content-poor feedback information to correct assumptions about the nature of a task or of a set of stimuli. This feedback information is often delivered as generic rewards or punishments, and has little to do with the stimulus features to be learned. How can such low-content feedback lead to such an efficient learning paradigm? Through a review of existing neuro-computational models of reinforcement learning, we suggest that the efficiency of this type of learning resides in the dynamic and synergistic cooperation of brain systems that use different levels of computations. The implementation of reward signals at the synaptic, cellular, network and system levels give the organism the necessary robustness, adaptability and processing speed required for evolutionary and behavioral success.

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Section: Models Of the Effects Of Dopamine Releasesupporting

confidence: 79%

Section: Models Of the Effects Of Dopamine Releasesupporting

confidence: 74%

Section: Models Of the Effects Of Dopamine Releasementioning

confidence: 99%

Section: Models Of the Effects Of Dopamine Releasementioning

confidence: 99%

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Computational models of reinforcement learning: the role of dopamine as a reward signal

2010

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“…La stimulation de ces neurones à une basse fréquence (1 Hz, protocole de long term depression [LTD]) permet la « dépotentiali-sation » de la transmission glutamatergique sur les MSN par un mécanisme postsynaptique (réduction du nombre de AMPAR à la membrane des MSN). L'application de ce traitement abolit complètement la sensibilisation locodes MSN dépend de la stimulation de ces mêmes récepteurs [10]. La LTP est une forme de plasticité synaptique dans laquelle l'activité renforce les synapses glutamatergiques, généralement via l'insertion dans la membrane plasmique du neurone postsynaptique d'un plus grand nombre de récepteurs au glutamate (de type -amino-3-hydroxy-…”

Section: Nouvelleunclassified

Approche optogénétique de suppression de la plasticité synaptique induite par la cocaïne

Lüscher

Pascoli²

2012

Med Sci (Paris)

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Basal Ganglia and The Regulation of Movement

Turner

2009

Encyclopedia of Life Sciences

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The basal ganglia (BG) is composed of several heavily interconnected nuclei at the base of the cerebrum. A series of anatomically distinct parallel circuits through the BG receive afferent projections from and project back to cortical regions that mediate skeletomotor, oculomotor, frontal associative, and limbic functions. All circuits share a common intrinsic organization captured largely by the heuristic model of direct and indirect pathways that link BG input stations to outputs. Activation of the direct pathway may facilitate movement whereas the indirect pathway may suppress movement. Neuromodulators such as dopamine have different effects on activity and synaptic plasticity in the two pathways. Clinical disorders that involve the BG are often associated with movement disorders. Although the actual roles of the BG in the control of movement are still actively debated, growing evidence suggests it acts as a reinforcement‐driven tutor for learning automatic behavioural routines. Key concepts The BG is organized as anatomically segregated loop circuits that contribute to the control of movement, cognition and motivation. All BG circuits share a common basic organization. Input projections from cortex and thalamus terminate as excitatory synapses in the striatum and subthalamic nucleus. Output projections tonically inhibit target neurons in thalamic and brainstem nuclei. Direct and indirect pathways connect input and output nuclei of the BG. Activation of the direct pathway facilitates movement whereas activation of the indirect pathway suppresses movement. A variety of neuromodulators, such as dopamine, affect the activity of neurons in the direct and indirect pathways differently. Most BG‐related clinical conditions (e.g. Parkinson disease) arise from imbalanced activation of direct and indirect pathways and involve abnormal discharge patterns in BG output neurons. BG circuits may regulate how an animal allocates time and effort to movements and actions and act as a tutor for new skill learning.

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Dichotomous Dopaminergic Control of Striatal Synaptic Plasticity

Cited by 1,064 publications

References 30 publications

Computational models of reinforcement learning: the role of dopamine as a reward signal

Computational models of reinforcement learning: the role of dopamine as a reward signal

Approche optogénétique de suppression de la plasticité synaptique induite par la cocaïne

Basal Ganglia and The Regulation of Movement

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