Behavioral flexibility is increased by optogenetic inhibition of neurons in the nucleus accumbens shell during specific time segments

Aquili, Luca; Liu, Andrew W.; Shindou, Mayumi; Shindou, Tomomi; Wickens, Jeffery R.

doi:10.1101/lm.034199.113

Cited by 26 publications

(16 citation statements)

References 73 publications

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“…Indeed, modification of instrumental learning by optogenetic manipulation of striatal neurons was only effective in a narrow temporal window [i.e. prior to or concurrent with the onset of cue (Tai et al, 2012), or in the time segment (1.5 seconds) between action selection and outcome (Aquili et al, 2014)], supporting the temporal importance of dopamine, glutamate and neuromodulator signalling in striatum-dependent instrumental learning. Different from rapid neurotransmitter release such as dopamine and glutamate, extracellular adenosine is generated by conversion of ATP to adenosine through a set of ectonucleotidases and by bidirectional nucleotide transporters .…”

Section: Transient and "Time-locked" Activation Of Optoa 2a R Signalimentioning

confidence: 98%

Optogenetic Activation of Adenosine A2A Receptor Signaling in the Dorsomedial Striatopallidal Neurons Suppresses Goal-Directed Behavior

Chen

et al. 2015

Neuropsychopharmacol

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The striatum has an essential role in neural control of instrumental behaviors by reinforcement learning. Adenosine A(2A) receptors (A(2A)Rs) are highly enriched in the striatopallidal neurons and are implicated in instrumental behavior control. However, the temporal importance of the A(2A)R signaling in relation to the reward and specific contributions of the striatopallidal A(2A)Rs in the dorsolateral striatum (DLS) and the dorsomedial striatum (DMS) to the control of instrumental learning are not defined. Here, we addressed temporal relationship and sufficiency of transient activation of optoA(2A)R signaling precisely at the time of the reward to the control of instrumental learning, using our newly developed rhodopsin-A2AR chimeras (optoA(2A)R). We demonstrated that transient light activation of optoA(2A)R signaling in the striatopallidal neurons in 'time-locked' manner with the reward delivery (but not random optoA(2A)R activation) was sufficient to change the animal's sensitivity to outcome devaluation without affecting the acquisition or extinction phases of instrumental learning. We further demonstrated that optogenetic activation of striatopallidal A(2A)R signaling in the DMS suppressed goal-directed behaviors, as focally genetic knockdown of striatopallidal A(2A)Rs in the DMS enhanced goal-directed behavior by the devaluation test. By contrast, optogenetic activation or focal AAV-Cre-mediated knockdown of striatopallidal A(2A)R in the DLS had relatively limited effects on instrumental learning. Thus, the striatopallidal A(2A)R signaling in the DMS exerts inhibitory and predominant control of goal-directed behavior by acting precisely at the time of reward, and may represent a therapeutic target to reverse abnormal habit formation that is associated with compulsive obsessive disorder and drug addiction.

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Section: Transient and "Time-locked" Activation Of Optoa 2a R Signalimentioning

confidence: 98%

Optogenetic Activation of Adenosine A2A Receptor Signaling in the Dorsomedial Striatopallidal Neurons Suppresses Goal-Directed Behavior

Chen

et al. 2015

Neuropsychopharmacol

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“…Cognitive flexibility, often referred to as behavioural flexibility in animal studies [1], is an essential subdomain of executive function (EF) that facilitates goal-directed behavioural adaptations in response to changing circumstances [2]. The neuronal network subserving cognitive flexibility is thought to include frontostriatal circuits, specifically involving dorsolateral/medial prefrontal cortex (dlPFC/dmPFC), anterior cingulate cortex (ACC), orbitofrontal cortex (OFC), nucleus accumbens (NAC) and the dorsomedial striatum (DMS) [3][4][5][6].…”

Section: Introductionmentioning

confidence: 99%

Catecholaminergic modulation of indices of cognitive flexibility: A pharmaco-tDCS study

et al. 2019

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“…These results indicate that altering neural networks in a way that either terminates seizures as soon as they are detected (eg, RNS), or pushes epileptic networks to self‐organize into a different dynamic pattern that is less likely to generate seizures, is a viable path forward to new therapies. Consistent with the arguments for seizures, direct modification of neural circuits could also positively affect the comorbidities, given that these are also emergent behaviors of an abnormally behaving complex system …”

Section: A Network Level Definition Of Mechanismsmentioning

confidence: 71%

“…Consistent with the arguments for seizures, direct modification of neural circuits could also positively affect the comorbidities, given that these are also emergent behaviors of an abnormally behaving complex system. [38][39][40] The emphasis of treatment has been on the prevention of seizures. However, conceptualizing epilepsy in a complex systems framework opens the door to treatments that directly target comorbidities.…”

Section: Definition Of Mechanismsmentioning

confidence: 99%

WONOEP APPRAISAL: The many facets of epilepsy networks

et al. 2018

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The brain is a complex system composed of networks of interacting elements, from genes to circuits, whose function (and dysfunction) is not derivable from the superposition of individual components. Epilepsy is frequently described as a network disease, but to date, there is no standardized framework within which network concepts applicable to all levels from genes to whole brain can be used to generate deeper insights into the pathogenesis of seizures or the associated morbidities. To address this shortcoming, the Neurobiology Commission of the International League Against Epilepsy dedicated a Workshop on Neurobiology of Epilepsy (XIV WONOEP 2017) with the aim of formalizing network concepts as they apply to epilepsy and to critically discuss whether and how such concepts could augment current research endeavors. Here, we review concepts and strategies derived by considering epilepsy as a disease of different network hierarchies that range from genes to clinical phenotypes. We propose that the concept of networks is important for understanding epilepsy and is critical for developing new study designs. These approaches could ultimately facilitate the development of novel diagnostic and therapeutic strategies.

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Behavioral flexibility is increased by optogenetic inhibition of neurons in the nucleus accumbens shell during specific time segments

Cited by 26 publications

References 73 publications

Optogenetic Activation of Adenosine A2A Receptor Signaling in the Dorsomedial Striatopallidal Neurons Suppresses Goal-Directed Behavior

Optogenetic Activation of Adenosine A2A Receptor Signaling in the Dorsomedial Striatopallidal Neurons Suppresses Goal-Directed Behavior

Catecholaminergic modulation of indices of cognitive flexibility: A pharmaco-tDCS study

WONOEP APPRAISAL: The many facets of epilepsy networks

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