Striatal Local Circuitry: A New Framework for Lateral Inhibition

Burke, Dennis A; Rotstein, Horacio G.; Alvarez, Veronica A.

doi:10.1016/j.neuron.2017.09.019

Cited by 183 publications

(214 citation statements)

References 194 publications

(274 reference statements)

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“…The proposed involvement of DA in the generation of striatal neuronal assemblies (Burke, Rotstein, & Alvarez, ; Nicola, Surmeier, & Malenka, ; O'Donnell, ) became testable through calcium imaging that allows simultaneous measurement of many individual neurons (Carrillo‐Reid et al., ; Jaidar et al., ). With the use of population calcium imaging that allows the indirect measurement of neuronal spiking in striatal networks in vitro (Carrillo‐Reid et al., ; Jaidar et al., ; Lopez‐Huerta et al., ) we characterized the population activity of SPNs in slices obtained from naïve controls and mice depleted of DA for at least 9 days.…”

Section: Resultsmentioning

confidence: 99%

“…The reasons for the differences in neuronal recruitment between patterned and continuous stimulation, although interesting, are not the focus of this paper; methodological aspects perhaps involving a ChR2‐activated calcium conductance; reciprocal multisynaptic influences between direct and indirect SPNs and motor cortex (Burke et al., ; Freeze, Kravitz, Hammack, Berke, & Kreitzer, ; O'Hare et al., ; Oldenburg & Sabatini, ; Shipp, ), intrastriatal influences on SPNs (Planert, Szydlowski, Hjorth, Grillner, & Silberberg, ; Taverna, Ilijic, & Surmeier, ) and or the participation of interneurons (Damodaran, Evans, & Blackwell, ; Dehorter et al., ) should be considered in further analyses. Modulation of neuronal assemblies by specific patterns of neuronal stimulation may represent a modified animal model to study the pathogenesis in basal ganglia.…”

Section: Discussionmentioning

confidence: 99%

“…The reasons for the differences in neuronal recruitment between patterned and continuous stimulation, although interesting, are not the focus of this paper; methodological aspects perhaps involving a ChR2-activated calcium conductance; reciprocal multisynaptic influences between direct and indirect SPNs and motor cortex (Burke et al, 2017;Freeze, Kravitz, Hammack, Berke, & Kreitzer, 2013;O'Hare et al, 2016;Oldenburg & Sabatini, 2015;Shipp, 2017), intrastriatal F I G U R E 7 Analysis of network dynamics of D1 and D2 SPNs. The similarity index matrices of the stimulation induced by continuous (a) and stimulation in patterned pulses (b) show that continuous delivery of light activated sets of neurons with higher similarity index across stimulations, than stimulation delivered in patterned pulses.…”

Section: Discussionmentioning

confidence: 99%

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Synchronized activation of striatal direct and indirect pathways underlies the behavior in unilateral dopamine‐depleted mice

Jáidar

Carrillo-Reid

Nakano

et al. 2019

Eur J of Neuroscience

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For more than three decades it has been known, that striatal neurons become hyperactive after the loss of dopamine input, but the involvement of dopamine (DA) D1‐ or D2‐receptor‐expressing neurons has only been demonstrated indirectly. By recording neuronal activity using fluorescent calcium indicators in D1 or D2 eGFP‐expressing mice, we showed that following dopamine depletion, both types of striatal output neurons are involved in the large increase in neuronal activity generating a characteristic cell assembly of particular neurons that dominate the pattern. When we expressed channelrhodopsin in all the output neurons, light activation in freely moving animals, caused turning like that following dopamine loss. However, if the light stimulation was patterned in pulses the animals circled in the other direction. To explore the neuronal participation during this stimulation we infected normal mice with channelrhodopsin and calcium indicator in striatal output neurons. In slices made from these animals, continuous light stimulation for 15 s induced many cells to be active together and a particular dominant group of neurons, whereas light in patterned pulses activated fewer cells in more variable groups. These results suggest that the simultaneous activity of a large dominant group of striatal output neurons is intimately associated with parkinsonian symptoms.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

“…The reasons for the differences in neuronal recruitment between patterned and continuous stimulation, although interesting, are not the focus of this paper; methodological aspects perhaps involving a ChR2-activated calcium conductance; reciprocal multisynaptic influences between direct and indirect SPNs and motor cortex (Burke et al, 2017;Freeze, Kravitz, Hammack, Berke, & Kreitzer, 2013;O'Hare et al, 2016;Oldenburg & Sabatini, 2015;Shipp, 2017), intrastriatal F I G U R E 7 Analysis of network dynamics of D1 and D2 SPNs. The similarity index matrices of the stimulation induced by continuous (a) and stimulation in patterned pulses (b) show that continuous delivery of light activated sets of neurons with higher similarity index across stimulations, than stimulation delivered in patterned pulses.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Synchronized activation of striatal direct and indirect pathways underlies the behavior in unilateral dopamine‐depleted mice

Jáidar

Carrillo-Reid

Nakano

et al. 2019

Eur J of Neuroscience

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“…Dopamine increases the excitability of striatal THINs, which themselves act to inhibit striatal SPN's (Ibanez‐Sandoval et al., , ). This feedforward inhibition may have an important function in selecting striatal cell ensembles representing appropriate actions and inhibiting inappropriate actions (Burke, Rotstein, & Alvarez, ; Markowitz et al., ; Roux & Buzsaki, ). Alternatively, THINs may provide a similar action selection function based on their interactions with other striatal interneurons, including striatal cholinergic interneurons (English et al., ; Lee et al., ; Yamanaka et al., ).…”

Section: Discussionmentioning

confidence: 99%

Loss of striatal tyrosine‐hydroxylase interneurons impairs instrumental goal‐directed behavior

Kaminer

Espinoza

Bhimani

et al. 2019

Eur J of Neuroscience

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The striatum mediates a broad range of cognitive and motor functions. Within the striatum, recently discovered tyrosine hydroxylase expressing interneurons (THINs) provide a source of intrastriatal synaptic connectivity that is critical for regulating striatal activity, yet the role of THIN's in behavior remains unknown. Given the important role of the striatum in reward‐based behaviors, we investigated whether loss of striatal THINs would impact instrumental behavior in mice. We selectively ablated striatal THINs in TH‐Cre mice using chemogenetic techniques, and then tested THIN‐lesioned or control mice on three reward‐based striatal‐dependent instrumental tests: (a) progressive ratio test; (b) choice test following selective‐satiety induced outcome devaluation; (c) outcome reinstatement test. Both striatal‐THIN‐lesioned and control mice acquired an instrumental response for flavored food pellets, and their behavior did not differ in the progressive ratio test, suggesting intact effort to obtain rewards. However, striatal THIN lesions markedly impaired choice performance following selective‐satiety induced outcome devaluation. Unlike control mice, THIN‐lesioned mice did not adjust their choice of actions following a change in outcome value. In the outcome reinstatement test THIN‐lesioned and control mice showed response invigoration by outcome presentation, suggesting the incentive properties of outcomes were not disrupted by THIN lesions. Overall, we found that striatal THIN lesions selectively impaired goal‐directed behavior, while preserving motoric and appetitive behaviors. These findings are the first to describe a function of striatal THINs in reward‐based behavior, and further illustrate the important role for intrastriatal interneuronal connectivity in behavioral functions ascribed to the striatum more generally.

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“…Fast learning in the anterior striatum might involve dopaminergic modulation of synaptic weights among neurons receiving updates about the value of visual objects during learning [7,14]. In the striatum these neurons are spiny projection neurons (SPNs) and recent in-vivo evidence in rodent striatum supports the view that synaptic connections among SPN's are trained by inhibition from fast spiking interneurons (FSI's) [15][16][17]. According to this model cognitive flexibility is achieved through selective FSI-mediated inhibition of SPN neurons processing cortical inputs about distractors and disinhibition of SPNs processing reward predictive, relevant information [18].…”

mentioning

confidence: 99%

Cell-type Specific Learning of Attentional Gating in Primate Striatum

Boroujeni

Oemisch

Hassani

et al. 2019

Preprint

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Cognitive flexibility depends on a fast neural learning mechanism for enhancing momentary relevant over irrelevant information. A possible neural mechanism realizing this enhancement uses fast-spiking interneurons (FSIs) in the striatum to train striatal projection neurons to gate relevant and suppress distracting cortical inputs. We found support for such a mechanism in nonhuman primates during the flexible adjustment of visual attention. FSIs gated visual attention cues during feature-based learning. One FSI population showed stronger inhibition during learning, while another FSI subpopulation showed weaker inhibition after learning signifying post-learning disinhibition.Additionally, a smaller neural subpopulation increased activity when salient distractor events were successfully suppressed. These findings highlight that fast behavioral learning of feature relevance is accompanied by fast neural learning of cell-type specific corticostriatal gating.Adaptive behavior depends on neural mechanisms that learn which objects in our environment have value and are relevant to achieve our goals. Knowing the value of objects is essential to not

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Striatal Local Circuitry: A New Framework for Lateral Inhibition

Cited by 183 publications

References 194 publications

Synchronized activation of striatal direct and indirect pathways underlies the behavior in unilateral dopamine‐depleted mice

Synchronized activation of striatal direct and indirect pathways underlies the behavior in unilateral dopamine‐depleted mice

Loss of striatal tyrosine‐hydroxylase interneurons impairs instrumental goal‐directed behavior

Cell-type Specific Learning of Attentional Gating in Primate Striatum

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