Medium Spiny Neurons Research Articles

A low-cost perfusion heating system for slice electrophysiology

AbstractTemperature-critical applications, such as patch-clamp electrophysiology, require constant perfusion at a fixed temperature. However, maintaining perfusate at a specific temperature throughout various applications requires heaters or coolers with integrated feedback systems, which has historically increased complexity and cost. This makes such systems prohibitively expensive in research environments with lower funding rates, particularly in developing countries. We developed a custom temperature control system that relies on off-the-shelf components and few custom parts, which can be easily produced with common tools. Our system can be built for less than $30 and maintains a set perfusate temperature within 0.4 °C while introducing negligible electrical interference. Using this system, we demonstrate that Striatal Medium Spiny Neurons exhibit increased membrane resistance, longer membrane time constants, lower firing rates, and increased rheobase current at room temperature compared to physiological temperature.

New MiniPromoter Ple389 (ADORA2A) drives selective expression in medium spiny neurons in mice and non-human primates.

Compact cell type-specific promoters are important tools for basic and preclinical research and clinical delivery of gene therapy. In this work, we designed novel MiniPromoters to target D1 and D2 type dopaminoceptive medium spiny neurons in the striatum by manually identifying candidate regulatory regions or employing the OnTarget webserver. We then empirically tested the designs in rAAV-PHP.B for specificity and robustness in three systems: intravenous injection in mice, intracerebroventricular injection in mice, and intracerebroventricular injection in non-human primates. Twelve MiniPromoters were designed from eight genes: seven manually and five using OnTarget. When delivered intravenously in mice, three MiniPromoters demonstrated highly selective expression in the striatum, with Ple389 (ADORA2A) showing high levels of dopamine D2-receptor cell co-localization. The same three MiniPromoters also displayed enriched expression in the striatum when delivered intracerebroventricularly in mice with high levels of DARPP32 co-localization. Finally, Ple389 (ADORA2A) was intracerebroventricularly injected in non-human primates and showed enriched expression in the striatum as in the mouse. Ple389 (ADORA2A) demonstrated expression in the medium spiny neurons in all three systems tested and exhibited the highest level of D2-MSNs and DARPP32 co-labeling in mice, demonstrating its potential as a tool for gene therapy approaches for Parkinson and Huntington disease treatment.

Pathogenic LRRK2 mutations cause loss of primary cilia and Neurturin in striatal parvalbumin interneurons.

Parkinson's disease-associated, activating mutations in the LRRK2 kinase block primary cilium formation in cell culture and in specific cell types in the brain. In the striatum that is important for movement control, about half of astrocytes and cholinergic interneurons, but not the predominant medium spiny neurons, lose their primary cilia. Here, we show that mouse and human striatal parvalbumin interneurons that are inhibitory regulators of movement also lose primary cilia. Without cilia, these neurons are not able to respond to Sonic hedgehog signals that normally induce the expression of Patched RNA, and their numbers decrease. In addition, in mouse, glial cell line-derived neurotrophic factor-related Neurturin RNA is significantly decreased. These experiments highlight the importance of parvalbumin neurons in cilium-dependent, neuroprotective signaling pathways and show that LRRK2 activation correlates with decreased Neurturin production, resulting in less neuroprotection for dopamine neurons.

The interhemispheric amygdala-accumbens circuit encodes negative valence in mice.

The structurally symmetric mammalian brain hemispheres are interconnected by commissural axons across the midline. However, the functions of interhemispheric connectivity remain largely unknown. We found that in mice, transection of the anterior commissure (AC), which connects the rostroventral forebrain, impaired avoidant behaviors. The basolateral amygdala (BLA) in the mouse projects to the contralateral nucleus accumbens (NAc) through the AC, independent of its ipsilateral projections. Aversive stimuli activated contralateral BLA-NAc projections. Positive stimuli, however, activated ipsilateral projections. Selective activation of contralateral BLA-NAc projections activated D2-positive medium spiny neurons (D2-MSNs), reduced NAc dopamine levels, and caused aversion, whereas selective activation of ipsilateral BLA-NAc projections activated D1-MSNs, increased NAc dopamine levels, and induced reward. The contralateral BLA-AC-NAc pathway is crucial for encoding negative valence, demonstrating distinct functions of intra- and interhemispheric circuits in brain physiology.

Restoring Compromised Cl- in D2 Neurons of a HD Mouse Model Rescues Motor Disability.

Huntington's disease (HD) is a progressive neurodegenerative disorder with no cure, characterized by significant neurodegeneration of striatal GABAergic medium spiny neurons (MSNs). Early stages of the disease are characterized by the loss of dopamine 2 receptor-expressing MSNs (D2 MSNs) followed by degeneration of dopamine 1 receptor-expressing MSNs (D1 MSNs), leading to aberrant basal ganglia signaling. While the early degeneration of D2 MSNs and impaired GABAergic transmission are well-documented, potassium chloride cotransporter 2 (KCC2), a key regulator of intracellular chloride (Cl-), and therefore GABAergic signaling, has not been characterized in D1 and D2 MSNs in HD. We aimed to investigate whether Cl- regulation was differentially altered in D1 and D2 MSNs and may contribute to the early degeneration of D2 MSNs in male and female symptomatic R6/2 mice. We used electrophysiology to record the reversal potential for GABAA receptors (EGABA), a read-out for the efficacy of Cl- regulation, in striatal D1 and D2 MSNs and their corresponding output structures. During the early symptomatic phase (P55-P65), Cl- impairments were observed in D2 MSNs in R6/2 mice, with no change in D1 MSNs. Cl- regulation was also dysfunctional in the globus pallidus externa, resulting in GABA-mediated excitation. When we overexpressed KCC2 in D2 MSNs using AAV-mediated delivery, we delayed the onset of motor impairments in R6/2 mice. We demonstrate that Cl- homeostasis is differentially altered in D1 and D2 MSNs and may contribute to the enhanced susceptibility of D2 MSNs during HD progression.Significance Statement Huntington's Disease is an inherited neurodegenerative disease caused by a repeat expansion in the Huntingtin gene and characterized by the sequential loss of dopamine 2 and dopamine 1 receptor-expressing medium spiny neurons (D2 and D1 MSNs) of the striatum. MSNs release GABA, which depends on proper Cl- regulation for inhibition. We asked whether Cl- homeostasis is differentially altered in D1 and D2 MSNs and their output structures, and whether this altered expression contributes to the pattern of degeneration between these two principal striatal cell types. Using electrophysiology, biochemistry, and fluorescence imaging, we determined that Cl- regulation was impaired in D2 MSNs in R6/2 mice, with no change in D1 MSNs. Cl- was also dysregulated in the globus pallidus externa resulting in excitatory GABA.

Dietary regulation of silent synapses in the dorsolateral striatum

Obesity and drugs of abuse share overlapping neural circuits and behaviors. Silent synapses are transient synapses that are important for remodeling brain circuits. They are prevalent during early development but largely disappear by adulthood. Drugs of abuse increase silent synapses during adulthood and may facilitate reorganizing brain circuits around drug-related experience, facilitating addiction and contributing to relapse during treatment and abstinence. Whether obesity causes alterations in the expression of silent synapses in a manner similar to drugs of abuse has not been examined. Using a dietary-induced obesity paradigm, mice that chronically consumed high fat diet (HFD) exhibited increased silent synapses in both direct and indirect pathway medium spiny neurons in the dorsolateral striatum. Both the time of onset of increased silent synapses and their normalization upon discontinuation of HFD occurs on an extended time scale compared to drugs of abuse. These data demonstrate that chronic consumption of HFD, like drugs of abuse, can alter mechanisms of circuit plasticity likely facilitating neural reorganization analogous to drugs of abuse.

Preclinical Evaluation of MK-8189: A Novel Phosphodiesterase 10A Inhibitor for the Treatment of Schizophrenia.

MK-8189 is a novel phosphodiesterase 10A (PDE10A) inhibitor being evaluated in clinical studies for the treatment of schizophrenia. PDE10A is a cyclic nucleotide phosphodiesterase enzyme highly expressed in medium spiny neurons of the striatum. MK-8189 exhibits sub-nanomolar potency on the PDE10A enzyme and has excellent pharmaceutical properties. Oral administration of MK-8189 significantly increased cGMP and pGluR1 in rat striatal tissues. Activation of the dopamine D1 direct and D2 indirect pathways was demonstrated by detecting significant elevation of mRNA encoding substance P (Sub P) and enkephalin (ENK) after MK-8189 administration. The PDE10A tracer [3H]MK-8193 was used determine the PDE10A enzyme occupancy (EO) required for efficacy in behavioral models. In the rat conditioned avoidance responding assay, MK-8189 significantly decreased avoidance behavior at PDE10A EO greater than ~48%. MK-8189 significantly reversed an MK-801-induced deficit in pre-pulse inhibition at PDE10A EO of ~47% and higher. Target engagement of MK-8189 in rhesus monkeys was examined with [11C]MK-8193 in PET studies and plasma concentrations of 127nM MK-8189 yielded ~50% EO in the striatum. The impact of MK-8189 on cognitive symptoms was evaluated using the objective retrieval task in rhesus monkeys. MK-8189 significantly attenuated a ketamine-induced deficit in object retrieval performance at exposure that yielded ~29% PDE10A EO. These findings demonstrate the robust impact of MK-8189 on striatal signaling and efficacy in preclinical models of symptoms associated with schizophrenia. Data from these studies were used to establish the relationship between preclinical efficacy, plasma exposures, and PDE10A EO to guide dose selection of MK-8189 in clinical studies. Significance Statement We describe the primary pharmacology of MK-8189 a PDE10A inhibitor under evaluation for the treatment of schizophrenia. We report efficacy in preclinical models that have been used to characterize other PDE10A inhibitors and atypical antipsychotics. The PDE10A occupancy achieved by MK-8189 in behavioral studies was used to support dose selection in clinical trials. This work provides evidence to support exploration of higher levels of PDE10A occupancy in clinical trials to determine if this translates to improved efficacy in patients.

Novel voltage-dependent Cl− channels in striatal medium spiny neurons are unrelated to ClC-1 or other known Ca2+-induced Cl− channel/transporter types

Intracellular chloride (Cl−) homeostasis is a critical regulator of neuronal excitability. Voltage-dependent neuronal Cl− channels remain the least understood in terms of their role as a source of Cl− entry controlling excitability. We have shown recently that striatal medium spiny neurons (MSNs) express a functional Cl− conducting ClC-1-like channel with properties similar but not identical to native ClC-1 channels (Yarotskyy, V., Lark, A.R.S., Nass S.R., Hahn, Y.K., Marone, M.G., McQuiston, A.R., Knapp, P.E., Hauser, K.F. (2022) Am. J. Physiol. Cell. Physiol. 322 (2022) C395-C409). Using a myotonic SWR/J-Clcn1adr-mto/J mouse model with a premature stop codon for the ClC-1 channel rendering it non-functional, we demonstrate that striatal MSNs isolated from wild type (wt) and homozygous mutant (adr) mouse embryos have identical voltage-dependent outwardly rectifying Cl− currents. In contrast and as expected, homozygous adr skeletal muscle flexor digitorum brevis (FDB) fibers display nominal macroscopic Cl− currents compared to heterozygous wild-type adr FDB fibers. Together, our findings demonstrate that the novel ClC-1-like channels in MSNs are unrelated to skeletal muscle-specific ClC-1 channels, and therefore represent a unique voltage-dependent neuronal Cl− channel of unknown identity.

Extracellular signal-regulated protein kinase-2 signaling in the nucleus accumbens facilitates stress-susceptibility and cocaine reinstatement.

BackgroundSecond messenger signaling within the mesolimbic reward circuit plays a key role in the negative effects of stress and the underlying mechanisms that promote drug abuse. Since the nucleus accumbens (NAc) integrates reward valence, we investigated how extracellular signal-regulated protein kinase-2 (ERK2) signaling affects the development of stress-related comorbidities, including negative affect and drug sensitivity. MethodsWe assessed how chronic unpredictable stress (CUS) influenced the phosphorylation of ERK2-signaling proteins within the NAc of male Sprague Dawley rats. Using a herpes-simplex virus, we either upregulated or downregulated NAc ERK2 activation and evaluated behavioral responses to stress-eliciting stimuli (elevated plus maze, open field, forced-swim test) and cocaine-seeking behavior (conditioned place preference, self-administration). We also examined ERK2-mediated modifications in spine morphology of medium spiny neurons (MSNs) within the NAc. ResultsCUS increased the phosphorylation of ERK2-signaling proteins within the NAc. Viral-mediated activation of NAc ERK2 enhanced susceptibility to both depression- and anxiety-related stimuli and increased cocaine-seeking behavior (conditioned place preference and reinstatement). These behavioral changes were associated with an increase in stubby and mushroom spines of NAc MSNs. Conversely, downregulation of ERK2 activation attenuated affect-related behavioral responses in the forced swim test and blunted cocaine’s rewarding effects, without influencing NAc spine morphology. ConclusionsNAc ERK2 contributes to stress-induced behavioral deficits, including anxiety- and depression-like phenotypes, while promoting cocaine-seeking behavior. These findings suggest that ERK2 signaling in the NAc plays a role in the comorbidity of these related syndromes.

Dendritome Mapping Unveils Spatial Organization of Striatal D1/D2-Neuron Morphology.

Morphology is a cardinal feature of a neuron that mediates its functions, but profiling neuronal morphologies at scale remains a formidable challenge. Here we describe a generalizable pipeline for large-scale brainwide study of dendritic morphology of genetically-defined single neurons in the mouse brain. We generated a dataset of 3,762 3D-reconstructed and reference-atlas mapped striatal D1- and D2- medium spiny neurons (MSNs). Integrative morphometric analyses reveal distinct impacts of anatomical locations and D1/D2 genetic types on MSN morphologies. To analyze striatal regional features of MSN dendrites without prior anatomical constraints, we assigned MSNs to a lattice of cubic boxes in the reference brain atlas, and summarized morphometric representation ("eigen-morph") for each box and clustered boxes with shared morphometry. This analysis reveals 6 modules with characteristic dendritic features and spanning contiguous striatal territories, each receiving distinct corticostriatal inputs. Finally, we found aging confers robust dendritic length and branching defects in MSNs, while Huntington's disease (HD) mice exhibit selective length-related defects. Together, our study demonstrates a systems-biology approach to profile dendritic morphology of genetically-defined single-neurons; and defines novel striatal D1/D2-MSN morphological territories and aging- or HD-associated pathologies.

Manipulation of radixin phosphorylation in the nucleus accumbens core modulates risky choice behavior

Ezrin-Radixin-Moesin (ERM) proteins are actin-binding proteins that contribute to morphological changes in dendritic spines. Despite their significant role in regulating spine structure, the role of ERM proteins in the nucleus accumbnes (NAcc) is not well known, especially in in the context of risk-reward decision-making. Here, we measured the relationship between synaptic excitation and inhibition (E/I ratio) from medium spiny neurons in the NAcc core obtained in the rat after a rat gambling task (rGT). Then, after surgery of a phosphomimetic pseudo-active mutant form of radixin (Rdx-T564D) in the NAcc core, we examined its role in synaptic plasticity and the accompanying risk-choice behavior in rGT. We found that basal E/I ratio in the NAcc core was higher in risk-averse rats than risk-seeking rats. However, it was significantly reduced in risk-averse rats similar to that in risk-seeking rats in the presence of Rdx-T564D in the NAcc core. Furthermore, the head sizes of spines were shifted in risk-averse rats expressing Rdx-T564D in the NAcc core, similar to those observed in risk-seeking rats. The effects of Rdx-T564D in risk-averse rats were again manifested as behavioral changes, with reduced selection of optimal choices and increased selection of disadvantageous ones. In this study, we demonstrated that manipulation of radixin phosphorylation status in the NAcc core can alter glutamatergic synaptic transmission and spine structure at this site, as well as risk choice behaviors in the rGT. These novel findings illustrate that radixin in the NAcc core plays a significant role in determining risk preference during the rGT.

Lasting effects of adolescent social instability stress on dendritic morphology in the nucleus accumbens in female and male Long Evans rats

Social instability stress (SS) in adolescence in rats leads to long-lasting changes in social behaviour and reward-related behaviour relative to control rats. Given the role of the nucleus accumbens (NAc) in such behaviours, we investigated the morphology of medium spiny neurons (MSNs), which are most neurons in the NAc, in adult female and male rats exposed to SS in adolescence. Irrespective of sex, SS rats had increased number of dendritic spines in both the core and shell regions of the NAc (2.3 % and 18.1 % increase, respectively). In the core, SS rats had a 16 % reduction in the total dendritic lengths of MSNs, whereas in the shell, SS rats had a greater dendritic length closer to the soma, and particularly in SS female rats, whereas the opposite was found farther from the soma (SS 10.6 % > CTL overall). Although the extent to which such structural changes may underlie the enduring effects of SS in adolescence requires investigation, the results add to evidence that changes to the social environment in adolescence can determine adult neuronal structural.

Cofilin linked to GluN2B subunits of NMDA receptors is required for behavioral sensitization by changing the dendritic spines of neurons in the caudate and putamen after repeated nicotine exposure

BackgroundNicotine dependence is associated with glutamatergic neurotransmission in the caudate and putamen (CPu) of the forebrain which includes alterations in the structure of dendritic spines at glutamate synapses. These changes after nicotine exposure can lead to the development of habitual behaviors such as smoking. The present study investigated the hypothesis that cofilin, an actin-binding protein that is linked to the GluN2B subunits of N-methyl-D-aspartate (NMDA) receptors regulates the morphology of dendritic spines in the neurons of the CPu after repeated exposure to nicotine.ResultsAdult male rats received subcutaneous injections of nicotine (0.3 mg/kg/day) or vehicle for seven consecutive days. DiI staining was conducted to observe changes in dendritic spine morphology. Repeated subcutaneous injections of nicotine decreased the phosphorylation of cofilin while increasing the formation of thin spines and filopodia in the dendrites of medium spiny neurons (MSN) in the CPu of rats. Bilateral intra-CPu infusion of the cofilin inhibitor, cytochalasin D (12.5 µg/µL/side), restored the thin spines and filopodia from mushroom types after repeated exposure to nicotine. Similar results were obtained from the bilateral intra-CPu infusion of the selective GluN2B subunit antagonist, Ro 25-6981 (4 µM/µL/side). Bilateral intra-CPu infusion of cytochalasin D that interferes with the actin-cofilin interaction attenuated the repeated nicotine-induced increase in locomotor sensitization in rats.ConclusionsThese findings suggest that active cofilin alters the structure of spine heads from mushroom to thin spine/filopodia by potentiating actin turnover, contributing to behavioral sensitization after nicotine exposure.

Striatal lateral inhibition regulates action selection in a mouse model of levodopa-induced dyskinesia.

Striatal medium spiny neurons (MSNs) integrate multiple external inputs to shape motor output. In addition, MSNs form local inhibitory synaptic connections with one another. The function of striatal lateral inhibition is unknown, but one possibility is in selecting an intended action while suppressing alternatives. Action selection is disrupted in several movement disorders, including levodopa-induced dyskinesia (LID), a complication of Parkinson's disease (PD) therapy characterized by involuntary movements. Here, we identify chronic changes in the strength of striatal lateral inhibitory synapses in a mouse model of PD/LID. These synapses are also modulated by acute dopamine signaling. Chemogenetic suppression of lateral inhibition originating from dopamine D2 receptor-expressing MSNs lowers the threshold to develop involuntary movements in vivo , supporting a role in motor control. By examining the role of lateral inhibition in basal ganglia function and dysfunction, we expand the framework surrounding the role of striatal microcircuitry in action selection.

Pharmacology of natural bioactive compounds used for management of Huntington diseases: An overview

Huntington's disease (HtD), an inherited genetic neurodegenerative disorder, posed threat to elderly population world-wide. HtD is caused by the repetition of cytosine-adenine-guanine (CAG) in HtD gene, which further leads to the formation of a mutant Huntington (mHtt) protein that is responsible for neuronal dysfunction and cell death. Symptoms of HtD usually begin in adulthood and progress slowly, resulting in psychiatric disturbances, motor deficits and cognitive dysfunction. The medium spiny neurons of the striatum and cortex are mainly affected in HtD. Multiple hypotheses have been proposed to elucidate the underlying mechanisms that lead to neuronal dysfunction and cell death. This typically includes molecular genetics, oxidative stress (OS), excitotoxicity, mitochondrial impairment etc. Natural bioactives are a diverse group of compounds derived from plants, animals and microorganisms. They have been found to modulate multiple signaling pathways involved in the development of HtD and have potentials in reducing OS, neuroinflammation, and neuronal death, which are key pathological processes in HtD.Mostly natural bioactive offers protection either by down-regulating the OS, excitotoxicity, mitochondrial dysfunctions, microglial inactivation, neuroinflammation and/or by upregulating ubiquitin-proteasome system, autophagy & lysosomal degradation pathway, apoptotic pathway, purinergic signaling pathway.In this chapter, we have summarized various natural bioactives that exhibit therapeutic potential against HtD. Furthermore, we have discussed the opportunities and challenges associated with the development of safe and effective natural bioactives-based therapies against HtD.

Cell type-specific epigenetic priming of gene expression in nucleus accumbens by cocaine.

A hallmark of addiction is the ability of drugs of abuse to trigger relapse after periods of prolonged abstinence. Here, we describe an epigenetic mechanism whereby chronic cocaine exposure causes lasting chromatin and downstream transcriptional modifications in the nucleus accumbens (NAc), a critical brain region controlling motivation. We link prolonged withdrawal from cocaine to the depletion of the histone variant H2A.Z, coupled with increased genome accessibility and latent priming of gene transcription, in D1 dopamine receptor-expressing medium spiny neurons (D1 MSNs) that relate to aberrant gene expression upon drug relapse. The histone chaperone ANP32E removes H2A.Z from chromatin, and we demonstrate that D1 MSN-selective Anp32e knockdown prevents cocaine-induced H2A.Z depletion and blocks cocaine's rewarding actions. By contrast, very different effects of cocaine exposure, withdrawal, and relapse were found for D2 MSNs. These findings establish histone variant exchange as an important mechanism and clinical target engaged by drugs of abuse to corrupt brain function and behavior.

Genome-wide association study meta-analysis of 9,619 cases with tic disorders

Despite the significant personal and societal burden of tic disorders (TD), treatment outcomes remain modest, necessitating a deeper understanding of their etiology. Family history is the biggest known risk factor and identifying risk genes could accelerate progress in the field. Expanding upon previous sample size limitations, we added 4,800 new TD cases and 971,560 controls, conducting a GWAS meta-analysis with 9,619 cases and 981,048 controls of European ancestry. We attempted to replicate the results in an independent deCODE Genetics GWAS (885 TD cases and 310,367 controls). To characterize GWAS findings, we conducted several post-GWAS gene-based and enrichment analyses. A genome-wide significant hit (rs79244681, p=2.27x10-08) within MCHR2-AS1 was identified, though it was not replicated. Post-GWAS analyses revealed a 13.8% SNP-heritability and three significant genes: BCL11B, NDFIP2, and RBM26. Common variant risk for TD was enriched within genes preferentially expressed in the cortico-striato-thalamo-cortical circuit (including the putamen, caudate, nucleus accumbens, and Brodman area 9) and five brain cell types (excitatory and inhibitory telencephalon-, inhibitory- di- and mesencephalon, hindbrain-, and medium spiny neurons). TD polygenic risk was enriched within loss-of-function intolerant genes (p=0.0017) and high-confidence neurodevelopmental disorder genes (p=0.0108). Of 112 genetic correlations, 43 were statistically significant, showing high positive correlations with most psychiatric disorders. Of the two SNPs previously associated with TD, one (rs2453763) replicated in an independent sub-sample of our GWAS (p=0.00018). This GWAS was still underpowered to identify high-confidence, replicable loci, but the results suggest imminent discovery of common genetic variants for TD.

The Orbitofrontal Cortex to Striatal Cholinergic Interneuron Circuit Controls Cognitive Flexibility Shaping Alcohol-Seeking Behavior

A top-down neuronal circuit from the orbitofrontal cortex (OFC) to the dorsomedial striatum (DMS) appears to be critical for cognitive flexibility. However, how OFC projections to different types of neurons in the DMS control cognitive flexibility and contribute to substance seeking and use, which are relatively inflexible behaviors, remains unclear. Mice were trained on two-bottle choice and operant alcohol self-administration procedures. The cognitive flexibility of the mice was tested through a place discrimination task. Electrophysiology and in vivo optogenetics were used to test the function of neural circuits in alcohol-seeking behavior. We depicted a connection from the OFC to striatal neurons and found that OFC afferents could elicit functional flexibility in striatal cholinergic interneurons (CINs). A mouse model of chronic alcohol consumption showed impaired cognitive flexibility and reduced burst-pause firing. The impairment of the OFC-DMS circuit resulted in a reduction in glutamatergic transmission in OFC-medium spiny neurons (MSNs) through a CIN-mediated pre-inhibition mechanism. Importantly, remodeling the OFC-DMS circuit by inducing LTP restored cognitive flexibility. Furthermore, CINs were responsible for the impact of remodeling of the OFC-DMS circuit on cognitive flexibility. This regulatory role of CINs preferentially facilitated the potentiation of glutamatergic transmission in D2 receptor-expressing medium spiny neurons (D2-MSNs) but not in D1-MSNs. Finally, activation of the OFC-CIN-D2-MSN circuit decreased alcohol-seeking behavior. Improving OFC-CIN circuit-mediated cognitive flexibility may provide a novel strategy for treating uncontrolled alcohol-seeking behavior.

DIETARY REGULATION OF SILENT SYNAPSES IN THE DORSOLATERAL STRIATUM.

Obesity and drugs of abuse share overlapping neural circuits and behaviors. Silent synapses are transient synapses that are important for remodeling brain circuits. They are prevalent during early development but largely disappear by adulthood. Drugs of abuse increase silent synapses during adulthood and may facilitate reorganizing brain circuits around drug-related experience, facilitating addiction and contributing to relapse during treatment and abstinence. Whether obesity causes alterations in the expression of silent synapses in a manner similar to drugs of abuse has not been examined. Using a dietary-induced obesity paradigm, mice that chronically consumed high fat diet (HFD) exhibited increased silent synapses in both direct and indirect pathway medium spiny neurons in the dorsolateral striatum. Both the time of onset of increased silent synapses and their normalization upon discontinuation of HFD occurs on an extended time scale compared to drugs of abuse. These data demonstrate that chronic consumption of HFD, like drugs of abuse, can alter mechanisms of circuit plasticity likely facilitating neural reorganization analogous to drugs of abuse.

Enhancer AAV toolbox for accessing and perturbing striatal cell types and circuits.

We present an enhancer AAV toolbox for accessing and perturbing striatal cell types and circuits. Best-in-class vectors were curated for accessing major striatal neuron populations including medium spiny neurons (MSNs), direct and indirect pathway MSNs, as well as Sst-Chodl, Pvalb-Pthlh, and cholinergic interneurons. Specificity was evaluated by multiple modes of molecular validation, three different routes of virus delivery, and with diverse transgene cargos. Importantly, we provide detailed information necessary to achieve reliable cell type specific labeling under different experimental contexts. We demonstrate direct pathway circuit-selective optogenetic perturbation of behavior and multiplex labeling of striatal interneuron types for targeted analysis of cellular features. Lastly, we show conserved in vivo activity for exemplary MSN enhancers in rat and macaque. This collection of striatal enhancer AAVs offers greater versatility compared to available transgenic lines and can readily be applied for cell type and circuit studies in diverse mammalian species beyond the mouse model.