Protein O-GlcNAcylation is a post-translational modification that links environmental stimuli with changes in intracellular signal pathways, and its disturbance has been found in neurodegenerative diseases and metabolic disorders. However, its role in the mesolimbic dopamine (DA) system, especially in the ventral tegmental area (VTA), needs to be elucidated. Here, we found that injection of Thiamet G, an O-GlcNAcase (OGA) inhibitor, in the VTA and nucleus accumbens (NAc) of mice, facilitated neuronal O-GlcNAcylation and decreased the operant response to sucrose as well as the latency to fall in rotarod test. Mice with DAergic neuron-specific knockout of O-GlcNAc transferase (OGT) displayed severe metabolic abnormalities and died within 4-8 weeks after birth. Furthermore, mice specifically overexpressing OGT in DAergic neurons in the VTA had learning defects in the operant response to sucrose, and impaired motor learning in the rotarod test. Instead, overexpression of OGT in GABAergic neurons in the VTA had no effect on these behaviors. These results suggest that protein O-GlcNAcylation of DAergic neurons in the VTA plays an important role in regulating the response to natural reward and motor learning in mice.
Animals ; Dopaminergic Neurons/physiology* ; GABAergic Neurons/physiology* ; Mice ; Nucleus Accumbens/metabolism* ; Reward ; Ventral Tegmental Area/metabolism*

Ventral tegmental area (VTA) is an important relay station of signal transmission in the reward system. The plasticity of VTA dopaminergic neurons directly influences actions of other regions of the reward system. Studies concerning the plasticity of VTA dopaminergic neurons focus mainly on synaptic plasticity, while much less attention has been given to the plasticity of intrinsic excitability of the neurons. The aim of the present study was to investigate the effect of high-frequency stimulation (HFS) on the plasticity of excitability of VTA neuron. Whole-cell patch-clamping was performed on VTA dopaminergic neurons in midbrain slices bathed with PTX, AP-5 and CNQX, and HFS was introduced to cell soma. The result showed that, after HFS induction the pharmacologically isolated neurons showed increased input resistance and firing frequency, as well as decreased rheobase. Meanwhile, the steady-state whole-cell current decreased, and the hyperpolarization-activated current (I(h)) decreased. These results suggest that HFS on soma induces a long-term potentiation of excitability in VTA dopaminergic neurons, and the underlying mechanism involves the changes of membrane current.
Animals ; Dopaminergic Neurons ; cytology ; Long-Term Potentiation ; Patch-Clamp Techniques ; Ventral Tegmental Area ; physiology

Parkinson's disease (PD) is a progressive neurodegenerative movement disorder characterized by severe loss of substantia nigra dopamine (DA) neurons. The target region of substantia nigra DA neurons is the dorsal striatum. According to the classic model, activation of DA receptors on striatal medium spiny neurons (MSNs) modulates their intrinsic excitability. Activation of D1 receptors makes MSNs in the direct "Go" pathway more excitable, whereas activation of D2 receptors makes MSNs in the indirect "NoGo" pathway less excitable. Therefore increased DA increases the responsiveness of the Go pathway while decreases the responsiveness of the NoGo pathway. Both mechanisms increase motor output. Conversely, diminished DA will favor the inhibitory NoGo pathway. Therefore, DA has direct, "on-line" effect on motor performance. However, in addition to modulating the intrinsic excitability of MSNs "on-line", DA also modulates corticostriatal plasticity, therefore could potentially produce cumulative and long-lasting changes in corticostriatal throughput. Studies in my lab suggest that DA blockade leads to both direct motor performance impairment and D2 receptor dependent NoGo learning ("learned" motor inhibition) that gradually deteriorates motor performance. NoGo learning is experience dependent and task specific. It is different from blocked learning since NoGo learning impairs future performance even after DA is restored. More recent data from my lab suggest that NoGo learning in the absence of DA arises from increased LTP at the indirect pathway corticostriatal synapses and contributes significantly to PD-like motor symptoms. Our data and hypotheses suggest a novel therapeutic strategy for PD that targets directly signaling molecules for corticostriatal plasticity (e.g. the cAMP pathway and downstream signaling molecules) and prevents aberrant plasticity under conditions of DA denervation.
Corpus Striatum ; cytology ; Dopamine ; physiology ; Dopaminergic Neurons ; pathology ; Humans ; Neuronal Plasticity ; Parkinson Disease ; physiopathology ; Receptors, Dopamine D1 ; physiology ; Receptors, Dopamine D2 ; physiology ; Substantia Nigra ; pathology

Animals ; Behavior, Animal ; physiology ; Dopamine ; metabolism ; Dopaminergic Neurons ; physiology ; Humans ; Mice ; Motor Activity ; physiology ; Parkinson Disease ; metabolism ; physiopathology ; Pars Compacta ; physiopathology

Burst firing of dopaminergic neurons in ventral tegmental area (VTA) induces a large transient increase in synaptic dopamine (DA) release and thus is considered the reward-related signal. But the mechanisms of burst generation of dopaminergic neuron still remain unclear. This experiment investigated the burst firing of VTA dopaminergic neurons in rat midbrain slices perfused with carbachol and L-glutamate individually or simultaneously to understand the neurotransmitter mechanism underlying burst generation. The results showed that bath application of carbachol (10 μmol/L) and pulse application of L-glutamate (3 mmol/L) both induced burst firing in dopaminergic neuron. Co-application of carbachol and L-glutamate induced burst firing in VTA dopaminergic cells which couldn't be induced to burst by the two chemicals separately. The result indicates that carbachol and L-glutamate co-regulate burst firing of dopaminergic neuron.
Action Potentials ; drug effects ; Animals ; Carbachol ; pharmacology ; Dopaminergic Neurons ; physiology ; Drug Synergism ; Female ; Glutamic Acid ; pharmacology ; Male ; Rats ; Rats, Sprague-Dawley ; Ventral Tegmental Area ; physiology

Animals ; Disease Progression ; Dopaminergic Neurons ; physiology ; Free Radical Scavengers ; blood ; Hydroxyl Radical ; antagonists & inhibitors ; Male ; Oxidopamine ; Parkinsonian Disorders ; blood ; chemically induced ; physiopathology ; Rats ; Rats, Sprague-Dawley

The thalamostriatal pathway is implicated in Parkinson's disease (PD); however, PD-related changes in the relationship between oscillatory activity in the centromedian-parafascicular complex (CM/Pf, or the Pf in rodents) and the dorsal striatum (DS) remain unclear. Therefore, we simultaneously recorded local field potentials (LFPs) in both the Pf and DS of hemiparkinsonian and control rats during epochs of rest or treadmill walking. The dopamine-lesioned rats showed increased LFP power in the beta band (12 Hz-35 Hz) in the Pf and DS during both epochs, but decreased LFP power in the delta (0.5 Hz-3 Hz) band in the Pf during rest epochs and in the DS during both epochs, compared to control rats. In addition, exaggerated low gamma (35 Hz-70 Hz) oscillations after dopamine loss were restricted to the Pf regardless of the behavioral state. Furthermore, enhanced synchronization of LFP oscillations was found between the Pf and DS after the dopamine lesion. Significant increases occurred in the mean coherence in both theta (3 Hz-7 Hz) and beta bands, and a significant increase was also noted in the phase coherence in the beta band between the Pf and DS during rest epochs. During the treadmill walking epochs, significant increases were found in both the alpha (7 Hz-12 Hz) and beta bands for two coherence measures. Collectively, dramatic changes in the relative LFP power and coherence in the thalamostriatal pathway may underlie the dysfunction of the basal ganglia-thalamocortical network circuits in PD, contributing to some of the motor and non-motor symptoms of the disease.
Animals ; Brain Waves ; physiology ; Corpus Striatum ; physiopathology ; Cortical Synchronization ; physiology ; Dopaminergic Neurons ; physiology ; Electrocorticography ; Male ; Neural Pathways ; physiopathology ; Oxidopamine ; Parkinsonian Disorders ; physiopathology ; Rats, Wistar ; Thalamic Nuclei ; physiopathology ; Walking ; physiology

In the experiment, we designed and synthesized two siRNAs based on the sequence of nuclear receptor-related factor 1 (Nurr1) mRNA. They were separately subcloned into the plasmid of pSilenCircle (pSC) containing U6 promoter. The pSC-Nurr1 vectors (pSC-N1 and pSC-N2) specific to Nurr1 gene and the negative control vector of short-hairpin RNA (shRNA) eukaryotic expression vector were constructed. We cultured the dopaminergic cell line MN9D and the verified vectors were transfected with LipofectamineTM 2000 in vitro. The positive cell clones transfected with pSC were obtained after being screened with 500 mug/ml G418. After that, the silencing effects of Nurr1 and TH mRNA or protein were detected by real time RT-PCR and Western blot. The neurite extension of MN9D cells was observed and photographed by inverted microscope. The results showed that Nurr1 mRNA expression in MN9D cells was specifically down-regulated by the vectors of pSC-N1 and pSC-N2, and the silencing effects were 62.3% and 45.6%, respectively. The dopaminergic phenotype of TH mRNA was also suppressed significantly and the silencing effects were 76.3% and 62.6%, respectively. Meanwhile, the expressions of Nurr1 and TH proteins were also significantly suppressed, and the silencing effects of Nurr1 and TH protein were 57.4%, 72.0% and 79.1%, 70.1% respectively. The negative control and liposome groups had no effect on the two genes. In conclusion, Nurr1 shRNA expressing vectors can inhibit the expressions of Nurr1 and TH mRNA or protein in MN9D cells, and Nurr1 might play a role in neurite extension of MN9D cells. Nurr1 shRNA expressing vector may provide a novel applicable strategy for the study on the function of the genes associated with Parkinson disease and the development of dopaminergic neuron.
Cell Line ; Dopaminergic Neurons ; cytology ; metabolism ; Down-Regulation ; Fetus ; Humans ; Mesencephalon ; cytology ; Neurites ; physiology ; Nuclear Receptor Subfamily 4, Group A, Member 2 ; genetics ; metabolism ; RNA, Messenger ; genetics ; metabolism ; RNA, Small Interfering ; genetics ; Transfection ; Tyrosine 3-Monooxygenase ; genetics ; metabolism