Repeated administration of Sigma ligands alters the population activity of rat midbrain dopaminergic neurons

Acute and repeated administration of antipsychotic drugs produce distinctive profiles of electrophysiological effects on the population activity of midbrain dopaminergic (DA) neurons which correlate with their clinical effects. Sigma receptors have been hypothesized to be involved in psychosis and in the efficacy of antipsychotic drugs, but little is known about the effects of repeated treatment with sigma ligands on the activity of midbrain DA neuronal populations. In the present study, the cells-pertrack cell-sampling method was used to evaluate the effects of 3 sigma ligands on the numbers of spontaneously active A9 and A10 DA neurons in chloral hydrate-anesthetized rats. One-hour pretreatment with either (+)-pentazocine (10 mg/kg, i.p.), DTG (2 mg/kg, i.p.), or JO 1784 (1 or 10 mg/kg, s.c.) did not alter the number of spontaneously active DA neurons encountered per electrode track. Repeated treatment (21 daily injections) with (+)-pentazocine (1 or 10 mg/kg) or DTG (0.2 or 2 mg/kg) increased the number of A10 DA cells per track; JO 1784 (10 mg/kg but not 1 mg/kg) moderately decreased the number of active A9 DA cells and increased the firing rate of A10 DA neurons. The effect of JO 1784 on A9 DA neurons was not due to depolarization inactivation. The effects of all 3 sigma ligands differ from those of antipsychotic drugs, all of which inactivate A10 DA neurons after repeated treatment. Clinical studies are necessary to determine if selective sigma ligands will provide a novel alternative to DA antagonists in the treatment of psychosis. © 1993 Wiley-Liss, Inc.     

Nicotine and alcohol: the role of midbrain dopaminergic neurons in drug reinforcement

Nicotine and alcohol addiction are leading causes of preventable death worldwide and continue to constitute a huge socio‐economic burden. Both nicotine and alcohol perturb the brain's mesocorticolimbic system. Dopamine (DA) neurons projecting from the ventral tegmental area (VTA) to multiple downstream structures, including the nucleus accumbens, prefrontal cortex, and amygdala, are highly involved in the maintenance of healthy brain function. VTA DA neurons play a crucial role in associative learning and reinforcement. Nicotine and alcohol usurp these functions, promoting reinforcement of drug taking behaviors. In this review, we will first describe how nicotine and alcohol individually affect VTA DA neurons by examining how drug exposure alters the heterogeneous VTA microcircuit and network‐wide projections. We will also examine how coadministration or previous exposure to nicotine or alcohol may augment the reinforcing effects of the other. Additionally, this review briefly summarizes the role of VTA DA neurons in nicotine, alcohol, and their synergistic effects in reinforcement and also addresses the remaining questions related to the circuit‐function specificity of the dopaminergic system in mediating nicotine/alcohol reinforcement and comorbidity.     

Burst firing in midbrain dopaminergic neurons

Midbrain dopaminergic (DA) neurons fire bursts of activity in response to sensory stimuli, including those associated with primary reward. They are therefore conditional bursters – the bursts conveying, amongst other things, motivationally relevant information to the forebrain. In the forebrain, bursts give rise to a supra-additive release of dopamine, and possibly favour the release of co-localised neuropeptides. Evidence is presented that in rat DA neurons, bursts are engendered by the activity of cortically-regulated afferents. Certain factors are identified which, in combination, lead to burst production: (1) A burst of activity in EAAergic afferents to DA neurons arising from non-cortical sources, but controlled by the medial prefrontal cortex; (2) N-methyl-

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-aspartate receptor activation, producing a slow depolarising wave in the recipient neuron; (3) activation of a high threshold, dendritically located calcium conductance which produces a ‘plateau potential'; (4) activation of a calcium-activated potassium conductance, which terminates the burst. These factors are argued to operate in the context of an ‘optimal' level of intracellular calcium buffering for bursting. Other factors which appear to be involved in bursting in other systems, in particular a low threshold calcium conductance, are rejected as being necessary for bursting in DA neurons. The factors which do play a crucial role in burst production in DA neurons are integrated into a theory from which arises a series of hypotheses amenable to empirical investigation. Additional factors are discussed which may modulate bursting. These may either act indirectly through changes in membrane potential (or intracellular calcium concentration), or they may act directly through an interaction with certain conductances, which appear to promote or inhibit burst firing in DA neurons.     

Decreased firing frequency of midbrain dopamine neurons in mice lacking mu opioid receptors

Dopamine neurons originating in the midbrain and projecting to cortico-limbic and motor structures are one of the major neuronal substrates implicated in the reinforcing properties of drugs of abuse. The output of this system is largely determined by its impulse activity (amount and pattern of firing activity). Several intrinsic and synaptic factors can influence dopamine neuronal activity and, consequently, addiction liability. Pharmacological studies indicate that mu-opioid receptors and their activation by endogenous opioids may play an important role. In the present study, we use a genetic approach to better understand the role of mu-opioid receptors in modulating dopamine neuronal activity in vivo. Using in vivo extracellular single-unit recordings, we show that mice lacking mu-opioid receptors exhibit lower firing rates of dopamine neurons compared with their wild-type littermates. Although we observed no overall changes in bursting activity compared with wild-type mice, animals lacking mu-opioid receptors exhibited a higher proportion of regular-spiking cells that lacked bursting activity. These findings are the first to emphasize the critical role of mu-opioid receptors in modulating action potential output of dopamine neurons in vivo using a genetic approach. They also provide a possible underlying mechanism for the decreased reinforcing properties of drugs of abuse that was previously observed in mice lacking mu-opioid receptors.     

Glutamatergic inputs to midbrain dopaminergic neurons in primates

Anterograde tract-tracing and immunohistochemical methods were used to study projections from the pedunculopontine tegmental nucleus (PPN) to midbrain dopaminergic neurons in the squirrel monkey (Saimiri sciureus). The PPN harbored numerous cholinergic and glutamatergic neurons, as well as neurons that displayed both cholinergic and glutamatergic markers. Injections of anterograde tracer into the PPN led to intense fiber labeling in the substantia nigra pars compacta (SNc) and the ventral tegmental area (VTA). This pedunculonigral projection was partly bilateral. At the electron microscopic level, about 40–60% of the anterogradely labeled terminal boutons were glutamate-positive and formed asymmetric synapses with the dopaminergic neurons of the SNc–VTA complex. These data provide direct evidence for a pedunculonigral glutamatergic projection. This projection may play a crucial role in the control of the firing pattern of SNc–VTA dopaminergic neurons and could be involved in glutamate-mediated excitotoxicity that is believed to lead to SNc cell death in Parkinson's disease.     

Glutamate receptor stimulation induces a persistent rhythmicity of the GABAergic inputs to rat midbrain dopaminergic neurons

The substantia nigra pars compacta and the ventral tegmental area are part of a complex network in the basal ganglia involved in behaviours as diverse as motor planning, generation of pleasure and drug addiction. Here we report that in the dopaminergic neurons of the rat ventral midbrain a brief coactivation of group I metabotropic and NMDA glutamate receptors may transform a temporally dispersed synaptic GABAergic input into a rhythmic pattern (range 4.5-22.5 Hz), probably through a mechanism involving electrotonic couplings. The plastic and long-lasting modification in the temporal code of the inhibitory synaptic activity induced by glutamate may be a key element in determining the function of midbrain dopaminergic neurons in both normal and pathological behaviour.     

Adolescent exposure to cannabinoids induces long-lasting changes in the response to drugs of abuse of rat midbrain dopamine neurons.

BACKGROUND: Recent studies have raised concerns about subtle long-lasting neurobiological changes that might be triggered by exposure to Cannabis derivatives, especially in a critical phase of brain maturation, such as puberty. The mesolimbic dopamine (DA) system, involved in the processing of drug-induced reward, is a locus of action of cannabinoids and endocannabinoids. Thus, we compared the effects of repeated cannabinoid administration in adolescent and adult rats on DA neuronal functions and responses to drugs of abuse. METHODS: Single-unit extracellular recordings from antidromically identified mesoaccumbens DA neurons and from their target cells in the nucleus accumbens were carried out in urethane-anesthetized rats. Animals were pretreated during adolescence or adulthood, for 3 days, with the cannabinoid agonist WIN55212.2 (WIN) or vehicle and allowed a 2-week interval. RESULTS: In cannabinoid-administered rats, DA neurons were significantly less responsive to the stimulating action of WIN, regardless of the age of pretreatment; however, in the adolescent group, but not in the adult, long-lasting cross-tolerance developed to morphine, cocaine, and amphetamine. CONCLUSIONS: Our study suggests that an enduring form of neuronal adaptation occurs in DA neurons after subchronic cannabinoid intake at a young age, affecting subsequent responses to drugs of abuse.     

中脑多巴胺能神经元发育分化的基因调控机制

中脑多巴胺能神经系统由于涉及帕金森病、精神分裂症、药物成瘾等多种严重神经精神障碍的病理过程而受到重视。多巴胺神经元的发育是一包括多种转录因子和生长因子参与的严格控制过程。在胚胎发育早期，是由控制中脑发育的多种同源域蛋白调控多巴胺前体细胞的增殖和迁移；在特异性转录因子Nurrl和Ptx3表达后，多巴胺神经元开始表达特定的表型并合成DA；最终在与纹状体靶细胞的正确联系建立的前提下分化成熟；同时这一过程要受到来自周围细胞信号的相互影响。     

中脑多巴胺能神经元发育分化的基因调控机制

中脑多巴胺能神经系统由于涉及帕金森病、精神分裂症、药物成瘾等多种严重神经精神障碍的病理过程而受到重视.多巴胺神经元的发育是一包括多种转录因子和生长因子参与的严格控制过程.在胚胎发育早期,是由控制中脑发育的多种同源域蛋白调控多巴胺前体细胞的增殖和迁移;在特异性转录因子Nurr1和Ptx3表达后,多巴胺神经元开始表达特定的表型并合成DA;最终在与纹状体靶细胞的正确联系建立的前提下分化成熟;同时这一过程要受到来自周围细胞信号的相互影响.     

Neuroimmunophilin ligands exert neuroregeneration and neuroprotection in midbrain dopaminergic neurons

Immunosuppressant drugs, like FK506, and nonimmunosuppressant compounds like, GPI1046 and L685818, are immunophilin ligands that specifically bind to immunophilins, like FK506 binding protein 12 (FKBP12). Several lines of evidence show that these ligands exert neurotrophic properties in neural injury models and in PC12 cells. However, the mechanism of the neurotrophic function of the immunophilin ligands is poorly known. In the present study, we use MPP+ and 6-OHDA toxicity models to examine both neuroprotective and neuroregenerative effects of immunophilin ligands on primary cultures of midbrain dopaminergic neurons. We find that FK506, GPI1046 and L685818 at concentrations from 0.01 to 1 microM partially, but significantly, protect dopaminergic neurons against both MPP+ and 6-OHDA toxicity. By Western blot analysis, we also find that all three compounds prevent tyrosine hydroxylase (TH) loss induced by MPP+ and 6-OHDA treatments. Morphologic analysis of dopaminergic neurons, by immunocytochemistry, shows that MPP+ and 6-OHDA cause the retraction and loss of neuronal processes, while FK506, GPI1046 and L685818 promote regeneration of these processes as indicated by increases in process number and length. To examine if FKBP12 is required for neurotrophic effects of immunophilin ligands, we cultured dopaminergic neurons from FKBP12 knockout mice and find that FK506 still protects dopaminergic neurons against MPP+ toxicity. These results suggest that FKBP12 is not essential for the neurotrophic properties of immunophilin ligands, and immunophilin ligands are a new class of neuroprotective and neuroregenerative agents that may have therapeutic potential in a variety of neurological disorders.     

Actions of methylphenidate on dopaminergic neurons of the ventral midbrain.

BACKGROUND: Methylphenidate has been suggested to exert its therapeutic effect mainly by blocking the dopamine transporter. In spite of the importance of this interaction, no detailed information is available yet on its actions on single dopaminergic neurons. METHODS: We examined the effects of methylphenidate on dopaminergic neurons using electrophysiological recordings from rat midbrain slices. RESULTS: Methylphenidate inhibited spontaneous firing and caused a membrane hyperpolarization in current clamp or an outward current in voltage clamp. These effects were antagonized by the D(2) receptor antagonist sulpiride. An acute dopamine-depleting treatment of the slices with the dopa-decarboxylase inhibitor carbidopa significantly reduced the effects of methylphenidate. This drug potentiated, in a concentration-dependent manner, cellular responses to exogenous dopamine application. CONCLUSIONS: Our electrophysiological data are consistent with the hypothesis that methylphenidate inhibits dopamine transporter and suggest that the depression of firing is mediated by the release of newly synthesized dopamine which accumulates extracellularly due to inhibition of its reuptake.     

Stress increases MHC-I expression in dopaminergic neurons and induces autoimmune activation in Parkinson's disease

The expression of major histocompatibility complex class I (MHC-I), a key antigen-presenting protein, can be induced in dopaminergic neurons in the substantia nigra, thus indicating its possible involvement in the occurrence and development of Parkinson''s disease. However, it remains unclear whether oxidative stress induces Parkinson''s disease through the MHC-I pathway. In the present study, polymerase chain reaction and western blot assays were used to determine the expression of MHC-I in 1-methyl-4-phenylpyridinium (MPP⁺)-treated SH-SY5Y cells and a 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-induced Parkinson''s disease mouse model. The findings revealed that MHC-I was expressed in both models. To detect whether the expression of MHC-I was able to trigger the infiltration of cytotoxic T cells, immunofluorescence staining was used to detect cytotoxic cluster of differentiation 8 (CD8)⁺ T cell infiltration in the substantia nigra of MPTP-treated mice. The results indicated that the presentation of MHC-I in dopaminergic neurons was indeed accompanied by an increase in the number of CD8⁺ T cells. Moreover, in MPTP-induced Parkinson''s disease model mice, the genetic knockdown of endogenous MHC-I, which was caused by injecting specific adenovirus into the substantia nigra, led to a significant reduction in CD8⁺ T cell infiltration and alleviated dopaminergic neuronal death. To further investigate the molecular mechanisms of oxidative stress-induced MHC-I presentation, the expression of PTEN-induced kinase 1 (PINK1) was silenced in MPP⁺-treated SH-SY5Y cells using specific small interfering RNA (siRNA), and there was more presentation of MHC-I in these cells compared with control siRNA-treated cells. Taken together, MPP⁺-/MPTP-induced oxidative stress can trigger MHC-I presentation and autoimmune activation, thus rendering dopaminergic neurons susceptible to immune cells and degeneration. This may be one of the mechanisms of oxidative stress-induced Parkinson''s disease, and implies the potential neuroprotective role of PINK1 in oxidative stress-induced MHC-I presentation. All animal experiments were approved by the Southern Medical University Ethics Committee (No. 81802040, approved on February 25, 2018).

Chinese Library Classification No. R459.9; R363; R364     

Changing responsiveness of developing midbrain dopaminergic neurons for extracellular growth factors

Numerous purified growth factors as well as yet-unidentified neurotrophic activities within mesencephalic glia support the survival of dopaminergic neurons. To further characterize the functional role of these multiple growth factor influences in dopaminergic cell development, various purified growth factors as well as mesencephalic glial-conditioned medium (CM) were screened for effects on dopaminergic cell survival and glial numbers in serum-free low density cultures of the dissociated embryonic day (E) 15 and E17 rat mesencephalon. In E15 mesencephalic cultures, dopaminergic cell survival increased with brain-derived neurotrophic factor (BDNF), glial cell line-derived neurotrophic factor (GDNF), basic fibroblast growth factor (bFGF), transforming growth factor α (TGFα), insulin-like growth factor-1 (IGF-1), platelet-derived growth factor-BB (PDGF-BB), and interleukin-6 (IL-6). bFGF, TGFα, PDGF, and IL-6 also stimulated glial proliferation as demonstrated by autoradiographic labeling for ³H-thymidine. Moreover, CM derived from the mesencephalic glial cell line Mes42 completely prevented the death of E15 dopaminergic neurons within the initial days of cultivation. In E17 mesencephalic cultures, survival-promoting effects on dopaminergic neurons were present with BDNF, GDNF, and bFGF. TGFα, IGF-1, PDGF-BB, and IL-6 stimulated glial proliferation but did not affect dopaminergic cell survival. Similarly, mesencephalic glial-CM completely failed to support the survival of E17 dopaminergic neurons. These observations demonstrate that during embryonic development, dopaminergic cell survival sequentially depends on distinct sets of growth factors. The concomitant loss of sensitivity of developing dopaminergic neurons for mesencephalic glial-CM as well as TGFα, IGF-1, PDGF-BB, and IL-6 further provides evidence that these growth factors indirectly affect early dopaminergic neurons through glial-mediated processes and suggests a crucial role of glia during the initial stages of neuronal development. J. Neurosci. Res. 51:508–516, 1998. © 1998 Wiley-Liss, Inc.     

Electrophysiologic changes in ventral midbrain dopaminergic neurons resulting from (+/-) -3,4-methylenedioxymethamphetamine (MDMA-"Ecstasy").

BACKGROUND: Although dopamine (DA) has been implicated in the psychostimulant properties of 3,4-methylenedioxymethamphetamine (MDMA), there is no detailed information on its modalities of action on single ventral midbrain dopaminergic neurons. METHODS: We examined the actions of MDMA on intracellularly recorded dopaminergic neurons maintained in slices. RESULTS: At 1 micromol/L, MDMA depolarized and excited the cells; at 3 micromol/L, either excited or inhibited the neurons. Interestingly, higher concentrations (10-30 micromol/L) inhibited firing through membrane hyperpolarization or caused an outward current. Whereas MDMA's excitatory effects were antagonized by pindolol, indicating involvement of 5-HT 1B receptors, the inhibitory effects were counteracted by sulpiride indicating involvement D2 receptors. Treatment of the cells with carbidopa eliminated MDMA-induced firing inhibition and membrane hyperpolarization. MDMA enhanced DA-induced cellular responses but reduced those of amphetamine. Cocaine-induced outward currents were not affected by MDMA. These actions are consistent with inhibition of the DA transporter. Moreover, MDMA depressed the GABA(B) IPSP by activating 5-HT 1B receptors. CONCLUSIONS: Our data demonstrate that 3-30 micromol/L MDMA preferentially inhibits the dopaminergic cells via indirect activation of D2 autoreceptors due to increased extracellular concentration of DA. In contrast, reduction of the GABA(B) IPSP could partially account for excitation caused by 1-3 micromol/L drug.     

Angiotensin II protects cultured midbrain dopaminergic neurons against rotenone-induced cell death

In humans, EEG power in the theta frequency band (5-8 Hz) during quiet waking increases during sleep deprivation (SD), and predicts the subsequent homeostatic increase of sleep slow-wave activity (SWA; EEG power between 0.5 and 4.0 Hz). These findings indicate that theta power in waking is an EEG variable, which reflects the rise in sleep propensity. In rodents, a number of short sleep attempts, as well as SWA in the waking EEG increase in the course of SD, but neither variable predicts the subsequent homeostatic increase of EEG SWA during recovery sleep. To investigate whether there is an EEG marker for sleep propensity also in rodents, the EEG of the rat was recorded during 6 h SD in the first half of the light period (SDL, n = 7). During SDL, power of the waking EEG showed an increase in the delta (1.5-4 Hz) and low theta (5-6.5 Hz) band. Based on the neck muscle EMG, wakefulness was subdivided into active (high EMG activity) and quiet (low EMG activity) waking. During quiet waking, the theta peak occurred at 5.5 Hz, the frequency at which the increase of EEG power during SD was most pronounced. This increase was due to higher amplitude of theta waves, while wave incidence (frequency) was unchanged. Correlation analysis showed that the rise in EEG power in the 5-7 Hz band during SD predicted the subsequent enhancement of SWA in non-rapid eye movement sleep. The analysis of data of a further batch of rats which were sleep deprived for 6 h after dark onset (SDD, n = 7) revealed a significant increase in theta-wave amplitude during the SD and a tendency for a similar, positive correlation between the increase of theta power (5-7 Hz) and subsequent SWA. The results indicate that in rats, as in humans, a specific waking EEG frequency, i.e., theta power in quiet waking is a marker of sleep propensity.     

Diet and chronic haloperidol effects on rat midbrain dopamine neurons

The effects of dietary glucose (chow containing 0%, 10%, 20%, or 40% glucose, w/w) on chronic haloperidol-induced changes in dopamine (DA) neuronal activity were tested. Rats were treated daily by oral gavage for 21 days with either water or 0.5 mg/kg haloperidol, then anesthetized for in vivo electrophysiological recording. The numbers of spontaneously active DA neurons in the substantia nigra (A9) and ventral tegmental area (A10) regions of the midbrain were estimated with the cells-per-track sampling method. In rats fed standard chow, haloperidol significantly reduced the number of active neurons in both regions compared to water controls. In water controls there were no differences in DA cells per track between rats fed standard chow or chow containing 10% or 20% glucose, whereas these glucose diets significantly attenuated the effects of chronic haloperidol on DA cells per track. The 40% glucose diet itself nonsignificantly reduced cells per track and, in turn, nonsignificantly attenuated the effects of haloperidol. The results demonstrate that dietary glucose content can alter haloperidol-induced changes in the activity of midbrain DA neurons.     

Differentiated dopaminergic MN9D cells only partially recapitulate the electrophysiological properties of midbrain dopaminergic neurons

The cell line MN9D, a fusion of embryonic ventral mesencephalic and neuroblastoma cells, is extensively used as a model of dopamine (DA) neurons because it expresses tyrosine hydroxylase and synthesizes and releases DA. These cells are also used to test mechanisms and potential therapeutics relevant to the loss of DA neurons in Parkinson's disease. To date, little work has been done to determine whether MN9D cells electrophysiologically resemble mature DA neurons. We examined sodium, calcium and potassium currents in undifferentiated and differentiated MN9D cells, and compared these to those found in acutely dissociated mouse substantia nigra pars compacta DA neurons. It was observed that undifferentiated MN9D cells bore no resemblance to DA neurons. Upon differentiation with butyric acid with or without a prior treatment with glial cell line-derived neurotrophic factor, differentiated MN9D cells produce an electrophysiological profile that more closely resembles substantia nigra pars compacta DA neurons even though the A-type potassium current remains noticeably absent. These observations demonstrate that undifferentiated MN9D cells are not reasonable models of DA neurons. Although differentiated MN9D cells are closer to the mature DA neuronal phenotype, they do not fully mimic DA neurons and are likely to be of questionable value as a model because of their substantive differences, including the lack of the characteristic A-type potassium current. The future use of one or a combination of growth or other factors to differentiate MN9D cells may yield a more useful model system for Parkinson's disease studies in vitro.     

SK channels control the firing pattern of midbrain dopaminergic neurons in vivo

A vast body of experimental in vitro work and modelling studies suggests that the firing pattern and/or rate of a majority of midbrain dopaminergic neurons may be controlled in part by Ca2+-activated K+ channels of the SK type. However, due to the lack of suitable tools, in vivo evidence is lacking. We have taken advantage of the development of the water-soluble, medium potency SK blocker N-methyl-laudanosine (CH3-L) to test this hypothesis in anaesthetized rats. In the lateral ventral tegmental area, CH3-L iontophoresis onto dopaminergic neurons significantly increased the coefficient of variation of their interspike intervals and the percentage of spikes generated in bursts as compared to the control condition. The effect of CH3-L persisted in the presence of a specific GABA(A) antagonist, suggesting a direct effect. It was robust and reversible, and was also observed in the substantia nigra. Control experiments demonstrated that the effect of CH3-L could be entirely ascribed to its blockade of SK channels. On the other hand, the firing pattern of noradrenergic neurons was much less affected by CH3-L. We provide here the first demonstration of a major role of SK channels in the control of the switch between tonic and burst firing of dopaminergic neurons in physiological conditions. This study also suggests a new strategy to develop modulators of the dopaminergic (DA) system, which could be of interest in the treatment of Parkinson's disease, and perhaps other diseases in which DA pathways are dysfunctional.