Edward D. French

II. Excitotoxic models for neurodegenerative disorders

Abstract In recent years, considerable interest has been shown in the neurotoxic properties of excitatory amino acids and their possible relevance for the study of human neurodegenerative disorders. The term “excitotoxin” has been coined for a family of acidic amino acids which are neuroexcitants and produce a characteristic type of “axon-sparing” neuronal lesion. Intracerebral infusions of kainic and ibotenic acids, the two most commonly used excitotoxins, result in a morphological and biochemical picture in experimental animals which resembles that observed in the brains of Huntingtons disease and epilepsy victims. The emergence of such animal models for neurodegenerative disorders has led to the hypothesis that endogenous excitotoxins may exist which are linked to the pathogenesis of human diseases. The most promising candidate discovered so far is quinolinic acid, a hepatic tryptophan metabolite which has recently also been found to occur in brain tissue. The particular excitotoxic properties of quinolinic acid warrant a thorough investigation of its metabolic and synaptic disposition in normal and abnormal brain function. While little is known about the mechanisms by which excitotoxins cause selective neuronal death, most current speculations propose the participation of specific synaptic receptors for acidic amino acids. The recent development of selective antagonists of such receptors has aided in the elucidation of excitotoxic mechanisms. Although a biochemical link between endogenous excitotoxins and human neurodegenerative disorders remains elusive at present, pharmacological blockade of excitotoxicity may constitute a novel therapeutic strategy for the treatment of these disease states.

Cannabinoids excite dopamine neurons in the ventral tegmentum and substantia nigra

EXTRACELLULAR recordings were used to determine the effects of cannabinoids on the activity of dopamine neurons within the ventral tegmental area (VTA) and substantia nigra pars compacta (SNC). Systemic administration of the natural psychoactive cannabinoid Δ9-tetrahydrocannabinol (Δ9-THC) and the synthetic cannabimimetic aminoalkylindole WIN 55,212-2 produced dose-dependent increases in firing rate and burst firing in both neuronal populations. These effects appear to be specific as the non-psychoactive cannabidiol and the inactive enantiomer WIN 55,212-3 failed to alter either parameter of neuronal excitability. Furthermore, dopamine neurons in the VTA were more sensitive than those in the SNC to the stimulatory actions of Δ9-THC. These results may provide a mechanism by which psychoactive cannabinoids increase extracellular dopa-mine levels in mesolimbic and striatal tissues, and thereby contribute to the reinforcing effects of marijuana.

Δ9-Tetrahydrocannabinol excites rat VTA dopamine neurons through activation of cannabinoid CB1 but not opioid receptors

Behavioral, biochemical and recent electrophysiological data have increasingly implicated the involvement of dopamine in the central actions of cannabinoid compounds. However, the site and mechanism by which cannabinoids stimulate dopamine systems has been somewhat controversial. Central opioid systems have also been suggested to play a role in some cannabinoid-induced behaviors as evidenced by their attenuation in the presence of the opioid antagonist naloxone. However, recent studies using the cannabinoid receptor-selective antagonist SR141716A suggest that the central actions of psychoactive cannabinoids are mediated principally through activation of CB1 receptors. Using single cell electrophysiological recordings in the rat we assessed the effects of both SR141716A and naloxone on delta9-tetrahydrocannabinol (THC)-induced activation of ventral tegmental dopamine neurons. While dopamine cell firing was dose-dependently increased following cumulative dosing with delta9-THC it was partially or completely inhibited following pretreatment with 0.5 and 2 mg/kg SR141716A, respectively. However, 1 and 10 mg/kg naloxone failed to alter the response to delta9-THC. These data provide the first evidence that delta9-THC-induced changes in mesolimbic dopamine neuronal activity are mediated by the CB1 cannabinoid receptor, but a causal link for the involvement of opioid systems could not be established.

Non-competitive N-methyl-d-aspartate antagonists are potent activators of ventral tegmental A10 dopamine neurons

The response of ventral tegmental (VTA) A10 dopamine neurons to a series of compounds covering the spectrum from high-affinity phencyclidine receptor ligands (MK-801, PCP) to high-affinity sigma-receptor ligands [+)-pentazocine, DTG) was measured using single-unit extracellular recording techniques in the rat. Dose-response comparisons revealed that MK-801 was 3, 6, 19 and 119 times more potent at activating A10 neurons than PCP, (+)-SKF-10,047, ketamine and (+)-pentazocine, respectively. DTG (1,3-di-o-tolylguanidine), the most selective sigma-ligand, and U50,488H, a kappa-opiate, failed to produce any stimulation of firing. Also, pretreatment with haloperidol, a potent sigma-receptor ligand, did not prevent MK-801-induced excitations. Thus, the activation of the A10-mesolimbic-mesocortical dopamine pathways by PCP, PCP-like drugs and sigma-psychotomimetics is mediated by the PCP receptor, not the haloperidol-sensitive sigma-receptor, with potencies directly correlated to their activity as non-competitive N-methyl-D-aspartate (NMDA) antagonists.

Activation of the A10 mesolimbic system by the σ-receptor agonist (+)SKF 10,047 can be blocked by rimcazole, a novel putative antipsychotic

This study evaluated with electrophysiological and behavioral techniques the ability of rimcazole, a novel putative antipsychotic and selective sigma-receptor ligand, to antagonize the stimulation of the mesocorticolimbic dopamine system by the sigma-agonist, (+)SKF 10,047. Rimcazole effectively blocked the (+)SKF 10,047-induced excitation of ventral tegmental dopamine neurons while having no effect on either spontaneous activity or apomorphine-elicited slowing of A10 firing. Rimcazole also antagonized the behavioral hyperactivity produced by (+)SKF 10,047, but not by d-amphetamine which is also mediated through the same mesolimbic dopamine pathway. These data provide further evidence that rimcazoles novel pharmacologic profile may involve a blockade of sigma-receptors on mesocorticolimbic dopamine neurons.

The Abused Inhalant Toluene Increases Dopamine Release in the Nucleus Accumbens by Directly Stimulating Ventral Tegmental Area Neurons

Recreational abuse of toluene-containing volatile inhalants by adolescents is a significant public health problem. The mechanisms underlying the abuse potential of such substances remain unclear, but could involve increased activity in mesoaccumbal dopamine (DA) afferents innervating the nucleus accumbens (ACB). Here, using in vitro electrophysiology, we show that application of behaviorally relevant concentrations of toluene directly stimulates DA neurons in the ventral tegmental area (VTA), but not surrounding midbrain regions. Toluene stimulation of VTA neurons persists when synaptic transmission is reduced. Moreover, unlike non-DA neurons, the magnitude of VTA DA neuron firing does not decline during longer exposures designed to emulate ‘huffing’. Using dual-probe in vivo microdialysis, we show that perfusion of toluene directly into the VTA increases DA concentrations in the VTA (somatodendritic release) and its terminal projection site, the ACB. These results provide the first demonstration that even brief exposure to toluene increases action potential drive onto mesoaccumbal VTA DA neurons, thereby enhancing DA release in the ACB. The finding that toluene stimulates mesoaccumbal neurotransmission by activating VTA DA neurons directly (independently of transynaptic inputs) provide insights into the neural substrates that may contribute to the initiation and pathophysiology of toluene abuse.

A comparison of the effects of nicotine on dopamine and non-dopamine neurons in the rat ventral tegmental area: an in vitro electrophysiological study

Increased neurotransmission within the mesolimbic dopamine system is considered an essential component for the rewarding and dependence producing properties of nicotine. Nicotinic acetylcholine receptors on dopamine containing neurons in the ventral tegmental area are thought to be a prime target for nicotines stimulatory effects. However, there is no evidence regarding the actions of nicotine on ventral tegmental GABAergic interneurons which play an important modulatory role in mesolimbic dopamine neuronal excitability. In the present study we sought to characterize the effects of nicotine on the activity of both dopamine and non-dopamine neurons in the juvenile rat ventral tegmentum. Extracellular recording techniques in rat brain slices and two methods of drug perfusion were used. Nicotine was found to markedly increase the firing rate of both groups, although the dopamine neuronal response pattern was considerably different and more vigorous than that in the non-dopamine neurons. The nicotine-induced excitations were also reversed by mecamylamine. Furthermore, desensitization to nicotines stimulatory effects occurred in both neuronal populations, although non-dopamine neurons appeared to desensitize to a greater degree. In fact, the desensitization accompanying sequential uninterrupted applications of nicotine appears to occur at concentrations below that described to produce receptor activation. The low nM concentrations of nicotine used in the present study are comparable to plasma levels of nicotine found after smoking a cigarette or even with passive inhalation of tobacco smoke. Thus, the present results not only confirm that nicotine stimulates the firing rate of ventral tegmental area dopamine neurons, but also that GABAergic neurons may be an important target for nicotines central nervous system effects. The less robust response in the non-dopamine presumptive GABAergic population and their more pronounced desensitization could lead to disinhibition of dopamine neurons thereby facilitating a more sustained increase in the response of mesolimbic dopamine neurons to nicotine.

N-methyl-d-aspartic acid biphasically regulates the biochemical and electrophysiological response of A10 dopamine neurons in the ventral tegmental area: in vivo microdialysis and in vitro electrophysiological studies

The effects of local perfusion of the ventral tegmental area (VTA) with N-methyl-D-aspartic acid (NMDA) on extracellular dopamine concentrations in the nucleus accumbens were investigated by using in vivo microdialysis in halothane anaesthetized rats. The electrophysiological response of VTA dopamine neurons to NMDA were also assessed in an in vitro rat brain slice preparation. In both preparations NMDA elicited a biphasic response. Exposure of the VTA to low doses of NMDA (< 100 microM) elicited increases in dialysate dopamine levels in the nucleus accumbens and increases in the firing rate of VTA dopamine neurons. Larger doses (> 100 microM) resulted in profound reductions in both dopamine release in the accumbens and firing in the VTA. A strong correlation between the ability of NMDA to influence dopamine release in the accumbens and the firing rate in the VTA was observed. Perfusion with the non-competitive NMDA receptor antagonist PCP eliminated the NMDA-induced increases in extracellular dopamine in the accumbens. These data suggest that dopamine release in the accumbens and the firing rate of dopamine neurons can be both increased or decreased depending upon the magnitude of glutamatergic stimulation within the VTA.

Phencyclidine-induced locomotor activity in the rat is blocked by 6-hydroxydopamine lesion of the nucleus accumbens: Comparisons to other psychomotor stimulants

The present study was primarily designed to explore the relationship between phencyclidine(PCP)-induced hyperactivity and the mesolimbic dopamine (DA) system. In addition, the motor-activating and behavioral effects of amphetamine (1.5 mg/kg), SKF-10,047 (25.0 mg/kg), scopolamine (1.0 mg/kg), and caffeine (10.0 mg/kg) were also measured and compared to PCP action. While all compounds produced a moderate to large degree of hyperactivity with varying time courses for effect, gross behavioral observations indicated a greater similarity between PCP and SKF-10,047 than between any of the other drugs. Following bilateral 6-hydroxydopamine lesions of the nucleus accumbens the robust locomotor-stimulating action of 5 mg/kg PCP was significantly reduced. Such lesions also successfully prevented amphetamine- and SKF-10,047-induced hyperactivity, but not the behavioral activation produced by scopolamine or caffeine. These results suggest that PCP and SKF-10,047, like amphetamine, elicit locomotor activity through presynaptic DA mechanisms within the mesolimbic system.

Acute toluene induces biphasic changes in rat spontaneous locomotor activity which are blocked by remoxipride

The behavioral hyperactivity elicited by most drugs of abuse has been linked to changes in mesolimbic dopamine neurotransmission. However, the locomotor stimulant effects of toluene, a constituent in many abused inhalants, has not been clearly associated with this site of action. The present study was designed to examine the hypothesis that toluene-induced hyperactivity is also dependent upon intact dopamine neurotransmission. Using photocell-equipped cages, 600-1200 mg/kg toluene produced an inverted U-shaped dose response. However, in the presence of 5 mg/kg remoxipride, a selective D2-dopamine antagonist toluene-induced hyperactivity was reduced by 57%. The effects of remoxipride appear to be selective as a pretreatment, as it did not reduce either spontaneous locomotor activity or the stimulatory effects of the muscarinic antagonist scopolamine. These results clearly show that toluene induces locomotor hyperactivity through a dopamine-dependent mechanism. Because the mesolimbic dopamine system has been shown to play a role in the rewarding properties of drugs of abuse, its activation by toluene may also underlie the abuse potential of this and other inhalants.