Regional distribution and effects of postmortal delay on endocannabinoid content of the human brain.

Tissue levels of anandamide (AEA) and 2-arachidonoylglycerol (2-AG) have been determined in 16 regions and nuclei from human brains, using liquid chromatography/in-line mass spectrometry. Measurements in brain samples stored at -80 degrees C for 2 months to 13 years indicated that endocannabinoids were stable under such conditions. In contrast, the postmortal delay had a strong effect on brain endocannabinoid levels, as documented in brain samples microdissected and frozen 1-6 h postmortem, and in neurosurgical samples 0, 5, 30, 60, 180 and 360 min after their removal from the brain. The tissue levels of AEA increased continuously and in a region-dependent manner from 1 h after death, increasing about sevenfold by 6 h postmortem. In contrast, concentrations of 2-AG, which were 10-100 times higher in human brain regions than those of AEA, rapidly declined: within the first hour, 2-AG levels dropped to 25-35% of the initial ('0 min') value, thereafter they remained relatively stable. As analyzed in samples removed 1-1.5 h postmortem, AEA levels ranged from a high of 96.3 fmol/mg tissue in the nucleus accumbens to a low of 25.0 fmol/mg in the cerebellum. 2-AG levels varied eightfold, from 8.6 pmol/mg in the lateral hypothalamus to 1.1 pmol/mg in the nucleus accumbens. Relative levels of AEA and 2-AG varied from region to region, with the 2-AG:AEA ratio being high in the sensory spinal trigeminal nucleus (140:1), the spinal dorsal horn (136:1) and the lateral hypothalamus (98:1) and low in the nucleus accumbens (16:1) and the striatum (31:1). The results highlight the pitfall of analyzing endocannabinoid content in brain samples of variable postmortal delay, and document differential distribution of the two main endocannabinoids in the human brain.

Assessment of brain dopamine metabolism from plasma HVA and MHPG during debrisoquin treatment: validation in monkeys treated with MPTP.

Homovanillic acid (HVA) is formed from dopamine that escapes conversion to norepinephrine in noradrenergic neurons throughout the body as well as from dopamine synthesized in dopaminergic neurons that are mainly in brain. Debrisoquin has been used to diminish peripheral formation of dopamine to enhance the value of plasma HVA as an index of brain dopaminergic activity. This enhancement may be improved if the residual HVA formed in noradrenergic neurons could be estimated. By use of simultaneously measured plasma levels of the major metabolite of norepinephrine, the degree of residual catecholamine formation in noradrenergic neurons can be estimated. By extrapolating to zero MHPG levels the linear relationship of plasma HVA to plasma MHPG, an estimate of HVA formed solely from brain dopaminergic neurons can be obtained. This method was tested by administering debrisoquin to monkeys before and after destruction of brain dopaminergic neurons with MPTP. After MPTP treatment there were decreases in plasma HVA that were relatively greatest when considered in relation to MHPG. The results support the view that the plasma HVA levels at extrapolated zero MHPG levels improves precision in assessing brain dopamine metabolism.

Differential inhibition of neuronal and extraneuronal monoamine oxidase.

This study examined whether the neuronal and extraneuronal sites of action of two monoamine oxidase (MAO) inhibitors, l-deprenyl and debrisoquin, could be distinguished by their effects on plasma concentrations of catecholamine metabolites. Plasma concentrations of the intraneuronal deaminated metabolite of norepinephrine, dihydroxyphenylglycol (DHPG), were decreased by 77% after debrisoquin and by 64% after l-deprenyl administration. Plasma concentrations of the extraneuronal O-methylated metabolite of norepinephrine, normetanephrine, were increased substantially more during treatment with l-deprenyl than with debrisoquin (255% compared to a 27% increase). The comparable decreases in plasma concentrations of DHPG indicate a similar inhibition of intraneuronal MAO by both drugs. Much larger increases in normetanephrine after l-deprenyl than after debrisoquin are consistent with a site of action of the latter drug directed at the neuronal rather than the extraneuronal compartment. Thus, differential changes in deaminated and O-methylated amine metabolites allows identification of neuronal and extraneuronal sites of action of MAO inhibitors.

Glycine stimulates striatal dopamine release in conscious rats.

1. Glycine is an inhibitory neurotransmitter in the spinal cord and brainstem. The mechanism of this inhibition is via binding of glycine to specific receptors, increasing transmembrane Cl- conductance and hyperpolarizing neurones. Strychnine selectively antagonizes these effects. The role of glycinergic neurones in supraspinal regions is poorly understood. 2. Effects of glycine on release of catecholamines in the striatum were examined by microdialysis in freely-moving rats. Transcription of the genes encoding strychnine-sensitive glycine receptors was assessed in the striatum and substantia nigra, by use of reverse transcription followed by the polymerase chain reaction. 3. Glycine administered via the microdialysis probe dose-dependently increased concentrations of dopamine and its metabolites, dihydroxyphenylacetic acid and homovanillic acid, in the perfusate, indicating increased local release and metabolism of dopamine. Strychnine markedly attenuated these responses. Whereas striatal tissue did not contain mRNA for either the adult or neonatal form of strychnine-sensitive glycine receptor, nigral tissue contained a message for the adult form. 4. The results suggest that dopaminergic cells in the substantia nigra synthesize strychnine-sensitive glycine receptors and transport the receptors to terminals in the striatum. Occupation of the glycine receptors then exerts a net stimulatory effect on striatal dopamine release in vivo.

1-Methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) effects on enkephalinergic neurons in various regions of mouse brain.

In order to elucidate the effects of MPTP on enkephalinergic neurons, dopamine (DA), norepinephrine (NE), proenkephalin (PE) mRNA and met-enkephalin (ME) were measured in striatum, olfactory tubercle, and prefrontal cortex of C57/B16 mice 1 day-2 weeks following treatment with 96 mg/kg MPTP HCl (24 mg/kg i.p., twice/day for 2 days). DA and its metabolites were depleted 70% in striatum and 40% in olfactory tubercle within 1 day. In cortex, DA was unchanged, whereas homovanillic acid and NE were depleted 50 and 40% respectively by 3 days. ME increased in all three brain regions at different times whereas PE mRNA showed a different pattern in each region, with an increase in olfactory tubercle, a decrease in cortex, and in striatum, a decrease at 1 day followed by an increase at 3 days. Thus enkephalinergic neurons in each region respond differently to MPTP treatment. In striatum and olfactory tubercle. DA is depleted sufficiently to release its tonic inhibition on the enkephalinergic neurons, thereby leading to increased enkephalin synthesis. In cortex, the change in NE metabolism appears to cause a decrease of ME release and thereby a depression of PE synthesis. The possible relationship between these results and the changes observed in Parkinson's disease are discussed.

Estimation of striatal dopamine spillover and metabolism in vivo.

A microdialysis probe with an attached microinjection cannula was inserted into rat striatum. [3H]dopamine (or [14C]sucrose as a reference substance for diffusion) was infused via the cannula, with microdialysate sampled for concentrations of endogenous and [3H]-labeled dopamine and its metabolites. The calculated specific activities of the [3H]-labeled metabolites led to the conclusions that striatal extracellular dopamine undergoes inactivation mainly by extraneuronal but also by neuronal uptake and intracellular metabolism. Some of the dopamine taken up into nerve terminals slowly re-enters (spillover) the extracellular fluid unchanged. This spillover was calculated to be about 5 pmol/min. Destruction of dopaminergic terminals increases the turnover of vesicular stores in the surviving terminals, both by increased vesicular leakage and by increased release into the extracellular fluid.

3,4-Dihydroxyphenylacetaldehyde potentiates the toxic effects of metabolic stress in PC12 cells.

3,4-Dihydroxyphenylacetaldehyde (DOPAL) is a toxic metabolite formed by the oxidative deamination of dopamine. This aldehyde is mainly oxidized to 3,4-dihydroxyphenylacetic acid (DOPAC) by aldehyde dehydrogenase (ALDH), but is also partly reduced to 3, 4-dihydroxyphenylethanol (DOPET) by aldehyde or aldose reductase (ARs). In a previous study, we found that rotenone, a complex I inhibitor, induced a rapid accumulation of DOPAL and DOPET in the medium of cultured PC12 cells. Here, we examined the potential role of DOPAL in the toxicity induced by complex I inhibition in PC12 cells and compared the effects of rotenone on concentrations of DOPAL and DOPET to those of MPP(+). DOPAL and DOPET levels were increased by rotenone but decreased by MPP(+). Inhibition of ALDH by daidzein reduced the formation of DOPAC and increased the accumulation of DOPAL. Inhibition of ARs (with AL1576) diminished DOPET formation and elevated DOPAL concentrations. Combined inhibition of ALDH and ARs markedly elevated DOPAL concentrations while diminishing DOPET and DOPAC levels. The elevation of DOPAL levels induced by combined inhibition of ALDH and ARs had no effect on cell viability. However, combined inhibition of ALDH and ARs potentiated rotenone-induced toxicity. Both the potentiation of toxicity and the increase in DOPAL levels were blocked by inhibition of monoamine oxidase with clorgyline indicating that accumulation of DOPAL was responsible for the potentiated rotenone-induced toxicity following combined inhibition of ALDH and ARs. Since complex I dysfunction is reported to be involved in the pathogenesis of Parkinson's disease, DOPAL potentiation of the deleterious effects of complex I inhibition may contribute to the specific vulnerability of dopaminergic neurons to injury.

Kir6.2 oligoantisense administered into the globus pallidus reduces apomorphine-induced turning in 6-OHDA hemiparkinsonian rats.

ATP-sensitive inwardly rectifying potassium channels (KATPs) couple cell metabolism with its membrane potential. The best characterized KATP is the pancreatic KATP which is an heteromultimer of Kir6.2 and SUR1 protein subunits. KATPs are found in a variety of excitable cells, including neurons of the central nervous system. Basal ganglia (BG), especially in the substantia nigra (SN) reticulata and the globus pallidus (GP), have a high density of KATPs. Pharmacological modulation of the KATPs within the BG alters GABAergic activity and produces behavioural changes. However, the relatively high concentrations of drugs used might not have been entirely selective for the KATPs and may have acted at presynaptic nerve terminals as well as on the post-synaptic neurons. As an alternative means of examining the role of KATPs in regulating motor behavior, we used oligoantisense technology to diminish selectively Kir6.2 formation in the GP neurons. We then examined the effect of reduction in Kir6.2 expression on apomorphine-induced turning behavior in rats with unilateral 6-hydroxydopamine (6-OHDA) lesions of the SN. Two weeks after injection of 6-OHDA, contralateral circling in response to apomorphine (0.25 mg/kg sc) was recorded. Kir6.2 antisense oligodeoxyribonucleotide (ODN) was then administered daily for 6 days into the GP ipsilateral to the 6-OHDA injection. Responses to apomorphine were then tested again and the animals killed to determine the effect of the antisense ODN on Kir6. 2 mRNA. Administration of Kir6.2 antisense ODN significantly attenuated apomorphine-induced contralateral turning and specifically reduced Kir6.2 mRNA in the injected GP. These results are consistent with pharmacological experiments which suggest that KATP channels in the GP are involved in motor responses to apomorphine in 6-OHDA lesioned rats, localizing the effects to the GP neurons, probably through modulation of the GABAergic system.

Neurochemical alterations in the cerebellum of a murine model of Niemann-Pick type C disease.

Niemann-Pick disease Type C (NPC) is a progressive neurovisceral metabolic disorder that is caused in most patients by a defect in a recently found gene, NPC-1. Neurological damage includes visual disorders such as vertical supranuclear gaze palsy, movement disorders such as dystonia and ataxia, dementia, and seizures. So far the biochemical deficit, most likely manifested by delayed intracellular cholesterol transport, has not been correlated with the progressive neurological damage. A mutant Balb/C mouse with a defect in the same gene is used as a model to study NPC. Pathological examination of brain tissue obtained by autopsy from NPC patients or brains of affected NPC mice of different ages, revealed signs of extensive damage throughout the brain, including neurofibrillary tangles and intracellular storage of various compounds. Loss of cerebellar Purkinje cells was the most significant specific damage. The present study examined whether the neurochemical changes present in the NPC mouse brain were related to the pathological changes. The results show major alterations in the levels of serotonin and its main metabolite, 5-hydroxyindoleacetic acid, in the cerebellum and cortex of NPC mice. The levels of the inhibitory amino acid glycine were threefold higher in the cerebellum of NPC mice and those of glutamate and GABA decreased in the cortex. Tyrosine hydroxylase immunoreactivity was present in Purkinje cells, and the levels of L-DOPA increased specifically in the vermis of the cerebellum. These results are the first to indicate changes in neurotransmitters in NPC and that these could be correlated with some of the neuropathology of this disease.

The partial dopamine receptor agonist terguride in the MPTP-induced hemiparkinsonian monkey model.

The partial dopamine agonist terguride (transdihydrolisuride) administered to four 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) lesioned hemiparkinsonian monkeys (at a dose of 4 mg/kg orally) induced marked contralateral turning that lasted 3.5 h. The 6-n-propyl derivative of terguride (proterguride) given to two monkeys (at a dose of 0.4 mg/kg orally) caused contralateral turning which lasted for more than 24 h but produced side effects such as dyskinesia and stereotype. After terguride treatment, cerebrospinal fluid concentrations of 3-methoxy-4-hydroxy-phenylglycol (MHPG) were increased, whereas concentrations of the metabolites dihydroxyphenylacetic acid (DOPAC), homovanillic acid (HVA), and 5-hydroxyindoleacetic acid (5-HIAA) were not significantly altered.

Effect of glipizide on dopamine synthesis, release and metabolism in PC12 cells.

Sulfonylureas block ATP-dependent K(+) channels (K/ATP channels) in pancreatic beta cells and brain gamma-aminobutyric acid (GABA) containing neurons causing depolarization-evoked insulin or GABA release. In high concentrations, sulfonylureas also inhibit catecholamine release from bovine adrenal chromaffin cells and isolated guinea pig aorta. In this study, we examined the effect of glipizide, a sulfonylurea, on dopamine release from PC12 cells and found that neither basal nor K(+)-stimulated dopamine release was affected. Although PC12 cells expressed mRNA for the K/ATP channel, functional K/ATP channels could not be demonstrated electrophysiologically, consistent with the lack of effect of glipizide on dopamine release. Glipizide did, however, increase cytoplasmic retention of the acidic dopamine metabolites, 3, 4-dihydroxyphenylacetic acid (DOPAC) and homovanillic acid (HVA), indicating blockade of their outward transport. The cellular accumulation of DOPAC was accompanied by reduced tyrosine hydroxylase activity and reduced formation of dopamine and its metabolites presumably by a negative feedback effect of the increased cytoplasmic concentrations of DOPAC.

Acidic dopamine metabolites are actively extruded from PC12 cells by a novel sulfonylurea-sensitive transporter.

Incubation of PC 12 cells with the sulfonylurea drug, glipizide (1-100 microM), increased intracellular levels of the acidic metabolites of dopamine, 3,4-dihydroxyphenylacetic acid (DOPAC) and homovanillic acid (HVA). The levels of these acids in the medium were decreased, indicating the presence of a sulfonylurea-sensitive organic anion transporter. In the present study, we demonstrate that the sulfonylurea-sensitive transport of acidic dopamine metabolites is unidirectional, ATP dependent, unaffected by ouabain or by tetrodotoxin and blocked by drugs that interact with the multidrug-resistance protein-1 (MRP1). However, over-expression of MRP1 did not affect transport of the acid metabolites. The pharmacological profile and ion dependence of the transporter also differs from that of known ATP-binding cassette (ABC) family members. Using microdialysis, we also demonstrated a sulfonylurea-sensitive transport process in the striatum of freely moving rats. These results show that acidic dopamine metabolites are actively secreted from dopaminergic cells into surrounding extracellular fluid by a previously undescribed transporter.

Increased striatal dopamine production from L-DOPA following selective inhibition of monoamine oxidase B by R(+)-N-propargyl-1-aminoindan (rasagiline) in the monkey.

Striatal extracellular fluid concentrations of dopamine and metabolites in response to direct striatal administration of two L-DOPA boluses administered sequentially were determined in three rhesus monkeys during halothane anesthesia. Whereas in an initial microdialysis run, generation of dopamine was less following the second L-DOPA bolus than the first, in a subsequent run, in which the selective MAO-B inhibitor R(+)-N-propargyl-1-aminoindan (rasagiline) was administered systemically (0.2 mg/kg s.c.) between the two L-DOPA boluses, generation of dopamine was greater following the second bolus.

Increased cerebral blood flow but no reversal or prevention of vasospasm in response to L-arginine infusion after subarachnoid hemorrhage.

OBJECT: The reduction in the level of nitric oxide (NO) is a purported mechanism of delayed vasospasm after subarachnoid hemorrhage (SAH). Evidence in support of a causative role for NO includes the disappearance of nitric oxide synthase (NOS) from the adventitia of vessels in spasm, the destruction of NO by hemoglobin released from the clot into the subarachnoid space, and reversal of vasospasm by intracarotid NO. The authors sought to establish whether administration of L-arginine, the substrate of the NO-producing enzyme NOS, would reverse and/or prevent vasospasm in a primate model of SAH. METHODS: The study was composed of two sets of experiments: one in which L-arginine was infused over a brief period into the carotid artery of monkeys with vasospasm, and the other in which L-arginine was intravenously infused into monkeys over a longer period of time starting at onset of SAH. In the short-term infusion experiment, the effect of a 3-minute intracarotid infusion of L-arginine (intracarotid concentration 10(-6) M) on the degree of vasospasm of the right middle cerebral artery (MCA) and on regional cerebral blood flow (rCBF) was examined in five cynomolgus monkeys. In the long-term infusion experiment, the effect of a 14-day intravenous infusion of saline (control group, five animals) or L-arginine (10(-3) M; six animals) on the occurrence and degree of cerebral vasospasm was examined in monkeys. The degree of vasospasm in all experiments was assessed by cerebral arteriography, which was performed preoperatively and on postoperative Days 7 (short and long-term infusion experiments) and 14 (long-term infusion experiment). In the long-term infusion experiment, plasma levels of L-arginine were measured at these times in the monkeys to confirm L-arginine availability. Vasospasm was not affected by the intracarotid infusion of L-arginine (shown by the reduction in the right MCA area on an anteroposterior arteriogram compared with preoperative values). However, intracarotid L-arginine infusion increased rCBF by 21% (p < 0.015; PCO2 38-42 mm Hg) in all vasospastic monkeys compared with rCBF measured during the saline infusions. In the long-term infusion experiment, vasospasm of the right MCA occurred with similar intensity with or without continuous intravenous administration of L-arginine on Day 7 and had resolved by Day 14. The mean plasma L-arginine level increased during infusion from 12.7+/-4 microg/ml on Day 0 to 21.9+/-13.1 microg/ml on Day 7 and was 18.5+/-3.1 microg/ml on Day 14 (p < 0.05). CONCLUSIONS: Brief intracarotid and continuous intravenous infusion of L-arginine did not influence the incidence or degree of cerebral vasospasm. After SAH, intracarotid infusion of L-arginine markedly increased rCBF in a primate model of SAH. These findings discourage the use of L-arginine as a treatment for vasospasm after SAH.

Effect of MPTP-induced parkinsonism in monkeys on the urinary excretion of HVA and MHPG during debrisoquin administration.

During debrisoquin administration to three monkeys there were significant reductions in excretion rates of HVA, the major dopamine metabolite, and MHPG, the major norepinephrine metabolite. Excretion rates of HVA were highly correlated to those of MHPG. The regression line relating HVA and MHPG excretion suggests that a portion of HVA (about 25%) is derived from a source independent of norepinephrine metabolites. There was a striking reduction of this portion of HVA excretion after MPTP-induced destruction of dopaminergic nigrostriatal neurons. These results support the view that the rate of HVA formation in brain dopaminergic neurons can be estimated from the relationship of urinary excretion rates of HVA and MHPG before and during debrisoquin treatment.

Determination of submicromolar concentrations of neurotransmitter amino acids by fluorescence detection using a modification of the 6-aminoquinolyl-N-hydroxysuccinimidyl carbamate method for amino acid analysis.

A sensitive method for quantitatively determining submicromolar levels of neurotransmitter amino acids (e.g. Asp, Glu and gamma-aminobutyric acid) in microdialysates from brain and cerebrospinal fluids is reported. 6-Aminoquinolyl-N-hydroxy-succinimidyl carbamate (AQC) was employed as the derivatization reagent, followed by HPLC separation and fluorescence detection of the derivatives. The derivatization was conducted simply by mixing the AQC directly with the microdialysis samples. The reaction was complete within seconds after mixing at room temperature. Separation development optimizing the gradient profile, eluent pH and column temperature resulted in an excellent separation of the required amino acids in less than 30 min. Other resolved amino acids in the same profile include Gly, taurine, and Pro. Recoveries for the amino acids of interest spiked into high salt containing perfusion buffers were greater than 97%. The sensitivity of the method was increased by employing a 16-microliter flow cell in the detector and analyzing 20-microliter aliquots of the derivatization mixtures. With the optimized conditions, the detection limits were 3-7 nM (fmol/microliter). Typical reproducibility (%R.S.D.) for quantitation of these amino acids at submicromolar levels was approximately 2%. Excellent linearity (r2 > 0.999) was achieved over the range 0.2-20 microM. The low detection limits permitted the analysis of a number of different microdialysate samples including those from cerebrospinal fluid, as well as substantia nigra and hypothalamus from brain samples, even at basal levels where gamma-aminobutyric acid concentration may be < 50 nM. The excellent sensitivity made it easy to distinguish basal from stimulated levels of neurotransmitter amino acids, even from sample sizes as small as 10 microliters.

Method for determining serum pepsinogen concentration, using pepsin standards and ultraviolet absorbance.

A simplification of the traditional hemoglobin methods for determining serum pepsinogen concentration was developed. In this method, 10% trichloroacetic acid solution was added to control samples, and hemoglobin substrate was added to controls and active enzyme samples; standards and samples were incubated for 18 hours, the proteins in the active tubes were precipitated with trichloroacetic acid and removed by filtration, and the absorbances of the supernatant of each standard and sample at 280 nm were measured. The major differences between this method and other methods for determining pepsinogen values are that the preacidification of serum with hydrochloric acid was eliminated, the incubation period was reduced to 18 hours (down from 24 hours), the relative pepsinogen concentration was determined by measuring the concentration of hydrolysis products, using ultraviolet, rather than visible absorbance, and a pepsin standard curve was used to determine the serum pepsinogen concentration. Comparison of freshly prepared pepsinogen and pepsin standard curves indicated that the pepsinogen preparations were slightly more active than the pepsin preparations (on a weight-to-weight basis) on the same substrate. Pepsin standards are used because they are more stable than pepsinogen standards. Three linear standard curve ranges were used: O 10 to 100, 50 to 300, and 100 to 500 ng of pepsinogen/ml of serum. The use of pepsin standard curves permits some variability of the incubation conditions without altering the results. For best results, the hemoglobin substrate solution should be prepared daily. This method may be useful in diagnosing ostertagiasis.

Reference serum pepsinogen concentrations in dairy cattle.

Serum samples from 27 yearling heifers and 50 lactating cows were analyzed for pepsinogen concentration. Concentrations were 44 +/- 12 (SD) ng of pepsinogen/ml (2,200 mU of tyrosine/ml) of serum for the yearling heifers and 20 +/- 8 ng/ml (1,400 mU of tyrosine/ml) for the lactating cows. These initial data indicate that a yearling calf, grazing on pasture, with a serum pepsinogen concentration greater than 68 ng/ml (2,900 mU of tyrosine/ml) should be examined for ostertagiasis.

The role of the endocannabinoid system in the control of energy homeostasis.

The endocannabinoid system has recently emerged as an important regulator of energy homeostasis, involved in the control of both appetite and peripheral fat metabolism. We briefly review current understanding of the possible sites of action and cellular mechanisms involved in the central appetitive and peripheral metabolic effects of endocannabinoids. Studies in our laboratory, using leptin-deficient obese rodents and CB1 cannabinoid receptor (CB1)-deficient mice, have indicated that endocannabinoids acting via CB1 are involved in the hunger-induced increase in food intake and are negatively regulated by leptin in brain areas involved in appetite control, including the hypothalamus, limbic forebrain and amygdala. CB1-/- mice are lean and are resistant to diet-induced obesity (DIO) despite similar energy intake to wild-type mice with DIO, suggesting that CB1 regulation of body weight involves additional peripheral targets. Such targets appear to include both adipose tissue and the liver. CB1 expressed in adipocytes has been implicated in the control of adiponectin secretion and lipoprotein lipase activity. Recent findings indicate that both endocannabinoids and CB1 are present in the liver and are upregulated in DIO. CB1 stimulation increases de novo hepatic lipogenesis through activation of the fatty acid biosynthetic pathway. Components of this pathway are also expressed in the hypothalamus where they have been implicated in the regulation of appetite. The fatty acid biosynthetic pathway may thus represent a common molecular target for the central appetitive and peripheral metabolic effects of endocannabinoids.

Metabolic stress in PC12 cells induces the formation of the endogenous dopaminergic neurotoxin, 3,4-dihydroxyphenylacetaldehyde.

3,4-Dihydroxyphenylacetaldehyde (DOPAL) has been reported to be a toxic metabolite formed by the oxidative-deamination of dopamine (DA) catalyzed by monoamine oxidase. This aldehyde is either oxidized to 3,4-dihydroxyphenylacetic acid (DOPAC) by aldehyde dehydrogenase, an NAD-dependent enzyme or reduced to 3, 4-dihydroxyphenylethanol (DOPET) by aldehyde or aldose reductase. In the present study we examined whether levels of DOPAL are elevated by inhibition of the mitochondrial respiratory chain. Using inhibitors of mitochondrial complexes I, II, III and IV we found that inhibition of complex I and III increased levels of DOPAL and DOPET. Nerve growth factor-induced differentiation of PC12 cells markedly potentiated DOPAL and DOPET accumulation in response to metabolic stress. DOPAL was toxic to differentiated PC12 as well as to SK-N-SH cell lines. Because complex I dysfunction has been implicated in the pathogenesis of Parkinson's disease, the accumulation of DOPAL may explain the vulnerability of the dopaminergic system to complex I inhibition. The rapid appearance of DOPAL and DOPET after inhibition of complex I may be a useful early index of oxidative stress in DA-forming neurons.