The regional distribution of dopamine and serotonin uptake and transmitter concentrations in the human brain

Serotonin and Melatonin Show Different Modes of Action on Aβ42 Protofibril Destabilization

Alzheimer's disease (AD) is associated with the aberrant self-assembly of amyloid-β (Aβ) protein into fibrillar deposits. The disaggregation of Aβ fibril is believed as one of the major therapeutic strategies for treating AD. Previous experimental studies reported that serotonin (Ser), one of the indoleamine neurotransmitters, and its derivative melatonin (Mel) are able to disassemble preformed Aβ fibrils. However, the fibril-disruption mechanisms are unclear. As the first step to understand the underlying mechanism, we investigated the interactions of Ser and Mel molecules with the LS-shaped Aβ₄₂ protofibril by performing a total of nine individual 500 ns all-atom molecular dynamics (MD) simulations. The simulations demonstrate that both Ser and Mel molecules disrupt the local β-sheet structure, destroy the salt bridges between K28 side chain and A42 COO^-, and consequently destabilize the global structure of Aβ₄₂ protofibril. The Mel molecule exhibits a greater binding capacity than the Ser molecule. Intriguingly, we find that Ser and Mel molecules destabilize Aβ₄₂ protofibril through different modes of action. Ser preferentially binds with the aromatic residues in the N-terminal region through π-π stacking interactions, while Mel binds not only with the N-terminal aromatic residues but also with the C-terminal hydrophobic residues via π-π and hydrophobic interactions. This work reveals the disruptive mechanisms of Aβ₄₂ protofibril by Ser and Mel molecules and provides useful information for designing drug candidates against AD.

Structural Influence and Interactive Binding Behavior of Dopamine and Norepinephrine on the Greek-Key-Like Core of α-Synuclein Protofibril Revealed by Molecular Dynamics Simulations

The pathogenesis of Parkinson’s disease (PD) is closely associated with the aggregation of α-synuclein (αS) protein. Finding the effective inhibitors of αS aggregation has been considered as the primary therapeutic strategy for PD. Recent studies reported that two neurotransmitters, dopamine (DA) and norepinephrine (NE), can effectively inhibit αS aggregation and disrupt the preformed αS fibrils. However, the atomistic details of αS-DA/NE interaction remain unclear. Here, using molecular dynamics simulations, we investigated the binding behavior of DA/NE molecules and their structural influence on αS44–96 (Greek-key-like core of full length αS) protofibrillar tetramer. Our results showed that DA/NE molecules destabilize αS protofibrillar tetramer by disrupting the β-sheet structure and destroying the intra- and inter-peptide E46–K80 salt bridges, and they can also destroy the inter-chain backbone hydrogen bonds. Three binding sites were identified for both DA and NE molecules interacting with αS tetramer: T54–T72, Q79–A85, and F94–K96, and NE molecules had a stronger binding capacity to these sites than DA. The binding of DA/NE molecules to αS tetramer is dominantly driven by electrostatic and hydrogen bonding interactions. Through aromatic π-stacking, DA and NE molecules can bind to αS protofibril interactively. Our work reveals the detailed disruptive mechanism of protofibrillar αS oligomer by DA/NE molecules, which is helpful for the development of drug candidates against PD. Given that exercise as a stressor can stimulate DA/NE secretion and elevated levels of DA/NE could delay the progress of PD, this work also enhances our understanding of the biological mechanism by which exercise prevents and alleviates PD.

Elucidation of the interplay between Fe(II), Fe(III), and dopamine with relevance to iron solubilization and reactive oxygen species generation by catecholamines

The non-enzymatically catalyzed oxidation of dopamine (DA) and the resultant formation of powerful oxidants such as the hydroxyl radical ((•) OH) through 'Fenton chemistry' in the presence of iron within dopaminergic neurons are thought to contribute to the damage of cells or even lead to neuronal degenerative diseases such as Parkinson's disease. An understanding of DA oxidation as well as the transformation of the intermediates that are formed in the presence of iron under physiological conditions is critical to understanding the mechanism of DA and iron induced oxidative stress. In this study, the generation of H2 O2 through the autoxidation and iron-catalyzed oxidation of DA, the formation of the dominant complex via the direct reaction with Fe(II) and Fe(III) in both oxygen saturated and deoxygenated conditions and the oxidation of Fe(II) in the presence of DA at physiological pH 7.4 were investigated. The oxidation of DA resulted in the generation of significant amounts of H2 O2 with this process accelerated significantly in the presence of Fe(II) and Fe(III). At high DA:Fe(II) ratios, the results from this study suggest that DA plays a protective role by complexing Fe(II) and preventing it from reacting with the generated H2 O2 . However, the accumulation of H2 O2 may result in cellular damage as high intracellular H2 O2 concentrations will result in the oxidation of remaining Fe(II) mainly through the peroxidation pathway. At low DA:Fe(II) ratios however, it is likely that DA will act as a pro-oxidant by generating H2 O2 which, in the presence of Fe(II), will result in the production of strongly oxidizing (•) OH radicals. Powerful oxidants such as the hydroxyl radical ((•) OH) have previously been thought to be generated through the interplay between dopamine (DA) and iron, contributing to damage to cells and, potentially, leading to neuronal degenerative diseases such as Parkinson's disease. Our results suggest that DA plays a dual role as high DA/Fe(II) ratios prevent Fe(II) from reacting with the generated H2 O2 thereby reducing (•) OH generation, whereas low DA/Fe(II) ratios enhance (•) OH generation as a result of reaction of unbound Fe(II) and H2 O2 produced via both autoxidation and iron-catalyzed oxidation of DA.

Decreased brain dopamine cell numbers in human cocaine users

Cocaine use diminishes striatal and midbrain dopamine neuronal components in both post-mortem and in vivo human experiments. The diffuse nature of these declines suggests the possibility that cocaine use might cause a loss of dopamine neurons in humans. Previous rodent studies have not detected cocaine-induced dopamine cell damage. The present experiment involved counting midbrain dopamine neurons utilizing both melanin and tyrosine hydroxylase immunoreactivity. Well-preserved blocks ranging from +38 mm obex to +45 mm obex were examined in 10 cocaine users and 9 controls. Sections were also examined for signs of acute pathological injury by counting activated macrophages and microglia. Melanized cells at six midbrain levels were significantly reduced in cocaine users by both drug exposures. The estimated total number of melanized dopamine cells in the anterior midbrain was significantly reduced in cocaine users by 16%. Results with tyrosine hydroxylase immunoreactivity were less conclusive because of variability in staining. Both activated macrophages and activated microglia were significantly increased among cocaine users. Cocaine exposure may have neurotoxic effects on dopamine neurons in humans. The infiltration of phagocytic cells suggests that the lower number of dopamine cells found in cocaine users was a relatively recent effect. The loss of dopamine cells could contribute to and intensify cocaine dependence, as well as anhedonic and depressive symptoms, in some cocaine users. Further efforts at clarifying the pathophysiological mechanisms involved may help explain treatment refractoriness, and identify targets for therapeutic intervention.

Sex differences in [123I]beta-CIT SPECT measures of dopamine and serotonin transporter availability in healthy smokers and nonsmokers

Nicotine and other constituents of tobacco smoke elevate dopamine (DA) and serotonin (5-HT) levels in brain and may cause homeostatic adaptations in DA and 5-HT transporters. Since sex steroids alter DA and 5-HT transporter expression, the effects of smoking on DA and 5-HT transporter availability may differ between sexes. In the present study, DA and 5-HT transporter availabilities were quantitated using single photon emission computed tomography (SPECT) imaging approximately 22 h after bolus administration of [123I]beta-CIT, an analog of cocaine which labels DA and 5-HT transporters. Forty-two subjects including 21 pairs of age-, race-, and gender-matched healthy smokers and nonsmokers (12 female and 9 male pairs) were imaged. Regional uptake was assessed by the outcome measures, V3", which is the ratio of specific (i.e., ROI-cerebellar activity) to nondisplaceable (cerebellar) activity, and V3, the ratio of specific to free plasma parent. Overall, striatal and diencephalic [123I]beta-CIT uptake was not altered by smoking, whereas brainstem [123I]beta-CIT uptake was modestly higher (10%) in smokers vs. nonsmokers. When subgrouped by sex, regardless of smoking status, [123I]beta-CIT uptake was higher in the striatum (10%), diencephalon (15%), and brainstem (15%) in females vs. males. The sex*smoking interaction was not significant in the striatum, diencephalon, or brainstem, despite the observation of 20% higher brainstem [123I]beta-CIT uptake in male smokers vs. nonsmokers and less than a 5% difference between female smokers and nonsmokers. The results demonstrate higher DA and 5-HT transporter availability in females vs. males and no overall effect of smoking with the exception of a modest elevation in brainstem 5-HT transporters in male smokers. Although these findings are preliminary and need validation with a more selective 5-HT transporter radiotracer, the results suggest that brainstem 5-HT transporters may be regulated by smoking in a sex-specific manner.

Serotonin transporter (5-HTT) gene polymorphisms and susceptibility to cocaine dependence among African-American individuals

Studies indicate that the serotonin system, particularly the serotonin transporter (5-HTT), may modulate the central effects of cocaine. We investigated whether a polymorphism in the 5' promotor region (5-HTTLPR) of the 5-HTT gene confers susceptibility to cocaine dependence. One hundred and ninety-seven cocaine-dependent African-American subjects and 101 controls were studied. Polymerase chain reaction based genotyping of a biallelic repeat polymorphism in the 5' promotor region yielded 2 alleles containing 484 (S) and 528 bp (L) repeats, respectively. There were no significant differences between controls of European background (n = 40) and African-American controls (n = 61) in distribution of genotypes (European: LL = 32.5%, LS = 40.0%, SS = 27.5%; African-American: LL = 27.9%, LS = 57.4%, SS = 14.7%) (chi(2) = 3.60, df = 2, p = 0.16) or allele frequencies (European: L = 52.5%, S = 47.5%; African-American: L = 56.6%, S = 43.4%) (chi(2) = 2.21, df = 1, p = 0.13). When cocaine patients were compared to an ethnically diverse control group (n = 101), frequencies of the L variant (65.0%) were significantly higher while the S variant (35.0%) was less frequent among cocaine patients compared to controls (L = 53.9%, S = 46.1%) (chi(2) = 6.83, df = 1, p < 0.01). Similarly, there were more cocaine patients with the LL genotype (41.1%) and less with the SS genotype (11.2%) compared to controls (LL = 29.7%, SS = 21.8%) (chi(2) = 7.43, df = 2, p < 0.05). However, after restricting controls to African-American individuals only (n = 61), cocaine subjects and controls did not differ significantly with respect to genotype distribution (chi(2) = 4.24, df = 2, p = 0.12) or allele frequencies (chi(2) = 2.83, df = 1, p = 0.10). In conclusion, although comparisons with a heterogeneous control group indicated a possible association between allelic variants of 5-HTTLPR and cocaine dependence among African-American cocaine subjects, this relationship was not observed when the control group was limited to African-American people only. Our findings need to be confirmed on larger samples of ethnically matched individuals.

Subcellular distribution of receptor sites in human brain: differentiation between heavy and light structures of high and low density

Studies of the subcellular localization of neuroreceptors in the rat brain have shown that most of them are associated with light and low density subcellular fractions. In two human brain areas, quite different subcellular distributions were observed. After fractionation by differential centrifugation of frontal cortex homogenates, benzodiazepine and serotonin 5-HT2 receptors were mainly found in the heavy mitochondrial (M) fraction, whereas mu-opiate and muscarinic cholinergic receptors were mainly concentrated in the microsomal (P) fraction. In human putamen, the presynaptic markers of dopaminergic nerve terminals (neurotensin receptors, dopamine uptake sites and amine vesicular transporter-binding sites), benzodiazepine receptors and serotonin uptake sites were recovered both in the high and low density fractions, whereas the muscarinic, opiate and, to a lesser extent, dopamine D2 receptors were mostly concentrated in the microsomal fraction. In the cerebral cortex, after isopycnic centrifugation in sucrose gradients, neuroreceptors were found in the high density fractions where the peaks of cytochrome oxidase and that of nerve endings, as identified by amine uptake and by means of electron microscopy were also found. A single peak of benzodiazepine receptors was observed in high density (1.15-1.17 g/ml) fractions suggesting that these receptors are much more concentrated in the nerve terminals or dendrites rather than in the dendritic spines or vesicles. The fact that muscarinic and opiate receptors were recovered in the P fraction with plasma membrane constituents and also in M and L fractions, which is confirmed by a bimodal distribution in sucrose gradient, suggests that they are localized in both the nerve terminals or dendrites and in the small vesicles or dendritic spines. In the putamen, much of the specific binding to uptake sites for dopamine and serotonin was recovered in the high density fractions, but the existence of another peak at a lower density indicates the presence of microsomal uptake sites. The results indicate that differential and isopycnic fractionation methods performed on human brain samples, make it possible to separate tissue fractions enriched in nerve endings, dendrites, dendritic spines, plasma membranes or vesicles.

[3H]paroxetine and [3H]citalopram as markers of the human brain 5-HT uptake site: a comparison study

The binding of [3H]paroxetine and [3H]citalopram to the human brain serotonin (5-HT) uptake site has been characterized and compared. Our results reveal that the binding exclusively involved with the 5-HT uptake site is identical for both [3H]ligands. The selective 5-HT uptake inhibitor citalopram displays the highest affinity for this uptake site, as compared with the affinities obtained for desipramine and norzimeldine, which is in accordance with their respective blockage of 5-HT uptake. Similar Bmax values were obtained for both radioligands in the brain regions studied, indicating their binding to the same presynaptic membrane protein. Together these findings suggest that both [3H]paroxetine and [3H]citalopram are good markers of the 5-HT transporter as both bind selectively and with high affinity to the serotonin uptake sites. However, the higher affinity of [3H]paroxetine confirms that this compound is the best radioligand for the 5-HT uptake site available today.

[125I]RTI-55 binding to cocaine-sensitive dopaminergic and serotonergic uptake sites in the human brain

[125I]RTI-55 is a newly synthesized cocaine congener that may offer advantages over other ligands previously used to examine cocaine binding sites. However, the in vitro pharmacological and anatomical characterization of [125I]RTI-55 binding sites has not been previously performed in human brain. To determine the specificity, stability, and feasibility of [125I]RTI-55 for use in radioligand binding assays in postmortem human tissue, a series of experiments were performed characterizing [125I]RTI-55 binding sites in human brain using homogenized membrane preparations and quantitative autoradiography. Analysis of the association, dissociation, and saturation data favored two-phase processes. A curve-fitting analysis of the data derived in saturation experiments found a high-affinity site with KD = 66 +/- 35 pM and Bmax = 13.2 +/- 10.1 pmol/g of tissue and a low-affinity site with KD = 1.52 +/- 0.55 nM and Bmax of 47.5 +/- 11.2 pmol/g of tissue. Competition by ligands known to bind to the dopamine transporter showed a rank order of RTI-55 > GBR-12909 > maxindol > WIN 35428 > = methylphenidate > (-)-cocaine > buproprion > (+)-amphetamine. Binding to serotonergic sites was evaluated in the midbrain. Results of the saturation experiment performed autoradiographically in the midbrain showed a single site with KD = 370 +/- 84 pM. It appears that [125I]RTI-55 should be useful in further studies of the regulation of cocaine binding sites using postmortem human specimens.

Cocaine use increases [3H]WIN 35428 binding sites in human striatum

Animal studies suggest that chronic cocaine exposure may increase the function and/or synthesis of the dopamine transporter (DAT) under certain conditions, but the literature is complex. In order to test the hypothesis that cocaine exposure alters the DAT in humans, preliminary studies were done characterizing [3H]WIN 35428 binding in human striatum from normal controls. Following these experiments, the effects of chronic cocaine were examined in post mortem striatal specimens from 7 cocaine users and 7 controls matched for age and post mortem interval, employing quantitative autoradiography. Initial saturation experiments indicated that a one-site model was preferred with a Kd of 11 +/- 4 nM. [3H]WIN 35420 binding was then examined in cocaine users and controls at 0.5, 5, 10, and 50 nM radioligand concentrations. At each concentration of [3H]WIN 35420, optical densities for cocaine-exposed subjects were increased in caudate, putamen, and accumbens. The results suggest that total numbers of binding sites were increased in cocaine users. Based on the present and previous results, it appears that the regulation of the DAT is fairly plastic, and is highly sensitive to cocaine dosing regimes and withdrawal intervals. Chronic adaptations induced by cocaine in the DAT could contribute to the symptoms of binging, withdrawal depression, and/or craving.

Recent developments in the pathophysiology and treatment of hepatic encephalopathy

The pathophysiology of HE has not yet been clarified. At present the main mechanisms under discussion are the combined effects of different toxins, such as ammonia, mercaptans, phenols and short- and medium-chain fatty acids, as well as a change particularly in GABAergic and glutamatergic neurotransmission. In this chapter the current views on the importance of these individual factors in the pathophysiology of HE are discussed; possible connections between changes in neurotransmission and the effect of different neurotoxins are presented. In addition, possible therapies resulting from recent knowledge of the pathophysiology of this disease are discussed, such as the use of Bz receptor antagonists.

Autoradiographic characterization of [3H]imipramine and [3H]citalopram binding in rat and human brain: species differences and relationships to serotonin innervation patterns

The neuroanatomical distribution of binding sites for [3H]imipramine and [3H]citalopram was assessed by in vitro autoradiography in select regions of the rat and human forebrain. To determine involvement of serotonin-containing terminals in the binding of [3H]imipramine and [3H]citalopram, binding of these compounds was measured in rats after destroying serotonin-containing neurons with 5,7-dihydroxytryptamine (5,7-DHT). Treatment with this neurotoxin decreased serotonin content by 90% and reduced [3H]citalopram binding to a similar extent. These results demonstrate that [3H]citalopram binding is a reliable marker for serotonin-containing terminals. Binding of [3H]imipramine was reduced by only 15-35% after 5,7-DHT treatment. These latter results suggest that only a small fraction of [3H]imipramine binding to brain sections is associated with serotonergic terminals under standard conditions used in autoradiographic studies with the ligand. Dose-response effects of fluoxetine and desipramine on displacement of [3H]imipramine binding in forebrain regions indicate that the ligand labels predominantly high capacity, low affinity binding sites. To determine the utility of the rat brain as a model for [3H]imipramine and [3H]citalopram binding in the human brain, binding of the ligands was compared in human and rat hypothalamus, amygdala, and hippocampus. The pharmacological characteristics of [3H]imipramine and [3H]citalopram binding were similar in the rat and human brain. However, substantial species differences were observed in topographic patterns of [3H]imipramine binding within the hippocampus and hypothalamus. The distribution of [3H]citalopram binding sites within the amygdala and hypothalamus were also strikingly different in rats compared to humans. This work provides the first demonstration that marked species differences exist in the topography of serotonergic innervation and in the distribution of [3H]imipramine binding sites within the rat and human brain regions examined.

Mesostriatal and mesolimbic dopamine uptake binding sites are reduced in Parkinson's disease and progressive supranuclear palsy: a quantitative autoradiographic study using [3H]mazindol

It has been suggested that not only mesostriatal but also mesolimbic pathways are involved in the degeneration of dopaminergic neurons in Parkinson's disease. Using quantitative ligand autoradiography we have investigated dopamine transporter sites in basal ganglia of patients affected by Huntington's chorea, Parkinson's disease and progressive supranuclear palsy. [3H]Mazindol, a ligand for catecholamine uptake, was used in the presence of desipramine to block the binding to norepinephrine uptake sites. Schizophrenic cases were entered in the study to take into account the effects of neuroleptics, commonly administered also to Huntington's disease patients, on dopamine uptake sites. In control cases high densities of [3H]mazindol binding sites were found in the caudate nucleus, putamen and nucleus accumbens, whereas very low densities were present in substantia nigra and ventral tegmental area. In Huntington's chorea the density of [3H]mazindol binding sites was slightly decreased in the caudate nucleus, an area severely affected by the neurodegenerative process. In schizophrenic patients the density of dopamine uptake sites in the basal ganglia was slightly reduced, mainly in the middle third of putamen. Both Parkinson's disease and progressive supranuclear palsy populations were characterized by a marked loss of [3H]mazindol binding sites in the neostriatum (about 75%) and in the nucleus accumbens (about 65%). These results suggest that in Parkinson's disease and progressive supranuclear palsy severe decreases of dopamine uptake sites occur not only in the mesostriatal pathway but also in the mesolimbic tract.

Regional distribution of monoamines and dopamine D1- and D2-receptors in the striatum of the rat

Dopamine (DA) D1- and D2-receptor densities were determined in 18 discrete areas of the caudate-putamen-globus pallidus of male Wistar rats and compared to local DA concentrations. All three parameters were found to decrease caudally. The globus pallidus was distinguished by the low concentration of DA and its receptors and high noradrenaline (NA) content. While there were no mediolateral differences in DA or DA D1-receptors, a clear mediolateral gradient was observed for DA D2-receptors which extended over several sections of the brain. The ratio of DA D1- to D2-receptors was significantly higher in the dorsal than in the ventral areas of the mediolateral and caudal striatum. This is the first report of clear dorsoventral differences in parameters relating to DA activity in the striatum. These findings may be of particular significance in understanding the functional dichotomy between the dorsal and ventral striatum.

Distribution of catecholamine uptake sites in human brain as determined by quantitative [3H] mazindol autoradiography

Because of the importance of the catecholamine system in Parkinson's disease and its relevance to a variety of clinical movement disorders, catecholamine uptake sites were mapped in the human brain using [3H] mazindol autoradiography. Displacement studies with known dopamine (DA) and noradrenaline (NA) uptake blockers showed that binding in the striatum was to dopamine uptake sites; binding in the locus coeruleus was to noradrenergic uptake sites. By using the selective noradrenergic uptake blocker desmethylimipramine (DMI), a comprehensive map of both DA and NA uptake sites was generated. In general, catecholamine uptake sites were better seen in terminals than in cells of origin or axonal projections. In some areas, such as the locus coeruleus, punctate binding could be seen over individual pigmented cells. A variegated pattern of binding was seen in caudate nucleus and putamen and some correspondence of patches of low binding with striosomes was observed in the caudate. The highest levels of binding to DA uptake sites was observed in the striatum, where regional differences in binding occurred. The most dense binding was seen in the ventral striatum, and a rostral-to-caudal decrement in binding levels in caudate nucleus and putamen was evident. Binding was more intense in the putamen compared to the caudate and within the caudate lower values were seen laterally. The highest levels of binding to noradrenergic uptake sites were in the locus coeruleus and dorsal raphé, although these sites may be on terminals from other projections. Whereas uptake sites were more often evident in known catecholamine pathways, [3H] mazindol binding was seen in some areas where catecholamine neurons or terminals had not been identified previously. These maps of the catecholamine uptake system add further information concerning the nature of the distribution of catecholamines in human brain and provide an important baseline for the study of disease and ageing processes.

Effect of estradiol and progesterone on rat striatal dopamine uptake sites

Striatal dopamine (DA) uptake sites labelled with [3H]GBR-12935 binding were investigated in ovariectomized (OVX) rats acutely treated with 17 beta-estradiol (E2) or progesterone (P). One injection of E2 (100 ng, SC) to OVX rats increased plasma levels of this steroid after 15 min while plasma prolactin (PRL) levels remained unchanged. The E2 injection left striatal [3H]GBR-12935 binding affinity unchanged while the maximum density increased 15 and 30 min after the injection (+24% and +18%, respectively). One injection of P (110 micrograms, SC) to OVX rats increased this steroid plasma level from 15 to 120 min while plasma PRL levels remained unchanged. [3H]GBR-12935 binding density and affinity remained unchanged up to 120 min after the injection. Thus, acutely, E2 but not P, modulated striatal DA uptake sites in OVX rats. The effect of E2 appeared in coincidence with the peak of this steroid plasma concentration. This increase was rapid and is probably nongenomic and suggests a causal effect relationship as well as a presynaptic site of action of E2.

Enantiomeric composition of urinary salsolinol in parkinsonian patients after Madopar

Urinary salsolinol output had been shown to be lower in Parkinsonian patients than in controls and to increase largely after L-dopa therapy. It had also been established that the R enantiomer of salsolinol is either the predominant or the sole enantiomer present in the urine of healthy subjects. When Madopar was administered to Parkinsonians, the enantiomeric composition of urinary salsolinol showed an S/R ratio around 1. Considering brain and plasma concentrations in dopamine, acetaldehyde and pyruvate, it is suggested that, under physiological conditions, urinary salsolinol should have a central origin in humans. Conversely, urinary salsolinol in Madopar-treated Parkinsonian patients might be predominantly formed at the periphery.

[3H]GBR 12935 binding to dopamine uptake sites in the human brain

Binding of 1-[2-(diphenylmethoxy)ethyl]-4-(3-phenylpropyl)piperazine ([3H]GBR 12935) was studied in membrane preparations of several human brain regions. In putamen, the substituted piperazine derivates cis- and trans-flupenthixol displaced 90% of the total [3H]GBR 12935 binding. Computer-assisted analysis of the competition curves revealed a high-affinity site (30%; KiH = 54 nM) and a low-affinity site (60%; KiL = 4.5 microM). The dopamine uptake blockers mazindol and nomifensine only displaced 30% of the total [3H]GBR 12935 binding in a monophasic way. Binding of [3H]GBR 12935 to the dopamine uptake sites, i.e., that displaced by dopamine uptake blockers, corresponded to part of the binding having low affinity for flupenthixol and was only detected in putamen, nucleus caudatus, nucleus accumbens, and substantia nigra. Even after masking the high-affinity binding site for flupenthixol by including 1 microM cis-flupenthixol in the binding assays, no dopamine uptake sites could be detected in globus pallidus, amygdala, thalamus, hippocampus, and cerebral cortex. Binding of [3H]GBR 12935 to dopamine uptake sites was lost in the nucleus caudatus ipsilateral to ventral midbrain infarctions, confirming their location on nigrostriatal nerve endings. Gross unilateral lesions of the striato- and pallidonigral pathways did not affect the number of dopamine uptake sites in the ipsilateral substantia nigra, suggesting that they may reside on the soma or dendrites of nigral neurons.

Monoamines and metabolites in autopsied brain tissue from cirrhotic patients with hepatic encephalopathy

Alterations in the metabolism of monoamine neurotransmitters have been proposed to be involved in the development of the hepatic encephalopathy (HE) associated with experimental and human liver failure. In order to evaluate this hypothesis, the monoamines and some of their metabolites were measured in homogenates of caudate nucleus (CAU), prefrontal (PFCo) and frontal cortex (FCo) dissected from brains obtained at autopsy from nine cirrhotic patients who had died in hepatic coma and an equal number of control subjects, free from neurological, psychiatric and hepatic disorders, matched for age and time interval from death to freezing of autopsied brain samples. Monoamine measurements were performed by high-performance liquid chromatography with ion-pairing and electrochemical detection after a simple extraction procedure. In all three regions investigated, concentrations of dopamine (DA) were unchanged in cirrhotic patients vs controls while its metabolites, 3-methoxytyramine (3-MT) and homovanillic acid (HVA) were selectively affected i.e. 3-MT was found to be increased in CAU, while HVA levels were increased in FCo and CAU. DOPAC was also found to be unchanged in CAU. Noradrenaline (NA) levels were greatly increased in PFCo and FCo of cirrhotic patients but remained unchanged in CAU. No significant differences in the concentrations of either serotonin (5-HT) or of its precursor 5-hydroxytryptophan (5-HTP) were found in any of the three regions studied. However, 5-hydroxyindoleacetic acid (5-HIAA), the major metabolite of 5-HT, was increased in PFCo and CAU of cirrhotic patients. These findings show that selective alterations of catecholamine and 5-HT systems are involved in human HE and therefore, they may play an important role in the pathogenesis of certain neurological symptoms associated with this encephalopathy.

Postmortem- and cryostability of the potassium-evoked release of [3H]5-hydroxytryptamine from rat cerebral cortical miniprisms

A prerequisite for the study of neurotransmitter release from human brain autopsy samples with histories of different diseases is that the cryo- and postmortem stability of the release process is good. In the present study, the effect of post-mortem delay and of storage at -70 degrees C by the "slow freeze--fast thaw" method of Hardy et al. [J Neurochem (1983) 40: 608-614] (which allows for the retention of metabolic activity of the tissue after the storage and thawing) of rat cerebral cortex samples upon the release of [3H]5-hydroxytryptamine ([3H]5-HT) from prelabelled miniprisms has been investigated. Storage of samples at -70 degrees C by this method resulted in samples that accumulated less [3H]5-HT but showed an increased sensitivity to the Ca2+-dependent releasing properties of K+ when compared with "fresh" samples. On the other hand, the sensitivity of the K+-evoked release to the inhibitory effects of the serotoninergic agonist 5-methoxy-N,N-dimethyltryptamine were reduced by storage. The effects on [3H]5-HT accumulation and on K+-evoked release were due mainly to the freeze-thaw procedure, the length of storage at -70 degrees C having only a minor influence on these parameters. A post-mortem interval of 5 hours at either +4 or +22 degrees C prior to storage of the tissue reduced the K+-evoked release of tritium, but did not affect the accumulation of [3H]5-HT or the inhibitory effects of 5-methoxy-N,N-dimethyltryptamine on the K+-evoked release over and above the effects produced by the storage per se.

High affinity [3H]paroxetine binding to serotonin uptake sites in human brain tissue

[3H]Paroxetine binding to human brain tissue was characterized. Competition studies in the putamen and frontal cortex revealed single-site binding models for binding sensitive to 5-hydroxytryptamine (5-HT) (Ki 1-3 microM) and citalopram (Ki 0.6 nM), which displaced the same amount of binding. However, desipramine, norzimeldine and fluoxetine displaced additional binding (10-20%) and these competitors fitted two-site binding models with high affinity components in the nanomolar range and low affinity components in the micromolar range. The high affinity components approximated the 5-HT- and citalopram-sensitive binding fraction. Most of the [3H]paroxetine binding sites were protease-sensitive, but the low-affinity (microM) sites appeared to be protease-resistant. Based on these findings, only the [3H]paroxetine binding representing the fraction sensitive to 30 microM 5-HT (or e.g. 0.3 microM norzimeldine), was regarded as specific binding. This binding fraction was saturable with an apparent binding affinity (Kd) of 0.03-0.05 nM throughout the brain. The highest binding densities were obtained in the hypothalamus and substantia nigra (Bmax 500 fmol/mg protein). The basal ganglia reached intermediate densities (Bmax 200 fmol/mg protein), whereas cortical areas had low Bmax values (less than 100 fmol/mg protein). The lowest B max value was noted in cerebellar cortex (30 fmol/mg protein). The [3H]paroxetine binding was competitively inhibited by low concentrations of 5-HT, imipramine and norzimeldine, suggesting that the substrate recognition site for 5-HT uptake was labeled. Compounds active at dopaminergic, noradrenergic, histaminergic, 5-HT1, 5-HT2 and cholinergic muscarinic sites did not affect the binding at 100 microM concentrations. It is concluded that [3H]paroxetine is a marker for the 5-HT uptake site in the human brain, provided that an adequate pharmacological definition of specific binding is performed.

[3H]GBR 12935 binding to dopamine uptake sites: subcellular localization and reduction in Parkinson's disease and progressive supranuclear palsy

[3H]GBR 12935 bound with high affinity to dopamine uptake sites in rat striatum where a close parallelism was observed between the subcellular localization profiles for [3H]dopamine uptake and [3H]GBR 12935 specific binding. Using the same ligand, we characterized the dopamine uptake sites in human striatum: the mean KD value was 3.2 nM and the specific binding was inhibited by several dopamine uptake blockers but with slightly lower affinities than those observed in the rat. The subcellular localization profile revealed a synaptosomal enrichment of the specific binding in human striatum. [3H]GBR 12935 binding was decreased in the putamen and caudate nucleus of subjects with Parkinson's disease (33 and 46% of control values, respectively) and progressive supranuclear palsy (38 and 57% of control values, respectively). It is very unlikely that the remaining binding sites in both diseases correspond to piperazine acceptor sites that are not involved in dopamine uptake. However, we cannot exclude the possibility that some of these remaining dopamine transporter sites are not functional, since the reduction in [3H]GBR 12935 specific binding was less marked than the decrease in the dopamine content of the same areas.

A comparison of methodologies for the study of functional transmitter neurochemistry in human brain

A number of different approaches to the study of functional neurochemistry in human brain are discussed. The advantages and disadvantages of three main techniques are contrasted: (i) using animal tissue preparations as models of the human brain; (ii) using human peripheral tissue preparations as models of dynamic CNS processes; and (iii) studying human tissue, obtained postmortem, directly. Animal models are often readily obtained and reliable, and the high degree of inbreeding of common laboratory animals ensures that they usually yield consistent results. However, there are a number of human disorders for which animal models are either poor or unavailable, and species differences make extrapolation from the animal to the human case difficult. Human peripheral tissue models rely on a degree of homology between peripheral and CNS processes; in most cases, the evidence for such homologies derives from animal, rather than human, studies. Moreover, several examples are known where a peripheral process mimics the equivalent glial cell activity more closely than the neuronal, which can be a serious drawback for studies of neurotransmission. The use of postmortem human brain tissue presents a number of obvious difficulties, resulting from variations in the patient's age, agonal state, sex, preterminal medication, postmortem delay, etc. Human beings are genetically and nutritionally heterogeneous, so that data variability is usually greater here than when using tissue from laboratory animals. However, it is possible to control for a number of these factors, for example, by matching samples for basal metabolic rate and tissue integrity, and recently developed tissue freezing and storage techniques permit the use of within-subject experimental designs to help reduce experimental variation. A range of neurotransmitter functions are well retained in such tissue samples, so that regional variations, differential transmitter activities, drug effects, etc., can be studied in normal tissue samples, as well as in samples taken from cases of neurological and psychiatric disease. This allows, for example, changes in neuroanatomical indices to be correlated with localised alterations in a specific neurotransmitter function. A systematic approach to the analysis and matching of tissue samples is advocated. The three approaches should be considered to be complementary, especially for the study of human brain diseases.

A disorder of cortical GABAergic innervation in Alzheimer's disease

Synaptosomal gamma-aminobutyric acid (GABA) uptake has been used as a biochemical marker for GABAergic terminals in controls and Alzheimer disease brains. Use of this marker suggests a large (ca. 70%) loss of cortical and hippocampal GABA terminals in Alzheimer brain. To explain this observation we suggest that neuron loss in this disorder occurs via a process of cortical retrograde degeneration. This scheme reconciles our findings with previous neurochemical measurements on Alzheimer disease brains and also better reconciles the biochemistry with the histology of the disorder.

Region-specific loss of glutamate innervation in Alzheimer's disease

Synaptosomal D-aspartate has been used as a marker for glutamate neurons in control and in postmortem Alzheimer's disease brains. This technique shows a marked (60%) decrease of the glutamate uptake site in cortical and hippocampal regions. There were no significant changes in subcortical regions. We interpret these results as indicating loss of, or damage to, cortical glutamatergic innervation. These losses probably represent the biochemical correlate of pyramidal neuron damage in Alzheimer's disease.