Effects of Hypoxia on the Activities of Noradrenergic and Dopaminergic Neurons in the Rat Brain

The effects of hypoxia (10% O2, 90% N2) on the content, biosynthesis, and turnover of noradrenaline (NA) and 3,4-dihydroxyphenylethylamine (dopamine, DA) in the rat brain were examined. Up to 24 h following exposure to hypoxia, NA content in the whole brain was decreased, whereas DA content remained unchanged. The accumulation of 3,4-dihydroxyphenylalanine (DOPA) after central decarboxylase inhibition was decreased. The turnover rate of DA after synthesis inhibition was markedly decreased up to 8 h and returned to the control level within 24 h. In contrast, the turnover rate of NA was all but unchanged, except for a 4-h exposure. The 2-h exposure to the hypoxic environment resulted in a significant decrease in NA content and DOPA accumulation in all brain regions tested, but no significant change was observed in DA content. The turnover rate of DA was remarkably decreased in all brain regions tested, whereas the rate of NA was slightly decreased only in the cerebral cortex and hippocampus. These results suggest that although hypoxia decreases the biosynthesis of both NA and DA, the effects of oxygen depletion on the functional activities of NA neurons differ considerably from those of DA neurons: Only in the cerebral cortex and hippocampus are the NA neurons slightly sensitive to hypoxia, whereas the DA neurons are most sensitive in all brain regions.     

Release of ( 3 H)noradrenaline and ( 3 H)dopamine from field stimulated cerebral cortex slices. Effect of tyrosine hydroxylase and dopamine- -hydroxylase inhibition

Rat cerebral cortex slices were incubated in vitro with [³H]dopamine (DA) or [³H]noradrenaline (NA) (10^?7M), superfused by fresh buffer and stimulated by an electric field. The stimulation-induced overflow of [³H]DA and [³H]NA was determined. In slices from untreated rats about 16 ng [³H]NA/g tissue was formed from [³H]DA, corresponding to about 5 per cent of the endogenous NA concentration. Stimulation markedly enhanced the overflow of [³H]NA. The [³H]NA newly formed from [³H]DA was overflowing to a greater extent than [³H]NA previously taken up from the incubation medium, indicating a preferential release of newly synthesized transmitter. The stimulation-induced overflow of [³H]DA and [³H]NA was increased in slices of rats pretreated with a tyrosine hydroxylase inhibitor (H44/68). It seems that depletion of the endogenous NA stores of central NA neurons by tyrosine hydroxylase inhibition makes the [³H]cate-cholamines more available for release. Pretreatment of the rats with the DA-β-hydroxylase inhibitors FLA63 or FLA69 considerably diminished the formation of [³H]NA from [³H]DA. Stimulation markedly enhanced the overflow of [³H]DA indicating that DA can act as a ‘false transmitter’ in central NA neurons after DA-β-hydroxylase inhibition.     

Effect of L-Dopa on the Locomotor Activity of Rats pretreated with 6-Hydroxydopamine

LARGE doses of 3,4-dihydroxyphenylalanine (dopa) cause increased locomotor activity in rats and mice pretreated with a peripherally acting decarboxylase inhibitor^1–3. The effect of dopa is enhanced in animals pretreated with a mono-amine oxidase inhibitor^4–7 and reduced when the decarboxylation of dopa in the brain is inhibited¹. Consequently, the increase in motor activity is thought to be due to the formation of catecholamines in the brain.     

Amphetamine Response in Rat after Dopamine Neurone Destruction

AMPHETAMINE increases spontaneous locomotor activity and induces stereotyped motor responses in rats. The magnitude of these two behavioural responses varies according to the dose and which optical isomer of the drug is used^1,2. Amphetamine is known to influence the uptake and release of catecholamines in the brain both in vitro³ and in vivo^4,5 and the finding that inhibition of catecholamine synthesis by α methyl-p-tyrosine abolishes the behavioural effect of the drug^6,7 suggests that a release of catecholamines may mediate these effects. The amine transmitters noradrenaline (NA) and dopamine (DA) are localized in different anatomical systems in the brain^8,9 and attempts have been made to correlate the specific behavioural effects of amphetamine with one or other of these aminergic systems. Taylor and Snyder, on the basis of comparisons of the potency of d- and l-amphetamine in behavioural and biochemical tests, suggested that a release of NA mediates the locomotor activity and DA the stereotypy responses. We have attempted to pursue these hypotheses with lesions to aminergic pathways.     

Serotonin,dopamine, noradrenaline and their metabolites: Levels in the brain of the house cricket (Acheta domesticus L.) during a 24-hour period and after administration of quipazine—a 5-HT2 receptor agonist

1. The levels of 5-HT, DA, NA and DA metabolites (NADA, DOPAC) measured by HPLC (with electrochemical detection) in the brain of the house cricket did not change over a 24-hr period. The level of 5-HIAA, a 5-HT metabolite, was below the limit of detection.2. The 5-HT and DOPAC levels decreased and NADA increased after quipazine injection but DA and NA levels did not change after it.3. [³H]Ketanserin was used to identify serotonin receptors bound to sites in the house cricket brain with a K_d of 5 nM and a concentration of B_max 180 fmol/mg protein.     

ACCUMULATION AND DISAPPEARANCE OF NORADRENALINE AND ITS MAJOR METABOLITES SYNTHESIZED FROM INTRAVENTRICULARLY INJECTED [3H]DOPAMINE IN THE RAT BRAIN

Abstract— A new combined ion-exchange and thin-layer-chromatographic procedure is described which separates and measures quantitatively, after intraventricular injection of [³H]dopamine (DA), the rat brain content of labelled noradrenaline (NA) and the following labelled noradrenaline metabolites: free 3-methoxy-4-hydroxyphenylethyleneglycol (MOPEG), conjugated MOPEG, free plus conjugated dihydroxyphenylethyleneglycol (DOPEG), vanillic mandelic acid (VMA) and normetanephrine (NM). Labelled dopamine and its metabolites were also measured. The time-course study performed from 5 min to 24 h after [³H]DA showed that MOPEG and DOPEG, mainly as conjugates, are major NA metabolites whereas VMA is a very insignificant NA metabolite in the rat brain. A very rapid initial increase of [³H]NM, free MOPEG and conjugated MOPEG was found during the time interval where the [³H]NA biosynthesis is very high (0–15 min). This combined with the finding that these metabolites stabilize at lower levels during the [³H]NA ‘storage phase’ (9–24 h) provides a strong indication that newly synthesized NA preferentially is metabolized. Our measurements of endogenous NA, free MOPEG and conjugated MOPEG provide additional support. The injections of various decreasing doses of [³H]DA (3·08–0·0010 μg) showed that the proportions of total [³H]MOPEG and total [³H]DOPEG to [³H]NA were constant after all [³H]DA doses investigated. This finding indicates that the [³H]NA synthesized in situ behaves as a tracer, even after injections of non-tracer doses of [³H]DA. The results seem thus to indicate that the present technique provides a powerful tool for the investigations on central noradrenaline metabolism.     

Histochemical demonstration of transmitter release from noradrenaline,dopamine and 5-hydroxytryptamine nerve terminals in field stimulated rat brain slices

Summary The effect of electrical field stimulation on noradrenaline (NA), dopamine (DA) and 5-hydroxytryptamine (5-HT) nerve terminals in rat brain slicesin vitro was investigated. Slices prepared from the cerebral cortex or the neostriatum were incubated in physiologic buffer for 30 min and then superfused by buffer and stimulated by an electrical field (biphasic pulses, 10 Hz, 12 mA, 2 ms) for various time periods. The effect of the stimulation was studied at the cellular level with the histochemical fluorescence technique of Falck and Hillarp. The transmitter overflow into the superfusing buffer caused by the stimulation was studied with isotope technique. Cerebral Cortex NA Nerve Terminals. Stimulation caused release of NA from cortical NA nerve terminals. Already after 2 min stimulation a slight decrease of the fluorescence intensity of the nerve terminals could be found. Stimulation for 15 to 30 min greatly reduced the fluorescence intensity. In slices preincubated with³H-NA the stimulation-induced overflow of tritium during 2 min stimulation was about 15% (i.e. 15% of the tissue tritium content was overflowing into the superfusing buffer in response to stimulation for 2 min). During prolonged stimulation there was a considerable decline of the tritium efflux. Cerebral Cortex 5-HT Nerve Terminals. The 5-HT-analogue 6-hydroxytryptamine (6-HT) which is readily taken up into 5-HT nerve terminals was used to permit good visualization of these nerve terminals. Uptake of 6-HT into cortical NA nerve terminals was prevented by preincubation with 6-hydroxydopamine (6-OH-DA) or protriptyline. Stimulation for 15 to 30 min reduced the fluorescence intensity of the 5-HT nerve terminals. In slices preincubated with³H-5-HT the stimulation-induced overflow of tritium during 2 min stimulation was about 5%. The tritium efflux slowly decreased during continuous stimulation. Neostriatal DA Nerve Terminals. In slices frozen directly after preparation an intense diffuse fluorescence could be seen. After incubation in drug-free buffer at 37° C the fluorescence was localized in the varicosities of the DA nerve terminals. The central parts of the slices almost completely lacked specific fluorescence, while the outer zones were brightly fluorescent. No clear reduction of the fluorescence intensity of the DA nerve terminals in the outer zone could be observed after stimulation for 30 min. In slices preincubated with³H-DA the stimulation-induced overflow of tritium during 2 min stimulation was about 2%. The tritium efflux slowly decreased during continuous stimulation.It is suggested that the differences in release between the various nerve terminal systems foundin vitro reflect differences in transmitter release occurringin vivo. The comparably high release of NA per impulse from the cortical NA nerve terminals implicate that the discharge rate of these neuronsin vivo is very low.This investigation has been supported by grants from the Swedish Medical Research Council (B72-14X-2330-05A) and Magnus Bergwall's Foundation.The author is greatly indebted to Mrs. Annika Hamberger for her skillful technical assistance. For generous supplies of drugs thanks are due to Hässle, Göteborg, Sweden, through Dr. H. Corrodi (6-HT, 6-OH-DA and H44/68).     

Effects of acute handling stress on cerebral monoaminergic neurotransmitters in juvenile Senegalese sole Solea senegalensis

Juvenile Senegalese sole Solea senegalensis were subjected for short periods to two different types of handling‐related stress: air exposure stress and net handling stress. The S. senegalensis were sacrificed 2 and 24 h after the stress events and the levels of serotonin (5‐HT), noradrenaline (NA), dopamine (DA) and their respective major metabolites, 5‐hydroxyindoleacetic acid (5‐HIAA), 3‐methoxy‐4‐hydroxyphenylglycol (MHPG) and 3,4‐dihydroxyphenylacetic acid (DOPAC), were measured in three brain regions (telencephalon, hypothalamus and optic tectum) and compared with those in control, non‐stressed S. senegalensis. Neither type of stress caused any significant alteration of serotoninergic activity (5‐HIAA:5‐HT ratio) or NA levels. Dopaminergic activity (DOPAC:DA ratio) was lower in stressed fish in all of the brain regions studied. For both air exposure stress and net handling stress, DA levels were significantly higher (P < 0·05) than in the control S. senegalensis. In addition, the higher DA levels after net handling stress were always significantly higher (P < 0·05) than those observed after acute air exposure stress, except in the telencephalon after 24 h. The significantly lower DOPAC:DA ratio (P < 0·05) in all of the brain regions studied was only observed in response to net handling stress.     

Tissue catecholamine concentrations in spontaneously hypertensive rats

Tissue concentrations of noradrenaline (NA), dopamine (DA) and adrenaline (A) were compared in spontaneously hypertensive (SHR) and normotensive (NCR) rats, aged 1, 3, 8, 14 and 24 weeks The organs analyzed included the brain, subdivided into prosencephalon and rhombencephalon, heart, adrenal glands and kidney. Brain catecholamines were significantly lower in SHR than in NCR, and the difference appeared already at the age of 3 weeks. Concomitant increase was found in the adrenal NA and A concentrations of the SHR. Concentration of NA in the heart decreased in the SHR following onset of hypertension. It is concluded that the diminished NA, DA and A concentrations in the brain as well as the augmented adrenal NA and A levels in the SHR may be causally related to the development of hypertension, while the heart NA level reflects the secondary, hypertension -- related changes.     

Long term effect of lithium on brain regional catecholamine metabolism

Administration of LiCl (2-4 mmol/kg/day, po) to adult male albino rats for 7 consecutive days increased the catabolism of dopamine (DA) in striatum (ST) and noradrenaline (NA) in hypothalamus (H). Extension of the period of treatment with LiCl (2-4 mmol/kg/day, po) to 14 consecutive days increased catabolism of DA in CX (cerebral cortex) and PM (pons-medulla) and NA in H, and decreased metabolism of DA in ST and NA in PM. Further prolongation of treatment with LiCl (2 or 4 mmol/kg/day, po) for 21 consecutive days greatly affected DA and NA metabolism in the respective brain regions. These results, thus suggest that LiCl produces region specific differential action depending on its dosage and duration of treatment in catecholaminergic activity in rat brain.     

Effect of corticosterone on noradrenergic nuclei in the pons-medulla and [3H]NA release from terminals in hippocampal slices

The aim of the present study was to investigate possible membrane and genomic effects of corticosterone on the noradrenergic system of the rat brain. Corticosterone effects were studied in vivo by treating rats s.c. with 10 mg/kg corticosterone for 7 or 14 days. In the first two experiments corticosterone significantly decreased th noradrenaline (NA) and dopamine (DA) levels in the pons-medulla, an area which contains the A1-A7 noradrenergic cell groups, while the NA and DA levels in the dorsal hippocampus remained unchanged. In a third experiment where the locus coeruleus (LC) and the A1 and A2 nuclei (A1,A2) were analysed separately, NA levels were unchanged but total MHPG levels and the total MHPG/NA ratio were decreased in the A1,A2 area. Chronic corticosterone treatment (14 days) did not alter the ₂-adrenoceptor-mediated modulation of [³H]NA release from dorsal hippocampal slices. Neither the spontaneous outflow nor the electrically stimulated release of [³H]NA from dorsal hippocampal slices of untreated rats was affected by exposure of the slices to corticosterone (10^–7 M–10^–4 M) in the superfusion buffer. Thus, chronic corticosterone treatment of rats altered the noradrenergic system of the pons-medulla, but did not change the ₂-adrenoceptor-mediated modulation of NA release in the dorsal hippocampus, a major terminal area of the LC neurons. Corticosterone also did not appear to have a direct membrane effect on the NA terminals in the dorsal hippocampus of the rat.     

On the uptake of exogenous catecholamines by adrenal chromaffin cells and nerve endings

Summary Light-microscopic autoradiography has revealed characteristic labelling patterns in adrenal medullary cells following the intravenous administration of different catecholamines. The uptake patterns for [³H] dopa, [³H] dopamine, [³H] noradrenaline and [³H] adrenaline have been compared. In all cases A cells were more active than NA cells and cells situated in the zone nearest the cortex demonstrated a markedly higher rate of uptake than central cells. It was concluded that adjacent chromaffin cells with very similar morphology may differ as much as 50 fold in their capacities to incorporate exogenous amines. The adrenergic nature of the innervation of the vessels of the adrenal cortex and capsule in the mouse was confirmed.     

Roles Played by the Na+/Ca2+ Exchanger and Hypothermia in the Prevention of Ischemia-Induced Carrier-Mediated Efflux of Catecholamines into the Extracellular Space: Implications for Stroke Therapy

The release of [³H]dopamine ([³H]DA) and [³H]noradrenaline ([³H]NA) in acutely perfused rat striatal and cortical slice preparations was measured at 37 °C and 17 °C under ischemic conditions. The ischemia was simulated by the removal of oxygen and glucose from the Krebs solution. At 37 °C, resting release rates in response to ischemia were increased; in contrast, at 17 °C, resting release rates were significantly reduced, or resting release was completely prevented. The removal of extracellular Ca²⁺ further increased the release rates of [³H]DA and [³H]NA induced by ischemic conditions. This finding indicated that the Na⁺/Ca²⁺ exchanger (NCX), working in reverse in the absence of extracellular Ca²⁺, fails to trigger the influx of Ca²⁺ in exchange for Na⁺ and fails to counteract ischemia by further increasing the intracellular Na⁺ concentration ([Na⁺]_i). KB-R7943, an inhibitor of NCX, significantly reduced the cytoplasmic resting release rate of catecholamines under ischemic conditions and under conditions where Ca²⁺ was removed. Hypothermia inhibited the excessive release of [³H]DA in response to ischemia, even in the absence of Ca²⁺. These findings further indicate that the NCX plays an important role in maintaining a high [Na⁺]_i, a condition that may lead to the reversal of monoamine transporter functions; this effect consequently leads to the excessive cytoplasmic tonic release of monoamines and the reversal of the NCX. Using HPLC combined with scintillation spectrometry, hypothermia, which enhances the stimulation-evoked release of DA, was found to inhibit the efflux of toxic DA metabolites, such as 3,4-dihydroxyphenylacetaldehyde (DOPAL). In slices prepared from human cortical brain tissue removed during elective neurosurgery, the uptake and release values for [³H]NA did not differ from those measured at 37 °C in slices that were previously maintained under hypoxic conditions at 8 °C for 20 h. This result indicates that hypothermia preserves the functions of the transport and release mechanisms, even under hypoxic conditions. Oxidative stress (H₂O₂), a mediator of ischemic brain injury enhanced the striatal resting release of [³H]DA and its toxic metabolites (DOPAL, quinone). The study supports our earlier findings that during ischemia transmitters are released from the cytoplasm. In addition, the major findings of this study that hypothermia of brain slice preparations prevents the extracellular calcium concentration ([Ca²⁺]_o)-independent non-vesicular transmitter release induced by ischemic insults, inhibiting Na⁺/Cl^?-dependent membrane transport of monoamines and their toxic metabolites into the extracellular space, where they can exert toxic effects.

     

Regional distribution of monoamines in the nucleus accumbens of the rat

Monoamine concentrations were low in the rostral area of the nucleus accumbens. Their distributions were not identical. Differences were observed in the medial area. DA concentrations were high in both medial and caudal areas. Noradrenaline (NA) and serotonin (5-HT) concentrations were considerably lower than the dopamine (DA) concentration. The NA concentration was highest in the caudal area of the nucleus accumbens and the (5-HT) concentration was highest in the ventrocaudal area. There was a rostrocaudal decrease in the 3,4-dihydroxyphenylacetic acid (DOPAC)/DA and 5-hydroxyindole-3-acetic acid (5-HIAA)/5-HT ratios. Uptake of [³H]DA and [¹⁴C]choline was lowest in the rostral area. The K⁺-stimulated release of [¹⁴C]acetylcholine (ACh) was also lowest rostrally, but there was no rostrocaudal difference in the K⁺-stimulated release of [³H]DA. These results provide further evidence of the heterogeneity of the nucleus accumbens.     

Dynamic Storage of Dopamine in Rat Brain Synaptic Vesicles In Vitro

Abstract: The dynamics of catecholamine storage were studied in highly purified, small synaptic vesicles from rat brain both during active uptake or after inhibiting uptake with reserpine, tetrabenazine, or removal of external dopamine. To assess turnover during active uptake, synaptic vesicles were allowed to accumulate [³H]dopamine ([³H]DA) for ～10 min and then diluted 20-fold into a solution containing unlabeled DA under conditions such that active uptake could continue. After dilution, [³H]DA was lost with single exponential kinetics at a half-time of ～4 min at 30°C in 8 mM Cl^? medium, in which both voltage and H⁺ gradients are present in the vesicles. In 90 mM Cl^? medium, in which high H⁺ and Cl^? gradients but no voltage gradient are present, [³H]DA escaped at a half-time of ～7 min. In both high and low Cl^? media, ～40% of [³H]DA efflux was blocked by reserpine or tetrabenazine. The residual efflux also followed first-order kinetics. These results indicate that two efflux pathways were present, one dependent on DA uptake (and thus on the presence of external DA) and the other independent of uptake, and that both pathways function regardless of the type of electrochemical H⁺ gradient in the vesicles. The presence of both uptake-dependent and -independent efflux was observed in experiments using DA-free medium, instead of uptake inhibitors, to prevent uptake. Uptake-independent efflux showed molecular selectivity for catecholamines; [¹⁴C]DA was lost about three times faster than [³H]norepinephrine after adding tetrabenazine directly (without dilution) to vesicles that had taken up comparable amounts of each amine. In addition, the first-order rate constant for uptake-independent efflux showed little change over a 60-fold range of internal DA concentrations, which suggests that this pathway had a high transport capacity. All efflux was blocked at 0°C, suggesting that efflux did not occur through a large pore. There was little or no change in the proton gradient in synaptic vesicles, monitored by [¹⁴C]methylamine equilibration, during the experimental manipulations used here. Thus, the driving force for catecholamine uptake remained approximately constant. The physiological role of uptake-independent efflux could be to allow the monoamine content of synaptic vesicles to be regulated over a time range of minutes and, thereby, control the amount released by exocytosis. These results imply that catecholamines turn over with a half-time of minutes during active uptake by brain synaptic vesicles in vitro.     

EFFECTS OF 6-HYDROXYDOPAMINE ON CATECHOLAMINE CONTAINING NEURONES IN THE RAT BRAIN

After the intraventricular injection of 6-hydroxydopamine (6-OHDA), there was a long lasting reduction in the brain concentrations of noradrenaline (NA) and dopamine (DA). The brain concentration of NA was affected by lower doses of 6-OHDA than were required to deplete DA. A high dose of 6-OHDA which depleted the brain of NA and DA by 81 per cent and 66 per cent respectively, had no significant effect on brain concentrations of 5-hydroxytryptamine (5-HT) or γ-aminobutyric acid (GABA). The fall in catecholamines was accompanied by a long lasting reduction in the activities of tyrosine hydroxylase and DOPA decarboxylase in the hypothalamus and striatum, areas in the brain which are rich in catecholamine containing nerve endings. There was, however, no consistent effect on catechol-O-methyl transferase or monamine oxidase activity in these brain regions. The initial accumulation of [³H]NA into slices of the hypothalamus and striatum was markedly reduced 22–30 days after 6-OHDA treatment. These results are consistent with the evidence in the peripheral sympathetic nervous system that 6-OHDA causes a selective destruction of adrenergic nerve endings and suggest that this compound may have a similar destructive effect on catecholamine neurones in the CNS.     

Effects of Substantia Nigra Lesions on the Locomotor and Stereotypy Responses to Amphetamine

IT is usually supposed that amphetamine produces behavioural effects which include an increase of spontaneous motor activity and the elicitation of stereotyped behaviours¹, by causing a release of endogenous catecholamines in the central nervous system². This view is, for example, supported by the observation that amphetamine can release the catecholamines noradrenaline (NA) and dopamine (DA) from the central nervous system in vitro² and in vivo^{3, 4} and that inhibition of catecholamine biosynthesis blocks the amphetamine effect⁵. Anatomical studies of the distribution of neurones containing catecholamine however, raise, questions about the general applicability of this hypothesis⁶.     

Selective Lesions by Manganese and Extensive Damage by Iron After Injection into Rat Striatum or Hippocampus

Abstract: Regional ⁴⁵Ca²⁺ accumulation and analysis of monoamines and metabolites in dissected tissues were used to localize, quantify, and characterize brain damage after intracerebral injections of Mn²⁺ into striatum and hippocampus. The specificity of Mn²⁺-induced lesions is described in relation to brain damage produced by local Fe²⁺or 6-hydroxydopamine (6-OHDA) injections. In striatum, Fe²⁺ and Mn²⁺ produced dose-dependent (0.05-0.8 μmol) dopamine (DA) depletion, with Fe²⁺ being 3.4 times more potent than Mn²⁺. Studies examining the time course of changes in monoamine levels in striatum following local application of 0.4 μmol of Mn²⁺ revealed maximal depletion of all substances investigated (except 5-hydroxyin-doleacetic acid) after 3 days. The effects on DA (87% depletion at day 3) and its major metabolites were most pronounced and lasted until at least 90 days (40% depletion), whereas serotonin and noradrenaline levels recovered within 21 and 42 days, respectively. In addition, levels of 3-methoxytyramine, which is used as an index of DA release, also recovered within 42 days, indicating a functional restoration of DA neurotransmission despite substantial loss of DA content. Intrastriatal Mn²⁺ (0.4 μmol) produced time-dependent ⁴⁵Ca²⁺ accumulation in striatum, globus pallidus, entopeduncular nucleus, several thalamic nuclei, and substantia nigra pars reticulata ipsilateral to the injection site. In contrast, 6-OHDA injected at a dose equipotent in depleting DA produced significantly less ⁴⁵Ca²⁺ accumulation in striatum and globus pallidus and no labeling of other brain areas, whereas Fe²⁺ (0.4 μmol) produced extensive ⁴⁵Ca²⁺ accumulation throughout basal ganglia, accumbens, and cerebral cortex. In hippocampus, high Mn²⁺ (0.4 μmol) produced limited ⁴⁵Ca²⁺ accumulation in subiculum and dentate gyrus, whereas low Fe²⁺ (0.1 μmol) produced widespread ⁴⁵Ca²⁺ accumulation throughout hippocampus, thalamus, and cerebral cortex. It is concluded that (a) Mn²⁺ is selectively neurotoxic to pathways intrinsic to the basal ganglia, (b) intrastriatal injections can be used as a model for systemic Mn²⁺ intoxications, and (c) high endogenous Fe³⁺ and/or catecholamine levels potentiate the neurotoxicity of Mn²⁺.     

Effect of 1-methyl-4-phenyl-1,2,3,6 tetrahydropyridine (MPTP) on monoamine neurotransmitters in mouse brain & heart

The effect of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) was studied on dopamine (DA), norepinephrine (NE), serotonin (5HT) and γ-aminobutyric acid (GABA) neurons in mouse brain and on NE neurons of mouse heart. MPTP (45 mg/kg) was administered s.c. to mice twice daily for 2 consecutive days. This dosage regimen produced a decrease in the forebrain concentrations of DA and NE at 7 and 20 days after injection. In contrast, the forebrain concentrations of 5HT and GABA were not significantly decreased at either time. MPTP administration also produced a marked decrease in the uptake of ³H-DA into striatal slices and ³H-NE into cerebral cortical slices. In contrast, the uptake of ³H-NE into hypothalamic slices and the uptake of ³H-5HT into slices from several brain regions were not altered. MPTP initially reduced the concentration of NE in the heart, but unlike the persistent decreases in the forebrain concentrations of NE and DA, the NE concentration in the heart returned to control levels at approximately 20 days after MPTP administration. These results, showing that MPTP can produce a long lasting and selective decrease in the forebrain concentrations of NE and DA and in the uptake of radioactive DA and NE into brain slices, suggest that MPTP can cause the destruction of catecholamine neurons in mouse brain. In contrast, MPTP administration does not appear to produce long term changes in either 5HT or GABA neurons.     

Differential effects of experimentally induced blood pressure changes on the release of catecholamines in hypothalamic and limbic areas of rats

The effects of longer lasting blood pressure changes on the release of endogenous catecholamines (CA) in limbic and hypothalamic areas were studied in anaesthetized rats. For this purpose the central nucleus of the amygdala (AC), ventral hippocampus (VH) and medial hypothalamus (MH) were simultaneously superfused through push-pull cannulae with artificial cerebrospinal fluid and the release of the endogenous catecholamines dopamine (DA), noradrenaline (NA) and adrenaline (A) was determined before and after blood pressure manipulations. A fall in blood pressure elicited by the ganglionic blocking agent chlorisondamine resulted in different changes of the various CA release patterns in AC. Short lasting increased CA release rates as compared to prehypotension levels could be observed in the hippocampus. The activity of catecholaminergic neurons in MH remained unchanged. A rise in arterial blood pressure induced by intravenous injection of tramazoline did not change the release rates of DA in all 3 brain areas studied. In hippocampus, NA levels in the superfusates decreased initially during hypertension but returned to normal values 40 min after drug injection. In the late phase of hypertension increased rates of release of NA in the amygdala and of A in the hypothalamus could be observed. The different patterns in the release of CA suggest that DA, NA and A are differentially implicated in the regulation of experimentally induced blood pressure changes.