Amine accumulation in behavioural pathology

Recovery of experimental Parkinson's disease with the melatonin analogues ML-23 and S-20928 in a chronic, bilateral 6-OHDA model: a new mechanism involving antagonism of the melatonin receptor

Over the past 10 years, there has been a resurgence of interest in examining the role of melatonin in health and disease. While the brunt of research in this area has portrayed melatonin in a favorable light, there is a growing body of evidence suggesting that melatonin may possess adverse effects contributing to the development of various neuropsychiatric disease states. In preclinical models of Parkinson's disease (PD), melatonin has been shown to enhance the severity of this condition while its antagonism, using constant light or pinealectomy, facilitates recovery. To test this hypothesis further, the present study employed the melatonin analogues ML-23 and S-20928 in a post-6-OHDA injection regime to determine whether they may have a favorable effect on the symptoms of this more chronic model of PD. When ML-23 was injected I.P. in a dose of 3 mg/kg twice daily for 3.5 days after 6-OHDA, significant improvement in motor function and regulatory deficits was observed. Similarly, the injection of S-20928 in a 1 mg/kg dose (I.P.), in the same regimen, facilitated modest improvement in motor function and regulatory deficits while the larger dose enhanced the severity of behavioural deficits and produced severe side effects causing deterioration in condition during the course of drug administration. ML-23 administration totally abolished the 6-OHDA-induced mortality, which accompanies dopamine (DA) degeneration, while S-20928 had no effect on this parameter. These results suggest that some melatonin analogues can aid in recovery from DA depleting lesions after DA degeneration has commenced and the recovery is not attributable to the antioxidative properties of this hormone. While the exact mechanism by which ML-23 and S-20928 are exerting their therapeutic effect is unclear, it is possible that antagonism of melatonin receptors may play some role and this should be considered when assessing the potential of melatonin analogues for treatment of human neuropsychiatric disorders.

Orphan neurones and amine excess: the functional neuropathology of Parkinsonism and neuropsychiatric disease

The aetiology and treatment of Parkinsonism is currently conceptualised within a dopamine (DA) deficiency-repletion framework. Loss of striatal DA is thought to cause motor impairment of which tremor, bradykinaesia and rigidity are prominent features. Repletion of deficient DA should at least minimise parkinsonian signs and symptoms. In Section 2, based on extensive pre-clinical and clinical findings, the instability of this approach to Parkinsonism is scrutinised as the existing negative findings challenging the DA deficiency hypothesis are reviewed and reinterpreted. In Section 3 it is suggested that Parkinsonism is due to a DA excess far from the striatum in the area of the posterior lateral hypothalamus (PLH) and the substantia nigra (SN). This unique area, around the diencephalon/mesencephalon border (DCMCB), is packed with many ascending and descending fibres which undergo functional transformation during degeneration, collectively labelled 'orphan neurones'. These malformed cells remain functional resulting in pathological release of transmitter and perpetual neurotoxicity. Orphan neurone formation is commonly observed in the PLH of animals and in man exhibiting Parkinsonism. The mechanism by which orphan neurones impair motor function is analogous to that seen in the diseased human heart. From this perspective, to conceptualise orphan neurones at the DCMCB as 'Time bombs in the brain' is neither fanciful nor unrealistic [E.M. Stricker, M.J. Zigmond, Comments on effects of nigro-striatal dopamine lesions, Appetite 5 (1984) 266-267] as the DA excess phenomenon demands a different therapeutic approach for the management of Parkinsonism. In Section 4 the focus is on this novel concept of treatment strategies by concentrating on non-invasive, pharmacological and surgical modification of functional orphan neurones as they affect adjacent systems. The Orphan neurone/DA excess hypothesis permits a more comprehensive and defendable interpretation of the interrelationship between Parkinsonism and schizophrenia and other related disorders.

Inhibition of long-term potentiation development in rat hippocampal slice by alpha 2-macroglobulin, an acute-phase protein in the brain

Alpha-2-macroglobulin (alpha 2M) in the rat and human brain is an acute-phase protein synthesized primarily by astrocytes, and it has been implicated in Alzheimer's disease and other neuropathological processes. The activated forms of alpha 2M, but not the native form, can suppress the neurite outgrowth of the central neurons, presumably through binding to neurotrophic factors and through direct inhibition of neurotrophic factor receptor signal transduction. Since neurotrophic factors are known to be involved in synaptic plasticity, we tested the effect of both the native and methylamine-activated (MA-alpha 2M) forms of alpha 2M on long-term potentiation (LTP) in area CA1 of adult rat hippocampal slice. Neither native alpha 2M nor MA-alpha 2M had an effect on baseline synaptic transmission. LTP induced by 200-Hz trains in the presence of 1.4 microM or 0.14 microM native alpha 2M was indistinguishable from control LTP. Although the presence of MA-alpha 2M at the same concentrations did not interfere with LTP induction, the development and maintenance of potentiation was blocked in a concentration-dependent time course. Results of this study indicate that the accumulation and activation of alpha 2M with inflammatory neuropathologies such as Alzheimer's disease can inhibit synaptic plasticity, which might partly account for the memory deficits seen in these patients.

Amphetamine-induced rotational behavior in rats: relationship to hypothalamic and striatal degeneration

When lesions are placed unilaterally in the nigrostriatal system of experimental animals, rotational behavior occurs in response to peripheral administration of dopamine (DA) agonists. In spite of considerable evidence to the contrary, it is assumed that in order for this rotation to occur, an almost complete depletion of striatal DA must be achieved. To test this hypothesis further, 20 male Sprague-Dawley rats were injected unilaterally with 2 microL of 8 micrograms/microL of 6-hydroxydopamine (6-OHDA) via acute injection needles or chronically indwelling cannulae. Acute injection of 6-OHDA resulted in a rotation rate of 7.2 to 18.9 revolutions per minute in response to peripheral amphetamine injection (5 mg/Kg) while injection of 6-OHDA through chronically indwelling cannulae produced rotation ranging from 1.4 to 9.9 rotations per minute. Under the conditions of either method of injection, the animals displaying the most severe rotation still showed partial denervation of striatal DA as revealed by catecholamine fluorescence histochemistry. Conversely, numerous animals demonstrating very low rates of amphetamine-induced rotation often displayed a complete loss of striatal, accumbens, and olfactory tubercle catecholamine fluorescence. Moreover, large quantities of lateral hypothalamic amine accumulation were observed in rotating rats indicating that this neurochemical change may be of functional significance for rotational responses. The present results, when taken into consideration with previous work, indicate that the routine selection of rotating animals for pharmacological testing for potential antiParkinsonian medication or intracerebral grafting purely on the basis of their rotational behavior does not necessarily imply that complete striatal denervation has occurred. Moreover, these findings demonstrate that amine accumulation in the lateral hypothalamus of rotating animals with DA depleting lesions is an important phenomenon implicated in the expression of rotational behavior in animals and possibly in the pathophysiology of Parkinson's disease.

Amine accumulation: a possible precursor of Lewy body formation in Parkinson's disease

It is now well recognized that the hypothalamus is an important site of neuropathology in Parkinson's disease (PD). Lewy bodies, a marker of nerve cell degeneration and a pathological hallmark of PD, have been observed frequently in the hypothalamus of PD patients by Lewy (1923) and other investigators and confirmed by more recent systematic studies by Langston & Forno (1978). Both Lewy and Langston & Forno found a predilection of Lewy body formation in specific hypothalamic nuclei with the tuberomammillary, lateral, and posterior areas containing by far the highest average counts per nucleus. Selective vulnerability of the tuberomammillary, lateral, and posterior hypothalamic cell groups to degeneration has been observed also in aging, postencephalitic Parkinsonism, Alzheimer's disease, and schizophrenia. The susceptibility of these particular nuclei to degenerative changes including Lewy body formation is not presently understood nor are the mechanisms by which Lewy bodies are formed in PD and other CNS disorders. Accumulation of amines, a pathological process which follows degeneration of catecholamine-containing neurons in experimental animals, also occurs most frequently in the lateral and posterior hypothalamic areas. In the present communication we propose that in PD, amine accumulation may be a precursor to Lewy body formation and that the susceptibility of certain hypothalamic areas to Lewy body formation may be related to their propensity to accumulate amines. Furthermore, the frequent co-existence of Lewy bodies and Alzheimer's neurofibrillary tangles in the lateral and posterior hypothalamic nuclei suggest that they may share a common pathogenetic etiology. If confirmed, this hypothesis may provide an experimental model by which the formation of Lewy bodies and neurofibrillary tangles may be investigated.

Sensitivity of dopamine receptors in the lateral hypothalamus is altered in 6-hydroxydopamine treated rats

Amine accumulation is observed in the lateral hypothalamus (LH) after nigrostriatal neurons degenerate. It has been proposed that this accumulation is a source of amines which are released into the hypothalamus thereby affecting the function of adjacent aminergic receptors. To approximate this condition of continuous exposure of LH receptors to endogenous amines, dopamine (DA) was injected into the LH of rats once daily for 5 consecutive days. A control group received 4 daily injections of tartaric acid vehicle and then DA on day 5. Rats pretreated with DA showed severe impairment of open field performance and motor reflex control on day 5 when they were compared to control animals which received vehicle pretreatment. In a second study, the DA receptor antagonist haloperidol was injected into the area of amine accumulation in the LH to determine whether this might block amine release from areas of accumulation thereby to attenuate lesion-induced rotation. Haloperidol administered once daily for 4 out of 7 days, once daily for 7 days or via a continuous infusion for 7 days, all reduced d,l-amphetamine-induced turning to control levels. These results suggest that prolonged exposure of hypothalamic DA receptors alters their sensitivity to subsequent doses of DA and that amine released from areas of accumulation may be blocked by haloperidol to enhance behavioral recovery from DA depleting lesions. Moreover, these findings indicate that the hypothalamus participates in the behavioral effects induced by DA depleting lesions and highlight the importance of hypothalamic pathology in Parkinson's disease.

Amelioration of experimental parkinsonism by intrahypothalamic administration of haloperidol

Accumulation of amines in the degenerating axons of ascending catecholamine-containing neurons in the hypothalamus has been proposed as a site of function neurotransmitter release and may thereby participate in the development of motor impairment seen after central dopamine-depleting lesions. To test this hypothesis further the dopamine receptor antagonist haloperidol (1 microL of a 14 nmol solution) was injected directly into the lateral hypothalamus (LH) in 6 different injection regimes to determine whether amphetamine-induced turning could be attenuated with this treatment. The injection of haloperidol at 1 and 24 h (group 1), 24 h (group 2) or 6+ 7 d (group 3) after 6-hydroxydopamine (6-OHDA) did not modify amphetamine-induced turning. However, the injection of haloperidol at 1 h, 24 h, 7 d, and 8 d (group 4), days 1-7 (group 5), or gradual infusion (14 nmol/microliters/h) for 7 days (group 6) all reduced the 6-OHDA-induced turning to a level similar to that of controls. These results add further support to the contention that amines are released from the axons of degenerating neurones in the hypothalamus and that this phenomenon participates in the elicitation of behavioral impairment attributed solely to the loss of functional neurotransmitters from terminal fields. Furthermore, the data emphasize the importance of hypothalamic pathology in the development of Parkinsonism and suggest that intrahypothalamic administration of dopamine blocking agents might be useful in the treatment of Parkinsonism.

Factors in amphetamine-induced contralateral rotation in the unilateral 6-OHDA lesion rat model during the first-week postoperative: implications for neuropathology and neural grafting

Amphetamine induced ipsilateral rotation in rats with chronic unilateral 6-hydroxydopamine (6-OHDA) lesions is a widely accepted line of evidence supportive of dopaminergic mediation of amphetamine effects on motoric behavior. However, there is literature indicating that amphetamine induces contralateral rotation, in the early postoperative phase of a unilateral 6-OHDA lesion. In an attempt to reconcile these opposite amphetamine effects on rotation in terms of dopaminergic mechanisms, a series of 4 experiments were conducted. These studies showed that amphetamine reliably elicits contralateral rotation for up to 7 days postoperative but only ipsilateral rotation thereafter. The amphetamine induced contralateral rotation differed behaviorally in several respects from subsequent ipsilateral rotation induced by amphetamine. It was comparatively more intense; and, while onset of peak rotation was dose dependent, rate of rotation was independent of dose level (0.5, 1.0 and 2.5 mg/kg). Dopamine and dopamine metabolite analyses by HPLC-EC after 3 postoperative intervals (days 3, 6, and 9) indicated a progressive and severe depletion of striatal dopamine in conjunction with elevated dopamine turnover. Importantly, after 6 days postoperative, dopamine was reduced to less than 0.06% after intact hemisphere but yet, amphetamine (1.0 mg/kg) elicited contralateral rotation. It was proposed that amphetamine could release a small amount of dopamine present in a sparse number of residual degenerating terminals and this dopamine, unrestricted by reuptake, could widely access supersensitive dopamine receptors to elicit contralateral rotation. This possibility calls into question amphetamine tests for neural graft efficacy in animal models which use amphetamine induced contralateral rotation as the criterion response.

The brain and higher mental function

Critical evaluation of biological theories of psychiatric disorder requires an understanding of current concepts of higher mental function and its related biology. Both the nature of the topic and the rapidity of advances in the field make it difficult to obtain an updated synthesis. Part I of this paper attempts to provide that by reviewing current concepts of the mind/body relationship, emotion, arousal, attention, consciousness and motivation. Part II considers those concepts in relation to recent work on the structure and function of the reticular, limbic and anterior cerebral systems. It is concluded that the model of the limbic system as subserving emotional life could now perhaps be set aside in favour of the model of a core set of chemically identified neurons in the reticular system being necessary but not sufficient to subserve higher mental function whilst also subserving other integrating functions for which no mental terminology is required. The problem of developing an eclectic theory of higher mental function that will embrace these concepts is discussed.

Opposite effects of ibotenic acid and 6-hydroxydopamine lesions of the lateral hypothalamus on intracranial self-stimulation and stimulation-induced locomotion

The purpose of the present study was to test the respective roles of the intrinsic neurons and of the catecholaminergic fibers in two behaviors elicited by electrical stimulation of the lateral hypothalamus, intracranial self-stimulation and the increase in locomotor activity produced by noncontingent stimulation. One group of rats was unilaterally injected in the middle lateral hypothalamus with a dose of ibotenic acid known to significantly decrease self-stimulation (4 micrograms/0.5 microliter). Two other groups received, in the same area, an injection of a small dose of 6-hydroxydopamine (2 micrograms/0.5 microliter). The rats of one of these groups were pre-treated with desmethylimipramine. Two other groups of rats were respectively injected with the vehicle of each neurotoxin. Eight days later all rats were bilaterally implanted with stimulation electrodes, one in the lesioned area, the other in the contralateral region. Each electrode of each animal was tested first for self-stimulation, then for locomotor activation measured in the open field produced by non-contingent stimulation. Whatever the lesion or the behavior tested, the response of the lateral hypothalamus contralateral to the lesioned area was normal. Self-stimulation was disturbed only with stimulation of the lateral hypothalamus lesioned by ibotenic acid. Self-stimulation in the lateral hypothalamus lesioned by 6-hydroxydopamine was normal. However, a significant loss of noradrenaline in the hippocampus and of dopamine in the striatum was observed. Furthermore, the brains of two rats unilaterally injected with the usual dose of 6-hydroxydopamine were processed for tyrosine hydroxylase immunocytochemistry.(ABSTRACT TRUNCATED AT 250 WORDS)

Amine accumulation, catecholamine depletion and motor impairment in Macaca fasicularis and the C-57 black mouse after MPTP administration

1. Macaca fasicularis monkeys and C-57 black mice were injected with N-methyl-4-phenyl-1,2,3,6-tetrahydropyridine in different injection regimes. 2. The performance of monkeys on a rapid alternating movement task was measured before, during and after drug injection. 3. The open field performance of C-57 black mice was assessed 0.5hr, 24hr and 7 days after the completion of the injection regime. 4. Only the monkey receiving the 2mg/kg dose over 8 days displayed progressive akinesia and muscular rigidity. 5. Only a very slight impairment of motor function was seen in the C-57 black mice 0.5hr after injection. 6. Fluorescent histochemical analysis revealed that while striatal depletion was severe in monkeys and mice, accumulation of amines was seen only in the brain tissue of the severely impaired monkey. 7. Degeneration-associated increases in amines are important in the aetiology of Parkinsonian-like motor impairment produced by selective neurotoxins across different species.

The function of lateral hypothalamic catecholamine and endorphin systems in the control of motor performance

Morphine (1 or 10 micrograms in 1 microliter) or beta-endorphin (1 microgram in 1 microliter) were injected bilaterally into the posterior lateral hypothalamus of Sprague-Dawley rats to determine what effect they may have on motor performance. Severe reductions in open field performance and motor reflex control were observed after the injection of 1 microgram of beta-endorphin or morphine into this area. The injection of 10 micrograms of morphine into the same area was less effective in causing motor impairment. The central (32.7 micrograms in 1 microliter) and peripheral (2 mg/kg) injection of naloxone did not prevent the motor impairment observed after the injection of beta-endorphin or morphine. Pretreatment with 6-hydroxydopamine into the lateral hypothalamus in a multistage regime did not prevent the motor impairment observed after beta-endorphin or morphine injection. These results indicate that lateral hypothalamic participation in the control of motor function may not involve the ascending nigrostriatal and mesocortical dopamine systems and that endogenous opiate systems may function independently to influence motor performance.

MPTP, impairment of motor performance and amine accumulation in Macaca fascicularis

The selective neurotoxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) was injected (IV) into monkeys (Macaca fascicularis) in two different injection regimes. With the small dose regime, one monkey was injected with 0.25 mg/kg, every other day, over a 16 day period. In the large dose regime, another monkey was injected with 0.5 mg/kg every other day, over an 8 day period. While the time required for drug delivery was varied between animals, the total dose delivered was 2 mg/kg in both animals. Before, during and for 14 days after the course of drug administration both animals were assessed on several motor function tests. The animal receiving the small dose regime showed normal motor performance on all tests for the duration of the study, however, the monkey receiving the large dose regime displayed progressive akinesia, muscular rigidity, and aphagia. In fact, impairment was so severe that this animal had to be force fed and maintained with daily oral L-dopa. Fluorescent histochemical assessment of forebrain in both monkeys revealed that striatal tissue was totally devoid of fluorescence in both cases. Large, swollen axons in the internal capsule, hypothalamus and midbrain were visible only in the severely impaired animal. These results suggest that, as with other neurotoxins, degeneration associated increases in amines may be important in the aetiology of Parkinson-like motor impairment produced by selective neurotoxins.

Amine accumulation in Parkinson's disease and other disorders

Amine accumulation in the axons of degenerating, amine-containing neurones is a natural component of neurone death in many species, including man. While it is becoming increasingly clear that this phenomenon may have functional significance in animal models of Parkinson's Disease, its potential importance in the clinical syndrome has been pretermitted. There are several reasons for this. Failure to sample tissue which contains accumulated amines, the masking of accumulation by adjacent depleted tissues and the degradation of accumulated amines in post-mortem tissues from Parkinsonian brains could account for the low incidence of detection of accumulation in this disorder. Increased levels of amines have been detected in the brains of patients with other conditions including cerebral infarction, Alzheimer's Disease and Huntington's Chorea. These increases have been attributed previously to enhanced aminergic activity, rather than a stage in the degenerative process, as our hypothesis suggests. In addition to the potential importance of amine accumulation in the pathophysiology of various clinical syndromes, a more thorough investigation of this phenomenon in animal models would seem essential since they are used routinely to both describe the basic principles of dopamine function and to evaluate therapeutic possibilities in Parkinson's Disease.

Further studies on the neurochemical specificity of 6-hydroxydopamine as compared to radiofrequency lesions

Despite the large volume of literature during the past 15 years addressing the problem concerning the neurochemical specificity of 6-hydroxydopamine (6-OHDA), there is still disagreement over this issue. While some claim that the catecholamine-specific effects of this drug can be maximized by controlling the dose injected, others claim that all doses of 6-OHDA produce non-specific damage (NSD), thereby contraindicating its use in experimental paradigms. In the present study, we examined the degree of neurochemical specificity of 6-OHDA by comparing the volume of proximal accumulation to that of NSD, produced by 6-OHDA (2 microliter of 8 micrograms/microliter) or radiofrequency (RF) lesions (60 degrees C for 50 s and 45 degrees C for 30 s), placed in the medial forebrain bundle. The volume of NSD and accumulation produced by 6-OHDA was significantly less than that produced by large RF lesions which had a similar effect on the gross behaviour of albino rats. Smaller RF lesions produced similar volumes of NSD but less amine accumulation than did 6-OHDA, and did so without affecting normal behaviour. The ratio of NSD to accumulation in 6-OHDA treated rats was 3/1, while large and small RF lesions produced a NSD/accumulation ratio of 15/1. The present study introduces a novel method of determining the degree of neurochemical specificity which can be achieved with 6-OHDA and reveals that it is several magnitudes more neurochemically specific than RF lesions.

Histochemical, biochemical and behavioural consequences of MPTP treatment in C-57 black mice

The histochemical, biochemical and behavioural consequences of MPTP administration in C-57 black mice was assessed 0.5 h, 24 h and 7 days after the last injection of this drug administered daily for 10 days during a 12 day period (30 mg/kg/injection or vehicle). A slight but significant impairment of open field performance was observed at 0.5 h after the last injection of MPTP while a facilitation of locomotory behaviour was observed only in the 24 h post-injection group. Striatal dopamine levels were reduced to 14, 18 and 27% of control levels in the 0.5 h, 24 h and 7 day post-MPTP treated groups, respectively. Histochemical assessment was in agreement with the biochemical assay results in that all MPTP treated animals showed severe depletion of striatal terminal fields. Other terminal fields were occasionally affected by MPTP treatment and only rarely was any change in the fluorescence or morphology of nigral cell bodies seen. Accumulation of amines in the degenerating amine-containing axons which traverse the lateral hypothalamus was not seen in any of the MPTP treated animals. These results indicate that, in the C-57 black mouse, MPTP causes a depletion of striatal dopamine without causing nigral cell loss or axon swelling as is observed with other experimental treatments such as 6-hydroxydopamine. Consistent with this is the behavioural data, indicating that severe deficits in motor function which are associated with nigrostriatal cell loss were not seen.(ABSTRACT TRUNCATED AT 250 WORDS)

Central and peripheral proglumide administration and cholecystokinin-induced satiety

Peripheral (50 mg/ml) or central (50 micrograms/microliter) injections of proglumide were made into Sprague-Dawley rats which displayed satiety-like responses after the peripheral (100 micrograms/kg) or central (50 ng in 1 microliter) administration of cholecystokinin (CCK). The satiety produced by CCK injection into the lateral hypothalamus, area postraema and ventromedial hypothalamus was significantly reversed by proglumide injections into these areas during a 4 h food intake test. Peripheral injection of proglumide after central or peripheral CCK injection did not modify this type of CCK-induced satiety. Central proglumide injection produced a reliable decrease in water intake and this is compatible with previous findings which describe the stimulation of water intake after central gastrin administration. These results suggest that various central and peripheral mechanisms which are involved in the regulation of appetite may function independently as a 'failsafe' system.

The amine accumulation-producing capacity of 6-hydroxydopamine and its neurochemical specificity

There was considerable research during the 1970's addressing the problem of the neurospecificity of 6-hydroxydopamine (6-OHDA). Despite the numerous attempts to define the criteria governing the use of this drug in experimental paradigms, some believed that specific damage to catecholamine (CA)-containing neurones could be achieved only by controlling the dose injected, while others claimed that the neurotoxic effect that this drug had on non-CA systems was so severe that it contraindicated its use experimentally. The issue still remains unresolved. In the present study, we examined the degree of neurochemical specificity produced by 6-OHDA or radiofrequency (RF) lesions by comparing the quantity of amine accumulation to the amount of physical damage at the lesion site (termed non-specific damage, NSD) which each technique produced. The volume of NSD produced by 6-OHDA (2 microliter of 8 micrograms/ul) was significantly less than that produced by large RF lesions (60 degrees C for 50 sec) both of which has a similar effect on the regulation of short term body weight. Both types of lesions produced similar quantities of amine accumulation. Smaller RF lesions (45 degrees C for 30 sec) produced the same amount of NSD as did 6-OHDA but significantly less amine accumulation and had no effect on body weight regulation. The ratio of NSD to amine accumulation in 6-OHDA treated rats was 3/1 while large and small RF lesions produced a NSD/accumulation ratio of 15/1. The present results reveal that the neurochemical specificity of 6-OHDA is several magnitudes greater than with RF lesions, when using the criteria as defined in the present experiment.(ABSTRACT TRUNCATED AT 250 WORDS)