C. David Marsden

1-Methyl-4-phenyl-1,2,3,6-tetrahydropyridine-induced parkinsonism in the common marmoset.

The administration of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) (1-4 mg/kg i.p.) for 4 days induced dose-dependent parkinsonism in the common marmoset within 48 h. MPTP produced profound akinesia, rigidity of the trunk and limbs, postural abnormalities, loss of vocalization and, in some cases, postural tremor. In a single animal the administration of L-DOPA in conjunction with a peripheral decarboxylase inhibitor, reversed the parkinsonian symptoms. Subsequent biochemical analysis showed a profound loss of dopamine and [3H]dopamine uptake in the caudate-putamen, but no change in specific [3H]spiperone binding.

Tissue pH as an indicator of mRNA preservation in human post-mortem brain

The relationship between pH and mRNA preservation in post-mortem human brain was examined using in situ hybridization histochemistry and Northern hybridization with oligonucleotide probes in a large group of human subjects, including control and neuropathological cases. Tissue pH was found to correlate strongly with preservation of four mRNA species in three brain areas. Tissue with low pH, assumed to result from prolonged terminal hypoxia, contained reduced or absent mRNA, while tissue with higher pH was found to contain quantifiable amounts, the values for pathological brain samples being comparable to those for control material of similar pH. Measurement of tissue pH provides a simple means to screen post-mortem brain for mRNA preservation and is suggested as a means to match material in case-control studies of human neurodegenerative disease.

Stereotyped behaviour patterns and hyperactivity induced by amphetamine and apomorphine after discrete 6-hydroxydopamine lesions of extrapyramidal and mesolimbic nuclei

Changes in stereotyped sniffing, biting and hyperactivity induced by apomorphine and D-amphetamine in the rat were determined after bilateral 6-hydroxy-dopamine (6-OHDA) lesions (8-16 micron/4micron6) of the extrapyramidal caudate-putamen (CP) (anterior and centre), globus pallidus (GP) and substantia nigra (SN), the mesolimbic nucleus (ACB), tuberculum olfactorium (TUO) and central amygdaloid nucleus (ACE). Lesions were also induced in the medial forebrain bundle in the lateral hypothalamus (LH). The 6-OHDA lesions of the CP reduced amphetamine biting but not sniffing or hyperactivity. Centrally placed 6-OHDA failed to modify any response to apomorphine but anterior locations reduced apomorphine biting. Both lesion locations led to a 45-65% reduction in striatal dopamine (DA) content, but the anterior location also involved depletions of mesolimbic DA. 6-OHDA lesions of the GP reduced striatal DA by 62% but initially potentiated before reducing both apomorphine and amphetamine biting. These lesions also potentiated amphetamine hyperactivity but other parameters were unmodified. The LH and SN lesions reduced striatal and mesolimbic DA by 75-80% and potentiated apomorphine biting. The LH lesions reduced amphetamine biting and hyperactivity but the SN lesions initially potentiated these responses. 6-OHDA lesions of the ACB reduced the DA content of this nucleus by 72% but had little effect on the TUO: these lesions reduced the duration of amphetamine hyperactivity and potentiated apomorphine biting. In contrast, equally selective lesions of the TUO (80% DA depletion) enhanced the locomotor activity response to both apomorphine and amphetamine; apomorphine biting was also increased but other parameters were unmodified. Lesions of the ACE depleted amygdaloid DA by at least 80% and reduced or abolished apomorphine and amphetamine biting in the chronic stage. The results indicate that the sites for mediation of sterotyped sniffing, biting or hyperactivity are not the same for apomorphine and amphetamine, and that each behavioural state involves the functioning of more than one DA-containing area.

Different sites of action of electrical and magnetic stimulation of the human brain.

The latency of the surface recorded electromyographic response to either an electrical or magnetic stimulus applied to the scalp has been measured in the first dorsal interosseous and abductor pollicis brevis muscles of 3 subjects. In the contracting muscle the response latency to the magnetic stimulus was longer by 1.4-2.7 ms compared to the electrical stimulus. Poststimulus time histograms of the firing of single motor units of first dorsal interosseous muscle were studied in 4 subjects. The first period of increased probability of firing of the single motor units showed a similar latency difference (mean 2.8 ms) to the two modes of stimulation. It is concluded that the extra delay to magnetic stimulation is consumed in central motor pathways. This implies that the two modes of stimulation activate the brain at different sites. It is suggested that the magnetic stimulus excites the corticospinal neurones transynaptically, whereas the electrical stimulus excites these neurones directly.

The rotating rodent: a two component system?

The hypothesis that the rotating rat requires both nigro-striatal and mesolimbic dopaminergic components for activity has been tested. 6-Hydroxydopamine lesions were induced unilaterally in either or both the ascending nigrostriatal and mesolimbic dopamine pathway. In one group of rats the nucleus accumbens was destroyed bilaterally with electrolesions. Circling behaviour was only recorded when there was both an imbalance in striatal dopamine concentrations concomitant with stimulation of the limbic dopamine regions. Lesions of the mesolimbic dopamine pathway resulted in changes in drug-induced motor activity but postural asymmetry or circling behaviour was not observed. The results support the hypothesis that the rotating rodent requires two functional dopamine components: striatal dopamine imbalance causing a postural asymmetry and stimulation of mesolimbic dopamine systems providing a locomotor component. The relevance of these components in this animal model is discussed with reference to dopaminergic agonist and antagonist drugs.

Serotoninergic modulation of the dopamine response from the nucleus accumbens

The depletion of brain 5-hydroxytryptamine (5-HT) by electrolytic lesions of the midbrain raphC nuclei, or by synthesis inhibition, results in marked hyperactivity in the rat (Kostowski, Giacolone & others, 1968; Jacobs, Trimbach & others, 1975). This would suggest that 5-HT may normally participate in motor control by exerting a powerful inhibitory effect. The nature of the system or systems subjected to such a control is not known but catecholaminergic mechanisms have been shown to be essentially involved in the regulation of motor activities and some workers have suggested a possible relation between these controlling mechanisms and 5-HT function (Neil], Grant & Grossman, 1972; Costall & Naylor, 1974). A site for such an interaction is suggested by recent studies showing that a marked hyperactivity results from an increased dopaminergic activity within the nucleus accumbens (Pijnenburg, Honig & van Rossum, 1975; Costall & Naylor, 1975), and this nucleus is known to be innervated by serotoninergic as well as by dopaminergic neurons (Fuxe, 1965; Conrad, Leonard & Pfaff, 1974). Therefore, we investigated the possible role of the nucleus accumbens in the hypothesized dopaminergic/serotoninergic control of motor function. Bilateral stainless-steel guide cannulae (0.65 mm diameter) were chronically implanted, using stereo: taxic techniques, to allow the direct injection into the nucleus accumbens of male, Sprague-Dawley rats (250-300 g). Chloral hydrate (300 mg kg-l, i.p.) was used as anaesthetic. 0.3 mm diameter stainless-steel stylets terminated 0-5 mm below the guide tips and kept the guides patent. Animals were subjected to intracerebral injections 10-14 days after surgery when they were manually restrained as the stylets were replaced by stainless-steel injection units which terminated 2.5 mm below the guides at the centre of the nucleus accumbens (Ant. 9.0, Vert. 0, Lat. d~l .6) (De Groot, 1959). Injection units were coupled to Agla micrometer syringes and 2 pl drug or solvent solution was delivered bilaterally over 5 s with a further 55 s allowed for deposition of drug. Rats were used on two occasions with an intervening 7-10 day recovery period, and were then killed for histological and biochemical examination. In some experiments, lesions were made in the medial raphk nucleus on the same occasion as implantation of the guides. These lesions were induced electrolytically using a stainless-steel electrode, 0.64 mm diameter, which was insulated excepting at the tip. The electrode

The relationship between striatal and mesolimbic dopamine dysfunction and the nature of circling responses following 6-hydroxydopamine and electrolytic lesions of the ascending dopamine systems of rat brain.

The importance of extrapyramidal and mesolimbic function for circling behaviour was investigated by placing 6-hydroxydopamine (6-OHDA) and electrolesions in the cell bodies, axons and terminals of each system. Circling behaviour was weak when 6-OHDA was placed at the centre of the substantia nigra (SN), but the characteristic contralateral/ipsilateral turning to apomorphine/amphetamine were recorded. Circling was more marked when 6-OHDA was placed anterior to the SN but was generally absent following injections posterior to the SN. However, 6-OHDA placed in the medial forebrain bundle in the lateral hypothalamus resulted in intense contralateral/ipsilateral turning to apomorphine/amphetamine. Generally, the intensity of circling responses was related to the degree of striatal dopamine (DA) depletion but the more effective lesions also caused reductions in mesolimbic DA content. However, circling was not observed following any 6-OHDA injection into the mesolimbic DA system and it is concluded that mesolimbic DA function is not essential for the initiation of circling. In contrast to the 6-OHDA lesions, rats circled ipsilateral to both apomorphine and amphetamine when the SN was damaged by electrocoagulation to cause marked depletion of striatal dopamine. Lesser depletions of striatal dopamine after electrocoagulation in different regions of the medial forebrain bundle were associated with a lower intensity of ipsilateral circling to both drugs. In general, the differences between 6-OHDA and electrolesions could not be explained by additional damage to ascending noradrenaline or 5-hydroxytryptamine pathways. Lower doses of apomorphine were effective in the 6-OHDA circling rats, and the ipsilateral striatum of such rats was more sensitive to directly applied DA. Higher doses of apomorphine were required to produce circling after chronic electrolesions which rendered the ipsilateral striatum insensitive to DA. The contralateral circling to apomorphine after 6-OHDA lesions was abolished by chronic but not by acute electrolesion of the SN. It is suggested that electrolesions of the SN cause different effects to 6-OHDA because they destroy neuronal pathways in addition to the dopaminergic nigrostriatal tract. These appear to be required for the expression of circling behaviour caused by stimulation of the denervated striatum. Whereas 6-OHDA lesions result in super-sensitivity of the denervated strital DA receptors, electrolesions may cause a hypo-sensitivity of the same receptor sites.

Changes in rat striatal dopamine turnover and receptor activity during one years neuroleptic

Administration of trifluoperazine (2.5--3.5 mg/kg/day p.o.) or thioridazine (30--40 mg/kg/day) for up to 1 year initially increased homovanillic acid and 3,4-dihydroxyphenylacetic acid concentrations in striatum. However, by 1 month and thereafter metabolite levels returned almost to control values. Dopamine concentrations were elevated after 3 months administration of both drugs and also after 12 months administration of trifluoperazine. Trifluoperazine administration for 1 month produced a marked increase in the dissociation constant (KD) for striatal 3H-spiperone binding but a reduction in receptor numbers. Thereafter receptor numbers increased at 6 and 12 months in both trifluoperazine and thioridazine treated animals compared to control values. The KD for both drug treated groups returned to normal at 6 months; however, by 12 months drug treated animals again demonstrated high KD values. Dopamine stimulation of striatal adenylate cyclase was inhibited after administration of trifluoperazine or thioridazine for 1 week or 1 month. However, by 6 and 12 months this effect was replaced by an enhanced stimulation. Administration of lower doses of trifluoperazine (0.7--0.9 mg/kg/day p.o.) or thioridazine (6--9 mg/kg/day p.o.) for up to 1 year produced similar although generally less marked changes in these biochemical indices of dopamine function. This study provides evidence of biochemical changes which parallel the behavioural findings of enhanced dopamine receptor activity that occur during continuous long-term neuroleptic administration to rodents.

Sequencing of the α-Synuclein Gene in a Large Series of Cases of Familial Parkinson's Disease Fails to Reveal any Further Mutations

A mutation in exon 4 of the human alpha-synuclein gene was reported recently in four families with autosomal dominant Parkinsons disease (PD). In order to examine whether mutations in this exon or elsewhere in the gene are common in familial PD, all seven exons of the alpha-synuclein gene were amplified by PCR from index cases of 30 European and American Caucasian kindreds affected with autosomal dominant PD. Each product was sequenced directly and examined for mutations in the open reading frame. No mutations were found in any of the samples examined. We conclude that the A53T change described in the alpha-synuclein gene is a rare cause of PD or may even be a rare variant. Mutations in the regulatory or intronic regions of the gene were not excluded by this study.

Cerebral dopamine function in rats following withdrawal from one year of continuous neuroleptic administration

Continuous administration of trifluoperazine (2.5--3.5 mg/kg/day) or thioridazine (30--40 mg/kg/day) to rats for 12 months enhanced the stereotyped response to apomorphine (0.5 mg/kg s.c.), increased dopamine 1--150 muM) stimulation of striatal adenylate cyclase, increased KD and Bmax for dopamine (10(-4) M) specific 3H-spiperone striatal binding and produced spontaneous mouthing movements. On drug withdrawal, spontaneous locomotor activity was enhanced after 2 weeks and the enhanced stereotyped response was maintained for up to 1 month. Spontaneous mouthing had disappeared 2 weeks after drug withdrawal. The increase in Bmax for 3H-spiperone binding was maintained for up to 3 months after drug removal, but KD reverted to control levels by 2 weeks. In contrast, the dopamine stimulation of striatal adenylate cyclase remained enhanced for the 6 month withdrawal period. Administration of trifluoperazine (0.7--0.9 mg/kg/day) or thioridazine (6--8 mg/kg/day) for 12 months produced a less marked effect than administration of the higher dose. No enhancement of effect was observed on drug withdrawal and the initial changes disappeared rapidly on removal of drug. Supersensitivity of striatal dopamine mechanisms produced by continuous long-term neuroleptic administration differs from that produced by shorter treatment periods since no enhancement of effect occurs on drug withdrawal. The behavioural and biochemical components of the supersensitivity show variable time courses and in particular the enhanced stimulation of striatal adenylate cyclase persists for at least 6 months. Such effects may be of relevance to tardive dyskinesias in man.