Selective loss of AMPA receptors at corticothalamic synapses in the epileptic stargazer mouse.

Absence seizures are common in the stargazer mutant mouse. The mutation underlying the epileptic phenotype in stargazers is a defect in the gene encoding the normal expression of the protein stargazin. Stargazin is involved in the membrane trafficking and synaptic targeting of α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors (AMPARs) at excitatory glutamatergic synapses. Thus, the genetic defect in the stargazer results in a loss of AMPARs and consequently, excitation at glutamatergic synapses. Absence seizures are known to arise in thalamocortical networks. In the present study we show for the first time, using Western blot analysis and quantitative immunogold cytochemistry, that in the epileptic stargazer mouse, there is a global loss of AMPAR protein in nucleus reticularis (RTN) and a selective loss of AMPARs at corticothalamic synapses in inhibitory neurons of the RTN thalamus. In contrast, there is no significant loss of AMPARs at corticothalamic synapses in excitatory relay neurons in the thalamic ventral posterior (VP) region. The findings of this study thus provide cellular and molecular evidence for a selective regional loss of synaptic AMPAR within the RTN that could account for the loss of function at these inhibitory neuron synapses, which has previously been reported from electrophysiological studies. The specific loss of AMPARs at RTN but not relay synapses in the thalamus of the stargazer, could contribute to the absence epilepsy phenotype by altering thalamocortical network oscillations. This is supported by recent evidence that loss of glutamate receptor subunit 4 (GluA4) (the predominant AMPAR-subtype in the thalamus), also leads to a specific reduction in strength in the cortico-RTN pathway and enhanced thalamocortical oscillations, in the Gria4(-/-) model of absence epilepsy. Thus further study of thalamic changes in these models could be important for future development of drugs targeted to absence epilepsy.

Resonant antidromic cortical circuit activation as a consequence of high-frequency subthalamic deep-brain stimulation.

Deep brain stimulation (DBS) is an effective treatment of Parkinson's disease (PD) for many patients. The most effective stimulation consists of high-frequency biphasic stimulation pulses around 130 Hz delivered between two active sites of an implanted depth electrode to the subthalamic nucleus (STN-DBS). Multiple studies have shown that a key effect of STN-DBS that correlates well with clinical outcome is the reduction of synchronous and oscillatory activity in cortical and basal ganglia networks. We hypothesized that antidromic cortical activation may provide an underlying mechanism responsible for this effect, because stimulation is usually performed in proximity to cortical efferent pathways. We show with intracellular cortical recordings in rats that STN-DBS did in fact lead to antidromic spiking of deep layer cortical neurons. Furthermore, antidromic spikes triggered a dampened oscillation of local field potentials in cortex with a resonant frequency around 120 Hz. The amplitude of antidromic activation was significantly correlated with an observed suppression of slow wave and beta band activity during STN-DBS. These findings were seen in ketamine-xylazine or isoflurane anesthesia in both normal and 6-hydroxydopamine (6-OHDA)-lesioned rats. Thus antidromic resonant activation of cortical microcircuits may make an important contribution toward counteracting the overly synchronous and oscillatory activity characteristic of cortical activity in PD.

The influence of the subthalamic nucleus upon the damage to the dopamine system following lesions of globus pallidus in rats.

Lesioning or stimulating the subthalamic nucleus (STN) in patients with Parkinson's disease, or in animal models of parkinsonism, alleviates many of the symptoms and so it is tempting to think of the STN as a part of the cause of Parkinson's disease. The globus pallidus (GP) is thought to have a tonic inhibitory action on the STN. An ibotenic acid injection into the GP in rats removes the cells of the GP and, over the following 6 weeks, a progressive loss of dopamine cells (counted stereologically in sections stained for tyrosine hydroxylase) develops in substantia nigra (SN). In this investigation we show that, when animals have the STN cells destroyed by very small ibotenic acid injections, their dopamine neurons are not damaged. Furthermore, if a lesion to the GP follows a lesion of STN then the dopamine cells also survive this double insult, at least for the first 3 weeks following the lesion. The experiments provide good reason to suspect that, at least in the short term, increased activity in the STN is a contributory cause of the loss of dopamine cells which follows the lesion of the GP in rats. Whether or not this is part of the mechanism of cell loss in Parkinson's disease, the rats with GP lesions at least provide an opportunity to test strategies that might protect dopamine cells from slowly developing damage. Removing the STN seems to be neuroprotective in this new model of dopamine degeneration.

Evidence of a breakdown of corticostriatal connections in Parkinson's disease.

Dendritic spines are important structures which receive synaptic inputs in many regions of the CNS. The goal of this study was to test the hypothesis that numbers of dendritic spines are significantly reduced on spiny neurones in basal ganglia regions in Parkinson's disease as we had shown them to be in a rat model of the disease [Exp Brain Res 93 (1993) 17]. Postmortem tissue from the caudate and putamen of patients suffering from Parkinson's disease was compared with that from people of a similar age who had no neurological damage. The morphology of Golgi-impregnated projection neurones (medium-sized spiny neurones) was examined quantitatively. The numerical density of dendritic spines on dendrites was reduced by about 27% in both nuclei. The size of the dendritic trees of these neurones was also significantly reduced in the caudate nucleus from the brains of PD cases and their complexity was changed in both the caudate nucleus and the putamen. Dendritic spines receive crucial excitatory input from the cerebral cortex. Reduction in both the density of spines and the total length of the remaining dendrites is likely to have a grave impact on the ability of these neurones to function normally and may partly explain the symptoms of the disorder.

Death of dopaminergic neurones in the rat substantia nigra can be induced by damage to globus pallidus.

Parkinson's disease is a debilitating disorder that results from the death of dopaminergic neurones in the substantia nigra. Subthalamic nucleus neurones use glutamate as their neurotransmitter and send excitatory projections to the substantia nigra. Changes in both the mean firing rate and firing pattern of neurones of the subthalamic nucleus have been found in patients with this disease. This has led to the suggestion that hyperactivity of the subthalamic nucleus may be involved in the pathology of the dopaminergic neurones. Subthalamic nucleus lesions or treatment with glutamatergic antagonists can be neuroprotective in animal models of Parkinson's disease but until now there has been no direct evidence that hyperactivity of subthalamic nucleus neurones can lead to downstream cell death. Here we show that lesions of the rat globus pallidus (a treatment that has been shown to increase subthalamic nucleus neuronal activity) result in a significant reduction of the number of dopaminergic neurones in the substantia nigra.

Identification of the source of the bilateral projection system from cortex to somatosensory neostriatum and an exploration of its physiological actions.

Microinjections of cholera toxin B subunit were made into the area of the neostriatum that receives input from the primary somatosensory barrel cortex (SI) in the rat. Studies of the cortices then allowed retrograde identification of the cortical cells supplying the striatal input. When injections were restricted to the neostriatum, retrograde labelling was found in layer V of both SI cortices. Ipsilateral to the injection, cells were retrogradely filled with toxin in all parts of the barrel field, in adjacent parietal cortex, in the motor cortex and in prefrontal areas. A similar distribution across cortical areas was seen contralaterally; however, the stained cells in the SI were between rather than within barrel columns. An earlier anterograde study suggested two inputs from the SI to the neostriatum. The present results indicate that one input to the somatosensory area of the neostriatum arises bilaterally from neurons between the barrels of the SI, while the topographic pathway from below the barrels is present only ipsilaterally. These anatomical results indicate that separate stimulation of the two corticostriatal pathways from the barrel cortex is possible. Electrical stimulation of the contralateral cortex will activate the bilateral pathway, while electrical stimulation of the whisker pads activates the barrels and hence the topographic pathway. Neurons in the somatosensory region of the striatum responded to stimuli in the contralateral cortex and in the contralateral whisker pad. In spite of very different path lengths, stimuli via the two routes gave rise to excitatory postsynaptic potentials in the striatal cells with similar latencies. The excitatory postsynaptic potentials to whisker pad stimulation had a rapid rise time and usually resulted in at least one action potential. Responses to stimulation of the contralateral cortex rose to a peak more slowly and were more variable in latency, but also gave rise to an action potential in the majority of cases. All the neurons had the physiological characteristics of medium-sized densely spiny cells and after intracellular filling with biocytin had the appropriate morphology. In summary, we propose that two corticostriatal pathways arise from layer V cells in the barrel area of the somatosensory cortex; one is bilateral and arises from cells mainly below the septa, while a topographical pathway arises from cells below the barrels. Both pathways can raise the spiny output cells of the striatum to firing threshold. The latencies from the contralateral cortex imply slowly conducting fibres with considerably more temporal dispersion than the pathway from below the barrels, which we excited from the contralateral periphery.

Computational models of the basal ganglia.

Computer simulation studies and mathematical analysis of models of the basal ganglia are being used increasingly to explore theories of basal ganglia function. We review the implications of these new models for a general understanding of basal ganglia function in normal as well as in diseased brains. The focus is on their functional similarities rather than on the details of mathematical methodologies and simulation techniques. Most of the models suggest a vital role for the basal ganglia in learning. Although this interest in learning is partly driven by experimental results associating the acute firing of dopamine cells with reward prediction in monkeys, some of the models have preceded the electrophysiological results. Another common theme of the models is selection. In this case, the striatum is seen as detecting and selecting cortical contexts for access to basal ganglia output. Although the behavioral consequences of this selection are hard to define, the models provide frameworks within which to explore these ideas empirically. This provides a means of refining our understanding of basal ganglia function and to consider dysfunction within the new logical frameworks.

Dopamine and synaptic plasticity in the neostriatum.

After the unilateral destruction of the dopamine input to the neostriatum there are enduring changes in rat behaviour. These have been ascribed to the loss of dopamine and the animals are often referred to as 'hemiparkinsonian'. In the denervated neostriatum, we have shown that not only are the tyrosine hydroxylase positive boutons missing, but also the medium sized densely spiny output cells have fewer spines. Spines usually have asymmetric synapses on their heads. In a recent stereological study we were able to show that there is a loss of approximately 20% of asymmetric synapses in the lesioned neostriatum by 1 mo after the lesion. Current experiments are trying to establish the specificity of this loss. So far we have evidence suggesting that there is no obvious preferential loss of synapses from either D1 or D2 receptor immunostained dendrites in the neostriatum with damaged dopamine innervation. These experiments suggest that dopamine is somehow necessary for the maintenance of corticostriatal synapses in the neostriatum. In a different series of experiments slices of cortex and neostriatum were maintained in vitro in such a way as to preserve at least some of the corticostriatal connections. In this preparation we have been able to show that cortical stimulation results in robust excitatory postsynaptic potentials (EPSPs) recorded from inside striatal neurons. Using stimulation protocols derived from the experiments on hippocampal synaptic plasticity we have shown that the usual consequence of trains of high frequency stimulation of the cortex is the depression of the size of EPSPs in the striatal cell. In agreement with similar experiments by others, the effect seems to be influenced by NMDA receptors since the unblocking of these receptors with low Mg++ concentrations in the perfusate uncovers a potentiation of the EPSPs after trains of stimulation. Dopamine applied in the perfusion fluid round the slices has no effect but pulsatile application of dopamine, close to the striatal cell being recorded from, and in temporal association with the cortical trains, leads to a similar LTP like effect. The reduction of K+ channel conductance in the bath with TEA also has the effect of making cortical trains induce potentiation of corticostriatal transmission. TEA applied only to the cell being recorded from has no similar effect; the cortical stimulation again depresses the EPSP amplitude, so the site of action of TEA may well be presynaptic to the striatal cell. The morphological and physiological experiments may not necessarily be related but it is tempting to suggest that dopamine protects some corticostriatal synapses by potentiating them but that in the absence of dopamine others simply disconnect and are no longer detectable on electron microscopy.

Corticofugal axons from adjacent 'barrel' columns of rat somatosensory cortex: cortical and thalamic terminal patterns.

The cortical representations of the vibrissae of the rat form a matrix in which each whisker has its own area of cortex, called a 'barrel'. The afferent pathways from the periphery travel first to the trigeminal nuclei and thence via the ventroposteromedial thalamus (VPM) to the cortical barrels have been described in detail. We have studied the output from barrels by filling adjacent areas of the primary somatosensory cortex (SI) with either Phaseolus vulgaris leucoagglutinin (PHA-L) or biotinylated dextran amine (BDA) and demonstrating the course and terminations of the axons that arise within the barrel fields. The method not only dramatically illustrates the previously described corticothalamic pathway to VPM but also demonstrates a strict topography in the cortical afferents to the thalamic reticular nucleus (RT). Cells supplying the RT projection are found below the barrels in layer IV. Connections to the posterior thalamus, on the other hand, have no discernible topography and are derived from cortical areas surrounding the barrels. Thus the outputs of these 'septal' areas return to the region from which they receive thalamic input. The corticocortical connections are also visible in the same material. Contralateral cortical connections arise from the cells of the septa between barrels. The projections to secondary somatosensory area (SII) are mirror images of the barrel pattern in SI with rather more overlap but nonetheless a recognisable topography.

Acute in vivo neurotoxicity of peptides from Maedi Visna virus transactivating protein Tat.

Lentiviruses such as Maedi Visna virus (MVV) in sheep, and human immunodeficiency virus (HIV) in man often cause a variety of neurological syndromes in later stages of infection. Neuropathological investigations reveal damage to myelin and astrocytosis in both white and grey matter. MVV infection induces axonal damage with some areas of necrosis while neuronal loss, and synaptic damage have been reported in HIV-1 infection. It is not clear, at present, how this neurodegeneration is mediated but, as these viruses do not directly infect neurons, an indirect neurotoxic action of the viruses is indicated. Previous experiments have shown that the intra-striatal injection in rats of a synthetic peptide derived from the basic region of the MVV transactivating protein Tat causes considerable neurotoxicity 1 week post-operatively. By in vivo stereotaxic injections of the same synthetic peptide, and subsequent immunocytochemical detection of neurons, astrocytes and microglia, we show that this neurotoxicity displays a distinctive and unusual lesion profile and is evident as rapidly as 0.5 h post-operatively. Furthermore, neuroprotection studies suggest that the early effects of the MVV tat peptide may involve glutamate neurotoxicity via the N-methyl-D-aspartate (NMDA) receptors since the application of dizolcipine (MK801) reduces the volume of the lesion seen at 1 h after the injection of neurotoxic peptide, while L-NAME is ineffective. The mechanism of this early neurotoxicity is thus different from the longer term actions already described.

Double anterograde tracing of outputs from adjacent "barrel columns" of rat somatosensory cortex. Neostriatal projection patterns and terminal ultrastructure.

The sensory input to the neostriatum from groups of cortical cells related to individual facial vibrissae has been investigated at both light- and electron-microscopic resolution. The purpose of the study was to establish the extent to which corticostriatal input maintains the anatomical coding of spatial information that is present in cortex. A double anterograde tracing method was used to identify the output projections from groups of adjacent neurons in different barrel columns, so that the anatomical relationships between two groups could be studied throughout their length. Adjacent whiskers are represented in adjoining cortical barrels and an examination of corticostriatal projections from these reveals two patterns of projection. In one, the anatomical topography is partially preserved; the barrels are represented in adjoining, discrete, areas of the somatosensory neostriatum. In the second projection pattern, the neostriatal innervation is diffuse and adjacent barrels are represented in overlapping regions of the neostriatum. Moreover, the fibres are thinner, have smaller boutons, and are present in both the ipsilateral and contralateral neostriatum. The two systems also enter the neostriatal neuropile separately. The discrete topographic system enters the adjacent neostriatum as collaterals which leave the descending corticofugal fibres at right angles, while the diffuse system enters directly from the corpus callosum at an acute angle. Examination of the neostriatal terminal fields by correlated light and electron microscopy, shows that characteristic axospinous terminals on spiny neurons are made by both groups of cortical fibres, although they differ in their size and morphology. It is concluded that at least two corticostriatal pathways arise from the barrel cortex. One connection maintains some of the anatomical code implicit in the barrel pattern of primary somatosensory cortex, but another, more diffuse, system is overlaid upon it which may carry different information from this complex area of cortex.

Effects of potassium channel blockers on synaptic plasticity in the corticostriatal pathway.

High-frequency stimulation (HFS) of the cerebral cortex or underlying white matter usually induces long-term depression (LTD) in the corticostriatal pathway. Long-term potentiation (LTP) has been described in striatal cells exposed to extracellular tetraethylammonium (TEA). The facilitating effect of TEA may be due to blockade of K+ channels in the postsynaptic neurone or alternatively to presynaptic effects on the release of neurotransmitters such as glutamate or dopamine. We compared the effects of HFS on LTP in striatal cells in four groups of neurones. HFS in control conditions induced LTD (-28.6 +/- 2.0% at 20 min, n = 10) whereas HFS in extracellular TEA (30 mM) induced LTP (+51.0 +/- 24.2% at 20 min, n = 7). LTP was not induced in cells loaded with intracellular Cs (-20.3 +/- 11.4% at 20 min, n = 10) or intracellular TEA (-11.8 +/- 8.9% at 20 min, n = 10), despite comparable effects on postsynaptic responses to HFS. Since the effects of the intracellular K+ channel blockers are limited to the cell being recorded from. these findings suggest that the facilitating effect of extracellular TEA on LTP induction involves a presynaptic action.

Plasticity of synapses in the rat neostriatum after unilateral lesion of the nigrostriatal dopaminergic pathway.

In the 6-hydroxydopamine model of Parkinson's disease in the rat, there is a significant reduction in the number of dendritic spines on the principal projection neurons in the neostriatum, presumably attributable to loss of the nigrostriatal dopamine input. These spines invariably receive input from terminals forming asymmetric synapses that originate mainly from the cortex. The object of the present study was to determine the fate of those terminals after the loss of dendritic spines. Unbiased estimates of synaptic density and absolute numbers of synapses in a defined volume of the neostriatum were made using the "disector" and Cavalieri techniques. Numerical synaptic density of asymmetric synaptic contacts was 17% lower in the neostriatum deprived of dopamine innervation and, in absolute terms, there were 3 billion (19%) fewer contacts. The numerical density of a subpopulation of asymmetric contacts on dendritic spines that have complex or perforated synaptic specializations and normally make up 9% of the asymmetric population was 44% higher on the experimental side. Asymmetric synapses were found to be enriched in glutamate using postembedding immunogold labeling. The present observations demonstrate that the loss of spines previously reported after 6-hydroxydopamine lesions is accompanied by a loss of asymmetric synapses rather than by the movement of synapses from spines to other postsynaptic targets. The study also demonstrates that there is an increase in complex synaptic interactions that have been implicated in synaptic plasticity in other regions of the CNS after experimental manipulations.

Plasticity of striatopallidal terminals following unilateral lesion of the dopaminergic nigrostriatal pathway: a morphological study.

In Parkinson's disease the dopaminergic nigrostriatal pathway degenerates, resulting in an imbalance in activity of two pathways of information flow through the basal ganglia. In animal models of the disease, the striatonigral pathway becomes underactive and the striatopallidal pathway becomes overactive. In the present study immunocytochemistry for enkephalin and GABA and anterograde labelling were used to investigate whether morphological plasticity occurs in striatopallidal terminals following unilateral removal of the nigrostriatal dopaminergic pathway. Pallidal terminals were immunostained to reveal enkephalin and examined in the electron microscope (n=399). Immunoreactive synaptic bouton profiles were on average 64% larger on the experimental side 26 days after the lesion. Analysis of their shape revealed that those on the dopamine-depleted side of the brain were more irregular in profile and that their synaptic specialisations were more complex in shape but not significantly different in length. Striatopallidal terminals were also identified by GABA immunocytochemistry combined with anterograde labelling (n=20). Double-labelled boutons were significantly larger in cross-sectional area on the experimental side (57%). Analysis of terminals that were simply labelled by the immunogold method to reveal GABA (n=278) showed no significant differences in size between terminals from the dopamine-depleted and control side. This suggests that a substantial number of GABAergic terminals in the globus pallidus do not belong to the striatopallidal population of terminals. These morphological changes correlate with previous studies suggesting striatopallidal boutons are more active after destruction of dopaminergic input to the neostriatum.

Morphological changes in met(5)-enkephalin-immunoreactive synaptic boutons in the rat neostriatum after haloperidol decanoate treatment.

The morphological plasticity of an identified population of synaptic boutons in the rat neostriatum was investigated 24 h (short-term treatment) or 14 days (long-term treatment) after administration of the depot neuroleptic, haloperidol decanoate. Specific methionine(5)-enkephalin antiserum was used to label bouton profiles in the dorsal neostriatum. The size and shape of these boutons was subsequently analysed with quantitative methods at the ultrastructural level. Immunoreactive synaptic bouton profiles were found to have a larger cross-sectional area, to be less circular in shape and to have a longer maximum diameter after long-term neuroleptic treatment. These parameters were not significantly affected by short-term neuroleptic treatment. The morphological parameters indicate that methionine(5)-enkephalin-immunoreactive boutons become enlarged, probably by elongating. This suggests that boutons containing methionine(5)-enkephalin increase their potential synaptic efficacy in the long term after neuroleptic treatment.

Dopamine reverses the depression of rat corticostriatal synapses which normally follows high-frequency stimulation of cortex in vitro.

Learning deficits resulting from dopamine depletion suggest that striatal dopamine release is crucial for reinforcement. Recently described firing patterns of dopamine neurons in behaving monkeys show that transient increases in dopamine release are brought about by reinforcement. We describe an enduring change in the strength of synaptic transmission following pulsatile application of dopamine intended to mimic the transient increases associated with reinforcement. Intracellular records were made from neurons in slices of the rat corticostriatal system. Neurons having the properties of the medium-sized spiny neurons responded to cortical stimulation with depolarizing potentials (peak amplitude 12.0 +/- 1.3 mV; latency 9.2 +/- 0.1 ms; mean +/- S.D., n = 19), which had the properties of monosynaptic excitatory postsynaptic potentials. After trains of stimuli to the cortex had been applied in conjunction with intracellular depolarizing current, the size of these excitatory postsynaptic potentials was reduced (-27% at 20 min). Application of dopamine (approximately 30 microM) in a solution containing KCl concomitant with depolarization and presynaptic activation increased the subsequent excitatory postsynaptic potentials (+21% at 20 min) without significant lasting change in the membrane properties of the postsynaptic cell. This suggests that dopamine has an enduring, activity-dependent action on the efficacy of corticostriatal transmission, which may be a cellular basis for the learning-related effects of the nigrostriatal system.

Inhibition of neuronal nitric oxide synthase by 7-nitroindazole: effects upon local cerebral blood flow and glucose use in the rat.

The novel nitric oxide synthase inhibitor 7-nitroindazole (7-NI) is relatively specific for the neuronal isoform of the enzyme and in this study we have used this compound to investigate the physiological role of perivascular nitric oxide-containing nerves in the cerebrovascular bed. Following injection of 7-NI (25 or 50 mg/kg, i.p.), cerebral blood flow and glucose utilization were measured in the conscious rat using the fully quantitative [14C]iodoantipyrine and 2-[14C]deoxyglucose techniques, respectively. Neither dose of the drug produced any change in arterial blood pressure, confirming a lack of effect upon the endothelial isoform of the enzyme, although there was a pronounced decrease in heart rate (-28% by 10 min postinjection). Throughout the brain 25 mg/kg 7-NI i.p. resulted in decreases in blood flow of between -20% in the hippocampus and -58% in the substantia nigra. Increasing the dose to 50 mg/kg resulted in a further generalized decrease, to almost -60% in parts of the thalamus and hippocampus, but in every animal this higher dose of 7-NI also produced randomly distributed areas of relative hyperaemia, which were most commonly found in those areas where the most intense hypoperfusion was otherwise in evidence. Despite these changes in blood flow, in all but a very few areas of the brain no significant decrease in glucose use was measured at either of the two doses of 7-NI. Thus despite the greater specificity of 7-NI for neuronal nitric oxide synthase, the cerebrovascular effects of the drug in vivo are very similar to that reported for the arginine analogues. However, these data do suggest that nitric oxide-releasing neurones in the brain may have an important role to play in the regulation of cerebral blood flow.