Catherine Strazielle

Distribution of dopamine transporters in basal ganglia of cerebellar ataxic mice by [125I]RTI-121 quantitative autoradiography.

Dopamine (DA) uptake sites, or transporters, were examined with [125I]RTI-121 in mutant mice that exhibit motor control deficits, namely weaver, lurcher and dystonia musculorum. In lurcher mice, the distribution of [125I]RTI-121 binding was similar to controls, except for a decrease in the subthalamic nucleus. For dystonia musculorum mice, the labelling presented no differences between controls and mutants, except for decreases in the dorsal half of caudal neostriatum and in the ventral tegmental area. Moreover, in this mutant the left rostral neostriatum DA transporters were reduced, when compared to the right counterpart. In weaver heterozygote (wv/+) mice, the distribution and density gradients of [125I]RTI-121 labelling were similar as in their controls, except in caudal neostriatum, where binding was slightly higher. In contrast, the weaver homozygote (wv/wv) showed important decreases in labelling of the dorsal quadrant of rostral neostriatum as well as of the dorsal half of caudal neostriatum, where the reductions of binding densities were of 65% to 70%, respectively. There were also slight decreases in [125I]RTI-121 binding in olfactory tubercles as well as in subthalamic nucleus, but only in wv/wv mice. In substantia nigra pars compacta and ventral tegmental area of wv/wv mice the labelling was lower; however, while the 60% decrease in labelling in substantia nigra was highly significant, the 30% reduction in ventral tegmental area did not attain statistical significance. In summary, in the ataxic neurological mutant mice studied, important reductions of DA transporters were documented only for the weaver mice, the cerebellar mutant presenting, besides its cerebellar pathology, a known degeneration of mesencephalic dopaminergic neurons. The results rule out major alterations of the central DA systems in lurcher and dystonia musculorum, and are compatible with the hypothesis that the dopaminergic abnormalities of weaver mutants are not secondary to cerebellar atrophy, but may be a direct consequence of the abnormal weaver gene expressed by DA neurons leading to their apoptotic death.

Regional brain distribution of noradrenaline uptake sites, and of α1-, α2- and β-adrenergic receptors in PCD mutant mice: a quantitative autoradiographic study

Abstract The mouse “Purkinje cell degeneration” (pcd) is characterized by a primary loss of Purkinje cells, as well as by retrograde and secondary partial degeneration of cerebellar granule cells and inferior olivary neurons; this neurological mutant can be considered as an animal model of human degenerative ataxia. To determine the consequences of this cerebellar pathology on the noradrenergic system, noradrenaline transporters as well as α1-, α2- and β-adrenergic receptors were evaluated by quantitative ligand binding autoradiography in adult control and pcd mice using, respectively, [3H]nisoxetine, [3H]prazosin, [3H]idazoxan and [3H]CGP12177. In cerebellar cortex and deep nuclei of pcd mutants, [3H]nisoxetine labelling of noradrenaline transporters was higher than in control mice. However, when binding densities were corrected by surface area, they remained unchanged in the cerebellar cortex but associated with 25% and 40% lower levels of labelling of α1 and β receptors, as well as a very important increase (275%) of α2 receptors. In deep cerebellar nuclei, surface corrections did not reveal any changes either in transporter or in receptor densities. Higher densities of [3H]nisoxetine labelling were found in several regions related with the cerebellum, namely inferior olive, inferior colliculus, vestibular, reticular, pontine, raphe and red nuclei, as well as in primary motor and sensory cerebral cortex; they may reflect an increased noradrenergic innervation related to motor adjustments for the cerebellar dysfunction. Increased [3H]nisoxetine labelling was also measured in vegetative brainstem regions and in dorsal hypothalamus, implying altered autonomic functions and possible compensation in pcd mutants. Other changes found in extracerebellar regions affected by the mutation, such as thalamus and the olfactory system implicated both noradrenaline transporters and adrenergic receptors. In contrast to the important alterations of the noradrenergic system in cerebellar cortex, the lack of receptor changes in deep cerebellar nuclei suggests that local adaptations may be sufficient to minimize the consequence of the cerebellar atrophy on motor control. An intense labelling by [3H]idazoxan of the inner third of the molecular layer was a novel, albeit unexplained finding, and could represent a postsynaptic subset of α2-adrenergic receptors.

Regional distribution of the 5-HT innervation in the brain of normal and lurcher mice as revealed by [3H]citalopram quantitative autoradiography

The neurological cerebellar mutant lurcher is characterized by a primary degeneration of Purkinje cells as well as retrograde secondary partial degeneration of cerebellar granule cells and inferior olivary neurons. Since serotonin (5-HT) has been implicated in the modulation of excitatory amino acid systems of the cerebellum, the 5-HT innervation of the normal and lurcher mice was examined by quantifying uptake sites using [3H]citalopram autoradiography, and by biochemical assays of the indoles 5-HT, 5-hydroxy-L-tryptophan and 5-hydroxyindole-3-acetic acid using high-performance liquid chromatography. Comparable results were found between [3H]citalopram binding and 5-HT tissue concentrations in different brain regions. The highest [3H]citaslopram labelling was observed in defined structures of the mesencephalic and upper pontine regions, in limbic strutures, in hypothalamus and in discrete thalamic divisions, while the lowest labelling of uptake sites was documented in cerebellum and brainstem reticular formation. In lurcher mutants, the histology confirmed cell degeneration and the reduction in width, leading to 65%, 45% and 25% atrophies of total cerebellum, deep nuclei and inferior olivary nucleus, respectively. The [3H]citalopram labelling corrected for surface loss was 45% and 20% higher to cerebellar deep nuclei and red nucleus, respectively, but remained unchanged in the cerebellar cortex and inferior olivary nucleus. Moreover, higher labelling was found in nucleus raphe dorsalis, ventral tegmental area, inferior colliculus, locus coeruleus, pontine central grey and anterior thalamic nuclei, areas known to be part of cerebellar afferent and efferent systems. The present results indicate that in such pathological conditions as described for the lurcher mutant, the 5-HT system may modulate motor function not only at the level of the cerebellum, but also in other forebrain structures functionally related to the motor system.

Brain dopamine and amino acid concentrations in Lurcher mutant mice.

Lurcher mutant mice are characterized by massive degeneration of the cerebellum, including Purkinje cells and granule cells, as well as for the loss of neurons from the inferior olive. Concentrations of dopamine and two of its metabolites and of several amino acid neurotransmitters were determined in the cerebellum and in other brain regions of these mutants. By comparison to wild-type mice of the same background strain, glutamate and taurine concentrations were reduced in the Lurcher cerebellum. No decrease was found for aspartate, gamma-aminobutyric acid (GABA), glycine, as well as dopamine and its metabolites. Moreover, no neurochemical alterations occurred in the brain stem, thalamus, or neostriatum of Lurcher mutants. A selective reduction of glutamate concentration was found in the hippocampus, while all amino acids measured were decreased in the entorhinal-piriform areas. These results indicate region-selective reductions of neurotransmitter concentrations in a mouse mutant with a defined cerebellar cortical pathology.

Central serotonin system in dystonia musculorum mutant mice: Biochemical, autoradiographic and immunocytochemical data

The autosomal recessive mutation dystonia musculorum (dtJ/dtJ) causes degenerative alterations of peripheral and central sensory pathways that lead to ataxia. To investigate possible changes in the central serotonin system of these mice, HPLC measurements of 5‐hydroxytryptophan, 5‐hydroxy‐tryptamine (serotonin; 5‐HT), and 5‐HT metabolites were obtained from 22 brain regions and the spinal cord of wild type and dtJ/dtJ mutant mice. Also, 5‐HT transporters were quantified by [3H]citalopram autoradiography in 72 brain regions, subregions, and nuclei, and the 5‐HT innervation visualized by immunocytochemistry throughout the brain and spinal cord. In all brain regions measured for indoleamine content, there were no significant differences between the two genotypes. In the spinal cord, an increased tissue concentration of 5‐HT (+34%), 5‐hydroxyindole‐3‐acetic acid (+33%), 5‐hydroxytryptophol (+21%), and 5‐hydroxytryptophan (+45%) in dtJ/dtJ actually corresponded to the same total amount of each of these indoleamines in the entire spinal cord, when taking into account its reduced size in the mutants. Quantification of the binding to 5‐HT transporters showed increases in the medial geniculate nucleus (+14%), medial (+24%) and lateral (+18%) hypothalamus, interpeduncular (+13%), vestibular (+22%), and deep cerebellar nuclei (+37%) of dtJ/dt mice, and decreases in the ventral tegmental area (−13%), median and linear raphe nuclei (−20%), as well as in the solitary complex (−35%). There were no apparent differences in the distribution of 5‐HT‐immunostained fibers in these and other regions of brain and in the spinal cord of dtJ/dtJ compared to wild type mice. The bulk of these results indicates a relative sparing of the central 5‐HT system in the dtJ/dtJ mice, even though alterations in 5‐HT transporters could justify attempts at improving the sensorimotor dysfunction by administration of serotoninergic agents in these mice. Synapse 37:179–193, 2000.

Biochemical and autoradiographic studies of the central noradrenergic system in dystonia musculorum mutant mice.

The autosomal recessive mutation dystonia musculorum (dt(J)/dt(J)) causes degenerative alterations of peripheral and central sensory pathways leading to ataxia. To determine the consequences of this pathology on the central noradrenergic (NA) system, NA contents were measured by high-performance liquid chromatography (HPLC) in 22 brain regions and spinal cord, while NA transporters, or uptake sites, were evaluated by quantitative ligand binding autoradiography, using [3H]nisoxetine, in wild-type and dt(J)/dt(J) mutant mice. The only significant differences in NA contents between the two genotypes were increased levels in hypothalamus and mesencephalic dopaminergic regions A9/A10 of dt(J)/dt(J) mutants. The dt(J)/dt(J) spinal cord showed a similar result, but its NA content remained unchanged when taking into account its reduced volume. Binding to NA transporters revealed increased densities in sensory nuclei of cranial nerves, granular layer of the cerebellar cortex, as well as in cerebellar-related and basal ganglia structures, such as the lateral cuneate nucleus, pontine nuclei, substantia nigra, pontine reticular formation, median raphe nucleus and superior colliculus. Forebrain regions were relatively unaffected in the dt(J)/dt(J) mutants, although NA transporter densities were higher in piriform cortex, hippocampal subdivisions and ventro-anterior thalamic nucleus. In contrast, densities of NA transporters were decreased in hypothalamic subregions and in two ventrobasal thalamic nuclei. The results are discussed in relation to expression of the dystonin gene in normal brain, cellular defects resulting from the loss of gene transcription in the dt(J)/dt(J) mutation, functional circuits of the central nervous system and some of the phenotypical characteristics of dystonia musculorum mutants.

Repeated corticosterone injections in adult mice alter stress hormonal receptor expression in the cerebellum and motor coordination without affecting spatial learning

Graphical abstract Figure. No caption available. HighlightsAcute corticosterone induced specific motor coordination deficit in rotorod test.Glucocorticoid exposure decreased CRH‐R1 transcription in cerebellum.Corticosterone effects on cerebellar CRH/CRH‐R1 possibly caused motor alteration.Corticosterone decreases energy metabolism in efferent cerebellar circuitry. Abstract Receptors for glucocorticoid (GR) and corticotropin‐releasing hormone (CRH) are largely found in brain sensorimotor structures, particularly in cerebellum, underlining a potential role of stress hormones in the regulation of motor function. Since CRH is involved in neuroplasticity, known for its trophic effect on synapses, we investigated how manipulations in corticosterone serum levels can modulate the CRH system in the cerebellum and affect motor coordination. Corticosterone at doses of either 15 or 30 mg/kg was injected in mice and the status of hormonal expression evaluated in cerebellum, hippocampus, and hypothalamus in undisturbed housing conditions or after different behavioral tests. Under both conditions, metabolic activity in numerous brain regions involved in motor functions and emotion was measured by means of cytochrome oxidase (COX) activity labeling. After six consecutive days of corticosterone administration, CRH‐R1 transcription was downregulated in hypothalamic and cerebellar regions and hypometabolic changes were observed in mice treated with the higher dose for several limbic and sensorimotor circuitries, notably basal ganglia, deep cerebellar nuclei, and red nucleus. Corticosterone did not modify motor activity, anxiety, and spatial orientation, but decreased latencies before falling from the rotorod and prevented mice from reaching targets in the coat‐hanger test. In addition, COX activities were similar to control mice except in ventromedial thalamus and dorsal neostriatum, possibly indicating that physical activity protected brain energy metabolism against the stress hormone. The present findings showed that the CRH/CRH‐R1 system might play a role in mediating the effects of stress on cerebellar function, affecting especially motor learning tasks.

Regional Variations of 5HT Concentrations in Rorasg (staggerer) Mutants

Ataxic Rorasg (staggerer) mouse mutants, containing a deletion of the Rora gene which encodes a retinoid-like nuclear receptor, were compared to non-ataxic controls for concentrations of 5-hydroxytryptamine (HT), its main metabolite (5-hydroxy-indole acetic acid, 5HIAA), and its precursor (tryptophan) in cerebellum, brainstem, and forebrain. In Rorasg cerebellum, 5HT concentrations increased relative to controls, while tryptophan concentrations decreased. 5HIAA concentrations increased in mutant cerebellum and brainstem, but the 5HIAA/5HT ratio declined only in cerebellum. These results indicate that 5HT turnover decreased in cerebellum of an ataxic mutant, perhaps indicative of presynaptic accumulation and compromised neurotransmission and susceptible to be modified by 5HT pharmacotherapy.

Neuroanatomical pathways underlying the effects of hypothalamo-hypophysial-adrenal hormones on exploratory activity

Abstract When injected via the intracerebroventricular route, corticosterone-releasing hormone (CRH) reduced exploration in the elevated plus-maze, the center region of the open-field, and the large chamber in the defensive withdrawal test. The anxiogenic action of CRH in the elevated plus-maze also occurred when infused in the basolateral amygdala, ventral hippocampus, lateral septum, bed nucleus of the stria terminalis, nucleus accumbens, periaqueductal grey, and medial frontal cortex. The anxiogenic action of CRH in the defensive withdrawal test was reproduced when injected in the locus coeruleus, while the amygdala, hippocampus, lateral septum, nucleus accumbens, and lateral globus pallidus contribute to center zone exploration in the open-field. In addition to elevated plus-maze and open-field tests, the amygdala appears as a target region for CRH-mediated anxiety in the elevated T-maze. Thus, the amygdala is the principal brain region identified with these three tests, and further research must identify the neural circuits underlying this form of anxiety.

Motor Performance and Regional Brain Metabolism of Four Spontaneous Murine Mutations with Degeneration of the Cerebellar Cortex

Four spontaneous mutations with cerebellar atrophy exhibit ataxia and deficits in motor coordination tasks requiring balance and equilibrium. These mutants were compared to their respective controls for regional brain metabolism assessed by histochemical staining of the mitochondrial enzyme, cytochrome oxidase (CO). The enzymatic activity of Grid2Lc, Grid2ho, Rorasg, and Relnrl mutants was altered in cerebellum and cerebellar-related pathways at brainstem, midbrain, and telencephalic levels. The CO activity changes in cerebellar cortex and deep cerebellar nuclei as well as some cerebellar-related regions were linearly correlated with motor performance in stationary beam and rotorod tasks of Grid2Lc, Rorasg, and Relnrl mutants. These results indicate that in addition to its relation to neural activity, CO staining can be used as a predictor of motor capacity.