Lazaros C. Triarhou

Time of neuron origin and gradients of neurogenesis in midbrain dopaminergic neurons in the mouse

Previous [3H]thymidine studies in Nisslstained sections in rats established that the substantia nigra pars compacta and the ventral tegmental area originate sequentially according to an anterolateral to posteromedial neurogenetic gradient. We investigated whether that same pattern is found in mice in the dopaminergic neurons in each of these structures. Using tyrosine hydroxylase immunostaining combined with [3H]thymidine autoradiography, the time of origin of dopaminergic midbrain neurons in the retrorubral field, the substantia nigra pars compacta, the ventral tegmental area, and the interfascicular nucleus was determined in postnatal day 20 mice. The dams of the experimental animals were injected with [3H]thymidine on embryonic days (E) 11–E12, E12–E13, E13–E14, and E14–E15. The time of origin profiles for each group indicated significant differences between populations. The retrorubral field and the substantia nigra pars compacta arose nearly simultaneously and contained the highest proportion of neurons, 49 to 37%, generated on or before E11. Progressively fewer early-generated neurons were found in the ventral tegmental area (20%), and the interfascicular nucleus (8.5%). In addition, anterior dorsolateral neurons in the substantia nigra and ventral tegmental area were more likely to be generated early than the posterior ventromedial neurons. These findings indicate that mouse and rat brains have nearly identical developmental patterns in the midbrain, and neurogenetic gradients in dopaminergic neurons are similar to those found in Nissl studies in rats.

Developmental expression of polypeptide PEP-19 in cerebellar cell suspensions transplanted into the cerebellum of pcd mutant mice

SummaryCerebellar cell suspensions were prepared from normal mouse embryos and implanted into the cerebellum of Purkinje cell degeneration (pcd) mutant mice, which are characterized by a virtually complete degeneration of Purkinje cells between postnatal day (P) 17 and P45. The expression of immunoreactivity for PEP-19, a developmentally-regulated brain-specific polypeptide, was analyzed in normal mouse cerebellum, as well as in pcd mutants with or without grafts. In the normal cerebellum, PEP-19 immunoreactivity was present in Purkinje cells. In unoperated mutants, 45 days of age or older, Purkinje cells were absent. In grafted pcd mice, numerous PEP-19 immunoreactive, neuroblast-like cells were seen in the graft at 5 days after transplantation. By 9 days, large PEP-19 immunoreactive neurons were found in the host molecular layer; by 17 days after transplantation, such neurons displayed an extensive dendritic tree and resembled differentiated Purkinje cells. The vast majority of PEP-19 immunoreactive cells was located in the molecular layer of the host at 9 days after transplantation and beyond; nonetheless, the same cells extended axonal processes toward the graft, indicating an affinity for co-grafted (possibly deep nuclei) neurons. These results point to the ability of donor Purkinje cells for survival, migration into the host brain and morphological and chemical differentiation following transplantation to the degenerated cerebellar cortex of the recipient mutants.

Anterograde transsynaptic degeneration in the deep cerebellar nuclei of Purkinje cell degeneration (pcd) mutant mice.

SummaryThe genetically-determined loss of Purkinje cells (PCs) in ‘Purkinje cell degeneration’ (pcd) mutant mice results in the loss of presynaptic afferents to the deep cerebellar nuclei (DCN). This deafferentation takes place between postnatal day (P)17 and P45, i.e. after the maturation of cerebellar circuitry. We examined the DCN of normal and pcd mutant mice by quantitative light microscopic methods to determine whether neuronal atrophy or loss in the DCN take place during and after the loss of their input from the PCs. Neuronal diameters in control mice were 16.4±0.72 μm (mean±S.D.) at P23 and 15.6±0.64 μm at P300. The respective values in pcd mutant mice were 15.7±0.58 μm and 13.5±0.24 μm. Diameters in 300-day-old mutants were significantly smaller than those in both age-matched controls and 23-day-old mutants (P< 0.001). Neuronal populations in the DCN of control mice were 10,167± 949 at P23 and 10,429±728 at P300. The respective values in mutants were 9,436±1,366 and 7,424±1,324. There was a significant difference of 29% [95% confidence limits: 9–45%] between 300-day-old mutants and age-matched controls (P<0.01), and a significant loss of 21% [95% confidence limits: 4–36%] in 300-day-old mutants with respect to 23-day-old mutants (P<0.05). The total volume of the DCN was 22% less in 300-day-old mutants in relation to 23-day-old mutants (P< 0.05). These findings support the idea that the stability of DCN neurons in the mature cerebellum depends in part on the synaptic input from PCs.

Degeneration and graft-induced restoration of dopamine innervation in the weaver mouse neostriatum: a quantitative radioautographic study of [3H]dopamine uptake

SummaryA recently introduced quantitative radioautographic technique was used to characterize the striatal dopaminergic deficit in weaver mutant mice and to evaluate the extent of DA reinnervation resulting from cell suspension grafts of fetal ventral mesencephalic tissue. Brain slices from normal mice and unilaterally grafted weaver mice were incubated in [3H]DA, in the presence of desipramine and pargyline, 3–5 months after graft surgery. Semi-thin sections from the fixed and resin-embedded slices were subsequently exposed on tritium sensitive film and afterwards dipped in nuclear emulsion for light microscope radioautography. Alternate slices were embedded in Epon for post-embedding tyrosine hydroxylase (TH) immunocytochemistry. The grain density of the film radioautographs matched well the distribution of TH positive fibers. Both methods revealed an almost complete absence of DA axons in the dorsomedial quadrant of the weaver neostriatum and an increasing density of DA innervation towards the ventrolateral areas. In the light microscope radioautographs, only the ventral striatum (i.e. nucleus accumbens and olfactory tubercle) and a narrow ventral and periventricular zone of the caudate-putamen were covered by silver grain clusters typical of DA varicosity labeling. Such labeled varicosities were nevertheless found in reduced numbers in the lateral portion of both nucleus accumbens and the olfactory tubercle. The remaining neostriatum was overlaid by diffuse silver grains, suggesting a deficient DA uptake and storage mechanism in the residual DA fibers in this region. Immunocytochemistry using antibodies specific for DA or TH provided further evidence that the residual DA innervation in the weaver neostriatum was biochemically defective. Weaver mice with grafts of ventral mesencephalic tissue in the right neostriatum showed an amphetamine-induced rotational bias to the contralateral side, which was not seen in the sham-operated animals. In contrast to the intrinsic weaver neostriatal DA innervation, DA fibers of graft origin exhibited the normal, clustered type of varicosity labeling. The computerized image analysis of silver grain density in film radioautographs was calibrated by counting these labeled varicosities in selected areas of light microscope radioautographs from the same sections. Results showed a mean DA reinnervation of neostriatal tissue surrounding the graft of about 20%, in some cases up to 80%, of the density seen in wild type mice, with a gradual decrease with distance up to 1–1.4 mm from the graft. The ventral parts of the neostriatum, which contained higher numbers of residual intrinsic DA fibers, were much more sparsely reinnervated than the dorsal and dorsomedial areas. These data show that a quantitatively significant DA reinnervation of the weaver neostriatum can be provided by fetal mesencephalic cell suspension grafts and that these DA fibers become functional, at least with respect to their DA uptake and storage mechanisms, in a neostriatal environment where intrinsic weaver DA axons are strongly deficient. However, observations in long-term weaver mice (9 months after transplantation) suggested that the graft-derived DA fiber outgrowth was reduced with time in the affected striatum, in spite of good survival of the grafted neurones.

The dendritic dopamine projection of the substantia nigra: phenotypic denominator of weaver gene action in hetero- and homozygosity

While cerebellar granule cell migration and survival are affected by the weaver (wv) mutation both in the heterozygous and homozygous states, the dopamine (DA) deficit of the nigrostriatal projection has been shown to involve only midbrain DA cell bodies and nigrostriatal DA axons of homozygous mutants. We have identified a cellular site which is defective in the mesencephalic DA system of mice both heterozygous and homozygous for the wv gene. That deficit involves the dendritic DA projection which extends from the substantia nigra pars compacta (SNc) into the pars reticulata (SNr). In the midbrain of heterozygotes, dopaminergic dendrites are reduced by 60% at 20 days of age, when DA neurone number in the midbrain, DA content in the neostriatum and pattern of synaptic connectivity of nigrostriatal axon terminals are normal. At the same age, the deficit of dopaminergic dendrites in the SNr of homozygotes (76%) is disproportionate to the loss of DA cell bodies (42%). These findings: (a) may provide clues to the aetiopathogenetic mechanisms of wv gene operation; and (b) may explain the generalised convulsions intermittently manifested by weaver heterozygotes, as the SN has been implicated in the pathophysiology of experimental seizures.

Synaptic connectivity of tyrosine hydroxylase immunoreactive nerve terminals in the striatum of normal, heterozygous and homozygous weaver mutant mice

SummaryStriatal dopamine deficiency in weaver mutant mice is associated with loss of mesencephalic dopamine neurons. The maximum dopamine concentration in the striatum of weaver mutants is found on postnatal day 20, when it represents 50% of the control value. By day 180, it declines to 25% of the control value. Correspondingly, the number of nigral dopamine neurons is 58% of the normal number on day 20 and becomes 31% of the normal value by day 90. The aim of the present study was to examine whether dopamine axon terminals in the weaver striatum establish synaptic connections with postsynaptic neurons at the time when striatal dopamine concentration is at its peak value (i.e. on postnatal day 20), and if so, to compare the profile of synaptic connectivity of dopamine axon terminals found in the striatum of normal mice with that of heterozygous and homozygous weaver mutants. To that end, 20-day-old weaver homozygotes, along with age-matched weaver heterozygotes and wild-type mice were studied by electron microscopy after immunocytochemical labelling for tyrosine hydroxylase. A single micrograph of each of 1543 dopamine axon terminals was examined in total in the three genotypes; quantitative analyses of the relations of tyrosine hydroxylase immunoreactive nerve terminals were carried out in the dorsolateral striatum, which receives the dopamine projection from the substantia nigra proper. In all three genotypes, junctional contacts formed by tyrosine hydroxylase immunoreactive nerve terminals in the striatum were predominantly of the symmetrical type. In wild-type and heterozygous mice, the majority of contacts (92% and 91% respectively) were formed with dendrites and spines. In weaver mutant mice, the majority of contacts (87%) were also with dendrites and spines, but the proportion of axosomatic contacts was double that found in normal animals. The proportions of contacts that displayed junctional membrane specializations in single sections were 27% in wild-type mice, 29% in weaver heterozygotes, and 17% in homozygous weaver mutants. Taking into consideration that the plane of the section might not always have included the synaptic specialization, a stereological formula was applied. It was estimated that 85–89% of the contacts may be truly junctional in the striatum of normal and heterozygous mice, whereas only 53% may be junctional in the striatum of weaver homozygotes.The reduced incidence of junctional synapses in weaver homozygotes may suggest either inadequate synaptogenesis, or an early loss of synapses after their formation, or both. Further, the increased incidence of axosomatic contacts may be indicative of synaptic immaturity, as such contacts are commonly seen in early developmental stages. Our results support the developmental nature of the nigrostriatal deficit in weaver mutants, since the synaptic investment of striatal neuronal elements by dopamine afferents appears to be immature at the time when nigrostriatal synaptogenesis is normally complete.

Monoaminergic nerve terminals in the cerebellar cortex of purkinje cell degeneration mutant mice: Fine structural integrity and modification of cellular environs following loss of Purkinje and granule cells

The cerebellar cortex of normal and Purkinje cell degeneration mutant mice was examined by electron microscopy after fixation with potassium permanganate for the demonstration of small granular vesicles in monoaminergic nerve terminals. In control mice, monoaminergic terminals were found mainly in apposition to Purkinje cell dendrites. After the degeneration of Purkinje cells, which constitute the major target for monoaminergic fibres in the cerebellum, monoaminergic terminals persisted in the cerebellar cortex of Purkinje cell degeneration mutant mice. They were ensheathed by astroglial processes in most of the instances. They were also apposed to boutons that contained agranular vesicles, and to stellate cells in the molecular layer. Clear synaptic specializations in the form of thickening of the synaptic membranes were not observed in either control or mutant mice. It is hypothesized that the survival of monoaminergic axons following loss of their target cells may be attributed to the lack of intimate adhesion to their target elements, to a possible functional interaction with the glia, or to the integrity of the extracerebellar terminal fields of the monoamine axon collaterals.

Functional innervation of the striatum by ventral mesencephalic grafts in mice with inherited nigrostriatal dopamine deficiency

Weaver mutant mice are characterized by a decrease in striatal dopamine (DA), which is associated with a progressive loss of DA neurones in the substantia nigra. This mutant thus provides the opportunity to examine the functional effects of DA neurones grafted to the striatum in a genetic model of parkinsonism. Ventral mesencephalic tissue from normal foetuses was placed on the surface of the right dorsal striatum of adult weaver mutants. After grafting, animals were tested for methamphetamine-induced circling behaviour. Mutants with DA containing grafts displayed a significant circling bias toward the left, non-grafted side. Mutants without grafts did not display any rotational bias to either side. These results demonstrate that grafted DA containing neurones establish a functional innervation of the weaver striatum and suggest that grafting of neural tissue is a viable approach in restoring function in genetic degenerative disorders of the nigrostriatal system.

Weaver Gene Expression in Central Nervous System

Publisher Summary The anatomical phenotype of the weaver mutant mouse has been studied extensively by means of conventional histological, ultrastructural, and histochemical methods. This chapter discusses the cellular effects of the mutation in homozygosity and heterozygosity, organized by neural system and target cell type, in an attempt to offer a perspective of the acquired knowledge for the future use of the weaver mouse in addressing specific neurobiological problems. It is reported that a cohesive hypothesis on how a single gene defect brings about the developmental and degenerative phenotype of the weaver mutant mouse should underscore the types of neuronal targets involved, that is, granule cells, Purkinje cells, and mesencephalic dopamine (DA) neurons, the aspects of cellular biology that are compromised, including exit from the cell cycle, migratory processes, axonogenesis, and dendrogenesis, and the relative effects of the mutation in the heterozygous and homozygous states. Mechanisms of cerebellocortical development have been studied to a great depth. Information on mesencephalic DA neurons, specifically their genesis, pre- and postnatal ontogeny (108), and interrelationship with radial glia, can add useful dimensions to a synthetic thinking about the mutation.

Intraparenchymal grafting of cerebellar cell suspensions to the deep cerebellar nuclei of pcd mutant mice, with particular emphasis on re-establishment of a Purkinje cell cortico-nuclear projection

SummaryIn transplanting embryonic cerebellar grafts to the cerebellar cortex of “Purkinje cell degeneration” (pcd) mutant mice to replace missing Purkinje cells (PC), donor PC leave the graft and migrate to the molecular layer of the host. However, PC axons do not always reach the deep cerebellar nuclei of the host, which would be a key element in restoring much of the necessary inhibitory cortico-nuclear projection associated with normal cerebellar function. Rather, grafted PC axons often innervate a region containing deep cerebellar nuclei neurons inside the transplant, while the perikaryon migrates to the host molecular layer. In the present study, aimed at re-establishing a PC innervation of the deep nuclei, we implanted E12 cerebellar cell suspensions intraparenchymally to the deep cerebellar mass of the hosts. The development of grafted PC was monitored with 28-kDa calcium-binding protein (CaBP) immunocytochemistry at various times after transplantation. At short survival times (5 days after grafting), grafts were confined to the site of the original injection. At longer survival times (7–32 days after grafting), grafted PC formed a migratory stream that reached the cerebellar cortex of the host. The most robust graft development was seen 1 month after grafting, the longest survival time allowed in this series of experiments. At that time, clusters of donor PC were found both in the deep nuclei parenchyma and aligned along cortical folia. The orientation of the dendritic trees of PC that had migrated to the cortex was toward the pia. A CaBP-immunoreactive fibre plexus innervated the host deep cerebellar nuclei. The stream of grafted PC extended from the deep cerebellar nuclei to the cerebellar cortex of the host, indicating that donor PC could establish their axonal contacts in the deep nuclei and then move to their final cortical locality, thus recapitulating a migratory path normally taken during cerebellar ontogeny. It appears therefore that both from the pathophysiological and ontogenetic standpoints, the deep cerebellar nuclei represent the appropriate site for PC implantation in cerebellocortical atrophy.