Phenotypic effects of the weaver gene are evident in the embryonic cerebellum but not in the ventral midbrain

Role of Nuclear Receptors in Central Nervous System Development and Associated Diseases

The nuclear hormone receptor (NHR) superfamily is composed of a wide range of receptors involved in a myriad of important biological processes, including development, growth, metabolism, and maintenance. Regulation of such wide variety of functions requires a complex system of gene regulation that includes interaction with transcription factors, chromatin-modifying complex, and the proper recognition of ligands. NHRs are able to coordinate the expression of genes in numerous pathways simultaneously. This review focuses on the role of nuclear receptors in the central nervous system and, in particular, their role in regulating the proper development and function of the brain and the eye. In addition, the review highlights the impact of mutations in NHRs on a spectrum of human diseases from autism to retinal degeneration.

Principal component and cluster analysis of morphological variables reveals multiple discrete sub-phenotypes in weaver mouse mutants

The present study evaluates the usefulness of the principal component analysis-based cluster analysis in the categorization of several sub-phenotypes in the weaver mutant by using several morphological parameters from the cerebellar cortex of control, heterozygous (+/wv) and homozygous (wv/wv) weaver mice. The quantified parameters were length of the cerebellar cortex, area of the external granular layer, area of the molecular layer, number of the external granular layer cells (EGL), and number of Purkinje cells (PCs). The analysis indicated that at postnatal day 8, the genotype +/wv presented three sub-phenotypes tagged as +/wv (0), +/wv (1) and +/wv (2), whereas two sub-phenotypes designated as wv (0)/wv (1) and wv (0)/wv (2) were identified in the genotype wv/wv. The number of PCs for the genotype +/wv and the number of EGL cells for the genotype wv/wv were the variables that discriminated the best among sub-phenotypes. Each one of the sub-phenotypes showed specific abnormalities in the cytoarchitecture of the cerebellar cortex as well as in the foliar pattern. In particular, the wv (0)/wv (1) and wv (0)/wv (2) sub-phenotypes had the most altered cytoarchitectonics, followed by the +/wv (2) sub-phenotype and then by the +/wv (1) one. The sub-phenotype +/wv (0) was the less affected one. Apart from reporting for the first time the coexistence of several sub-phenotypes in the weaver mutant, our approach provides a new statistical tool that can be used to assess cerebellar morphology.

Transplantation of embryonic and adult neural stem cells in the granuloprival cerebellum of the weaver mutant mouse

Numerous studies have explored the potential of different stem and progenitor cells to replace at-risk neuronal populations in a variety of neurodegenerative disease models. This study presents data from a side-by-side approach of engrafting two different stem/progenitor cell populations within the postnatal cerebellum of the weaver neurological mutant mouse--cerebellar-derived multipotent astrocytic stem cells and embryonic stem cell-derived neural precursors--for comparative analysis. We show here that both donor populations survive, migrate, and appear to initiate differentiation into neurons within the granuloprival host environment. Neither of these disparate stem/progenitor cell populations adopted significant region-specific identities, despite earlier studies that suggested the potential of these cells to respond to in vivo cues when placed in a permissive/instructive milieu. However, data presented here suggest that molecular and cellular deficits present within weaver homozygous or heterozygous brains may promote a slightly more positive donor cell response toward acquisition of a neuronal phenotype. Hence, it is likely that a fine balance exists between a compromised host environment that is amenable to cell replacement and that of a degenerating cellular milieu where it is perhaps too deleterious to support extensive neuronal differentiation and functional cellular integration. These findings join a growing list of studies that show successful cell replacement depends largely on the interplay between the potentiality of the donor cells and the specific pathological conditions of the recipient environment, and that emergent therapies for neurological disorders involving the use of neural stem cells still require refinement.

Purkinje cell age-distribution in fissures and in foliar crowns: a comparative study in the weaver cerebellum

Generation and settling of Purkinje cells (PCs) are investigated in the weaver mouse cerebellum in order to determine possible relationships with the fissuration pattern. Tritiated thymidine was supplied to pregnant females at the time that these neurons were being produced. Autoradiography was then applied on brain sections obtained from control and weaver offspring at postnatal (P) day 90. This makes it possible to assess the differential survival of neurons born at distinct embryonic times on the basis of the proportion of labeled cells located at the two foliar compartments: fissures and foliar crowns. Our data show that throughout the surface contour of the vermal lobes, generative programs of PCs were close between wild type and homozygous weaver. Similar data were found in the lobules of the lateral hemisphere. On the other hand, the loss of PCs in weaver cerebella can be related to foliar concavities or convexities depending on the vermal lobe or the hemispheric lobule studied. Lastly, we have obtained evidence that late-generated PCs of both normal and mutant mice were preferentially located in fissures. These quantitative relationships lead us to propose a model in which the final distribution of PCs through the vermal contour would be coupled to two factors: the cortical fissuration patterning and a "time-sequential effect" of weaver mutation.

The weaver gene expression affects neuronal generation patterns depending on age and encephalic region

Cell generation and survival are investigated in three different neuronal populations of weaver mice: Purkinje and fastigial neurons in the cerebellum, and dopaminergic neurons in the substantia nigra pars compacta. Tritiated thymidine was supplied to pregnant females at the time that these neurons were being produced. Autoradiography was then applied on brain sections obtained from the control and weaver offspring at postnatal (P) day 8 and 90. This makes it possible to assess the differential survival of neurons that were born at distinct embryonic times on the basis of the proportion of labeled cells at two postnatal ages. When labeling profiles were measured at P8, the inferred time of origin was similar between +/+ and wv/wv genotypes for each neuronal population considered. The same occurred at P90 for Purkinje or fastigial neurons, but the labeling profiles of midbrain neurons were different between wild type and weaver homozygotes. There is already a substantial reduction in the number of Purkinje and fastigial cells at P8, but loss of dopaminergic neurons was only detected in 90-day-old weavers and, therefore, vulnerability is built into this midbrain neural system during its late postnatal development. Our results show that depletion of Purkinje and fastigial cells is random with respect to the time of their birth, whereas the weaver gene seems to be specifically targeting the late-generated dopaminergic neurons.

Regional differences in the Purkinje cells settled pattern: a comparative autoradiographic study in control and homozygous weaver mice

To determine whether Purkinje cells located in the vermis and the lateral hemispheres of weaver mice homozygotes are distributed according to precise neurogenetic gradients, [3H]thymidine autoradiography was applied on sections of homozygous weaver mice and normal controls on postnatal day 90. The experimental animals were the offspring of pregnant dams injected with [3H]thymidine on embryonic days 11-12, 12-13, 13-14, and 14-15. The results indicate that, at the level of the vermis, neurogenetic gradients were similar for wild-type and homozygous weaver in each lobe studied of the cerebellar cortex. The same was found for the lobulus simplex and for the ansiform and paramedian lobules when the lateral hemisphere was considered. In the vermis of both experimental groups, the anterior and inferior lobes have more late-generated Purkinje cells than the central and posterior lobes, while in the lateral hemisphere, the lobulus simplex and the ansiform lobule present more early generated Purkinje cells than the paramedian lobule. In weaver homozygotes, the most important deficit of Purkinje cells, in the region of the vermis, was observed in the central lobe; depletion was less observable in the anterior lobe and least observable in the posterior and inferior lobes. In the lateral hemispheres, the most important loss of Purkinje cells was observed in the paramedian lobule, followed by the lobulus simplex. The ansiform lobule presented values that showed no statistical difference between control and homozygous weaver. When Purkinje cells were registered in the entire sections, no significant differences were observed between the two experimental groups. This was due to a considerable volume of the weaver homozygote cerebellar tissue, which has no counterpart in the control mice, compensating for the neuronal loss observed in the other studied areas of the lateral hemisphere.

Evidence that the loss of Purkinje cells and deep cerebellar nuclei neurons in homozygous weaver is not related to neurogenetic patterns

To determine whether the neurogenetic patterns of Purkinje cells and deep cerebellar nuclei neurons were normal in weaver homozygotes and whether the degeneration of those neuronal types was linked to their time of origin, [3H] thymidine autoradiography was applied on sections of homozygous weaver mice and normal controls on postnatal day 90. The experimental animals were the offspring of pregnant dams injected with [3H] thymidine on embryonic days 11-12, 12-13, 13-14 and 14-15. The results show that the onset of neurogenesis, its pattern of peaks and valleys, and its total span were similar between wild type and homozygous weaver in the cerebellar areas analyzed, indicating that the loss of Purkinje cells and deep cerebellar nuclei neurons is not related to neurogenetic patterns. In weaver homozygotes, the loss of Purkinje cells and deep cerebellar nuclei neurons followed a lateral to medial gradient of increasing severity. Thus, the vermis and the fastigial nucleus, which are medially located, presented the most important neuron loss, whereas in the lateral hemisphere and the dentate nucleus, neuron loss was spared.

The weaver gene has no effect on the generation patterns of mesencephalic dopaminergic neurons

To determine if the weaver gene has action on late-generated neurons in midbrain areas on postnatal day (P) 8 [(3)H] thymidine autoradiography and tyrosine hydroxylase immunohistochemistry were combined in the same tissue section in homozygous weaver mice and normal controls. The experimental animals were the offspring of pregnant dams injected with [3H] thymidine on embryonic days (E)11-12, E12-13, E13-14 and E14-15. Both the span of neurogenesis and the neurogenetic timetables of dopaminergic neurons were similar between wild-type and homozygous weavers in all midbrain areas analyzed. No loss of late-generated dopaminergic neurons was observed. The cytoarchitecture of the midbrain dopaminergic cell groups were also the same in both experimental groups indicating that cell migration, settling, and cytodifferentiation proceeds normally in spite of the presence of the weaver gene.

Evidence of elevated intracellular calcium levels in weaver homozygote mice

1. A mutation in the G-protein-linked, inwardly rectifying K+ channel GIRK2 leads to the loss of cerebellar and dopaminergic mesencephalic neurons in weaver mice. The steps leading to cell death are not well understood but may involve constitutive influx of Na+ and Ca2+ into the neurons. 2. We found that resting [Ca2+]i was dramatically higher in cerebellar neurons from weaver mice compared to wild-type neurons. 3. High-K+ stimuli elicited much smaller changes in [Ca2+]i in weaver cerebellar neurons compared to wild-type neurons. 4. weaver cerebellar granule cells could be rescued from cell death by the GIRK2wv cationic channel blocker, QX-314. 5. QX-314 lowered resting intracellular Ca2+ levels in weaver cerebellar granule cells. 6. These results suggest that changes in resting [Ca2+]i levels and alterations in K+ channel function are most likely to contribute to the developmental abnormalities and increased cerebellar cell death observed in weaver mice.

The weaver GIRK2 mutation leads to decreased levels of serum thyroid hormone: characterization of the effect on midbrain dopaminergic neuron survival

The selective neurodegenerative changes occurring in the weaver mutant cerebellum and midbrain are linked to a point mutation in an inward rectifying potassium channel (GIRK2). However, given that GIRK2 is widely expressed in the CNS, it is not understood why this mutation only leads to neuroanatomically selective and developmentally specific neuronal cell death. Here we show that the phenotype of the weaver mutant mouse includes hypothyroidism, which is associated with delays in somatic development and decreased expression of striatal transforming growth factor alpha (TGF-alpha). Since thyroid hormone has major effects on brain development, further studies were performed to address whether some of pathological changes detected the weaver mutant mouse are due to the reduced thyroid hormone levels. We observed that daily thyroid hormone replacement was able to stimulate somatic growth and restore TGF-alpha expression to wild-type levels, indicating that while these mice are responsive to thyroid hormone they possibly have a defect in the ability to regulate its release at the level of the hypothalamic pituitary axis. However, when we assessed whether thyroid hormone replacement could rescue midbrain dopaminergic neurons we found that this treatment accelerated rather than attenuated neurodegeneration. We did not observe that thyroid hormone was able to directly regulate expression of GIRK2 mRNA levels in the midbrain and therefore, speculate that the mechanism by which thyroid hormone accelerates midbrain dopaminergic neurodegeneration is by enhancing the maturation of the striatonigral inputs. In summary, we detected reduced levels of serum thyroid hormone in the weaver mutant mouse, which appears to be responsible for delays in somatic growth and the onset of neurodegenerative changes in the midbrain.

The weaver mouse gain-of-function phenotype of dopaminergic midbrain neurons is determined by coactivation of wvGirk2 and K-ATP channels

The phenotype of substantia nigra (SN) neurons in homozygous weaver (wv/wv) mice was studied by combining patch-clamp and single-cell RT-multiplex PCR techniques in midbrain slices of 14-d-old mice. In contrast to GABAergic SN neurons, which were unaffected in homozygous weaver mice (wv/wv), dopaminergic SN neurons possessed a dramatically altered phenotype with a depolarized membrane potential and complete loss of spontaneous pacemaker activity. The gain-of-function phenotype was mediated by a large, nonselective membrane conductance exclusively present in (wv/wv) dopaminergic SN neurons. This constitutively activated conductance displayed a sensitivity to external QX-314 (IC(50) = 10.6 microM) very similar to that of heterologously expressed wvGirk2 channels and was not further activated by G-protein stimulation. Single-cell Girk1-4 expression profiling suggested that homomeric Girk2 channels were present in most dopaminergic SN neurons, whereas Girk2 was always coexpressed with other Girk family members in GABAergic SN neurons. Surprisingly, acute QX-314 inhibition of wvGirk2 channels did not induce wild-type-like pacemaker activity but instead caused membrane hyperpolarization. Additional application of a blocker of ATP-sensitive potassium channels (100 microM tolbutamide) induced wild-type-like pacemaker activity. We conclude that the gain-of-function weaver phenotype of dopaminergic substantia nigra neurons is mediated by coactivation of wvGirk2 and SUR1/Kir6. 2-mediated ATP-sensitive K(+) channels. We also show that in contrast to wild-type neurons, all (wv/wv) dopaminergic SN neurons expressed calbindin, a calcium-binding protein that marks dopaminergic SN neurons resistant to neurodegeneration. The identification of two ion channels that in concert determine the weaver phenotype of surviving calbindin-positive dopaminergic SN neurons will help to understand the molecular mechanisms of selective neurodegeneration of dopaminergic SN neurons in the weaver mouse and might be important in Parkinson's disease.

A cell cycle alteration precedes apoptosis of granule cell precursors in the weaver mouse cerebellum

A missense mutation in the gene coding for the G-protein-activated inwardly rectifying potassium (GIRK) channel, GIRK2, is responsible for apoptosis in the external germinal layer (EGL) of the cerebellum and a nonapoptotic death of midbrain dopaminergic neurons in the weaver (wv) mouse. Failure of axonogenesis and migration are considered to be the primary consequences of GIRK2 channel malfunction in the cerebellum. We investigated whether a disruption of the cell cycle precedes the failure of migration and axonogenesis and leads to massive apoptosis. To this end, immunohistochemistry and immunoblotting for PCNA, Cdk4, cyclin D, cyclin A, and the Cdk inhibitor p27/kip1, as well as in situ end-labeling for apoptotic DNA fragmentation, were applied to cerebella of P7-P21+/+, wv/+, and wv/wv mice. In +/+ and wv/+ mice, the expression of cell cycle proteins was limited to the outer, premigratory zone of the EGL. Antibodies to p27, a marker of cell differentiation, gave a reverse staining pattern. Due to migration delay, patches of p27-positive cells persisted in the outer EGL in P21 wv/+ mice. On the contrary, marked cell cycle up-regulation and absence of p27 occurred throughout the EGL at all ages in wv/wv mice, indicating an inability to switch off the cell cycle. Mitotic index evaluation showed that cell cycle activation was unrelated to proliferative events. Cell cycle proteins were not expressed in the substantia nigra, suggesting that nonapoptotic death of mature dopaminergic neurons is not preceded by abortive cell cycle re-entry. Our data show that abnormalities of the cell cycle in wv/wv cerebellum represent a major and early consequence of GIRK2 channel malfunction and may strongly influence the susceptibility of EGL cells to apoptosis. These observations may help in understanding the pathogenesis of human neurological channelopathies.

Characterization of murine Girk2 transcript isoforms: structure and differential expression

A mutation in the G-protein-linked inwardly rectifying K+ channel 2 gene (Girk2) is the cause of the weaver mouse phenotype. We determined that the originally published Girk2 transcript is composed of five exons. The primary coding exon (designated exon 4a in our system) encodes over two-thirds of the protein. Five different full-length Girk2 transcript isoforms (designated Girk2-1, Girk2A-1, Girk2A-2, Girk2B, and Girk2C) originating from different transcriptional start sites and/or alternative splicing were isolated by cDNA RACE. Several of the transcripts were predicted to encode truncated proteins that may lack some of the G-proteincoupling sequence. Northern blotting and in situ hybridization studies with transcript-specific probes indicated that the transcripts were differentially expressed in both normal and weaver mice. All transcripts tested were expressed in the three major targets of action of the weaver mutation: cerebellum, substantia nigra, and testis. Two of the transcripts, Girk2A-1 and Girk2A-2, encode identical proteins and have a distinct pattern of expression in testis, which suggests that they are associated with specific stages of spermatogenesis. An additional transcript, Girk2D, appears to be brain-specific, not polyadenylated, and highly expressed in cerebellar granule cells.