Brain nucleic acids and protein in various neurological mutant mice

A study was made to compare alterations in the cerebral contents of nucleic acids and protein of several mouse strains affected by different neurological mutations: jimpy, msd, quaking, reeler, weaver, and dwarf. In normal and affected jimpy and msd mice the brain components analyzed were very similar. On the other hand, the cerebral hemispheres of quaking mice showed significant decreases in total RNA and DNA, when compared with those of normal littermates. In the affected reeler and weaver mice, total protein, RNA, and DNA in the cerebellum differed markedly from controls. Protein decreased slightly, whereas nucleic acids showed no significant variation in the cerebral hemispheres of the same mutants. The cerebella and cerebral hemispheres of affected dwarf mice had wet weights and total protein contents that were about 20% lower than those of their controls; DNA did not vary significantly in the various brain regions analyzed. The decrease of DNA we report in reeler and weaver mutant cerebellum in toto quantifies the lack of cell number, in contrast to histological studies which give only semiquantitative information.     

Contents of several amino acids in the cerebellum, brain stem and cerebrum of the 'staggerer', 'weaver' and 'nervous' neurologically mutant mice.

The content of glutamate, GABA, aspartate, glycine and alanine was determined in the cerebellum, brain stem and cerebrum of three different mutant mice which have been named ‘staggerer’, ‘weaver’ and ‘nervous’ on the basis of neurological symptoms. In the ‘staggerer’ and ‘weaver’ mutants there is an almost complete absence of granule cells in the cerebellar cortex while in the ‘nervous’ mutant there is a loss of Purkinje cells (and to a lesser extent a loss of granule cells) in the cerebellar cortex. In the cerebellum of the ‘weaver’ mutant, the content of glutamate was signficantly lower (P < 0.025) than control values (8.77 ± 0.76 vs 12.0 ± 1.3 μmol/g tissue wet wt) and the contents of GABA and glycine were significantly greater than normal levels. In the cerebellum of the ‘staggerer’ mutant, the content of glutamate was significantly lower (6.62 ± 0.70 μmol/g) and the contents of glycine and alanine significantly higher than control values. In the cerebrum and brain stem regions of the staggerer mutant, weaver mutant and the normals the contents of the five amino acids were the same. The contents of glycine and alanine in the cerebellum, GARA and glycine in the brain stem and GABA and alanine in the cerebrum of the nervous mutants were higher than control values. The data are discussed in terms of a possible role for glutamate functioning as an excitatory transmitter when released from the cerebellar granule cells.     

Ontogeny of the cell adhesion molecule L1 in the cerebellum of weaver and reeler mutant mice

The ontogeny of cell adhesion molecule L1 in cerebellum was quantitatively assessed in weaver and reeler mutant mice and in heterozygous litter-mate controls. In the latter the concentration and the amount of L1 both increased from the first postnatal week to become maximum at the second. In contrast, in the weaver and reeler neurologic mutant mice, L1 decreased steadily. The L1 concentration and the amount of L1 was lower in the cerebellum of homozygous mutant mice than in litter-mate controls. The findings are consistent with L1 being a component of axonal plasma membranes. However, no evidence was found of any direct effect of thewv andrl phenotypes on L1 expression.     

Glutamate Dehydrogenase in Cerebellar Mutant Mice: Gene Localization and Enzyme Activity in Different Tissues

Many similarities of both the inheritance pattern and the neuropathology can be observed between olivopontocerebellar atrophies, or so-called multiple system atrophies (MSAs), and murine cerebellar mutations like Purkinje cell degeneration, nervous, staggerer, weaver, and reeler. Our study aimed to test whether the glutamate dehydrogenase (GDH) deficiency observed in some MSA patients could be found also in any of the murine mutants. GDH activity was assayed in several organs of these mutants, and no general deficiency was detected. By contrast, the level was found to be elevated in the cerebellum. The GDH gene was localized on mouse chromosome 14 and does not map close to any known neurological mutation in the mouse. We conclude, for the moment, that none of these cerebellar mutant mice can be considered as an animal model for GDH-deficient MSA.     

Glial Cell Markers in the Reeler Mutant Mouse: A Biochemical and Immunohistological Study

The glial cell contents of S100 protein, 2',3'-cyclic AMP, 3'-phosphohydrolase (CNP), isoenzyme II of carbonic anhydrase (CAII) and butyrylcholinesterase (BuChE) were biochemically determined in the cerebellum and cerebrum of the reeler mutant mouse. Astrocytes and oligodendrocytes, shown by this study, contain abnormal amounts of these components. The CAII concentration was significantly increased in the particulate fraction of the reeler cerebellum and cerebrum (by 50% and 89%, respectively). The BuChE specific activity was greatly increased in the reeler, by 120% for cerebellum and by 40% in cerebrum. In contrast, the S100 protein concentration was reduced in the reeler cerebellum by 40% and by 25% in cerebrum, while the CNP specific activity increased by 30% in the reeler cerebellum. In addition, the glial cell distribution was studied by immunohistological techniques with antibodies directed against S100 protein, glial fibrillary acidic protein (GFA) and CAII. Apparently the density of glial cells is not significantly affected. However, the Golgi epithelial cells were usually abnormally placed and their Bergmann fibres were less well developed.     

Alterations in Protective Enzymes Against Peroxidation in the Central and Peripheral Nervous System of Control and Dysmyelinating Mutant Mice

The activities of peroxide-detoxifying enzymes such as superoxide dismutase (SOD), glutathione peroxidase, glutathione reductase, and catalase were measured in the nervous system of neurological dysmyelinating mutants: quaking (Qk), shiverer (Shi), and trembler (Tr) mice. Cu/Zn-SOD activity was higher in the cerebellum of Qk and Shi mice (by 53% and 106%, respectively) in comparison with controls, but it was the same in the cerebellum of Tr mice and their corresponding controls. In contrast, there was no difference in the level of Cu/Zn-SOD activity in the cerebrum of Qk, Shi, and Tr mice and their respective controls. Mn-SOD activity was the same among all the mutants compared to control animals in both cerebrum and cerebellum. In Shi cerebellum, glutathione peroxidase and glutathione reductase activities were slightly decreased (a 21.6% and a 13.2% diminution, respectively), whereas catalase activity in cerebrum and cerebellum was the same among mutants and control mice. In the sciatic nerve from Tr mice, all the enzymatic activities were enhanced: sixfold increase for total SOD, and 2.4-fold, 3.5-fold, and 1.8-fold increase for glutathione peroxidase, glutathione reductase, and catalase, respectively.     

Elevated immunoreactive-somatostatin levels in the brain of ataxic mutant mice

Immunoreactive-somatostatin (IR-SRIF) levels were investigated in the brain of 4 types of ataxic mice (Rolling Mouse Nagoya, Weaver, PCD, Staggerer) with different cerebellar pathologies. IR-SRIF concentrations (ng/mg) were found to be significantly elevated in both cerebellum and cerebrum of all ataxic mutant mice, IR-SRIF (ng/organ) was found to be increased in the cerebellum and cerebrum in Rolling Mouse Nagoya and PCD compared with control mice. The gel-filtration profile (Sephadex G-50) in the cerebellar extracts of Rolling Mouse Nagoya proved to be identical to that of control mice. Three peaks of IR-SRIF were found to be uniformly elevated in Rolling Mouse Nagoya, with the highest peak coinciding with authentic somatostatin-14. The present results suggest that elevated levels of IR-SRIF in the brain may play a role in the mechanism underlying the manifestation of ataxia in ataxic mutant mice, especially in Rolling Mouse Nagoya and PCD.     

Brain DNA metabolism in myelin deficient mutant jp,jpmsd and qk mice

We studied metabolism of brain DNA in three myelin deficient mutants qk, jp and jp^msd mice. The DNA content, the in vivo incorporation of [¹⁴C]thymidine in DNA and the activity of acid DNase in tissues (cerebellum and cerebrum) from normal littermates and affected mice were compared. The results showed that neither the DNA content, the incorporation of [¹⁴C]thymidine in DNA nor the activity of acid DNase in brain were altered in qk affected mice. In jp^msd mice, however, the DNA content as well as the incorpation of thymidine in DNA were reduced in both cerebellum and cerebrum, but the activity of acid DNase was reduced in cerebrum only. In jp mice, although the DNA content was reduced in both cerebellum and cerebrum, the incorporation of thymidine in DNA and the activity of acid DNase were reduced in cerebrum only. The data suggest a) that in qk mutants DNA metabolism and hence cell (glial) proliferation is not affected; b) that in jp^msd mutants DNA synthesis, and thus the cell proliferation is reduced in cerebellum as well as in cerebrum of the affected mice and c) that in jp mutants the synthesis of DNA and the cell proliferation is reduced in cerebrum but not in cerebellum.     

Glutamic acid: A strong candidate as the neurotransmitter of the cerebellar granule cell

Free amino acids and cholinergic enzymes were investigated in the cerebellum of reeler and weaver mice in an attempt to identify the neurotransmitter characteristic of the granule cell population and to clarify any neurotransmitter abnormalities of their pre- and postsynaptic neurons induced by their depletion. The data indicate that glutamic acid may be the neurotransmitter of the granule cells. Pre- and postsynaptic neurotransmitter activity seemed not to be markedly altered in cerebellar granule cell dysgenesis.     

Loss of Sulfoglucuronyl and Other Neolactoglycolipids in Purkinje Cell Abnormality Murine Mutants

A significant reduction in the content of two members of the sulfoglucuronyl-neolacto series of glycolipids (SGGLs), 3-sulfoglucuronyl-lacto-N-neotetraosylceramide (SGGL-1) and 3-sulfoglucuronyl lacto-N-norhexaosylceramide (SGGL-2), in the cerebellum of the Purkinje cell abnormality mutants, Purkinje cell degeneration (pcd/pcd), lurcher (Lc/+), and staggerer (sg/sg), was also confirmed in the mildly affected nervous (nr/nr) mutant. The expression of SGGLs was studied during development of the pcd/pcd mutant cerebellum, and it was shown that the rate of decline in the level of SGGLs practically coincided with the loss of Purkinje cell perikarya. This indicated that SGGLs are primarily localized in Purkinje cells and that initially, at least, there is no genetic defect in the biosynthesis of SGGLs in the mutant. The precursors of SGGLs, viz., lacto-N-neotetraosylceramide (paragloboside) and lacto-N-norhexaosylceramide, as well as other glycolipids derived from these precursors, such as X-determinant fucoglycolipids and disialosyllacto-N-neotetraosylceramide, were also present in normal cerebellum. Levels of paragloboside and its other derivatives, similar to SGGLs, were also significantly reduced in the Purkinje cell abnormality mutants pcd/pcd, sg/sg, Lc/+, and nr/nr but were normal in other cerebellar mutants, such as quaking (qk/qk), weaver (wv/wv), and reeler (rl/rl), where Purkinje cells are not involved. Thus, the entire paragloboside family of glycolipids is primarily associated with Purkinje cells in the cerebellum. Although levels of monoclonal antibody HNK-1-reactive glycolipids were reduced in the Purkinje cell abnormality mutants, HNK-1-reactive glycoproteins were not affected in these mutants.     

Sulfoglucuronyl Neolactoglycolipids in Adult Cerebellum: Specific Absence in Murine Mutants with Purkinje Cell Abnormality

It is shown here that glycolipids of the sulfoglucuronyl neolacto series (SGGLs) are present in the adult rodent cerebellum. SGGLs were not detected in the cerebellar murine mutants lurcher, Purkinje cell degeneration, and staggerer, in which Purkinje cell loss is the primary defect. SGGLs were present, however, in normal amounts in weaver and reeler mutants, in which there is a major and relatively specific loss of granule cells without obvious deficiency in Purkinje cells. In the myelin-deficient quaking mutant, the expression of SGGLs also was nearly normal. The loss of SGGLs in Purkinje cell-deficient mutants was specific, since most of the major lipids were not affected significantly and only the percentage composition of other lipids, such as sulfatides and gangliosides, was altered in the mutants. These and other results strongly suggest that SGGLs and other glycolipids of the paragloboside family are localized specifically in Purkinje cells and their arbors in the adult cerebellum. This is the first demonstration of the localization of a specific glycolipid and its analogs in a specific cell type in the nervous system.     

Interleukin-1 Hyperproduction by In Vitro Activated Peripheral Macrophages from Cerebellar Mutant Mice

Several mutations in mice produce complex patterns of neuronal degeneration of the cerebellum and of its afferent pathways. In the staggerer (sg/sg) mutant, atrophy of the lymphoid organs and immunological abnormalities have been described. To search for a possible link between the neurological and the immune disorders in this mutant, we studied the production by its peripheral macrophages of interleukin-1 (IL-1), which roles in both immune and nervous systems are well established. Suspensions of peritoneal and/or spleen macrophages from mutants and their appropriate controls were stimulated in vitro by lipopolysaccharide. Northern and dot blots, performed with murine IL-1 cDNA probes, revealed a clear-cut hyperexpression of IL-1 mRNA in staggerer macrophages. An IL-1 bioassay using the IL-1-responsive D10.G4 cell line also revealed a sixfold increase of IL-1 activity in the macrophage supernatants of staggerer mutant mice. The hyperproduction was found in 3-week to 1-year-old staggerer and also in heterozygous (+/sg) mice. A similar phenomenon existed in cerebellar mutants lurcher, Purkinje cell degeneration (pcd), and to a lesser extent reeler and wobbler, but was absent in the neurological mutants weaver, jimpy, and motor end plate disease (medH). These observations establish that in several point mutations in mice, central nervous degeneration is associated with dysregulation of IL-1 production by peripheral macrophages.     

Extent of multiple innervation of purkinje cells by climbing fibers in the olivocerebellar system of weaver,reeler, and staggerer mutant mice

Multiple innervation of cerebellar Purkinje cells (PCs) by climbing fibers (CFs) has been described recently in adult weaver, reeler, and staggerer mutant mice, instead of the monoinnervation found in normal adults. In the present study, the extent of this multiple innervation was estimated by two methods, using both evoked and spontaneous activity of the olivocerebellar system. Concordant values were obtained: the mean number of CF collaterals per PC was between 3.5 and 4 in weaver and staggerer and close to 3.2 for the multiply innervated PCs of reeler mice. These values are of the same order of magnitude as those for the transient multiple innervation in developing rats (Mariani and Changeux, 1981a, b).     

Fundamental study on ataxic mice (wriggle mouse Sagami)

Wriggle mouse Sagami (WMS), a newly discovered BALB/C mouse strain, is characterized by its locomotor instability, abnormal gait pattern and neck wriggling. Although the growth of WMS mice is delayed, compared with normal BALB/C mice, the brain size corresponds to the relatively smaller body weight. In gross or histological examinations no local atrophy appears in the cerebrum, cerebellum, brain stem or spinal cord. The c-GMP level in the WMS cerebellum is decreased, but the c-AMP level is normal. The ataxic gait is not improved significantly by the administration of thyrotropin releasing hormone (TRH). These results indicate that the mechanism inducing ataxia and abnormal gait pattern in WMS may be different from those in other genetically-determined ataxic mice, e. g., Rolling mouse Nagaya (RMN), PCD, Staggerer and Reeler.     

Neuronal expression of macrophage colony stimulating factor in Purkinje cells and olfactory mitral cells of wild-type and cerebellar-mutant mice

Macrophage colony stimulating factor (M-CSF) is known to be the most effective growth factor for macrophage and microglial proliferation. In the brain tissue system, M-CSF is mainly produced in astrocytes and microglia, but is not known to occur in neurons. In the present paper, we examined the distribution of neurons expressing M-CSF in the mouse brain by immuno-histochemistry and in situ hybridization. We observed M-CSF immunoreactivity in both the cerebellum and the olfactory bulb. These positive cells were found to be Purkinje cells in the cerebellum, and mitral cells in the olfactory bulb. M-CSF mRNA expression was also confirmed to occur in these cells. Purkinje cells of reeler and weaver mutants showed M-CSF expression as seen in wild-type mice; however, those in the staggerer mutant did not. This expression in wild-type mice first appeared at postnatal day 7 and continued stably thereafter. When Purkinje cells were deprived of their climbing fibre innervation by inferior cerebellar pedunculotomy or by transplantation of cerebellar anlagen into the anterior eye chamber, the expression of M-CSF remained unchanged. These data indicate that expression of M-CSF in Purkinje cells is controlled by an intrinsic mechanism and could, therefore, be a new marker of postnatal development in rodent cerebella. The absence of M-CSF expression in the staggerer mutant is possibly due to developmental arrest in the early postnatal period.     

Reduced histone levels induced by "reeler" and "weaver" mutations in the mouse cerebellum.

Five major protein bands present in the polyacrylamide gel electrophoresis pattern of normal cerebellum are apparently absent or decreased in amounts in both reeler and weaver mutant cerebellar tissues. All five bands were identified as histones and the deficiencies related to the decreased cerebellar cellularity produced by both mutations. These results, therefore, rule out an earlier suggestion that two of these proteins are granular cell specific proteins (1). Preliminary evidence for high levels of F1 histone in the nuclei of cerebellar cells, which appear to be reduced in the reeler syndrome, is presented.     

Galactosyltransferase Defects in Reeler Mouse Brains

Galactosyltransferase activities were examined in the cerebellum, cerebral cortex, and brain stem of reeler and wild-type mice. Galactosyltransferase assays were optimal for all required substrates, linear with incubation time, and proportional to protein concentration. In brain areas affected by the reeler mutation (i.e., cerebral cortex and cerebellum), galactosylation of both endogenous and exogenous glycoprotein acceptors was greatly reduced in reeler relative to controls. On the other hand, glycosylation of endogenous glycolipids was low, and equal between reeler and wild-type. Galactosyltransferase activities were similar, though not identical, in reeler and wild-type brain stems, which are phenotypically normal in reeler mice. Glucosyltransferase, beta-galactosidase, beta-N-acetylglucosaminidase, acid phosphatase, and lactate dehydrogenase specific activities were all unaffected in reeler cerebella, while galactosyltransferase activity was 52% of control. Inhibition of either UDPgalactose hydrolysis or beta-galactosidase had no effect on galactosyltransferase activity. The spectrum or galactosyltransferase deficiencies in reeler suggests that this enzyme is associated with the development of young granule cells.     

Expression of glial antigens C1 and M1 in developing and adult neurologically mutant mice

The distribution of two glial antigens (C1 and M1) has been studied by indi-rect immunofluorescence during postnatal development of the cerebella of normal and neurologically mutant mice (weaver, staggerer, reeler, Purkinje cell degeneration, and wobbler). During the first postnatal week of normal development, C1 antigen is expressed in ependyma, Bergmann glial fibers (BG), and astrocytes of the internal granular layer and white matter. After day 10, C1 antigen is restricted to BG and ependymal cells. During the sec-ond and third week, BG undergo a transient loss of C1 antigen that starts in medioventral areas and spreads in a gradient dorsally and laterally. In reeler, weaver, and staggerer, C1 antigen expression is normal during the first postnatal week, and subsides in BG in a similar spatial gra- dient as described for the normal littermates. However, the loss of C1 anti-gen in BG occurs earlier (first in reeler, then in weaver, and last in staggerer) and is not reversible as it is in normal mice. In Purkinje cell de-generation, C1 antigen expression is diminished in BG after the onset of be-havioral abnormalities. Wobbler is normal with respect to C1 antigen ex-pression at adult ages. M1 antigen is detectable in white matter astrocytes from postnatal day 7 on, and persists in these cells into adulthood. Astrocytes of the internal granular layer and BG express M1 antigen only transiently in normal mice during the second and third weeks. The appearance of M1 antigen in BG occurs in a spatiotemporal gradient, matching the one in which C1 antigen disappears. M1 antigen expression is abnormally maintained in BG of reeler, staggerer, and weaver. In Purkinje cell degeneration, M1 antigen is ex-pressed abnormally at the onset of behavioral abnormalities first in.astro-cytes of the internal granular layer and, with growing age, increasingly also in BG. In wobbler, BG do not express M1 antigen. However, astrocytes of the granular layer are abnormally M1 antigen-positive.     

Presence of protein I, a phosphoprotein associated with synaptic vesicles, in cerebellar granule cells

Abstract: The cerebellar levels of Protein I, a synapse-specific neuronal phosphoprotein, have been investigated in the cerebellar mouse mutants staggerer ( sg ), weaver ( wv ), nervous ( nr ), and Purkinje cell degeneration ( pcd ). The Protein I concentration was reduced by about 66% in sg and wv mutants, representing a 90% loss of Protein I per cerebellum. A heterozygote effect was observed in the wv mutant. These results indicate that a great majority of Protein I in the normal cerebellum may be present in the granule cells. in nr mutants the cerebellar Protein I concentration was reduced by only 12% in 62-day-old mice, suggesting that Purkinje cells contribute little to cerebellar Protein I. However, a greater reduction was observed in pcd mutants, which may reflect on the nature of the pcd mutation.     

2-Deoxyglucose Incorporation in the Cerebellum of Weaver and Nervous Mutant Mice

Abstract: The 2-deoxyglucose autoradiographic method has been used to study activity in cerebellum of the weaver and nervous mutant mice. Patterns of 2-deoxyglucose incorporation into the cerebral hemispheres from weaver and nervous strains did not differ significantly from those of the controls. In the normal cerebellum, 2-deoxyglucose incorporation was maximal in the granular layer, where mossy fibers form synapses with the dendrites of granule cells. In the cerebellum of nervous mice, which lacks Purkinje cells, the incorporation of the 2-deoxyglucose was maximal in the granular layer, but the incorporation into the molecular layer appeared less than in the control. The incorporation into the cerebellum from weaver, which lacks granule cells, was much higher than that of the control, the maximal incorporation being found in the Purkinje cell layer and in cell masses located in the white matter. These data suggest that the heterologous synapses that mossy fibers or climbing fibers form with the cells in the Purkinje cell layer and the cells in the white matter in the weaver cerebellum are functional.