Electron microscope study of the changes in the pyriform neurocytes in the mouse cerebellum during protein-calorie deficiency

The changes in the distribution of dark, light and intermediate pyriform neurocytes (Purkinje's cells) in the cerebellum of mice which developed under the conditions of protein-caloric deficiency were assayed from the 10th to the 40th day of mouse life. In the control animals, the number of dark cells was 7 +/- 3%, of intermediate 44 +/- 7%, and that of light ones 49 +/- 7%. Under malnutrition the number of dark cells rose to 26 +/- 5% (P less than 0.01), that of intermediate cells fell to 33 +/- 6% (P less than 0.01), and the number of light cells changed insignificantly (41 +/- 6%, P less than 0.1). Electron microscopy of the ultrastructure of dark cells has disclosed dystrophic and destructive changes in the nucleus and in the main organelles of the cytoplasm. Pronounced astroglial reaction was not infrequently observed around dark cells.     

Ultrastructural changes in the neuropile of the sensorimotor cortex during long-term protein-calorie deficiency

The effect of alimentary (protein-caloric) deficiency on the brain sensomotor cortex of mice was studied during their postnatal development. It was found that malnutrition of mice from day 10 to day 40 of postnatal period brought about the most remarkable changes in synaptic junctions located on the dendritic spines. They manifested destruction of the spine apparatus, reduction of the width of synaptic slits and of postsynaptic membranes. Dystrophic and destructive alterations are frequently encountered in dendrites, axon terminals, and myelinized axons, indicating the reduced compensatory functions of the CNS.     

Ultrastructural changes in synaptic junctions of the mouse neocortex during rehabilitation after prolonged protein-calorie malnutrition

The quantitative ultrastructural study of neocortical synaptic junctions has been performed during rehabilitation after protein-caloric deficiency. It has been shown that simple food rehabilitation does not lead to absolute restoration of synaptic junctions. However, food rehabilitation with carnitine restores the ultrastructure of synaptic junctions, with the length of the active zones and the number of spine apparatus cisterns exceeding the control values. Nevertheless, synaptic cleft width and postsynaptic density remain lower than in the control group, both after simple food rehabilitation and food rehabilitation with carnitine.     

Ultrastructural characteristics of the neocortex during rehabilitation from the sequelae of long-term protein-energy deficiency

Electron microscopy of mouse neocortex was carried out during rehabilitation following long-term protein-caloric deficiency. Food rehabilitation led to partial recovery of brain ultrastructure, however, a high neuronal level of secondary lysosoms and lipofuscin bodies was preserved, with the changes in the spine apparatus and synaptic contacts persisting in neuropile. Carnitine addition to food during rehabilitation increased the number of free ribosomes in cortical neurons. A substantial development of granular endoplasmic reticulum was observed. A greater number of spine apparatus cisterns was detected, however, like in conventional rehabilitation, the width of synaptic clefts and postsynaptic densities remained narrower than in control mice.     

Long-term synaptic changes induced in the cerebellar cortex by fear conditioning

To better understand learning mechanisms, one needs to study synaptic plasticity induced by behavioral training. Recently, it has been demonstrated that the cerebellum is involved in the consolidation of fear memory. Nevertheless, how the cerebellum contributes to emotional behavior is far from known. In cerebellar slices at 10 min and 24 hr following fear conditioning, we found a long-lasting potentiation of the synapse between parallel fibers and Purkinje cells in vermal lobules V-VI, but not in the climbing fiber synapses. The mechanism is postsynaptic, due to an increased AMPA response. In addition, in hotfoot mice with a primary deficiency of the parallel fiber to Purkinje cell synapse, cued (but not contextual) fear conditioning is affected. We propose that this synapse plays an important role in the learned fear and that its long-term potentiation may represent a contribution to the neural substrate of fear memory.     

Vitamin E Concentrations in the Brains and Some Selected Peripheral Tissues of Selenium-Deficient and Vitamin E-Deficient Mice

Abstract: Weanling male CD-1 mice were fed control, vitamin E-deficient or selenium-deficient diets for periods of 12 to 20 weeks. α-Tocopherol concentrations in plasma, liver, and testes, as well as in three specific areas in the brain (cerebral hemisphere, cerebellum, and medulla plus pons) were determined by high performance liquid chromatography. Significant concentrations of α-tocopherol were found in all brain samples from vitamin E-deficient animals long after the peripheral tissues were depleted, indicating that brain is more resistant to vitamin E deficiency than peripheral tissues. Cerebellar concentrations of α-tocopherol were consistently lower than those of cerebral hemisphere and medulla-pons. Further more, the cerebellar α-tocopherol concentration sustained a larger decline than the other two brain areas within 6 weeks of vitamin E deficiency treatment. These and other data suggest that cerebellum may be more susceptible to damage from vitamin E deficiency than other parts of the brain. Selenium deficiency did not affect brain a-tocopherol concentrations during the 12 weeks of the study.     

Cerebellar regulation mechanisms learned from studies on GluRdelta2

The amino acid sequence suggests that glutamate receptor delta2 (GluRdelta2) belongs to an ionotropic GluR (iGluR) subunit family. However, neither the direct binding to glutamate nor the incorporation into any native iGluRs has been demonstrated. One prominent feature of GluRdelta2 is its predominant expression at parallel fiber-Purkinje cell synapses in the cerebellum. Knockdown or knockout of GluRdelta2 impairs synaptic plasticity, stabilization, elimination, motor control, and learning. Therefore, GluRdelta2 plays a crucial role in the cerebellar function. Several ataxic spontaneous mutant mice have defects in the GluRdelta gene. Numerous proteins interacting with GluRdelta2 have been identified. Recent in vivo studies on GluRdelta2 knockout mice shed light on the mechanism by which GluRdelta2 deficiency causes ataxia and unveiled some secondary influence of the GluRdelta2 deficiency on the function of the central nervous system. Studies on GluRdelta2 might provide unique clues regarding not only the molecular mechanism of synaptic regulations but also the functioning mechanism of the entire cerebellar system.     

Change in the staining properties of pyriform neurocytes in the mouse cerebellum during protein-calorie deficiency and subsequent rehabilitation

Quantitative analysis has been carried out on semithin sections of cerebellum cortex to investigate the relation between Purkinje cells with different dyeing properties. The number of dark Purkinje cells was found to increase after a month-long food rehabilitation of ill-fed mice. At the same time addition of carnitine to the mouse food has resulted in a significant decline in the number of dark Purkinje cells, as compared to control animals. The data obtained suggest that the rising number of dark Purkinje cells in the cerebellum cortex under conditions of malnutrition is probably due to the increased intracellular accumulation of free fatty acids.     

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.     

Nos2 inactivation promotes the development of medulloblastoma in Ptch1(+/-) mice by deregulation of Gap43-dependent granule cell precursor migration

Medulloblastoma is the most common malignant brain tumor in children. A subset of medulloblastoma originates from granule cell precursors (GCPs) of the developing cerebellum and demonstrates aberrant hedgehog signaling, typically due to inactivating mutations in the receptor PTCH1, a pathomechanism recapitulated in Ptch1(+/-) mice. As nitric oxide may regulate GCP proliferation and differentiation, we crossed Ptch1(+/-) mice with mice lacking inducible nitric oxide synthase (Nos2) to investigate a possible influence on tumorigenesis. We observed a two-fold higher medulloblastoma rate in Ptch1(+/-) Nos2(-/-) mice compared to Ptch1(+/-) Nos2(+/+) mice. To identify the molecular mechanisms underlying this finding, we performed gene expression profiling of medulloblastomas from both genotypes, as well as normal cerebellar tissue samples of different developmental stages and genotypes. Downregulation of hedgehog target genes was observed in postnatal cerebellum from Ptch1(+/+) Nos2(-/-) mice but not from Ptch1(+/-) Nos2(-/-) mice. The most consistent effect of Nos2 deficiency was downregulation of growth-associated protein 43 (Gap43). Functional studies in neuronal progenitor cells demonstrated nitric oxide dependence of Gap43 expression and impaired migration upon Gap43 knock-down. Both effects were confirmed in situ by immunofluorescence analyses on tissue sections of the developing cerebellum. Finally, the number of proliferating GCPs at the cerebellar periphery was decreased in Ptch1(+/+) Nos2(-/-) mice but increased in Ptch1(+/-) Nos2(-/) (-) mice relative to Ptch1(+/-) Nos2(+/+) mice. Taken together, these results indicate that Nos2 deficiency promotes medulloblastoma development in Ptch1(+/-) mice through retention of proliferating GCPs in the external granular layer due to reduced Gap43 expression. This study illustrates a new role of nitric oxide signaling in cerebellar development and demonstrates that the localization of pre-neoplastic cells during morphogenesis is crucial for their malignant progression.     

Stimulation of the brain NO/cyclic GMP pathway by peripheral administration of tetrahydrobiopterin in the hph-1 mouse

Mutations in GTP-cyclohydrolase I (GTP-CH) have been identified as causing a range of inborn errors of metabolism, including dopa-responsive dystonia. GTP-CH catalyses the first step in the biosynthesis of tetrahydrobiopterin (BH4), a cofactor necessary for the synthesis of catecholamines and serotonin. Current therapy based on monoamine neurotransmitter replacement may be only partially successful in correcting the neurological deficits. The reason might be that BH4 is also a cofactor for nitric oxide synthase. Using a strain of mutant GTP-CH-deficient (hph-1) mice, we demonstrate that in addition to impaired monoamine metabolism, BH4 deficiency is also associated with diminished nitric oxide synthesis in the brain (as evaluated by measuring the levels of cyclic GMP), when compared with wild-type animals. We have found a decline in the levels of BH4 with age in all animals, but no gender-related differences. We found a strong association between the levels of BH4 and cyclic GMP in hph-1 mice but not in wild-type animals. We also demonstrate that acute peripheral administration of BH4 (100 micromol/kg s.c.) in hph-1 mice significantly elevated the brain BH4 concentration and subsequently cyclic GMP levels in cerebellum, with peaks at 2 and 3 h, respectively. We suggest that BH4 administration should be considered in BH4 deficiency states in addition to monoamine replacement therapy.     

Tyrosine hydroxylase expression and Cdk5 kinase activity in ataxic cerebellum

Ataxia has been associated with abnormalities in neuronal differentiation and migration, which are regulated by Cyclin-dependent kinase 5 (Cdk5). The cerebellum of mice lacking Cdk5 or its activator, p35, resembles those of ataxic reeler and scrambler mice, suggesting that Cdk5 may contribute to ataxic pathology. As with other ataxic mice, the pogo/pogo mouse shows aberrant cerebellar tyrosine hydroxylase (TH) expression. Since Cdk5 phosphorylates and upregulates TH expression, we sought to analyze (i) Cdk5 activity in the pogo cerebellum, which exhibits abnormal TH expression, and (ii) TH expression in the cerebellum of p35-/- and p39-/- mice, which display reduced Cdk5 activity. Interestingly, we found that increased TH expression in the pogo cerebellum coincided with reduced Cdk5 activity. However, reduced Cdk5 activity in both p35-/- and p39-/- cerebellum did not correspond to defects in TH expression. Together, these suggest that abnormal TH expression in the cerebellum might be regulated by mechanisms other than Cdk5 activity.     

Cerebellar regulation mechanisms learned from studies on GluRδ2

The amino acid sequence suggests that glutamate receptor σ2 (GluRσ2) belongs to an ionotropic GluR (iGluR) subunit family. However, neither the direct binding to glutamate nor the incorporation into any native iGluRs has been demonstrated. One prominent feature of GluRσ2 is its predominant expression at parallel fiber-Purkinje cell synapses in the cerebellum. Knockdown or knockout of GluRσ2 impairs synaptic plasticity, stabilization, elimination, motor control, and learning. Therefore, GluRσ2 plays a crucial role in the cerebellar function. Several ataxic spontaneous mutant mice have defects in the GluRσ2 gene. Numerous proteins interacting with GluRσ2 have been identified. Recent in vivo studies on GluRσ2 knockout mice shed light on the mechanism by which GluRσ2 deficiency causes ataxia and unveiled some secondary influence of the GluRσ2 deficiency on the function of the central nervous system. Studies on GluRσ2 might provide unique clues regarding not only the molecular mechanism of synaptic regulations but also the functioning mechanism of the entire cerebellar system     

Alteration of gene expression profile in Niemann-Pick type C mice correlates with tissue damage and oxidative stress

Background

Niemann-Pick type C disease (NPC) is a neurovisceral lipid storage disorder mainly characterized by unesterified cholesterol accumulation in lysosomal/late endosomal compartments, although there is also an important storage for several other kind of lipids. The main tissues affected by the disease are the liver and the cerebellum. Oxidative stress has been described in various NPC cells and tissues, such as liver and cerebellum. Although considerable alterations occur in the liver, the pathological mechanisms involved in hepatocyte damage and death have not been clearly defined. Here, we assessed hepatic tissue integrity, biochemical and oxidative stress parameters of wild-type control (Npc1 ^+/+; WT) and homozygous-mutant (Npc1 ^−/−; NPC) mice. In addition, the mRNA abundance of genes encoding proteins associated with oxidative stress, copper metabolism, fibrosis, inflammation and cholesterol metabolism were analyzed in livers and cerebella of WT and NPC mice.

Methodology/Principal Findings

We analyzed various oxidative stress parameters in the liver and hepatic and cerebellum gene expression in 7-week-old NPC1-deficient mice compared with control animals. We found signs of inflammation and fibrosis in NPC livers upon histological examination. These signs were correlated with increased levels of carbonylated proteins, diminished total glutathione content and significantly increased total copper levels in liver tissue. Finally, we analyzed liver and cerebellum gene expression patterns by qPCR and microarray assays. We found a correlation between fibrotic tissue and differential expression of hepatic as well as cerebellar genes associated with oxidative stress, fibrosis and inflammation in NPC mice.

Conclusions/Significance

In NPC mice, liver disease is characterized by an increase in fibrosis and in markers associated with oxidative stress. NPC is also correlated with altered gene expression, mainly of genes involved in oxidative stress and fibrosis. These findings correlate with similar parameters in cerebellum, as has been previously reported in the NPC mice model.     

Severe impairment of cerebellum development in mice expressing a dominant-negative mutation inactivating thyroid hormone receptor alpha1 isoform

Thyroid hormone deficiency is known to deeply affect cerebellum post-natal development. We present here a detailed analysis of the phenotype of a recently generated mouse model, expressing a dominant-negative TRα1 mutation. Although hormonal level is not affected, the cerebellum of these mice displays profound alterations in neuronal and glial differentiation, which are reminiscent of congenital hypothyroidism, indicating a predominant function of this receptor isoform in normal cerebellum development. Some of the observed effects might result from the cell autonomous action of the mutation, while others are more likely to result from a reduction in neurotrophic factor production.     

A relationship between cerebellar Purkinje cells and spatial working memory demonstrated in a lurcher/chimera mouse model system

New emphasis has been placed upon cerebellar research because of recent reports demonstrating involvement of the cerebellum in non-motor cognitive behaviors. Included in the growing list of cognitive functions associated with cerebellar activation is working memory. In this study, we explore the potential role of the cerebellum in spatial working memory using a mouse model of Purkinje cell loss. Specifically, we make aggregation chimeras between heterozygous lurcher (Lc/+) mutant embryos and +/+ (wildtype) embryos and tested them in the delayed matching-to-position (DMTP) task. Lc/+ mice lose 100% of their Purkinje cells postnatally due to a cell-intrinsic gain-of-function mutation. Lc/+<->+/+ chimeras therefore have Purkinje cells ranging from 0 to normal numbers. Through histological examination of chimeric mice and observations of motor ability, we showed that ataxia is dependent upon both the number and distribution of Purkinje cells in the cerebellum. In addition, we found that Lc/+ mice, with a complete loss of Purkinje cells, have a generalized deficit in DMTP performance that is probably associated with their motor impairment. Finally, we found that Lc/+<->+/+ chimeric mice, as a group, did not differ from control mice in this task. Rather, surprisingly, analysis of their total Purkinje cells and performance in the DMTP task revealed a significant negative relationship between these two variables. Together, these findings indicate that the cerebellum plays a minor or indirect role in spatial working memory.     

Deletion of apolipoprotein E gene modifies the rate of depletion of alpha tocopherol (vitamin E) from mice brains

Our previous reports show that apolipoprotein E (apoE) influences the dynamics of alpha tocopherol (vitamin E) in brain. In this investigation, the patterns of depletion of alpha tocopherol from tissues of apoE deficient and wild type mice were compared after the animals were fed vitamin E deficient diets. Alpha tocopherol concentrations in specific regions of the brain and peripheral tissues at different times were determined by HPLC with electrochemical detection. ApoE deficiency significantly retarded the rate of depletion of alpha tocopherol from all regions of the brain. In addition, comparison of the rates of depletion of alpha tocopherol in both apoE deficient and wild type animals showed that cerebellum behaved differently from other areas such as cortex, hippocampus and striatum. This reinforces the uniqueness of cerebellum with regard to vitamin E biology. Patterns of depletion of tocopherol from peripheral tissues were different from brain. Serum tocopherol was higher in apoE deficient animals and remained higher than wild type during E deficiency. Depletion of liver tocopherol also tended to be unaffected by apoE deficiency. Our current and previous observations strongly suggest that apoE has an important role in modulating tocopherol concentrations in brain, probably acting in concert with other proteins as well.     

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.     

Subcellular distribution of carbonic anhydrase and Na+,K+-ATPase in the brain of the hyt/hyt hypothyroid mice

Activities of carbonic anhydrase and Na⁺,K⁺-ATPase in tissue homogenates and in subcellular fractions from different brain regions were studied in inherited primary hypothyroid (hyt/hyt) mice. The body weight, the weight of different brain regions, and the plasma thyroxine and triiodothyronine levels of hyt/hyt mice were significantly lower than those of the age-matched hyt/+ controls. In tissue homogenates of cerebral cortex, brain stem and cerebellum of hypothyroid mice, the activity of carbonic anhydrase (units/mg protein) was 59.2, 57.6, and 43.2%, and the activity of Na⁺,K⁺-ATPase (nmol Pi/mg protein/min) was 73.7, 74.4 and 68.7%, respectively, of that in corresponding regions of euthyroid littermates. The decrease in enzyme activity in tissue homogenates was also reflected in different subcellular fractions. In cerebral cortex and brain stem, carbonic anhydrase activity in cytosol, myelin and mitochondrial fractions of hypothyroid mice was about 45–50% of that in euthyroid mice, while in cerebellum the carbonic anhydrase activity in these subcellular fractions of hyt/hyt mice was only 33–38% of that in hyt/+ controls. Na⁺,K⁺-ATPase activity in myelin fraction of different brain regions of hyt/hyt mice was about 34–42% of that in hyt/+ mice, while in mitochondria, synaptosome and microsome fractions were about 44–52, 46–53, and 66–68%, respectively of controls. These data indicate that the activity of both carbonic anhydrase and Na⁺,K⁺-ATPase was affected more in the myelin than other subcellular fractions and more in the cerebellum than cerebral cortex and brain stem by deficiency of thyroid hormones. A reduction in the activity of transport enzymes in brain tissues as a result of thyroid hormone deficiency during the critical period of development may underlie permanent nervous disorders in primary hypothyroidism.