Responses to novelty in staggerer mutant mice

Responses to novelty in normal C57BL/6 and staggerer mutant mice were recorded. The normal mice confronted a novel object in their familiar environment showed avoidance and burying responses while the staggerer mutant mice contacted it. When given the opportunity to move around freely in simultaneously presented novel and familiar environments, the mutant mice more quickly entered the novel areas than normal animals. these data reveal a significant decrease in the neophobic components of the neotic behaviour in the staggerer mice. However, since the mutant mice did not show a locomotor deficit, the impairment of neophobia seems not to be due to the gait abnormalities of these animals. The results support the view that the cerebellum may contribute to the organization of complex behaviours.     

Alteration of brain type N-glycans in neurological mutant mouse brain

We have previously detected two brain-specific and development-dependent N-glycans [H. Shimizu, K. Ochiai, K. Ikenaka, K. Mikoshiba, and S. Hase (1993) J. Biochem. 114, 334-338]. In the present study we attempted to analyze specific N-glycans detected in neurological mutant mice. N-glycans in cerebrum and cerebellum obtained from 3-week-old neurological mutant mice (jimpy, staggerer, and shiverer) were compared with those obtained from normal mice. N-glycans liberated from the cerebrum and cerebellum by hydrazinolysis-N-acetylation were pyridylaminated, and pyridylamino derivatives of N-glycans thus obtained were separated into neutral and five acidic fractions by anion exchange chromatography. PA-N-glycans in each fraction were compared with those obtained from normal mice by reversed-phase HPLC, and the following results were obtained. The ratio of the two brain-type N-glycans, Manalpha1-3(GlcNAcbeta1-2Manalpha1-6)(GlcNAcbeta1-4)Manbeta1-4GlcNAcbeta1-4(Fucalpha1-6)GlcNAc (BA-1) to GlcNAcbetaManalpha1-3(GlcNAcbeta1-2Manalpha1-6)(GlcNAcbeta1-4)Manbeta1-4GlcNAcbeta1-4(Fuca1-6)GlcNAc (BA-2), was higher in staggerer mice than other mutant mice and normal mice. Sia-Gal-BA-2, triantennary N-glycans, and bisected biantennary N-glycans were found in the cerebellum of shiverer and staggerer mice but not in normal or jimpy mice. High-mannose type N-glycans were not altered in mutant mice brains. The amounts of disialylbiantennary N-glycans and disialylfucosylbiantennary N-glycans were lower in jimpy mouse cerebellum than in normal mouse cerebellum, but were higher in shiverer mouse. Some alterations of N-glycans specific to mutations were successfully identified, suggesting that expression of component(s) of the N-glycan biosynthetic pathway was specifically affected in neurological mutations.     

Altered Ontogenesis of Muscarinic Receptors in Agranular Cerebellar Cortex

Abstract: The developmental pattern, the agonist binding properties and the cellular origin(s) of muscarinic binding sites were investigated in agranular cerebellum of x-irradiated rats, of Gunn rats with hereditary hyperbilirubinemia, and of staggerer mutant mice. The density of muscarinic binding sites was found to be higher than normal in all of these cerebellar types, indicating that granular neurons do not greatly contribute to binding of acetylcholine in the rodent cerebellum. The total number of muscarinic binding sites as measured by binding of [³H]4NMPB remains unchanged in the agranular cerebellum of x-irradiated rats. However, the number of muscarinic sites is reduced by about 30% in the agranular cerebellum of homozygous Gunn rats (jj), in which fibrous astrocytes and Purkinje cells are also damaged. In the cerebellum of staggerer mice (sg/sg), where a cascade of events leads to massive damage to mossy fibers and Golgi cells in addition to granular neurons and Purkinje cells, the content of muscarinic receptors is reduced by 50%. Thus, the number of muscarinic binding sites in the rodent cerebellum seems to depend on the integrity of the additional cell types and cellular elements, damaged in these agranular models. The ontogenetic variations in the affinity of cerebellar muscarinic sites for binding of carbamylcholine in normal and Gunn rat cerebellum were compared with those observed in x-irradiated and staggerer cerebellum, where elimination of granular neurons induces the formation of ‘heterologous’ synapses. Muscarinic binding affinity increases 10-fold during postnatal development in the cerebellum of normal and Gunn rats. In the immature x-irradiated cerebellum, the affinity of muscarinic binding sites was found to be nearly as high as that detected in the adult normal cerebellum. In contrast, cerebella of 5-month-old staggerer mice display 5-fold lower affinity than their normal counterpart values, as low as that determined in normal immature cerebellum. The characteristic ontogenetic pattern of muscarink binding is therefore indicated to be related to the formation of correct circuitry, but not to the presence of granular neurons, in the developing rat cerebellum.     

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.     

Differential IL-6 mRNA expression by stimulated peripheral macrophages of Staggerer and Lurcher cerebellar mutant mice.

We have recently reported about a hyperexpression of interleukin-1 mRNA by stimulated peripheral macrophages of several cerebellar mutant mice exhibiting complex patterns of neuronal degeneration in the cerebellum. Interestingly, studying the staggerer mutant mice, our data showed a hyperexpression of IL-1 beta mRNA and a hyperproduction of the cytokine. The hyperexpression of IL-1 beta mRNA was observed whatever the conditions of stimulation and the stimulating agent used, a hyperexpression of IL-1 alpha and TNF alpha mRNAs was also detected. This set of data suggests a hyperexcitability state of (sg/sg) macrophages. In the present study, we examined the IL-6 mRNA expression by stimulated peripheral macrophages of two cerebellar mutant mice, the staggerer and the lurcher mutants. Our results show that IL-6 mRNA is hyperexpressed in stimulated macrophages of staggerer mutant mice. On the contrary, no hyperexpression is observed in stimulated macrophages of lurcher mutant mice. These results suggest that the neuronal degeneration affecting the cerebellum in the two mutant mice do not lead to the same immunological defect at the peripheral level.     

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).     

Direct Behavioral and Neurophysiological Evidence for Retronasal Olfaction in Mice

The neuroscience of flavor perception is hence becoming increasingly important to understand food flavor perception that guides food selection, ingestion and appreciation. We recently provided evidence that rats can use the retronasal mode of olfaction, an essential element of human flavor perception. We showed that in rats, like humans, odors can acquire a taste. We and others also defined how the input of the olfactory bulb (OB) -not functionally imageable in humans- codes retronasal smell in anesthetized rat. The powerful awake transgenic mouse, however, would be a valuable additional model in the study of flavor neuroscience. We used a go/no-go behavioral task to test the mouse''s ability to detect and discriminate the retronasal odor amyl acetate. In this paradigm a tasteless aqueous odor solution was licked by water-restricted head-fixed mice from a lick spout. Orthonasal contamination was avoided. The retronasal odor was successfully discriminated by mice against pure distilled water in a concentration-dependent manner. Bulbectomy removed the mice''s ability to discriminate the retronasal odor but not tastants. The OB showed robust optical calcium responses to retronasal odorants in these awake mice. These results suggest that mice, like rats, are capable of smelling retronasally. This direct neuro-behavioral evidence establishes the mouse as a useful additional animal model for flavor research.     

Olfactory learning abilities in staggerer mutant mice.

Staggerer mutant mice were compared to non-mutant mice in two olfactory learning tasks. It was found that, in spite of a delayed acquisition compared to non-mutants, staggerer mice were able to learn an olfactory habituation task. On the other hand, staggerer presented deficits in an associative olfactory task and, contrary to non-mutants, did not learn this task. Perturbations in olfactory bulbs of staggerer mice could explain their olfactory learning deficits.     

3Development-Dependent Regulation of N-Acetyl-β-d-Hexosaminidase of Cerebellum and Cerebrum of Normal and Staggerer Mutant Mice

Distinctive activities of various glycosidases were expressed in the cerebellum and cerebral cortex of mice during their development. In particular, N-acetyl-beta-D-hexosaminidase (EC 3.2.1.30) appeared to be developmentally regulated. A transient peak of enzyme activity at postnatal day 7 was characteristic for the cerebellum, whereas the activity in the cerebral cortex gradually increased through the 1st postnatal month and was maintained at a high level of activity throughout adulthood. The regulation of N-acetylhexosaminidase activity in the developing cerebellum of the staggerer mouse deviated clearly from enzyme activities in the wild-type, whereas the activity pattern in the staggerer cerebral cortex remained unaffected. In experiments mixing wild-type and staggerer cerebellum homogenates, the specific activity was additive. Thus, involvement of inhibitors or activating molecules can be excluded. This developmentally controlled regulation or disregulation in staggerer appears to be enzyme specific, sine beta-glucosidase, alpha-glucosidase, and beta-galactosidase did not exhibit such a pattern in either normal or staggerer mice. In the mutation weaver that, like staggerer, loses the majority of its cerebellar granule cells, N-acetyl-beta-hexosaminidase activity of the cerebellum was not elevated, indicating a specific defect in staggerer rather than a general effect on lysosomal enzymes due to cell death.     

Two proteins associated with cerebellar hypoplasia in jaundiced Gunn rats

Two cerebellar proteins with apparent molecular weights of 250,000 (GR-250) and 50,000 (GR-50) are closely associated with cerebellar hypoplasia in jaundiced homozygous Gunn rats. These proteins, found in Gunn rat cerebellum (4–60 days of age) and cerebrum as well as staggerer mouse cerebellum, were studied with electrophoretic techniques. After 8 days of life, GR-250 decreased and GR-50 increased in the homozygous Gunn rat cerebellum. The pI's of GR-250 and GT-50 were 4.7–5.8 and 4.6–4.9, respectively, and the former protein was shown to bind to Concanavalin A. A comparative study between cerebella of Gunn rats and staggerer mice revealed that GR-250 and P₄₀₀, a protein generally thought to be characteristic of the Purkije cells, were identical. Evidence was also obtained showing that GR-250 was present in the Gunn rat cerebrum. GR-50 was not detectable in the staggerer mouse cerebellum but instead, a protein (MW 47,000) was found to be increased in the mutant mouse cerebellum.     

Reduced influence of penile disability on the mating capacity of male staggerer mice]

Most staggerer mutant mice do not mate spontaneously. This deficiency may be attributed to a penile disability (during erection, the penis in extension is directed backward). The main characteristics of this phenomenon and its involvement in the reproduction of the staggerer mutant have been considered in our study. Seventy-four percent (n = 66) of staggerer males presented this temporary abnormality at least once. It appeared when the males were 84 +/- 37-d old (M +/- SD). In most animals the penile abnormality was labile and did not exceed 1 wk duration in 48% (n = 32) of the males. Three males mated in spite of presenting this abnormal erection. Moreover, 25% of males (n = 23) did not present this disability; nevertheless, most of them (91%) still did not reproduce. Other mechanisms are certainly responsible for the inefficient mating. In any case, the influence of penile disability on this deficiency appears to be weak.     

Structural and immunohistological modifications in olfactory bulb of the staggerer mutant mouse.

In the present study, we describe the structural and cytological changes observed in staggerer mutant olfactory bulbs, as compared to normal mice. On the basis of photonic and ultrastructural observations we tried to define the alterations induced by the mutation: i.e. a reduction of bulb size, a reduction in the volume of three out of the six architectonic layers (glomerular, external and internal plexiform), a reduction of glomeruli size, a loss of half the mitral cells and a slight decrease in juxtaglomerular interneuron number. In staggerer, an hypertrophy of glial ensheathing cell processes was especially evident at the level of each glomerulus, whereas the density of the astrocyte network was weaker in the granular layer and the nerve layer not apparently impaired. An immunofluorescent labelling study combined with confocal scanning microscopy was performed in order to identify the cellular type and the differentiation degree of the various elements. Antibodies anti-GFAP, a protein present in both ensheathing cells and astrocytes, and anti-OMP, the specific maturation protein of the nerve layer, were used for that purpose. Data confirmed the reality of the gliosis and the persistence of the sensory component in the mutant. All the structural alterations described in staggerer olfactory bulb were in close agreement with the functional troubles previously recorded. Our results are discussed in connection with the present knowledge on embryonal origin, fetal development and adult cellular renewal of the olfactory bulb.     

Comparisons between warm and cold water swim stress in mice

The following experiments evaluated the effects of warm- or cold-water swim stress on tail-flick latencies (TFL) in mice. To first determine the appropriete control group, the TFL's of dry-vs-dunked mice were compared. Dry mice had significantly shorter TFL's than dunked mice, implying that the dampness of the mouse's tail contributed to the increase in the TFL. Therefore, dunked mice were used as the relevant control for the swum mice. Cold water swimming (2°C) produced a significant increase in the TFL; this was not blocked by the opiate antagonist naloxone (3 mg/kg sc) or potentiated by the enkephalinase inhibitor thiorphan (100 mg/kg sc). Warm water swimming (32°C) up to 3 min produced an inconsistent effect on TFL's, implying that the effects were at the threshold of detectability. Naloxone attenuated and thiorphan modestly potentiated the effects of warm water swimming on TFL's. This suggests that warm water swim stress-induced increases in mouse TFL's may involve opioid pathways, whereas cold water swim stress-induced changes in mice TFL's appear not to be opioid mediated.     

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.     

Multiple innervation of Purkinje cells by climbing fibers in the cerebellum of the adult staggerer mutant mouse

Intracellular recordings from Purkinje cells (PC) in the cerebellum of adult staggerer mutant mice revealed that the orthodromic response of PCs to juxtafastigial (JF) stimulation closely resembled a climbing fiber response (CFR). However, for most of the PCs studied, these responses were graded in a stepwise manner when the stimulus strength was increased. The underlying excitatory synaptic potentials (EPSPs) had the typical shape of EPSPs mediated through climbing fibers (CFs), but their size fluctuated in discrete steps, the highest one reaching the firing level. In the same PCs, the size of the spontaneous EPSPs fluctuated in a similar fashion and the frequency of each step was in the range of CF-mediated EPSPs. These results strongly suggest that in staggerer mice several CFs synapse with each PC instead of a single CF as in normal adults. Furthermore, the activation through some of these CFs does not reach the firing level of the corresponding PC.     

Anticipatory behaviour and stereotypical behaviour in farmed mink (Mustela vison) in the presence,absence and after the removal of swimming water

Captive animals are often provided with cage enrichments in order to improve their welfare. Swimming water is an often-discussed requirement for farmed mink. The present study aimed to give insight into the value of swimming water for farmed mink by measuring anticipatory and stereotypical behaviour in subjects raised and housed in the presence and absence of swimming water and in subjects that were deprived of swimming water.The major findings of the present experiments are that: (1) there was no significant difference in anticipatory behaviour between subjects reared and housed in the presence or absence of swimming water; nor was there a significant difference in anticipatory behaviour after removing the water for 2.5 weeks, (2) there was no significant difference in stereotypical behaviour in winter in the presence, absence and after 2.5 months deprivation of swimming water, and finally, (3) there was no significant correlation between anticipatory activity and stereotypical behaviour.The results suggest that mink might not experience consequences, in the sense of increased reward-sensitivity or stereotypy levels, due to the absence of swimming water if they never experienced this incentive before, and that swimming water and an empty bath, such as used in this experiment, might be equally valued incentives for mink.     

Thyroxine Injections Do Not Cause Premature Induction of Thymidine Kinase in sg/sg Mice

Severe hyperthyroidism from the time of birth causes a premature induction and termination of thymidine kinase activity in the cerebella of wild-type mice. This leads to elevated enzyme levels at postnatal days 5 and 6, with significantly lower levels by postnatal day 7 (which is actually the time of peak activity in normal animals). In this study, neonatal hyperthyroidism does not have significant effects on postnatal day 5, 6, or 7 enzyme levels in the neurological mutant staggerer. This is consistent with the hypothesis that thyroid hormone exerts its effects via the Purkinje cells, which are reduced in number and grossly stunted in the mutant.     

ATP-Dependent Glutamate Uptake into Synaptic Vesicles from Cerebellar Mutant Mice

The ATP-dependent glutamate uptake system in synaptic vesicles prepared from mouse cerebellum was characterized, and the levels of glutamate uptake were investigated in the cerebellar mutant mice, staggerer and weaver, whose main defect is the loss of cerebellar granule cells, and the nervous mutant, whose main defect is the loss of Purkinje cells. The ATP-dependent glutamate uptake is stimulated by low concentrations of chloride, is insensitive to aspartate, and is inhibited by agents known to dissipate the electrochemical proton gradient. These properties are similar to those of the glutamate uptake system observed in the highly purified synaptic vesicles prepared from bovine cortex. The ATP-dependent glutamate uptake system is reduced by 68% in the staggerer and 57-67% in the weaver mutant; these reductions parallel the substantial loss of granule cells in those mutants. In contrast, the cerebellar levels of glutamate uptake are not altered significantly in the nervous mutant, which has lost Purkinje cells, but not granule cells. In view of evidence that granule cells are glutamatergic neurons and Purkinje cells are GABAergic neurons, these observations support the notion that the ATP-dependent glutamate uptake system is present in synaptic vesicles of glutamatergic neurons.     

Diving behaviour and energetics in breeding little penguins (Eudyptula minor)

We present data on the diving behaviour and the energetics of breeding little penguins in Tasmania, Australia. Using an 18 m long still water canal in conjunction with respirometry, we determined the energy requirements while diving. Using electronic devices measuring dive depth or swimming speed, we investigated the foraging behaviour at sea. Cost of Transport was calculated to be minimal at the speed the birds prefer at sea (1.8 m/s) and averaged 11.1 J/kg/m (power requirements at that speed: 20.0 W/kg). Metabolic rate of little penguins resting in water was found to be 8.5 W/kg. The externally-attached devices had no significant influence on the energy expenditure.
Foraging trips can be divided into four distinct phases with different diving behaviours. A mean of 500 dives was executed per foraging trip lasting about 18 hours with 60% of this time being spent swimming. The total distance travelled averaged 73 km per day, although foraging range was about 12km. Mean swimming speed of little penguins at sea was 1.8 m/s, maximum swimming speed was 3.3 m/s. More than 50% of all dives had maxima not exceeding 2 m. Maximum depth reached was 27 m. Mean dive duration was 21 s. There were inter-sex differences in diving behaviour as well as changes in foraging behaviour over the breeding period. Aerobic dive limits (ADL) in the wild were estimated between 42 and 50 s. From the swim canal experiments we derived an ADL of 44 s. Total oxygen stores were calculated to be 45 ml O₂/kg. Only 2% of all dives exceeded the ADL. FMRs at sea were calculated to be between 1280 and 1500 kJ/kg/d according to chick size. The yearly food requirements of a breeding little penguin amount to 114 kg.