Manipulation of dopamine metabolism contributes to attenuating innate high locomotor activity in ICR mice.

Attention-deficit hyperactivity disorder (ADHD) is defined as attention deficiency, restlessness and distraction. The main characteristics of ADHD are hyperactivity, impulsiveness and carelessness. There is a possibility that these abnormal behaviors, in particular hyperactivity, are derived from abnormal dopamine (DA) neurotransmission. To elucidate the mechanism of high locomotor activity, the relationship between innate activity levels and brain monoamines and amino acids was investigated in this study. Differences in locomotor activity between ICR, C57BL/6J and CBA/N mice were determined using the open field test. Among the three strains, ICR mice showed the greatest amount of locomotor activity. The level of striatal and cerebellar DA was lower in ICR mice than in C57BL/6J mice, while the level of L-tyrosine (L-Tyr), a DA precursor, was higher in ICR mice. These results suggest that the metabolic conversion of L-Tyr to DA is lower in ICR mice than it is in C57BL/6J mice. Next, the effects of intraperitoneal injection of (6R)-5, 6, 7, 8-tetrahydro-l-biopterin dihydrochloride (BH4) (a co-enzyme for tyrosine hydroxylase) and L-3,4-dihydroxyphenylalanine (L-DOPA) on DA metabolism and behavior in ICR mice were investigated. The DA level in the brain was increased by BH4 administration, but the increased DA did not influence behavior. However, L-DOPA administration drastically lowered locomotor activity and increased DA concentration in several parts of the brain. The reduced locomotor activity may have been a consequence of the overproduction of DA. In conclusion, the high level of locomotor activity in ICR mice may be explained by a strain-specific DA metabolism.

Naloxone-precipitated morphine withdrawal behavior and brain IL-1ß expression: comparison of different mouse strains.

The development of opioid dependence involves classical neuronal opioid receptor activation and is due in part to engagement of glia causing a proinflammatory response. Such opioid-induced glial activation occurs, at least in part, through a non-classical opioid mechanism involving Toll-like-receptor 4 (TLR4). Among the immune factors released following the opioid-glia-TLR4 interaction, interleukin-1ß (IL-1ß) plays a prominent role. Previous animal behavioral studies have demonstrated significant heterogeneity of chronic morphine-induced tolerance and dependence between different mouse strains. The aim of this study was to investigate whether the heterogeneity of chronic opioid-induced IL-1ß expression contributes to differences in opioid tolerance and withdrawal behaviors. Chronic morphine-induced tolerance and dependence were assessed in 3 inbred wild-type mouse strains (Balb/c, CBA, and C57BL/6) and 2 knockout strains (TLR4 and MyD88). Analysis of brain nuclei (medial prefrontal cortex, cortex, brain stem, hippocampus, and midbrain and diencephalon regions combined) revealed that, of inbred wild-type mice, there are significant main effects of morphine treatment on IL-1ß expression in the brain regions analyzed (p<0.02 for all regions analyzed). A significant increase in hippocampal IL-1ß expression was found in C57BL/6 mice after morphine treatment, whilst, a significant decrease was found in the mPFC region of wild-type Balb/c mice. Furthermore, the results of wild-type inbred strains demonstrated that the elevated hippocampal IL-1ß expression is associated with withdrawal jumping behavior. Interestingly, knockout of TLR4, but not MyD88 protected against the development of analgesic tolerance. Gene sequence differences of IL - 1ß and TLR4 genes alone did not explain the heterogeneity of dependence behavior between mouse strains. Together, these data further support the involvement of opioid-induced CNS immune signaling in dependence development. Moreover, this study demonstrated the advantages of utilizing multiple mouse strains and indicates that appropriate choice of mouse strains could enhance future research outcomes.

Circadian variation of mouse aqueous humor protein.

PURPOSE: The first aim was to document the 24 h pattern of total protein concentration in aqueous humor of the C57BL/6J mouse strain under various environmental light-dark conditions. The second aim was to determine the diurnal/nocturnal change of aqueous humor protein concentration in the CBA/CaJ mouse strain reported to show a unique absence of diurnal/nocturnal elevation of intraocular pressure (IOP). METHODS: Mice of both strains were entrained to a daily 12 h diurnal/light (6 AM to 6 PM) and 12 h nocturnal/dark cycle. Total protein concentrations of aqueous humor were determined using specimens collected from C57BL/6J mice every 4 h under standard light-dark, acute constant dark, and acute constant light conditions. Aqueous humor protein concentrations in CBA/CaJ mice were determined at three diurnal times and three nocturnal times. RESULTS: The C57BL/6J mouse strain showed a higher aqueous humor protein concentration during the diurnal period than during the nocturnal period under standard light-dark conditions. This pattern persisted under acute constant dark and was modulated under acute constant light. The CBA/CaJ mouse strain showed a similar diurnal/nocturnal decrease of total aqueous humor protein concentration. CONCLUSIONS: Endogenous circadian variation of aqueous humor protein concentration occurs in the C57BL/6J mouse strain. The nocturnal concentration is significantly lower than the diurnal concentration. A similar diurnal/nocturnal decrease of aqueous humor protein concentration occurs in the CBA/CaJ mouse strain, indicating that this change of aqueous humor protein is unrelated to the diurnal/nocturnal pattern of IOP.

Firing features and potassium channel content of murine spiral ganglion neurons vary with cochlear location.

Neurons from varied regions of the central nervous system can show widely divergent responses to electrical stimuli that are determined by cell-specific differences in ion channel composition. The well-ordered and highly characterized peripheral auditory system allows one to explore the significance of this diversity during the final stages of postnatal development. We examined the electrophysiological features of murine spiral ganglion neurons in vitro at a time when recordings could be made from the cell bodies before myelination. These cells carry information about sound stimuli from hair cell receptors in the basilar membrane and are arranged tonotopically. Spiral ganglion neuron responses to depolarizing current injection were assessed with whole-cell current clamp recordings from cells that were isolated separately from the apical and basal thirds of the mouse cochlea. These cells displayed systematic variation in their firing. Apex neurons (low frequency coding) showed longer latency, slowly adapting responses, whereas base neurons (high frequency coding) showed short latency, rapidly adapting responses to the same stimuli. This physiological diversity was mirrored by regional differences in ion channel content assessed immunohistochemically. Apex neurons had a preponderance of Kv4.2 subunits, whereas base neurons possessed greater levels of K(Ca), Kv1.1, and Kv3.1 subunits. Taken together, these results indicate that the distribution of a set of voltage-gated potassium channels may relate specifically to a particular range of coding frequencies. These studies also suggest that intrinsic properties of spiral ganglion neurons can contribute to the characteristic responses of the peripheral auditory system. Their potential role in development and adult function is discussed.

In vivo and in vitro glycogenic effects of methionine sulfoximine are different in two inbred strains of mice.

We investigated the relationship between brain glycogen anabolism and methionine sulfoximine (MSO)-induced seizures in two inbred mouse strains that presented differential susceptibility to the convulsant. CBA/J was considered a MSO-high-reactive strain and C57BL/6J a MSO-low-reactive strain. Accordingly, the dose of MSO needed to induce seizures in CBA/J mice is lower than that in C57BL/6J mice, and CBA/J mice which had seizures, died during the first convulsion. In addition, the time--course of the MSO effect is faster in CBA/J mice than that in C57BL/6J mice. Analyses were performed in C57BL/6J and CBA/J mice after administration of 75 (subconvulsive dose) and 40 mg/kg of MSO (subconvulsive dose, not lethal dose), respectively. In the preconvulsive period, MSO induced an increase in the brain glycogen content of C57BL/6J mice only. Twenty-four hours after MSO administration, the brain glycogen content increased in both strains. The activity and expression of fructose-1,6-bisphosphatase, the last key enzyme of the gluconeogenic pathway, were increased in MSO-treated C57BL/6J mice as compared to control mice, at all experimental time points, whereas they were increased in CBA/J mice only 24 h after MSO administration. These latter results correspond to CBA/J mice that did not have seizures. Interestingly, the differences observed in vivo were consistent with results in primary cultured astrocytes from the two strains. This data suggests that the metabolism impairment, which was not a consequence of seizures, could be related to the difference in seizure susceptibility between the two strains, depending on their genetic background.

Expression of connexin 30 in the developing mouse cochlea.

Mutations in the GJB6 gene encoding connexin 30 (Cx30) can cause dominant forms of nonsyndromic deafness. By studying immunohistochemical localization of Cx30 in the mouse cochlea at different ages from 0 to 30 days after birth, we found that the expression of Cx30 is nearly the same as that of Cx26. These findings suggest that as well as Cx26, Cx30 may also contribute to the generation and maturation of endocochlear potential.

Differential metabolite accumulation may be the cause of strain differences in sensitivity to streptozotocin-induced beta cell death in inbred mice.

Inbred strains of mice vary in their sensitivity to the diabetogenic effects of streptozotocin (STZ). To investigate the basis for this strain difference we exposed islet cells from two strains of mice that differ in sensitivity to the drug. We examined them morphologically and measured islet NAD + NADH content, streptozotocin metabolite accumulation, glucose transport capacity, Glut2 levels and medium nitrite accumulation. C57bl/6J mice were more sensitive to STZ than Balb/c mice as judged by the extent of pancreatic insulin depletion and beta cell death, in vivo and in vitro. The mode of cell death was necrosis. After a 30-min in vitro exposure to the drug the more sensitive C57bl/6J islets contained higher levels of streptozotocin metabolites and less NAD + NADH than the more resistant Balb/c islets. The lack of any strain differences in 3-O-methyl glucose transport, Glut2 levels and medium nitrite accumulation suggested that STZ transport and nitric oxide metabolism were not responsible for differences in STZ sensitivity and metabolite accumulation. Thus the strain differences in STZ sensitivity appears to be due to intracellular events within the beta cell occurring after STZ transport and before NAD + NADH depletion. STZ metabolite accumulation appears to be associated with STZ sensitivity. Further studies are warranted to determine if differential STZ metabolite accumulation is responsible for STZ sensitivity.

Glycine immunoreactivity and receptor binding in the cochlear nucleus of C57BL/6J and CBA/CaJ mice: effects of cochlear impairment and aging.

Glycinergic neurons in the cochlear nucleus (CN) of C57BL/6J (C57) and CBA/CaJ (CBA) mice were studied by using immunocytochemical and receptor-binding techniques. Adult C57 mice exhibit progressive cochlear pathology as they age, whereas aging CBA mice retain good hearing. In the CN of old C57 mice (18 months) with severe hearing loss, the number of glycine-immunoreactive neurons decreased significantly. The number (Bmax) of strychnine-sensitive glycine receptors (GlyR) decreased significantly in the dorsal CN of old C57 mice. Significant effects were not observed in the CN of middle-aged C57 mice (with less-severe hearing loss) or in very old CBA mice (which do not exhibit severe hearing loss). The data suggest that the combination of severe hearing loss and old age results in deficits in one or more inhibitory glycinergic circuits in the CN.

Autoimmunity to heat shock protein 60 and antigen-specific production of interleukin-10.

The immunopathologic sequelae of chlamydial infection are correlated with immune responses to the Chlamydia trachomatis heat shock protein 60 (hsp60). One pathogenic mechanism that may explain this association is the induction of autoimmune responses to self hsp60, since these two proteins share a high degree of amino acid sequence identity. To investigate the conditions under which autoimmune responses can be generated against self hsp60, groups of CBA mice were immunized with recombinant mouse hsp60, recombinant chlamydial hsp60, or both proteins. The data show that autoimmune responses characterized by strong T-cell proliferation and high titers of antibody to self hsp60 are induced only by concurrent immunization with mouse and chlamydial hsp60. Immunization with mouse hsp60 alone induced lymphocytes that secreted high levels of interleukin-10 (IL-10) but did not proliferate in response to in vitro stimulation with mouse hsp60; coimmunization with mouse and chlamydial hsp60s induced lymphocytes that proliferated strongly in response to mouse hsp60, secreted 6-fold less IL-10, and exhibited a 12-fold increase in the ratio of gamma interferon/IL-10 production. Switches in cytokine production patterns may mediate the pathogenesis of hsp60-associated diseases such as C. trachomatis immunopathology.

[The characteristics of the brain serotonin system and anxiety in the C57BL and CBA mouse strains]. / Osobennosti serotoninovoi sistemy mozga i trevozhnost' u myshei linii C57BL i CBA.

Serotonin metabolism and 5-HT2A and 5-HT1A specific binding were studied in high-aggressive C57BL and low-aggressive CBA mice. In three main tests for anxiety (elevated plus-maze "dark-light test", and social contacts) C57BL mice revealed higher anxiety than CBA, Activity of tryptophan hydroxylase, the key enzyme in serotonin biosynthesis was significantly lower in the midbrain and neostriatum of C57BL than CBA mice. The specific binding of [3H]-ketanserin in C57BL was higher in the frontal cortex and lower in the neostriatum than in the same structures of CBA mice being indicative of the differences in 5-HT2A receptor density. There were no significant differences in 5-HT1A receptor density (as indicated by specific [3H]-8-OH-DPAT binding) between the strains. It was suggested that decreased serotonin metabolism and characteristic distribution of 5-HT2A receptors can underlie the expression of genetic predisposition to anxiety and aggression.

Development of calretinin immunoreactivity in the mouse inner ear.

Calretinin is a calcium-binding protein of the EF-hand family. It has been previously identified in particular cell types of adult guinea pig, rat, and chinchilla inner ear. Development of calretinin immunoreactivity in the mouse inner ear was investigated from embryonic day 13 (E13) to the adult stage. In the adult mouse vestibule, calretinin immunoreactivity was present in the same structures as described for the rat and guinea pig: the population of afferent fibers forming calyx units and a small number of ganglion neurons. The earliest immunoreactivity was found at E17 in vestibular hair cells (VHCs), then, at E19, in afferent fibers entering the sensory epithelia and in rare ganglion neurons. At postnatal day 4 (P4), a few vestibular nerve fibers and ganglion neurons were reactive. From this stage until P14, immunoreactivity developed in the calyx units and disappeared from VHCs. At P14, immunostaining was adult-like. In the adult mouse cochlea, immunoreactivity was present in the same cell populations as described in the rat: the inner hair cells (IHCs) and most of Corti's ganglion neurons. Calretinin immunoreactivity appeared at E19-P0 in IHCs and ganglion neurons of the basal turn. At P1, outer hair cells (OHCs) of the basal turn were positive. Calretinin immunoreactivity then appeared in IHCs, OHCs, and ganglion neurons of the medial turn, then of the apical turn. At P4, all IHCs and OHCs and most of the ganglion neurons were immunostained. Immunoreactivity gradually disappeared from the OHCs starting at P10 and, at P22, only IHCs and ganglion neurons were positive. The sequences of appearance of calretinin were specific to each cell type of the inner ear and paralleled their respective maturation. Calretinin was transiently expressed in VHCs and OHCs.

Murine intestinal disaccharidases: identification of structural variants of sucrase-isomaltase complex.

This study was directed to determine the extent of variability in structure or expression of intestinal disaccharidase [gamma-glucoamylase (gamma-GA), sucrase-isomaltase (SI), and lactase] between different strains of mice. Reduced levels of sucrase activity (approximately 20 U/g of protein) were observed in three strains of mice belonging to the CBA/Ca lineage. Four other strains of mice analyzed exhibited higher levels of sucrase activity (approximately 50 U/g of protein). Decreased levels of sucrase in CBA/Ca mice were not associated with decreased levels of activity associated with the isomaltase subunit or with decreased levels of SI mRNA expression. High-performance liquid chromatographic gel filtration, heat inactivation, and kinetic analysis indicated that the differences between strains in sucrase activity might be attributed to structural differences in the sucrase subunit of the SI complex, thus rendering it more susceptible to cleavage and inactivation. However, no differences in kinetic properties of the sucrase subunit were observed between strains. Murine gamma-GA was found to account for a greater proportion of maltase activity (approximately 70%) than that observed in other species (i.e., approximately 20%). In addition, CBA/Ca mice were found to be deficient in intestinal maltase activity (approximately 60 U/g) compared with the other strains studied (approximately 300 U/g).

Characterization of intestinal gamma-glucoamylase deficiency in CBA/Ca mice.

In previous work, we found that CBA/Ca mice display only 20% of the maltase activity present in other mouse strains. In this study, we characterized more fully the maltase deficiency in CBA/Ca mice. Virtually all of the intestinal maltase activity of CBA/Ca mice was inactivated at 50 degrees C, indicating that it was due only to the sucrase-isomaltase complex. High-performance liquid chromatographic analysis revealed that CBA/Ca mice had undetectable maltase activity displaying the molecular mass characteristic of murine gamma-glucoamylase (gamma-GA) (530 kDa). Gel electrophoretic analysis confirmed that CBA/Ca mice lacked maltase activity with molecular mass of 530 kDa corresponding to gamma-GA. Two-dimensional electrophoretic analysis revealed that the gamma-GA deficiency in CBA/Ca mice was due to the failure to synthesize the enzyme and not to the synthesis of an inactive protein. gamma-GA maltase activity could not be induced in CBA/Ca mice by a diet rich in starch, whereas the activity of other disaccharidases were readily increased. gamma-GA-deficient CBA/Ca mice appear to lack any gross metabolic abnormality resulting from this defect.

Dendritic cells are potent antigen-presenting cells for microbial superantigen.

Dendritic cells (DC) were found to be more efficient than macrophages (MO) in activating T cell responses to Staphylococcal enterotoxin B (SEB) using the hanging drop techniques and DC as antigen presenting cells (APC). When superantigen was presented via DC, the activation of T cells was not dependent on antigen processing and MHC class II molecules IA and IE were involved.

Development of glutamic acid decarboxylase-immunoreactive elements in the cerebellar cortex of normal and lurcher mutant mice.

The development of glutamic acid decarboxylase-immunoreactivity (GAD-IR) in cells, fibers, and varicosities of the cerebellar cortex has been examined by light microscopy in normal and lurcher mutant mice between postnatal day 3 and 30 (P3-P30). Purkinje cell morphology was demonstrated in adjacent sections by using an antiserum to the 28Kd vitamin D-dependent calcium binding protein (CaBP). In early postnatal lurcher mice, but not in normal littermates, GAD-IR fibers, presumably Purkinje cell pseudopodia, invade the external granular layer. The plexus of CaBP-IR axons in the internal granular layer is much less complex in lurcher mice than in normal littermates, even before the onset of lurcher Purkinje cell degeneration at P8. In normal mice, GAD-IR fibers encapsulate Purkinje cell somata by P15. Lurcher Purkinje cells, in contrast, receive scattered contacts by GAD-IR puncta and possess a "cap" of such elements surrounding the primary dendrite and apical soma. Pinceau formations, visible as a knot of GAD-IR puncta hanging from the base of Purkinje cells in normal P15 mice, are not present in lurcher littermates. "Empty baskets" or collapsed pinceau formations in regions devoid of Purkinje cells are not revealed by anti-GAD immunohistochemistry in the P17-P30 lurcher cerebellar cortex.

The influence of different light intensities on pineal melatonin content in the retinal degenerate C3H mouse and the normal CBA mouse.

The sensitivity of light-induced suppression of pineal melatonin content was compared between C3H mice with hereditary retinal degeneration and CBA mice with normal retinas. At 2 h before lights on of light-dark (LD) cycles, when pineal melatonin content is the highest in both strains, groups of mice were exposed to different intensities of white fluorescent light (100, 0.14, 0.017 lux in both strains and 0.0021 and 0.00026 lux in CBA mice). For each intensity, pineals were collected just before and 5, 15 and 30 min after exposure to light. In C3H mice, the threshold of light intensity to suppress pineal melatonin content was between 0.14 and 0.017 lux, whereas that in CBA mice was between 0.0021 and 0.00026 lux. These results suggest that both rods and cones mediate photic information to the pineal gland in mice.

Measurement of 3-methoxytyramine by in vivo voltammetry: evidence for differences in central dopamine function in BALB/c and CBA mice.

Differential pulse voltammetry (DPV) combined with carbon fibre electrodes allows selective detection of electroactive dopamine and serotonin metabolites in vivo. While usually employed in rats, we have now applied this in vivo technique in two inbred strains of mice: BALB/c and CBA. Three distinct oxidation peaks were recorded in vivo in the striatum of either BALB/c or CBA mice with a small shoulder occurring after the third peak at approximately +400 mV. Pargyline (150 mg/kg i.p.) potentiated this voltammetric shoulder into an easily measurable peak (Peak 4). In addition, Peak 4 was 2-3 times larger in BALB/c than in CBA mice. Homovanillic acid (HVA) and 3-methoxytyramine (3-MT), both catabolites of dopamine, oxidised at approximately +400 mV in vitro. Brain tissue levels of HVA and 3-MT, measured by high-performance liquid chromatography (HPLC) with electrochemical detection, demonstrated that pargyline treatment reduced striatal HVA, but increased 3-MT. These results support the view that Peak 4 recorded in the striatum of pargyline-treated mice in vivo is due to the oxidation of extracellular 3-MT. Thus, Peak 4 may be a useful index of dopamine release in situations where dopamine itself cannot be detected. Local infusion of KCl (2 microliters, 0.1 M) further increased the size of Peak 4 in the striatum of both BALB/c and CBA mice. However, the increase was approx. 3 times greater in BALB/c mice, supporting previous evidence of greater dopaminergic function of BALB/c compared with CBA mice. In addition these two inbred strains of mice provide model systems for investigating the comparative functional roles of nigrostriatal pathways.

Hepatic hydroxymethylglutaryl coenzyme A reductase activity in inbred strains of mice.

Hydroxymethylglutaryl coenzyme A reductase (HMGR) activity is a major factor in the regulation of cholesterol homeostasis. Enzyme activity is known to vary with age, sex, diurnal cycle, and dietary properties in rats. Mice are available in numerous genetic strains and could be a useful inexpensive animal model for studying diet and genetic interactions in the regulation of cholesterol metabolism. Obese and non-obese C57BL/6J, CBA/J, and obese and non-obese DW dbPas mice were subjected to variations in light cycle, feeding schedule, and pectin and fat composition of their diets. They were then killed by decapitation, and hepatic microsomal HMGR analyzed. The mice responded in the same ways as rats to light cycle, feeding pattern, and sex difference. They exhibited marked differences in HMGR activity due to age, genotype, strain, and diet variations. We conclude that mice will, indeed, offer an excellent animal model for the study of cholesterol metabolism regulation.

[Effect of sex hormones on the 1,2-dimethylhydrazine metabolic activity in the kidneys of CBA-strain mice]. / Vliianie polovykh gormonov na aktivnost' metabolizma 1,2-dimetilgidrazina v pochkakh myshei linii CBA.

1,2-dimethylhydrazine (DMH) metabolizing activity of kidney microsomes was shown to be two times higher in male, than in female CBA mice. Castration decreased DMH metabolizing activity of male kidney microsomes to the females' level. DMH metabolizing activity of castrated males treated with testosterone propionate was identical to that of intact males. The incorporation of 14C-DMH into kidney DNA was also higher in male, than in female CBA mice.