Age-dependent kainate sensitivity in heterozygous rolling Nagoya Cav2.1 channel mutant mice.

Cav2.1α1 is involved in glutamate release. The kainate-induced intensive firing of neurons via glutamate receptors causes seizure and neuronal damage, especially in the hippocampus. Cav2.1α1 mutation in homozygous rolling Nagoya (rol/rol) mice caused reduced Ca(2+) permeability compared to wild-type mice. The rol/rol mice exhibited ataxia approximately after 2 weeks of age. Although we have reported that heterozygous rolling Nagoya (rol/+) mice show age-dependent behavioral changes, sensitivity to kainate has not been examined. To examine the relationship between Cav2.1 function and neurological disease, we investigated how Cav2.1 is related to kainate-induced seizure and neuronal damage using 2- and 18-month-old rol/+ mice. The seizure scores of 18-month-old rol/+ mice that received 20mg/kg kainate intraperitoneally were significantly lower than those of wild-type mice. As a consequence of seizure, kainate induced delayed neuronal damage along with astrocytic growth in the hippocampus in wild-type mice, with a moderate effect observed in rol/+ mice. In the hippocampus of 18-month-old rol/+ mice, the levels of mutant-type Cav2.1α1 were increased compared to +/+ mice. The phosphorylation of p38, a mitogen-activated protein kinase (MAPK) activated by kainate, was not increased after kainate injection compared to +/+ mice. No difference was observed between 2-month-old rol/+ and wild-type mice intraperitoneally injected with 20mg/kg kainate in these analyses. These findings suggest that rol/+ mice experience age-related changes in sensitivity to kainate due to changes in the p38 MAPK signaling pathway via a mutant Cav2.1 channel. Hence, rol/+ mice may represent a novel model to delineate the association between Cav2.1 function, synaptic transmission, and the postsynaptic signaling cascade.

Rolling Nagoya mouse strain (PROD-rol/rol) with classic piebald mutation.

Ataxic rolling Nagoya (PROD-rol/rol) mice, which carry a mutation in the α1 subunit of the Cav2.1 channel (Cacna1a) gene, were discovered in 1969. They show white spots on agouti coat and have a mutation in the piebald spotting (s) locus. However, mutation analysis of the s locus encoding the endothelin receptor type B (Ednrb) gene in PROD-rol/rol mice had not been performed. Here, we examined the genomic and mRNA sequences of the Ednrb gene in PROD-rol/rol and wild-type rolling Nagoya (PROD-s/s) and studied the expression patterns of Ednrb and Cacna1a genes in these mice in comparison with C57BL/6J mice. Polymerase chain reaction analyses revealed two silent nucleotide substitutions in the coding region and insertion of a retroposon-like element in intron 1 of the Ednrb gene. Expression analyses demonstrated similar localizations and levels of Ednrb and Cacna1a expression in the colon between PROD-rol/rol and PROD-s/s mice, but the expression levels of both genes were diminished compared with C57BL/6J mice. Microsatellite genotyping showed that at least particular regions of chromosome 14 proximal to the Ednrb locus of the PROD strain were derived from Japanese fancy piebald mice. These results indicated that PROD-rol/rol mice have two mutant genes, Ednrb and Cacna1a. As no PROD strain had an intact Ednrb gene, using congenic rolling mice would better serve to examine rolling Nagoya-type Cav2.1 channel dysfunctions.

Impaired motor function in senescence-accelerated mouse prone 1 (SAMP1).

Senescence-accelerated mouse prone (SAMP) strains of mice show early onset of senescence, whereas senescence-accelerated mouse resistant (SAMR) strains are resistant to early senescence and serve as controls. Although SAMP6 and SAMP8 are established models of central nervous system alterations, it is unclear whether SAMP1/Sku (SAMP1) is characterized by brain alterations and dysfunction related to behavioral functioning. In the present study, behavioral tests (i.e., locomotor activity, Y-maze, rotating rod, hind-limb extension, and traction), histochemistry, and Western blot analyses were employed to study this mouse model using 2- and 4-month-old SAMP1 and age-matched control SAMR1. Although 2-month-old SAMP1 and SAMR1 showed similar activity, 4-month-old SAMP1 exhibited less activity than age-matched SAMR1 in locomotor activity and Y-maze tests. In rotating rod test, 2- and 4-month-old SAMP1 showed motor-coordination dysfunction. An abnormal extension reflex in the hind-limb test was observed in 2- and 4-month-old SAMP1. There were no significant differences between SAMP1 and SAMR1 with respect to grip strength in the traction test or alternation behavior in the Y-maze test. Histochemistry and Western blot analyses exhibited that cerebellar Purkinje cells in 4-month-old SAMP1 mice persistently expressed tyrosine hydroxylase. These results suggest that SAMP1 is a useful model for examining mechanisms underlying motor dysfunction.

New ataxic tottering-6j mouse allele containing a Cacna1a gene mutation.

Voltage-gated Ca(2+) (Ca(v)) channels control neuronal functions including neurotransmitter release and gene expression. The Cacna1a gene encodes the α1 subunit of the pore-forming Ca(v)2.1 channel. Mice with mutations in this gene form useful tools for defining channel functions. The recessive ataxic tottering-6j strain that was generated in the Neuroscience Mutagenesis Facility at The Jackson Laboratory has a mutation in the Cacna1a gene. However, the effect of this mutation has not been investigated in detail. In this study, mutation analysis shows a base substitution (C-to-A) in the consensus splice acceptor sequence linked to exon 5, which results in the skipping of exon 5 and the splicing of exon 4 directly to exon 6. The effect of this mutation is expected to be severe as the expressed α1 subunit protein lacks a significant part of the S4-S5 linker, S5, and part of S5-S6 linker in domain I. Tottering-6j mice display motor dysfunctions in the footprint, rotating rod, and hind-limb extension tests. Although cytoarchitecture of the mutant brains appears normal, tyrosine hydroxylase was persistently expressed in cerebellar Purkinje cells in the adult mutant mice. These results indicate that tottering-6j is a useful model for functional studies of the Ca(v)2.1 channel.

High-cholesterol feeding aggravates cerebral infarction via decreasing the CB1 receptor.

We examined how feeding conditions affect the CB1 receptor and cerebral infarction caused by cerebral ischemia. Mice were divided into the following three groups: normal diet (ND), caloric restriction (CR) and high-cholesterol-enriched diet (HCD), and were kept for 6 weeks. After 6 weeks, we measured both serum and brain cholesterol and the expression level of cannabinoid CB1 receptor within the brain in intact mice. In addition, middle cerebral artery (MCA) was occluded for 2 h following reperfusion. Serum cholesterol significantly increased in the HCD group in comparison with both the ND and CR groups. However, brain cholesterol decreased in the HCD group. Then, the expression level of CB1 receptor significantly decreased in the HCD group, while that of the CR group clearly increased in comparison with the ND group in intact mice. In MCA-occluded mice, The HCD group produced the most severe cerebral infarction, while cerebral infarction was significantly decreased in the CR group. These results suggest that CR prevents infarction by increasing CB1 receptor expression, while high-cholesterol feeding aggravates cerebral infarction both by hypercholesterolemia in serum and by decreasing CB1 receptor expression modulated by hypocholesterolemia within the brain.