Satoshi Kikkawa

Apolipoprotein E and Reelin ligands modulate tau phosphorylation through an Apolipoprotein E receptor/disabled-1/glycogen synthase kinase-3β cascade

Neurofibrillary tangles comprised of highly phosphorylated tau proteins are a key component of Alzheimers disease pathology. Mice lacking Reelin (Reln), double‐knockouts lacking the VLDL receptor (VLDLR) and ApoE receptor2 (ApoER2), and mice lacking disabled‐1 (Dab1) display increased levels of phosphorylated tau. Because Reln binds to recombinant ApoE receptors, assembly of a Reln/ApoE‐receptor/Dab1 (RAD) complex may initiate a signal transduction cascade that controls tau phosphorylation. Conversely, disruption of this RAD complex may increase tau phosphorylation and lead to neurodegeneration. To substantiate this concept, we mated Reln‐deficient mice to ApoE‐deficient mice and found that in the absence of Reln, tau phosphorylation increased as the amount of ApoE decreased. Paralleling the change in tau phosphorylation levels, we found that GSK‐3β activity increased in Reln‐deficient mice and further increased in mice lacking both Reln and ApoE. CDK‐5 activity was similar in mice lacking Reln, ApoE, or both. GSK‐3β and CDK‐5 activity increased in Dab1‐deficient mice, independent of ApoE levels. Further supporting the idea that increased tau phosphorylation results primarily from increased kinase activity, the activity of two phosphatases was similar in all conditions tested. These data support a novel, ligand‐mediated signal transduction cascade— initiated by the assembly of a RAD complex that suppresses kinase activity and controls tau phosphorylation.

Missplicing resulting from a short deletion in the reelin gene causes reeler-like neuronal disorders in the mutant shaking rat Kawasaki.

The shaking rat Kawasaki (SRK) is an autosomal recessive mutant that exhibits reeler‐like abnormal locomotor behaviors. The murine reeler mutants arise from several mutations in the specific gene called reelin, which result in defects of Reelin expression or secretion in the cerebral cortex and other regions of CNS. To address the issue of whether the SRK mutation also arises from a mutation in reelin, we analyzed the reelin gene in SRK. Northern analysis of reelin mRNA from normal rats showed that rat reelin was expressed as a ∼12‐kb transcript in both the cerebrum and the cerebellum, whereas reelin expression was markedly reduced in the SRK brains. In situ hybridization analysis showed that reelin mRNA in the SRK brains was expressed in Cajal‐Retzius cells in the marginal zone of the cerebral cortex and outer granular cells in the cerebellar cortex in similar manners to normal controls, but its expression was considerably reduced. On Western blotting and immunohistochemical analyses using antibodies specific for the Reelin protein, no immunoproduct was recognized in the cerebral and cerebellar cortices. From the cDNA sequences, we found a 64‐base heterologous sequence in SRK reelin, which contains a termination codon in the reading frame. Furthermore, genomic DNA analysis revealed that a 10‐base deletion, which contains a predicted splice donor site, occurred in the SRK genomic reelin gene, resulting in “read through” into the following intron in SRK. Thus, the SRK mutation is another type of mutation that lacks expression of the functional Reelin protein and, therefore, causes the reeler phenotype. J. Comp. Neurol. 463:303–315, 2003.

Distribution of Ca2+/calmodulin-dependent protein kinase I beta 2 in the central nervous system of the rat

Recently, we reported the mRNA localization of Ca2+/calmodulin-dependent protein kinase I beta 2 isoform (CaMKIβ2) in the mouse nervous system. In the present study, polyclonal antibody against CaMKIβ2 was generated and used to investigate the distribution of the enzyme within the central nervous system of the rat. Interestingly some differences were observed between the enzyme localization and previous mRNA detection [J. Neurochem. 268 (1999) 26512]. The strongest expression of the enzyme was found in pontine nuclei. Immunopositive fibers could be traced through the middle cerebellar peduncle until they reached the cerebellum. Quite strong staining could also be observed in almost all of the neurons in the neocortex, hippocampus, amygdala, hypothalamus, brainstem and cerebellum, including the nuclei of the cranial nerves and Purkinje cell layer of the cerebellar cortex which was not clearly detected in the previous in situ hybridization study. In the spinal cord, CaMKIβ2 could be detected in the gray matter with stronger expression in the dorsal horn. CaMKIβ2 showed very strong nuclear localization but was also present in the cytoplasm of some neurons. Such localization suggests that CaMKIβ2 may be involved in many neuronal functions in the central nervous system, including the possibility of important roles in nuclear signal transduction.

Expression of zebrafish ROR alpha gene in cerebellar-like structures

Mouse genetic studies have identified several genes involved in cerebellar development. The mouse mutants staggerer and lurcher are functionally deficient for the retinoid‐related orphan receptor alpha (ROR alpha) and glutamate receptor delta2 (Grid2) genes, respectively, and they show similar functional and developmental abnormalities in the cerebellum. Here, we report the cloning and expression pattern of zebrafish ROR alpha orthologues rora1 and rora2, and compare their expression pattern with that of grid2. Expression of rora1 and rora2 is initiated at late gastrula and pharyngula stages, respectively. Both rora1 and rora2 are spatially expressed in the retina and tectum. Expression of rora2 was further observed in the cerebellum, as reported for mammalian ROR alpha. In the adult brain, rora2 and grid2 are coexpressed in brain regions, designated as cerebellar‐like structures. These observations suggest an evolutionarily conserved function of ROR alpha orthologues in the vertebrate brain. Developmental Dynamics 236:2694–2701, 2007.

Dynamic changes in the gene expression of zebrafish Reelin receptors during embryogenesis and hatching period

The brain morphology of vertebrates exhibits huge evolutionary diversity, but one of the shared morphological features unique to vertebrate brain is laminar organization of neurons. Because the Reelin signal plays important roles in the development of the laminar structures in mammalian brain, investigation of Reelin signal in lower vertebrates will give some insights into evolution of vertebrate brain morphogenesis. Although zebrafish homologues of Reelin, the ligand, and Dab1, a cytoplasmic component of the signaling pathway, have been reported, the Reelin receptor molecules of zebrafish are not reported yet. Here, we sought cDNA sequence of zebrafish homologue of the receptors, vldlr and apoer2, and examined their expression patterns by in situ hybridization. Developmental gene expression pattern of reelin, dab1, vldlr, and apoer2 in the central nervous system of zebrafish was compared, and their remarkable expression was detected in the developing laminar structures, such as the tectum and the cerebellum, and also non‐laminated structures, such as the pallium. The Reelin receptors exhibited different spatial and temporal gene expression. These results suggest a possibility that duplication and subsequent functional diversity of Reelin receptors contributed to the morphological and functional evolution of vertebrate brain.

Postnatal Development of Entorhinodentate Projection of the Reeler Mutant Mouse

We anterogradely labeled entorhinodentate axons by the injection of biotin dextran amine into the entorhinal cortex of adult wildtype and reeler mice to clarify whether the course and terminal endings of the reeler entorhinal projection are normal or not. We found that in the reeler mouse, biotin dextran amine-labeled entorhinodentate fibers arising from the entorhinal cortex curved around the hippocampal fissure instead of crossing it, whereas in the wildtype mouse, they crossed the fissure as a perforant pathway. Next, we examined carbocyanine dye (DiI) labeling of the immature entorhinodentate projection and the developmental changes of the hippocampal fissure during early postnatal days based on the laminin and glial fibrillary acidic protein (GFAP) immunohistochemistry. Injection of DiI into the entorhinal area of the wildtype and reeler mice at postnatal day 1 resulted in anterograde labeling of pioneer axons passing through the hippocampal fissure. However, follower axons could not penetrate through the hippocampal fissure in reeler mice, whereas in the normal controls, many DiI-labeled axons continued to pass through the fissure. GFAP immunohistochemistry demonstrated that GFAP-immunopositive astrocytes were abundant along the hippocampal fissure both in the wildtype and reeler mice at birth. In the wildtype mouse, GFAP-positive neurons nearby the fissure were decreasing in number during the early postnatal days, whereas in the reeler mouse, many GFAP-positive astrocytes were continuing to accumulate there. This barrier made of astrocytes in the reeler mouse may obstruct the ingrowth of the follower axons arising from the entorhinal cortex through the hippocampal fissure, resulting in the abnormal course of the entorhinodentate axons in this mutant.

GABA modulates development of cerebellar Purkinje cell dendrites under control of endocannabinoid signaling

J. Neurochem. (2010) 114, 627–638.

Cytoarchitecture of the olfactory bulb in the laggard mutant mouse.

The laggard (lag) mutant mouse, characterized by hypomyelination and cerebellar ataxia, is a spontaneously occurring mutant mouse caused by mutation in the Kif14 gene. In this mutant mouse, the laminated structures such as the cerebral and cerebellar cortices and the dentate gyrus are cytoarchitecturally abnormal. Macroscopically, the olfactory bulb of the lag mutant mouse is smaller in size and more transparent than the normal counterpart. Hematoxylin-eosin staining reveals that the mutant olfactory bulb has normal lamination in general, but detailed analysis has demonstrated that olfactory periglomerular cells and granule cells are reduced in number. In the mutant, olfactory glomeruli are cytoarchitecturally disorganized and mitral cells are arranged in multiple cell layers instead of being arranged in a single layer. The rostral migratory stream in the mutant becomes gradually thinner or obliterated during early postnatal days. Some of mitral cells and periglomerular cells are multinucleated, suggesting that Kif14 mutation leads to an abnormal cell division. In the mutant, terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL)-positive cells in the subventricular zone of the lateral ventricle are increased in number, especially at perinatal age, suggesting that the decreased population of granule cells in the lag mutant mouse is caused by the increased apoptotic cell death. The olfactory input appears to be intact, as indicated by anterograde labeling of olfactory nerves with an injection of wheat germ agglutinin-horseradish peroxidase (WGA-HRP) into the olfactory mucosa. In conclusion, the olfactory bulb of the lag mutant mouse is cytoarchitecturally affected, suggesting that the causal gene for lag mutation, i.e., Kif14, has multiple effects on the development of laminated structures in the central nervous system in addition to the myelin formation.