EC:2.7.11.22 - FACTA Search

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Query: EC:2.7.11.22 (cdc2)
8,319 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The p35/cdk5 neuronal-specific kinase complex has been shown to play an important role in the laminar configuration of cortical neurons. Mice lacking either p35 or cdk5 exhibit a disrupted cortical lamination pattern. We showed previously that instead of the normal "inside-out" layering pattern of cortical neurons, cortical neurons are layered from "outside-in" in p35 mutant mice. To gain insight into the mechanisms that underlie these defects, we examined the organization of landmark structures formed during cortical development and the migratory behavior of p35(-/-) cortical neurons by using bromodeoxyuridine labeling. In the present study, we show that reelin localization in the marginal zone is normal in p35 mutant mice. Furthermore, the preplate splits into the marginal zone and subplate properly, a developmental event that fails to occur in reeler mice. Finally, the migration of the earliest born cortical plate neurons is normal in p35 mutant mice; cortical neurons subsequently generated remain underneath these neurons. These data suggest that the p35/cdk5 kinase is required for cortical plate neurons to migrate past preexisting neurons and take up superficial positions to constitute the inside-outside layering order of cortical lamination.
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PMID:A novel disruption of cortical development in p35(-/-) mice distinct from reeler. 961 3

Cyclin-dependent kinase 5 (Cdk5) is a member of the family of cell cycle-related kinases. Previous neuropathological analysis of cdk5(-/-) mice showed significant changes in CNS development in regions from cerebral cortex to brainstem. Among the defects in these animals, a disruption of the normal pattern of cell migrations in cerebellum was particularly apparent, including a pronounced abnormality in the location of cerebellar Purkinje cells. Complete analysis of this brain region is hampered in the mutant because most of cerebellar morphogenesis occurs after birth and the cdk5(-/-) mice die in the perinatal period. To overcome this disadvantage, we have generated chimeric mice by injection of cdk5(-/-) embryonic stem cells into host blastocysts. Analysis of the cerebellum from the resulting cdk5(-/-) left arrow over right arrow cdk5(+/+) chimeric mice shows that the abnormal location of the mutant Purkinje cells is a cell-autonomous defect. In addition, significant numbers of granule cells remain located in the molecular layer, suggesting a failure to complete migration from the external to the internal granule cell layer. In contrast to the Purkinje and granule cell populations, all three of the deep cerebellar nuclear cell groupings form correctly and are composed of cells of both mutant and wild-type genotypes. Despite similarities of the cdk5(-/-) phenotype to that reported in reeler and mdab-1(-/-) (scrambler/yotari) mutant brains, reelin and disabled-1 mRNA were found to be normal in cdk5(-/-) brain. Together, the data further support the hypothesis that Cdk5 activity is required for specific components of neuronal migration that are differentially required by different neuronal cell types and by even a single neuronal cell type at different developmental stages.
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PMID:Migration defects of cdk5(-/-) neurons in the developing cerebellum is cell autonomous. 1040 39

Reeler, an autosomal recessive mutant mouse, is characterized by ataxic gait and tremor. In this mutant, the cerebral and cerebellar cortices and hippocampus are cytoarchitectually disorganized: neuronal components are ectopically located in these laminated structures. Since reelin, the gene responsible for the reeler mutation, was discovered by D'Arcangelo et al. (Nature 374: 719-723, 1995), remarkable progress has occurred in this field. The reelin gene encodes an extracellular protein, Reelin, that is crucial for neuronal migration. During embryogenesis, reelin is expressed in the Cajal-Retzius cells in the cerebral cortex and in the outer granule cells in the cerebellar cortex. Although non-laminated structures such as facial nucleus, inferior olivary complex, and dorsal cochlear nucleus are also cytoarchitectually deranged in this mutant, only a few studies have been done to clarify the detailed abnormalities in these non-laminated structures. In this review, we focused on the cytoarchitectonic abnormality in the facial nucleus of the reeler mouse. The branchiomotor neurons in the facial nucleus are generated from the ventricular zone of the floor of the fourth ventricle, migrate ventrolaterally, and finally settle near the ventral surface of the hindbrain. Time schedules for the generation, axon formation and migration of facial motoneurons are similar both in the normal and reeler mice, but the reeler phenotype becomes identifiable at the end of neuronal migration. Although the reason why the facial nucleus is cytoarchitectually abnormal in the reeler mouse is still unknown, the long migration of the facial motoneurons seems to be susceptible to the absence of Reelin in the reeler mouse. In spite of the cytoarchitectual abnormality, retrograde horseradish peroxidase (HRP) study confirmed that the musculotopic arrangements within the facial nucleus of the reeler mouse are still preserved, suggesting that neuronal migration and target recognition are regulated independently. More recently, other reeler-like mutants have been reported. Among them, yotari and scrambler mice arise from mutations in mdab1, a mouse gene related to Drosophila gene disabled (dab). More than 10 years ago, an autosomal recessive rat mutant, shaking rat Kawasaki (SRK), was described that exhibits a phenotype identical to reeler, but the gene responsible for this rat mutation remains unknown. Interestingly, the facial nucleus is cytoarchitectually more deranged in yotari and SRK than their reeler counterpart. Although the reason why yotari exhibits a phenotype identical to reeler in the laminated structures but not in non-laminated structures such as the facial nucleus has remained obscure, mDab1 and Reelin proteins may function as signaling molecules in a different way between laminated and non-laminated structures. Phenotypes resembling that of reeler are seen with mutations in mdab1, cdk5 and p35. Cdk5 and p35 are respectively the catalytic and regulatory subunits of a serine/threonine kinase, that could potentially operate in a common signalling pathway with mDab and Reelin. These plausible partners for Reelin and mDab1 should help us to understand how the activities of these proteins coordinate neuronal migration and rearrangement.
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PMID:[Cytoarchitectonic abnormality in the facial nucleus of the reeler mouse]. 1049 86

This paper proposes an evolutionary hypothesis for the origin of (i) the inside-out pattern of mammalian corticogenesis in which late-generated cells become located more superficially than early-generated cells, and (ii) the predominantly radial organization of isocortical inputs in mammals. It is suggested that an outside-in neurogenetic gradient (in which early-generated cells are located more superficially than late-generated cells), as occurs in reptilian cortex, would have positioned the late-produced, associative neurons (destined to supragranular layers in modern isocortex) below the early-produced output neurons. This may have limited the possibilities of synaptic contacts between the younger cells and the afferent terminals which were located in the more superficial layer I. There was probably an adaptive benefit in those individuals in which late-produced cells were capable of passing through the layers of already migrated cells, thus making contacts with superficial afferents and generating corticocortical and local circuits that processed the information before producing an output. Reelin, an extracellular glycoprotein found in layer I, and a cyclin-dependent kinase (cdk5) and its neuronal-specific activator (p35) may have played key roles in the generation of the inside-out gradient. Additionally, by serving as a waiting compartment for thalamic axons while the cortical plate develops, the subplate zone may have participated in the change from an emphasis in a tangential arrangement of thalamic terminals that is characteristic of reptilian cortex to the predominantly radial mode of termination that is observed in mammalian isocortex.
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PMID:Evolution of isocortical organization. A tentative scenario including roles of reelin, p35/cdk5 and the subplate zone. 1055 88

Neurofibrillary tangles comprised of highly phosphorylated tau proteins are a key component of Alzheimer's 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-3beta 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-3beta 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.
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PMID:Apolipoprotein E and Reelin ligands modulate tau phosphorylation through an apolipoprotein E receptor/disabled-1/glycogen synthase kinase-3beta cascade. 1249 May 40

The signaling cascades governing neuronal migration are believed to link extracellular signals to cytoskeletal components. MAP1B is a neuron-specific microtubule-associated protein implicated in the control of the dynamic stability of microtubules and in the cross-talk between microtubules and actin filaments. Here we show that Reelin can induce mode I MAP1B phosphorylation, both in vivo and in vitro, through gsk3 and cdk5 activation. Additionally, mDab1 participates in the signaling cascade responsible for mode I MAP1B phosphorylation. Conversely, MAP1B-deficient mice display an abnormal structuring of the nervous system, especially in brain laminated areas, indicating a failure in neuronal migration. Therefore, we propose that Reelin can induce post-translational modifications on MAP1B that could correlate with its function in neuronal migration.
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PMID:A role of MAP1B in Reelin-dependent neuronal migration. 1559 Sep 13

The Reelin-Disabled 1 (Dab1) signaling pathway plays an important role in neuronal cell migration during brain development. Dab1, an intracellular adapter protein which is tyrosine phosphorylated upon Reelin stimulation, has been directly implicated in the transmission and termination of Reelin-mediated signaling. Two main forms of Dab1 have been identified in the developing chick retina, an early isoform (Dab1-E) expressed in progenitor cells and a late isoform (Dab1-L, a.k.a. Dab1) expressed in differentiated cells. Dab1-E is missing two Src family kinase (SFK) phosphorylation sites that are critical for Reelin-Dab1 signaling and is not tyrosine phosphorylated. We have recently demonstrated a role for Dab1-E in the maintenance of retinal progenitor cells. Here, we report that Dab1-E is phosphorylated at serine/threonine residues independent of Reelin. Cdk2, highly expressed in retinal progenitor cells, mediates Dab1-E phosphorylation at serine 475 which in turn promotes ubiquitination-triggered proteasome degradation of Dab1-E. Inhibition of protein phosphatase 1 and/or protein phosphatase 2A leads to increased Dab1-E instability. We propose that Dab1 turnover is regulated by both Reelin-independent serine/threonine phosphorylation and Reelin-dependent tyrosine phosphorylation.
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PMID:Serine phosphorylation regulates disabled-1 early isoform turnover independently of Reelin. 2111 10