UMLS:C0040822 - FACTA Search

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Query: UMLS:C0040822 (tremor)
18,428 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Shaking rat Kawasaki (SRK), a newly discovered neurological mutant rat in the Wistar strain, is described. The abnormalities of SRK rats are transmitted as an autosomal recessive trait. The neurological signs are shaking of the body and an ataxic-paretic gait from day 10 postnatal. The affected rats survive for about 1 month. Macroscopically, the cerebellum is small and frequently the vermis and paraflocculus lacking. The most conspicuous histological finding in the central nervous system is malposition of the neurons in the cerebral cortex, hippocampus and cerebellum. Myelination and synapse formation are intact. Abnormal myelinated fibers are present in the molecular layer of the cerebral cortex and in the central gray matter of the spinal cord. These morphological abnormalities resemble those reported in the reeler mutant mouse. SRK rats are another good animal model of human congenital malformations with neuronal migration disorders.
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PMID:Shaking rat Kawasaki (SRK): a new neurological mutant rat in the Wistar strain. 317 2

The cerebellum of shaking rat Kawasaki (SRK) was studied histochemically and immunocytochemically. The cerebellar cortex was characterized by a delay in the disappearance of the external granular layer, a narrow molecular layer, a narrow and cell sparse internal granular layer, and disarranged and heterotopically situated Purkinje cells with tortuous arborization and a large cell cluster in the depths of the cerebellum. Golgi-Cox staining revealed an abnormal ramification and polarity of ectopic Purkinje cells. Ultrastructurally, most spines of Purkinje cells in the depths remained naked. Based on these results, it is suggested that the genetically determined mechanisms responsible for the abnormal structure in the cerebellar cortex of SRK may include a migratory disorder of the Purkinje cells, and a decrease in the microneurons with a resulting decrease of synaptic contacts on the Purkinje cell soma and dendrite.
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PMID:Histopathological study on cerebellar dysgenesis of shaking rat Kawasaki (SRK). 804 14

Shaking rat Kawasaki (SRK) is an autosomal recessive mutant rat that exhibits tremor, dystonia, and ataxia and that is characterized by abnormal lamination of the cerebral and cerebellar cortices and the hippocampus. To examine whether or not layer V neurons in the mutant neocortex are malpositioned in accordance with the aberrant laminar cytoarchitecture, horseradish peroxidase (HRP) was injected into the lumbar spinal cord of SRK mutant and normal control rats to label cortical pyramids projecting through the corticospinal tract (CST). HRP-labeled CST neurons of both normal and SRK rats were found mainly in the hindlimb area of the sensory-motor cortex, indicating a normal tangential distribution of labeled CST neurons in the SRK mutant. In the radial axis, however, labeled CST neurons were spread throughout all layers of the mutant cortex, whereas those in normal rats were restricted to layer V. In the mutant, most labeled CST neurons located in the inner third of the cortex had a typical pyramidal form with an upright apical dendrite, but many of those located near the pial surface displayed abnormal shapes and could be subdivided into inverted pyramidal, horizontal, and bipolar neurons on the basis of their dendritic morphology. The abnormal distribution pattern of labeled CST neurons in the mutant was quantified using a standardized measure of their depth distribution, where 0% = the level of the white matter and 100% = the pial surface. The mean value for the SRK cortex of 47.0% was significantly greater than the figure of 40.5% for normal rats (P < 0.01, Student's t test), indicating a spread of CST neurons toward the pial surface in SRK, but even more striking was the size of the standard deviation: 30.4 in SRK compared with 7.1 in controls. The distribution pattern of CST neurons of the SRK rat was also statistically identical with that of the reeler mouse, which is a well-known mutant that also exhibits an abnormal lamination pattern in the cerebral cortex. These results indicate that neuronal components of the neocortex of the SRK mutant are intermingled along the radial axis, but not in the tangential axis, and provide further evidence for a strong similarity between this spontaneous rat mutation and the reeler malformation.
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PMID:Corticospinal tract neurons are radially malpositioned in the sensory-motor cortex of the Shaking rat Kawasaki. 920 47

The present report provides the first detailed description of the hippocampus in the Shaking Rat Kawasaki (SRK) mutant by using a panel of antibody markers to delineate its laminar organization. The mutant was characterised at postnatal day 21 by severe malformations of both neuronal position and orientation, the most striking of which was the presence of a rounded central granule cell mass in the dentate gyrus rather than the normal V-shaped granule cell layer. Despite this finding, the SRK dentate gyrus not only retained a cell-sparse molecular layer (thinner but similar in gross appearance to that of control littermates), but the sharp laminar boundary between its inner and outer parts was as clearly marked by IM1 and OM4 antibody staining as it was in the normal dentate gyrus. These immunocytochemical data suggest that the entorhinal terminal field of the dentate gyrus may be relatively normal in the mutant, despite entorhinal afferents appearing to take an abnormal trajectory after they fail to cross the hippocampal fissure. Laminar malformations included disruption of the SRK pyramidal cell layer, with spreading of the CA3 mossy fibre projection to an ectopic infrapyramidal position, radial displacement of CA1 pyramids, and transposition of a hitherto unremarked longitudinal fibre bundle immunoreactive for calretinin from its normal position in the stratum lacunosum-moleculare of field CA2 to an alvear position in SRK. The SRK malformations were very like but not identical to those seen in the mouse reeler mutant, suggesting similar underlying developmental mechanisms.
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PMID:Laminar boundaries persist in the hippocampal dentate molecular layer of the mutant Shaking Rat Kawasaki despite aberrant granule cell migration. 1036 11

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

The Shaking Rat Kawasaki (SRK) is a neurological mutant that exhibits abnormalities of cell migration and lamination, with many similarities to the mouse reeler mutant. We recently used lamina-specific antibody staining to show that despite severe aberrations in the laminar organization of the SRK dentate gyrus, the entorhinal terminal field in the outer dentate molecular layer appeared relatively normal (Woodhams & Terashima, 1999, J. Comp. Neurol. 409 p57). However, neurofilament immunostaining suggested that entorhino-dentate afferents take an abnormal trajectory in reaching their appropriate targets, the granule cells dendrites. In the present study, anterograde tracing with the carbocyanine dye 1, 1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate (DiI) has been used to delineate directly the path that entorhinal axons take to the dentate gyrus, confirming that in SRK entorhinal axons do indeed reach their appropriate terminal fields in the molecular layer, with laminar segregation between projections from the lateral and medial entorhinal cortices. However, these fibres fail to cross the hippocampal fissure between the subiculum and the dentate gyrus, coursing instead parallel to it until they curve round the deepest point of the fissure in field CA3. Similar findings were seen in the murine reeler mutant. Insertion of DiI crystals into the entorhinal cortex of neonatal rats also retrogradely labelled the developmentally transient Cajal-Retzius cells at the hippocampal fissure; these survive for longer in SRK than in normal littermates. The presence of a marked astrogliosis at the SRK hippocampal fissure may play a part in determining the abnormal trajectory taken by entorhino-dentate afferents in this mutant.
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PMID:Aberrant trajectory of entorhino-dentate axons in the mutant Shaking Rat Kawasaki: a Dil-labelling study. 1097 14

Shaking Rat Kawasaki (SRK) is an autosomal recessive mutant rat that is characterized by cerebellar ataxia. Although previous studies indicated many points of similarity between this mutant rat and the reeler mouse, nonlaminated structures such as the facial nucleus have not been studied in this mutant rat. Nissl-stained sections through the brainstem showed that the cytoarchitecture of the facial, motor trigeminal, and ambiguus nuclei was abnormal in SRK, especially in the lateral cell group of the facial nucleus and the compact formation of the ambiguus nucleus. To examine whether orofacial motoneurons are also malpositioned in the SRK rat, horseradish peroxidase (HRP) was injected into the facial, masticatory, and abdominal esophageal muscles of the SRK rats and normal controls to label facial, trigeminal, and ambiguus motoneurons, respectively. HRP-labeled facial, trigeminal, and ambiguus motoneurons of the SRK rat were distributed more widely than those of their normal counterparts, as in the case of the reeler mouse, with the one exception that labeled facial motoneurons innervating the nasolabial muscle were distributed more widely in the ventrolateral-to-dorsomedial direction in comparison with those of the reeler mutant. These data demonstrate that nonlaminated structures in the brainstem of the SRK rat are affected severely, as is the case in the reeler mutant mouse.
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PMID:Branchiogenic motoneurons innervating facial, masticatory, and esophageal muscles show aberrant distribution in the reeler-phenotype mutant rat, Shaking Rat Kawasaki. 1159 54

Shaking Rat Kawasaki (SRK) is an autosomal recessive mutant rat recognized by unstable gait and tremor and by early death around the time of weaning. We previously reported that corticospinal tract neurons are malpositioned in the motor cortex of the SRK rat [Ikeda and Terashima (1997) J. Comp. Neurol. 383, 370-380]. In the present study, we examined the distribution pattern of callosal commissural (CC) and corticothalamic (CT) neurons of SRK and normal rats with the injection of horseradish peroxidase (HRP) into the contralateral hemisphere or wheat germ agglutinin-conjugated HRP into the ventral lateral thalamic nucleus. The intracortical distribution pattern of retrogradely labeled CC and CT neurons in the motor cortex of SRK rat was abnormal: CC neurons were more deeply situated and CT neurons were more superficially situated in the SRK cortex than the corresponding components in the normal cortex. Most of labeled CC and CT neurons had abnormal dendritic configurations. Statistical analysis revealed that the difference of the mean intracortical position of CC and CT neurons of the SRK was significantly different from the normal counterparts (Student's t-test, P<0.01). Taken together with previous findings, our data demonstrate that the abnormal cytoarchitecture of SRK cortex resembles the reeler cortex.
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PMID:Abnormal distributions of callosal commissural and corticothalamic neurons in the cerebral neocortex of Shaking Rat Kawasaki. 1220 12

Shaking Rat Kawasaki (SRK) is a Reelin-deficient rat, that shows significant cytoarchitectural abnormalities in the cerebral and cerebellar cortices in a similar manner to the reeler malformation. In the present study, we investigated the cytoarchitecture and myeloarchitecture of the superior colliculus (SC) of this mutant rat. The Nissl staining clearly showed that neuronal components in the superficial layers of the SC in SRK rat were intermingled with each other and that the boundaries between these superficial layers were blurred. The MBP immunohistochemistry showed an abnormal fiber pattern in the superficial layers of the SC of this mutant rat. In the normal rat, myelinated fibers passed rostrocaudally through the optic layer, and only a few myelinated fibers were recognized in the uppermost two layers, i.e., the zonal and superficial gray layers. By contrast, in SRK rat, the myelinated fibers were distributed throughout the entire thickness of the superficial layers of the SC. Anterograde labeling of retinotectal fibers with an injection of Cholera Toxin subunit B into the retina revealed that this abnormal fiber pattern was associated with the anomalous course of the retinotectal fibers. No distinct differences in the cytoarchitecture and fiber pattern in the deep layers of the SC were seen. In conclusion, the present study demonstrated that the cytoarchitecture and fiber patterning in the superficial layers of the SC were disrupted in SRK rat, suggesting that Reelin protein regulates the formation of the superficial layers of the SC.
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PMID:Cytoarchitecture and fiber pattern of the superior colliculus are disrupted in the Shaking Rat Kawasaki. 1264 43

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 approximately 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.
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PMID:Missplicing resulting from a short deletion in the reelin gene causes reeler-like neuronal disorders in the mutant shaking rat Kawasaki. 1282 Jan 63

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