Shoichi Takikita

Activation of Src Kinase in Platelet-Derived Growth Factor-B-Dependent Tubular Regeneration after Acute Ischemic Renal Injury

We previously reported that the platelet-derived growth factor B-chain (PDGF-B)/PDGF receptor (PDGFR) axis is involved in tubular regeneration after ischemia/reperfusion injury of the kidney. In the present study, we examined the activation of Src tyrosine kinase, a crucially important signaling molecule for PDGFR, and assessed the role of Src in PDGF-B-dependent renal tubular regeneration afterischemia/reperfusion injury. Immunoblot using clone 28, a monoclonal antibody specific for the active form of Src kinases, demonstrated increased active Src expression in the injured rat kidney 6 hours after reperfusion with peak activation at 12 hours. In vitro kinase assay confirmed increased Src activity that concurred with PDGFR-beta activation as detected by the increment of receptor-phosphorylated tyrosine. Immunohistochemistry using clone 28 demonstrated that active Src was preferentially expressed in the S3 segment of the proximal tubule in reperfused kidney, where it is not normally expressed. This enhanced expression of active Src was co-localized with the increased PDGFR expression in the tubular cells that were undergoing cell proliferation cycle. Trapidil administration suppressed Src and PDGFR-beta activation in the reperfused kidney and resulted in deteriorated renal function. These findings suggest that active Src participates in PDGF-B-dependent regeneration of tubular cells from acute ischemic injury.

Thyrotropin-releasing hormone: role in the treatment of West syndrome and related epileptic encephalopathies.

Thyrotropin-releasing hormone (TRH) has been successfully used for treating children with neurologic disorders including epilepsy. The effectiveness of TRH and a TRH analog has been reported in West syndrome, Lennox-Gastaut syndrome, and early infantile epileptic encephalopathy that were intractable to anticonvulsants and adrenocorticotrophic hormone (ACTH). However, the peptide has not been widely studied as a treatment of intractable epilepsy outside Japan. TRH is safe in children and effective in some cases of West syndrome and Lennox-Gastaut syndrome. TRH is considered as a possible new strategy for treating West syndrome and Lennox-Gastaut syndrome prior to ACTH therapy, especially for the patient with an infection, immunosuppression, or severe organic lesions in the brain. The mechanisms of its antiepileptic action may differ from those of other antiepileptic drugs. One possibility is that TRH may act as an antiepileptic through a kynurenine mechanism, considering that kynurenic acid acts as an antagonist on the N-methyl-D-aspartate receptor complex.

Experimental mumps virus-induced hydrocephalus: viral neurotropism and neuronal maturity.

In order to elucidate the relationship between virus neurotropism and neuronal maturity, two experiments were performed. First, mumps virus infectivity was compared among the different developmental stages of hamster brains inoculated with mumps virus by examining the immunohistochemical distribution of mumps virus antigen. Second, brain lesions resulting from mumps virus infection during the period of neuronal migration were histologically and ultrastructurally analyzed. Three groups of Syrian hamsters, Group E12 (fetuses on the 12th day of gestation), and Groups P2 and P30 (2 and 30 days old, respectively), were injected with mumps virus intraplacentally or intracerebrally. In Group P30, mumps virus antigen was observed specifically in ependymal cells and the choroid plexus. In addition to these areas, in Group P2, some neurons in layers II and III of the cerebral cortex also showed virus antigen immunoreactivity. In Group E12, mumps virus antigen accumulated primarily in the neuroepithelial cells within the ventricular zone. Neither specific intranuclear changes related to viral replication nor the formation of complete virions and nucleocapsids was observed. We conclude that mumps virus neurotropism to hamster brains is dependent on the degree of neuronal maturity and that mumps virus can induce an abortive infection and resultant neuronal cell necrosis in the immature developing hamster brain.

Neuronal Apoptosis Mediated by IL-1β Expression in Viral Encephalitis Caused by a Neuroadapted Strain of the Mumps Virus (Kilham Strain) in Hamsters

The neuroadapted Kilham strain of the mumps virus produces lethal encephalitis in newborn hamsters after intracerebral inoculation. The pathogenesis of this encephalitis is not fully understood, but recently, apoptosis and associated cytokine production have been recognized to be major pathologic mechanisms by which viruses cause injury to neuronal host cells. To analyze the main factors producing brain injury in this viral encephalitis, the following questions were investigated: (1) does the virus induce neuronal apoptosis and (2) does expression of cytokines regulate the induction of neuronal apoptosis? Terminal deoxynucleotidyl transferase-mediated dUTP nick end-labeling (TUNEL) was used as a marker of neuronal apoptosis and TUNEL-positive neurons were widespread in the infected cerebral cortex. DNA fragmentation yielding DNA ladders characteristic of apoptosis was also observed in infected hamster brain tissue. Apoptotic cells in infected brains were observed after the appearance of inflammatory changes. Overexpression of IL-1 beta, but not TNF-alpha or Fas-L, was clearly detected in infected brains, as determined by Western blot and RT-PCR. Immunohistochemistry revealed a striking correlation between IL-1 beta expression and neuronal apoptosis. Injection of recombinant IL-1 beta into normal hamster brain resulted in neuronal apoptosis in cerebral cortex. On the other hand, neutralizing IL-1 beta antibodies decreased the number of cells undergoing apoptosis in infected hamster brains and subsequent death. We conclude that the fatal encephalitis induced by the Kilham strain of the mumps virus is mediated by immunopathological processes and that overexpression of IL-1 beta, which mediates the induction of neuronal apoptosis, may play a major role in these processes.

Experimental schizencephaly induced by Kilham strain of mumps virus : pathogenesis of cleft formation

The pathogenesis of cleft formation in schizencephaly was analyzed by examining the brain lesions produced by the infection of the Kilham strain of mumps virus during the period of neuronal migration in hamsters. Mumps virus antigen was detected in the neuroepithelial cells within the ventricular zone, the choroid plexus in the lateral ventricles, and vimentin-immunoreactive radial glial fibers. The main pathological findings were cerebral hemorrhage, neuronal necrosis, microsulci on the cerebral cortex and cleft formation through the entire thickness of the cerebral mantle. The clefts seen in these experiments were lined by embryonal elements such as neuroepithelial cells and germinal cells. Based on these results and the original definition by Yakovlev and Wadsworth, the following two conclusions were suggested. First, the mumps virus localized to the neuroepithelial cells within the ventricular zone and the radial glial fibers may induce a destructive process and subsequent anomalous neuronal migration, resulting in cleft formation. Second, the formation of the ventricular cleft extending to the pial surface, which should be complete before the cortical infolding appears, is necessary in order to produce the characteristic cleft in schizencephaly which is associated with the pial-ependymal seam.

Experimental cortical dysplasia following ibotenate administration in hamsters: Pathogenesis of microgyria and associated gray matter heterotopia

ABSTRACT  The study presented here investigated the pathogenetic relationship among different types of neuronal migration disorders occurring simultaneously in the brain using an experimental model induced by ibotenate in hamsters. In the cerebral cortex, abnormal neuronal arrangement was induced 1 day after ibotenate injection. This brain lesion resulted in microgyria in the rostral portion, focal subcortical heterotopia in the mid‐portion, and focal subependymal heterotopia in the caudal portion in the same specimen. Vimentin‐immunoreactive radial glial fibers were lacking in the area of disorganized neuronal arrangement, but were detected around the microgyria and the intermediate zone surrounding focal subcortical heterotopia. The focal subependymal heterotopia did not include radial glial elements. Glial fibrillary acidic protein (GFAP)‐positive glial reaction was weak in these cortical lesions. We suggest that the occurrence of each type of migration disorder depends on the depth of the cortical lesion, that is, the production of microgyria, focal subcortical heterotopia and focal subependymal heterotopia are closely related to the lesions including the cortical plate, subplate and ventricular zone, respectively.

Increased apoptosis and hypomyelination in cerebral white matter of macular mutant mouse brain

Hypomyelination in developing brain is often accompanied by congenital metabolic disorders. Menkes kinky hair disease is an X-linked neurodegenerative disease of impaired copper transport, resulting from a mutation of the Menkes disease gene, a transmembrane copper-transporting p-type ATPase gene (ATP7A). In a macular mutant mouse model, the murine ortholog of Menkes gene (mottled gene) is mutated, and widespread neurodegeneration and subsequent death are observed. Although some biochemical analysis of myelin protein in macular mouse has been reported, detailed histological study of myelination in this mouse model is currently lacking. Since myelin abnormality is one of the neuropathologic findings of human Menkes disease, in this study early myelination in macular mouse brain was evaluated by immunohistochemistry. Two-week-old macular mice and normal littermates were perfused with 4% paraformaldehyde. Immunohistochemical staining of paraffin embedded and vibratome sections was performed using antibodies against either CNPase, cleaved caspase-3 or O4 (marker of immature oligodendrocytes). This staining showed that cerebral myelination in macular mouse was generally hypoplastic and that hypomyelination was remarkable in internal capsule, corpus callosum, and cingulate cortex. In addition, an increased number of cleaved caspase-3 positive cells were observed in corpus callosum and internal capsule. Copper deficiency induced by low copper diet has been reported to induce oligodendrocyte dysfunction and leads to hypomyelination in this mouse model. Taken together, hypomyelination observed in this study in a mouse model of Menkes disease is assumed to be induced by increased apoptosis of immature oligodendrocytes in developing cerebrum, through deficient intracellular copper metabolism.