Your search keyword '"Morito Takano"' showing total 2 results

1. Inflammatory cascades mediate synapse elimination in spinal cord compression

Author

Masaya Nakamura, Yuji Komaki, Yoshiaki Toyama, Keigo Hikishima, Morito Takano, Shinsuke Shibata, Hideyuki Okano, and Soya Kawabata

Subjects

Pathology, medicine.medical_specialty, Time Factors, Immunology, Inflammation, Spinal canal stenosis, Severity of Illness Index, Synapse, Mice, Cellular and Molecular Neuroscience, Spinal cord compression, medicine, Animals, Pyrophosphatases, Movement Disorders, Microglia, business.industry, Complement C1q, Gene Expression Profiling, Macrophages, Research, General Neuroscience, Neurodegeneration, cervical compressive myelopathy, Spinal cord, medicine.disease, Magnetic Resonance Imaging, complement activation classical pathway, Mice, Mutant Strains, Pathophysiology, Disease Models, Animal, tip-toe walking Yoshimura mice, medicine.anatomical_structure, Gene Expression Regulation, Spinal Cord, Neurology, Mutation, Synapses, synapse elimination, medicine.symptom, business, Spinal Cord Compression, Cysteine-Rich Protein 61, Signal Transduction

Abstract

Background Cervical compressive myelopathy (CCM) is caused by chronic spinal cord compression due to spondylosis, a degenerative disc disease, and ossification of the ligaments. Tip-toe walking Yoshimura (twy) mice are reported to be an ideal animal model for CCM-related neuronal dysfunction, because they develop spontaneous spinal cord compression without any artificial manipulation. Previous histological studies showed that neurons are lost due to apoptosis in CCM, but the mechanism underlying this neurodegeneration was not fully elucidated. The purpose of this study was to investigate the pathophysiology of CCM by evaluating the global gene expression of the compressed spinal cord and comparing the transcriptome analysis with the physical and histological findings in twy mice. Methods Twenty-week-old twy mice were divided into two groups according to the magnetic resonance imaging (MRI) findings: a severe compression (S) group and a mild compression (M) group. The transcriptome was analyzed by microarray and RT-PCR. The cellular pathophysiology was examined by immunohistological analysis and immuno-electron microscopy. Motor function was assessed by Rotarod treadmill latency and stride-length tests. Results Severe cervical calcification caused spinal canal stenosis and low functional capacity in twy mice. The microarray analysis revealed 215 genes that showed significantly different expression levels between the S and the M groups. Pathway analysis revealed that genes expressed at higher levels in the S group were enriched for terms related to the regulation of inflammation in the compressed spinal cord. M1 macrophage-dominant inflammation was present in the S group, and cysteine-rich protein 61 (Cyr61), an inducer of M1 macrophages, was markedly upregulated in these spinal cords. Furthermore, C1q, which initiates the classical complement cascade, was more upregulated in the S group than in the M group. The confocal and electron microscopy observations indicated that classically activated microglia/macrophages had migrated to the compressed spinal cord and eliminated synaptic terminals. Conclusions We revealed the detailed pathophysiology of the inflammatory response in an animal model of chronic spinal cord compression. Our findings suggest that complement-mediated synapse elimination is a central mechanism underlying the neurodegeneration in CCM.

Published

2014

2. Inflammatory cascades mediate synapse elimination in spinal cord compression.

Author

Morito Takano, Soya Kawabata, Yuji Komaki, Shinsuke Shibata, Keigo Hikishima, Yoshiaki Toyama, Hideyuki Okano, and Masaya Nakamura

Subjects

SPINAL cord diseases, SPINAL cord compression, SPONDYLOSIS, OSSIFICATION, GENE expression, MAGNETIC resonance imaging

Abstract

Background Cervical compressive myelopathy (CCM) is caused by chronic spinal cord compression due to spondylosis, a degenerative disc disease, and ossification of the ligaments. Tip-toe walking Yoshimura (twy) mice are reported to be an ideal animal model for CCM-related neuronal dysfunction, because they develop spontaneous spinal cord compression without any artificial manipulation. Previous histological studies showed that neurons are lost due to apoptosis in CCM, but the mechanism underlying this neurodegeneration was not fully elucidated. The purpose of this study was to investigate the pathophysiology of CCM by evaluating the global gene expression of the compressed spinal cord and comparing the transcriptome analysis with the physical and histological findings in twy mice. Methods Twenty-week-old twy mice were divided into two groups according to the magnetic resonance imaging (MRI) findings: a severe compression (S) group and a mild compression (M) group. The transcriptome was analyzed by microarray and RT-PCR. The cellular pathophysiology was examined by immunohistological analysis and immuno-electron microscopy. Motor function was assessed by Rotarod treadmill latency and stride-length tests. Results Severe cervical calcification caused spinal canal stenosis and low functional capacity in twy mice. The microarray analysis revealed 215 genes that showed significantly different expression levels between the S and the M groups. Pathway analysis revealed that genes expressed at higher levels in the S group were enriched for terms related to the regulation of inflammation in the compressed spinal cord. M1 macrophage-dominant inflammation was present in the S group, and cysteine-rich protein 61 (Cyr61), an inducer of M1 macrophages, was markedly upregulated in these spinal cords. Furthermore, C1q, which initiates the classical complement cascade, was more upregulated in the S group than in the M group. The confocal and electron microscopy observations indicated that classically activated microglia/macrophages had migrated to the compressed spinal cord and eliminated synaptic terminals. Conclusions We revealed the detailed pathophysiology of the inflammatory response in an animal model of chronic spinal cord compression. Our findings suggest that complement-mediated synapse elimination is a central mechanism underlying the neurodegeneration in CCM. [ABSTRACT FROM AUTHOR]

Published

2014