Your search keyword '"Motohashi, Norio"' showing total 5 results

1. Mutation-independent Proteomic Signatures of Pathological Progression in Murine Models of Duchenne Muscular Dystrophy

Author

van Westering, Tirsa L.E., Johansson, Henrik J., Hanson, Britt, Coenen-Stass, Anna M.L., Lomonosova, Yulia, Tanihata, Jun, Motohashi, Norio, Yokota, Toshifumi, Takeda, Shin'ichi, Lehtiö, Janne, Wood, Matthew J.A., EL Andaloussi, Samir, Aoki, Yoshitsugu, and Roberts, Thomas C.

Abstract

In this study we report the highest resolution proteomics analysis performed in dystrophic muscle to date. The use of two mouse models of Duchenne muscular dystrophy, at three different ages, has enabled the identification of mutation-independent protein signatures associated with dystrophic muscle, and the progression of disease pathology.

Published

2020

2. Tbx1 regulates inherited metabolic and myogenic abilities of progenitor cells derived from slow- and fast-type muscle

Author

Motohashi, Norio, Uezumi, Akiyoshi, Asakura, Atsushi, Ikemoto-Uezumi, Madoka, Mori, Shuuichi, Mizunoe, Yuhei, Takashima, Rumi, Miyagoe-Suzuki, Yuko, Takeda, Shin’ichi, and Shigemoto, Kazuhiro

Abstract

Skeletal muscle is divided into slow- and fast-type muscles, which possess distinct contractile and metabolic properties. Myogenic progenitors associated with each muscle fiber type are known to intrinsically commit to specific muscle fiber lineage during embryonic development. However, it is still unclear whether the functionality of postnatal adult myogenic cells is attributable to the muscle fiber in which they reside, and whether the characteristics of myogenic cells derived from slow- and fast-type fibers can be distinguished at the genetic level. In this study, we isolated adult satellite cells from slow- and fast-type muscle individually and observed that satellite cells from each type of muscle generated myotubes expressing myosin heavy chain isoforms similar to their original muscle, and showed different metabolic features. Notably, we discovered that slow muscle-derived cells had low potential to differentiate but high potential to self-renew compared with fast muscle-derived cells. Additionally, cell transplantation experiments of slow muscle-derived cells into fast-type muscle revealed that slow muscle-derived cells could better contribute to myofiber formation and satellite cell constitution than fast muscle-derived cells, suggesting that the recipient muscle fiber type may not affect the predetermined abilities of myogenic cells. Gene expression analyses identified T-box transcriptional factor Tbx1as a highly expressed gene in fast muscle-derived myoblasts. Gain- and loss-of-function experiments revealed that Tbx1modulated muscle fiber types and oxidative metabolism in myotubes, and that Tbx1stimulated myoblast differentiation, but did not regulate myogenic cell self-renewal. Our data suggest that metabolic and myogenic properties of myogenic progenitor cells vary depending on the type of muscle from which they originate, and that Tbx1expression partially explains the functional differences of myogenic cells derived from fast-type and slow-type muscles.

Published

2019

3. Myotubularin-Deficient Myoblasts Display Increased Apoptosis, Delayed Proliferation, and Poor Cell Engraftment

Author

Lawlor, Michael W., Alexander, Matthew S., Viola, Marissa G., Meng, Hui, Joubert, Romain, Gupta, Vandana, Motohashi, Norio, Manfready, Richard A., Hsu, Cynthia P., Huang, Ping, Buj-Bello, Anna, Kunkel, Louis M., Beggs, Alan H., and Gussoni, Emanuela

Abstract

X-linked myotubular myopathy is a severe congenital myopathy caused by deficiency of the lipid phosphatase, myotubularin. Recent studies of human tissue and animal models have discovered structural and physiological abnormalities in myotubularin-deficient muscle, but the impact of myotubularin deficiency on myogenic stem cells within muscles is unclear. In the present study, we evaluated the viability, proliferative capacity, and in vivoengraftment of myogenic cells obtained from severely symptomatic (Mtm1δ4) myotubularin-deficient mice. Mtm1δ4 muscle contains fewer myogenic cells than wild-type (WT) littermates, and the number of myogenic cells decreases with age. The behavior of Mtm1δ4 myoblasts is also abnormal, because they engraft poorly into C57BL/6/Rag1null/mdx5cv mice and display decreased proliferation and increased apoptosis compared with WT myoblasts. Evaluation of Mtm1δ4 animals at 21 and 42 days of life detected fewer satellite cells in Mtm1δ4 muscle compared with WT littermates, and the decrease in satellite cells correlated with progression of disease. In addition, analysis of WT and Mtm1δ4 regeneration after injury detected similar abnormalities of satellite cell function, with fewer satellite cells, fewer dividing cells, and increased apoptotic cells in Mtm1δ4 muscle. These studies demonstrate specific abnormalities in myogenic cell number and behavior that may relate to the progression of disease in myotubularin deficiency, and may also be used to develop in vitroassays by which novel treatment strategies can be assessed.

Published

2012

4. Muscle CD31(−) CD45(−) Side Population Cells Promote Muscle Regeneration by Stimulating Proliferation and Migration of Myoblasts

Author

Motohashi, Norio, Uezumi, Akiyoshi, Yada, Erica, Fukada, So-ichiro, Fukushima, Kazuhiro, Imaizumi, Kazuhiko, Miyagoe-Suzuki, Yuko, and Takeda, Shin'ichi

Abstract

CD31(−) CD45(−) side population (SP) cells are a minor SP subfraction that have mesenchymal stem cell-like properties in uninjured skeletal muscle but that can expand on muscle injury. To clarify the role of these SP cells in muscle regeneration, we injected green fluorescent protein (GFP)-positive myoblasts with or without CD31(−) CD45(−) SP cells into the tibialis anterior muscles of immunodeficient NOD/scidmice or dystrophin-deficient mdxmice. More GFP-positive fibers were formed after co-transplantation than after transplantation of GFP-positive myoblasts alone in both mdxand NOD/scidmuscles. Moreover, grafted myoblasts were more widely distributed after co-transplantation than after transplantation of myoblasts alone. Immunohistochemistry with anti-phosphorylated histone H3 antibody revealed that CD31(−) CD45(−) SP cells stimulated cell division of co-grafted myoblasts. Genome-wide gene expression analyses showed that these SP cells specifically express a variety of extracellular matrix proteins, membrane proteins, and cytokines. We also found that they express high levels of matrix metalloproteinase-2 mRNA and gelatinase activity. Furthermore, matrix metalloproteinase-2 derived from CD31(−) CD45(−) SP cells promoted migration of myoblasts in vivo. Our results suggest that CD31(−) CD45(−) SP cells support muscle regeneration by promoting proliferation and migration of myoblasts. Future studies to further define the molecular and cellular mechanisms of muscle regeneration will aid in the development of cell therapies for muscular dystrophy.

Published

2008

5. β2-Agonist Clenbuterol Induced Changes in the Distribution of White Blood Cells in Rats

Author

Shirato, Ken, Tanihata, Jun, Motohashi, Norio, Tachiyashiki, Kaoru, Tomoda, Akio, and Imaizumi, Kazuhiko

Abstract

Clenbuterol [CLE: 4-amino-α(t-butyl-amino)methyl-3,5-dichlorobenzyl alcohol] is well known as a potent β2-adrenergic agonist and non-steroidal anabolic drug, and thus it is generally used for sports doping and asthma therapy. Although the functions of immune cells such as white blood cells (WBCs) have shown to be modulated through β2-adrenoceptors, the effects of CLE on immune-responsive systems have not been elucidated systematically. Therefore, the effects of CLE on the number of WBCs were studied in rats. Male adult rats were divided into CLE-administered group and the control group to compare the number of total WBCs, neutrophils, monocytes, lymphocytes, eosinophils, and basophils. The administration (dose = 1.0 mg ⋅ kg−1body weight ⋅ day−1, s.c.) of CLE was maintained for 30 days. CLE did not change the number of total WBCs during the experimental period. However, CLE increased significantly the number of neutrophils and monocytes, while CLE decreased drastically the number of lymphocytes and eosinophils. There was no significant change in the number of basophils between both groups. These results suggest that the administration of CLE induces drastic redistribution of WBCs in circulation without changing the number of total WBCs, and these responses of WBCs during the administration of CLE are sustained for at least 30 days.

Published

2007