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60. Diabetes and Stem Cell Function

Author

Fujimaki, Shin, Wakabayashi, Tamami, Takemasa, Tohru, Asashima, Makoto, and Kuwabara, Tomoko

Subjects
Article Subject
Abstract

Diabetes mellitus is one of the most common serious metabolic diseases that results in hyperglycemia due to defects of insulin secretion or insulin action or both. The present review focuses on the alterations to the diabetic neuronal tissues and skeletal muscle, including stem cells in both tissues, and the preventive effects of physical activity on diabetes. Diabetes is associated with various nervous disorders, such as cognitive deficits, depression, and Alzheimer’s disease, and that may be caused by neural stem cell dysfunction. Additionally, diabetes induces skeletal muscle atrophy, the impairment of energy metabolism, and muscle weakness. Similar to neural stem cells, the proliferation and differentiation are attenuated in skeletal muscle stem cells, termed satellite cells. However, physical activity is very useful for preventing the diabetic alteration to the neuronal tissues and skeletal muscle. Physical activity improves neurogenic capacity of neural stem cells and the proliferative and differentiative abilities of satellite cells. The present review proposes physical activity as a useful measure for the patients in diabetes to improve the physiological functions and to maintain their quality of life. It further discusses the use of stem cell-based approaches in the context of diabetes treatment.

Published
2015
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68. Intrinsic Ability of Adult Stem Cell in Skeletal Muscle: An Effective and Replenishable Resource to the Establishment of Pluripotent Stem Cells

Author

Fujimaki, Shin, Machida, Masanao, Hidaka, Ryo, Asashima, Makoto, Takemasa, Tohru, and Kuwabara, Tomoko

Subjects
Article Subject
Abstract

Adult stem cells play an essential role in mammalian organ maintenance and repair throughout adulthood since they ensure that organs retain their ability to regenerate. The choice of cell fate by adult stem cells for cellular proliferation, self-renewal, and differentiation into multiple lineages is critically important for the homeostasis and biological function of individual organs. Responses of stem cells to stress, injury, or environmental change are precisely regulated by intercellular and intracellular signaling networks, and these molecular events cooperatively define the ability of stem cell throughout life. Skeletal muscle tissue represents an abundant, accessible, and replenishable source of adult stem cells. Skeletal muscle contains myogenic satellite cells and muscle-derived stem cells that retain multipotent differentiation abilities. These stem cell populations have the capacity for long-term proliferation and high self-renewal. The molecular mechanisms associated with deficits in skeletal muscle and stem cell function have been extensively studied. Muscle-derived stem cells are an obvious, readily available cell resource that offers promise for cell-based therapy and various applications in the field of tissue engineering. This review describes the strategies commonly used to identify and functionally characterize adult stem cells, focusing especially on satellite cells, and discusses their potential applications.

Published
2013
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72. Functional Overload Enhances Satellite Cell Properties in Skeletal Muscle.

Author

Fujimaki, Shin, Machida, Masanao, Wakabayashi, Tamami, Asashima, Makoto, Takemasa, Tohru, and Kuwabara, Tomoko

Abstract

Skeletal muscle represents a plentiful and accessible source of adult stem cells. Skeletal-muscle-derived stem cells, termed satellite cells, play essential roles in postnatal growth, maintenance, repair, and regeneration of skeletal muscle. Although it is well known that the number of satellite cells increases following physical exercise, functional alterations in satellite cells such as proliferative capacity and differentiation efficiency following exercise and their molecular mechanisms remain unclear. Here, we found that functional overload, which is widely used to model resistance exercise, causes skeletal muscle hypertrophy and converts satellite cells from quiescent state to activated state. Our analysis showed that functional overload induces the expression of MyoD in satellite cells and enhances the proliferative capacity and differentiation potential of these cells. The changes in satellite cell properties coincided with the inactivation of Notch signaling and the activation of Wnt signaling and likely involve modulation by transcription factors of the Sox family. These results indicate the effects of resistance exercise on the regulation of satellite cells and provide insight into the molecular mechanism of satellite cell activation following physical exercise. [ABSTRACT FROM AUTHOR]

Published
2015
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98. RNA Overshoot Accompanies Recovery of Delayed Plantaris Muscle Growth Resulting from Juvenile Hindlimb Suspension.

Author

MACHIDA, Masanao, TAKEDA, Kohei, FUJIMAKI, Shin, IKEMUNE, Sachiko, NESORI, Sachie, KIYOSAWA, Hidenori, and TAKEMASA, Tohru

Abstract

Delay in the growth of skeletal muscle resulting from physical inactivity during the juvenile period may affect the subsequent quality of life. Therefore, it is important to clarify whether recovery of this muscle growth delay can be achieved by physical training thereafter. In the present study, mice were subjected to hindlimb suspension from 5 to 8 weeks of age to induce a delay of muscle growth and reloading from 8 weeks of age to recovery of muscle. Growth of the plantaris muscle, which is composed of fast-twitch fibers, was monitored at 5, 8, 11 and 14 weeks of age. This revealed that the growth of the plantaris had completely recovered from this delay by 11 weeks of age. Moreover, the recovery was accompanied by a significant increase of RNA content relative to control muscle. Since ribosomal RNA accounts for the majority of total RNA, it was thought that the machinery for protein synthesis had become activated in the recovering muscle. In addition, phosphorylated ribosomal protein S6, which is an important factor for efficient translation, was increased at the same time. These results suggested that protein synthesis was enhanced in recovering muscle. In addition, the recovering muscle showed activation of the Erk pathway, one of the pathways controlling the expression of ribosomal RNA. These results suggest that loss of skeletal muscle due to unloading during the juvenile period can be completely recovered by reloading, and that this recovery might require an increase of RNA content mediated by the Erk pathway. [ABSTRACT FROM AUTHOR]

Published
2013

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