磷酸化酶重新表达、在绵羊肌营养不良模型中转录因子 NOTEXIN 诱导的肌肉损伤和再生后收缩力增加和疲劳减少。

Phosphorylase re-expression, increase in the force of contraction and decreased fatigue following notexin-induced muscle damage and regeneration in the ovine model of McArdle disease.

机构信息

School of Veterinary and Life Sciences, Murdoch University, Perth 6150, Western Australia, Australia; Australian Neuro-Muscular Research Institute,CNND, University of Western Australia, Perth 6150, Western Australia, Australia.

Centre for Medical Research, University of Western Australia, Perth 6150, Western Australia, Australia.

出版信息

Neuromuscul Disord. 2014 Feb;24(2):167-77. doi: 10.1016/j.nmd.2013.10.003. Epub 2013 Oct 26.

DOI:10.1016/j.nmd.2013.10.003

PMID:24309536

Abstract

McArdle disease is caused by a deficiency of myophosphorylase and currently a satisfactory treatment is not available. The injection of notexin into, or the layering of notexin onto, the muscles of affected sheep resulted in necrosis followed by regeneration of muscle fibres with the expression of both non-muscle isoforms of phosphorylase within the fibres and a reduction of the amount of glycogen in the muscle with an increase in the strength of contraction and a decrease in fatiguability in the muscle fibres. The sustained re-expression of both the brain and liver isoforms of phosphorylase within the muscle fibres provides further emphasis that strategies to enhance the re-expression of these isoforms should be investigated as a possible treatment for McArdle disease.

摘要

肌磷酸化酶缺乏症是由肌磷酸化酶缺乏引起的，目前尚无满意的治疗方法。将野黾毒素注入或涂敷于患病绵羊的肌肉中，会导致肌肉坏死，随后肌肉纤维再生，纤维内同时表达非肌肉型磷酸化酶同工酶，肌肉中的糖原含量减少，肌肉收缩力增强，疲劳性降低。肌肉纤维内持续重新表达脑型和肝型磷酸化酶同工酶，进一步强调了应该研究增强这些同工酶重新表达的策略，作为治疗肌磷酸化酶缺乏症的一种可能方法。

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磷酸化酶重新表达、在绵羊肌营养不良模型中转录因子 NOTEXIN 诱导的肌肉损伤和再生后收缩力增加和疲劳减少。

Phosphorylase re-expression, increase in the force of contraction and decreased fatigue following notexin-induced muscle damage and regeneration in the ovine model of McArdle disease.

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