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Impact of Exercise on Sarcopenia

运动对肌肉减少症的影响

基本信息

批准号：
7843579
负责人：
JUDD M. AIKEN
金额：
$ 43.7万
依托单位：
UNIVERSITY OF ALBERTA
依托单位国家：
美国
项目类别：
财政年份：
2009
资助国家：
美国
起止时间：
2009-05-15 至 2014-04-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/7843579
关键词：
Aerobic Aerobic Exercise Affect Age Age-Months Aging Animals Apoptotic Area Atrophic Attenuated Benefits and Risks Biological Models Complex Contractile Proteins Contralateral Cytochrome c Reductase Data Deletion Mutation Elderly Electron Transport Etiology Event Exercise Exhibits Fiber Genome Genotype Goals Health Human Hybrids Infiltration Intervention Link Literature Mammals Mechanics Mitochondria Mitochondrial DNA Modeling Moderate Exercise Molecular Morphology Muscle Muscle Fibers Mutation Necrosis Norway Outcome Study Oxidases Phenotype Play Prevalence Process Property Rattus Regimen Role Skeletal Muscle Soleus Muscle Succinate Dehydrogenase System Testing Time Training age related aged base combat cytochrome c oxidase design disability enzyme activity healthy aging male mature animal mitochondrial DNA mutation muscle aging muscle form public health relevance rectus femoris research study sarcopenia sedentary tool vastus lateralis

项目摘要

DESCRIPTION (provided by applicant): Sarcopenia, the loss of muscle mass and function due to muscle fiber loss and atrophy, is a prominent and debilitating age-related consequence in humans. There is a need for a healthy aging model system to efficiently evaluate potential interventions that delay or reduce sarcopenia of the aged. We defined the onset of significant muscle mass and fiber loss in the Fischer 344 x Brown Norway hybrid rat (FBN) at 30 months of age. Our studies have demonstrated that mitochondrial DNA (mtDNA) abnormalities play a causal role in muscle fiber loss. We have shown that age-dependent mtDNA deletion mutations clonally accumulate to high levels in aged skeletal muscle fibers. Concomitant with this increase in aberrant genomes is a loss of complex IV (cytochrome c oxidase; COX-) activity of the electron transport system (ETS) and the hyper-reactivity of complex II (succinate dehydrogenase; SDH++). These COX-/SDH++ regions of abnormal fibers are prone to atrophy and breakage, linking a molecular event, mtDNA deletion mutations, with an aging phenotype, muscle fiber loss. Endurance training is a common intervention employed by the elderly to combat the loss of muscle mass and function that occurs with age. Very little, however, is known of the impact of this intervention in very old humans or animals. We have recently completed a study showing that 3 months of high intensity endurance training, initiated at 30 months of age in the male FBN rat, increased the prevalence of ETS abnormal fibers, a detrimental process that leads to fiber loss. Our data is consistent with a rapidly growing body of literature that indicates the level of exercise necessary for beneficial adaptation declines with age. We hypothesize that the benefits/risks of aerobic exercise is dependent on i) the age at which aerobic exercise is initiated and ii) the intensity level of the exercise. To test this hypothesis, we will initiate two levels of exercise (moderate and high) prior to (24-month-old rats; SA1) and at the onset (30-month-old rats; SA2) of significant accumulation of mitochondrial abnormalities, muscle mass loss and fiber loss in male FBN rats. The sarcopenic profiles (muscle morphology and fiber fate) will be determined in control rats (sedentary at 24-. 30 and 36 months) and experimental rats at 36-months of age. These analyses will define muscle mass, muscle cross-sectional area, fiber number, fiber cross-sectional area, fiber type and fibrotic infiltration, as well as the number of fibers exhibiting necrotic and apoptotic changes. The impact of exercise on the abundance and progression and mtDNA deletion load will be determined in affected fibers (SA 3). We will also ascertain if single fibers with high mtDNA deletion loads have altered contractile function and whether exercise alters the mechanical properties of affected single fibers (SA4). This exercise model will serve as a means of testing our proposed mechanism of age-related fiber loss as well as further our understanding of the impact of aerobic exercise in aged skeletal muscle. An important outcome of these studies is to determine if endurance training, a commonly employed intervention of sarcopenia, can be beneficial to muscle health in old mammals. PUBLIC HEALTH RELEVANCE: Sarcopenia, the loss of muscle mass and function due to muscle fiber loss and atrophy, is a prominent and debilitating age-related consequence in humans. Although endurance training is a commonly applied intervention in the elderly, the benefits/risks are not well delineated and its impact is normally studied in young. By quantifying the molecular, cellular and functional effects of different regimens of endurance training on skeletal muscle in old and very old rats, we will determine whether endurance training attenuates sarcopenia.

描述（由申请方提供）：肌肉减少症，即由于肌纤维损失和萎缩导致的肌肉质量和功能损失，是人类中一种显著的和使人衰弱的年龄相关后果。需要一种健康老化模型系统来有效地评估延迟或减少老年人的肌肉减少症的潜在干预。我们定义了Fischer 344 x Brown Norway杂交大鼠（FBN）在30月龄时出现的显著肌肉质量和纤维丢失。我们的研究表明，线粒体DNA（mtDNA）异常在肌纤维损失中起着因果作用。我们已经证明，年龄依赖性mtDNA缺失突变在老年骨骼肌纤维中克隆积累到高水平。伴随着这种异常基因组的增加是电子传递系统（ETS）的复合物IV（细胞色素c氧化酶;考克斯-）活性的丧失和复合物II（琥珀酸脱氢酶; SDH++）的高反应性。这些异常纤维的考克斯-/SDH++区域易于萎缩和断裂，将分子事件、mtDNA缺失突变与衰老表型、肌纤维损失联系起来。耐力训练是老年人常用的干预措施，以对抗随着年龄的增长而发生的肌肉质量和功能的丧失。然而，很少有人知道这种干预对非常古老的人类或动物的影响。我们最近完成的一项研究表明，在雄性FBN大鼠30个月大时开始的3个月高强度耐力训练增加了ETS异常纤维的患病率，这是一种导致纤维丢失的有害过程。我们的数据与快速增长的文献一致，这些文献表明有益适应所需的运动水平随着年龄的增长而下降。我们假设有氧运动的益处/风险取决于i）开始有氧运动的年龄和ii）运动的强度水平。为了检验这一假设，我们将在雄性FBN大鼠中线粒体异常、肌肉质量损失和纤维损失显著积累之前（24月龄大鼠; SA 1）和开始时（30月龄大鼠; SA 2）开始两个水平的运动（中度和高度）。将在对照大鼠（24- 24小时久坐）中测定肌肉减少特征（肌肉形态学和纤维命运）。30和36个月）和36个月龄的实验大鼠。这些分析将定义肌肉质量、肌肉横截面积、纤维数量、纤维横截面积、纤维类型和纤维化浸润，以及表现出坏死和凋亡变化的纤维数量。将在受影响的纤维中确定运动对丰度和进展以及mtDNA缺失负荷的影响（SA 3）。我们还将确定高mtDNA缺失负荷的单纤维是否改变了收缩功能，以及运动是否改变了受影响的单纤维的机械特性（SA 4）。这个运动模型将作为一种手段来测试我们提出的与年龄相关的纤维损失的机制，以及进一步了解有氧运动对老年骨骼肌的影响。这些研究的一个重要成果是确定耐力训练（一种常用的肌肉减少症干预措施）是否有益于老年哺乳动物的肌肉健康。公共卫生相关性：肌肉减少症，由于肌肉纤维损失和萎缩导致的肌肉质量和功能的损失，是人类中一种突出的和使人衰弱的年龄相关后果。虽然耐力训练是老年人常用的干预措施，但其益处/风险尚未得到很好的描述，其影响通常在年轻人中进行研究。通过量化不同耐力训练方案对老年和极老年大鼠骨骼肌的分子、细胞和功能影响，我们将确定耐力训练是否减轻肌肉减少症。