Johnson W Thomas, Newman Samuel M
United States Department of Agriculture, Agricultural Research Service, Grand Forks Human Nutrition Research Center, Grand Forks, North Dakota 58202-9034 ; USDA, ARS, GFHNRC, P.O. Box 9034, Grand Forks, ND 58202-9034.
J Am Aging Assoc. 2003 Jan;26(1-2):19-28. doi: 10.1007/s11357-003-0003-x.
Heart mitochondria experience age-related declines in cytochrome c oxidase (CCO) activity and increases in the generation of reactive oxygen species (ROS) that may contribute to loss of cardiac function and the development of disease that occur with advancing age. In a manner similar to aging, copper deficiency also suppresses heart CCO activity and has cardiovascular consequences related to increased peroxidation. Food restriction is often used as a tool to study oxidative mechanisms of aging and the present study examines the potential of copper deficiency to model the role of mitochondria in cardiac aging by determining if the effect of food restriction on CCO activity and oxidative stress in heart mitochondria parallels its effect on cardiac mitochondria during aging. Overall, copper deficiency severely inhibited CCO activity and increased both Mn superoxide dismutase (MnSOD) and glutathione peroxidase (GPX) in isolated heart mitochondria. However, a 20% reduction in food intake by copper-deficient rats increased CCO activity by 65% and decreased MnSOD activity by 25% but had no effect in rats fed adequate copper. Copper deficiency also reduced the carbonyl content of 80-100 kDa mitochondrial proteins, but the reduction in carbonyl content was unaffected by food restriction. Food restriction did, however, completely prevent the enlargement of cardiac mitochondria in copper-deficient rats. Together, these findings indicate that copper deficiency induces mitochondrial antioxidant enzyme activity and hypertrophy in cardiac tissue in response to reduced CCO activity and that food restriction may counteract these changes by reducing oxidative stress. Because the action of food restriction on CCO activity and mitochondrially generated oxidative stress are similar in copper deficiency and aging, copper deficiency may serve as a short-term model for studying the potential roles of mitochondria in cardiac aging.
心脏线粒体的细胞色素c氧化酶(CCO)活性会随着年龄增长而下降,活性氧(ROS)生成增加,这可能导致心脏功能丧失以及随着年龄增长而出现的疾病发展。与衰老类似,铜缺乏也会抑制心脏CCO活性,并产生与过氧化增加相关的心血管后果。食物限制常被用作研究衰老氧化机制的工具,本研究通过确定食物限制对心脏线粒体CCO活性和氧化应激的影响是否与衰老过程中对心脏线粒体的影响相似,来检验铜缺乏模拟线粒体在心脏衰老中作用的潜力。总体而言,铜缺乏严重抑制了分离的心脏线粒体中的CCO活性,并增加了锰超氧化物歧化酶(MnSOD)和谷胱甘肽过氧化物酶(GPX)的活性。然而,铜缺乏大鼠食物摄入量减少20%会使CCO活性增加65%,MnSOD活性降低25%,但对摄入充足铜的大鼠没有影响。铜缺乏还降低了80 - 100 kDa线粒体蛋白的羰基含量,但羰基含量的降低不受食物限制的影响。不过,食物限制确实完全阻止了铜缺乏大鼠心脏线粒体的增大。这些发现共同表明,铜缺乏会因CCO活性降低而诱导心脏组织中的线粒体抗氧化酶活性和肥大,而食物限制可能通过降低氧化应激来抵消这些变化。由于食物限制对CCO活性和线粒体产生的氧化应激的作用在铜缺乏和衰老过程中相似,铜缺乏可能作为研究线粒体在心脏衰老中潜在作用的短期模型。