1 The Human Mitochondrion and Pathophysiology of Aging and Age-related Diseases

D. Wallace
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Abstract

During the past decade, interest has grown rapidly in the possibility that mitochondrial dysfunction has a significant role in the etiology of aging and the age-related diseases (Wallace 1992b). However, the potential importance of the mitochondrion in these processes has not been fully explored due in part to the dominance of the anatomical and Mendelian paradigms in Western medicine. Although these two paradigms have been highly successful in addressing organ-specific symptoms and Mendelian inherited diseases, respectively, they have been relatively unsuccessful in clarifying the etiology of multisystem, age-related disorders. Aging affects a variety of systems, although to different extents in different individuals. Furthermore, in stark contrast to the prediction of Mendelian genetics in which genetic traits are biallelic and thus quantized (+/+, +/−, −/−), age-related symptoms show a gradual decline suggestive of quantitative rather than quantized genetics. These ambiguities might be explained by adding the mitochondrial energetic and genetics paradigms to the existing anatomical and Mendelian paradigms. The mitochondria generate the energy for the body, although different tissues rely on mitochondrial energy to different extents. Moreover, each cell contains hundreds of mitochondria and thousands of mitochondrial DNAs (mtDNAs), with each mtDNA encoding the same 13 proteins that are critical for mitochondrial energy production. The mtDNA also has a very high mutation rate, such that mtDNA mutations accumulate in tissues over time. This results in a stochastic decline in energy output that ultimately falls below the minimal energetic threshold, resulting in cell loss, tissue dysfunction, and symptoms. WHY DO WE HAVE...
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人类线粒体与衰老和衰老相关疾病的病理生理
在过去的十年中,人们对线粒体功能障碍在衰老和与年龄有关的疾病的病因学中起重要作用的可能性的兴趣迅速增长(Wallace 1992b)。然而,线粒体在这些过程中的潜在重要性尚未得到充分探索,部分原因是西方医学中解剖学和孟德尔范式的主导地位。尽管这两种范式分别在解决器官特异性症状和孟德尔遗传疾病方面非常成功,但它们在阐明多系统、年龄相关疾病的病因方面相对不成功。衰老影响各种系统,尽管在不同的个体中影响程度不同。此外,与孟德尔遗传学的预测形成鲜明对比的是,孟德尔遗传学的遗传性状是双等位基因,因此是量化的(+/+,+/−,- /−),与年龄相关的症状表现出逐渐下降的迹象,表明是定量的而不是量化的遗传。这些模糊性可以通过将线粒体能量和遗传学范式添加到现有的解剖学范式和孟德尔范式中来解释。线粒体为身体产生能量,尽管不同的组织在不同程度上依赖线粒体能量。此外,每个细胞含有数百个线粒体和数千个线粒体dna (mtDNA),每个mtDNA编码相同的13种蛋白质,这些蛋白质对线粒体能量的产生至关重要。mtDNA也具有非常高的突变率,因此随着时间的推移,mtDNA突变在组织中积累。这导致能量输出随机下降,最终低于最小能量阈值,导致细胞损失、组织功能障碍和症状。为什么我们有……
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