The Mitochondrial Free Radical Theory of Aging - Supernova: Pliki

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A Descriptive Introduction to Human Aging 5.7.2. Pathological Pleiotropy Another way of looking at the pleiotropy of aging is from the evolutionary perspective. Natural selection has determined our lifespan, just as it determined everything else about our biology; moreover, it seems to be able to vary it remarkably easily, since (to take just one example) we live more than twice as long as our nearest relatives, chimpanzees. The environmental factor that most centrally determines maximum lifespan is now widely believed to be a species’s rate of extrinsic (age-independent) mortality, which in turn is mainly determined by its position in the food chain; this "disposable soma theory" will be described in Section 6.5.2. Here we will examine just one aspect of it: how many things (genes, systems) have to be varied. The answer from evolutionary theory is clear: everything—that is, all of the irreversible changes listed in Section 5.6 and any change to anything else that is not actively recycled. All of these degenerative processes can be slowed, but only at a metabolic cost, since maintenance requires energy and hence consumes nutrients. Therefore, none of these changes will be retarded “unnecessarily” assiduously, because that would be a waste of energy. An organism’s lifespan will not be increased by slowing one or two of these changes, only by slowing all of them. Thus, in well-tuned organisms (which is what evolution creates), all of those changes will reach macroscopically pathological proportions at about the same age (though perhaps only in one organ, as for lipofuscin in the retina)—which is exactly what we see, as surveyed in this chapter. But that pleiotropy is also overinterpretable. This chapter has drawn attention to the highly uneven distribution of some of these changes—that lipofuscin only does harm in the retina, for example; others, such as cancer and atherosclerosis, can happen in many places but don’t happen everywhere at once. This is a large part of the reason why such phenomena are popularly—and inaccurately—thought of as “not really aging”, but rather as diseases. But it has a profound implication for the practicality of extending lifespan by medical intervention: that all of these “particulate” pathologies are treatable by correspondingly particulate interventions, such as surgery. Therefore, the irreversible molecular changes that we should consider as the heart of aging from an interventionist viewpoint are the ubiquitous ones, which happen steadily throughout the body. As we shall see, this criterion points the finger very plainly at damage to mitochondrial DNA. References 1. Rose MR. Darwinian anti-aging medicine. J Anti-Aging Med 1998; 1:105-108. 2. Finch CE. Longevity, senescence and the genome. Chicago: University of Chicago Press, 1990. 3. Holliday R. Understanding ageing. Cambridge: Cambridge University Press, 1995. 4. Masoro EJ, ed. Handbook of physiology, Section 11: Aging. New York: Oxford University Press, 1995. 5. Arking RH. Biology of aging: Observations and principles. 2nd ed. Sunderland: Sinauer, 1998. 6. Henriksen T, Mahoney EM, Steinberg D. Enhanced macrophage degradation of biologically modified low density lipoprotein. Arteriosclerosis 1983; 3:149-159. 7. Steinberg D. Low density lipoprotein oxidation and its pathobiological significance. J Biol Chem 1997; 272:20963-20966. 8. Mahley RW, Innerarity TL, Pitas RE et al. Inhibition of lipoprotein binding to cell surface receptors of fibroblasts following selective modification of arginyl residues in arginine-rich and B apoproteins. J Biol Chem 1977; 252:7279-7287. 9. Chisolm GM. The oxidation of lipoproteins: Implications for atherosclerosis. In: Sies H, ed. Antioxidants in disease: Mechanisms and therapy. San Diego: Academic Press, 1997:88-107. 61
62 The Mitochondrial Free Radical Theory of Aging 10. Pearson TA, Wang BA, Solez K et al. Clonal characteristics of fibrous plaques and fatty streaks from human aortas. Am J Pathol 1975; 81:379-387. 11. Casalone R, Granata P, Minelli E et al. Cytogenetic analysis reveals clonal proliferation of smooth muscle cells in atherosclerotic plaques. Hum Genet 1991; 87:139-143. 12. a)McNamara DJ. Dietary cholesterol and the optimal diet for reducing risk of atherosclerosis. Can J Cardiol 1995; 11 Suppl G:123G-126G. 12. b) Zieske AW, Takei H, Fallon KB et al. Smoking and atherosclerosis in youth. Atherosclerosis 1999; 144:403-408. 12. c) McGill HC, McMahan CA, Malcom GT et al. Effects of serum lipiproteins and smoking on atherosclerosis in young men and women. The PDAY Research Group. Pathobiological Determinants of Atherosclerosis in Youth. Arterioscler Thromb Vasc Biol 1997; 17:95-106. 13. Bird AP. DNA methylation and the frequency of CpG in animal DNA. Nucleic Acids Res 1980; 8:1499-1504. 14. Warner HR, Fernandes G, Wang E. A unifying hypothesis to explain the retardation of aging and tumorigenesis by caloric restriction. J Gerontol 1995; 50A:B107-B109. 15. Rucklidge GJ, Milne G, McGaw BA et al. Turnover rates of different collagen types measured by isotope ratio mass spectrometry. Biochim Biophys Acta 1992; 1156:57-61. 16. Scharffetter K, Wlaschek M, Hogg A et al. UVA irradiation induces collagenase in human dermal fibroblasts in vitro and in vivo. Arch Dermatol Res 1991; 283:506-511. 17. Kurban RS, Bhawan J. Histologic changes in skin associated with aging. J Dermatol Surg Oncol 1990; 16:908-914. 18. Mays PK, McAnulty RJ, Campa JS et al. Age-related changes in collagen synthesis and degradation in rat- tissues. Importance of degradation of newly synthesized collagen in regulating collagen production. Biochem J 1991; 276:307-313. 19. a)West MD, Pereira-Smith OM, Smith JR. Replicative senescence of human skin fibroblasts correlates with a loss of regulation and overexpression of collagenase activity. Exp Cell Res 1989; 184:138-147. 19. b)Robert L. Mechanisms of aging of the extracellular matrix: Role of the elastin-laminin receptor. Gerontology 1998; 44:307-317. 20. Mitrovic D, Quintero M, Stankovic A et al. Cell density of adult human femoral condylar articular cartilage. Joints with normal and fibrillated surfaces. Lab Invest 1983; 49:309-316. 21. Reaven GM, Chen N, Hollenbeck C et al. Effect of age on glucose tolerance and glucose uptake in healthy individuals. J Am Geriatr Soc 1989; 37:735-740. 22. Higami Y, Shimokawa I, Okimoto T et al. Susceptibility of hepatocytes to cell death induced by single administration of cycloheximide in young and old F344 rats. Effect of dietary restriction. Mutat Res 1996; 357:225-230. 23. Higami Y, Shimokawa I, Tomita M et al. Aging accelerates but life-long dietary restriction suppresses apoptosis-related Fas expression on hepatocytes. Am J Pathol 1997; 151:659-663. 24. Wang E. Senescent human fibroblasts resist programmed cell death, and failure to suppress bcl2 is involved. Cancer Res 1995; 55:2284-2292. 25. Harley CB, Sherwood SW. Telomerase, checkpoints and cancer. Cancer Surv 1997; 29:263-284. 26. Hannover A. Mikroskopiske undersögelser af nervesystemet. Kongelige Danske Videnskabernes Selskabs 1842; 10:1-112. 27. Strehler BL, Mark DD, Mildvan AS et al. Rate and magnitude of age pigment accumulation in the human myocardium. J Gerontol 1959; 14:430-439. 28. Brunk UT, Jones CB, Sohal RS. A novel hypothesis of lipofuscinogenesis and cellular aging based on interactions between oxidative stress and autophagocytosis. Mutat Res 1992; 275:395-403. 29. Brunk UT, Terman A. The mitochondrial-lysosomal axis theory of cellular aging. In: Cadenas E, Packer L, eds. Understanding the basis of aging: Mitochondria, oxidants and aging. New York: Marcel Dekker, Inc., 1998:229-250. 30. Hogan MJ. Role of the retinal pigment epithelium in macular disease. Trans Am Acad Ophthalmol Otolaryngol 1972; 76:64-80.
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COMPANY de Grey The Mitochondrial F
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7. The Status of Gerontological The
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17. Conclusion: The Role of the Ger
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I cannot overstate my profound grat
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CHAPTER 1 Introduction 1.1. What Is
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Introduction Some may feel that all
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The Search for How So Few Anaerobic
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CHAPTER 10 Frequently-Asked Questio
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Frequently-Asked Questions The effe
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Frequently-Asked Questions Table 10
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Frequently-Asked Questions through
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Frequently-Asked Questions has been
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Frequently-Asked Questions Fig. 10.
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Frequently-Asked Questions Referenc
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Frequently-Asked Questions 45. Clay
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CHAPTER 11 A Challenge from Textboo
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CHAPTER 15 Transgenic Copies of mtD
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Transgenic Copies of mtDNA: Techniq
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Index Symbols “~”, 19 A Acetald
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Index protonation see protonation (
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