Rethinking modern theories of ageing and their classification: the proximate mechanisms and the ultimate explanations

Piotr Chmielewski

doi:10.1515/anre-2017-0021

Authors

Piotr Chmielewski Division of Anatomy, Department of Human Morphology and Embryology, Faculty of Medicine, Wrocław Medical University, Poland

DOI:

https://doi.org/10.1515/anre-2017-0021

Keywords:

ageing, gerontology, programmed ageing, quasi-programmed ageing, senescence, stochastic ageing, theories of ageing

Abstract

For a very long time, ageing has been an insurmountable problem in biology. The collection of age-dependent changes that render ageing individuals progressively more likely to die seemed to be an intractable labyrinth of alterations and associations whose direct mechanisms and ultimate explanations were too complex and difficult to understand. The science of ageing has always been fraught with insuperable problems and obstacles. In 1990, Zhores Medvedev presented a list of roughly 300 different hypotheses to illustrate this remarkable complexity of the ageing process and various approaches to understanding its mechanisms, though none of these hypotheses or aspect theories could be the general theory of senescence. Moreover, in the light of current data some of these ideas are obsolete and inapplicable. Nonetheless, the misconception that there are hundreds of valid theories of ageing persists among many researchers and authors. In addition, some of these obsolete and discarded hypotheses, such as the rate of living theory, the wear and tear theory, the poisoning theory, or the entropy theory still can be found in today’s medical textbooks, scientific publications aimed at the general public, and even in scientific writing. In fact, there are only several modern theories of ageing supported by compelling evidence that attempt to explain most of the data in current gerontology. These theories are competing to be a general and integrated model of ageing, making it unlikely that all of them could be true. This review summarises briefly several selected modern theories of senescence in the light of the contemporary knowledge of the biological basis for ageing and current data.

Downloads

Download data is not yet available.

References

Blagosklonny MV. 2010. Revisiting the antagonistic pleiotropy theory of aging: TOR-driven program and quasi-program. Cell Cycle 9(16):3171–6.
View in Google Scholar

Blagosklonny MV. 2011. Hormesis does not make sense except in the light of TOR-driving aging. Aging 3(11):1051–62.
View in Google Scholar

Blagosklonny MV. 2012. Answering the ultimate question “What is the proximal cause of aging?”. Aging 4(12):861–77.
View in Google Scholar

Blagosklonny MV. 2013. M(o)TOR of aging: MTOR as a universal molecular hypothalamus. Aging 5(7):490–4.
View in Google Scholar

Carter AJ, Nguyen AQ. 2011. Antagonistic pleiotropy as a widespread mechanism for the maintenance of polymorphic disease alleles. BMC Med Genet 12:160.
View in Google Scholar

Chmielewski P. 2016. The relationship between adult stature and longevity: tall men are unlikely to outlive their short peers – evidence from a study of all adult deaths in Poland in the years 2004–2008. Anthropol Rev 79(4):439–60.
View in Google Scholar

Chmielewski P, Borysławski K. 2016. Proksymalne przyczyny starzenia się człowieka: przypadkowe uszkodzenia molekularne czy hiperfunkcja programów rozwojowych? Kosmos 65:339–49.
View in Google Scholar

Chmielewski P, Borysławski K, Strzelec B. 2016. Contemporary views on human aging and longevity. Anthropol Rev 79:115–42.
View in Google Scholar

de Magalhães JP. 2012. Programmatic features of aging originating in development: aging mechanisms beyond molecular damage? The FASEB Journal 26(12):4821–6.
View in Google Scholar

Díaz-López A, Bulló M, Martínez-González MA, Corella D, Estruch R, Fitó M, Gómez-Gracia E, Fiol M, García de la Corte FJ, Ros E, Babio N, Serra-Majem L, Pintó X, Muñoz MÁ, Francés F, Buil-Cosiales P, Salas-Salvadó J. 2016. Dairy product consumption and risk of type 2 diabetes in an elderly Spanish Mediterranean population at high cardiovascular risk. Eur J Nutr 55(1):349–60.
View in Google Scholar

Dieckmann KP, Hartmann JT, Classen J, Lüdde R, Diederichs M, Pichlmeier U. 2008. Tallness is associated with risk of testicular cancer: evidence for the nutrition hypothesis. Br J Cancer 99(9):1517–21.
View in Google Scholar

Gao D, Ning N, Wang C, Wang Y, Li Q, Meng Z, Liu Y, Li Q. 2013. Dairy products consumption and risk of type 2 diabetes: systematic review and dose-response meta-analysis. PLoS One 8(9):e72965.
View in Google Scholar

Garcia-Cao I, Garcia-Cao M, Martin-Caballero J, Criado LM, Klatt P, Flores JM, Weill JC, Blasco MA, Serrano M. 2002. “Super p53” mice exhibit enhanced DNA damage response, are tumor resistant and age normally. EMBO J 21:6225–35.
View in Google Scholar

Gijsbers L, Ding EL, Malik VS, de Goede J, Geleijnse JM, Soedamah-Muthu SS. 2016. Consumption of dairy foods and diabetes incidence: a dose-response meta-analysis of observational studies. Am J Clin Nutr 103(4):1111–24.
View in Google Scholar

Gurven M, Costa M, Ben Trumble, Stieglitz J, Beheim B, Eid Rodriguez D, Hooper PL, Kaplan H. 2016. Health costs of reproduction are minimal despite high fertility, mortality and subsistence lifestyle. Sci Rep 6:30056.
View in Google Scholar

Harman D. 2006. Free radical theory of aging: an update. Increasing the functional life span. Ann N Y Acad Sci 1067:10–21.
View in Google Scholar

Hayflick L. 2007. Biological aging is no longer an unsolved problem. Ann N Y Acad Sci 1100:1–13.
View in Google Scholar

Heininger K. 2012. The germ-soma conflict theory of aging and death: obituary to the “evolutionary theories of aging”. WebmedCentral AGING 3(4):WMC003275.
View in Google Scholar

Holliday R. 2006. Aging is no longer an unsolved problem in biology. Ann N Y Acad Sci 1067:1–9.
View in Google Scholar

Holliday R. 2007. Aging: the paradox of life. Why we age. New York: Springer.
View in Google Scholar

Jin K. 2010. Modern biological theories of aging. Aging Dis 1(2):72–4.
View in Google Scholar

Kenyon C. 2001. A conserved regulatory system for aging. Cell 105(2):165–8.
View in Google Scholar

Kenyon C. 2005. The plasticity of aging: insights from long-lived mutants. Cell 120(4):449–60.
View in Google Scholar

Kenyon CJ. 2010. The genetics of ageing. Nature 464:504–12.
View in Google Scholar

Kenyon C. 2011. The first long-lived mutants: discovery of the insulin/IGF-1 pathway for ageing. Philos Trans R Soc Lond B Biol Sci 366(1561):9–16.
View in Google Scholar

Kirkwood TBL. 1977. Evolution of ageing. Nature 270:301–4.
View in Google Scholar

Kirkwood T. 1999. Time of our lives. The science of human aging. New York: Oxford University Press.
View in Google Scholar

Kirkwood TBL. 2005. Understanding the odd science of aging. Cell 120(4):437–47.
View in Google Scholar

Kirkwood TB, Melov S. 2011. On the programmed/non-programmed nature of ageing within the life history. Curr Biol 21(18):R701–7.
View in Google Scholar

Kochman K. 2015. New elements in modern biological theories of aging. Folia Medica Copernicana 3(3):89–99.
View in Google Scholar

Leontieva OV, Demidenko ZN, Blagosklonny MV. 2015. Dual mTORC1/C2 inhibitors suppress cellular geroconversion (a senescence program). Oncotarget 6:23238–48.
View in Google Scholar

Lipsky MS, King M. 2015. Biological theories of aging. Disease-a-Month 61:460–6.
View in Google Scholar

Longo VD, Mitteldorf J, Skulachev VP. 2005. Programmed and altruistic ageing. Nat Rev Genet 6:866–72.
View in Google Scholar

Medawar PB 1952. An unsolved problem of biology. London: HK Lewis and Co.
View in Google Scholar

Medvedev ZA. 1990. An attempt at a rational classification of theories of ageing. Biol Rev Camb Philos Soc 65:375–98.
View in Google Scholar

Mitteldorf J. 2010. Evolutionary origins of aging. In: Fahy GM, editor. The future of aging. Pathways to human life extension. New York: Springer.
View in Google Scholar

Mitteldorf J. 2016. An epigenetic clock controls aging. Biogerontology 17(1):257–65.10.1007/s10522-015-9617-5
View in Google Scholar

Mitteldorf J. 2017. Aging is a group-selected adaptation: theory, evidence, and medical implications. New York: Taylor & Francis Group.
View in Google Scholar

Rattan SIS. 2006. Theories of biological aging: genes, proteins, and free radicals. Free Radic Res 40(12):1230–8.
View in Google Scholar

Scrable H, Burns-Cusato M, Medrano S. 2009. Anxiety and the aging brain: stressed out over p53? Biochim Biophys Acta 1790:1587–91.
View in Google Scholar

Sergiev PV, Dontsova OA, Berezkin GV. 2015. Theories of aging: an ever-evolving field. Acta Naturae. 7(1):9–18.
View in Google Scholar

Sikora E. 2014. Starzenie i długowieczność. Postępy Biochemii 60(2):125–37.
View in Google Scholar

Skulachev VP. 1997. Aging is a specific biological function rather than the result of a disorder in complex living systems: biochemical evidence in support of Weismann’s hypothesis. Biochemistry 62(11):1191–5.
View in Google Scholar

Skulachev VP. 2001. The programmed death phenomena, aging, and the Samurai law of biology. Exp Gerontol 36(7):995–1024.
View in Google Scholar

Skulachev VP. 2011. Letter to the editor: Aging as a particular case of phenoptosis, the programmed death of an organism (a response to Kirkwood and Melov “On the programmed/non-programmed nature of ageing within the life history”. Aging 3(11): 1120–3.
View in Google Scholar

Skulachev VP. 2012. What is “phenoptosis” and how to fight it? Biochemistry 77(7):689–706.
View in Google Scholar

Skulachev VP. 2013. Concept of aging as a result of slow programmed poisoning of an organism with mitochondrial reactive oxygen species. In: VP Skulachev, AV Bogachev, FO Kasparinsky, editors. Principles of bioenergetics. New York: Springer.
View in Google Scholar

Skulachev VP, Longo VD. 2005. Aging as a mitochondria-mediated atavistic program: can aging be switched off? Ann NY Acad Sci 1057:145–64.
View in Google Scholar

Soedamah-Muthu SS, Verberne LD, Ding EL, Engberink MF, Geleijnse JM. 2012. Dairy consumption and incidence of hypertension: a dose-response meta-analysis of prospective cohort studies. Hypertension 60(5):1131–7.
View in Google Scholar

Tyner SD, Venkatachalam S, Choi J, Jones S, Ghebranious N, Igelmann H, Lu X, Soron G, Cooper B, Brayton C, Hee Park S, Thompson T, Karsenty G, Bradley A, Donehower LA. 2002. p53 mutant mice that display early ageing-associated phenotypes. Nature 415:45–53.
View in Google Scholar

van Heemst D, Beekman M, Mooijaart SP, Heijmans BT, Brandt BW, Zwaan BJ, Slagboom PE, Westendorp RGJ. 2005. Reduced insulin/IGF-1 signalling and human longevity. Aging Cell 4:79–85.
View in Google Scholar

Wang H, Fox CS, Troy LM, Mckeown NM, Jacques PF. 2015. Longitudinal association of dairy consumption with the changes in blood pressure and the risk of incident hypertension: the Frmanigham Heart Study. Br J Nutr 114(11):1887–99.
View in Google Scholar

Weismann A. 1889. Essays upon heredity and kindred biological problems. Oxford: Claderon Press.
View in Google Scholar

Westendorp RG, Kirkwood TB. 1998. Human longevity at the cost of reproductive success. Nature 396(6713):743–6.
View in Google Scholar

Williams G. 1957. Pleiotropy, nautral selection, and the evolution of senescence. Evolution 11:398–411.
View in Google Scholar

Zimniak P. 2012. What is the proximal cause of aging? Front Genet 3:189.
View in Google Scholar

Ziomkiewicz A, Sancilio A, Galbarczyk A, Klimek M, Jasienska G, Bribiescas RG. 2016. Evidence for the Cost of Reproduction in Humans: High Lifetime Reproductive Effort Is Associated with Greater Oxidative Stress in Post-Menopausal Women. PLoS One 11(1):e0145753.
View in Google Scholar