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Disposable soma theory of aging

January 01, 1970

The disposable soma theory of aging states that organisms age due to an evolutionary trade-off between growth, reproduction, and DNA repair maintenance.[1] Formulated by Thomas Kirkwood, the disposable soma theory explains that an organism only has a limited amount of resources that it can allocate to its various cellular processes.[2] Therefore, a greater investment in growth and reproduction would result in reduced investment in DNA repair maintenance, leading to increased cellular damage, shortened telomeres, accumulation of mutations, compromised stem cells, and ultimately, senescence. Although many models, both animal and human, have appeared to support this theory, parts of it are still controversial. Specifically, while the evolutionary trade-off between growth and aging has been well established, the relationship between reproduction and aging is still without scientific consensus, and the cellular mechanisms largely undiscovered.[3]

Background and history edit

British biologist Thomas Kirkwood first proposed the disposable soma theory of aging in a 1977 Nature review article.[1] The theory was inspired by Leslie Orgel's Error Catastrophe Theory of Aging, which was published fourteen years earlier, in 1963. Orgel believed that the process of aging arose due to mutations acquired during the replication process, and Kirkwood developed the disposable soma theory in order to mediate Orgel's work with evolutionary genetics.[1]

Principles edit

The disposable soma theory of aging posits that there is a trade-off in resource allocation between somatic maintenance and reproductive investment. Too low an investment in self-repair would be evolutionarily unsound, as the organism would likely die before reproductive age. However, too high an investment in self-repair would also be evolutionarily unsound due to the fact that one's offspring would likely die before reproductive age. Therefore, there is a compromise and resources are partitioned accordingly. However, this compromise is thought to damage somatic repair systems, which can lead to progressive cellular damage and senescence.[4] Repair costs can be categorized into three groups: (1) the costs of increased durability of nonrenewable parts; (2) the costs of maintenance involving cell renewal, and (3) the costs of intracellular maintenance.[5] In a nutshell, aging and decline is essentially a trade-off for increased reproductive robustness in youth.

Mechanisms edit

 
The IGF-1 pathway, which represses FOXO, thus preventing gene expression of longevity-inducing proteins

Growth and somatic maintenance edit

Main article: Mechanistic target of rapamycin § Aging

Much research has been done on the antagonistic effects of increased growth on lifespan. Specifically, the hormone insulin-like growth factor 1 (IGF-1), binds to a cell receptor, leading to a phosphorylation cascade. This cascade results in kinases phosphorylating forkhead transcription factor (FOXO), deactivating it. Deactivation of FOXO results in an inability to express genes involved in responding to oxidative stress response, such as antioxidants, chaperones, and heat-shock proteins.[6] Additionally, uptake of IGF-1 stimulates the mTOR pathway, which activates protein synthesis (and therefore growth) through upregulation of the translation-promoting S6K1, and also inhibits autophagy, a process necessary for recycling of damaged cellular products.[7] Decline of autophagy causes neurodegeneration, protein aggregation and premature aging.[8] Lastly, studies have also indicated that the mTOR pathway also alters immune responses and stimulates cyclin-dependent kinase (CDK) inhibitors such as p16 and p21. This leads to alteration of the stem-cell niche and results in stem cell exhaustion, another theorized mechanism of aging.[9]

Reproduction and somatic maintenance edit

While reproduction inhibits lifespan with regard to multicellular organisms, the precise mechanism responsible for this effect remains unclear. Although many models do illustrate an inverse relationship, and the theory makes sense from an evolutionary perspective, the cellular mechanisms have yet to be explored. However, with regards to cellular replication, the progressive shortening of telomeres is a mechanism which limits the amount of generations of a single cell may undergo.[10] Furthermore, in unicellular organisms like Saccharomyces cerevisiae, the formation of extrachromosomal rDNA circles (ERCs) in mother cells (but not daughter cells) upon every subsequent division is an identifiable type of DNA damage that is associated with replication. These ERCs accumulate over time and eventually trigger replicative senescence and death of the mother cell.[11]

Evidence edit

Growth and aging edit

There is a large body of evidence indicating the negative effects of growth on longevity across many species. As a general rule, individuals of a smaller size generally live longer than larger individuals of the same species.

Animal models edit

In dwarf models of mice, such Snell or Ames mice, mutations have arisen, either rendering them incapable of producing IGF-1 or unable to have adequate receptors for IGF-1 uptake. Furthermore, mice injected with growth hormone have been shown to have progressive weight loss, roughing of the coat, curvature of the spine, enlargement of the organs, kidney lesions and increased cancer risk.[12] This effect is also seen in different breeds of dogs, where smaller breeds of dogs typically live significantly longer compared to their larger counterparts. Selectively bred for their small size, smaller dog breeds like the Chihuahua (average lifespan of 15–20 years) have the B/B genotype for the IGF-1 haplotype, reducing the amount of IGF-1 produced. Conversely, large dogs like the Great Dane (average lifespan of 6–8 years) are homozygous for the IGF-1 I allele, which increases the amount of IGF-1 production.[13]

Human models edit

Initially, it was believed that growth hormone actually prolonged lifespan due to a 1990 study that indicated that injection of growth hormone to men over 60 years of age appeared to reverse various biomarkers implicated in aging, such as decreased muscle mass, bone density, skin thickness, and increased adipose tissue.[14] However, a 1999 study found that administering growth hormone also significantly increased mortality rate.[15] Recent genomic studies have confirmed that the genes involved in growth hormone uptake and signaling are largely conserved across a plethora of species, such as yeast, nematodes, fruit flies, mice and humans.[16] These studies have also shown that individuals with Laron syndrome, an autosomal recessive disorder resulting in dwarfism due to defects in growth hormone receptors, have increased lifespan. Additionally, these individuals have much lower incidences of age-related diseases such as type 2 diabetes and cancer.[17] Lastly, human centenarians around the world are disproportionately of short stature, and have low levels of IGF-1.[18]

Reproduction and aging edit

Numerous studies have found that lifespan is inversely correlated with both the total amount of offspring birthed, as well as the age at which females first gives birth, also known as primiparity.[19] Additionally, it has been found that reproduction is a costly mechanism that alters the metabolism of fat. Lipids invested in reproduction would be unable to be allocated to support mechanisms involved in somatic maintenance.[20]

Animal models edit

The disposable soma theory has been consistent with the majority of animal models. It was found in numerous animal studies that castration or genetic deformities of reproduction organs was correlated with increased lifespan.[21][22][23] Moreover, in red squirrels, it was found that females with an early primiparity achieved the highest immediate and lifetime reproductive success. However, it was also found that these same individuals had a decreased median and maximum lifespan. Specifically squirrels who mated earlier had a 22.4% rate of mortality until two years of age compared to a 16.5% rate of mortality in late breeders. In addition, these squirrels had an average maximum lifespan of 1035 days compared to an average maximum lifespan of 1245 days for squirrels that bred later.[19]

In another study, researchers selectively bred fruit flies over three years to develop two different strains, an early-reproducing strain and a late-reproducing strain. The late-reproducing line had a significantly longer lifespan than the early-reproducing line. Even more telling was that when the researchers introduced a mutation in the ovarian-associated gene ovoD1, resulting in defective oogenesis, the differences in lifespan between the two lines disappeared. The researchers in this case concluded that "aging has evolved primarily because of the damaging effects of reproduction earlier in life".[24]

Prominent aging researcher Steven Austad also performed a large-scale ecological study on the coast of Georgia in 1993. Austad isolated two opossum populations, one from the predator-infested mainland and one from the predator-absent nearby island of Sapelo. According to the disposable soma theory, a genetically isolated population subject to low environmentally-induced mortality would evolve delayed reproduction and aging. This is because without the pressure of predation, it would be evolutionarily advantageous to allocate more resources to somatic maintenance than reproduction, as early offspring mortality would be low. As predicted, even after controlling for predation, the isolated population had a longer lifespan, delayed primiparity, and reduced aging biomarkers such as tail collagen cross-linking.[25]

Human models edit

In general, only a few studies exist in human models. It was found that castrated men live longer than their fertile counterparts.[26] Further studies found that in British women, primiparity was earliest in women who died early and latest in women who died at the oldest ages. Furthermore, increased number of children birthed was associated with a decreased lifespan.[27] A final study found that female centenarians were more likely to have children in later life compared average, especially past the age of 40. The researchers discovered that 19.2% of female centenarians had their first child after the age of 40, compared to 5.5% of the rest of the female population.[28]

Relationship between cell damage and aging edit

Main article: Free radical theory
Main article: DNA damage theory of aging
 
The naked mole rat has a disproportionately long life of 30 years through efficient cellular repair mechanisms.

There are numerous studies that support cellular damage, often due to a lack of somatic maintenance mechanisms, as a primary determinant for aging, and these studies have given rise to the free radical theory of aging and the DNA damage theory of aging. One study found that the cells of short-living rodents in vitro show much greater mutation rates and a general lack of genome surveillance compared to human cells and are far more susceptible to oxidative stress.[29] Other studies have been conducted on the naked mole rat, a rodent species with remarkable longevity (30 years), capable of outliving the brown rat (3 years) by ten-fold. Additionally, almost no incidence of cancer has ever been detected in naked mole rats. Nearly all of the differences found between these two organisms, which are otherwise rather genetically similar, was in somatic maintenance. Naked mole rats were found to have higher levels of superoxide dismutase, a reactive oxygen species clearing antioxidant. In addition, naked mole rats had higher levels of base excision repair, DNA damage response signaling, homologous recombination repair, mismatch repair, nucleotide excision repair, and non-homologous end joining. In fact, many of these processes were near or exceeded human levels. Proteins from naked mole rats were also more resistant to oxidation, misfolding, ubiquitination, and had increased translational fidelity.[30]

Further studies have been conducted on patients with Hutchinson-Gilford Progeria Syndrome (HGPS), a condition that leads to premature aging. Patients with HGPS typically age about seven times faster than average and usually succumb to the disease in their early teens. Patients with HGPS have cellular defects, specifically in the lamin proteins, which regulate the organization of the lamina and nuclear envelope for mitosis.[31] A-type lamins promote genetic stability by maintaining levels of proteins that have key roles in the repair processes of non-homologous end joining and homologous recombination.[32] Mouse cells deficient for maturation of prelamin A show increased DNA damage and chromosome aberrations and have increased sensitivity to DNA damaging agents.[33]

Lastly, as mentioned previously, it has been found that the suppression of autophagy is associated with reduced lifespan, while stimulation is associated with extended lifespan. Activated in times of caloric restriction, autophagy is a process that prevents cellular damage through clearance and recycling of damaged proteins and organelles.[34]

Criticism edit

One of the main weaknesses of the disposable soma theory is that it does not postulate any specific cellular mechanisms to which an organism shifts energy to somatic repair over reproduction. Instead, it only offers an evolutionary perspective on why aging may occur due to reproduction. Therefore, parts of it are rather limited outside of the field of evolutionary biology.[3]

Caloric restriction edit

Main article: Calorie restriction § Sirtuin-mediated mechanism
 
Schematic showing the reallocation of energy investment towards self-repair during caloric restriction

Critics have pointed out the supposed inconsistencies of the disposable soma theory due to the observed effects of caloric restriction, which is correlated with increased lifespan.[35] Although it activates autophagy, according to classical disposable soma principles, with less caloric intake, there would less total energy to be distributed towards somatic maintenance, and decreased lifespan would be observed (or at least the positive autophagic effects would be balanced out). However, Kirkwood, alongside his collaborator Darryl P. Shanley, assert that caloric restriction triggers an adaptive mechanism which causes the organism to shift a higher proportion of resources to somatic maintenance, away from reproduction.[36] This theory is supported by multiple studies, which show that caloric restriction typically results in impaired fertility, but leave an otherwise healthy organism.[37][38] Evolutionarily, an organism would want to delay reproduction to when resources were more plentiful. During a resource-barren period, it would evolutionarily unwise to invest resources in progeny that would be unlikely to survive in famine. Mechanistically, the NAD-dependent deacetylase Sirtuin 1 (SIRT-1) is upregulated during low-nutrient periods. SIRT-1 increases insulin sensitivity, decreases the amount of inflammatory cytokines, stimulates autophagy, and activates FOXO, the aforementioned protein involved in activating stress response genes. SIRT-1 is also found to result in decreased fertility.[39]

In additional to differential partitioning of energy allocation during caloric restriction, less caloric intake would result in less metabolic waste in the forms of free radicals like hydrogen peroxide, superoxide and hydroxyl radicals, which damage important cellular components, particularly mitochondria. Elevated levels of free radicals in mice has been correlated with neurodegeneration, myocardial injury, severe anemia, and premature death.[40]

No changes were observed in the spontaneous chromosomal mutation frequency of dietary restricted mice (aged 6 and 12 months) compared to ad libitum fed control mice.[41] Thus dietary restriction appears to have no appreciable effect on spontaneous mutation in chromosomal DNA, and the increased longevity of dietary restricted mice apparently is not attributable to reduced chromosomal mutation frequency.

The grandmother hypothesis edit

Main article: Menopause § Evolutionary rationale

Another primary criticism of the disposable soma theory is that it fails to account for why women tend to live longer than their male counterparts.[42] Afterall, females invest significantly more resources into reproduction and according to the classical disposable soma principles, this would compromise energy diverted to somatic maintenance. However, this can be reconciled with the grandmother hypothesis. The Grandmother Hypothesis states that menopause comes about into older women in order to restrict the time of reproduction as a protective mechanism. This would allow women to live longer and increase the amount of care they could provide to their grandchildren, increasing their evolutionary fitness.[43] And so, although women do invest a greater proportion of resources into reproduction during their fertile years, their overall reproductive period is significantly shorter than men, who are able of reproduction during and even beyond middle age.[44] Additionally, males invest more resources into growth compare to females, which is correlated with decreased lifespan. Other variables such as increased testosterone levels in males are not accounted for. Increased testosterone is often associated with reckless behaviour, which may lead to a high accidental death rate.[45]

Contradicting models edit

A few contradicting animal models weaken the validity of the disposable soma theory. This includes studies done on the aforementioned naked mole rats. In these studies, it was found that reproductive naked mole rats actually show significantly increased lifespans compared to non-reproductive individuals, which contradicts the principles of disposable soma. However, although these naked mole rats are mammalian, they are highly atypical in terms of aging studies and may not serve as the best model for humans. For example, naked mole rats have a disproportionately high longevity quotient and live in eusocial societies, where breeding is usually designated to a queen.[46]

Sex biases and environment edit

The disposable soma theory is tested disproportionately on female organisms for the relationship between reproduction and aging, as females carry a greater burden in reproduction.[47] Additionally, for the relationship between growth and aging, studies are disproportionately conducted on males, to minimize the hormonal fluctuations that occur with menstrual cycling.[48] Lastly, genetic and environmental factors, rather than reproductive patterns, may explain the variations in human lifespan. For example, studies have shown that poorer individuals, to whom nutritious food and medical care is less accessible, typically have higher birth rates and earlier primiparity.[49]

References edit

  1. ^ a b c Kirkwood, T. (1977). "Evolution of ageing". Nature. 270 (5635): 301–304. Bibcode:1977Natur.270..301K. doi:10.1038/270301a0. PMID 593350. S2CID 492012.
  2. ^ Gavrilov LA, Gavrilova NS (2002). "Evolutionary theories of aging and longevity". ScientificWorldJournal. 7 (2): 339–356. doi:10.1100/tsw.2002.96. PMC 6009642. PMID 12806021.
  3. ^ a b Blagosklonny, MV (2010). "Why the disposable soma theory cannot explain why women live longer and why we age". Aging. 2 (12): 884–887. doi:10.18632/aging.100253. PMC 3034172. PMID 21191147.
  4. ^ Drenos F; Kirkwood, TB (2005). "Modelling the disposable soma theory of ageing". Mech Ageing Dev. 126 (1): 99–103. doi:10.1016/j.mad.2004.09.026. PMID 15610767. S2CID 2256807.
  5. ^ Kirkwood, TB; Rose MR (1991). "Evolution of senescence: late survival sacrificed for reproduction". Philos Trans R Soc Lond B Biol Sci. 332 (1262): 15–24. doi:10.1098/rstb.1991.0028. PMID 1677205.
  6. ^ O'Neill BT; Lee KY; Klaus K; Softic S; et al. (2016). "Insulin and IGF-1 receptors regulate FoxO-mediated signaling in muscle proteostasis". J Clin Invest. 126 (9): 3433–3346. doi:10.1172/JCI86522. PMC 5004956. PMID 27525440.
  7. ^ Johnson SC, Rabinovitch PS, Kaeberlein M (2013). "mTOR is a key modulator of ageing and age-related disease". Nature. 493 (7432): 338–345. Bibcode:2013Natur.493..338J. doi:10.1038/nature11861. PMC 3687363. PMID 23325216.
  8. ^ Komatsu M, Waguri S, Chiba T, Murata S, et al. (2006). "Loss of autophagy in the central nervous system causes neurodegeneration in mice". Nature. 441 (7095): 880–884. Bibcode:2006Natur.441..880K. doi:10.1038/nature04723. PMID 16625205. S2CID 4407360.
  9. ^ Castilho RM, Squarize CH, Chodosh LA, Williams BO, et al. (2009). "mTOR mediates Wnt-induced epidermal stem cell exhaustion and aging". Cell Stem Cell. 5 (3): 279–289. doi:10.1016/j.stem.2009.06.017. PMC 2939833. PMID 19733540.
  10. ^ Shay JW, Wright WE (2011). "Role of telomeres and telomerase in cancer". Semin Cancer Biol. 21 (6): 349–353. doi:10.1016/j.semcancer.2011.10.001. PMC 3370415. PMID 22015685.
  11. ^ Kaeberlein M, McVey M, Guarente L (1999). "The SIR2/3/4 complex and SIR2 alone promote longevity in Saccharomyces cerevisiae by two different mechanisms". Genes Dev. 13 (19): 2570–2580. doi:10.1101/gad.13.19.2570. PMC 317077. PMID 10521401.
  12. ^ Bartke A, Brown-Borg H (2004). "Life extension in the dwarf mouse". Curr Top Dev Biol. 63 (6): 189–225. doi:10.1016/j.semcancer.2011.10.001. PMC 3370415. PMID 22015685.
  13. ^ Sutter NB, Bustamante CD, Chase K, Gray MM (2007). "A Single IGF1 Allele Is a Major Determinant of Small Size in Dogs". Science. 316 (5821): 112–115. Bibcode:2007Sci...316..112S. doi:10.1126/science.1137045. PMC 2789551. PMID 17412960.
  14. ^ Rudman D, Feller AG, Nagraj HS, Gergans GA, et al. (1990). "Effects of human growth hormone in men over 60 years old". N Engl J Med. 323 (1): 1–6. doi:10.1056/NEJM199007053230101. PMID 2355952.
  15. ^ Takala J, Ruokonen E, Webster NR, Nielsen MS, Zandstra DF, et al. (1999). "Increased mortality associated with growth hormone treatment in critically ill adults". N Engl J Med. 341 (11): 785–792. doi:10.1056/NEJM199909093411102. PMID 10477776.
  16. ^ Longo VD, Finch CE (2003). "Evolutionary medicine: from dwarf model systems to healthy centenarians?". Science. 299 (5611): 1342–1346. doi:10.1126/science.1077991. PMID 12610293. S2CID 14848603.
  17. ^ Guevara-Aguirre J, Balasubramanian P, Guevara-Aguirre M, Wei M, et al. (2011). "Growth hormone receptor deficiency is associated with a major reduction in pro-aging signaling, cancer, and diabetes in humans". Sci. Transl. Med. 3 (70): 70–83. doi:10.1126/scitranslmed.3001845. PMC 3357623. PMID 21325617.
  18. ^ Govindaraju D, Atzmon G, Barzilai N (2015). "Genetics, lifestyle and longevity: Lessons from centenarians". Appl Transl Genom. 4: 23–32. doi:10.1016/j.atg.2015.01.001. PMC 4745363. PMID 26937346.
  19. ^ a b Descamps S, Boutin S, Berteaux D, Gaillard JM (2006). "Best squirrels trade a long life for an early reproduction". Proc Biol Sci. 273 (1599): 2369–2374. doi:10.1098/rspb.2006.3588. PMC 1636082. PMID 16928640.
  20. ^ Hansen M, Flatt T, Aguilaniu H (2013). "Reproduction, fat metabolism, and life span: what is the connection?". Cell Metab. 17 (1): 10–19. doi:10.1016/j.cmet.2012.12.003. PMC 3567776. PMID 23312280.
  21. ^ Drori D, Folman Y (1976). "Environmental effects on longevity in the male rat: exercise, mating, castration and restricted feeding". Exp. Gerontol. 11 (1): 25–32. doi:10.1016/0531-5565(76)90007-3. PMID 1278267. S2CID 37672329.
  22. ^ Flatt T (2011). "Survival costs of reproduction in Drosophila" (PDF). Exp. Gerontol. 46 (5): 369–375. doi:10.1016/j.exger.2010.10.008. PMID 20970491. S2CID 107465469.
  23. ^ Hsin H, Kenyon C (1999). "Signals from the reproductive system regulate the lifespan of C. elegans". Nature. 399 (6734): 362–366. Bibcode:1999Natur.399..362H. doi:10.1038/20694. PMID 10360574. S2CID 4358840.
  24. ^ Sgrò CM, Partridge L (1999). "A delayed wave of death from reproduction in Drosophila". Science. 286 (5449): 2521–2524. doi:10.1126/science.286.5449.2521. PMID 10617470.
  25. ^ Austad, SN (1993). "Retarded senescence in an insular population of Virginia opossums (Didelphis virginiana)". Journal of Zoology. 229 (4): 695–708. doi:10.1111/j.1469-7998.1993.tb02665.x.
  26. ^ Hamilton JB, Mestler GE (1969). "Mortality and survival: comparison of eunuchs with intact men and women in a mentally retarded population)". J. Gerontol. 24 (4): 395–411. doi:10.1093/geronj/24.4.395. PMID 5362349.
  27. ^ Westendorp RG, Kirkwood TB (1998). "Human longevity at the cost of reproductive success". Nature. 396 (6713): 743–746. doi:10.1038/25519. PMID 9874369. S2CID 151331241.
  28. ^ Perls TT, Alpert L, Fretts RC (1997). "Middle-aged mothers live longer". Nature. 389 (6647): 133. Bibcode:1997Natur.389..133P. doi:10.1038/38148. PMID 9296486. S2CID 4401775.
  29. ^ Lorenzini A, Stamato T, Sell C (2011). "The disposable soma theory revisited: time as a resource in the theories of aging". Cell Cycle. 10 (22): 3853–3856. doi:10.4161/cc.10.22.18302. PMID 22071624.
  30. ^ Azpurua J, Ke Z, Chen IX, Zhang Q, Ermolenko DN, et al. (2013). "Naked mole-rat has increased translational fidelity compared with the mouse, as well as a unique 28S ribosomal RNA cleavage". Proc Natl Acad Sci U S A. 110 (43): 17350–17355. Bibcode:2013PNAS..11017350A. doi:10.1073/pnas.1313473110. PMC 3808608. PMID 24082110.
  31. ^ Pollex RL, Hegele RA (2004). "Hutchinson-Gilford progeria syndrome". Clin. Genet. 66 (5): 375–381. doi:10.1111/j.1399-0004.2004.00315.x. PMID 15479179. S2CID 7529899.
  32. ^ Redwood, Abena B.; Perkins, Stephanie M.; Vanderwaal, Robert P.; Feng, Zhihui; Biehl, Kenneth J.; Gonzalez-Suarez, Ignacio; Morgado-Palacin, Lucia; Shi, Wei; Sage, Julien; Roti-Roti, Joseph L.; Stewart, Colin L.; Zhang, Junran; Gonzalo, Susana (27 October 2014). "A dual role for A-type lamins in DNA double-strand break repair". Cell Cycle. 10 (15): 2549–2560. doi:10.4161/cc.10.15.16531. PMC 3180193. PMID 21701264
  33. ^ Liu, Baohua; Wang, Jianming; Chan, Kui Ming; Tjia, Wai Mui; Deng, Wen; Guan, Xinyuan; Huang, Jian-dong; Li, Kai Man; Chau, Pui Yin; Chen, David J; Pei, Duanqing; Pendas, Alberto M; Cadiñanos, Juan; López-Otín, Carlos; Tse, Hung Fat; Hutchison, Chris; Chen, Junjie; Cao, Yihai; Cheah, Kathryn S E; Tryggvason, Karl; Zhou, Zhongjun (26 June 2005). "Genomic instability in laminopathy-based premature aging". Nature Medicine. 11 (7): 780–785. doi:10.1038/nm1266. PMID 15980864. S2CID 11798376
  34. ^ Glick D, Barth S, Macleod KF (2010). "Autophagy: cellular and molecular mechanisms". J. Pathol. 221 (1): 3–12. doi:10.1002/path.2697. PMC 2990190. PMID 20225336.
  35. ^ Blagosklonny, MV (2010). "Solving puzzles of aging: From disposable soma to signal-transduction pathways". Russ J Gen Chem. 80 (7): 1407–1414. doi:10.1134/s1070363210070364. S2CID 95075587.
  36. ^ Shanley DP, Kirkwood TB (2000). "Calorie restriction and aging: a life-history analysis". Evolution. 54 (3): 740–750. doi:10.1111/j.0014-3820.2000.tb00076.x. PMID 10937249. S2CID 26293762.
  37. ^ Holliday R. (2000). "Food, reproduction and longevity: is the extended lifespan of calorie-restricted animals an evolutionary adaptation?". BioEssays. 10 (4): 125–127. doi:10.1002/bies.950100408. PMID 2730632.
  38. ^ Masoro EJ, Austad SN (1996). "The evolution of the antiaging action of dietary restriction: a hypothesis". J Gerontol A Biol Sci Med Sci. 51 (6): 387–391. doi:10.1093/gerona/51a.6.b387. PMID 8914486.
  39. ^ Cantó C, Auwerx J (2009). "Caloric restriction, SIRT1 and longevity". Trends Endocrinol Metab. 20 (7): 325–331. doi:10.1016/j.tem.2009.03.008. PMC 3627124. PMID 19713122.
  40. ^ Pérez VI, Bokov A, Van Remmen H, Mele J, et al. (2009). "Is the oxidative stress theory of aging dead?". Biochim Biophys Acta. 1790 (10): 1005–1014. doi:10.1016/j.bbagen.2009.06.003. PMC 2789432. PMID 19524016.
  41. ^ Stuart GR, Oda Y, Boer JG, Glickman BW. No change in spontaneous mutation frequency or specificity in dietary restricted mice. Carcinogenesis. 2000 Feb;21(2):317-9. doi: 10.1093/carcin/21.2.317. PMID 10657975
  42. ^ Ginter E, Simko V (2013). "Women live longer than men". Bratisl Lek Listy. 114 (2): 45–49. doi:10.4149/bll_2013_011. PMID 23331196.
  43. ^ Hawkes K (2003). "Grandmothers and the evolution of human longevity". Am. J. Hum. Biol. 15 (3): 380–400. doi:10.1002/ajhb.10156. PMID 12704714. S2CID 6132801.
  44. ^ Vinicius L, Mace R, Migliano A (2014). "Variation in Male Reproductive Longevity across Traditional Societies". PLOS ONE. 9 (11): e112236. Bibcode:2014PLoSO...9k2236V. doi:10.1371/journal.pone.0112236. PMC 4236073. PMID 25405763.
  45. ^ Celec P, Ostatníková D, Hodosy J (2015). "On the effects of testosterone on brain behavioral functions". Front. Neurosci. 9: 12. doi:10.3389/fnins.2015.00012. PMC 4330791. PMID 25741229.
  46. ^ Dammann P, Burda H (2006). "Sexual activity and reproduction delay ageing in a mammal". Curr. Biol. 16 (4): 117–118. doi:10.1016/j.cub.2006.02.012. PMID 16488857. S2CID 17842436.
  47. ^ Hammers M, Richardson DS, Burke T, Komdeur J (2013). "The impact of reproductive investment and early-life environmental conditions on senescence: support for the disposable soma hypothesis" (PDF). J Evol Biol. 26 (9): 1999–2007. doi:10.1111/jeb.12204. PMID 23961923. S2CID 46466320.
  48. ^ Wu JJ, Liu J, Chen EB, Wang JJ, et al. (2013). "Increased mammalian lifespan and a segmental and tissue-specific slowing of aging after genetic reduction of mTOR expression". Cell Rep. 4 (5): 913–920. doi:10.1016/j.celrep.2013.07.030. PMC 3784301. PMID 23994476.
  49. ^ Murray, S. (2006). "Poverty and health". CMAJ. 174 (7): 923. doi:10.1503/cmaj.060235. PMC 1405857. PMID 16567753.

External links edit

Calorie restriction edit

  • Calorie Restriction Society

Biology of aging edit

  • Damage-Based Theories of Aging—Includes a discussion of the free radical theory of aging

January 01, 1970
disposable, soma, theory, aging, disposable, soma, theory, aging, states, that, organisms, evolutionary, trade, between, growth, reproduction, repair, maintenance, formulated, thomas, kirkwood, disposable, soma, theory, explains, that, organism, only, limited,. The disposable soma theory of aging states that organisms age due to an evolutionary trade off between growth reproduction and DNA repair maintenance 1 Formulated by Thomas Kirkwood the disposable soma theory explains that an organism only has a limited amount of resources that it can allocate to its various cellular processes 2 Therefore a greater investment in growth and reproduction would result in reduced investment in DNA repair maintenance leading to increased cellular damage shortened telomeres accumulation of mutations compromised stem cells and ultimately senescence Although many models both animal and human have appeared to support this theory parts of it are still controversial Specifically while the evolutionary trade off between growth and aging has been well established the relationship between reproduction and aging is still without scientific consensus and the cellular mechanisms largely undiscovered 3 Contents 1 Background and history 2 Principles 3 Mechanisms 3 1 Growth and somatic maintenance 3 2 Reproduction and somatic maintenance 4 Evidence 4 1 Growth and aging 4 1 1 Animal models 4 1 2 Human models 4 2 Reproduction and aging 4 2 1 Animal models 4 2 2 Human models 4 3 Relationship between cell damage and aging 5 Criticism 5 1 Caloric restriction 5 2 The grandmother hypothesis 5 3 Contradicting models 5 4 Sex biases and environment 6 References 7 External links 7 1 Calorie restriction 7 2 Biology of agingBackground and history editBritish biologist Thomas Kirkwood first proposed the disposable soma theory of aging in a 1977 Nature review article 1 The theory was inspired by Leslie Orgel s Error Catastrophe Theory of Aging which was published fourteen years earlier in 1963 Orgel believed that the process of aging arose due to mutations acquired during the replication process and Kirkwood developed the disposable soma theory in order to mediate Orgel s work with evolutionary genetics 1 Principles editThe disposable soma theory of aging posits that there is a trade off in resource allocation between somatic maintenance and reproductive investment Too low an investment in self repair would be evolutionarily unsound as the organism would likely die before reproductive age However too high an investment in self repair would also be evolutionarily unsound due to the fact that one s offspring would likely die before reproductive age Therefore there is a compromise and resources are partitioned accordingly However this compromise is thought to damage somatic repair systems which can lead to progressive cellular damage and senescence 4 Repair costs can be categorized into three groups 1 the costs of increased durability of nonrenewable parts 2 the costs of maintenance involving cell renewal and 3 the costs of intracellular maintenance 5 In a nutshell aging and decline is essentially a trade off for increased reproductive robustness in youth Mechanisms edit nbsp The IGF 1 pathway which represses FOXO thus preventing gene expression of longevity inducing proteins Growth and somatic maintenance edit Main article Mechanistic target of rapamycin Aging Much research has been done on the antagonistic effects of increased growth on lifespan Specifically the hormone insulin like growth factor 1 IGF 1 binds to a cell receptor leading to a phosphorylation cascade This cascade results in kinases phosphorylating forkhead transcription factor FOXO deactivating it Deactivation of FOXO results in an inability to express genes involved in responding to oxidative stress response such as antioxidants chaperones and heat shock proteins 6 Additionally uptake of IGF 1 stimulates the mTOR pathway which activates protein synthesis and therefore growth through upregulation of the translation promoting S6K1 and also inhibits autophagy a process necessary for recycling of damaged cellular products 7 Decline of autophagy causes neurodegeneration protein aggregation and premature aging 8 Lastly studies have also indicated that the mTOR pathway also alters immune responses and stimulates cyclin dependent kinase CDK inhibitors such as p16 and p21 This leads to alteration of the stem cell niche and results in stem cell exhaustion another theorized mechanism of aging 9 Reproduction and somatic maintenance edit While reproduction inhibits lifespan with regard to multicellular organisms the precise mechanism responsible for this effect remains unclear Although many models do illustrate an inverse relationship and the theory makes sense from an evolutionary perspective the cellular mechanisms have yet to be explored However with regards to cellular replication the progressive shortening of telomeres is a mechanism which limits the amount of generations of a single cell may undergo 10 Furthermore in unicellular organisms like Saccharomyces cerevisiae the formation of extrachromosomal rDNA circles ERCs in mother cells but not daughter cells upon every subsequent division is an identifiable type of DNA damage that is associated with replication These ERCs accumulate over time and eventually trigger replicative senescence and death of the mother cell 11 Evidence editGrowth and aging edit There is a large body of evidence indicating the negative effects of growth on longevity across many species As a general rule individuals of a smaller size generally live longer than larger individuals of the same species Animal models edit In dwarf models of mice such Snell or Ames mice mutations have arisen either rendering them incapable of producing IGF 1 or unable to have adequate receptors for IGF 1 uptake Furthermore mice injected with growth hormone have been shown to have progressive weight loss roughing of the coat curvature of the spine enlargement of the organs kidney lesions and increased cancer risk 12 This effect is also seen in different breeds of dogs where smaller breeds of dogs typically live significantly longer compared to their larger counterparts Selectively bred for their small size smaller dog breeds like the Chihuahua average lifespan of 15 20 years have the B B genotype for the IGF 1 haplotype reducing the amount of IGF 1 produced Conversely large dogs like the Great Dane average lifespan of 6 8 years are homozygous for the IGF 1 I allele which increases the amount of IGF 1 production 13 Human models edit Initially it was believed that growth hormone actually prolonged lifespan due to a 1990 study that indicated that injection of growth hormone to men over 60 years of age appeared to reverse various biomarkers implicated in aging such as decreased muscle mass bone density skin thickness and increased adipose tissue 14 However a 1999 study found that administering growth hormone also significantly increased mortality rate 15 Recent genomic studies have confirmed that the genes involved in growth hormone uptake and signaling are largely conserved across a plethora of species such as yeast nematodes fruit flies mice and humans 16 These studies have also shown that individuals with Laron syndrome an autosomal recessive disorder resulting in dwarfism due to defects in growth hormone receptors have increased lifespan Additionally these individuals have much lower incidences of age related diseases such as type 2 diabetes and cancer 17 Lastly human centenarians around the world are disproportionately of short stature and have low levels of IGF 1 18 Reproduction and aging edit Numerous studies have found that lifespan is inversely correlated with both the total amount of offspring birthed as well as the age at which females first gives birth also known as primiparity 19 Additionally it has been found that reproduction is a costly mechanism that alters the metabolism of fat Lipids invested in reproduction would be unable to be allocated to support mechanisms involved in somatic maintenance 20 Animal models edit The disposable soma theory has been consistent with the majority of animal models It was found in numerous animal studies that castration or genetic deformities of reproduction organs was correlated with increased lifespan 21 22 23 Moreover in red squirrels it was found that females with an early primiparity achieved the highest immediate and lifetime reproductive success However it was also found that these same individuals had a decreased median and maximum lifespan Specifically squirrels who mated earlier had a 22 4 rate of mortality until two years of age compared to a 16 5 rate of mortality in late breeders In addition these squirrels had an average maximum lifespan of 1035 days compared to an average maximum lifespan of 1245 days for squirrels that bred later 19 In another study researchers selectively bred fruit flies over three years to develop two different strains an early reproducing strain and a late reproducing strain The late reproducing line had a significantly longer lifespan than the early reproducing line Even more telling was that when the researchers introduced a mutation in the ovarian associated gene ovoD1 resulting in defective oogenesis the differences in lifespan between the two lines disappeared The researchers in this case concluded that aging has evolved primarily because of the damaging effects of reproduction earlier in life 24 Prominent aging researcher Steven Austad also performed a large scale ecological study on the coast of Georgia in 1993 Austad isolated two opossum populations one from the predator infested mainland and one from the predator absent nearby island of Sapelo According to the disposable soma theory a genetically isolated population subject to low environmentally induced mortality would evolve delayed reproduction and aging This is because without the pressure of predation it would be evolutionarily advantageous to allocate more resources to somatic maintenance than reproduction as early offspring mortality would be low As predicted even after controlling for predation the isolated population had a longer lifespan delayed primiparity and reduced aging biomarkers such as tail collagen cross linking 25 Human models edit In general only a few studies exist in human models It was found that castrated men live longer than their fertile counterparts 26 Further studies found that in British women primiparity was earliest in women who died early and latest in women who died at the oldest ages Furthermore increased number of children birthed was associated with a decreased lifespan 27 A final study found that female centenarians were more likely to have children in later life compared average especially past the age of 40 The researchers discovered that 19 2 of female centenarians had their first child after the age of 40 compared to 5 5 of the rest of the female population 28 Relationship between cell damage and aging edit Main article Free radical theoryMain article DNA damage theory of aging nbsp The naked mole rat has a disproportionately long life of 30 years through efficient cellular repair mechanisms There are numerous studies that support cellular damage often due to a lack of somatic maintenance mechanisms as a primary determinant for aging and these studies have given rise to the free radical theory of aging and the DNA damage theory of aging One study found that the cells of short living rodents in vitro show much greater mutation rates and a general lack of genome surveillance compared to human cells and are far more susceptible to oxidative stress 29 Other studies have been conducted on the naked mole rat a rodent species with remarkable longevity 30 years capable of outliving the brown rat 3 years by ten fold Additionally almost no incidence of cancer has ever been detected in naked mole rats Nearly all of the differences found between these two organisms which are otherwise rather genetically similar was in somatic maintenance Naked mole rats were found to have higher levels of superoxide dismutase a reactive oxygen species clearing antioxidant In addition naked mole rats had higher levels of base excision repair DNA damage response signaling homologous recombination repair mismatch repair nucleotide excision repair and non homologous end joining In fact many of these processes were near or exceeded human levels Proteins from naked mole rats were also more resistant to oxidation misfolding ubiquitination and had increased translational fidelity 30 Further studies have been conducted on patients with Hutchinson Gilford Progeria Syndrome HGPS a condition that leads to premature aging Patients with HGPS typically age about seven times faster than average and usually succumb to the disease in their early teens Patients with HGPS have cellular defects specifically in the lamin proteins which regulate the organization of the lamina and nuclear envelope for mitosis 31 A type lamins promote genetic stability by maintaining levels of proteins that have key roles in the repair processes of non homologous end joining and homologous recombination 32 Mouse cells deficient for maturation of prelamin A show increased DNA damage and chromosome aberrations and have increased sensitivity to DNA damaging agents 33 Lastly as mentioned previously it has been found that the suppression of autophagy is associated with reduced lifespan while stimulation is associated with extended lifespan Activated in times of caloric restriction autophagy is a process that prevents cellular damage through clearance and recycling of damaged proteins and organelles 34 Criticism editOne of the main weaknesses of the disposable soma theory is that it does not postulate any specific cellular mechanisms to which an organism shifts energy to somatic repair over reproduction Instead it only offers an evolutionary perspective on why aging may occur due to reproduction Therefore parts of it are rather limited outside of the field of evolutionary biology 3 Caloric restriction edit Main article Calorie restriction Sirtuin mediated mechanism nbsp Schematic showing the reallocation of energy investment towards self repair during caloric restriction Critics have pointed out the supposed inconsistencies of the disposable soma theory due to the observed effects of caloric restriction which is correlated with increased lifespan 35 Although it activates autophagy according to classical disposable soma principles with less caloric intake there would less total energy to be distributed towards somatic maintenance and decreased lifespan would be observed or at least the positive autophagic effects would be balanced out However Kirkwood alongside his collaborator Darryl P Shanley assert that caloric restriction triggers an adaptive mechanism which causes the organism to shift a higher proportion of resources to somatic maintenance away from reproduction 36 This theory is supported by multiple studies which show that caloric restriction typically results in impaired fertility but leave an otherwise healthy organism 37 38 Evolutionarily an organism would want to delay reproduction to when resources were more plentiful During a resource barren period it would evolutionarily unwise to invest resources in progeny that would be unlikely to survive in famine Mechanistically the NAD dependent deacetylase Sirtuin 1 SIRT 1 is upregulated during low nutrient periods SIRT 1 increases insulin sensitivity decreases the amount of inflammatory cytokines stimulates autophagy and activates FOXO the aforementioned protein involved in activating stress response genes SIRT 1 is also found to result in decreased fertility 39 In additional to differential partitioning of energy allocation during caloric restriction less caloric intake would result in less metabolic waste in the forms of free radicals like hydrogen peroxide superoxide and hydroxyl radicals which damage important cellular components particularly mitochondria Elevated levels of free radicals in mice has been correlated with neurodegeneration myocardial injury severe anemia and premature death 40 No changes were observed in the spontaneous chromosomal mutation frequency of dietary restricted mice aged 6 and 12 months compared to ad libitum fed control mice 41 Thus dietary restriction appears to have no appreciable effect on spontaneous mutation in chromosomal DNA and the increased longevity of dietary restricted mice apparently is not attributable to reduced chromosomal mutation frequency The grandmother hypothesis edit Main article Menopause Evolutionary rationale Another primary criticism of the disposable soma theory is that it fails to account for why women tend to live longer than their male counterparts 42 Afterall females invest significantly more resources into reproduction and according to the classical disposable soma principles this would compromise energy diverted to somatic maintenance However this can be reconciled with the grandmother hypothesis The Grandmother Hypothesis states that menopause comes about into older women in order to restrict the time of reproduction as a protective mechanism This would allow women to live longer and increase the amount of care they could provide to their grandchildren increasing their evolutionary fitness 43 And so although women do invest a greater proportion of resources into reproduction during their fertile years their overall reproductive period is significantly shorter than men who are able of reproduction during and even beyond middle age 44 Additionally males invest more resources into growth compare to females which is correlated with decreased lifespan Other variables such as increased testosterone levels in males are not accounted for Increased testosterone is often associated with reckless behaviour which may lead to a high accidental death rate 45 Contradicting models edit A few contradicting animal models weaken the validity of the disposable soma theory This includes studies done on the aforementioned naked mole rats In these studies it was found that reproductive naked mole rats actually show significantly increased lifespans compared to non reproductive individuals which contradicts the principles of disposable soma However although these naked mole rats are mammalian they are highly atypical in terms of aging studies and may not serve as the best model for humans For example naked mole rats have a disproportionately high longevity quotient and live in eusocial societies where breeding is usually designated to a queen 46 Sex biases and environment edit The disposable soma theory is tested disproportionately on female organisms for the relationship between reproduction and aging as females carry a greater burden in reproduction 47 Additionally for the relationship between growth and aging studies are disproportionately conducted on males to minimize the hormonal fluctuations that occur with menstrual cycling 48 Lastly genetic and environmental factors rather than reproductive patterns may explain the variations in human lifespan For example studies have shown that poorer individuals to whom nutritious food and medical care is less accessible typically have higher birth rates and earlier primiparity 49 References edit a b c Kirkwood T 1977 Evolution of ageing Nature 270 5635 301 304 Bibcode 1977Natur 270 301K doi 10 1038 270301a0 PMID 593350 S2CID 492012 Gavrilov LA Gavrilova NS 2002 Evolutionary theories of aging and longevity ScientificWorldJournal 7 2 339 356 doi 10 1100 tsw 2002 96 PMC 6009642 PMID 12806021 a b Blagosklonny MV 2010 Why the disposable soma theory cannot explain why women live longer and why we age Aging 2 12 884 887 doi 10 18632 aging 100253 PMC 3034172 PMID 21191147 Drenos F Kirkwood TB 2005 Modelling the disposable soma theory of ageing Mech Ageing Dev 126 1 99 103 doi 10 1016 j mad 2004 09 026 PMID 15610767 S2CID 2256807 Kirkwood TB Rose MR 1991 Evolution of senescence late survival sacrificed for reproduction Philos Trans R Soc Lond B Biol Sci 332 1262 15 24 doi 10 1098 rstb 1991 0028 PMID 1677205 O Neill BT Lee KY Klaus K Softic S et al 2016 Insulin and IGF 1 receptors regulate FoxO mediated signaling in muscle proteostasis J Clin Invest 126 9 3433 3346 doi 10 1172 JCI86522 PMC 5004956 PMID 27525440 Johnson SC Rabinovitch PS Kaeberlein M 2013 mTOR is a key modulator of ageing and age related disease Nature 493 7432 338 345 Bibcode 2013Natur 493 338J doi 10 1038 nature11861 PMC 3687363 PMID 23325216 Komatsu M Waguri S Chiba T Murata S et al 2006 Loss of autophagy in the central nervous system causes neurodegeneration in mice Nature 441 7095 880 884 Bibcode 2006Natur 441 880K doi 10 1038 nature04723 PMID 16625205 S2CID 4407360 Castilho RM Squarize CH Chodosh LA Williams BO et al 2009 mTOR mediates Wnt induced epidermal stem cell exhaustion and aging Cell Stem Cell 5 3 279 289 doi 10 1016 j stem 2009 06 017 PMC 2939833 PMID 19733540 Shay JW Wright WE 2011 Role of telomeres and telomerase in cancer Semin Cancer Biol 21 6 349 353 doi 10 1016 j semcancer 2011 10 001 PMC 3370415 PMID 22015685 Kaeberlein M McVey M Guarente L 1999 The SIR2 3 4 complex and SIR2 alone promote longevity in Saccharomyces cerevisiae by two different mechanisms Genes Dev 13 19 2570 2580 doi 10 1101 gad 13 19 2570 PMC 317077 PMID 10521401 Bartke A Brown Borg H 2004 Life extension in the dwarf mouse Curr Top Dev Biol 63 6 189 225 doi 10 1016 j semcancer 2011 10 001 PMC 3370415 PMID 22015685 Sutter NB Bustamante CD Chase K Gray MM 2007 A Single IGF1 Allele Is a Major Determinant of Small Size in Dogs Science 316 5821 112 115 Bibcode 2007Sci 316 112S doi 10 1126 science 1137045 PMC 2789551 PMID 17412960 Rudman D Feller AG Nagraj HS Gergans GA et al 1990 Effects of human growth hormone in men over 60 years old N Engl J Med 323 1 1 6 doi 10 1056 NEJM199007053230101 PMID 2355952 Takala J Ruokonen E Webster NR Nielsen MS Zandstra DF et al 1999 Increased mortality associated with growth hormone treatment in critically ill adults N Engl J Med 341 11 785 792 doi 10 1056 NEJM199909093411102 PMID 10477776 Longo VD Finch CE 2003 Evolutionary medicine from dwarf model systems to healthy centenarians Science 299 5611 1342 1346 doi 10 1126 science 1077991 PMID 12610293 S2CID 14848603 Guevara Aguirre J Balasubramanian P Guevara Aguirre M Wei M et al 2011 Growth hormone receptor deficiency is associated with a major reduction in pro aging signaling cancer and diabetes in humans Sci Transl Med 3 70 70 83 doi 10 1126 scitranslmed 3001845 PMC 3357623 PMID 21325617 Govindaraju D Atzmon G Barzilai N 2015 Genetics lifestyle and longevity Lessons from centenarians Appl Transl Genom 4 23 32 doi 10 1016 j atg 2015 01 001 PMC 4745363 PMID 26937346 a b Descamps S Boutin S Berteaux D Gaillard JM 2006 Best squirrels trade a long life for an early reproduction Proc Biol Sci 273 1599 2369 2374 doi 10 1098 rspb 2006 3588 PMC 1636082 PMID 16928640 Hansen M Flatt T Aguilaniu H 2013 Reproduction fat metabolism and life span what is the connection Cell Metab 17 1 10 19 doi 10 1016 j cmet 2012 12 003 PMC 3567776 PMID 23312280 Drori D Folman Y 1976 Environmental effects on longevity in the male rat exercise mating castration and restricted feeding Exp Gerontol 11 1 25 32 doi 10 1016 0531 5565 76 90007 3 PMID 1278267 S2CID 37672329 Flatt T 2011 Survival costs of reproduction in Drosophila PDF Exp Gerontol 46 5 369 375 doi 10 1016 j exger 2010 10 008 PMID 20970491 S2CID 107465469 Hsin H Kenyon C 1999 Signals from the reproductive system regulate the lifespan of C elegans Nature 399 6734 362 366 Bibcode 1999Natur 399 362H doi 10 1038 20694 PMID 10360574 S2CID 4358840 Sgro CM Partridge L 1999 A delayed wave of death from reproduction in Drosophila Science 286 5449 2521 2524 doi 10 1126 science 286 5449 2521 PMID 10617470 Austad SN 1993 Retarded senescence in an insular population of Virginia opossums Didelphis virginiana Journal of Zoology 229 4 695 708 doi 10 1111 j 1469 7998 1993 tb02665 x Hamilton JB Mestler GE 1969 Mortality and survival comparison of eunuchs with intact men and women in a mentally retarded population J Gerontol 24 4 395 411 doi 10 1093 geronj 24 4 395 PMID 5362349 Westendorp RG Kirkwood TB 1998 Human longevity at the cost of reproductive success Nature 396 6713 743 746 doi 10 1038 25519 PMID 9874369 S2CID 151331241 Perls TT Alpert L Fretts RC 1997 Middle aged mothers live longer Nature 389 6647 133 Bibcode 1997Natur 389 133P doi 10 1038 38148 PMID 9296486 S2CID 4401775 Lorenzini A Stamato T Sell C 2011 The disposable soma theory revisited time as a resource in the theories of aging Cell Cycle 10 22 3853 3856 doi 10 4161 cc 10 22 18302 PMID 22071624 Azpurua J Ke Z Chen IX Zhang Q Ermolenko DN et al 2013 Naked mole rat has increased translational fidelity compared with the mouse as well as a unique 28S ribosomal RNA cleavage Proc Natl Acad Sci U S A 110 43 17350 17355 Bibcode 2013PNAS 11017350A doi 10 1073 pnas 1313473110 PMC 3808608 PMID 24082110 Pollex RL Hegele RA 2004 Hutchinson Gilford progeria syndrome Clin Genet 66 5 375 381 doi 10 1111 j 1399 0004 2004 00315 x PMID 15479179 S2CID 7529899 Redwood Abena B Perkins Stephanie M Vanderwaal Robert P Feng Zhihui Biehl Kenneth J Gonzalez Suarez Ignacio Morgado Palacin Lucia Shi Wei Sage Julien Roti Roti Joseph L Stewart Colin L Zhang Junran Gonzalo Susana 27 October 2014 A dual role for A type lamins in DNA double strand break repair Cell Cycle 10 15 2549 2560 doi 10 4161 cc 10 15 16531 PMC 3180193 PMID 21701264 Liu Baohua Wang Jianming Chan Kui Ming Tjia Wai Mui Deng Wen Guan Xinyuan Huang Jian dong Li Kai Man Chau Pui Yin Chen David J Pei Duanqing Pendas Alberto M Cadinanos Juan Lopez Otin Carlos Tse Hung Fat Hutchison Chris Chen Junjie Cao Yihai Cheah Kathryn S E Tryggvason Karl Zhou Zhongjun 26 June 2005 Genomic instability in laminopathy based premature aging Nature Medicine 11 7 780 785 doi 10 1038 nm1266 PMID 15980864 S2CID 11798376 Glick D Barth S Macleod KF 2010 Autophagy cellular and molecular mechanisms J Pathol 221 1 3 12 doi 10 1002 path 2697 PMC 2990190 PMID 20225336 Blagosklonny MV 2010 Solving puzzles of aging From disposable soma to signal transduction pathways Russ J Gen Chem 80 7 1407 1414 doi 10 1134 s1070363210070364 S2CID 95075587 Shanley DP Kirkwood TB 2000 Calorie restriction and aging a life history analysis Evolution 54 3 740 750 doi 10 1111 j 0014 3820 2000 tb00076 x PMID 10937249 S2CID 26293762 Holliday R 2000 Food reproduction and longevity is the extended lifespan of calorie restricted animals an evolutionary adaptation BioEssays 10 4 125 127 doi 10 1002 bies 950100408 PMID 2730632 Masoro EJ Austad SN 1996 The evolution of the antiaging action of dietary restriction a hypothesis J Gerontol A Biol Sci Med Sci 51 6 387 391 doi 10 1093 gerona 51a 6 b387 PMID 8914486 Canto C Auwerx J 2009 Caloric restriction SIRT1 and longevity Trends Endocrinol Metab 20 7 325 331 doi 10 1016 j tem 2009 03 008 PMC 3627124 PMID 19713122 Perez VI Bokov A Van Remmen H Mele J et al 2009 Is the oxidative stress theory of aging dead Biochim Biophys Acta 1790 10 1005 1014 doi 10 1016 j bbagen 2009 06 003 PMC 2789432 PMID 19524016 Stuart GR Oda Y Boer JG Glickman BW No change in spontaneous mutation frequency or specificity in dietary restricted mice Carcinogenesis 2000 Feb 21 2 317 9 doi 10 1093 carcin 21 2 317 PMID 10657975 Ginter E Simko V 2013 Women live longer than men Bratisl Lek Listy 114 2 45 49 doi 10 4149 bll 2013 011 PMID 23331196 Hawkes K 2003 Grandmothers and the evolution of human longevity Am J Hum Biol 15 3 380 400 doi 10 1002 ajhb 10156 PMID 12704714 S2CID 6132801 Vinicius L Mace R Migliano A 2014 Variation in Male Reproductive Longevity across Traditional Societies PLOS ONE 9 11 e112236 Bibcode 2014PLoSO 9k2236V doi 10 1371 journal pone 0112236 PMC 4236073 PMID 25405763 Celec P Ostatnikova D Hodosy J 2015 On the effects of testosterone on brain behavioral functions Front Neurosci 9 12 doi 10 3389 fnins 2015 00012 PMC 4330791 PMID 25741229 Dammann P Burda H 2006 Sexual activity and reproduction delay ageing in a mammal Curr Biol 16 4 117 118 doi 10 1016 j cub 2006 02 012 PMID 16488857 S2CID 17842436 Hammers M Richardson DS Burke T Komdeur J 2013 The impact of reproductive investment and early life environmental conditions on senescence support for the disposable soma hypothesis PDF J Evol Biol 26 9 1999 2007 doi 10 1111 jeb 12204 PMID 23961923 S2CID 46466320 Wu JJ Liu J Chen EB Wang JJ et al 2013 Increased mammalian lifespan and a segmental and tissue specific slowing of aging after genetic reduction of mTOR expression Cell Rep 4 5 913 920 doi 10 1016 j celrep 2013 07 030 PMC 3784301 PMID 23994476 Murray S 2006 Poverty and health CMAJ 174 7 923 doi 10 1503 cmaj 060235 PMC 1405857 PMID 16567753 External links editCalorie restriction edit Calorie Restriction Society Biology of aging edit Damage Based Theories of Aging Includes a discussion of the free radical theory of aging Retrieved from https en wikipedia org w index php title Disposable soma theory of aging amp oldid 1217915463, wikipedia, wiki, book, books, library,

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