Disposable soma theory of aging

In biogerontology, 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 British biologist 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

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

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.[citation needed]

Mechanisms

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

Growth and somatic maintenance

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

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

Growth and aging

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.[citation needed]

Animal models

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

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

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

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

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 to the 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

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

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

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.[citation needed]

The grandmother hypothesis

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] After all, 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

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

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]

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Batocera ushijimai Klasifikasi ilmiah Kerajaan: Animalia Filum: Arthropoda Kelas: Insecta Ordo: Coleoptera Famili: Cerambycidae Subfamili: Lamiinae Tribus: Batocerini Genus: Batocera Spesies: Batocera ushijimai Batocera ushijimai adalah spesies kumbang tanduk panjang yang tergolong famili Cerambycidae. Spesies ini juga merupakan bagian dari genus Batocera, ordo Coleoptera, kelas Insecta, filum Arthropoda, dan kingdom Animalia. Larva kumbang ini biasanya mengebor ke dalam kayu dan dapat menye...

بيدرو إيمانويل

بيدرو إيمانويل   معلومات شخصية الميلاد 11 فبراير 1975 (العمر 49 سنة)لواندا  الطول 1.80 م (5 قدم 11 بوصة) مركز اللعب مدافع الجنسية البرتغال  معلومات النادي النادي الحالي الخليج (مدرب) مسيرة الشباب سنوات فريق 1986–1993 بوافيشتا المسيرة الاحترافية1 سنوات فريق م. (هـ.) 1993–1994 ...

 

Massimo Brunelli

Massimo BrunelliInformationsNaissance 27 juillet 1961 (62 ans)MilanNationalité italienneSpécialité Poursuite par équipesÉquipes amateurs 1981Lainatese-Brooklyn1982La Nuova Corbettese1983-1984FMG Diadora-Wilier Triestina1985?1986La Nuova Baggio-San Siro1987Dari-MecPrincipales victoires Champion du monde de poursuite par équipes (1985)modifier - modifier le code - modifier Wikidata Massimo Brunelli (né le 27 juillet 1961 à Milan) est un coureur cycliste italien. Biographie Né le 2...

 

Синелобый амазон

Синелобый амазон Научная классификация Домен:ЭукариотыЦарство:ЖивотныеПодцарство:ЭуметазоиБез ранга:Двусторонне-симметричныеБез ранга:ВторичноротыеТип:ХордовыеПодтип:ПозвоночныеИнфратип:ЧелюстноротыеНадкласс:ЧетвероногиеКлада:АмниотыКлада:ЗавропсидыКласс:Пт�...

2018 Copa Perú

Football league seasonCopa PerúSeason2018ChampionsPirata← 2017 2019 → The 2018 Peru Cup season (Spanish: Copa Perú 2018), the largest amateur tournament of Peruvian football, started in February. This edition has featured a change, with the elimination of the Regional Stage and the inclusion of participants from all the Regions of Peru in the National Stage. Under the new format, the tournament has four stages. The first three stages are played as mini-league round-robin tournaments, an...

 

Organ of Corti

Receptor organ for hearing This article needs additional citations for verification. Please help improve this article by adding citations to reliable sources. Unsourced material may be challenged and removed.Find sources: Organ of Corti – news · newspapers · books · scholar · JSTOR (December 2014) (Learn how and when to remove this template message) Organ of CortiA cross section of the cochlea illustrating the organ of CortiDetailsPart ofCochlea of the...

 

Shark tooth

Teeth of a shark For shark's teeth road markings, see Stop and yield lines. Fossil shark teeth (Cretaceous) from southern Israel Elementorum myologiae specimen, 1669 Sharks continually shed their teeth; some Carcharhiniformes shed approximately 35,000 teeth in a lifetime, replacing those that fall out.[1] There are four basic types of shark teeth: dense flattened, needle-like, pointed lower with triangular upper, and non-functional. The type of tooth that a shark has depends on its di...

Chardonnay

Chardonnay (diucapkan [ʃaʁ.dɔ.nɛ]) adalah sebuah varietas anggur berkulit hijau yang digunakan untuk membuat wine putih. Anggur tersebut berasal dari kawasan wine Burgundy, timur Prancis, tetapi sekarang tumbuh tempat wine diproduksi, dari Inggris sampai Selandia Baru. Referensi Jancis Robinson, editor (2006). The Oxford Companion to Wine, Third Edition. Oxford University Press. ISBN 0-19-860990-6. Pemeliharaan CS1: Teks tambahan: authors list (link) Oz Clarke; Margaret Ran...

 

Sahotra Sarkar

Indian-American biologist Sahotra SarkarBorn1962 (age 61–62)Alma materColumbia UniversityUniversity of ChicagoScientific careerFieldsConservation biologyInstitutionsMcGill UniversityUniversity of Texas at Austin Sahotra Sarkar (born 1962) is an Indian-American professor at the University of Texas at Austin, specializing in the philosophy of biology. Education and career Sarkar is originally from India where he lived in Darjeeling until 1975.[1] He earned a BA from Colu...

 

Overexploitation

Depleting a renewable resourceAtlantic cod stocks were severely overexploited in the 1970s and 1980s, leading to their abrupt collapse in 1992.[1] Overexploitation, also called overharvesting, refers to harvesting a renewable resource to the point of diminishing returns.[2] Continued overexploitation can lead to the destruction of the resource, as it will be unable to replenish. The term applies to natural resources such as water aquifers, grazing pastures and forests, wild me...

National Solar Mission

Initiative of the Government of India National Solar Mission (NSM)Mission statementAchieve 100 GW solar capacity by 2022Type of projectSolar energy missionCountryIndiaPrime Minister(s)Manmohan Singh (2010–14)Narendra Modi (2014–present)MinistryMinistry of New and Renewable EnergyLaunched11 January 2010; 14 years ago (2010-01-11)Closed2022; 2 years ago (2022)(?) [citation needed] The National Solar Mission is an initiative of the Government of In...

 

Gaetano Mosca

Italian political scientist and journalist Gaetano MoscaCOSML, COCI, SoKMember of the Italian Chamber of Deputiesfor PalermoIn office24 March 1909 – 29 September 1919ConstituencyCaccamo Personal detailsBorn(1858-04-01)1 April 1858Palermo, Kingdom of the Two SiciliesDied8 November 1941(1941-11-08) (aged 83)Rome, ItalyPolitical partyHistorical RightAlma materUniversity of PalermoProfessionTeacher, journalistPhilosophy careerEra20th-century philosophyRegionWestern philosophySchoo...

 

Boeing 777

Boeing 777Un Boeing 777-300ER di EmiratesDescrizioneTipoAereo di lineaAereo cargo Equipaggio2 piloti +gli assistenti di volo Progettista Boeing Costruttore Boeing Data primo volo12 giugno 1994 Anni di produzione1993-in produzione Data entrata in servizio7 giugno 1995 con United Airlines Utilizzatori principali (Gennaio 2024) Emirates144 esemplari United Airlines96 esemplari Qatar Airways91 esemplari Esemplari1 727[1] Costo unitario 777-200ER: 306,6 milioni di $ (20...

Matteo Ferrari

Untuk pembalap motor Italia, lihat Matteo Ferrari (pembalap motor). Matteo Ferrari Informasi pribadiNama lengkap Matteo FerrariTanggal lahir 5 Desember 1979 (umur 44)Tempat lahir Aflou, AljazairTinggi 188 cm (6 ft 2 in)[1]Posisi bermain Bek tengahKarier junior1995–1996 SPAL1996–1997 InternazionaleKarier senior*Tahun Tim Tampil (Gol)1997–1998 Genoa 3 (0)1998–1999 Lecce 13 (0)1999–2001 Internazionale 19 (0)1999–2000 → Bari (pinjaman) 26 (0)2001–2004 P...

 

Petualangan Tintin

Petualangan TintinBerkas:Tintin film kartun logo.jpgPetualangan TintinPengarangHergéPenerbitan Casterman PT. Tiga Lima Indira Gramedia Petualangan Tintin (bahasa Prancis: ''Les Aventures de Tintin et Milou'') adalah serial komik yang diciptakan oleh Hergé, seorang artis dari Belgia. Hergé adalah pseudonim dari Georges Remi (1907–1983) yang dituliskan menjadi RG (dibaca sebagai Hergé dalam bahasa Prancis). Serial ini pertama kali muncul dalam bahasa Prancis sebagai lampiran bagian an...

 

Glacial motion

Geological phenomenon This article needs additional citations for verification. Please help improve this article by adding citations to reliable sources. Unsourced material may be challenged and removed.Find sources: Glacial motion – news · newspapers · books · scholar · JSTOR (September 2013) (Learn how and when to remove this message) Termini of the glaciers in the Bhutan-Himalaya. Glacial lakes have been rapidly forming on the surface of the debris-...

Rhodesian African Rifles

Regiment of the Rhodesian Army Rhodesian African RiflesThe distinctive unit insignia (badge) of the Rhodesian African Rifles, featuring a Matabele shield, crossed by a Matabele stabbing spear and a Shona digging spear, obfuscated by a knobkerrie.Active1 May 1916 – 31 December 1981CountryRhodesia, Zimbabwe from 1980[note 1]Allegiance United Kingdom (1940-65; also officially successors to the service of the RNR 1916-18) Rhodesia (1965–70) Republic of Rhodesia (1970–...

 

Pir Kola Chah

Village in Gilan province, Iran Village in Gilan, IranPir Kola Chah Persian: پيركلاچاهVillagePir Kola ChahCoordinates: 37°15′47″N 49°37′47″E / 37.26306°N 49.62972°E / 37.26306; 49.62972[1]CountryIranProvinceGilanCountyRashtDistrictCentralRural DistrictHowmehPopulation (2016)[2] • Total2,437Time zoneUTC+3:30 (IRST) Pir Kola Chah (Persian: پيركلاچاه)[a] is a village in Howmeh Rural District of the Cen...