2.1. Antagonistic pleiotropy as a cause of aging

How might gene variants with bad effects on late-life health act? Here there are two ideas. First, they could be harmful mutations with effects that do not appear until late life. A suggested example is Huntington’s disease, which does not develop until mid-life, as the selection shadow deepens. This could explain its relatively high prevalence, despite being caused by a dominant mutation (Haldane, 1941). This instantiates the mutation accumulation theory of the evolution of aging (Medawar, 1952). Here, the harmful alleles that natural selection fails to eliminate and which cause aging are very much akin to disease-causing mutations, such as those causing Marfan syndrome or hemochromatosis. According to the mutation accumulation theory aging is a form of genetic disease, arising from a multiplicity of late-acting mutations.

Second, they may be gene variants that provide a fitness benefit in early life, but also promote pathology in later life. Due to the selection shadow, fitness benefits may outweigh the later detriment, resulting in the allele spreading through the population (Williams, 1957)(Fig. 1A). Here the new allele displays pleiotropy, i.e. has several effects, that are opposite in terms of impact on fitness, i.e. antagonistic pleiotropy (AP). Given that AP genes provide fitness benefits and are present due to positive selection, they cannot be viewed as defective or mutant; rather they are, in genetic terms, wild type. Thus, insofar as they are caused by AP genes, diseases of aging are genetic diseases arising from effects of the wild-type genome. The idea that normal gene function can cause disease might, from a medical perspective, seem a contradiction in terms. But evolutionary theory, now well supported empirically (Austad and Hoffman, 2018; Byars and Voskarides, 2020; Carter and Nguyen, 2011; Zhao and Promislow, 2019), tells us that normal genes can cause late-life pathology and diseases of aging. Such genes may be referred to as gerontogenes (Johnson and Lithgow, 1992).

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Fig. 1

Ultimate and proximate mechanisms of aging (traditional interpretations).

A, Antagonistic pleiotropy. A new allele that causes a fitness benefit in early life but a fitness cost (e.g. increased pathology) in later life may cause a net benefit in overall fitness due to the selection shadow (Williams, 1957). B, The damage/maintenance paradigm. Aging is caused by accumulation of stochastic molecular damage, whose levels can be controlled by somatic maintenance functions. C, The disposable soma theory. Investment of resources in reproduction more than somatic maintenance can increase fitness due to the selection shadow (Kirkwood, 1977). Genes promoting such resource allocation will exhibit antagonistic pleiotropy (Partridge and Gems, 2002a). D, Regulation of aging by nutrient pathways. Traditional view based on damage/maintenance paradigm (Partridge and Gems, 2006). The hyperfunction model argues that it is in fact the growth, development function that plays the main role in promoting aging.

This is a fundamental principle of pathophysiology critical for understanding late-life disease. Yet its utility is limited by the current lack of understanding of the actual biological mechanisms (biochemical, cellular, physiological) by which AP genes exert their effects. What is needed here is an account of the determinants of aging that encompasses both ultimate, evolutionary mechanisms and proximate, biological mechanisms into a single integrated understanding. Two such ultimate-proximate accounts of the causes of aging are the disposable soma theory and the programmatic theory.

4.1. The core programmatic theory

Growth hormone (GH), IIS and mTOR are part of a nutrient-sensitive signaling network that promotes growth, development and aging. This suggests that growth and development somehow cause aging. But three lines of reasoning initially seemed to argue against this deduction. First, it suggests that there is a program for aging, implying that aging is a purposeful adaptation; but according to evolutionary theory aging is non-adaptive, and therefore not programmed (Austad, 2004; Kirkwood, 2005; Partridge and Gems, 2002b). Second, growth and development are not obviously linked to somatic maintenance and molecular damage accumulation, which was assumed to be the main cause of senescence. Third, it is difficult to see how growth processes can limit lifespan. The programmatic theory provides answers to each of these three objections.

First, the program problem. Here it is helpful to consider Williams’ own initial thoughts about how AP might work at the level of gene function, which involve a hypothetical gene for calcium deposition. A new allele appears that increases Ca²⁺ deposition during bone development, and thereby promotes fitness (e.g. by aiding escape from predators); in later life, its continued action promotes Ca²⁺ deposition into blood vessel walls, contributing to arteriosclerosis (Fig. 2A) (Williams, 1957). In principle, a mechanism could evolve to switch off calcium deposition, but due to the selection shadow it does not. Here, an evolved function of a gene continues or runs on in a futile fashion in later life causing pathology. The principle involved here is notably different to the DS theory. If this can occur for the function of structural genes of this sort, why not for regulatory genes controlling entire developmental programs and involving action of large numbers of regulated genes (Fig. 2B)?

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Fig. 2

Antagonistic pleiotropy (AP) as hyperfunction.

A, AP as run-on of structural gene function. Hypothetical example (Williams, 1957). B, AP as run-on of regulatory gene function. This results in pathogenic quasi-programs (Blagosklonny, 2006a). C, Overview of the core programmatic theory of aging (Blagosklonny, 2006a; de Magalhães and Church, 2005); here passage from left to right denotes advancing age. See glossary for definition of terms.

Evolutionary theory rules out biological programs for aging (i.e. aging as an adaptation) for most species, but not programmatic or program-like mechanisms that promote senescence (Blagosklonny, 2007c; de Magalhães and Church, 2005). Part of the confusion arises because the word program here has two meanings. On the one hand it can mean a genetically-determined and complex process involving changes in gene expression, cellular function, tissue composition etc (programmed in the mechanistic sense); on the other hand it can mean a program for something that promotes fitness (programmed in the adaptive sense) (Galimov et al., 2019). Aided by this disambiguation, the new theory is able to argue that in later life programmatic changes occur that are programmed in the mechanistic but not the adaptive sense, or as Blagosklonny describes them, quasi-programmed (Blagosklonny, 2006a). The derived noun quasi-program, describing a programmatic, pathogenic entity, is particularly helpful for discussion of programmatic pathophysiology.

To explain the quasi-program concept, Blagosklonny employs various homely analogies. For example, one wants hot water for tea and so boils some in a saucepan. If, having taken the water, one leaves the saucepan on the hot stove, the pan will become damaged. Here a purposeful program for preparing hot water becomes a futile quasi-program for damaging the saucepan (Blagosklonny, 2006a). In living organisms later-life off switches for developmental programs are often absent because of declining selection in later life (Blagosklonny, 2006a; Williams, 1957). Similarly, de Magalhães uses the analogy of a program to build a house, and imagines a carpet layer working on pointlessly after completion of the program: “ever-increasing layers of carpets will eventually prevent doors from opening, and ultimately, nobody will be able to get in or out of the house” (de Magalhães, 2012). This starts to explain how growth promotion by IIS/mTOR can promote aging: they promote both developmental programs and senescence-promoting quasi-programs (Blagosklonny, 2006a; de Magalhães and Church, 2005).

But what about molecular damage? de Magalhães and Blagosklonny both suggest that the assumption that aging is largely and primarily caused by accumulation of molecular damage is incorrect (Blagosklonny, 2006a; de Magalhães and Church, 2005). As Blagosklonny articulates it, the primary mechanisms of aging do not involve loss of function, but rather the opposite: too much function or, as he puts it, hyperfunction, driven by wild-type gene action. This claim challenges the entrenched assumption that aging is fundamentally a passive process of system failure and breakdown. Thinking of mTOR effects in particular, Blagosklonny argues that it is the opposite: an active, self-destructive process.

Finally, how can processes of growth and development lead to disease? Broadly speaking, the programmatic theory argues that developmental changes in adulthood, including late-life continuation of developmental programs, is pathogenic, causing disruption of tissue and organ function. Several examples of simple forms of developmental run-on follow. Presbyopia is a type of long-sightedness that increases with age. Its cause is continued, futile growth of the lens during adulthood, leading to a gradual increase in lens thickness (Strenk et al., 2005). In men, the prostate gland typically exhibits a gradual increase in size as a response to long term exposure to dihydrotestosterone. This leads eventually to benign prostatic hyperplasia (Nacusi and Tindall, 2011; Waters et al., 2000) and increased risk of prostate cancer, a major cause of age-related death in men (Untergasser et al., 2005). In a third example, this time hypothetical, the process of synaptic pruning in the brain that promotes cognitive development runs on in later life, leading to age-related cognitive decline (De Magalhaes and Sandberg, 2005). A final example affects babirusas, a type of wild pig found in Indonesia. Adult males have curved, tusk-like maxillary canine teeth that point backwards up over the snout. These continue to grow until in some cases the backward curve of their growth trajectory drives them into the cranium, sometimes piercing it through (Macdonald, 2018). Here, in each case, continuation of normal, wild-type growth leads to pathology. However, most aging-related diseases are etiologically multi-factorial, and contributions of programmatic etiologies more complex (described below).

A simplified scheme of the programmatic theory is shown in Fig. 2C. Beyond these core tenets, Blagosklonny and de Magalhães have each contributed additional ideas, which extend and strengthen the theorem. For example, Blagosklonny elaborates upon how quasi-programs affect lifespan and disease, and makes pointed critiques of various concepts arising from the damage/maintenance paradigm, while de Magalhães integrates the programmatic theory conceptually with earlier developmental theories of aging, and explores evolutionary mechanisms beyond AP and IIS/mTOR that contribute to programmatic aging. Ideas from these two commentators will be discussed in turn.

5.3. Blagosklonny on the attack

In many of his essays, Blagosklonny uses conceptual research to compare how well damage-based and programmatic theories do at explaining findings past and present. Overall, these find in favor of the latter, and support critiques of several traditional biogerontological claims and concepts, which he sometimes pokes fun at for their perceived inadequacies.

5.3.2. Against disposable soma

The mTOR-driven quasi-programs (mTOR/QP) model provides an alternative ultimate-proximate model to the disposable soma (DS) theory, that is closer to Williams’ own original idea about proximate mechanisms of AP. Blagosklonny even refers to this model as “disposable soma theory 2”, insofar as the soma is disposable as the result of mTOR/QP action (rather than resource allocation etc) due to AP and the later-life selection shadow (Blagosklonny, 2013c). He points out that the mTOR/QP model originates from consideration of diverse scientific findings, unlike either Harman’s free radical theory (Blagosklonny, 2008b) or the DS theory (Blagosklonny, 2010e), and argues that it outperforms DS at explaining a range of phenomena.

For example, the life-extending effects of dietary restriction (DR) have been reconciled with DS by the allocation hypothesis. Here it is argued that DR leads to diversion of resources from reproduction to somatic maintenance, thereby increasing lifespan (Holliday, 1989; Kirkwood and Shanley, 2005; Masoro and Austad, 1996)(Fig. 5A). Blagosklonny argues that this is implausible for a number of reasons. Perhaps most cogently, a more parsimonious prediction from DS is that increasing resources for somatic maintenance would increase lifespan and vice versa (Blagosklonny, 2007b). By contrast the mTOR/QP model argues simply that reduction in nutrients reduces mTOR activity, which suppresses both growth and QPs (Fig. 5B).

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Fig. 5

Alternative theories about how dietary restriction increases lifespan.

A, The allocation hypothesis, based on the disposable soma theory. Reduced food leads to increased investment in somatic maintenance. B, Explanation based on the hyperfunction theory. Here reduced nutrients reduces growth pathway signaling, thus reducing quasi-programmed hyperfunction. Figure redrawn from (Blagosklonny, 2007b). The latter is both more parsimonious and consistent with existing knowledge of pathophysiology of various diseases of aging.

As another example, inhibition of protein biosynthetic genes in C. elegans increases lifespan, and it was suggested that this is due to freeing up of resources that are then invested in somatic maintenance (Hansen et al., 2007; Hipkiss, 2007). Blagosklonny argues instead that reducing protein synthesis prevents QP progression, pointing out that mTOR promotes protein synthesis (Blagosklonny, 2007b). As a third example, it was argued from the DS theory that women live longer due to increased investment into somatic maintenance (Kirkwood, 2010). Blagosklonny reasons that DS predicts that women should live shorter, since they invest more into reproduction; he suggests instead that increased mTOR activity promotes muscle growth in males, but accelerates aging (Blagosklonny, 2010a; Blagosklonny, 2010d; Leontieva et al., 2012b).

6.2. From the programmatic theory to epigenetic aging and biological clocks

A recent topic of interest among biogerontologists has been epigenetic changes during adulthood (Benayoun et al., 2015; Horvath and Raj, 2018). de Magalhães notes studies showing similarities between changes in gene expression occurring during development and aging (Lui et al., 2010; Somel et al., 2010; Takasugi, 2011) as evidence that drivers of epigenetic change are programmatic rather than stochastic (de Magalhães, 2012). As a developmental process, quasi-program execution is expected to involve epigenetic change. Thus, the programmatic theory provides an explanation in terms of ultimate and proximate causes for epigenetic changes in aging (though this does not rule out the action of other contributory mechanisms).

The question of how biological time is marked during aging is central to biogerontology, and many forms of clock have been proposed. These include a metabolic clock in the rate-of-living theory (Pearl, 1928), a telomere shortening replicometer in replicative senescence (Olovnikov, 1996), and epigenetic changes such as DNA methylation (Horvath, 2013; Horvath and Raj, 2018). According to the programmatic theory, the major aging clock is a developmental one. de Magalhães sees epigenetic changes as likely to arise from the ticking of a developmental clock (de Magalhães, 2012), whose speed is increased by IIS/mTOR (de Magalhães and Church, 2005). Consistent with this, the methylation clock is slowed by conditions in which mTOR is inhibited (Blagosklonny, 2018a), for example in mice treated with rapamycin, in long-lived Ames (Prop1), Snell (Pit1), and Laron (Ghr) dwarf mutant mice with defective GH signaling (Cole et al., 2017; Consortium, 2021; Petkovich et al., 2017; Wang et al., 2017), and in rapamycin-treated cultured human fibroblasts and keratinocytes (Horvath et al., 2019; Matsuyama et al., 2019). Moreover, mTOR functions in circadian clocks, underscoring the role of mTOR in setting the pace of biological time (Blagosklonny, 2018a).

The developmental basis of epigenetic changes during adulthood in mammals has received further support from recent work by Steve Horvath and colleagues. Of particular note, methylation clocks mark time during embryogenesis and postnatal development as well as (running much more slowly) during adulthood, and clock methylation sites are strongly associated with genes specifying developmental processes. The latter include those under regulation of the polycomb repressor complex (PRC), including multiple Hox genes, leading to the conclusion that “the essence of the aging process itself is an integral part of, and the consequence of the development of life” (Raj and Horvath, 2020). The link between clock methylation sites and PRC-regulated genes was also recently seen in a universal mammalian methylation clock, implying evolutionary conservation of developmental clock mechanisms (Consortium, 2021).

Almost a century ago, Raymond Pearl attributed rate-of-living effects, as seen in effects of ambient temperature on lifespan in poikilotherms (e.g. Drosophila, C. elegans)(Klass, 1977; Loeb and Northrop, 1917) to metabolic rate (Pearl, 1928), an idea that was subsequently linked to the ROS theory (Sohal and Weindruch, 1996). The programmatic theory suggests instead that effects of temperature on both development and aging reflects a change in the rate of developmental processes.

7.3. The ontogenesis of the programmatic theory

Scientific discovery is rightly the object of wonder, something to marvel at. In my view, this applies to the programmatic theory. In the early 18th century a fierce priority dispute broke out between Isaac Newton and Gottfried Leibniz arguing over who invented calculus. The modern view is that this was silly, and that both men developed it independently. Such independent, simultaneous discoveries are quite common, and illustrate how scientific innovation is not so much a reflection of individual genius, as interactions of imaginative individuals with a collective and evolving fabric of knowledge. Once the fashion among scientists, these days I-said-it-first-ism risks being interpreted as a character weakness (principally, egotism).

The transpersonal nature of scientific thinking applies well to the programmatic theory, which has evolved over a long period, with certain key contributors. Dilman’s overall scheme, based around his hypothalamic model, was flawed and did not cohere well, yet included a number of prescient elements which contributed to Blagosklonny’s more compelling and better-supported theorem. Dilman himself noted similarities between his ontogenetic theory and Bidder’s hypothesis, formulated in the 1930s (Dilman, 1986). By contrast, de Magalhães’ version of the programmatic theory was developed without knowledge of either Dilman or Blagosklonny’s work. The possibility of the programmatic theory was, as it were, hanging in the air from the early 2000s, and both de Magalhães and Blagosklonny spotted it, with Blagosklonny developing it in more detail with respect to its capacity to explain the origins of disease. Yet the programmatic theory of the mid-2000s forms only part of a wider biology of aging, as discussed here and elsewhere (Gems et al., 2021; Lohr et al., 2019; Maklakov and Chapman, 2019). Of Dilman: he was in many ways ahead of his time and his work deserves greater recognition than it received during his lifetime (at least, outside Russia). He was noted for his creative and integrative thinking style (Napalkov, 2001), characteristics shared by Blagosklonny, and de Magalhães too.