Because cells are the fundamental building blocks of our bodies, it is logical to assume that cellular changes contribute to the aging process. In this essay I review the methods used to study cellular aging in vitro, in particular replicative senescence, and debate whether these findings could be related to organismal aging.
The Hayflick Limit
In 1961, and in contradiction to what was thought at the time, Leonard Hayflick and Paul Moorhead discovered that human cells derived from embryonic tissues could only divide a finite number of times in culture. They divided the stages of cell culture into Phases I-III. Phase I is the primary culture, when cells from the explant multiply to cover the surface of the culture flask--most cell types grow in the lab attached to a solid surface. Phase II represents the period when cells divide in culture. Briefly, once cells cover a flask's surface, they stop multiplying. For cell growth to continue, the cells must be subcultivated. To do so, one removes the culture's medium and adds a digestive enzyme called trypsin that dissolves the substances binding cells together. After adding growth medium and pipetting one obtains the cells in a homogeneous suspension that are then divided by two--or more--new flasks. Cells then attach to the new flasks' surface and start dividing once again until a new subcultivation is required. Most cells divide vigorously and can often be subcultivated in a matter of a few days. After several months, however, cells start dividing slower, which marks the beginning of Phase III. Eventually cells stop dividing at all, though they may or may not die. Hayflick and Moorhead noticed that cultures stopped dividing after an average of 50 cumulative population doublings (CPDs)--splitting one flask of cells into two new flasks of the same size increases the CPDs by one, splitting by four flasks increases the CPDs by two and so on. This phenomenon of growth arrest after a period of apparently normal cell proliferation is known as the Hayflick limit, Phase III phenomenon, or, as it will be called herein, replicative senescence (RS).
Hayflick and Moorhead worked with fibroblasts, a cell type found in connective tissue widely used in research, but RS has been found in other cell types: keratinocytes, endothelial cells, lymphocytes, adrenocortical cells, vascular smooth muscle cells, chondrocytes, etc. In addition, RS is observed in cells derived from embryonic tissues, in cells from adults of all ages, and in cells taken from many animals: mice, chickens, Galapagos tortoises, etc. The number of CPDs cells undergo in culture varies considerably between cell types and species. Early results suggested a relation between CPDs cells could endure and the longevity of the species from which the cells were derived. For example, cells from the Galapagos tortoise, which -- as described -- can live over a century, divide about 110 times, while mouse cells divide roughly 15 times -- but see more recent studies below. In addition, cells taken from patients with progeroid syndromes such as Werner syndrome (WS) --described elsewhere -- endure far fewer CPDs than normal cells. Exceptions exist and certain cell lines can divide indefinitely without reaching RS. These are said to be "immortal" and include embryonic germ cells and most cell lines derived from tumors, such as HeLa cells. Some types of rat cells have also been claimed as capable of evading RS, and more recently some mouse cells have been found to be immortal under certain culture conditions, as detailed below.
Biomarkers of Cell Senescence
The discovery of RS sparked considerable interest and the phenotype of cell senescence in human fibroblasts has been characterized by a series of features, termed biomarkers d'Adda di Fagagna, 2007). The most obvious biomarker is growth arrest, i.e., cells stop dividing, which can be detected by different methods. Even vigorously dividing cultures are heterogeneous and contain a percentage of growth-arrested cells; this percentage progressively increases until all cells in the population are quiescent, that is, they have stopped dividing; interestingly, the percentage of growth-arrested cells is higher in cells from patients with progeroid syndromes, such as WS cells, when compared with normal cells at the same CPD. Senescent cells are growth arrested in the transition from phase G1 to phase S of the cell cycle. The growth arrest in RS is irreversible in the sense that growth factors cannot stimulate the cells to divide, even though senescent cells can remain metabolically active for long periods of time.
Another important biomarker is cellular morphology. While cells age in vitro they endure progressive morphological changes. Briefly, senescent cells are bigger and a senescent population has more diverse morphotypes than cells at earlier CPDs. In fact, a confluent senescent culture has a smaller cellular density than a confluent young culture, though this also occurs because senescent cells are more sensitive to cell-cell contact inhibition.
One widely-used marker of RS is senescence-associated β-galactosidase (SA β-gal) activity. The enzyme β-galactosidase, a lysosomal hydrolase, is normally active at pH 4, but in senescent cells it often happens for β-galactosidase to be active at pH 6 which can be detected with a simple biochemical assay. Both in vitro and in vivo, the percentage of cells positive for SA β-gal increases with, respectively, CPDs and age. Conversely, in immortal cell lines, such as HeLa tumor cells, the percentage of cells positive for SA β-gal does not correlate with CPDs. The increase in SA β-gal also correlates with the appearance of the senescent morphotypes. Lysosomes are organelles that break down cellular junk. Early reports showed that lysosomes increase in number and size in senescent cells. SA β-gal appears to be a result of increased lysosomal activity at a suboptimal pH, which becomes detectable in senescent cells due to an increase in lysosomal content. Other results also suggest that during in vitro aging increased autophagy -- i.e., digestion of the cell's organelles; discussed elsewhere -- may be associated with an increase of lysosomal mass and SA β-gal.
Normal human cells are diploid, which means they have two copies of each chromosome. With each subcultivation the percentage of polyploid cells -- i.e., with three or more copies of chromosomes--has been shown to increase. Deletions in the mitochondrial DNA (mtDNA) have also been observed both during RS and during aging in vivo, at least in some tissues.
The expression levels of several genes change during in vitro cellular aging. One important type of gene overexpressed in senescent cells are inflammatory regulators like interleukin 6 (IL6); some studies support a role for proinflammatory proteins secreted by senescent cells in driving senescence, which may lead to positive feedback loops and to senescence induction in normal cells near senescent cells. Senescent cells also display an increased activity of metalloproteinases which degrade the extracellular matrix. On the other hand, senescent cells have a decreased ability to express heat shock proteins.
Telomeres are non-coding regions at the tips of chromosomes. In vertebrates, they are composed of repeated sequences of TTAGGG. During in vitro aging, the telomeres shorten gradually in each subcultivation. The same process might occur in vivo too. Telomere shortening is the primary cause of RS in human fibroblasts, and given their importance, telomeres and their role in aging are discussed in detail in another essay.
Stress-Induced Premature Senescence
Assuming human fibroblasts endure 50 CPDs, 250 is more than enough cells for several lifetimes. However, a number of factors can accelerate and/or trigger cell senescence, one of which is oxidative stress. Normally, cell culture conditions include 20% oxygen (O2) and these were the conditions initially used by Hayflick and Moorhead and most subsequent studies. When human fibroblasts are cultured at 3% O2, which is closer to physiological conditions, they achieve a further 20 CPDs. Conversely, different types of human cells cultured above 20% O2 display a reduced growth rate and endure fewer CPDs. If O2 is above 50%, in fact, it becomes cytotoxic. The way subcytotoxic stress can accelerate the appearance of the senescent phenotype in cells has been deemed as another form of cellular senescence called stress-induced premature senescence (SIPS).
Not surprisingly, depending on the dose of stressor used, a cell population will react in different ways. For instance, a high cytotoxic dosage will cause such an amount of damage that cellular biochemical activities decrease leading to cellular death by necrosis. The level of damage sustained by cells determines whether programmed cell death--apoptosis--can unfold or, if the damage is lower, senescence. Since a cellular population is not homogeneous, the dosage of the stressor will shift the percentage of cells executing each of the possible programs depending on the amount of stress, respectively, from no stress to high stress: cellular proliferation, senescence, apoptosis, and necrosis.
In addition to O2, other sources of oxidative damage, such as H2O2 and tert-butylhydroperoxide, and other stressors--e.g., ethanol, ionizing radiations, and mitomycin C--can induce SIPS in many types of proliferative cells such as lung and skin fibroblasts, endothelial cells, melanocytes, and retinal pigment epithelial cells. The list of stressors that can cause SIPS is constantly growing. Instead of chronic stress, SIPS can be induced based on a single or repeated short exposure(s) to stressors. Oncogenes such as ras can also induce senescence. As discussed below, because organisms and cells are constantly being exposed to stressors, senescent cells in vivo may derive not only from cell divisions but from cells being exposed to stress.
Senescent Cells, Stress and Organismal Aging
The connection between organismal aging and cell senescence remains a subject of controversy, in spite of decades of study. Below I present and discuss some of the key arguments for and against a role of RS and senescent cells in human aging.
At least post partum, there is no relation between the number of CPDs cells can endure and the age of the donor. Chances are previous studies showing otherwise were biased. Likewise, one study in centenarians failed to find differences in the CPDs cells taken from centenarians could endure when compared to cells from young donors. As mentioned above, cells at birth from patients with certain progeroid syndromes have fewer divisions than cells from healthy controls. This, however, might be a result of increased cell death or exit from the cell cycle for reasons unrelated to RS. In fact, senescent cells from patients with Werner's syndrome have different patterns of gene expression and biomarkers of senescence; similar findings have been reported in Hutchinson-Gilford progeria). I should also point out that a caveat of comparing CPDs is that when cell lines are derived from people, the selected cells are those that grow because people, even very old people, never run out of proliferating cells. As such, these studies would not detect, say, differences in the proportion of proliferating cells.
Although a relation between a species' longevity and the CPDs its cells can endure in vitro exists, it is debatable if this is related to aging. For one, optimal culture conditions vary from species to species. As an example, O2 partial pressure can affect cellular proliferation and there is evidence that O2 limits the replicative capacity of mouse fibroblasts as these are immortal under low O2. As such, comparisons between different species may be biased due to intra-species differences in O2 sensitivity. In addition, due to the positive correlation between body size and longevity--mentioned before --, perhaps cells taken from long-lived animals endure more CPDs because of differences in size, not due to differences in longevity, as supported by results using more sophisticated methods.
Senescent cells and senescence-associated biomarkers can be found in various human tissues in vivo associated with both aging and pathology. Interestingly, stress-prone tissues appear to be the most affected. For example, fibroblasts cultured from distal lower extremities of patients with venous reflux, which precedes the development of venous ulcers, display characteristics of senescent cells. Similar results also relate cellular senescence to atherosclerosis and benign prostatic hyperplasia, a common age-related male pathology. One study found that the number of senescent fibroblasts increases exponentially with age in the skin of baboons and senescent cells are >15% of all cells in very old animals. In the mouse liver, one study estimated that over 20% of hepatocytes were potentially senescent. Senescent cells have been found in other mouse tissues too, though possibly through telomere-independent mechanisms. Markers of cell senescence, such as p16INK4a which is discussed elsewher, have been found in the mouse brain and pancreas, potentially contributing to age-dependent decline in regeneration. A gene expression meta-analysis across mammalian tissues and species found signatures of senescent cells in aged tissues. However, one study monitored p16INK4a expression with age in mice and found that, while its expression increases with age, total body p16INK4a expression does not predict overall mortality, raising questions about the role of senescent cells in aging.
Because senescent cells can secrete proinflammatory cytokines and other factors that disrupt the tissue microenvironment, they may contribute to disruption of cell and tissue function. Even a small percentage of senescent cells, in fact, may interfere with tissue homeostasis and function. Indeed, some evidence exist that senescent cells contribute to age-related pathologies such as osteoarthritis and to skin aging. Repeated stimulation of WI-38 human fibroblasts with pro-inflammatory cytokines interleukin-1 α (IL-1α) or tumor necrosis factor-α (TNF-α) induces SIPS. These cytokines' circulating levels increase in vivo, favoring inflammation and perhaps contributing to SIPS in vivo; senescent cells might then also contribute to increase inflammatory levels, creating a positive feedback loop.
Studies using genetically-modified mice found that genetic clearance of senescent cells delays aging-associated disorders in old mice. Initially this was observed in progeroid mice that exhibit accelerated aging and accumulate more senescent cells than normally. Clearance of senescent cells also did not extend lifespan in progeroid mice, which Baker et al. claim is due to their mice dying primarily of heart disease which is not affected by the treatment. More recently, using the same genetic approach, the same group found that removing senescent cells in mice preserves health in some tissues, though not in others, protects from cancer and extends median (but not maximum) lifespan. Therefore, these landmark studies provide evidence that senescent cells can promote age-related phenotypes, at least to a subset of organs.
Clearly, senescent cells can be found in vivo without telomere shortening. Since cells taken from old donors do not endure fewer CPDs, one hypothesis is that senescent cells in vivo are not widely caused by shortening telomeres but instead by various stressors and insults. Exemplifying, studies in centenarians have raised doubts on whether telomere shortening occurs in vivo and whether senescence-associated genes in vitro are also differentially expressed in vivo. Besides, some data indicate that chronic stressors may accelerate risk of a host of age-related diseases by prematurely aging the immune response. Lastly, as hinted by the above mentioned results on the impact of O2 in cell proliferation, RS for many cell lines in vitro and in vivo might instead be better defined as SIPS resulting from oxidative stress.
A relationship appears to exist between stress resistance and aging. In model organisms, extended longevity is often associated with increased stress resistance. Concisely, manipulations in C. elegans that extend longevity show a strong correlation with resistance to stress. In Drosophila too some mutations can increase longevity and augment stress resistance. Cell lines from long-lived mouse strains are also stress resistant and stress resistance in vitro correlates with mammalian longevity, at least for some stressors; similar results have been observed in birds. Cells from older individuals are more susceptible to stress and exhibit higher levels of biomarkers of senescence in general. Finally, cells taken from patients with progeroid syndromes are more susceptible to stress, as not surprisingly are late passage fibroblasts. Of course, it is not known whether these relationships are causal or not. Nevertheless, aging and stress resistance appear to be inversely related and so an association between cellular stress resistance and organismal aging is a possibility.
There is no doubt that changes occur with age at a cellular level. Some genetic interventions regulating aging appear to influence tissue homeostasis by affecting senescence, cell proliferation, and cell death, as detailed in the context of the endocrine theory of aging. Results from mice suggest that systemic factors can influence aging, but only to some degree, showing that intrinsic cellular mechanisms no doubt play a role in aging. In some tissues, such as the immune system, decreased proliferative ability may play a role in age-related degeneration. Successive transplants of spleen and bone marrow yielded far from conclusive results but it appears that a slight decrease in proliferative ability does occur in vivo in spite the cells having had to divide much more than 50 times. Renewal of cardiomyocytes in humans declines with age. Therefore, mechanisms of aging intrinsic to cells no doubt exist. These may be related to the senescent phenotype but no doubt to other processes too. It was initially reported that cells from older donors have a slower proliferative capacity. This effect, known as the latent period, occurs because fewer cells are in the replication cycle, not because they take longer to divide, but it has also been under attack. One study argued that cells ceasing division is not relevant to aging. Instead, altered gene expression, resulting from quality control defects that allow errors to accumulate as cells divide, leads to cells with diminished function.
Overall, it is clear that RS is not a faithful model of aging changes occurring in vivo. In fact, RS is widely recognized as an anti-cancer mechanism, as further debated elsewhere. Recent results also suggest a role for senescent cells during development and wound healing. Senescent cells also appear to have benefits in promoting insulin secretion by pancreatic beta cells. That is not to say, however, that senescent cells cannot play a role in some aspects of aging. One hypothesis is that while RS evolved as an anti-cancer mechanism, the accumulation of senescent cells contributes to aging. While there is little evidence to suggest that cells running out of divisions are a major factor in aging, it is possible that stress and various insults trigger cell senescence in vivo. Even a small fraction of senescent cells in organs may impair tissue renewal and homeostasis, decrease organ function, and contribute to the aging phenotype, as shown by the studies genetically ablating senescent cells. As such, there is some evidence that accumulating senescent cells might promote a subset of the aging phenotype, and clearly senescent cells may contribute to age-related pathologies or at the very least reflect damage to tissues.. Because telomere shortening is the main cause of RS in human fibroblasts, this topic is further debated in context of the role of telomeres in aging.
Stem Cells and Germ Cells
Stem cells are found in different places throughout the body and participate in tissue homeostasis by replacing differentiated cells that die; due to their high place in tissues' hierarchy, stem cells are promising subjects for study in the context of aging. Some human stem cells can express telomerase, indicating that the most actively dividing cell lines in the body overcome telomere shortening--though somatic stem cells can show senescence in vitro and in vivo. Interestingly, a correlation between mean telomeres and age is found in the first two decades for muscle satellite cells--a type of muscle stem cell--but not afterwards. Consequently, one hypothesis is that somatic cells can only divide a limited amount of times but are constantly being replenished by stem cells. Interestingly, satellite cells in mouse muscle become senescent-like with age due to p16INK4a activation, perhaps contributing to loss of homeostasis and regeneration in old muscle. Furthermore, one study found a correlation between stem cell turnover and mice lifespan, meaning that perhaps stem cell senescence influences organismic senescence. Mechanisms of stem cell aging are also of great interest and have been linked to various processes, including DNA damage and telomeres. At present this is only one hypothesis but no doubt unraveling the role of stem cells in aging is a major avenue for future research. As mentioned elsewhere, stem cells may also have anti-aging applications.
As previously mentioned, the doctrine of the immortal germplasm claims that germ cells are immortal and can divide forever. A prediction of such hypothesis is that the germ cells should have increased stress resistance and repair mechanisms. Experimental evidence, however, is contradictory: the soma of Drosophila has been reported to be more sensitive to mutagens; increased DNA repair has been documented in male mice germ cells, but using ionizing radiation no difference in sensibility was found between mice male germ cells and bone marrow. It has also been proposed that meiosis and gametogenesis can have recombinational and other genetic events that contribute to a rejuvenation not possible in differentiated somatic cells, yet little or no evidence exists to support such claims. Furthermore, the common notion that germ cells have improved DNA repair mechanisms and thus avoid aging is itself debatable.