Doubling potential, calendar time, and senescence of human diploid cells in culture

Human diploid cells (CF-1) derived from newborn foreskin tissue were maintained in a non-mitotic state for as long as 177 days by reducing the serum concentration of the incubation medium to 0.5%. The cells could be returned to the proliferative state by subcultivation with normal growth medium containing 10% serum. Cells treated in such a manner reached passage levels equivalent to controls that had been continuously cultured on growth medium, but they took a proportionately longer calendar time to achieve the equivalent passage levels. Also, by using ³H-thymidine incorporation, cells held in the non-mitotic conditions showed a longer ‘predictable life span’ than control cultures. During 21-day maintenance periods there was a 10–20% cell loss and ca 30% loss of protein per cell. The finite life span of these human diploid cells was clearly related to the number of cumulative population doublings rather than to the total calendar time in vitro.     

Lifetime reproductive success, longevity, and reproductive life history of female yellow baboons (Papio cynocephalus) of Mikumi National Park, Tanzania

The relationship between longevity and lifetime reproductive success (LRS) was studied in free-ranging female baboons of Mikumi National Park, Tanzania. A severe population decline occurred between the 12th and 20th years of the study. The total sample consisted of 72 females born and reaching adulthood before the start of the population decline. There were 27 females who were adult at the start of the study and 45 who became adult within the 12 years prior to the decline. The subjects were studied until all 72 were dead and all of their offspring were either dead or at least six years old; this took 24 years. The relationship of longevity to LRS was statistically significant for the total sample and for both sub-samples, with 70% of the total variance in LRS accounted for by longevity. Longevity was linked to LRS via a chain of statistically significant relationships: The longer the life span, the longer the reproductive life; the longer the reproductive life, the more offspring produced; the more offspring produced, the higher the LRS. Mean LRS, life span, and reproductive longevity all differed between the two sub-samples. Since the sub-samples were time-linked to a population decline affecting longevity, either sub-sample separately would fail to reflect the broader picture. This illustrates the importance of appreciable sample sizes from long-term studies in helping understand the dynamics between life history estimates and ecological conditions in variable environments.     

Telomerase can extend the proliferative capacity of human myoblasts,but does not lead to their immortalization

Normal cells in culture display a limited capacity to divide and reach a non-proliferative state called cellular senescence. Spontaneous escape from senescence resulting in an indefinite life span is an exceptionally rare event for normal human cells and viral oncoproteins have been shown to extend the replicative life span but not to immortalize them. Telomere shortening has been proposed as a mitotic clock that regulates cellular senescence. Telomerase is capable of synthesizing telomere repeats onto chromosome ends to block telomere shortening and to maintain human fibroblasts in proliferation beyond their usual life span. However, the consequence of telomerase expression on the life span of human myoblasts and on their differentiation is unknown. In this study, the telomerase gene and the puromycin resistance gene were introduced into human satellite cells, which are the natural muscle precursors (myoblasts) in the adult and therefore, a target for cell-mediated gene therapy. Satellite cells expressing telomerase were selected, and the effects of the expression of the telomerase gene on proliferation, telomere length, and differentiation were investigated. Our results show that the telomerase-expressing cells are able to differentiate and to form multinucleated myotubes expressing mature muscle markers and do not form tumors in vivo. We also demonstrated that the expression of hTERT can extend the replicative life of muscle cells although these failed to undergo immortalization.     

Post-reproductive life span and demographic stability

Recent field studies suggest that it is common in nature for animals to outlive their reproductive viability. Post-reproductive life span has been observed in a broad range of vertebrate and invertebrate species. But post-reproductive life span poses a paradox for traditional theories of life history evolution. The commonly cited explanation is the “grandmother hypothesis”, which applies only to higher, social mammals. We propose that post-reproductive life span evolves to stabilize predator-prey population dynamics, avoiding local extinctions. In the absence of senescence, juveniles would be the most susceptible age class. If juveniles are the first to disappear when predation pressure is high, this amplifies the population’s risk of extinction. A class of older, senescent individuals can help shield the juveniles from predation, stabilizing demographics and avoiding extinction. If, in addition, the life history is arranged so that the older individuals are no longer fertile, the stabilizing effect is further enhanced.     

Life Span Evolution in Eusocial Workers—A Theoretical Approach to Understanding the Effects of Extrinsic Mortality in a Hierarchical System

While the extraordinary life span of queens and division of labor in eusocial societies have been well studied, it is less clear which selective forces act on the short life span of workers. The disparity of life span between the queen and the workers is linked to a basic issue in sociobiology: How are the resources in a colony allocated between colony maintenance and reproduction? Resources for somatic maintenance of the colony can either be invested into quality or quantity of workers. Here, we present a theoretical optimization model that uses a hierarchical trade-off within insect colonies and extrinsic mortality to explain how different aging phenotypes could have evolved to keep resources secure in the colony. The model points to the significance of two factors. First, any investment that would generate a longer intrinsic life span for workers is lost if the individual dies from external causes while foraging. As a consequence, risky environments favor the evolution of workers with a shorter life span. Second, shorter-lived workers require less investment than long-lived ones, allowing the colony to allocate these resources to sexual reproduction or colony growth.     

Relief of oxidative stress by ascorbic acid delays cellular senescence of normal human and Werner syndrome fibroblast cells

Primary human cells have a definite life span and enter into cellular senescence before ceasing cell growth. Oxidative stress produced by aerobic metabolism has been shown to accelerate cellular senescence. Here, we demonstrated that ascorbic acid, used as an antioxygenic reagent, delayed cellular senescence in a continuous culture of normal human embryonic cells, human adult skin fibroblast cells, and Werner syndrome (WS) cells. The results using human embryonic cells showed that treatment with ascorbic acid phospholic ester magnesium salt (APM) decreased the level of oxidative stress, and extended the replicative life span. The effect of APM to extend the replicative life span was also shown in normal human adult cells and WS cells. To understand the mechanism of extension of cellular life span, we determined the telomere lengths of human embryonic cells, both with and without APM treatment, and demonstrated that APM treatment reduced the rate of telomere shortening. The present results indicate that constitutive oxidative stress plays a role in determining the replicative life span and that suppression of oxidative stress by an antioxidative agent, APM, extends the replicative life span by reducing the rate of telomere shortening.     

Catalytically active human telomerase mutants with allele-specific biological properties

Expression of the catalytic subunit of human telomerase, hTERT, extends human primary fibroblast life span. Such life span extension has generally been reported to be accompanied by net telomere lengthening, which led to the hypothesis that it is the telomere lengthening that causes the life span extension. Here we show that hTERT+C and hTERT-FlagC, mutant telomerase proteins with either 10 additional residues or a FLAG epitope added to the hTERT C-terminus, confer significant but limited life span extension to IMR90 human primary lung fibroblasts. However, as the cells continue to grow for >100 population doublings past their normal senescence point, bulk telomere length continues to erode to lengths much shorter than those seen at the senescence of control telomerase-negative cells. Expression of hTERT+C immortalized IMR90 cells transformed by three different oncogenes. Again, bulk telomeres became much shorter than those of the control cells at crisis. Additional hTERT mutants were constructed and analyzed similarly. Enzymatically active hTERT-N125A+T126A, like other previously reported conserved GQ domain mutants and C-terminally HA-tagged hTERT, failed to extend life span. Another GQ domain mutant, hTERT-E79A, was indistinguishable from wild-type hTERT in its cell growth effects, but there was no net telomere lengthening. These results uncover further hTERT allele-specific phenotypes that uncouple telomerase activity, net telomere lengthening and life span extension.     

Does the immune system of a mouse age faster than the immune system of a human?

One of the characteristics of all somatic cells is a finite life span. Cells may proliferate until they reach a point after which, although they are metabolically active, they can no longer produce daughter cells. This observation is central to the clonal exhaustion hypothesis, a mechanism cited to explain age-associated immune dysfunction. In this hypothesis, repeated division of lymphocytes leads to a replicative limit, after which they enter the senescent phase but are not lost from the pool of T cells. Advancing age would then be associated with an increase in the number of T cells that are unable to proliferate to a stimulus which induces a proliferative response in T cells from younger individuals. This hypothesis seems both logical and reasonable and is supported by data from both humans and mice with the demonstration of an age-related accumulation of senescent T cells in both species. However, there is an apparent paradox. The paradox arises because the onset of immunosenescence appears to be more closely linked to the life span of the animal rather than the life span of the lymphocyte. BioEssays 21:519–524, 1999. © 1999 John Wiley & Sons, Inc.     

Parental investment, late reproduction, and increased reserve capacity are associated with longevity in humans

Throughout the living world trade-offs between reproductive success and longevity have been observed. In general, two extremes of life history patterning are reported, r- and K-selected species. The latter tend toward larger body sizes, few offspring from any one pregnancy, few offspring over the female reproductive span, longer life spans, and greater parental investment (PI: all efforts and expenses associated with the production, gestation, post-natal care, feeding, and protection of young) (e.g., whales, elephants, hominids). r-selected species tend toward smaller body size, multiple births/litters per pregnancy, female production of many gametes and offspring over the life span, and low levels of PI (e.g., most plants, insects, mice). These differences have significant influences on physiological variation among human populations.Across human samples, reproductive success (RS: the number of offspring successfully birthed and reared to reproductive age) has been reported to vary positively, negatively, and not at all with longevity of women. This complexity may be in part due to the fact that both early-life and late-life fecundity are associated with longevity in women, while total parity seems a poor gauge of female longevity in humankind. Large variations in associations of RS with longevity in women suggest that multiple factors may confound this association. One confounding factor is that among women, RS is largely determined not by fecundity, but by the quality of PI available to offspring. Among modern humans, PI is more complex, longer lasting (both relatively and absolutely), and extensive than for any other mammal. This suggests that modern human life history is a reflection of the co-evolution of longevity and extensive PI as part of our species' biocultural evolution. The need for long-term PI has greatly shaped human physiological variation and patterns of longevity.     

Ce-emerin and LEM-2: essential roles in Caenorhabditis elegans development, muscle function, and mitosis

Emerin and LEM2 are ubiquitous inner nuclear membrane proteins conserved from humans to Caenorhabditis elegans. Loss of human emerin causes Emery-Dreifuss muscular dystrophy (EDMD). To test the roles of emerin and LEM2 in somatic cells, we used null alleles of both genes to generate C. elegans animals that were either hypomorphic (LEM-2-null and heterozygous for Ce-emerin) or null for both proteins. Single-null and hypomorphic animals were viable and fertile. Double-null animals used the maternal pool of Ce-emerin to develop to the larval L2 stage, then arrested. Nondividing somatic cell nuclei appeared normal, whereas dividing cells had abnormal nuclear envelope and chromatin organization and severe defects in postembryonic cell divisions, including the mesodermal lineage. Life span was unaffected by loss of Ce-emerin alone but was significantly reduced in LEM-2-null animals, and double-null animals had an even shorter life span. In addition to striated muscle defects, double-null animals and LEM-2-null animals showed unexpected defects in smooth muscle activity. These findings implicate human LEM2 mutations as a potential cause of EDMD and further suggest human LEM2 mutations might cause distinct disorders of greater severity, since C. elegans lacking only LEM-2 had significantly reduced life span and smooth muscle activity.     

Information theory of ageing: Studying the effect of bone marrow transplantation on the life span of mice

In this paper the method of life span extension of multicellular organisms (human) using reservation of stem cells followed by autotransplantation has been proposed. As the efficiency of this method results from the information theory of ageing, it is important to verify it experimentally testing the basic concepts of the theory. Taking it into consideration, the experiment on bone marrow transplantation to old mice from young closely related donors of the inbred line was carried out. It has been shown that transplanted animals exhibited a survival advantage, a mean life span increased by 34% as compared to the control. This result not only demonstrates the efficiency of the proposed method for life span extension of multicellular organisms, but also confirms the basis of the information theory of ageing.     

Successful immortalization of mesenchymal progenitor cells derived from human placenta and the differentiation abilities of immortalized cells

We reported previously that mesenchymal progenitor cells derived from chorionic villi of the human placenta could differentiate into osteoblasts, adipocytes, and chondrocytes under proper induction conditions and that these cells should be useful for allogeneic regenerative medicine, including cartilage tissue engineering. However, similar to human mesenchymal stem cells (hMSCs), though these placental cells can be isolated easily, they are difficult to study in detail because of their limited life span in vitro. To overcome this problem, we attempted to prolong the life span of human placenta-derived mesenchymal cells (hPDMCs) by modifying hTERT and Bmi-1, and investigated whether these modified hPDMCs retained their differentiation capability and multipotency. Our results indicated that the combination of hTERT and Bmi-1 was highly efficient in prolonging the life span of hPDMCs with differentiation capability to osteogenic, adipogenic, and chondrogenic cells in vitro. Clonal cell lines with directional differentiation ability were established from the immortalized parental hPDMC/hTERT+Bmi-1. Interestingly, hPDMC/Bmi-1 showed extended proliferation after long-term growth arrest and telomerase was activated in the immortal hPDMC/Bmi-1 cells. However, the differentiation potential was lost in these cells. This study reports a method to extend the life span of hPDMCs with hTERT and Bmi-1 that should become a useful tool for the study of mesenchymal stem cells.     

Expression profiles of p53-, p16(INK4a)-, and telomere-regulating genes in replicative senescent primary human, mouse, and chicken fibroblast cells.

Replicative senescence is known to be an intrinsic mechanism in determining the finite life span of in vitro cultured cells. Since this process is recognized as an evolutionarily conserved mechanism from yeast to mammalian cells, we compared the senescence-associated genetic alterations in the p53, p16(INK4a), and telomere regulatory pathways using replicative senescent human, mouse, and chicken fibroblast cells. Normal human diploid fibroblast (HDF; WI38) and chicken embryonic fibroblast (CEF) cells were shown to have a more extended in vitro proliferative potential than their mouse embryonic fibroblast (MEF) counterpart. In contrast to the HDF and CEF cells, MEF cells were shown to express telomerase mRNA and maintain telomerase activity throughout their in vitro life span. Functional p53 activity was shown to increase in the replicative senescent HDF and CEF cells, but not in replicative senescent MEF cells. On the other hand, there was a gradual elevation of p16(INK4a) expression with increased cell passages which reached a maximum in replicative senescent MEF cells. Taken together, the present study demonstrates that the p53, p16(INK4a), and telomere regulatory functions may be differentially regulated during replicative senescence in human, mouse, and chicken fibroblast cells.