Immortal phenotype of the HeLa variant D98 is recessive in hybrids formed with normal human fibroblasts

Normal human cells such as human diploid fibroblasts (HDF) have a finite proliferative lifespan in culture. Previous studies have shown that the limited lifespan phenotype is dominant in cell hybrids formed by fusion of HDF to at least 23 different kinds of immortal human cells. However, two independent studies reported that hybrid clones formed by the fusion of HDF to the HeLa variant D98 had unlimited division potential. Those results were potentially very important because they implied that a) there is a dominant mechanism for immortalization of human cells in addition to the well-documented recessive mechanism, and b) a dominant mechanism would lend itself to identification of the immortalizing gene. Consequently, we carried out more detailed studies of the behavior of D98 cells in hybrids. Our results indicate that the majority of D98 x HDF hybrid clones exhibit a clear-cut finite proliferative lifespan phenotype. In addition, these hybrid cell populations often give rise to an immortal focus of cells that can be seen to take over the population of mortal cells at the end of their lifespan. This phenomenon reconciles our data with the previous reports of immortal D98 x HDF hybrid clones and leads us to conclude that D98 cells do not express a dominant immortalizing gene.     

Experimental elongation of telomeres extends the lifespan of immortal x normal cell hybrids.

Hybrids between immortal cells that express telomerase and normal cells that lack telomerase have a limited lifespan. We demonstrate that telomerase is repressed in such hybrids. Treatment of immortal human cell lines with certain oligonucleotides resulted in telomere elongation. We took advantage of this observation to test the hypothesis that elongation of telomeres would extend the lifespan of cells in culture. An immortal human cell line was treated with an oligonucleotide to lengthen its telomeres and then was fused with mortal cells. The lifespan of these hybrid cells was longer than that of the hybrids in which telomeres had not been elongated. These observations provide the first direct evidence supporting the hypothesis that telomere length determines proliferative capacity of human cells.     

Correlation between complementation group for immortality and DNA synthesis inhibitors

Previous studies had demonstrated that a DNA synthesis inhibitor(s) was produced by senescent but not young human diploid fibroblasts (HDF). Analysis of immortal human cell lines led to the finding that SUSM-1, carcinogen-treated immortal human liver fibroblast cells, expressed a potent inhibitor of DNA synthesis that was active in proliferation-competent young HDF but did not affect the SUSM-1 cell line itself. To determine whether one mechanism of escape from senescence to the immortal phenotype involved the loss of response to such DNA synthesis inhibitors, we initiated the present study analyzing a larger number of immortal human cell lines representative of the four complementation groups for indefinite division identified to date. We have found a correlation between the assignment of a cell line to Complementation Group D and the production of DNA synthesis inhibitors coupled with inability to respond to the inhibitory factors. We have also observed a correlation between the ability of immortal cell lines to respond to such DNA synthesis inhibitory factors and assignment to Complementation Group B. These data suggest DNA synthesis inhibitors are involved in the limited lifespan of normal cells and that the immortalization process may involve alterations in the activity of or response to such inhibitors.     

Cellular lifespan and senescence signaling in embryonic stem cells

Most mammalian cells when placed in culture will undergo a limited number of cell divisions before entering an unresponsive non-proliferating state termed senescence. However, several pathways that are activated singly or in concert can allow cells to bypass senescence at least for limited periods. These include the telomerase pathway required to maintain telomere ends, the p53 and Rb pathways required to direct senescence in response to DNA damage, telomere shortening and mitogenic signals, and the insulin-like growth factor--Akt pathway that may regulate lifespan and cell proliferation. In this review, we summarize recent findings related to these pathways in embryonic stem (ES) cells and suggest that ES cells are immortal because these pathways are tightly regulated.     

Intermediate filament expression and lifespan potential in human somatic cell hybrids

Summary Limited lifespan human diploid fibroblast cells have been fused with the HeLa derived cell line HEB 7A which possesses transformed growth characteristics and unlimited division potential. HEB 7A expresses keratin intermediate filaments, while the fibroblast cells express only vimentin intermediate filaments. Independently arising clones of hybrids were examined for the presence of keratin by indirect immunofluorescence. Of 11 limited lifespan hybrids, all were keratin negative and possessed the growth characteristics of the fibroblast parent. Of 8 transformed hybrids, 6 arising early after fusion and 2 arising late, all were keratin-positive and simultaneously expressed the transformed growth characteristics of loss of density dependent growth inhibition, low serum dependence, and anchorage independence. It is concluded that the growth properties of these hybrids are associated with the type of intermediate filament expressed. The intermediate filament expression is therefore a marker of proliferative potential in these hybrids. This work was supported by grant no. AG 02664 from NIA (to C.L.B.) and by grant nos. 1R01 HD 18129-01 from NIH and PCM83-09068 from NSF (to R.H.S.). Editor’s Statement The tight correlation between the expression of the intermediate filaments of the immortal parent in hybrids of limited lifespan fibroblasts and HeLa cells with the transformed phenotype is of interest. It may offer important clues to the mechanism involved in cellular senescence. Gordon H. Sato     

Resilience to aging in the regeneration‐capable flatworm Macrostomum lignano

Animals show a large variability of lifespan, ranging from short‐lived as Caenorhabditis elegans to immortal as Hydra. A fascinating case is flatworms, in which reversal of aging by regeneration is proposed, yet conclusive evidence for this rejuvenation‐by‐regeneration hypothesis is lacking. We tested this hypothesis by inducing regeneration in the sexual free‐living flatworm Macrostomum lignano. We studied survival, fertility, morphology, and gene expression as a function of age. Here, we report that after regeneration, genes expressed in the germline are upregulated at all ages, but no signs of rejuvenation are observed. Instead, the animal appears to be substantially longer lived than previously appreciated, and genes expressed in stem cells are upregulated with age, while germline genes are downregulated. Remarkably, several genes with known beneficial effects on lifespan when overexpressed in mice and C. elegans are naturally upregulated with age in M. lignano, suggesting that molecular mechanism for offsetting negative consequences of aging has evolved in this animal. We therefore propose that M. lignano represents a novel powerful model for molecular studies of aging attenuation, and the identified aging gene expression patterns provide a valuable resource for further exploration of anti‐aging strategies.     

Generation of somatic cell hybrids for the production of biologically active factors that stimulate proliferation of other cells

OBJECTIVE: Some normal somatic cells in culture divide a limited number of times before entering a non-dividing state called replicative senescence and fusion of normal cells with immortal cells claimed to produce hybrid cells of limited proliferation. We reinvestigated the proliferative capacity of hybrid cells between normal cell and immortal cell. MATERIALS AND METHODS: Normal pig fibroblast cells and cells of immortal mouse fibroblast cell line F7, a derivative of GM05267, were fused by polyethylene glycol treatment and subsequently the fused cells were cultured in a selective medium containing hypoxanthine-aminopterin-thymidine in order to enrich the hybrid cells. The hybrid cells were then monitored for chromosome content and proliferation. RESULTS: Cytogenetic analysis revealed that the hybrid cells contained polyploidy chromosomes derived from normal pig fibroblasts. These hybrid cells exhibit no sign of replicative senescence after more than 190 population doublings in vitro. Instead, these hybrid cells have an accelerated growth and proliferate even in the complete absence of glutamine. In addition, these hybrids produce biologically active factors in the conditioned media, which not only can accelerate their own proliferation but also can reinitiate mitotic activity in the senescent-like normal fibroblast cells. CONCLUSIONS: Our results question the validity of cellular senescence as a dominant trait. Additionally, the generation of hybrid cells using the specific mouse cell line can be applied to the generation of hybrids with other normal cell types and can be used to produce tissue-specific growth-factor(s) to extend the lifespan and/or improve the proliferation of various normal cells, including adult stem cells.     

Telomere shortening associated with chromosome instability is arrested in immortal cells which express telomerase activity.

Loss of telomeric DNA during cell proliferation may play a role in ageing and cancer. Since telomeres permit complete replication of eukaryotic chromosomes and protect their ends from recombination, we have measured telomere length, telomerase activity and chromosome rearrangements in human cells before and after transformation with SV40 or Ad5. In all mortal populations, telomeres shortened by approximately 65 bp/generation during the lifespan of the cultures. When transformed cells reached crisis, the length of the telomeric TTAGGG repeats was only approximately 1.5 kbp and many dicentric chromosomes were observed. In immortal cells, telomere length and frequency of dicentric chromosomes stabilized after crisis. Telomerase activity was not detectable in control or extended lifespan populations but was present in immortal populations. These results suggest that chromosomes with short (TTAGGG)n tracts are recombinogenic, critically shortened telomeres may be incompatible with cell proliferation and stabilization of telomere length by telomerase may be required for immortalization.     

A novel human astrocyte cell line (A735) with astrocyte-specific neurotransmitter function

Summary Studies of brain cell function and physiology are hampered by the limited availability of imortal human brain-derived cell lines, as a result of the technical difficulties encountered in establishing immortal human cells in culture. In this study, we demonstrate the application of recombinant DNA vectors expressing SV40 T antigen for the development of immortal human cell cultures, with morphological, growth, and functional properties of astrocytes. Primary human astrocytes were transfected with the SV40 T antigen expression vectors, pSV3neo or p735.6, and cultures were established with an extended lifespan. One of these cultures gave rise to an immortal cell line, designated A735. All the human SV40-derived lines retained morphological features and growth properties of type 1 astrocytes. Immunohistochemical studies and Western blot analysis of the intermediate filament proteins and glutamine synthetase demonstrated a differentiated but immature astrocyte phenotype. Transport of γ-amino butyric acid and glutamate were examined and found to be by a glial-specific mechanism, consistent with the cell lines’ retaining aspects of normal glial function. We conclude that methods based on the use of SV40 T antigen can successfully immortalize human astrocytes, retaining key astrocyte functions, but T antigen-induced proliferation appeared to interfere with expression of glial fibrillary acidic protein. We believe A735 is the first documented nontumor-derived human glial cell line which is immortal.     

The effect of crowding on adult populations ofDelia (=Hylemya) antiqua (Meigen)

Using 5 density levels, the effect of increasing density was studied on several population statistics of adult Delia (=Hylemya) antiqua. Amongst the statistics studied were adult lifespan; female mating frequency, fecundity and egg hatchability. It was shown that females lived significantly longer than males and that increasing density significantly reduced lifespan. Density had no effect on mating frequency. Total fecundity/female was significantly reduced with increasing density but oviposition rate was density independent. Using these statistics, mean generation time T, net reproduction rate R₀ and capacity for increase r_c were calculated at the different density levels. Values of R₀ showed a one-tailed response but there was no clear effect of density on r_c. Multiple comparisons between variables revealed several important relationships.

1. Adult lifespan was the most important factor affecting egg production.
2. Number of mated females was more important in affecting total fecundity/cage than adult density.

It could also be calculated that to produce the effect of one single mated female on total fecundity/cage the overall density would have to be reduced by 0.0023 individuals/cm³. These results are discussed in the context of efficient laboratory rearing of the onion fly.     

Mechanisms responsible for the limited lifespan and immortal phenotypes in cultured mammalian cells

Normal mammalian cells have a limited lifespan in culture and hypotheses explaining cellular senescence usually fall into one of two categories. One of these postulates that random errors or damage accumulate in essential macromolecules and eventually outstrip the cell's capacity for resynthesis and repair. The second considers the changes when immortal clones are produced from normal cells and in particular the lifespans of hybrids when cells of differing growth potentials are fused. These data can be explained by postulating that the mortal phenotype is dominant and that trans-acting growth inhibitors are involved in limiting lifespan. But the results do not indicate if the inhibitors are the primary cause of senescence or a secondary effect induced by quite different initial events. We suggest that normal cells possess proof-reading mechanisms which monitor the accuracy of chromosome segregation and replication and which can induce the synthesis of growth inhibitors when they detect major errors in chromosome metabolism. It is further postulated that random damage accumulates during the growth of normal cells and eventually leads to detectable chromosome changes and the synthesis of inhibitors. Our hypothesis predicts that the emergence of immortal clones will be linked to the absence of active inhibitors and therefore to a loss in the fidelity of chromosome metabolism. Data are quoted which show that in contrast to normal cells, immortal clones have highly irregular karyotypes, amplify segments of their chromosomes, integrate exogenous DNA efficiently, maintain a constant level of 5-methylcytosine residues and have high frequencies of chromosomal aberrations. The mechanism of the proof-reading is unknown, but it may monitor changes in the patterns by which chromosome domains are attached to the nuclear matrix.     

A study of the effect of ultraviolet light on the division potential of human diploid fibroblasts

Culture and UV (254 nm) irradiation conditions that are suggested as appropriate for a study of the effect of UV on the limited in vitro lifespan of a normal human diploid fibroblast (HDF) strain are first described. An inoculation density at each subcultivation of 1.8 x 10(4) viable cells/cm-2 permits the decline in proliferative capacity to occur with kinetics similar to that observed using a 1:2 split and prevents cell overlap at the time of irradiation. Doses of 5 and 10 J/m2 have only a slight effect on initial growth rates and little or no effect on cell density achieved at confluence. With these conditions populations can be irradiated several times throughout the in vitro lifespan. No effect of UV on the limited division potential was observed. In the extreme, a population irradiated 14 times, once every second passage starting at P-18 with doses of 5 or 10 J/m2 had the same lifespan as controls, as measured by lifespan determinations and thymidine labeling index. Transformed cells were not detected in the multi-irradiated populations. Evidently no accumulation in the populations of damage induced by UV that affected life span, thymidine labeling index, growth rates or confluent cell densities occurred. No selection of a population with altered sensitivity occurred. An argument that genome hits may not be a prime reason for the limited proliferative capacity of HDF populations is presented.     

Molecular genetic approaches to the study of cellular senescence.

Normal cells in culture exhibit limited division potential, which is used as a model for cellular aging. In contrast, tumor-derived, carcinogen- or virus-transformed cells are capable of dividing indefinitely (immortal). Fusion of normal with immortal human cells yielded hybrids having limited life span, indicating that cellular senescence is a dominant phenotype and that immortality is recessive. Fusions of various immortal human cell lines with each other led to the identification of four complementation groups for indefinite division. In order to identify the chromosomes and genes involved in growth regulation, that had been modified in immortal cells, we used the technique of microcell fusion to introduce either a normal human chromosome 11 or 4 into cell lines representative of the different complementation groups. Chromosome 11 had no effect on the in vitro life span of the different immortal human tumor lines. However, when a normal human chromosome 4 was introduced into cell lines assigned to complementation group B, the cells lost the immortal phenotype. No effect on the proliferation potential of cell lines representative of the other complementation groups was observed. These results suggest that a gene(s) on human chromosome 4 has been modified in immortal cell lines assigned to complementation group B, to allow escape from senescence. They also provide evidence for a genetic basis for cellular aging.     

Sex differences in telomeres and lifespan in Soay sheep: From the beginning to the end

There is tremendous diversity in ageing rates and lifespan not only among taxa but within species, and particularly between the sexes. Women often live longer than men, and considerable research on this topic has revealed some of the potential biological, psychological and cultural causes of sex differences in human ageing and lifespan. However, sex differences in lifespan are widespread in nonhuman animals suggesting biology plays a prominent role in variation in ageing and lifespan. Recently, evolutionary biologists have borrowed techniques from biomedicine to identify whether similar mechanisms causing or contributing to variation in ageing and lifespan in humans and laboratory animals also operate in wild animals. Telomeres are repetitive noncoding DNA sequences capping the ends of chromosomes that are important for chromosomal stability but that can shorten during normal cell division and exposure to stress. Telomere shortening is hypothesized to directly contribute to the ageing process as once telomeres shorten to some length, the cells stop dividing and die. Men tend to have shorter telomeres and faster rates of telomere attrition with age than women, suggesting one possible biological cause of sex differences in lifespan. In this issue of Molecular Ecology, Watson et al. ( 2017 ) show that telomere lengths in wild Soay sheep are similar between females and males near the beginning of life but quickly diverge with age because males but not females showed reduced telomere lengths at older ages. The authors further show that some of the observed sex difference in telomere lengths in old age may be due to male investment in horn growth earlier in life, suggesting that sexually dimorphic allocation to traits involved in sexual selection might underlie sex differences in telomere attrition. This study provides a rare example of how biological mechanisms potentially contributing to sex differences in lifespan in humans may also operate in free‐living animals. However, future studies using a longitudinal approach are necessary to confirm these observations and identify the ultimate and proximate causes of any sex differences in telomere lengths. Collaborations between evolutionary biologists and gerontologists are especially needed to identify whether telomere lengths have a causal role in ageing, particularly in natural conditions, and whether this directly contributes to sex differences in lifespan.     

Limited lifespan in somatic cell hybrids and cybrids

The transformed phenotype is believed to be dominant in fusions between limited lifespan cells and transformed cells, based on heterokaryon experiments and on the isolation of transformed hybrids from mass cultures of fused cells. A series of fusions has been performed between limited lifespan Lesch-Nyhan fibroblast cells and a permanent HeLa cell line with a complementary genetic marker. The growth of independently isolated hybrid clones was followed in parallel with Lesch-Nyhan cells. In fusions involving Lesch-Nyhan cells which had completed about 50% of their lifespan, all hybrids initially show fibroblastic properties. Thirty-five hybrids had a limited lifespan slightly longer than Lesch-Nyhan controls. Three other hybrid clones, and all mass cultures of hybrids, showed the appearance of transformed colonies at a rate of approx. one transformant in 2 × 10₅ hybrid cells. These transformed cells showed anchorage independence, low serum requirement, chromosome loss, and have been maintained in culture for 50–100 population doublings with no signs of senescence. Fusions involving enucleated HeLa cells did not show transformation. Fusions with senescent Lesch-Nyhan cells yielded hybrids which grew beyond the normal Lesch-Nyhan cell lifespan, but which again showed limited lifespan and low frequency transformation. It is concluded that limited lifespan is expressed in a dominant manner in these fusions, and that transformation or “escape from senescence” is a low frequency event requiring the presence of the HeLa nucleus.     

Termination of lifespan of SV40-transformed human fibroblasts in crisis is due to apoptosis

Normal human fibroblasts in culture have a limited lifespan, ending in replicative senescence. Introduction of SV40 sequences encoding large T antigen and small t antigen into pre-senescent cells results in an extension of lifespan for an additional 20-30 population doublings. Rare clones of SV40-transformed cells are capable of indefinite growth and are described as immortal; however, the great majority of SV40-transformed cells terminate this extended lifespan in cell death, termed "crisis." We have examined the properties of cells in crisis to obtain further insights into mechanism of cell death and immortalization. Populations at the terminal cell passage show a balance between cell replication and cell death over a period of several weeks, with a progressive increase in cells undergoing cell death. During this period, there is less than a 3-fold increase in attached cell number, with two stages being identifiable on the basis of the focal pattern of cell survival. We also demonstrate that cells in crisis are undergoing apoptosis based on TUNEL assay, subG1 DNA content, annexin V reactivity, and activation of caspases 3 and 8. We suggest a model whereby SV40-transformed cells acquire increased sensitivity to apoptosis based on changes in properties which activate caspase 8 in addition to changes previously described involving shortening of telomeric sequences. While only telomere stabilization could be clearly shown to be essential for survival of cells through crisis, the extended period of cell replication and altered gene expression observed in SV40-transformed cells during crisis are compatible with other genetic alterations in immortal cells.     

Mitochondrial thioredoxin reductase 2 is elevated in long‐lived primate as well as rodent species and extends fly mean lifespan

In a survey of enzymes related to protein oxidation and cellular redox state, we found activity of the redox enzyme thioredoxin reductase (TXNRD) to be elevated in cells from long‐lived species of rodents, primates, and birds. Elevated TXNRD activity in long‐lived species reflected increases in the mitochondrial form, TXNRD2, rather than the cytosolic forms TXNRD1 and TXNRD3. Analysis of published RNA‐Seq data showed elevated TXNRD2 mRNA in multiple organs of longer‐lived primates, suggesting that the phenomenon is not limited to skin‐derived fibroblasts. Elevation of TXNRD2 activity and protein levels was also noted in liver of three different long‐lived mutant mice, and in normal male mice treated with a drug that extends lifespan in males. Overexpression of mitochondrial TXNRD2 in Drosophila melanogaster extended median (but not maximum) lifespan in female flies with a small lifespan extension in males; in contrast, overexpression of the cytosolic form, TXNRD1, did not produce a lifespan extension.