Effect of low dose rate irradiation on the division potential of cells in vitro. VI. Changes in DNA and in radiosensitivity during aging of human fobroblasts

Enzymatic shot-gun 5'-phosphorylation and 3'-sister phosphate exchange: a two-dimensional thin-layer chromatographic technique to measure DNA deoxynucleotide modification

DNA adducts occur through environmental, therapeutic, dietary, oxygen stress, and aging processes. A modified thin-layer chromatographic (TLC) technique can asses base composition and adduct formation. This requires labeling DNA by "shot-gun" 5'-phosphorylation of representative 32P-alpha-deoxyribonucleotide monophosphates. Subsequent 3'-monophosphate digest "sister exchanges" a radioactive 32PO4(2-) to the neighboring cold nucleotide. Separation in two-dimensional polyethyleneimine-cellulose TLC is carried out in acetic acid, (NH4)2SO4, and (NH4)HSO4. The technique was applied to control DNA, cold substitution of dUMP, methylation, depurination, and pBR322. This technique quantifies low-molecular-mass adducts and DNA integrity both in vivo and in vitro.

Effects of mutagens on the clonal lifespan of Paramecium tetraurelia

There has been interest in the phenomenon that a cell cannot undergo unlimited reproduction under adequate conditions and undergoes senescence. In holotrichous ciliates, Paramecium has a limit of vegetative reproduction without sexual reproduction but Tetrahymena does not always have a limited lifespan. Comparing the two species would increase our knowledge of the mechanism of cellular clonal aging. We previously showed that mutations induced by X-rays shorten clonal lifespan. In this study, we examined whether mutagens shorten the clonal lifespan of Paramecium tetraurelia. P. tetraurelia was exposed to the alkylating agent N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), 0.045 mg/ml, for 30 min. The animal was exposed to MNNG 6 times in total while young (under 80 divisions from the start of a clonal life cycle) or 4 times during the senescent stage. MNNG shortened the clonal lifespan as expressed by the decrease in fission number from 186 +/- 55 (4 cell lines) to 136 +/- 21 (6 cell lines) with the first two treatments but with further exposures the lifespan increased to 182 +/- 15 (5 cell lines). MNNG had no effect when administered at the older age. Exposure of P. tetraurelia to 4-nitroquinoline-N-oxide at 0.021 mg/ml twice for 12 and 15 min at the younger age reduced the mean clonal lifespan from 143 +/- 28 to 125 +/- 21 and the maximum lifespan from 263 +/- 33 to 175 +/- 25.

Altered cellular responsiveness during ageing

The capacity of cells and organisms to respond to external stimuli and to maintain stability in order to survive decreases progressively during ageing. The mitogenic and stimulatory effects of growth factors, hormones and other agents are reduced significantly during cellular ageing. The sensitivity of ageing cells to toxic agents including antibiotics, phorbol esters, radiations and heat shock increases. This failure of homeostasis during cellular ageing does not appear to be due to any quantitative and qualitative defects in the receptor systems. Instead, metabolic defects in the pathways of macromolecular synthesis may be the basis of altered cellular responsiveness during ageing.

Homoeostatic imbalance during cellular ageing: altered responsiveness

The inability of normal cells to maintain themselves for ever is a reflection of homoeostatic imbalance and a progressive failure of maintenance. Ageing cells respond less to growth stimulants whereas they show increased sensitivity to toxic agents including antibiotics, phorbol esters, radiation and other physical stresses. No major quantitative and qualitative defects in the receptor systems have been detected that could explain the reasons for altered responsiveness during ageing. Random metabolic defects in the processes involved in maintaining homoeostasis may be critical for causing homoeostatic imbalance, cellular ageing and death.

Chromatin reorganization during senescence of proliferating cells

It was previously proposed (Macieira-Coelho, 1979) that aging of proliferating cells is the result of genome reorganization taking place during the division cycle. This hypothesis was investigated and a reorganization could indeed be ascertained in the different hierarchical orders of DNA structure; a correlation was found between changes in chromatin organization and the impairment of cell cycle-related events. Indeed, like the latter, the reorganization of chromatin structure is characterized by a succession of subtle changes through the cell population life span, and a final short stage with abrupt events. The final events seem to concern mainly the organization of heterochromatin. The reorganization in the genome is accompanied by structural changes in the cellular scaffold and an evolution of cell morphology. The remodeling occurring in the cell through serial divisions seems to take place in such a way as to decrease the probability of further reorganizations, tending to a limit. The decline of the proliferative activity seems to be the result of the tendency to reach this limit.

A re-examination of the effects of ionizing radiation on lifespan and transformation of human diploid fibroblasts

Human diploid fibroblasts, strain MRC-5, were sequentially irradiated with 60Co gamma rays at intervals during their in vitro lifespan. The results indicate that 3 or 6 doses of 1 Gy can increase lifespan, and the same was true for cells treated with 3 doses of 3 Gy. Higher doses (5 x 3 Gy) did reduce growth potential, suggesting either that mid-late passage cells become more sensitive to radiation, or that doses beyond a given threshold reduce population lifespan by multiple cellular hits. The life extension induced by gamma rays might be due to an induced hypermethylation of DNA. Alternatively, oxygen radicals produced by irradiation might trigger an adaptive stress response which would remove damaged macromolecules and thereby increase the cells' growth potential. Whichever explanation is correct, the results show that the human fibroblast system is not appropriate for the study of the well known effect of ionizing radiation in shortening the lifespan of experimental animals. Contrary to earlier published results, populations of cells treated with cumulative doses of 15 Gy or 18 Gy and held for nearly 3 months after they had reached senescence (Phase III), produced no foci of transformed cells.

Decline of poly(ADP-ribosyl)ation during in vitro senescence in human diploid fibroblasts

Poly(ADP-ribose) polymerase activity was determined at various times during the in vitro life span of two human diploid fibroblast-like cell lines of different donor ages. The cell lines differed in their ability to transfer ADP-ribose, with cells from an embryonic donor exhibiting 2 to 3 times the activity found in cells obtained from a newborn donor. The activity in both cell lines decreased by 30-60% as the cells moved through their in vitro life spans. The decline could not be attributed to increases in glycohydrolase or the leakage of polymerase from older cell preparations. Enzyme activation with DNase I indicated that similar levels of enzyme were present in both cell lines at all in vitro ages. These results indicate that although poly(ADP-ribosyl)ation is inversely related to donor age as well as in vitro age the decrease is in response to other factors which change with increasing age.

Chromatin and nucleolar changes in Xeroderma pigmentosum cells resemble aging-related nuclear events

Xeroderma pigmentosum (XP) is a hereditary disease characterized by a defect in the excision-repair mode of ultraviolet light damage and a high incidence of skin tumors. Cultured fibroblasts from normal and XP cells at low population doubling times were compared by induction of mild spreading of their nuclear constituents in a highly alkaline solution containing detergent and formaldehyde. In each XP culture a certain fraction (10-80%) of the nuclei were abnormal (50-80% in cell lines from children with XP-C disorders and 10-35% from embryonic and adult XP cells). Although their chromatin threads appeared normal in structure, they were separated by intervals up to 5 times the normal spacing. In all XP cells having this abnormal spacing in the chromatin, fibrils of nucleolar origin were approximately doubled in thickness, denser and less tufted, and nucleolar granules were few and dispersed. We suggest that this study reveals an abnormal weakness of the chromatin in some XP cells which results in the breakage of some DNA fibers in our preparative alkaline conditions. This weakness may be related to single-stranded breaks induced by metabolism of a high level of active oxygen species. These nuclear changes in XP cells are similar to those which have been associated with normal or pathologic senescence.

No change in DNA damage or repair of single- and double-strand breaks as human diploid fibroblasts age in vitro

Using the in vitro human diploid fibroblast model, we tested theories of aging which hypothesize that either accumulation of DNA damage or decreased DNA repair capacity is causally related to cellular senescence. Between population doubling level (PDL) 32 and 71, fetal lung-derived normal diploid human fibroblasts (IMR 90) were assayed for both DNA single-strand breaks (SSBs, spontaneous and induced by 6 Gy) and DNA double-strand breaks (DSBs, spontaneous and induced by 100 Gy). After gamma-irradiation cells were kept on ice unless undergoing repair incubation at 37 degrees C for 7.5-120 min or 18-24 h. To assay DNA strand breaks we used the filter elution technique in conjunction with a fluorometric determination of DNA which is not biased in favor of proliferating aging cells as are radioactive labelling methods. We found no change with in vitro age in the accumulation of spontaneous SSBs or DSBs, nor in the kinetics or completeness of DNA strand rejoining after gamma-irradiation. Cells at varying PDLs rejoined approx. 90% of SSBs and DSBs after 60 min repair incubation and 100% after 18-24 h repair incubation. We conclude that aging and senescence as measured by proliferative lifespan in IMR 90 cells are neither accompanied nor caused by accumulation of DNA strand breaks or by diminished capacity to rejoin gamma-radiation-induced SSBs or DSBs in DNA.

Genome reorganization during aging of dividing cells

The study of the effect of low dose rate ionizing radiation on the long-term proliferation of fibroblasts led to the observation that radiation accentuated the growth potential of the cells, favoring events which normally take place during division. These events could be related to the genome reorganization taking place during division. Hence, it was hypothesized (Macieira-Coelho, 1979; Macieira-Coelho, 1980; Macieira-Coelho, 1981) that the long-term proliferation of fibroblasts depends upon the potential for reorganization of the genome, the latter being a self-limiting process. At each division residual quantitative and qualitative changes would accumulate in chromatin, limiting the long-term potential for further rearrangements. The hypothesis was checked looking for quantitative and qualitative changes in DNA through the in vitro lifespan of human fibroblast populations. It was found that at each population doubling in 20% of the cells there is unequal distribution of DNA between sister cells. Results show that this could be due to errors in chromosome assembly and segregation, to loss of DNA, to errors during semiconservative DNA synthesis and to multiple rounds of DNA replication at a single origin. An increased alkali- and thermo-lability of chromatin was found during in vitro aging. At the ultrastructural level after mild decondensation, chromatin fibers were spaced and shorter. After Miller's spreading, most of the chromatin of old cells had lost the nucleosome organization and was fragmented. These chromatin changes became apparent only towards the end of the life span of human embryonic fibroblasts but were already present in a significant fraction of low population doubling level (PDL) fibroblasts from human adults. Almost all cells of low-PDL fibroblasts from the Werner syndrome presented these chromatin changes. In addition, short, unbeaded DNA fragments could be seen in these fibroblasts, occasionally forming circles; they could correspond to transposable elements which detach during the division cycle and fail to reintegrate into chromosomes because of the age-related chromatin structural changes.

Chromatin structure, DNA synthesis and transcription through the lifespan of human embryonic lung fibroblasts

The presence in terminal embryonic fibroblasts of small molecular weight (MW) DNA independent of bulk DNA could be ascertained by three different techniques performed in parallel. This alteration was not artifactually induced, either by high pH and the detergent used or by the release of cellular enzymes. An increased thermolability of old chromatin was also observed. Cells with altered chromatin synthesized DNA and RNA according to a pattern similar to young type nuclei. Long-term treatment with hydrocortisone significantly increased the cell yield but did not prevent, in the late passages, the occurrence of old-type chromatin; the nucleolar filamentous masses, however, maintained a 'young' pattern. Short-term treatment induced only a moderate reversion in the appearance of chromatin lesions. Direct evidence was obtained of increased gene expression in the presence of hydrocortisone.

SV40 immortalization of adult human mesenchymal cells from neuroretina. Biological, functional and molecular characterization

Human adult mesenchymal cells from neuroretina (human choroid cells, HC) have acquired an infinite lifespan, following phenotypic transformation with a wild-type SV40. Immortalized cells (HC/SV40) contain high numbers of free circular viral DNA, and integrated molecules in a head-to-tail array in the cellular DNA. HC/SV40 cells express both the virus-coded "T" antigens and the cell-coded p53 transformation-associated protein. The transformed phenotype was further characterized by loss of contact inhibition of cell division, inability to induce the retraction of a fibrin clot and to spread within fibrin, and the existence of an altered distribution of actin cables. For the first time we also describe a coupling of the immunofluorescence and the quantitative cytofluorometric analyses, a new transformation parameter, since we show that SV40 transformation causes reorganization of the cell membrane by inducing the unmasking of the antigen recognized by the 4F2 monoclonal antibody, which is present in a "cryptic" form in the untransformed cells. Though the HC/SV40 cells have been continuously passaged over a 3-year period, they have not yet achieved a fully malignant phenotype, since they retain serum-dependency and the presence of a well developed fibronectin pericellular network, and they are not tumorigenic in nude mice. Thus this human immortal cell line constitutes a very useful tool for studying the progression toward full malignancy and the relationships between evolution of transformation parameters and changes in the viral and cellular genome interplay.

Chromatin organization and transcriptional activity in human embryonic lung fibroblasts aged in vitro

Chromatin organization was examined in confluent cultures of embryonic lung fibroblasts in the middle and at the end of their replicative lifespan. Age-related modifications resulted in an unusually wide spacing of the chromatin threads induced by a mild loosening treatment and an increased sensitivity of the nucleosomes to the Joy-containing hypotonic medium used in Miller's spreads. The profound changes in chromatin response to various hypotonic solutions were not associated with the disappearance of RNA synthesis in old type nuclei as demonstrated by high-resolution autoradiographical studies.

A re-evaluation of the changes in proliferation in human fibroblasts during ageing in vitro

Previously published studies concerning the proliferative changes, during ageing in vitro, of human embryonic fibroblasts, have been reappraised. The data suggest that the changes occur through shifts in a whole spectrum of cells between two extremes: complete inhibition and a normal division cycle. Reversion from the non-dividing to the dividing state becomes increasingly difficult and random. Ageing is the result of a long chain of events that hinder the transit of cells through the division cycle, mainly through interference with the G1 but also with the G2 period. Some metabolic events at the very end of the lifespan could support the terminal differentiation hypothesis.

Distribution of DNA between sister cells during serial subcultivation of human fibroblasts

The segregation of DNA at the time of cell division was analysed by measuring the DNA contents of cells in mitosis and the incorporation of tritiated thymidine (3H-TdR) on each half of anaphases and telophases. Results suggest that the spreads in the 2C and 4C DNA contents are due to quantitative differences which could originate during semi-conservative DNA synthesis, chromosome assembly and chromosome segregation. This continuous rearrangement of the genome could lead either to a degenerative process or to a differentiation program.

Cellular and molecular aspects of immune system aging

We begin with a brief discussion of the importance and advantages of immune studies to the problem of aging. This is followed by a short over-view of immune system aging at the systemic level. The major portion of the article is a review of observation, both at the cellular and molecular level, of changes in aging immune cells, with sections on intercellular communication, membrane phenomena, cyclic nucleotides, and molecular genetic changes.