Aging under glass

Cell senescence: role in aging and age-related diseases

Cell senescence is one of the major paradigms of aging research. It started with the demonstration by L. Hayflick of the limited number of divisions by normal, nontransformed cells, not shown by transformed malignant cells, this processes being largely regulated by the telomere-telomerase system. A complete renewal of this discipline came from the demonstration that cells can enter senescence at any time by an anti-oncogene-triggered pathway, enabling them to escape malignancy. The senescent cell became a major actor of the aging process, among others, by the acquisition of the senescence-associated secretory phenotype. This chapter is devoted to the regulatory process involved in the acquisition of the senescent cell phenotype and its role in organismal aging.

Age-related adaptation of bone-PDL-tooth complex: Rattus-Norvegicus as a model system

Functional loads on an organ induce tissue adaptations by converting mechanical energy into chemical energy at a cell-level. The transducing capacity of cells alters physico-chemical properties of tissues, developing a positive feedback commonly recognized as the form-function relationship. In this study, organ and tissue adaptations were mapped in the bone-tooth complex by identifying and correlating biomolecular expressions to physico-chemical properties in rats from 1.5 to 15 months. However, future research using hard and soft chow over relevant age groups would decouple the function related effects from aging affects. Progressive curvature in the distal root with increased root resorption was observed using micro X-ray computed tomography. Resorption was correlated to the increased activity of multinucleated osteoclasts on the distal side of the molars until 6 months using tartrate resistant acid phosphatase (TRAP). Interestingly, mononucleated TRAP positive cells within PDL vasculature were observed in older rats. Higher levels of glycosaminoglycans were identified at PDL-bone and PDL-cementum entheses using alcian blue stain. Decreasing biochemical gradients from coronal to apical zones, specifically biomolecules that can induce osteogenic (biglycan) and fibrogenic (fibromodulin, decorin) phenotypes, and PDL-specific negative regulator of mineralization (asporin) were observed using immunohistochemistry. Heterogeneous distribution of Ca and P in alveolar bone, and relatively lower contents at the entheses, were observed using energy dispersive X-ray analysis. No correlation between age and microhardness of alveolar bone (0.7 ± 0.1 to 0.9 ± 0.2 GPa) and cementum (0.6 ± 0.1 to 0.8 ± 0.3 GPa) was observed using a microindenter. However, hardness of cementum and alveolar bone at any given age were significantly different (P<0.05). These observations should be taken into account as baseline parameters, during development (1.5 to 4 months), growth (4 to 10 months), followed by a senescent phase (10 to 15 months), from which deviations due to experimentally induced perturbations can be effectively investigated.

Biology and Evolution of Aging: Implications for Basic Gerontological Health Research

The maximum lifespan of different animal species is genetically determined. Many biochemical and physiological systems which influence longevity have apparently evolved to regulate growth and development in a way which maximizes fitness given the ecological niche and constraints on the species. The diversity of individual genetic effects on aging makes it unlikely that either extrinsic factors such as nutrition and medicine or genetic intervention will have dramatic effects on the maximum lifespan of a species, in spite of significant qualitative effects on individuals. However, understanding the fundamental genetic determinants of senescence may be of particular importance to the treatment and or prevention of age associated problems involving tissue degeneration and/or cancer. Considerable investment in basic biological research on both aging and developmental processes is needed before this understanding can be achieved.

Proliferation of CD8+ in culture of human T cells derived from peripheral blood of adult donors and cord blood of newborns

As during replicative senescence either in vivo or in vitro, the growing up subpopulation of CD8+CD28- cells is observed, we compared replicative senescence of T cells derived from mononuclear cells of peripheral blood (PBMC) of adults with those from cord blood (CBMC), not having yet CD8+CD28- subpopulation. In PHA-stimulated and IL-2-dependent cultures, T cells from both cord blood and peripheral blood of young adults displayed similar pattern of replicative senescence characterised by gradual decrease of proliferation capacity (assessed by CFSE assay) and reduction of CD28+ subpopulation of CD8+ cells. We were also interested whether CD8+CD28- were just progeny of CD28+ cells or if they were able to proliferate by themselves. After PHA stimulation of cells from adult donors at different ages, including centenarians, the transient up-regulation of CD28+ was observed. In CBMC and PBMC from young donors, the entire CD28+ subpopulation entered the cell cycle. In PBMC, from the majority of middle-aged subjects and all centenarians both CD28+ and CD28- were proliferating. All together we can conclude that in vitro CD8+CD28- are the progeny of both CD8+CD28+ and CD8+CD28- subpopulations.

Age dependency of neointima formation on vascular prostheses in dogs

Neointima formed quickly on vascular prostheses implanted in young dogs but not in aged dogs. Previously, we found that impeding neointima formation on vascular prostheses occurred more frequently in aged animals. From these observations, we hypothesized that neointima formation was age-dependent in dogs. To test the hypothesis, 26 fabric Dacron vascular prostheses were analyzed. Half of them were retrieved from aged dogs (more than 13 years old) while the other half were from young ones (less than 1 year old). The grafts were harvested at 8 weeks and 3 months after implantation. The graft surfaces were photographed and analyzed by computer for the ratio of the areas with and without thrombus. Light and scanning electron microscopic observation revealed that most of the thrombus-free areas were lined with endothelial cells. Then the endothelialized areas were calculated. Using data obtained from macroscopic, light microscopic, and scanning electron microscopic observations, the arithmetic means were calculated as the degree of neointima formation. In young animals, the degrees at 8 weeks and at 3 months were 89.1 +/- 8.5% (mean +/- SD) and 95.7 +/- 3.3%, respectively. In old animals, they were 27.9 +/- 5.9% and 31.5 +/- 6. 8%, respectively. From these results, we concluded that neointima formation was age-dependent in dogs.

Cataloging altered gene expression in young and senescent cells using enhanced differential display

Recently, a novel PCR-based technique, differential display (DD), has facilitated the study of differentially expressed genes at the mRNA level. We report here an improved version of DD, which we call Enhanced Differential Display (EDD). We have modified the technique to enhance reproducibility and to facilitate sequencing and cloning. Using EDD, we have generated and verified a catalog of genes that are differentially expressed between young and senescent human diploid fibroblasts (HDF). From 168 genetags that were identified initially, 84 could be sequenced directly from PCR amplified bands. These sequences represent 27 known genes and 37 novel genes. By Northern blot analysis we have confirmed the differential expression of a total of 23 genes (12 known, 11 novel), while 19 (seven known, 12 novel) did not show differential expression. Several of the known genes were previously observed by others to be differentially expressed between young and senescent fibroblasts, thereby validating the technique.

Predicting Age from Body Measurements and Observations

From 51 body measurements and two qualitative observations on 600 men ranging in age from the third to the eighth decade of life (mean age, 43 years), sixteen measurements plus grayness of hair and baldness were entered into a multiple-regression equation to predict chronologic age. Ten variables gave an R of 0.77, predicting age with a standard error of estimate 5.88 years. The predictors, in order of their contribution, were grayness of hair (r = 0.64), hand grip, ear breadth and length, sitting height, nose breadth, bideltoid breadth, abdominal depth, triceps skinfold, and baldness. Eight variables did not contribute significantly: height, weight, chest depth and expansion, bi-iliac breadth, upper arm and calf circumferences, and nose length. Functional traits predicted age more closely than did gross body dimensions.

Molecular biology of aging

Aging is an extremely complex biologic phenomenon of immense importance. Currently we have only a poor and incomplete understanding of the fundamental molecular mechanisms involved. Despite numerous observations and diverse theories, no unifying or proven hypotheses have emerged. It is reasonable to conclude, however, that aging is a multifactorial process composed of both genetic and environmental components. Each physiologic system within an organism, each tissue within a system, and each cell type with a tissue appears to have its own trajectory of aging. Thus, aging must be studied as parts of a whole and understood as the sum of its parts. Cellular "clocks" exist and operate in the absence of higher-order "clocks". However, higher-order clocks are certainly in place in vivo, but their relationship to cellular clocks is not well understood. All aging changes have a cellular basis, and aging is perhaps best studied, fundamentally, at the cellular level under defined and controlled environmental conditions. Aging changes at the cellular level must be viewed, however, as components of a hierarchical, dynamic, and interacting network whose functional integrity progressively deteriorates with time. The powerful tools of molecular biology are now being applied by scientists to evaluate the leading hypotheses. The results of these studies should serve to advance our understanding of aging and to focus future research efforts. This work should provide the scientific foundation to enhance the quality of life for people suffering the failings of age.

The cultured diploid fibroblast as a model for the study of cellular aging

The limited proliferative potential of the cultured human diploid fibroblast is now well established. A number of biological correlates suggest that this culture system is a model for the study of aging at the cellular level. The mechanism(s) that causes the loss of proliferative activity is unknown; the results of some recent studies indicate that specific genes may play a pivotal role in cellular aging in vitro. The extent to which changes in proliferative functions are causally related to aging in vivo is currently under investigation.

Telomere loss: mitotic clock or genetic time bomb?

The Holy Grail of gerontologists investigating cellular senescence is the mechanism responsible for the finite proliferative capacity of somatic cells. In 1973, Olovnikov proposed that cells lose a small amount of DNA following each round of replication due to the inability of DNA polymerase to fully replicate chromosome ends (telomeres) and that eventually a critical deletion causes cell death. Recent observations showing that telomeres of human somatic cells act as a mitotic clock, shortening with age both in vitro and in vivo in a replication dependent manner, support this theory's premise. In addition, since telomeres stabilize chromosome ends against recombination, their loss could explain the increased frequency of dicentric chromosomes observed in late passage (senescent) fibroblasts and provide a checkpoint for regulated cell cycle exit. Sperm telomeres are longer than somatic telomeres and are maintained with age, suggesting that germ line cells may express telomerase, the ribonucleoprotein enzyme known to maintain telomere length in immortal unicellular eukaryotes. As predicted, telomerase activity has been found in immortal, transformed human cells and tumour cell lines, but not in normal somatic cells. Telomerase activation may be a late, obligate event in immortalization since many transformed cells and tumour tissues have critically short telomeres. Thus, telomere length and telomerase activity appear to be markers of the replicative history and proliferative potential of cells; the intriguing possibility remains that telomere loss is a genetic time bomb and hence causally involved in cell senescence and immortalization.

Effects of donor age on osteogenic cells of rat bone marrow in vitro

The effect of donor age on the production of bone-like tissue and expression of cellular alkaline phosphatase was examined in cultures of cells obtained from rat bone marrow. Stromal cells were obtained from the bone marrow of young (5-6 weeks) and old (18 months) rats and cultured in vitro. After 28 days in first subculture, the following were quantified: (1) the total number of mineralised nodules and the size distribution of nodules and (2) the density of osteoblasts and osteocytes associated with nodules in histological sections. The doubling times of the cultures and the numbers of cells in cultures which expressed alkaline phosphatase activity were determined in separate experiments. Cells from young cultures produced three times more bone-like nodules than old cultures, although no differences were seen in the size distribution of nodules, or on osteoblast and osteocyte density. Doubling times for both groups were similar. The numbers of alkaline phosphatase (AP) positive cells was reduced by half in old cultures. These data show that this model may be useful for the study of the mechanisms of ageing on osteogenesis, and demonstrate a reduced osteogenic capacity in old cultures. The results suggest that this effect may be due to a reduction in the generation of cells of osteoblast lineage during ageing.

Protein Turnover During Aging of Cultured Human Fibroblasts

Les cellules qui vieillissentin vitroou bien celles qui sont prélevées de donneurs d'àge avancé ou de sujets manifestant certaines des particularités qui s'apparentent à un vieillissement accéléré (progérie ou le syndrome de Werner), peuvent être qualifiées de 'vieilles'. Celles-ci on des taux de croissance ralentis en milieu de culture si on les compare aux cellules nouvelles ou à mi-passage prélevées de jeunes donneurs normaux. Durant la croissance exponentielle, les taux de constantes pour la synthèse protéique dans les jeunes cellules ne sont pas significativement différents de ceux retrouvés dans les vieilles cellules (0.023 ± 0.002h1vs. 0.021 ± 0.002h1respectivement) et pourtant les taux de croissance (i.e. accrétion protéique) sont de seulement 0.013±0.003h1dans les vieilles cellules comparés à 0.022±0.002h1dans les jeunes cellules. Done, le taux ralenti d'accumulation protéique durant la croissance des vieilles cellules comparé aux jeunes cellules est associé à une dégradation protéique accélérée (0.01±0.002h1vs 0.001 ±0.002h1;P<0.05) plutôt qu'à des taux ralentis de synthèse protéique. Lorsque les cellules deviennent quiescentes suivant une période d'inhibition de croissance due à la densité, les taux de synthèse protéique diminuent dans les jeunes et les vieilles cellules pour aboutir à des niveaux comparables (0.013±0.002h1) où les taux de croissance (0.003±0.0003h1) et de dégradation (0.01±0.003h1) ne sont significativement pas differents dans les deux groupes. Done, ce n'est qu'en période de croissance exponentielle qu'une différence dans le turn-over protéique entre jeunes et vieilles cellules est observée, alors que la dégradation est accélérée dans les vieilles cellules. La relation causale entre la dégradation protéique accélérée et les taux de croissance ralentis dans les vieilles cellules demeure inconnue.

Aging of the extracellular matrix and its pathology

Recent concepts on the mechanisms of aging of extracellular matrix (EM) are reviewed as well as its involvement in age-associated diseases. Cell differentiation, histogenesis and organogenesis can be analyzed in terms of the program of the biosynthesis of EM macromolecules during development, maturation and aging. The most important biological role of EM is the integration of cells in tissues, of tissues in organs and of organs in the whole organism. EM can directly influence cell behavior through the contact between EM and the genome mediated by structural glycoproteins (fibronectin, laminin, elastonectin, etc.) interacting with other EM macromolecules (collagen, proteoglycans, elastin) and the cytoskeleton by trans-membrane receptors (integrins). Most age-associated diseases exhibit a deviation (qualitative or quantitative) from the normal program of EM biosynthesis. Three examples are analyzed in some detail: atherosclerosis, diabetes and malignant tumors. The degradation of elastic fibers catalyzed by cellular elastase-type enzymes is observed in atherosclerosis and also in emphysema and skin aging. Several of these enzymes were isolated and characterized from platelets, fibroblasts, smooth muscle cells and lipoproteins. The biosynthesis of some of them increases with age and facilitates cell migration. Plasma fibronectin increases with age exponentially. This increase is absent or strongly attenuated in diabetes and some cancers. Tissue fibronectin increases in diabetes, Werner syndrome and in the peritumoral desmoplastic reaction while most tumor cells can no more retain fibronectin on their membrane facilitating their movement in the organism. These examples demonstrate the importance of the study of cell matrix interactions for gerontology.

Effect of lead on fibroblasts taken from an 84-year-old donor

Human, diploid fibroblasts from an 84-year-old donor (AlPos) were used to study the effect of 20, 40 and 80 micrograms/100 ml concentrations of lead on in vitro senescence. The results showed that there was a significant decrease in the number of total population doublings due to the treatment with lead. However, there was no significant difference between the effects of the three concentrations of lead. As far as nucleolar number is concerned in the case of the controls as well as in the lead-treated cells the number remained constant with aging in vitro. When the areas and dry mass of cells, nuclei and nucleoli were examined in controls and lead-treated groups at early and late doublings the results showed that in general no significant changes were noted with the exception of the 40 micrograms/100 ml lead treatment which caused a significant increase in these parameters with aging in vitro. The results are discussed and compared to those from a previous study [17] in which embryonic, IMR-90 cells were treated in a similar way. It is concluded that the fibroblasts from the 84-year-old donor AlPos are even more vulnerable than the embryonic cells to the effects of lead as indicated by the drastic curtailment of the in vitro lifespan exhibited in the case of treatment even with the lowest concentration of lead.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

The effect of clinical and subclinical concentrations of lead on the in vitro aging of human fibroblasts

The effect of 20, 40 and 80 micrograms per 100 ml concentrations of lead on the in vitro senescence of fetal human diploid fibroblasts IMR-90 was determined. The areas and dry mass of the cell, nucleus and nucleolus were measured at early, middle and late passages. There was a decrease in total population doublings as the concentration of lead in the medium was increased. Although there was a decrease in the number of nucleoli per cell with successive doublings, there was no difference between controls and lead-treated cells. There was an increase in nucleolar dry mass as the cells aged and this was most noticeable in the 40- and 80-micrograms groups. There were no noteworthy changes in nuclear and cellular areas and dry mass with respect to lead treatment. The results are discussed and it is concluded that even subclinical concentrations of lead cause an acceleration of cellular aging in vitro.

Reactivation of DNA synthesis in aging diploid human skin fibroblasts by fusion with mouse L karyoplasts cytoplasts and whole L cells

Diploid human skin fibroblasts derived from an 82-year-old donor with a 21-28 cell population doubling (CPD) range (where 28 CPD marked the end of the in vitro life span of the cells) were fused with whole L cells, L karyoplasts and L cytoplasts. The proportion of human nuclei incorporating tritiated thymidine after fusion was measured autoradiographically. Statistically significant increases in the labeling indices were found in the human nuclei in hybrid, heterodikaryon and cybrid cells when compared to control unfused human cells. Fusion of human diploid fibroblasts with human cytoplast derived from cells of the same CPD showed no significant changes in the labeling indices of the human nuclei.

Recent advances in the cell biology of aging

Cultured normal human and animal cells are predestined to undergo irreversible functional decrements that mimic age changes in the whole organism. When normal human embryonic fibroblasts are cultured in vitro, 50 +/- 10 population doublings occur. This maximum potential is diminished in cells derived from older donors and appears to be inversely proportional to their age. The 50 population doubling limit can account for all cells produced during a lifetime. The limitation on doubling potential of cultured normal cells is also expressed in vivo when serial transplants are made. There may be a direct correlation between the mean maximum life spans of several species and the population doubling potential of their cultured cells. A plethora of functional decrements occurs in cultured normal cells as they approach their maximum division capability. Many of these decrements are similar to those occurring in intact animals as they age. We have concluded that these functional decrements expressed in vitro, rather than cessation of cell division, are the essential contributors to age changes in intact animals. Thus, the study of events leading to functional losses in cultured normal cells may provide useful insights into the biology of aging.

Aging, natural death, and the compression of morbidity

The average length of life has risen from 47 to 73 years in this century, but the maximum life span has not increased. Therefore, survival curves have assumed an ever more rectangular form. Eighty per cent of the years of life lost to nontraumatic, premature death have been eliminated, and most premature deaths are now due to the chronic diseases of the later years. Present data allow calculation of the ideal average life span, approximately 85 years. Chronic illness may presumably be postponed by changes in life style, and it has been shown that the physiologic and psychologic markers of aging may be modified. Thus, the average age at first infirmity can be raised, thereby making the morbidity curve more rectangular. Extension of adult vigor far into a fixed life span compresses the period of senescence near the end of life. Health-research strategies to improve the quality of life require careful study of the variability of the phenomena of aging and how they may be modified.

Evaluation of growth hormone production from GH1 cells in vitro: effect of culture media and time in culture

Growth hormone production by a rat pituitary tumor cell line (GH1) was measured during lag, exponential, and plateau phases of growth in different culture media. Growth hormone secretion was low during lag and early exponential phase; it increased late in the exponential phase and continued to increase during the plateau phase. This biphasic pattern of growth hormone production was observed in all media and sera utilized. Both the doubling time and growth hormone production were influenced by the choice of media and sera. In addition, the length of time in culture affected the growth fraction with passage level 40 GH1 cells having a 79% growth fraction, whereas the growth fraction of passage level 100 cells was 95%. Using the population doubling time as a criterion for a choice of medium, F-10 medium supplemented with 20% fetal bovine serum consistently yielded the most rapid doubling time (32 hr), whereas Dulbecco's MEM supplemented with 15% horse serum and 2.5% fetal bovine serum yielded the greatest plateau cell density. Growth hormone secretion and the population doubling times were directly related to culture conditions including length of time in culture, choice of tissue culture media, choice of sera, and the phase of cell growth (lag, exponential or plateau).

Multigene families, histocompatibility systems, transformation, meiosis, stem cells, and DNA repair

Aging is probably not directly traceable to changes along the whole genome, but to a small portion thereof. The main histocompatibility complex appears to be one among the postulated sets of multigene families responsible. The immortality of transformed cells, the germ line, and possibly certain pluripotential stem cells may suggest common qualitative and/or quantitative differences in DNA repair mechanisms between these cell populations and committed, normal cell populations. A relationship between HLA and at least two diseases showing defective DNA-repair suggests that the same chromosome carrying the main histocompatibility complex may control some repair processes. The correspondence of variation in lifespans in different mouse strains with the DNA repair capabilities and degrees of autoimmune susceptibility of the same strains lends further support to the idea that DNA repair, immune dysfunction and aging in higher animals may be intimately related.

The iatrogenic psychology of practitioners' defeatism and other assertions of the null hypothesis

To illustrate iatrogenic defeatism, a series of surveys gave 370 psychiatrists, psychologists, and physicians (randomly selected from their national association biographical directories) the opportunity to submit examples of “incurable” disorders. Despite the scientific, logical, semantic, and practical absurdity of identifying anything as “incurable” (an assertion of the null hypothesis), the majority of the 139 respondents did exactly that, often listing disorders from their own specialization as hopeless. To the extent the respondents are representative of present clinical practice, a best guess is that scientifically grounded non-defeatist practitioners may be found in one of every two psychologists, one of every four psychiatrists, and one of every 10 non-psychiatric physician-specialists. The null assertions of Bender, Bergman, Hayflick, and other distinguished iatrogens are examined in the topic contexts of mortality and aging, child development norms, cortical decay, human genetics, senility, variable intelligence, and some new directions including biofeedback and hypnosis. The iatrogenic impact of prestigious defeatism may be hazardous to our health.

Evidence that transcription changes in ageing cultures are terminal events occurring after the expression of a reduced replicative potential

There is a progressive decline in replicative capacity with increasing age as expressed in terms of percentage labelled nuclei with 3H-thymidine and altered saturation density at confluency. This expression of ageing in vitro is seen in three different lines of human embryo diploid fibroblasts, although the pattern and rate of decline is different in each case. Generalization about in vitro ageing from studies with one cell line should therefore be made with care or avoided. There was an increase in total cellular RNA content as cultures aged which was more pronounced as cells entered the senescent or terminal phase of their lifespan. This increase appeared to be accompanied by a slightly elevated uptake and incorporation of 3H-uridine per cell. Template activity of isolated nuclei was markedly reduced in very late passage or phase III cells, but did not show a progressive decline with increasing age. These studies show that there is a reduced replicative potential which is not accompanied by a detectable decline in transcription, and suggest that the altered template activity should be regarded as an effect of ageing in vitro.

The biology of aging: 1976, an overview

This article is a comprehensive overview of the biology of aging. The largely unproductive history of research on aging is presented, to lay the groundwork for a discussion of why such research is performed and what aging levels and human models are employed. The anatomic, biochemical, physiologic and behavioral measures used in such studies are delineated. Some of the most promising theories of aging (genetic, autoimmune, viral, free radical) are discussed, as are factors that could prolong the lifespan if optimally employed. Philosophic considerations are emphasized.

A lack of correlation between decline in growth capacity and nuclear RNA synthesising activity in ageing human embryo cells in culture

A reduced proliferative capacity has been demonstrated between young (passage 5/24) and middle (passage 17/24) aged human embryo diploid fibroblast cultures. This difference was noted in both logarithmically growing and plateau-phase cultures in terms of growth curves, DNA content per dish and ability to incorporate 3H-thymidine. This reduction in growth potential is not accompanied by any reduction in chromatin template activity, determined in nuclear "ghost" monolayer, using either the endogenous polymerase or an exogenous bacterial enzyme. Therefore the declining division potential as these cells pass from young to middle passage is unlikely to occur as an expression of alterations in nuclear RNA synthesis. It is, however, possible that the apparently continuous decline in growth potential with age might be caused by different events at various stages of the cells's lifespan.

Collagen synthesized and modified by aging fibroblasts in culture

Collagen is produced by WI-38 diploid human fibroblast cultures throughout their life cycle. It is examined by a sensitive method based on the analysis of specific peptides obtained after digestion with bacterial collagenase. The production and hydroxylation of the collagen is strongly dependent upon the age (population doublings) of the culture and the presence of ascorbic acid. Young cultures (passage 26) produce large amounts of collagen in the absence of ascorbic acid, and this collagen is about 50% hydroxylated compared to that produced by young cultures in the presence of ascorbic acid. Ascorbic acid reduces to about one-half the amount of collagen produced by these young cultures. The young confluent cultures also depend strongly on ascorbic acid for hydroxylation of proline. The dependence declines rapidly with the age of the culture. The collagen produced by young cultures supplied with ascorbic acid is very similar to the type I collagen produced by normal individuals and has about the same degree of hydroxylation of its prolyl residues. The amount of collagen produced by "older" cultures is unaffected by ascorbic acid, but the degree of hydroxylation is normal only if ascorbic acid is present, and is decreased to about 60 to 70% in the absence of the vitamin. "Senescent" cultures showed little, if any, dependency on ascorbic acid, and the collagen produced, with and without the vitamine, is about 80% hydroxylated. The prolyl hydroxylation system of the WI-38 cells and the various controls on the system are age-dependent.

I. In vitrol transformation of rat embryo cells: correlations with the known tumorigenic activities of chemicals in rodents

Susceptibility to chemically induced transformation changed as a rat embryo cell culture was passaged. For the first 35 to 60 passages, the cultures were diploid and resistant to transformation by chemical carcinogens. However, cultures infected with a murine leukemia virus were transformed by chemicals. For the next 60 passages, the cultures were heteroploid, but retained contact inhibition and were not tumorigenic. Even without addition of heterotypic viruses, these heteroploid cultures could be transformed by chemicals, but the endogenous rat C-type virus could be demonstrated in the transformed cultures. At higher passages, the rates of spontaneous transformation gradually increased so that the cultures could not be used for transformation studies. Chemically induced transformation of the stable heteroploid cell line (F1706) was manifested by an easy to read focal alteration. Initial observations based on these foci were confirmed by inoculating the morphologically altered cells into isogeneic newborn rats. A number of carcinogenic and noncarcinogenic chemical analogues were tested for their ability to transform F1706 cultures. The compounds tested included 4 azo dyes, 12 polycyclic hydrocarbons, 12 aromatic amines, and 7 miscellaneous compounds. Based on the known activities of the same chemicals in rodents, certain active compounds failed to induce transformation in any test, and others induced transformation in only some tests, but these in vitro tests, if used as a screening assay, would have been correct in 82% of all individual tests, and over-all, would have correctly predicated the carcinogenic activity of 33 of the 35 agents tested.

Viral infection and interferon in cell cultures aged in vitro

Cells from leucosis-free chick embryos (skin and muscles), grown in vitro 1 and 7 days with no medium change, are used as a model for young dividing and stationary in vitro aged cells, respectively. Aged cultures are advantageous for IF induction by cytopathic and noncytopathic viruses. Decreased virus production in them is ascribed to a back effect of the early formed IF onto the inducing virus. A factor which stimulates viral IF interferon induction also in young cultures, is released from aged cells into the medium. This factor could belong -- according to its properties and action -- into the class of chalones.