Existence of high abundance antiproliferative mRNA's in senescent human diploid fibroblasts

Prolongation of the yeast life span by the v-Ha-RAS oncogene

The budding yeast Saccharomyces cerevisiae has a finite life span that is defined by the number of times the cell divides. The patterns of expression of certain genes change in a specific manner during the life span, implying that at least some of the manifestations of the ageing process are subject to gene regulation. It has now been determined that the controlled expression of the RAS oncogene in yeast increases the longevity of this organism, indicating that, conversely, a defined alteration in the activity of a single gene can extend this organism's life span. The results suggest that there is a balance between life-span extension and growth arrest when RAS is expressed. Inasmuch as the homologues of RAS in yeast function to integrate cell metabolism with the cell cycle, these studies raise the possibility that this integrative function may also apply to the co-ordination of successive cell cycles during the life span.

Expression of thermotolerance following microinjection of poly(A)RNA isolated from thermotolerant CHO cells

Poly(A)RNA was isolated from thermotolerant cells and microinjected into recipient non-tolerant Chinese hamster ovary (CHO) cells. The injected cells expressed thermotolerance to a subsequent test heat treatment both in terms of the end-points of colony formation (cell survival) and resumption of protein synthesis after test heating (translational labelling). The magnitude of thermotolerance expression was dependent on the experimental end-point (increase up to 3.8-fold for translational labelling and approximately 2-fold for survival) and on the time between microinjection and the test heat treatment. Control experiments showed that poly(A)RNA from non-tolerant cells did not alter the heat response of microinjected cells. Proteins corresponding to the poly(A)RNA from thermotolerant cells were analysed by in vitro translation and by labelling of microinjected cells, followed by SDS-PAGE. In vitro translations showed high levels of transcripts for classical heat-shock proteins (HSP 70/72, 89, 110) in poly(A)RNA from thermotolerant versus control cells. However, proteins synthesized in intact cells showed no detectable differences when cells were microinjected with poly(A)RNA from thermotolerant versus control cells, or not injected at all. In principle the data show that microinjection of specific poly(A)RNA fractions can be used for defining the contribution of individual gene products to the cellular heat response.

Extension of the life-span of human endothelial cells by an interleukin-1 alpha antisense oligomer

The proliferative potential of human diploid endothelial cells is finite, and cellular senescence in vitro is accompanied by the failure of the endothelial cell to respond to exogenous growth factors. Senescent human endothelial cells were shown to contain high amounts of the transcript for the cytokine interleukin-1 alpha (IL-1 alpha), a potent inhibitor of endothelial cell proliferation in vitro. In contrast, transformed human endothelial cells did not contain detectable IL-1 alpha messenger RNA. Treatment of human endothelial cell populations with an antisense oligodeoxynucleotide to the human IL-1 alpha transcript prevented cell senescence and extended the proliferative life-span of the cells in vitro. Removal of the IL-1 alpha antisense oligomer resulted in the generation of the senescent phenotype and loss of proliferative potential. These data suggest that human endothelial cell senescence in vitro is a dynamic process regulated by the potential intracellular activity of IL-1 alpha.

Replicative senescence: the human fibroblast comes of age

Human diploid fibroblasts undergo replicative senescence predominantly because of arrest at the G1/S boundary of the cell cycle. Senescent arrest resembles a process of terminal differentiation that appears to involve repression of proliferation-promoting genes with reciprocal new expression of antiproliferative genes, although post-transcriptional factors may also be involved. Identification of participating genes and clarification of their mechanisms of action will help to elucidate the universal cellular decline of biological aging and an important obverse manifestation, the rare escape of cells from senescence leading to immortalization and oncogenesis.

Hybrids from fusion of normal human T lymphocytes with immortal human cells exhibit limited life span

A number of normal human cell types have been shown to exhibit cellular senescence in vitro. We and others had found that fusion of normal human fibroblasts with immortal human cells yielded hybrids having limited lifespan. This indicated that the phenotype of cellular senescence is dominant and that immortality results from recessive changes in genes involved in growth control. They also supported the hypothesis that senescence results from genetic mechanisms rather than random damage. Since T lymphocytes are a highly differentiated cell type, in contrast to fibroblasts, it was of interest to determine whether similar mechanisms caused senescence in the T cells. We therefore fused normal human T lymphocytes with an immortal human cell line to determine whether they could restore the senescent, nondividing phenotype in hybrids, as do normal human fibroblasts. Eleven of fifteen hybrid clones studied exhibited limited proliferative potential after achieving a range of population doubling similar to that observed in the cell fusion studies involving normal fibroblasts. These results provide evidence that cellular senescence in T lymphocytes occurs via genetic mechanisms.

Failure to phosphorylate the retinoblastoma gene product in senescent human fibroblasts

Heterokaryon studies suggest that senescent and quiescent human diploid fibroblasts (HDF) contain a common inhibitor of entry into S phase. DNA synthesis can be induced in senescent and quiescent HDF by fusing them with cells containing DNA viral oncogenes such as SV40 T antigen, adenovirus E1A, or human papillomavirus E7. Both senescent and quiescent HDF contained the unphosphorylated form (p110Rb) of the retinoblastoma protein, a putative inhibitor of proliferation. After serum stimulation, senescent HDF did not phosphorylate p110Rb and did not enter S phase, whereas quiescent HDF phosphorylated p110Rb and entered S phase. These findings, combined with the observations that T antigen, E1A, and E7 form complexes with, and presumably inactivate, unphosphorylated p110Rb, suggest that failure to phosphorylate p110Rb may be an immediate cause of failure to enter S phase in senescent HDF.

Altered regulation of platelet-derived growth factor A-chain and c-fos gene expression in senescent progeria fibroblasts

The study of human genetic disorders known as premature aging syndromes may provide insight into the mechanisms of cellular senescence. These diseases are clinically characterized by the premature onset and accelerated progression of numerous features normally associated with human aging. Previous studies have indicated that fibroblasts derived from premature aging syndrome patients have in vitro growth properties similar to senescent fibroblasts from normal individuals. As an initial approach to determine whether gene expression is altered in premature aging syndrome fibroblasts, RNA was prepared from various cell strains and used for gel blot hybridization experiments. Although normal fibroblasts only express platelet-derived growth factor (PDGF) A-chain mRNA for a brief period following mitogenic stimulation, one strain of Hutchinson-Gilford (progeria) syndrome fibroblasts, AG3513, constitutively expresses PDGF A-chain mRNA and PDGF-AA homodimers. The PDGF A-chain gene does not appear to be amplified or rearranged in these fibroblasts. AG3513 progeria fibroblasts have properties characteristic of senescent cells, including an altered morphology and a diminished mitogenic response to growth promoters. The diminished response of AG3513 progeria fibroblasts to PDGF stimulation was examined in some detail. Studies using 125I-PDGF-BB, which binds with high affinity to both A- and B-type PDGF receptors, indicate that normal and AG3513 progeria fibroblasts have a similar number of PDGF receptors. Although receptor autophosphorylation occurs normally in PDGF-stimulated AG3513 progeria fibroblasts, c-fos mRNA induction does not. The senescent phenotype of AG3513 fibroblasts is probably unrelated to their constitutive PDGF A-chain gene expression; further studies are necessary in order to directly address this issue. Also, additional analysis of this progeria fibroblast strain may provide information on the control of mitogen-inducible gene expression in normal cells.

Tumor hypersensitive DNA is enriched in c-myc sequences and reacts differentially with normal and malignant genomic DNA

We now show that exposure of B16 melanoma cells to bromodeoxyuridine increases cell-substratum interactions concurrent with an increase in genome susceptibility to nucleases. Hypersensitive DNA was isolated after mild nicking of nuclei with DNase I followed by repair with DNA polymerase I in the presence of biotin-19-SS-dUTP and affinity chromatography on streptavidin-agarose. Dot blot studies showed that the hypersensitive DNA is enriched in c-myc sequences compared to total tumor genomic DNA, and hybridizes preferentially to the latter, compared to normal genomic DNA, particularly when prepared from BrdU-treated cells. Since hypersensitive DNA can hybridize with multiple Alu sequences in the genome, we postulate that one of the mechanisms for its differential reactivity may be by recognition of an unequal number of Alu repeats in normal and tumor genomic DNA.

Isolation and identification of aging-related cDNAs in the mouse

To identify genes whose expression changes as a function of aging, we screened mouse cDNA libraries with cDNAs from mice of different ages. Specifically, whole-mouse cDNA libraries were constructed in lambda gt10 using poly(A) RNA from young (3 month) and old (27 month) C57BL/6J inbred mice and these lambda plaques were hybridized with radioactive cDNAs made from pooled poly(A) RNA from animals 3 or 33 months of age. Five clones were isolated that showed an aging-related pattern of expression and four of these were identified by computerized sequence matching to the GenBank database: MUP2 (a major urinary protein); Q10 of the MHC locus; a cytoskeletal actin gene; and creatine kinase. One gene whose expression increases with aging and is most abundant in spleen remains unidentified. All five cDNAs showed 4-fold to 17-fold changes with aging in their steady-state mRNA levels in at least one tissue.

Aging and senescence of the budding yeast Saccharomyces cerevisiae

The budding yeast Saccharomyces cerevisiae has a limited life span, defined by the number of times an individual cell divides. Longevity in this organism involves a genetic component. Several morphological and physiological changes are associated with yeast aging and senescence. One of these, an increase in generation time with age, provides a 'biomarker' for the aging process. This increase in generation time has revealed the operation of a 'senescence factor(s)', which is likely to be a product of age-specific gene expression. The Cell Spiral Model indicates coordination of successive cell cycles to be inherent in the determination of life span. It is proposed that life expectancy depends on the function of a stochastic trigger during aging that sets in motion a programme leading to cell senescence and death.

Appearance of the terminal senescent cell population in human diploid fibroblasts analyzed by flow cytometry

We studied changes in the distribution pattern of relative RNA content during the in vitro aging of TIG-3 cells by flow cytometry (FACS III). Propidium iodide (PI) does not stain total cellular RNA, but it intercalates specifically into double-helical regions of both DNA and RNA. In applying this principle to RNA, we stained double-stranded RNA (dsRNA) in whole cells with PI after DNA digestion with DNase. The results showed that dsRNA distribution patterns were relatively constant at 7-75 population doublings (PD) but were significantly altered after 77 PD. The distribution patterns were similar as those for cell volume measured with a Coulter Counter. The total cellular dsRNA contents increased linearly at the senescent phase of their in vitro life span. In contrast, the mean dsRNA contents (50% dsRNA contents) rapidly increased to 77-79 PD, but decreased somewhat at 81-83 PD. Two-dimensional histograms of the dsRNA contents versus cell size were little altered from 25 PD to 75 PD. However, a population with relatively larger cell volume and weaker fluorescence intensity appeared and increased after 79 PD. This cell population group may be categorized as "terminal senescent cells" that no more divide in respect that the dsRNA content decreases in spite of the increase of total RNA content.

Age, anatomic site, and the replication and differentiation of adipocyte precursors

The effects of donor age and anatomic site on cellular replication and differentiation were studied in adipocyte precursors cloned from epididymal and perirenal depots of young, middle-aged, and senescent rats. As animals aged from 3 to 29 mo, there was a progressive reduction in the proportion of cells capable of extensive replication in both depots. An inverse relation between clonal capacity for replication and differentiation was found. This relation was affected by donor site but not age. Aging was, however, associated with a reduction in the frequency of clones capable of full differentiation into cells with single, large, central lipid inclusions. Hence, age and donor site may affect adipocyte precursor replication and differentiation by different mechanisms.

Repression of c-fos transcription and an altered genetic program in senescent human fibroblasts

Normal cells in culture invariably undergo senescence, whereby they cease proliferation after a finite number of doublings. Irreversible changes in gene expression occurred in senescent human fetal lung fibroblasts: a non-cell cycle-regulated mRNA was partially repressed; an unusual polyadenylated histone mRNA was expressed; although serum induced c-H-ras, c-myc, and ornithine decarboxylase mRNA normally, ornithine decarboxylase activity was deficient; and serum did not induce mRNA for a replication-dependent histone and for the c-fos proto-oncogene. The loss of c-fos inducibility was the result of a specific, transcriptional block. The results suggest that senescent fibroblasts were unable to proliferate because of, at least in part, selective repression of c-fos; moreover, the multiple changes in gene expression support the view that cellular senescence is a process of terminal differentiation.

An inhibitor of T lymphocyte blastogenesis derived from the unfertilized ova of Shad (Alosa sapidissima)

Unfertilized ova from Shad, a North Atlantic herring, contains a cytostatic inhibitor of T lymphocyte blastogenesis. The inhibitor has an estimated molecular weight of 10,000-30,000 Da, is heat stable, non dialyzable, and resistant to protease digestion and periodate oxidation. Although the inhibitor functions at an early metabolic event in T lymphocyte mitogenesis, it does not appear to interfere with thymidine transport, antagonize lectin binding to lymphocyte surface receptors, or interfere with the function of an essential serum component in the cell culture media.

Insulin and Serum-Stimulated Hexose Transport do not Change in Type II (Non Insulin Dependent) Diabetic Cultured Fibroblasts during in Vitro Aging

Des fibroblastes diabétiques de Type II en milieu de culture ne démontrent,in vitro, pas de changements reliés à l'àge dans l'insuline ou dans le transport de l'hexose stimulé par s'usage d'un protocole de réponse amplifié de dexaméthasone permettant l'usage de concentrations quasi-physiologiques d'insuline (6.7 nM) ne démontre toujours pas,in vitro, de changements reliés à l'àge dans le transport de l'hexose stimulé par insuline dans ces fibroblastes diabétiques de Type II en milieu de culture. Les données indiquent que les fibroblastes diabétiques de Type II réagissent sans différence à l'insuline ou au sérum durant le vieillissementin vitro.

Isolation of a cDNA that hybrid selects antiproliferative mRNA from rat liver

Studies of chromosome loss in inherited cancers, of fusions between proliferating and quiescent cells, and of microinjection of RNA from quiescent cells into proliferation competent cells have all provided evidence for antiproliferative genes in mammalian cells. In this report, we describe a partial cDNA clone isolated on the basis of its preferential hybridization to RNA from normal versus regenerating rat liver. The corresponding mRNA, enriched by hybrid selection, was microinjected into normal human diploid fibroblasts in cell culture, resulting in a 53% decrease in the fraction of nuclei incorporating tritiated thymidine. This mRNA is 2 kb in size and is expressed in eight tissues examined.

In vivo aging of human fibroblasts does not alter nuclear plasticity in heterokaryons

In vivo aging of human fibroblasts altered proliferative properties but not the potential for novel gene expression in response to muscle trans-acting factors. Heterokaryons produced by fusing fibroblasts with muscle cells permitted a dissociation of the effects of aging on cell division and other cell functions. Skin fibroblasts derived from fetal and adult stages of development were distinct cell types based on their doubling time, protein content, cell size, and specific binding of insulin and insulin-like growth factor I. Despite these differences in growth parameters, the two cell types were indistinguishable in heterokaryons. Muscle gene activation occurred in the absence of changes in chromatin structure requiring DNA replication. In addition, the time course, maximal efficiency, and effect of gene dosage on the expression of muscle gene products were similar for heterokaryons containing fetal and adult fibroblasts but distinct for heterokaryons containing keratinocytes. The difference between fibroblasts and keratinocytes in the time course of muscle gene expression is likely to reflect mechanisms of gene activation at the transcriptional level, since the kinetics of muscle protein accumulation paralleled that of muscle transcripts. These results indicate that nuclear plasticity is not altered in fibroblasts by in vivo aging.

Varying capacities for replication of rat adipocyte precursor clones and adipose tissue growth

Rat adipocyte precursor populations contain clones varying in capacity for replication. In this study we explored factors controlling the frequency of clones of varying replicative capacities (clonal composition). We also explored the relationship between this frequency and fat depot growth. In perirenal and epididymal depots clonal composition was identical bilaterally; perirenal depots contained more extensively replicating clones. Although there were large interanimal differences in clonal composition, variation between animals was always in the same direction for both depots. Clonal composition was unaffected by undernutrition while with animal growth the frequency of the most extensively replicating clones was reduced. Differentiation of precursors occurred in all clones, while differentiation did not occur in skin fibroblasts cloned under identical conditions. Clonal composition and mature fat cell number were related in that fat cell numbers were identical bilaterally in both depots and increased more extensively with growth in perirenal than epididymal tissue. We conclude (a) that clonal composition of adipocyte precursor populations is regulated genetically and by age, (b) that this composition determines, at least in part, the capacity for adipose depot growth.

Skin fibroblasts from individuals hemizygous for the familial adenopolyposis susceptibility gene show delayed crisis in vitro

Normal human fibroblast cells have not been reported to escape crisis--that is, they die after about 24 doublings in culture. We have been studying the growth properties of skin fibroblast cells from persons in families with familial adenopolyposis of the colon (FAP). An individual hemizygous at the FAP locus will develop hyperplasia of the colonic epithelium followed by colonic polyps, both at an early age. Polyps themselves still retain a single functional FAP allele. A mutation or deletion in this allele in a polyp is hypothesized to lead to further loss of growth control; thus, a tumor is formed. We found that the in vitro life-span of skin fibroblast cells from FAP individuals and from some asymptomatic children were markedly extended when compared with normal individuals.

Increase in abundance of a transcript hybridizing to elongation factor I alpha during cellular senescence and quiescence

We have isolated a senescence-specific clone (pSEN) from a cDNA library constructed from late passage WI-38 human diploid fibroblast that accounts for approximately 1% of the recombinants. Nucleotide sequence analysis of the partial cDNA clone has led to the identification of pSEN as elongation factor I alpha. Northern analysis of poly(A)+ RNA from various intermediate population doubling levels shows that a 2.2 kb transcript hybridizes to pSEN but is expressed prior to PDL-40 at very low levels. This transcript begins to accumulate at PDL-40 and is induced approximately 50-fold just prior to senescence. Furthermore, this transcript was shown to be specific to Go of the cell cycle whereas a second, lower molecular weight transcript (1.6 kb) was observed during S phase (Giordano and Foster, unpublished data). The 2.2 kb transcript is also detected in neonatal foreskin cells but very little increase in abundance is observed between early and late passage cells. Sucrose gradient fractionation of RNA from late passage WI-38 cells suggests that the lower molecular weight transcript is associated with the polysome fraction while the 2.2 kb transcript sediments with the nonpolysomal fraction. Thus, the possibility exists that the 1.6 kb transcript is derived from the 2.2 kb transcript.

Approach to the isolation of antiproliferative genes

Poly(A) RNAs from normal rat liver and senescent human fibroblasts appear to have more antiproliferative activity than RNAs from regenerating rat liver and early passage human fibroblasts. We have screened two rat liver and one human liver library by differential hybridization and isolated four candidate cDNAs for this antiproliferative activity; one is fibronectin and three others do not match to any sequence in the mammalian portion of the GENBANK database. We are currently testing the antiproliferative nature of these cDNAs by microinjection of hybrid-selected RNA, and we describe an alternative strategy for cloning such genes based on construction of a cDNA library in an RNA expression vector.

The relationship between cell size, the activity of DNA polymerase alpha and proliferative activity in human diploid fibroblast-like cell cultures

In kinetic studies with human diploid fibroblast-like (HDFL) cells carried out in heterokaryons and in monokaryons, we have observed a first-order relationship between the level or concentration of DNA polymerase alpha and the rate of initiation of new rounds of DNA synthesis. Because cell size is inversely proportional to the concentration of DNA polymerase alpha and presumably other replication factors, it is inversely related to the initiation of new rounds of DNA synthesis. An inverse relationship between cell size and clonogenic activity was also observed in both unsorted HDFL cells and in HDFL cells sorted on the basis of size. Experimental enlargement of cells by serum deprivation at low density resulted in changes in colony-forming ability that would be predicted by these studies. A causal relationship between the observed increase in cell size with advancing passage level and the loss of proliferative activity is suggested by these studies; in addition, cell size may be a useful biophysical marker for cellular aging.

Studies on the molecular-genetic basis of replicative senescence in Werner syndrome and normal fibroblasts

Based on evidence that human diploid fibroblasts (HDF) from the Werner syndrome (WS) of premature aging might overexpress an inhibitor of DNA synthesis (IDS), we prepared a eukaryotic cDNA expression library from WS mRNA and tested it for IDS activity in a transient assay. Two of six WS cDNA pools tested gave IDS activity, then on plus/minus screening revealed several differentially expressed cDNA clones. By slot blot and Northern analysis, one cDNA clone was found to be overexpressed in WS and normal senescent HDF, but not in quiescent normal HDF, indicating that it is senescence-specific. Further studies are needed to clarify: a) whether this cDNA truly acts as an IDS; b) if so, whether it acts alone or in concert with other cDNAs; and c) whether it is involved in the degenerative and malignant sequelae of WS and normal aging.

[Bourneville's disease of the bones or metastasis? Apropos of a case]

Tuberous sclerosis or Bourneville's disease is a phakomatosis with common but paucisymptomatic bone localisations. Some osseous lesions, of osteosclerotic type, can be radiologically diagnosed as primary or secondary malignant disorders. We describe a case of Bourneville's disease with bone involvement, radiologically characterized by osteosclerosis areas of the spine and the pelvis. Interestingly, bone scintiscan was normal. The absence of primary malignancy, the stability of control bone X-ray films, the clinical status and the family history, together with the pathognomonic radiological feature of the hands support the diagnosis of tuberous sclerosis with bone involvement.

Evidence for the involvement of a cytoplasmic factor in the aging of the yeast Saccharomyces cerevisiae

The life spans of individual Saccharomyces cerevisiae cells were determined microscopically by counting the number of buds produced by each cell to provide a measure of the number of cell generations (age) before death. As the cells aged, their generation times increased five- to sixfold. The generation times of daughter cells were virtually identical to those of their mothers throughout the life spans of the mothers. However, within two to three cell divisions after the daughters were detached from their mothers by micromanipulation, their generation times reverted to that characteristic of their own age. Recovery from the mother cell effect was also observed when the daughters were left attached to their mothers. The results suggest that senescence, as manifested by the increase in generation time, is a phenotypically dominant feature in yeast cells and that it is determined by a diffusible cytoplasmic factor(s) that undergoes turnover. This factor(s) appeared to be transmitted by a cell not only to its daughter, but also indirectly to its granddaughter. In separate studies, it was determined that the induced deposition of chitin, the major component of the bud scar, in the yeast cell wall had no appreciable effect on life span. We raise the possibility that the cytoplasmic factor(s) that appears to mediate the "senescent phenotype" is a major determinant of yeast life span. This factor(s) may be the product of age-specific gene expression.

Efficient immortalization by SV40 T DNA of skin fibroblasts from patients with Wilms' tumor associated with chromosome 11p deletion

We report that transfection with a plasmid containing the SV40 early region (T) leads to a very high frequency of immortalization in two different strains of human diploid fibroblasts, each with a partial deletion of the short arm of chromosome 11. Immortalization often occurred without a recognizable "crisis" phase. Preimmortal cells showed a high frequency of spontaneous mutations and chromosomal aberrations. These results suggest that a gene involved in the control of senescence of human cells in vitro may be associated with this chromosome.

Replication control and cellular life span

Cell proliferation involves both control of progress through the current cell cycle and coordination of successive cell cycles. We have focused our attention on the events that trigger traversal of the G1/S boundary of the cell cycle. A protein kinase activity was found in preparations of the DNA-replicative complex from the budding yeast Saccharomyces cerevisiae. The activity phosphorylated only a few of the proteins present in the replicative fraction, and it displayed a marked preference for a 48-kDa polypeptide. Most importantly, the protein kinase activity was heat-sensitive in replicative fractions from cdc7 cells, a mutant that arrests at the G1/S boundary at restrictive temperature. The results suggest that phosphorylation of components of the replication machinery may play a role in control of initiation of DNA replication during the cell cycle. We have also begun an analysis of cellular aging in yeast, as a means of addressing the problem of coordination of successive cell cycles. Yeast cells have a finite life span defined by reproductive capacity. With age, the generation time of yeast cells lengthened. The cell cycle of the daughter cell was under the control of the mother. This control was transient, and the daughter cell began dividing at the rate characteristic of its own age within three divisions of its birth. This suggests that the senescent phenotype, as manifested by lengthened generation time, is a dominant feature in yeast cells, and that it is determined by a diffusible cytoplasmic molecule(s) that undergoes turnover in young cells. In a search for this putative senescence factor(s), we are cloning genes that differentially expressed during the yeast life span. Several such genes have been isolated and partially characterized. Our goals are to determine whether the expression of one or more of these genes is casually associated with cell longevity. We propose the Cell Spiral model to describe the relationship between the cell cycle and cellular aging.

Identification of microinjected cells using biotinylated antibodies and Strep-avidin-conjugated horseradish peroxidase

Results from experiments using needle microinjection of cells are often compromised by an inability to readily demonstrate which cells within a population have been injected. The technique described here allows the unambiguous identification of cells that have been successfully microinjected. Sequential incubation of fixed cells with biotinylated anti-immunoglobulin antibodies, followed by horseradish peroxidase (HRP)-conjugated Strep-avidin and HRP substrate, provides a sensitive assay for identification of cells containing trace amounts of immunoglobulins. This allows direct correlation to the presence of injected molecules of effects on cell morphology, the ability to enter into DNA synthesis, or expression of specific genes. By a variety of criteria, nonspecific immunoglobulins do not adversely affect cellular processes when injected by themselves or in the presence of other proteins known to have biological effects when injected, such as cAMP-dependent protein kinase and the ras oncogene protein.

Genes specifically expressed at growth arrest of mammalian cells

A subtraction cDNA library enriched for RNA sequences preferentially expressed in growth-arrested cells was prepared. Six cDNA clones were identified, varying in abundance from 2% to 0.0002% of the library and in size from 0.8 to 10 kb. The corresponding mRNAs are downregulated with different kinetics upon induction of growth by serum. The kinetics of induction after serum starvation and density-dependent inhibition of two of these growth-arrest-specific (gas) genes were investigated in more detail. Two cell lines transformed by viral onc genes did not express the two gas genes. The full-length cDNA for one gene has been sequenced and the protein product preliminarily characterized by in vitro translation.

Automatic microinjection system facilitates detection of growth inhibitory mRNA

Naturally quiescent human lymphocytes, consisting predominantly of T cells, contain mRNA(s) that can inhibit DNA synthesis when injected into either human diploid fibroblasts (IMR-90) or transformed recipient cells (HeLa). By using an automated capillary microinjection system and a fluorescent coinjection marker (fluorescein isothiocyanate-dextran), individually injected cells can be retrieved and analyzed for DNA synthesis. mRNA isolated from resting T cells is able to block the cells from entering the S phase. The block is reversible and leads to a delay in DNA synthesis. The inhibitory effect is not observed if the injected mRNA is isolated from growth-activated T cells. The disappearance of the inhibition coincides with the approach of the G1/S boundary in both the donor T cells and the recipient human fibroblasts. The mRNA of resting T cells was size-fractionated and the peak inhibitory activity was recovered in a fraction approximately equal to 1.5 kilobases long.

Performance of an automated system for capillary microinjection into living cells

An automated capillary microinjection system for nuclear and cytoplasmic injections into cells is described. The system has been tested with samples of DNA, RNA and proteins. Movements of the capillary with precise cell positioning and time of injections are controlled by a computer. This first automated microinjection system allows injection of more than 1500 cells per hour with a minimum of practical training, volumes injected are more reproducible and cells are less damaged when compared with the standard manual injection technique. Retrieval of the injected cells is accurate to within 1% without complicated and laborious produced orientation marks on the cell support. The number of successfully injected cells is easily determined with great accuracy and the error of the statistical evaluation of the results is reduced to a minimum. Standardized procedures for pulling, handling and storage of the injection capillaries were developed.

Genetic analysis of indefinite division in human cells: identification of four complementation groups

Hybrids obtained following fusion of normal human diploid fibroblasts with different immortal human cell lines exhibited limited division potential. This led to the conclusion that the phenotype of cellular senescence is dominant and that immortal cells arise as a result of recessive changes in the growth control mechanisms of the normal cell. We have exploited the fact that immortality is recessive and, by fusing immortal human cell lines with each other, assigned 21 cell lines to at least four complementation groups for indefinite division. A wide variety of cell lines was included in the study to determine what parameters, if any, would affect complementation group assignment. The results indicate that cell type, embryonal layer of origin, and type of tumor do not affect group assignment. There does not appear to be any correlation between expression of an activated oncogene and group assignment. However, all of the immortal simian virus 40-transformed cell lines studied (with the exception of one xerodermapigmentosum fibroblast-derived line) assign to the same group, indicating that this virus immortalizes various human cells by the same processes. The assignment of immortal human cells to distinct groups provides the basis for a focused approach to determine the genes important in normal growth regulation that have been modified in immortal cells.

Potential and limitations of cultivated fibroblasts in the study of senescence in animals. A review on the murine skin fibroblasts system

Senescence is the last period of the life span, leading to death. It happens in all animals, with the exception of a few didermic species (Hydras) having a stock of embryonic cells and being immortal. The causes of animal senescence are badly known. They depend both on genetic characters (maximum life span of a species) and on medium factors (mean expectation of life of the animals of a species). Animal senescence could depend on cell aging: (1) by senescence and death of the differentiated cells, (2) by modified proliferation of the stem cells of differentiated tissues, (3) by alterations in the extracellular matrices, (4) by interactions between factors (1) (2) and (3) in each tissue, and (5) by interactions between the several tissues of an organism. This complexity badly impedes the experimental study of animal senescence. Normal mammal cells are aging when they are cultivated (in vitro aging). Present literature upon in vitro aging of cultivated human fibroblasts consists essentially of papers devoted to proliferation and differentiation characteristics and not to cell senescence. Murine skin fibroblasts have been studied in our laboratory, using different systems: (1) primary cultures isolated from peeled skins of mouse embryos, (2) mouse derms analysed in the animals, (3) cultivated explants of skins, (4) serial sub-cultures of fibroblasts isolated from these explants, (5) cells cultivated comparably on plane substrates (glass, plastic, collagen films) and on three-dimensional matrices (collagen fibres). In primary cultures (system 1) all the cell generations have been analysed, including the last one until death of the culture. We have shown that many characters are varying with cell generation. All the observed variations were: progressive, non-linear and correlated (intracellular feedbacks). We come to the conclusion that the main effects of cell mitotic age are (1) to depress the plasticity of the chromatin, (2) to change the organization of the cytoplasmic filaments, (3) to change the organization of the extracellular matrix. The collagen fibres are also acting upon nucleus and filaments either in the animals or in the cultures. The phenotype of a fibroblastic cell is thus both age- and environment-dependent. Overall data on in vitro cell aging point to the hypothesis that senescent cells are phenotypic variants and not mutant cells. Aging cell cultures are remarkably useful to the studies on cell proliferation decrease and cell cycle lengthening shown by the stem cells in animal tissues. We propose the hypothesis that the fibroblasts of the vertebrates would be homologous to the pluripotent mesenchyme cells of their embryos.

Strategies and criteria for the development of molecular biomarkers of senescence

While it may be possible to employ panels of molecular parameters which correlate with senescence in vivo or in vitro, in a manner analogous to the use of mutagenesis assays for economic carcinogen screening, such an endeavor would at present be impeded by the absence of a clear mechanistic rationale for focusing on particular biomarkers, and by the complexity of the senescent phenotype and its multilevel interactions. Nevertheless, insight into the mechanism(s) of senescence may derive indirectly from correlative studies, or directly from strategies of molecular intervention, provided that such studies meet reasonable criteria for relevance and functionality. Even the control of expression of a single gene may be quite complex, with multigenic interactions and the potential to produce a cascade affecting many downstream genes. In order to understand such processes, functional assays and selective systems will need to be developed.

Suicidal death of rat chloroleukaemia cells by activation of the long interspersed repetitive DNA element (L1Rn)

Rat chloroleukaemia cells, maintained in suspension culture in different media, show rapid exponential growth without cell loss. At about half of the maximal population density the long interspersed repetitive DNA element (L1Rn) is suddenly transcriptionally activated without any obvious exogenous reason. Population growth is then inhibited and, within about 24 h after reaching the maximal density, the population undergoes programmed death (apoptosis). Suicidal cell death is caused by sudden incorporation, apparently by retroposition via an RNA intermediate, of about 300,000 copies of the L1Rn element into random locations in the cell genome, thus creating lethal mutations. The preceding growth inhibition is associated with repression, to an undetectable level, of c-Ki-ras expression. Up to the point of massive L1Rn incorporation and cell death, all phenomena are quickly reversible by subculturing; medium change alone is not sufficient. Biological implications of these surprising findings are discussed.

Cellular senescence revisited: a review

The field of cellular senescence (cytogerontology) is reviewed. The historical precedence for investigation in this field is summarized, and placed in the context of more recent studies of the regulation of cellular proliferation and differentiation. The now-classical embryonic lung fibroblast model is compared to models utilizing other cell types as well as cells from donors of different ages and phenotypes. Modulation of cellular senescence by growth factors, hormones, and genetic manipulation is contrasted, but newer studies in oncogene involvement are omitted. A current consensus would include the view that the life span of normal diploid cells in culture is limited, is under genetic control, and is capable of being modified. Finally, embryonic cells aging in vitro share certain characteristics with early passage cells derived from donors of increasing age.

Alteration of the microtubule organization in aging WI-38 fibroblasts. A comparative study with embryonic hamster lung fibroblasts

The microtubule organization in human WI-38 fibroblasts subcultivated in vitro has been investigated using nocodazole, a reversible inhibitor of the microtubules. Two phenotypes were observed. The typical fibroblast cells, called Type 1 cells, showed, after nocodazole treatment, a centripetal depolymerization wave of the microtubules and the giant Type 2 cells which have a more heterogeneous behaviour. Some of the cells clearly showed a centrifugal depolymerization of the microtubules, others a mixed behavior and less than 1% displayed the same behavior as the Type 1 cells. Confirming previous data obtained with Hamster fibroblasts (Raes et al., 1983, 1984), these results suggest a modification in the microtubule organization which could account for the aberrant division of some WI-38 cells in aged cultures. The relevance of this observation for the emergence of the morphologically different Type 2 cells and for cell division impairment in serially in vitro cultivated cells is discussed.

Suppression of tumor growth by senescence in virally transformed human fibroblasts

Normal human cells whether embryonic, neonatal, or adult are resistant to experimentally induced tumorigenesis in contrast to rodent or chicken cells. We showed previously that neither transformation with simian virus 40 DNA nor transfection with human mutant HRAS DNA immortalized FS-2 cells (diploid, neonatal human fibroblasts). Further, tumorigenicity was not induced, despite expression of the respective transforming gene products tumor (T) antigen or p21. Here we describe treatment of FS-2 and FSSV cells with baboon endogenous virus pseudotyped Kirsten murine sarcoma virus. FSSV cells were derived from individual foci of simian virus 40-transformed FS-2 cells. The retrovirus-treated FS-2 cells (called FSK) appeared heavily granulated and expressed viral p21 but senesced during passage in culture and were not tumorigenic. The retrovirus-treated FSSV-27 cells (called FSVK-27) expressed simian virus 40 tumor antigen, had elevated levels of viral p21 protein, and formed transient tumors in nude mice. Whether grown in culture or explanted from small tumors, the FSVK-27 cells senesced. The FSVK-46 cells senesced before tumor growth occurred. On the contrary, Kirsten murine sarcoma virus (baboon endogenous virus) treatment of immortalized nontumorigenic human fibroblasts expressing simian virus 40 tumor antigen (Va2 cells) led to consistent tumor formation. The results illustrate the importance of senescence in restricting the tumor-forming ability of human cells.