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

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

Repair of radiation-induced DNA damage in nondividing populations of human diploid fibroblasts.

The occurrence of DNA repair in UV- (254 nm) and X-irradiated normal human diploid fibroblasts maintained in a quiescent, nondividing state using low serum (0.5%) medium was ascertained. Techniques that detect different steps of the excision repair process were used so that the extent of completion of repair at single sites could be determined. These included measuring the disappearance of pyrimidine dimers by chromatography, detecting repair synthesis by density-gradient and autoradiographic methods and detecting the rejoining of repaired regions and repair of x-ray-induced single-strand DNA breaks using alkaline sucrose gradients. Results show that dimer excision occurs and the subsequent steps of repair synthesis and ligation are completed. About 50% of the dimers formed by exposure to 20 J/m2 is excised in the initial 24-h post-UV period. DNA repair (unscheduled DNA synthesis) can be detected through a 5-d post-UV period. The fraction of damaged sites eventually repaired is not known. X-ray-induced single-strand DNA breaks are repaired rapidly.     

Tritium-arrested human diploid fibroblasts maintain balanced RNA and protein metabolism

Incorporation of ³H precursors into the protein or RNA of exponentially growing human diploid fibroblasts (WI38) inhibited DNA synthesis and cell division for a dose-related period. During this period of “tritium-arrest”, which can last for at least a month, the cells remain viable by morphologic criteria and maintain balanced RNA and protein metabolism. The cultures are eventually overgrown by a dose-related fraction of the population which retains DNA synthetic capacity. Tritium-arrested cell populations are suggested as a possible model for the study of metabolism in non-dividing cells.     

Messenger RNA regulation in human diploid fibroblasts

In resting, non-growing human diploid fibroblasts the amount of rRNA is reduced 1.8-fold, cytoplasmic polysomes are disaggregated, and the level of poly-A RNA (mRNA) is reduced 1.8-fold in relation to growing cells. The distribution of poly-A RNA is altered in resting, non-growing cells so that an average of 64% of the total cytoplasmic poly-A RNA sediments along with particles lighter than 80S (prepolysomal) in sucrose density gradients. By comparison, in growing cells only 30% of the cytoplasmic poly-A RNA sediments in the prepolysomal region. In SDS sucrose gradients, the sedimentation profile of the prepolysomal poly-A RNA from resting cells resembles that of polysomal poly-A RNA from those cells. In contrast, the average size of prepolysomal poly-A RNA from growing cells is much smaller than that of the polysomal poly-A RNA from those cells. These data are compatible with the possibility that resting cell prepolysomal poly-A is untranslated mRNA. Also consistent with this interpretation are experiments which demonstrate that one-quarter to one-third of the prepolysomal poly-A RNA of resting cells is recruited into polysomes in the presence of cycloheximide.     

Effects of cycloheximide on protein, RNA and DNA synthesis in cultures of CHO cells and human diploid fibroblasts]

In CHO cell line and primary human diploid fibroblasts culture an incorporation of protein, RNA and DNA biosyntheses precursors was investigated under different conditions of inhibition of translation by cycloheximide (CHM). Both CHO and human fibroblasts transitory treatment by CHM in the serumfree medium resulted in inhibition of protein and DNA syntheses during S-period while RNA synthesis increased up to 130% (CHM concentration from 0.003 to 2 Mg/ml), as well as in Go--an incorporation of 3H-U increased to 200% (CHM concentration-100 Mg/ml). Long-term treatment (48 hours) in the serum-free medium resulted in decreased uptake of 3H-T and 3H-L during first 6 hours of experiment, while incorporation of 3H-U increased to 160%. By 16-th hour of treatment characters of protein, RNA and DNA syntheses came back to control levels.     

Augmented expression of HSP72 protein in normal human fibroblasts irradiated with ultraviolet light.

Normal human fibroblasts synthesized heat shock protein (HSP) 72 constitutively and its expression was augmented 6 hours after UV irradiation. Maximum induction of HSP72 was obtained at 12 hours and HSP72 showed a punctuated distribution in nucleus. While unscheduled DNA synthesis was almost completed 12 hours after UV irradiation, the S phase fraction decreased immediately and recovered after 6 hours. Thus, HSP72 augmentation was occurred coincidentally with the recovery of S phase, and suggested that HSP72 had some function during the recovery of DNA replication inhibited after UV irradiation.     

Increased messenger RNA from protein synthesis inhibited human fibroblasts

Numerous reports have demonstrated that specific protein synthesis in response to specific inducers is markedly stimulated by a simultaneous brief exposure to protein synthesis inhibitors such as cycloheximide. This phenomenon is known as “superinduction” and is most often attributed to the accumulation of cytoplasmic messenger RNA during the inhibition period. Messenger RNA, as defined by rapid labeling, oligo (dt)-cellulose binding, and cell free protein synthesis stimulation was measured in cycloheximide treated human fibroblasts. In spite of a consistent 40% decrease in total polysomal ³H-uridine labeled RNA, a 1.5- to 2-fold increase in extractable mRNA was observed. These data provide direct evidence that protein synthesis inhibition stimulates the appearance of cytoplasmic mRNA and/or completely blocks its degradation and, are consistent with the hypothesis that mRNA accumulation partly underlies the superinduction phenomena.     

Mutagenic effect of BUdR in diploid human fibroblasts

It has only recently been possible to demonstrate the expected mutagenic effect of 5-bromodeoxyuridine (BUdR) in heteroploid hamster cells in culture. We have now extended this observation to diploid human fibroblasts utilizing techniques adapted from the work of Albertini and DeMars on X-ray mutagenesis at the hypoxanthine-guanine phosphoribosyltransferase (HGPRT) locus in these cells. In four separate experiments, fibroblasts from a female donor were exposed to 500 micrograms/ml ethylmethane sulfonate (EMS) or 3 micrograms/ml BUdR yielding survivals of 9% and 5%, respectively. After a 6-day expression period, survivors were plated in selection medium containing 0.3 micrograms/ml 8-azaguanine (8-AG). After 3-5 weeks, azaguanine-resistant colonies were isolated for characterization or stained for counting. The average spontaneous mutation rate/cell/generation was 0.6.10(-6). The average induced mutation rates for EMS and BUdR were 7.8.10(-6) and 6.3.10(-6)/cell/generation, respectively. Similar results were obtained in two experiments with an additional fibroblast line. Mutant colonies isolated following BUdR treatment demonstrated from 1.4 to 61.5% of the HGPRT activity of the parental line and showed at least 8% Barr bodies, excluding the possibility of contamination by Lesch-Nyhan cells. This demonstration of a BUdR effect comparable to that of an alkylating agent or X-irradiation opens the study of mutation due to base-analog substitution in diploid human cells.     

Macromolecular synthesis in human diploid fibroblasts. A viral probe examining the effect of in vivo aging.

The replication of vesicular stomatitis virus was examined in early-passage skin fibroblast cultures from old and young human donors. The production of virus was analysed by measuring synthesis of viral RNA in actinomycin D-treated cells, and by determining the yield of biologically-active viral progeny by plaque assay. Although no statistically significant differences (P < 0.05) were observed between old and young cultures, our assays were shown to be capable of detecting impaired macromolecular synthesis induced by incorporation of amino acid analogues. These results indicate that macromolecular synthesis does not appear to be significantly altered in cells from older donors.     

Kinetics of protein degradation in diploid and trisomic human fibroblasts

The degradation rate of long-lived and short-lived proteins was determined in diploid fibroblasts and fibroblasts with trisomy 7 derived from human embryos. Two fractions of proteins were detected in the exponentially growing diploid fibroblasts with half-lives (T 1/2) 37 and 19 hours. The rate of protein degradation increases in diploid fibroblasts as they approach confluence and protein fractions with T 1/2 30, 18 and 12 hours appear. The rate of protein degradation in trisomic fibroblasts does not change for the long-lived and short-lived proteins and is the same in both exponential (T 1/2 31 and 14 hours) and stationary phase (T 1/2 33 and 17 hours). The relative amount of the short-lived proteins in trisomic fibroblasts in the stationary phase decreased as compared with the one in diploid fibroblasts. It is apparent that a mechanism of regulation of protein catabolism in trisomic fibroblasts is impaired.     

Immobilized glycolipids from human diploid fibroblasts inhibit DNA synthesis of cultured human fibroblasts

Several previous studies have shown that glycolipids isolated from plasma membranes of cultured cells and added to cells in culture inhibit the growth rate in a concentration-dependent fashion. In order to investigate the possible involvement of glycolipids in the growth regulation of normal cells by cell-cell contacts, we tested the effect of immobilized glycolipids, isolated from human fibroblasts, on the DNA synthesis of freshly seeded fibroblasts. Gangliosides inhibited DNA synthesis to a great extent, whereas neutral glycolipids had only a minor effect. The degree of inhibition of DNA synthesis by immobilized gangliosides depended both on the cell density of the cultures from which the gangliosides were isolated and on the pretreatment of the immobilized gangliosides: Preincubation with DMEM without FCS of immobilized gangliosides, isolated from confluent cultures, resulted in a 75% inhibition of growth rate of embryonal human lung fibroblasts (FH109) cultured on immobilized gangliosides. Under the same conditions, gangliosides from sparse cultures reduced the growth rate by about 30%. On the other hand, the degree of inhibition exerted by immobilized gangliosides isolated from confluent cultures was found to be greatly reduced by preincubation with DMEM with FCS, whereas the slight inhibition of growth rate, exerted by gangliosides from sparse cultures, was found to be reversed into a slight stimulation of growth rate after preincubation with complete medium. Concomitantly with the reduction of the inhibition of DNA synthesis, it was found that the complete medium, used for preincubation of the gangliosides, was no longer able to support DNA synthesis to the same extent as untreated complete medium. The data suggest that gangliosides bind growth-supporting factors of the serum, gangliosides isolated from sparse cultures being more potent in the binding of these molecules than gangliosides isolated from dense cultures.     

Regulation of protein synthesis in human diploid fibroblasts: reduced initiation efficiency in resting cultures

The level of poly A+ RNA in growing cultures of human diploid fibroblasts is 1.8-fold times greater than in resting cultures. The level of functional ribosomes in growing cultures is 2.8 times that in resting cultures. Since transit times are similar in both types of cells, it can be concluded that the rate of protein synthesis in growing cultures is 2.8 times that in resting cultures. a reduced efficiency of mRNA translation at the level of initiation in resting cultures is proposed as a probable explanation for the fact that the decrease in protein synthesis rates is greater than the decrease in mRNA levels. This hypothesis is supported by the observations that: (a) poly A+ RNA is associated with smaller polysomes in resting than in growing cells, and (b) cycloheximide treatment of resting cells results in recruitment of nonpolysomal poly A+ RNA into polysomes and a shift of polysomal poly A+ RNA into larger polysomes.     

Dual effect of protein kinase C on the induction of DNA synthesis by colcemid in G0-arrested human diploid fibroblasts

G0-arrested human diploid fibroblasts, TIG-1, was stimulated to induce DNA synthesis by serum, epidermal growth factor (EGF), colchicine, colcemid, or 12-O-tetradecanoylphorbol-13-acetate (TPA). The induction of DNA synthesis was mediated by protein kinase C (PKC) when stimulated with TPA but not when stimulated with other agents. When TPA-stimulated cells were immediately treated with colcemid, induction of DNA synthesis was reduced. This reduction diminished when colcemid was added more than 6 h after TPA treatment. Conversely, when colcemid-stimulated cells were treated with TPA, induction of DNA synthesis was also reduced. This reduction was enhanced when the interval between the addition of two stimulants was extended. PKC-deprivation abolished both stimulatory and inhibitory effects of TPA on DNA synthesis. Staurosporine blocked an induction of DNA synthesis by TPA but appeared to be ineffective on the inhibitory action of TPA on DNA synthesis by colcemid. These results suggest that the inhibitory effect of TPA on the induction of DNA synthesis by colcemid is mediated by down regulation-sensitive and staurosporine-insensitive PKC.     

Proliferative response of human diploid fibroblasts to intermittent light exposure

Three- to four-hour exposure to fluorescnt light, one to three times weekly, reproducibly enhanced the proliferation rate of human diploid fibroblasts. This enhancement was observed in WI-38 and a line from whole embryo mince at late population doubling level (PDL) as well as in a line from adult skin at early PDL. Single or multiple exposures of short duration stimulated proliferation, whereas exposures of long duration were cytotoxic. This proliferative response is reversible, and is mediated through the culture medium, Dulbecco Vogt's supplemented with 10% fetal bovine serum. Apparently light produces some mitogenic substance(s) in the culture medium that accumulates in the cells and is toxic or growth-stimulatory depending on its concentration per cell. Another possibility is that light produces in the medium both cytotoxic and growth-stimulatory substances.     

The distribution of DNA excision-repair sites in human diploid fibroblasts following ultraviolet irradiation

Using the technique for separating DNA fragments containing excision-repair sites from total genomic DNA as described in the previous paper (Cohn, S. M., and Lieberman, M. W. (1984) J. Biol. Chem. 259, 12456-12462), we have developed a method for directly determining the distribution of excision-repair sites in the genome. DNA was prepared from confluent, diploid human fibroblasts which had been irradiated with ultraviolet light and incubated in the presence of 5-bromo-2'-deoxyuridine (BrdUrd), repaired fragments were isolated, and the dependence of the fraction of total DNA fragments containing excision-repair sites on DNA fragment length was determined by electrophoretic analysis. The observed dependence was compared to the relationship expected for a random distribution of repair sites. At 36 h following 3 J/m2 UV, the distribution of repair sites was indistinguishable from a random distribution; however, at doses of UV above 6 J/m2, the observed dependence indicated that the distribution of repair sites was nonrandom. A time course of the distribution of repair sites following 12 J/m2 UV was clearly nonrandom from 4 h after irradiation until at least 36 h following irradiation. By 72 h, however, the distribution had become random. In cells treated with hydroxyurea, a reduced number of excision-repair sites were present, but the distribution of repair sites was also nonrandom. Autoradiographic analysis of the amount of unscheduled DNA synthesis in individual nuclei suggested that the nonrandom distribution of repair sites did not result from variable extents of repair synthesis in different cell populations or from cell death.     

Influence of confluent holding time on UV light mutagenesis in human diploid fibroblasts

We have investigated the induction of mutants resistant to 6-thioguanine (6TG) following 254 nm ultraviolet light exposure of density-inhibited cultures of human diploid fibroblasts. Phenotypic expression of 6TG resistance was maximal within 9 days and remained stable through 19 days after irradiation. In reconstruction studies, complete recovery of 6TG-resistant mutants occurred at cell densities of up to 35 000 cells per 100-mm petri dish. The induced mutation frequency increased linearly with dose over the range of 3–9 J/m²; the D₀ of the survival curve was 4.2 J/m². Delaying subculture to low density for 1.5–24 h after irradiation produced unexpected alterations in induced mutation frequencies. An increase in UV-induced mutations of approximately 3-fold was observed in cultures maintained in confluence for 3 h. This trend was reversed with longer holding times: the mutation frequency declined sharply in cultures held for 6 h compared to the 3-h value, and thereafter showed a steady and gradual diminution to background levels.

These data suggest that the repair of potentíally mutagenic damage is a complex phenomenon which can lead to an increase or decrease in mutation frequency as a function of holding time. Although the decline in mutation frequency observed following longer holding intervals is consistent with the notion of an error-free process, we hypothesize that the increased mutation frequency produced by a short holding period reflects the existence of a cell-mediated process which enhances the mutagenic potential of at least some UV-induced DNA photoproducts.