Loss of inducible photorepair in a frog cell line hypersensitive to solar UV light

The induction of enzymatic photorepair (EPR) in ICR 2A frog cells and a derived mutant cell line DRP36 hypersensitive to solar UV was studied. Using clonogenic assays, when induced wild-type cells demonstrated an 8-fold increase of EPR the mutant cells displayed a near-background level of inducible EPR. The constitutive EPR in mutant cells, however, was the same as in wild-type cells. A mixed culture of ICR 2A and DRP36 cells showed an intermediate inducible EPR depending upon the cell ratio. Inducible EPR was also detected at the DNA level in wild-type cells, but not in mutant cells.     

Redistribution of the CDK inhibitor p27 between different cyclin.CDK complexes in the mouse fibroblast cell cycle and in cells arrested with lovastatin or ultraviolet irradiation.

The cyclin-dependent kinase (CDK) inhibitor p27 binds and inhibits the kinase activity of several CDKs. Here we report an analysis of the behavior and partners of p27 in Swiss 3T3 mouse fibroblasts during normal mitotic cell cycle progression, as well as in cells arrested at different stages in the cycle by growth factor deprivation, lovastatin treatment, or ultraviolet (UV) irradiation. We found that the level of p27 is elevated in cells arrested in G0 by growth factor deprivation or contact inhibition. In G0, p27 was predominantly monomeric, although some portion was associated with residual cyclin A.Cdk2. During G1, all of p27 was associated with cyclin D1.Cdk4 and was then redistributed to cyclin A.Cdk2 as cells entered S phase. The loss of the monomeric p27 pool as cyclins accumulate in G1 is consistent with the in vivo and in vitro data showing that p27 binds better to cyclin.CDK complexes than to monomeric CDKs. In growing cells, the majority of p27 was associated with cyclin D1 and the level of p27 was significantly lower than the level of cyclin D1. In cells arrested in G1 with lovastatin, cyclin D1 was degraded and p27 was redistributed to cyclin A.Cdk2. In contrast to p21 (which is a p27-related CDK inhibitor and is induced by UV irradiation), the level of p27 was reduced after UV irradiation, but because cyclin D1 was degraded more rapidly than p27, there was a transient increase in binding of p27 to cyclin A.Cdk2. These data suggest that cyclin D1.Cdk4 acts as a reservoir for p27, and p27 is redistributed from cyclin D1.Cdk4 to cyclin A.Cdk2 complexes during S phase, or when cells are arrested by growth factor deprivation, lovastatin treatment, or UV irradiation. It is likely that a similar principle of redistribution of p27 is used by the cell in other instances of cell cycle arrest.     

Cell division transforms mutagenic lesions into deletion-recombinagenic lesions in yeast cells.

Cell proliferation has been recognized as an important factor in human and experimental carcinogenesis. Point mutations as well as larger chromosomal rearrangements are involved in the initiation of cancer. In this paper we compared the relative potencies of radiation and chemical carcinogens for inducing point mutations vs. deletions in cell cycle arrested with dividing cells of Saccharomyces cerevisiae. Point mutation substrates and deletion (DEL) recombination substrates were constructed with the genes CDC28 and TUB2 that are required for cell cycle progression through G1 and G2, respectively. The carcinogens ionizing radiation, UV, MMS, EMS and 4-NQO induced point mutations in G1 and in G2 arrested as well as in dividing cells. UV, MMS, EMS and 4-NQO caused very weak if any increases in DEL recombination in G1 or G2 arrested cells, but large increases in dividing cells. When cells treated with carcinogen either in G1 or G2 were allowed to progress through the cell cycle, a time-dependent increase in DEL recombination was seen. Ionizing radiation and the site-specific endonuclease I-SceI, which both directly create double-strand breaks, induced DEL recombination in G1 as well as in G2 arrested cells. In conclusion, UV-, MMS-, EMS- and 4-NQO-induced DNA damage was converted during DNA replication to a lesion capable of inducing DEL recombination which is probably a DNA strand break. Thus, cell proliferation is not necessary to turn DNA alkylation or UV damage into a mutagenic lesion but to convert the damage into a lesion that induces DNA deletions. These results are discussed with respect to mechanisms of carcinogenesis.     

Glyoxalase-I activity and cell cycle regulation in yeast

The status of glyoxalase-I was explored in exponentially growing and G₁ arrested temperature sensitive (ts) cell division cycle (cdc) mutants of Saccharomyces cerevisiae. It was observed that the specific activity of this enzyme was correlated with overall growth status. The activity was high in actively growing cells and was low in G₁ arrested cells. Specific activities of glyoxalase-I were also low in G₁ arrested prolonged stationary phase (PSP) cells of S. cerevisiae and Candida albicans. The activity of glyoxalase-I recovered when G₁ arrested S. cerevisiae (ts) cells were allowed to regrow under permissive conditions. Results demonstrate that although glyoxalase-I activity is a good indicator of cell growth status, it is not involved in cell cycle regulation of this eukaryotic organism.     

The synthesis of beta-galactosidase by constitutive and other regulatory mutants of Escherichia coli in chemostat culture.

The synthesis of beta-galactosidase by an E. coli constitutive mutant was examined in a chemostat using glucose-, glycerol-, succinate- or N-limited growth media. Except for glucose-grown bacteria, the steady-state intracellular level of beta-galactosidase was maximal at dilution rates between 0-2 and 0-3 h-1. At higher dilution rates enzyme synthesis was reduced by catabolite repression, which could be relieved by the addition of cyclic AMP. With a catabolite-resistant mutant (UV5c), no decrease in enzyme level at high dilution rates were observed. All mutants examined were constitutive and gave decreased enzyme levels at low dilution rates, with the exception of lac-/F'lac UV5c mutants where the enzyme levels rose at low dilution rates. Hyper-producing mutants were isolated but were unstable. A constitutive mutant growing on glycerol-limited media was considered the most suitable for large-scale production of beta-galactosidase in a chemostat.     

Induction of sister chromatid exchanges and chromosome aberrations in cho cells arrested in the cell cycle by arginine deprivation

Summary Sister chromatid exchanges (SCE) and chromosome aberrations were induced in nondividing CHO cells that had been arrested in their cell cycle by deprivation of the essential amino acid arginine. Cells arrested in arginine-deficient medium (ADM) were treated with one of the mutagenic agents N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) or mitomycin C (MMC) and refed with complete medium; the recovering cell population was sampled at various intervals thereafter and mitotic cells analyzed for the presence of chromosome aberrations and SCE. Both chemicals were observed to cause delays in the cell cycle of recovering cells and to induce, chromosome aberrations and SCE at low doses. We have described the variation in the incidence of chromosome aberrations and SCE with respect to sampling time and the number of cell cycles traversed. When ADM-arrested CHO cells were treated with three mutagens at various intervals either before or after release from ADM, it was observed that: (a) UV light induced the greatest number of SCE when applied to cells undergoing DNA synthesis, and SCE yeilds induced by this agent could be reduced by postirradiation incubation in ADM; (b) MNNG induced fewer SCE when applied to cells undergoing DNA synthesis, and SCE yields induced by this agent could not be reduced by posttreatment incubation in ADM for 24 hr. (c) MMC induced the same level irrespective of the time of exposure, and SCE yields induced by this agent could not be reduced by posttreatment incubation in ADM for 24 hr. This work was supported by grants from the British Columbia Foundation for Non-Animal Research (to W. D. M.), and the National Cancer Institute of Canada and the National Research Council of Canada (to H. F. S.). Professor H. F. Stich is a Research Associate of the NCI.     

Integration and scaling of UV‐B radiation effects on plants: from DNA to leaf

A process‐based model integrating the effects of UV‐B radiation through epidermis, cellular DNA, and its consequences to the leaf expansion was developed from key parameters in the published literature. Enhanced UV‐B radiation‐induced DNA damage significantly delayed cell division, resulting in significant reductions in leaf growth and development. Ambient UV‐B radiation‐induced DNA damage significantly reduced the leaf growth of species with high relative epidermal absorbance at longer wavelengths and average/low pyrimidine cyclobutane dimers (CPD) photorepair rates. Leaf expansion was highly dependent on the number of CPD present in the DNA, as a result of UV‐B radiation dose, quantitative and qualitative absorptive properties of epidermal pigments, and repair mechanisms. Formation of pyrimidine‐pyrimidone (6‐4) photoproducts (6‐4PP) has no effect on the leaf expansion. Repair mechanisms could not solely prevent the UV‐B radiation interference with the cell division. Avoidance or effective shielding by increased or modified qualitative epidermal absorptance was required. Sustained increased UV‐B radiation levels are more detrimental than short, high doses of UV‐B radiation. The combination of low temperature and increased UV‐B radiation was more significant in the level of UV‐B radiation‐induced damage than UV‐B radiation alone. Slow‐growing leaves were more affected by increased UV‐B radiation than fast‐growing leaves.     

Recovery of Saccharomyces cerevisiae mating-type a cells from G1 arrest by alpha factor.

Mating-type a cells of the yeast Saccharomyces cerevisiae that had been specifically arrested in the G1 phase of the cell cycle by alpha factor, an oligopeptide pheromone made by alpha cells, recovered and resumed cell division after a period of inhibition which was dependent on the concentration of alpha factor used. These treated a cells were more resistant to alpha factor than untreated a cells, but lost their resistance upon further cell division. However, cells arrested for 6 h were no more resistant to alpha factor than cells arrested for only 2.5 h. Mating-type a strains could inactivate or remove alpha factor from the culture fluid, but two a sterile (nonmating) mutants and an a/alpha diploid strain could not. These results suggest that a cells have a mechanism, which may involve uptake or inactivation of alpha factor, for recovering from alpha factor arrest. However, the results do not distinguish between a recovery mechanism which is constitutive and one which is induced by alpha factor. The loss of alpha factor activity during recovery appeared to be primarily cell contact mediated, although an extracellular, diffusible inhibitor of alpha factor that is labile or that functions stoichiometrically could not be ruled out.     

Effects of DNA double-strand and single-strand breaks on intrachromosomal recombination events in cell-cycle-arrested yeast cells.

Intrachromosomal recombination between repeated elements can result in deletion (DEL recombination) events. We investigated the inducibility of such intrachromosomal recombination events at different stages of the cell cycle and the nature of the primary DNA lesions capable of initiating these events. Two genetic systems were constructed in Saccharomyces cerevisiae that select for DEL recombination events between duplicated alleles of CDC28 and TUB2. We determined effects of double-strand breaks (DSBs) and single-strand breaks (SSBs) between the duplicated alleles on DEL recombination when induced in dividing cells or cells arrested in G1 or G2. Site-specific DSBs and SSBs were produced by overexpression of the I-Sce I endonuclease and the gene II protein (gIIp), respectively. I-Sce I-induced DSBs caused an increase in DEL recombination frequencies in both dividing and cell-cycle-arrested cells, indicating that G1- and G2-arrested cells are capable of completing DSB repair. In contrast, gIIp-induced SSBs caused an increase in DEL recombination frequency only in dividing cells. To further examine these phenomena we used both gamma-irradiation, inducing DSBs as its most relevant lesion, and UV, inducing other forms of DNA damage. UV irradiation did not increase DEL recombination frequencies in G1 or G2, whereas gamma-rays increased DEL recombination frequencies in both phases. Both forms of radiation, however, induced DEL recombination in dividing cells. The results suggest that DSBs but not SSBs induce DEL recombination, probably via the single-strand annealing pathway. Further, DSBs in dividing cells may result from the replication of a UV or SSB-damaged template. Alternatively, UV induced events may occur by replication slippage after DNA polymerase pausing in front of the damage.     

Differential distribution of B16F10 melanoma cells in the liver lobule

The distribution pattern and the number of tumor cells arrested in the liver were studied in mouse livers. Mice were perfused intravascularly with a suspension of B16F10 melanoma cells. The animals were sacrificed at 0, 1, 5, and 20 min after tumor cell perfusion. The pattern of tumor cell distribution was studied by morphological methods, and by a combined method of fluorescent-tumor cell labelling and histochemical succinate dehydrogenase activity on frozen sections, in order to define the localization of tumor cells arrested in the liver lobule. The results show that the tumor cells have an exclusive distribution in the periportal regions of the liver lobule (identified as the high succinate dehydrogenase activity areas), and that the cells are not arrested in the pericentral regions (identified as the low succinate dehydrogenase activity areas). In addition, indomethacin treatment (2 mg/kg/day) induced an increase in the number of melanoma cells arrested in the liver, but a different distribution with respect to controls was not observed. These results show that periportal regions of the liver lobule constitute a particular domain in which the B16F10 melanoma cells present a special retention ability that can be modulated by indomethacin treatment.     

Variations in constitutive and inducible UV-B tolerance; dissecting photosystem II protection in Arabidopsis thaliana accessions

The rise in ultraviolet-B (UV-B) (280–315 nm) radiation levels, that is a consequence of stratospheric ozone layer depletion, has triggered extensive research on the effects of UV-B on plants. Plants raised under natural sunlight conditions are generally well protected from the potentially harmful effects of UV-B radiation. However, it is mostly unknown to which extent UV protection is constitutive and/or induced. In this study, we have analysed the role of constitutive and inducible protection responses in avoiding UV-B damage to photosystem II of photosynthesis. We have assayed the UV susceptibility of photosystem II in 224 Arabidopsis thaliana accessions from across the Northern hemisphere, and found a continuum of constitutive UV-protection levels, with some accessions being UV sensitive and others UV tolerant. Statistical analysis showed only very weak associations between constitutive UV tolerance and the geographic origin of accessions. Instead, most of the variance in constitutive UV-B protection of photosynthesis is present at the level of local Arabidopsis populations originating in the same geographic and climatic area. The variance in constitutive UV protection is, however, small compared to the amplitude of environmentally induced changes in UV protection. Thus, our data emphasise the importance of inducible responses for the protection of photosystem II against UV-B. Remarkably, the conditions that induce UV-protective responses vary; accessions from lower latitudes were found to switch-on UV defences more readily than those of higher latitudes. Such altered regulation of induction may comprise a suitable adaptation response when levels of a stressor are fluctuating in the short term, but predictable over longer periods.     

The effects of long-term elevated UV-B on the growth and phenolics of field-grown silver birch (Betula pendula)

The effects of long‐term elevated UV‐B radiation on silver birch (Betula pendula Roth) seedlings were studied over three growing seasons in an outdoor experiment in Finland started 64 days after germination. One group of seedlings was exposed to a constant 50% increase in UV‐B_CIE radiation, which corresponds to 20–25% of ozone depletion; another group received a small increase in UV‐A radiation and a third (the control group) received ambient solar radiation. Changes in growth appeared during the third growing season; the stems of the UV‐B treated seedlings were thinner and their height tended to be shorter compared with that of the control seedlings. In contrast, there were no UV‐B effects on biomass, bud burst, bud dry weights, leaf area, rust frequency index or chlorophyll concentrations in any of the summers. During the three‐year study, the flavonols were significantly increased by the elevated UV‐B only in the first growing season. The responses varied greatly among individual compounds; the most induced were the quercetin glycosides, while the main flavonols, myricetins, were reduced by the UV‐A control treatment. In the second summer phenolic acids, such as 3,4′‐dihydroxypropiophenone‐3‐glucoside, neochlorogenic acid and 5‐coumarylquinic acid, were increased by the UV‐B treatment. In the third year, the constitutive concentrations of phenolics were not affected by the UV‐B treatment.     

The effect of inhibition of protein synthesis on UV-irradiatedescherichia coli uvrE cells

The uvrE (E. coli KS 114) cells carry a mutation in the gene that codes for helicase II. This is the protein responsible for replicative unwinding of double-helical DNA. The repair mode of such cells may be altered as compared with the wild type. The survival of uvrE cells during postirradiation incubation under inhibition of de novo protein synthesis was increased which indicates that this process of repair in uvrE cells is mediated by constitutive proteins and does not require any inducible products but takes a certain time. This inhibition of de novo protein synthesis causes also an inhibition of dimer excision, an increase of the parental DNA degradation and a decrease of parental and daughter DNA molar mass. On the other hand, it seems that induced proteins are formed in uvrE cells after UV irradiation but their influence is low in inducible repair and they can act only under conditions of complete protein synthesis.     

Detection of intracellular forms of secretory aspartic proteinase in Candida albicans.

The extracellular proteinase (EPR) of Candida albicans was induced in a medium containing bovine serum albumin as sole nitrogen source. There were two intracellular forms in cells induced to produce EPR, a 43 kDa protein (EPR) and a 45 kDa protein (cross-reacting material of EPR; CRM-EPR); these were detected by immunoblotting using anti-EPR antiserum. The 43 kDa protein (EPR) may be the same as the extracellular form judging by molecular mass, and the 45 kDa protein (CRM-EPR) may be a precursor form of EPR. Many dense granules were observed by electron microscopy near the plasma membrane of the mother cells in EPR-producing cells. Both the 43 and 45 kDa proteins were recovered in a membrane fraction and were solubilized by Triton X-100. When the membrane fraction was further fractionated by sucrose density gradient centrifugation, the 43 and 45 kDa proteins were differentially fractionated. This suggests that they were located in different membrane-bound structures and is consistent with an assumption that the 45 kDa protein is a precursor for EPR.     

Epidermal growth factor receptors lose ligand binding ability as WI-38 cells progress from short-term to long-term quiescence

WI-38 cells, density arrested for short periods of time, can be stimulated to re-enter the cell cycle by epidermal growth factor (EGF) alone. However, cells density arrested for longer periods have a prolonged prereplicative phase when serum stimulated and cannot be stimulated by EGF alone. Radio-ligand binding studies performed on WI-38 cells showed that actively growing cells bind [¹²⁵I]EGF at relatively low levels that increase to a maximum as the cells become contact inhibited. As the cells enter a state of deeper quiescence, EGF binding falls to one-third to one-fifth the short-term growth arrested levels, remaining constant thereafter. The EGF-receptor complexes internalize more slowly in long-term growth arrested cells, and the rate of ligand association to the receptor is lower than short-term growth arrested cells. The amount of EGF receptor protein in lysates of equal numbers of both short- and long-term quiescent cells remains the same. These results suggest that the failure of long-term growth arrested cells to respond to EGF is not due to dramatic changes in the amount of receptor protein during prolonged quiescence but more likely to an alteration in the ability of these receptors to bind ligand and/or activate the EGF signal transduction pathway. © 1993 Wiley-Liss, Inc.     

Induction of human cell DNA synthesis by herpes simplex virus type 2.

The effect of herpes simplex virus type 2 (HSV-2) infection on the synthesis of DNA in human embryonic fibroblast cells was determined at temperatures permissive (37 C) and nonpermissive (42 C) for virus multiplication. During incubation of HSV-2 infected cultures at 42 C for 2 to 4 days or after shift-down from 42 to 37 C, incorporation of (3H)TdR into total DNA was increased 2-to 30-fold as compared with mock-infected cultures. Analysis of the (3H)DNA suggested that host cell DNA synthesis was induced by HSV-2 infection. Induction of host cell DNA synthesis by HSV-2 also occurred in cells arrested in DNA replication by low serum concentration. The three strains of HSV-2 tested were capable of stimulating cellular DNA synthesis. Virus inactivated by UV irradiation, heat, or neutral red dye and light did not induce cellular DNA synthesis, suggesting that an active viral genome is necessary for induction.     

Nifedipine reversibly arrests mitosis in stamen hair cells of tradescantia

Mitotic stamen hair cells of Tradescantia virginiana (cv. Zwanenburg Blue) become arrested in metaphase following a 30-min treatment with 10 to 100 microM nifedipine, a Ca2+-channel entry blocker. The time interval between nuclear envelope breakdown and anaphase onset in untreated cells is approximately 33 min +/- 4 min; nifedipine extends this "metaphase transit time" beyond 70 min. Nifedipine can be photoreversed in situ by exposure to 365 nm light. UV illumination inactivates the drug, its inhibitory effect on Ca2+ is abolished, and cells arrested in metaphase enter anaphase within 3 to 18 min of UV exposure if CaCl2 is present in the medium. The interval between UV illumination and anaphase onset is inversely related to the extracellular concentration of CaCl2. If CaCl2 is not added to the medium, the interval between UV exposure and anaphase onset is usually longer than 18 min. The sole addition of 100 microM CaCl2 to the medium is insufficient to reverse nifedipine inhibition; unless the cells are exposed to UV light, anaphase will not commence. The threshold concentration of free Ca2+ for rapid anaphase onset (less than 10 min after UV photoreversal) is between 1 and 10 microM. These results suggest that an influx of Ca2+ from the extracellular medium to the cytosolic compartment is necessary for normal progression from metaphase to anaphase and that this influx may serve as a trigger for chromosome separation.     

Fine structural and cytochemical studies of human diploid fibroblasts arrested in an essentially nonmitotic state.

Human diploid fibroblasts can be maintained in vitro in an arrested, essentially nonmitotic state for extended periods of time by reducing the serum concentration in the medium from 10 to 0.5%. Arrested cells can be induced to re-enter the proliferative state by subcultivation in medium containing 10% serum. Fine structure, acid phosphatase, cytochrome oxidase, and extracellular carbohydrates in arrested cells were examined and compared to cultures growing in 10% serum and to cells transferred to 10% serum after 21 days in 0.5% serum. Cells in 10% serum posessed a well-developed Golgi complex, extensive rough endoplasmic reticulum, mitochondria containing transverse cristae, and many free ribosomes in the cytoplasm. In arrested cells, Golgi complexes were rarely observed, the number of both free and membrane-bound ribosomes was reduced, the number of cristae per mitochondria was decreased and the amount of demonstrable cytochrome oxidase activity was diminished. There was an accumulation of intercellular carbohydrate components. After subcultivation with medium containing 10% serum, arrested cells regained the ultrastructural characteristics of cells continuously cultured at this serum level; however, the amount of intercellular carbohydrate remained elevated. These results indicate that distinct yet reversible changes occur in the subcellular morphology and organization of cells maintained in an essentially nonmitotic state. This arrested state may be a close approximation to the situation as it occurs in vivo in expanding cell populations.     

Fine structural and cytochemical studies of human diploid fibroblasts arrested in an essentially nonmitotic state

Summary Human diploid fibroblasts can be maintained in vitro in an arrested, essentially nonmitotic state for extended periods of time by reducing the serum concentration in the medium from 10 to 0.5%. Arrested cells can be induced to re-enter the proliferative state by subcultivation in medium containing 10% serum. Fine structure, acid phosphatase, cytochrome oxidase, and extracellular carbohydrates in arrested cells were examined and compared to cultures growing in 10% serum and to cells transferred to 10% serum after 21 days in 0.5% serum. Cells in 10% serum possessed a well-developed Golgi complex, extensive rough endoplasmic reticulum, mitochondria containing transverse cristae, and many free ribosomes in the cytoplasm. In arrested cells, Golgi complexes were rarely observed, the number of both free and membranebound ribosomes was reduced, the number of cristae per mitochondrion was decreased and the amount of demonstrable cytochrome oxidase activity was diminished. There was an accumulation of intercellular carbohydrate components. After subcultivation with medium containing 10% serum, arrested cells regained the ultrastructural characteristics of cells continuously cultured at this serum level; however, the amount of intercellular carbohydrate remained elevated. These results indicate that distinct yet reversible changes occur in the subcellular morphology and organization of cells maintained in an essentially nonmitotic state. This arrested state may be a close approximation to the situation as it occurs in vivo in expanding cell populations.