Inhibition and recovery of ribosomal RNA synthesis in ultraviolet-irradiation mammalian cells

Cellular responses to hematoporphyrin-induced photooxidative damage in Fanconi anemia, xeroderma pigmentosum and normal human fibroblasts

Several observations reported in the literature suggest that singlet oxygen (1O2) might play a role in the clastogenic process in Fanconi anemia (FA) cells, and that the antioxidant status of xeroderma pigmentosum (XP) may also be altered. In order to test the ability of FA and XP cells, relative to normal cells, to cope with 1O2 damage, the effects of photosensitization by hematoporphyrin (HP) have been determined (i) on host cell reactivation (HCR) of damaged infecting herpes simplex virus (HSV) or transfecting SV40 DNA, and (ii) on DNA template capability and clonogenicity of treated cells. Results showed no significant difference among the three types of cells, either for the survival of HP-photosensitized HSV, or for the yields of SV40 virus following transfection of cultures with damaged viral DNA. The treatment of cells with HP plus 365-nm light leads to a dose-dependent, homothetic reduction of 18S and 28S ribosomal RNA (rRNA) synthesis, presumably through a mechanism other than the formation of transcription termination sites. After a 24-h post-exposure incubation, the rate of rRNA synthesis was restored to higher than normal levels in all cell lines. Finally, two FA cell lines showed a higher survival to HP photosensitization than two normal cell lines. Another FA cell line and XP-A and XP-C cells were in the range of sensitivity of the two normal strains for this treatment. These results indicate that FA cells possess an antioxidant defense system at least as efficient as that of normal cells for processing 1O2-induced damage.

A Drosophila model for xeroderma pigmentosum and Cockayne's syndrome: haywire encodes the fly homolog of ERCC3, a human excision repair gene

The haywire gene of Drosophila encodes a protein with 66% identity to the product of the human ERCC3 gene, associated with xeroderma pigmentosum B (XP-B) and Cockayne's syndrome (CS). XP is a human autosomal recessive disease characterized by extreme sensitivity to ultraviolet irradiation and marked susceptibility to skin cancer. In addition, XP and CS patients often exhibit a variety of defects, ranging from central nervous system disorders to hypogonadism. Phenotypes of haywire mutants mimic some of the effects of XP. Many haywire alleles are recessive lethal, viable alleles cause ultraviolet sensitivity, and files expressing marginal levels of haywire display motor defects and reduced life span. Progeny of females carrying a maternal effect allele show central nervous system defects.

Oxidative and other DNA damages as the basis of aging: a review

DNA damages occur continuously in cells of living organisms. While most of these damages are repaired, some accumulate. In particular, there is evidence for DNA damage accumulation in non-dividing cells of mammals. These accumulated DNA damages probably interfere with RNA transcription. We consider that the decline in the ability of DNA to serve as a template for gene expression is the primary cause of aging. Oxidative DNA damages are among the best documented and prevalent DNA damages and are likely to be a prominent cause of aging.

A reduced rate of bulky DNA adduct removal is coincident with differentiation of human neuroblastoma cells induced by nerve growth factor

Human SY5Y neuroblastoma cells which were differentiated in culture by treatment with 7S murine nerve growth factor for 5 weeks and selection with aphidicolin (L. Jensen, Dev. Biol. 120:56-64, 1987) demonstrated a considerably slower rate of removal of DNA adducts of benzo[a]pyrene, benzo[a]pyrenediolepoxide, and N7-methylguanine than did undifferentiated mitotic cells. A dramatic decline in unscheduled DNA synthesis induced by UV radiation was similarly observed. DNA polymerase beta and uracil DNA glycosylase were unchanged after differentiation, DNA polymerase alpha and DNA methylase decreased roughly threefold, and total apurinic-apyrimidinic endonuclease activity increased roughly threefold after treatment.

A reduced rate of bulky DNA adduct removal is coincident with differentiation of human neuroblastoma cells induced by nerve growth factor

Human SY5Y neuroblastoma cells which were differentiated in culture by treatment with 7S murine nerve growth factor for 5 weeks and selection with aphidicolin (L. Jensen, Dev. Biol. 120:56-64, 1987) demonstrated a considerably slower rate of removal of DNA adducts of benzo[a]pyrene, benzo[a]pyrenediolepoxide, and N7-methylguanine than did undifferentiated mitotic cells. A dramatic decline in unscheduled DNA synthesis induced by UV radiation was similarly observed. DNA polymerase beta and uracil DNA glycosylase were unchanged after differentiation, DNA polymerase alpha and DNA methylase decreased roughly threefold, and total apurinic-apyrimidinic endonuclease activity increased roughly threefold after treatment.

Inhibition of DNA replication and repair by cadmium in mammalian cells. Protective interaction of zinc

The effects of the treatment of cultured human and simian cells with Cadmium (Cd), a toxic and carcinogenic metal, were first assayed on macromolecular synthesis. It was observed that DNA synthesis was inhibited by Cd concentrations considerably lower than those inhibiting protein and RNA synthesis. Because of the necessary occurrence of a DNA resynthesis step during the DNA excision repair process, the consequences of the exposure of cells to Cd were ulteriorly tested on different parameters measuring DNA repair after ultraviolet (UV) damage. UV-induced unscheduled DNA synthesis (UDS) was found 2-3 times lower in Cd (4 X 10(-6) M) treated cells than in control cells for UV doses higher than 10 J/m2. DNA breaks accumulated in UV-irradiated cells during post-exposure incubation in presence of Cd, whereas they were induced only transiently in control cells irradiated with the same dose. Cd inhibited in a concentration-dependent way the recovery of RNA transcription impaired by UV-irradiation. However, at concentrations used, Cd had no significant effects on DNA size and on rRNA synthesis in unirradiated cells. Finally, Cd was shown to inhibit the repair of potentially lethal damage during a 24 h liquid holding and to increase the toxicity of UV-irradiation. The interactions between Cd and Zinc (Zn), an essential metal for many enzymatic proteins, were also analysed. Results showed that Zn, at 5 to 10 times higher concentrations, counteracts the inhibitory effects of Cd on DNA synthesis and restores, at least partially, the repair capability of cells and their survival. The possible molecular level and mechanism of action of these metals are discussed.

The molecular basis of the evolution of sex

Traditionally, sexual reproduction has been explained as an adaptation for producing genetic variation through allelic recombination. Serious difficulties with this explanation have led many workers to conclude that the benefit of sex is a major unsolved problem in evolutionary biology. A recent informational approach to this problem has led to the view that the two fundamental aspects of sex, recombination and outcrossing, are adaptive responses to the two major sources of noise in transmitting genetic information, DNA damage and replication errors. We refer to this view as the repair hypothesis, to distinguish it from the traditional variation hypothesis. On the repair hypothesis, recombination is a process for repairing damaged DNA. In dealing with damage, recombination produces a form of informational noise, allelic recombination, as a by-product. Recombinational repair is the only repair process known which can overcome double-strand damages in DNA, and such damages are common in nature. Recombinational repair is prevalent from the simplest to the most complex organisms. It is effective against many different types of DNA-damaging agents, and, in particular, is highly efficient in overcoming double-strand damages. Current understanding of the mechanisms of recombination during meiosis suggests that meiosis is designed for repairing DNA. These considerations form the basis for the first part of the repair hypothesis, that recombination is an adaptation for dealing with DNA damage. The evolution of sex can be viewed as a continuum on the repair hypothesis. Sex is presumed to have arisen in primitive RNA-containing protocells whose sexual process was similar to that of recombinational repair in extent segmented, single-stranded RNA viruses, which are among the simplest known organisms. Although this early form of repair occurred by nonenzymatic reassortment of replicas of undamaged RNA segments, it evolved into enzyme-mediated breakage and exchange between long DNA molecules. As some lines of descent became more complex, their genome information increased, leading to increased vulnerability to mutation. The diploid stage of the sexual cycle, which was at first transient, became the predominant stage in some lines of descent because it allowed complementation, the masking of deleterious recessive mutations. Out-crossing, the second fundamental aspect of sex, is also maintained by the advantage of masking mutations. However, outcrossing can be abandoned in favor of parthenogenesis or selfing under conditions in which the costs of mating are very high.(ABSTRACT TRUNCATED AT 400 WORDS)

DNA photobinding of 7-methylpyrido[3,4-c]psoralen and 8-methoxypsoralen. Effects on macromolecular synthesis, repair and survival in cultured human cells

The photobinding to DNA of tritiated 7-methylpyrido[3,4-c]psoralen (MPP), a recently synthesized monofunctional compound of therapeutical interest, and of 8-methoxypsoralen (8-MOP) was determined in cultured normal human fibroblasts. Employing compounds at 10(-6) M, MPP photobinds approximately 11 times more efficiently than 8-MOP: one molecule is fixed respectively per 7.5 X 10(4) or 8.1 X 10(5) base pairs/kJ . m-2 of 365-nm radiation (UVA). Removal of bound material from DNA is slow and limited in 48-72 h of post-treatment incubation to 30-40% of initial adducts formed by MPP and to 50-60% of those of 8-MOP. For equivalent photobinding MPP and 8-MOP induce similar inhibitions of DNA synthesis. However, the recovery of DNA synthesis during post-treatment incubation is lower after photoaddition of MPP than after that of 8-MOP. MPP also exerts a much higher lethal effect than 8-MOP: one lethal hit corresponds to about 4400 and to 19,900 adducts per cell respectively. Alkaline elution experiments confirmed the monofunctional nature of MPP and indicated that in MPP-damaged cells DNA breaks accumulate with time of post-treatment incubation. In contrast, after photoaddition of 3-carbethoxypsoralen (3-CPs), another monofunctional furocoumarin, or irradiation with 254-nm UV, DNA breaks are induced only transiently. In 8-MOP-treated cells, DNA cross-links appear to be partially repaired. In conclusion, MPP monoadducts turn out to constitute more cytotoxic lesions than 8-MOP mono- and bi-adducts.

Genetic damage, mutation, and the evolution of sex

The two fundamental aspects of sexual reproduction, recombination and outcrossing, appear to be maintained respectively by the advantages of recombinational repair and genetic complementation. Genetic variation is produced as a by-product of recombinational repair, but it may not be the function of sexual reproduction.

The evolutionary role of recombinational repair and sex

We have argued that sexual reproduction arose very early in the evolution of life as a way of overcoming informational damage or loss through recombinational repair. As organisms became more complex and genome information content expanded, diploidy, at first transient, became the predominant way of coping with increased vulnerability to mutation. This allowed further genome expansion. Once such expansion had occurred, however, diploidy became essentially irreversible, since reversion to haploidy would lead to expression of accumulated deleterious recessive alleles. This expression of recessive alleles also imposes a stiff penalty on organisms that experiment with close inbreeding forms of recombinational repair. A consequence of sex is that fitness (defined as per capita rate of increase) is density dependent. At low population density, fitness declines due to increased costs of finding a mate. This fundamental constraint on population increase can inhibit evolutionary success of the best adapted species if it is small in numbers. Sexual reproduction also tends to eliminate new coadapted genotypes within a species by breaking up their coadapted gene complexes; this also contributes to the cohesion of species. In general, we think the existence of species and their characteristic cohesion and stability over time are direct consequences of sex; and sex in turn is a consequence of the need to overcome gene damage through recombinational repair while at the same time masking the deleterious effects of mutation.

Plasminogen activator: analysis of enzyme induction by ultraviolet irradiation mapping

Ultraviolet irradiation mapping techniques have previously been used to study the organization of eucaryotic gene classes and transcription units. We used the same method to probe some regulatory phenomena observed in the induction of plasminogen activator (PA) biosynthesis: PA synthesis in chicken embryo fibroblasts is induced by tumor-promoting phorbol esters and by retinoic acid; furthermore, PA induction by phorbol esters is synergistic with transformation, being 10- to 20-fold greater in virus-transformed cells than in normal cells. We found that the ultraviolet irradiation inactivation cross sections for PA induction by phorbol esters and by retinoate differed significantly, suggesting that these agents induce PA biosynthesis by different mechanisms. On the other hand, the ultraviolet irradiation sensitivity of phorbol ester induction in normal chicken embryo fibroblasts was the same as in transformed cells, indicating that the synergism of transformation and phorbol esters is probably not due to different pathways of PA induction.

Mechanisms of tolerance to DNA lesions in mammalian cells

In recent years it has become clear that different pathways are involved in the process of removing lesions from DNA. In spite of a continuous surveillance of the genetic integrity by repair enzymes, quite often lesions are not eliminated before the portion of the genome where they have been inserted is used for DNA replication or transcription. Actually, the number of unexcised lesions a cell can tolerate without significantly losing its capacity to reproduce is surprising. As an example, human fibroblasts from certain patients with the genetic disease xeroderma pigmentosum (XP)† are virtually unable to excise pyrimidine dimers, the major DNA lesion produced by short-wavelength UV light.

Survival, DNA synthesis and ribosomal RNA transcription in monkey kidney cells treated by formaldehyde

Separate cultures of CV-1 cells were exposed for 15 min to 1-16 mM formaldehyde (FA) at various time intervals before labeling with [3H]uridine. The labeled RNA extracted from whole cells was analyzed by polyacrylamide gel electrophoresis. Results indicated that FA produced transcription-terminating lesions in DNA which depressed RNA synthesis, gave rise to shortened RNA chains and modified the expression of transcription-linked genes. These lesions were efficiently repaired since a recovery of RNA transcription, with disappearance of the initially observed alterations, rapidly occurred during post-treatment incubation of cells. Cycloheximide (5 micrograms/ml) strongly inhibited this recovery, whereas fluorodeoxyuridine (10(-5) M) was without effect. The rate of semi-conservative DNA synthesis, measured autoradiographically by thymidine incorporation, as well as the number of cells performing DNA replication, fell to zero after 15-min exposure to FA concentrations greater than 2 mM. Both parameters recovered subnormal levels during a 24-h incubation after treatment with FA concentration up to 8 mM, in agreement with the high survival observed. Unscheduled DNA synthesis was not detectable during the restoration of DNA and RNA synthesis.

Survival and herpes virus production of normal and xeroderma pigmentosum fibroblasts after treatment with formaldehyde

The survival of excision-deficient and of excision-proficient (variant) skin fibroblasts from xeroderma pigmentosum (XP) donors was about 5 times and twice, respectively, more sensitive to formaldehyde (FA) treatment than that of skin fibroblasts from healthy and XP heterozygote donors. The capacity of FA-treated host cells to further support Herpes virus (HSV) replication was also more sensitive to FA in XP12BE (group A) than in normal (KD) cells. An important recovery of this capacity occurred in both cell types when they were infected at increasing times (up to 36 h) after FA treatment. This contrasts with the decreasing capacity observed in XP12BE when similarly infected at increasing times after exposure to ultraviolet. In addition, the survival of FA-treated HSV was comparable in KD and XP12BE cells, whereas that of UV-irradiated HSV was much lower in XP12BE than in KD cells.

Herpes virus production as a marker of repair in ultra-violet irradiated human skin cells of different origin

Confluent cultures of human skin fibroblasts were irradiated with ultra-violet light 0 to 48 hours before infection with herpes simplex virus type 1 (HSV). The one-cycle viral yield was measured. Different responses were obtained according to the origin of the host cells. (1) Cells from three normal donors showed a dose-dependent recovery of HSV production during the 36--40 hours following U.V. exposure. The recovery was maximal for a dose at which a plateau level of unscheduled DNA synthesis (UDS) was reached (24 Jm-2). (2) In a xeroderma pigmentosum (XP) heterozygote line from a mother of XP children, the level of UDS after irradiation up to 48Jm-2 was normal whereas the extent of recovery of HSV production capacity was lower than that of the normal lines. (3) In strains from two cases of XP children, with a normal UDS (XP variants), the recovery process was slowed down and its extent was lower than in normal or XP heterozygote cells. (4) Excision-deficient XP strains from eight cases of XP children presented either no recovery (two strains having the lowest UDS, less than 2 per cent) or a small recovery, the extent of which was in good agreement with the corresponding level of UDS (between 5 and 30 per cent). Measurement of this recovery seems to be a very sensitive assay for detecting differences in the repair abilities of U.V.-irradiated human skin cells of various origins.

Impairment of RNA synthesis and its recovery in angelicin photosensitized mammalian cells. A probe for DNA damage and repair

The template activity of DNA for ribosomal RNA transcription has been investigated in monkey kidney CV-1 cells after angelicin photosensitization in order to monitor the induction of lesions in the DNA and their possible subsequent disappearance, i.e. repair. Separate confluent cultures were submitted to a single angelicin treatment at different time intervals before incubation with [3H]uridine. The labeled RNA prepared from whole cells was analysed by polyacrylamide-agarose gel electrophoresis. The results indicate that: Angelicin monoadditions on DNA constitute transcription-terminating lesions which depress overall RNA synthesis, give rise to shortened RNA chains and modify the expression of transcriptional linked genes. CV-1 cells are able to repair, at least partially, the induced transcription-terminating lesions and progressively recover RNA synthesis with a reversion of the initially observed modifications. The repair seems to be independent of semiconservative DNA synthesis since fluorodeoxyuridine does not affect the recovery of RNA transcription. The present work also confirms the arrangement of rRNA genes in tandem behind a common operator in the order 18--28 S as previously determined in the same cells by a radiological mapping technique and reinforces the potential applicability of transcription analysis to the study of repair processes operating on physically or chemically induced damage in DNA.

DNA ligase activity in UV-irradiated monkey kidney cells

The DNA ligase activity of monkey kidney CV-1 cells has been measured at different stages of culture growth and after different time intervals following ultraviolet irradiation. Results indicate that: - The level of enzyme activity is about twice higher in non synchronous, rapidly dividing cells than in confluent cultures. - UV-irradiation of cells induces a "de novo" synthesis of DNA ligase. - This induction is dose dependent in its extent and kinetics, and may lead to a DNA ligase level in UV-irradiated stationary cultures of the same order as observed in unirradiated exponentially growing cells. - This induction seems to be independent of semiconservative DNA synthesis since it is not affected by fluorodeoxyuridine.

Effects of ultraviolet irradiation and postirradiation incubation on heterogenous nuclear RNA size in murine cells

We have analyzed the decrease in synthesis of individual size classes of heterogeneous nuclear RNA (hnRNA) in ultraviolet (UV)-irradiated Merwin plasmacytoma (MPC-11) cells at various times of postirradiation incubation. HnRNA from nonirradiated control cells is distributed over a wide range from approximately 60S to 5S, with 42S RNA carrying more label than any other size class. HnRNA from UV-irradiated cells shows a dose-dependent shift in size distribution toward lower molecular weight. The size distribution of hnRNA synthesized after prolonged times of postirradiation incubation is restored toward normal, i.e., synthesis of long RNA molecules increases relative to the synthesis of short ones. Analysis of the total number of hnRNA chains synthesized during a 20-min [(3)H]uridine pulse shows a considerable reduction in their number with increasing UV dose. Murine cell lines are excision-repair-deficient but capable of post replication repair inhibited by caffeine. HnRNA transcripts of cells incubated in its presence were studied. The caffeine, which has no effect on hnRNA size in control cells, inhibits to a considerable extent the restoration of full-length transcripts during postirradiation incubation. The lack of excision repair in MPC-11 was confirmed by the analysis of pyrimidine dimers in trichloracetic acid-insoluble and soluble fractions within 8 h of postirradiation incubation.The size of parental and daughter strand DNA in UV-irradiated cells was correlated with RNA transcript size. The parental DNA in these experiments does not change its size as a consequence of UV exposure and postirradiation incubation. In contrast, daughter DNA strands are short in UV-irradiated cells and they increase in size during postirradiation incubation to reach the size of parental strands after 8 h.