The influence of thymine and 5-bromouracil on the sensitivity ofEscherichia coli to alkylation,UV and X-irradiation

The influence is followed of an alkylating agent (triethylene-melamine) UV and X-irradiation on the survival ofEscherichia coli 15 T∋ells grown in a minimal medium containing enzymatic hydrolysate of caseine. Thymine-less death of a considerable number of cells was observed in a culture grown in this medium. A conclusive difference in the sensitivity to the lethal agents used was found between a culture grown in a thymine-less medium and bacteria grown in a medium containing excess (20 μg/ml) of thymine. The culture grown with a sufficient thymine concentration was more sensitive to alkylation and X-rays, whereas bacteria surviving conditions of thymine-less death were more resistant to the above agents. However, such cells were more sensitive to UV-irradiation. The differences found are discussed from the point of view of DNA concentrations found in the individual cultures.     

Enhancement of the uvrA gene dosage reduces pyrimidine dimer excision in UV-irradiated Escherichia coli

E. coli possesses an efficient repair mechanism able to remove pyrimidine dimers from UV-irradiated DNA, which is catalyzed by UvrABC endonuclease. In E. coli B/r Hcr⁺ cells transformed with a multicopy plasmid harboring a gene coding for UvrA, the excision capacity was greatly reduced. The course of thymine dimer excision was investigated using the enzymatic as well as the radiochromatographic method and the results are discussed in term of nonspecific interaction between the excess of UvrA protein and undamaged DNA duplex.     

Establishment of a monoclonal antibody recognizing cyclobutane-type thymine dimers in DNA: a comparative study with 64M-1 antibody specific for (6-4)photoproducts

We obtained a monoclonal antibody (TDM-1) binding to 313-nm UV-irradiated DNA in the presence of acetophenone. The binding of TDM-1 to 254-nm UV-irradiated DNA was not reduced with the subsequent irradiation of 313-nm UV. Furthermore, the treatment of UV-irradiated DNA with photolyase from E. coli and visible light exposure reduced both the antibody binding and the amount of thymine dimers in the DNA. A competitive inhibition assay revealed that the binding of TDM-1 to UV-irradiated DNA was inhibited with photolyase, but not with 64M-1 antibody specific for (6-4)photoproducts. These results suggest that TDM-1 antibody recognizes cyclobutane-type thymine dimers in DNA. Using TDM-1 and 64M-1 antibodies, we differentially measured each type of damage in DNA extracted from UV-irradiated mammalian cells. Repair experiments confirm that thymine dimers are excised from UV-irradiated cellular DNA more slowly than (6-4)photoproducts, and that the excision rates of thymine dimers and (6-4)photoproducts are lower in mouse NIH3T3 cells than in human cells.     

Analysis of differential sensitivities of synchronized HeLa S3 cells to radiations and chemical carcinogen during the cell cycle. II. Ultraviolet light

UV-induction of thymine dimers in cellular DNA and their excision during different phases of the cell cycle of HeLa S3 cells were studied. Induction of thymine dimers was higher in the mitotic phase and the middle of the S phase than in the G₁ phase and from the late S phase to the early G₂ phase which are rather insensitive to UV. However, there is no significant difference in excision rate of UV-induced thymine dimers from the irradiated cells through the cell cycle. These findings indicate that the cyclic variation of UV-survivals during the cell cycle may be due to differences in the amount of thymine dimers in cellular DNA induced by UV-irradiation.     

The kinetics of thymine dimer excision in ultraviolet-irradiated human cells

We have investigated the kinetics of the loss of thymine dimers from the acid-insoluble fraction of several ultraviolet (UV)-irradiated cultured human cell lines. Our results show that UV fluences between 10 and 40 J/m2 produce an average of 21-85 x 10(5) thymine dimers per cell and an eventual maximal loss per cell of 12-20 x 10(5) thymine dimers. The time for half-maximal loss of dimers ranged from 12-22 h after UV irradiation. In contrast, the time for half-maximal repair synthesis of DNA measured by autoradiography was 4.5 h. This figure agrees well with reported half-maximal repair synthesis times, which range from 0.5 to 3.6 h based on our analysis. The discrepancy in the kinetics of the loss of thymine dimers from DNA and repair synthesis is discussed in terms of possible molecular mechanisms of thymine dimer excision in vivo and in terms of possible experimental artifacts.     

Manipulation of medium conditions and differentiation in the rat myogenic cell line L6

Myoblasts of the L6 rat cell line were grown in Ham's F12 nutrient medium containing 10% fetal calf serum (F12 + FCS). Although the cells were confluent by 6 days in culture, fusion was not observed even if cultures were maintained for 10–14 days. At least 80% of the cells in such confluent unfused cultures were in the G₁ phase of the cell cycle and less than 5% of the cells in confluent cultures synthesized DNA during a 4-day period. The synthesis of muscle-specific proteins (α-actin, β-tropomyosin, and myosin light chains LC1_emb and LC2_F) was negligible when compared to fused cultures of L6 cells grown for a similar time in Dulbecco's medium with 10% FCS (DME + FCS). When the unfused cultures were shifted from F12 + FCS to DME + FCS, DNA synthesis could be demonstrated in more than 95% of the cells and fusion occurred, indicating that neither proliferative nor myogenic capacity had been irreversibly lost. Raising the levels of calcium, varying the serum concentration from 0 to 20%, or the addition of medium components (present in DME but reduced or absent in F12) all failed to induce fusion in the L6 cells grown in F12. However, L6 cells will fuse in mixtures of F12 + FCS and DME + FCS. Fusion will also occur if L6 cells are grown at clonal density in F12 + FCS supplemented with calcium. While it has not been possible to determine why F12 + FCS is nonpermissive for L6 cells in confluent mass cultures, the results demonstrate that prolonged residence in the G₁ phase of the cell cycle is not a sufficient condition for L6 myoblast differentiation to occur.     

The effect of 5-Iodouracil on the growth and biosynthetic processes of bacteriophage T4td8 in the absence of light

5-Iodouracil (IUra)-substituted progeny bacteriophage T4td8 were grown under conditions such that, upon CsCl equilibrium isopycnic gradient centrifugation, progeny with density distributions about the median similar to that of unsubstituted phage are obtained. In the absence of light a monotonie relationship exists between decreasing progeny viability and increasing percent IUra substitution. IUra is equivalent to thymine as a growth factor on a molar basis, and at concentrations of IUra plus thymine above that required for maximum particle production, the percent IUra substitution in phage DNA is determined by the mole fraction of IUra in the medium. The lethal effects of 5-iodo-2'-deoxyuridine (IdUrd) and IUra are equivalent, and are not produced by a direct effect on the phage particles. At equivalent percent substitution in phage DNA the order of lethality is IUra > 5-bromouracil (BrUra) > 5-chlorouracil (ClUra). There is no interference with the transfer of thymine from host cell to progeny phage by the presence of IUra in the medium, and IUra affects neither the time of lysis nor the content of phage DNA in the infected cells.     

A comparison of the utilization of thymine and thymidine for the synthesis of DNA-thymine in novikoff hepatoma cells

A comparison was made between the utilization of thymine and thymidine for the synthesis of DNA in Novikoff hepatoma cells growing in suspension culture. When the cell cultures were switched from exponential growth to a relatively non-growing condition, by resuspending them in culture media minus serum for 18 h, there was an 85% decrease in the rate of thymidine incorporation but only a 15% decrease in the rate of thymine incorporation. Exposure to an alkylating agent (methyl methane sulfonate) resulted in a 79% decrease in thymidine incorporation, while thymine incorporation was decreased only 35%. Thymidine at a concentration equal to its Km for incorporation into DNA (4 × 10⁻⁷ M) had virtually no effect on thymine incorporation. It was not until a thymidine concentration of ten times the K_m was employed that appreciable (40%) decreases in the rate of thymine incorporation were observed. Examination of total cellular DNA or nuclear DNA gave similar results. These studies are interpreted as indicating the presence of multiple precursor pools for the synthesis of DNA-thymine in Novikoff hepatoma cells.     

Pyrimidine dimer excision in surviving and nonsurviving cells of ultraviolet-irradiated cultures of Escherichia coli.

We compared dimer excision in viable and nonviable cells fractions separated from Escherichia coli B/r cultures exposed to ultraviolet (UV) irradiation. For cells grown on minimal medium with glycerol as a carbon source, both fractions from the irradiated (20 J/m2, 5% survival) culture excised 60 to 70% of the thymine dimers from prelabeled DNA within 120 min. This percentage was, within experimental error, the same as that obtained from unseparated cultures. When isolated viable and nonviable populations were given a second UV exposure (20 J/m2) both types of cells were again able to excise dimers. The UV survival curve for the isolated viable population indicates that these cells are no more sensitive to radiation than exponentially growing cells not previously exposed to UV. The extent of dimer excision after UV irradiation was also the same in viable and nonviable cells separated from cultures grown on a glucose minimal medium in which both populations excised about 85% of the dimers within 120 min. These results show that the extent of removal of pyrimidine dimer from deoxyribonucleic acid is not precisely correlated with survival of repair-competent bacterial cells after exposure to UV light.     

Immunochemical quantitation of UV-induced oxidative and dimeric DNA damage to human keratinocytes

There is growing evidence to suggest that solar radiation-induced, oxidative DNA damage may play an important role in skin carcinogenesis. Numerous methods have been developed to sensitively quantitate 8-oxo-2′deoxyguanosine (8-oxodG), a recognised biomarker of oxidative DNA damage. Immunoassays may represent a means by which the limitations of many techniques, principally derived from DNA extraction and sample workup, may be overcome. We report the evaluation of probes to thymine dimers and oxidative damage in UV-irradiated cells and the DNA derived therefrom. Thymine dimers were most readily recognised, irrespective of whether in situ in cells or in extracted DNA. However, using antibody-based detection the more subtle oxidative modifications required extraction and, in the case of 8-oxodG, denaturation of the DNA prior to successful recognition. In contrast, a recently described novel probe for 8-oxodG detection showed strong recognition in cells, although appearing unsuitable for use with extracted DNA. The probes were subsequently applied to examine the relative induction of lesions in cells following UV irradiation. Guanine-glyoxal lesions predominated over thymine dimers subsequent to UVB irradiation, whereas whilst oxidative lesions increased significantly following UVA irradiation, no induction of thymine dimers was seen. These data support the emerging importance of oxidative DNA damage in UV-induced carcinogenesis.     

Repair rate in human fibroblasts measured by thymine dimer excorporation

Summary The UV photoproduct, thymine dimer ( ), is excorporated with a remarkably low rate from the DNA of human fibroblasts grown in cell culture. An UV dose of 18 J/m² creates 0.045% (related to thymine). Within the first two days of repair logarithmically growing and quiescent fibroblasts exhibit the same repair rates; thereafter, the proportion of is lower in growing cells due to recovery of DNA replication. Only about 50% of the lesions are excised within 24 h. In quiescent cells, 13% of the thymine dimers originally present can be detected as late as a week after UV-irradiation. Two distinct first-order rate constants indicate that approximately half of the dimers are less accessible to repair. Repair measured by the nucleoid decondensation technique corresponds to the faster repair rate, whereas the slow repair rate cannot be detected by this method. Saturation of repair is found beyond 27 J/m². The remarkably slow rate of excision indicates that thymine dimers are not lethal lesions in human fibroblasts.     

Action of T4 endonuclease V on DNA containing various photoproducts

The action of T4 endonuclease V on DNA containing various photoproducts was investigated. (1) The enzyme introduced strand breaks in DNA from ultraviolet-irradiated vegetative cells of Bacillus subtilis but not in DNA from irradiated spores of the same organism. DNA irradiated with long wavelength (360 nm peak) ultraviolet light in the presence of 4,5',8-trimethylpsoralen was not attacked by the enzyme. These results indicate that 5-thyminyl 5,6-dihydrothymine (spore photoproduct) and psoralen mediated cross-links in DNA are not recognized by T4 endonuclease V. (2) DNA of phage PBS1, containing uracil in place of thymine, and DNA of phage SPO1, containing hydroxymethyluracil in place of thymine, were fragmented by the enzyme when the DNA's had been irradiated with ultraviolet light. T4 endonuclease V seems to act on DNA with pyrimidine dimers whether the dimers contain thymine residues or not.     

Reduced formation of bipyrimidine photoproducts in DNA UV irradiated at high intensity

DNA was irradiated using an excimer laser (248 nm) at low intensity (3.15 x 10(7) watts/m2) or high intensity (1.25 x 10(11) watts/m2). Fluences up to 30 kJ/m2 were delivered at either intensity. Following irradiation, DNA damage products were measured, yielding the following findings: 1) the rate of formation of thymine-thymine and thymine-cytosine cyclobutane dimers and the bipyrimidine photoadduct 6-4'-[pyrimidine-2'-one]thymine were reduced at high intensity by about 2-fold and 2) extensive release of free thymine and thymine decomposition fragments occurred at high intensity, but not at low intensity. The effects of high intensity UV are due to promotion of low-lying excited state(s) by absorption of a second photon, producing higher excited state(s) with consequent ionization and base loss. Possible excited state intermediates in this process are the lowest triplet state of DNA bases and prolonged singlet states associated with excimer formation. The depletion of these excited states via promotion may be the cause of the diminished yield of bimolecular pyrimidine photoproducts, suggesting that these photoproducts are formed at low UV intensity in part from long-lived excited states. Long-lived excited states present at conventional UV intensities may contribute to formation of some photoproducts that occur rarely, but are of potential biologic importance, such as dimers between nonadjacent pyrimidines on the same strand and interstrand dimers forming DNA cross-links.     

The broth effect and mutation frequency decline in cells ofEscherichia coli after irradiation with UV-light

Dependence of the broth effeot and the phenomenon of mutation frequency decline on dose of the applied UV radiation was investigated in the strainEscherichia coli B/r Hcr+ thy trp. Reversions to Trp⁺ were followed. The degree of the broth effect and the mutation frequency decline is minimal within the range of UV doses corresponding to a survival of cells lower than 10-1. In connection with the two effects, excision of thymine dimers, initiation of synthesis, synthesis and degradation of DNA were also investigated. It was found that stimulation or inhibition of an inaccurate postreplication repair mechanism, rather than inhibition or stimulation of excision of thymine dimers, are responsible for the broth effect and the mutation frequency decline, respectively.     

Thymine dimer excision in UV-irradiated and 5-fluorouracil-postincubatedEscherichia coli

The effect of post-irradiation cultivation with 5-fluorouracil on the excision of thymine dimers following UV irradiation was examined inEscherichia coli 15 T-U-his-. It was found that an increase of the number of surviving cells caused by 60-min post-incubation with 5-fluorouracil is not accompanied by any more rapid and complete removal of thymine dimers from the damaged molecule of DNA     

Induction of unscheduled DNA synthesis by the carcinogen 7-bromomethylbenz(a)anthracene and its removal from the DNA of normal and xeroderma pigmentosum lymphocytes

The carcinogen 7-bromomethylbenz(a)anthracene (BBA), which can bind strongly to DNA, induces unscheduled DNA synthesis (DNA repair) in normal lymphocytes but almost none in lymphocytes from patients with Xeroderma pigmentosum (XP), and inherited disease known to be defective in excision repair of ultraviolet-damaged DNA. We studied [³H]BBA's ability to bind to DNA of normal and XP lymphocytes, its influence on unscheduled DNA synthesis, and its removal from the DNA of both cell types. We found that 20–30% of the BBA is bound to macromolecules other than DNA and that its binding to DNA is essentially complete after 30 min. The induction of unscheduled DNA synthesis by the carcinogen in XP lymphocytes was approximately 10% of that induced in normal lymphocytes. While 15–20% of the BBA was removed from the DNA of normal cells 6 h after treatment, only 1–2% was removed from the DNA of XP cells. Thus, XP cells not only are defective in repairing ultraviolet-damaged DNA and excising thymine dimers but also fail to repair DNA damaged by certain carcinogens, and, most importantly, fail to remove the DNA-bound carcinogen, BBA.     

Mechanisms of targeted frameshift mutations: Insertions arising during error-prone or SOS synthesis of DNA containing cis-syn cyclobutane thymine dimers

It is still unclear how frameshift mutations arise at cyclobutane pyrimidine dimers. The polymerase model is commonly used to explain the mechanisms of various mutations. An alternative polymerase-tautomer model was developed for UV-induced mutagenesis. A mechanism was proposed for targeted insertions caused by cis-syn cyclobutane thymine dimers. Targeted insertions are frameshift mutations due to addition of one or more nucleotides in a DNA sequence opposite to a lesion capable of stopping DNA synthesis. Among other factors, cyclobutane pyrimidine dimers can cause targeted insertions. UV irradiation can change the tautomeric form of DNA bases. Five rare tautomeric forms are possible for thymine, and they are stable when the thymine is a component of a cyclobutane dimer. A structural analysis showed that none of the canonical nucleotides can be added opposite to a specific rare thymine tautomer so that hydrogen bonds form between the two bases. A single nucleotide gap is consequently left in the corresponding site of the nascent strand when a specialized or modified DNA polymerase drives SOS or error-prone DNA synthesis on a template containing cis-syn cyclobutane thymine dimers with a base occurring in the rare tautomeric form. If the DNA composition is homogenous within the region, the end of the growing DNA strand may slip to form a complementary pair with the nucleotide adjacent to the dimer according to the Streisinger model, thus producing a loop. A targeted insertion is thereby generated to make the daughter strand longer. Targeted insertions were for the first time assumed to result from the cis-syn cyclobutane thymine dimers wherein one or both of the bases occur in the specific tautomeric form that does not allow the addition and hydrogen bonding of any canonical nucleotide in the opposite position. A model was developed to explain how targeted insertions of one or more nucleotides are caused by cis-syn cyclobutane thymine dimers. Thus, the polymerase-tautomer model can explain the nature and formation of targeted frameshift mutations in addition to hot and cold spots or targeted or untargeted nucleotide substitutions.     

Effects of temperature on the photoreactivation of ultraviolet-b–induced dna damage in Palmaria palmata (Rhodophyta)

The accumulation of DNA damage (thymine dimers and 6-4 photoproducts) induced by ultraviolet-B radiation was studied in Palmaria palmata (L.) O. Kuntze under different light and temperature conditions, using specific monoclonal antibodies and subsequent chemiluminescent detection. Both types of damage were repaired much faster under ultraviolet-A radiation (UVAR) plus photosynthetically active radiation (PAR) than in darkness, which indicates photoreactivating activity. At 12° C, all thymine dimers were repaired after 2 h irradiation with UVAR plus PAR, whereas 6-4 photoproducts were almost completely repaired after 4 h. After 19 h of darkness, almost complete repair of 6-4 photoproducts was found, and 67% of the thymine dimers were repaired. In a second set of experiments, repair of DNA damage under UVAR plus PAR was compared at three different temperatures (0, 12, and 25° C). Again, thymine dimers were repaired faster than 6-4 photoproducts at all three temperatures. At 0° C, significant repair of thymine dimers was found but not of 6-4 photoproducts. Significant repair of both thymine dimers and 6-4 photoproducts occurred at 12 and 25° C. Optimal repair efficiency was found at 25° C for thymine dimers but at 12° C for 6-4 photoproducts, which suggests that the two photorepair processes have different temperature characteristics.     

Immunochemical determination of DNA damage induced by high doses of ionizing radiation

It was shown by the immunochemical method that DNA of X-irradiated E. coli cells of a radiosensitive mutant ABA88uvr A6 can react with the antiserum to thymine dimers which, in all appearance, are induced by ionizing radiation in bacterial DNA. The number of thymine dimers in DNA of E. coli AB1886uvr A6 increased with the dose increase. No dimers were detected in radioresistant cells of M. radioproteolyticus probably due to the effective excision thereof.     

Potential of mean force calculations of the stacking-unstacking process in single-stranded deoxyribodinucleoside monophosphates.

The free energy of the stacking-unstacking process of deoxyribodinucleoside monophosphates in aqueous solution has been investigated by potential of mean force calculations along a reaction coordinate, defined by the distance between the glycosidic nitrogen atoms of the bases. The stacking-unstacking process of a ribodinucleoside monophosphate was observed to be well characterized by this coordinate, which has the advantage that it allows for a dynamical backbone and flexible bases. All 16 naturally occurring DNA dimers composed of the adenine, cytosine, guanine, or thymine bases in both the 5' and the 3' positions were studied. From the free-energy profiles we observed the deepest minima for the stacked states of the purine-purine dimers, but good stacking was also observed for the purine-pyrimidine and pyrimidine-purine dimers. Substantial stacking ability was found for the dimers composed of a thymine base and a purine base and also for the deoxythymidylyl-3',5'-deoxythymidine dimer. Very poor stacking was observed for the dCpdC dimer. Conformational properties and solvent accessibility are discussed for the stacked and unstacked dimers. The potential of mean force profiles of the stacking-unstacking process for the DNA dimers are compared with the RNA dimers.