In vitro repair of UV-or X-irradiated bacteriophage T4 DNA by extract from blue-green alga Anacystis nidulans

The cell-free extract from blue-green alga Anacystis nidulans contains enzymatic activities which repair in vitro transforming DNA of bacteriophage T4 damaged by UV light or X-rays. The repair effect of the extract was observed with double-stranded irradiated DNA but not with denatured irradiated DNA. The level of restoration of the transforming activity depends on the protein concentration in the reaction mixture and on the dose of irradiation. A fraction of DNA lesions induced by X-rays is repaired by a NAD-dependent polynucleotide ligase present in the extract. The repair of UV-induced lesions is the most efficient in the presence of magnesium ions, NAD, ATP and the four deoxynucleoside triphosphates. The results indicate that the repair of UV-irradiated DNA is performed with the participation of DNA polymerase and polynucleotide ligase which function in the cell-free extract of the algae on the background of a low deoxyribonuclease activity.Abbreviations UV ultraviolet - TA transforming activity - PN-ligase polynucleotide ligase - NAD nicotinamide adenine dinucleotide - dNTP deoxynucleoside triphosphates - dATP, dGTP, dTTP triphosphates of deoxyadenosine, deoxyguanosine, deoxythymidine and deoxycytidine, respectively     

Repair of ultraviolet-irradiated transforming deoxyribonucleic acid in Haemophilus influenzae

Ultraviolet-sensitive and wild-type Haemophilus influenzae cells were exposed to irradiated and unirradiated transforming deoxyribonucleic acid (DNA) containing a marker which can be linked to another marker in the cells. Lysates were made after various times of incubation and assayed for transforming activity on an excisionless recipient. Repair can be noted as an increase in activity from the irradiated donor DNA after its linkage to the recipient DNA. No repair can be observed in a mutant which is unable to integrate transforming DNA. There is a little repair in another mutant which is unable to excise pyrimidine dimers. H. influenzae cells also repair nondimer damage, as judged by the increase in activity observed in lysates made with irradiated and maximally photoreactivated DNA.     

Genetic Analysis of Repair of Ultraviolet Damage by Competent and Noncompetent Cells of Bacillus subtilis

The repair of ultraviolet (UV) damage in Bacillus subtilis W23T(-) has been studied by transformation with deoxyribonucleic acid (DNA) extracted from irradiated cells before and after repair. The extent of repair of genetic markers by donor cells after low or moderate doses of UV was found to be related only to the initial degree of inactivation. After a very high dose, further inactivation occurred, also in proportion to initial damage. In addition, the competent recipient cells were shown to repair approximately 75% of the damage in transforming DNA. The sensitivities of markers irradiated either in vivo or in vitro appeared to be related to map position, the more proximal markers showing a greater resistance to UV inactivation.     

Efficiency of Escherichia coli repair processes on uv-damaged transforming plasmid DNA

A comparison has been made of the efficiencies with which the dark repair processes of Escherichia coli act on ultraviolet irradiated bacterial chromosomal DNA and ultraviolet damaged transforming plasmid DNA. It is shown that postreplicational repair pathways act very inefficiently on transforming plasmid DNA, and that the majority of repair is carried out by excision repair pathways. However, even excision repair pathways act less efficiently on damaged plasmid DNA than they do on chromosomal DNA. The large effect of mutations in recB on plasmid survival suggests that the product of this gene may be essential for the excision repair pathways which act on plasmid DNA, but not for those which act on chromosomal DNA.     

Repair of Irradiated Transforming Deoxyribonucleic Acid in Wild Type and a Radiation-Sensitive Mutant of Micrococcus radiodurans

The survival of biological activity in irradiated transforming deoxyribonucleic acid (DNA) has been assayed in the wild type and a radiation-sensitive mutant of Micrococcus radiodurans. The frequency of transformation with unirradiated DNA was lower in the mutant to about the same extent as the mutant's increased sensitivity to radiation. However, in both the wild type and the mutant, the irradiated DNA that was incorporated into the bacterial genome was repaired to the same extent as determined by the loss of transforming activity with increasing radiation dose. This applied to DNA irradiated either with ionizing or ultraviolet (UV) radiation. The rate of inactivation of biological activity after UV radiation was the same in any of the DNA preparations tested. For ionizing radiation, the rate of inactivation varied up to 40-fold, depending on the DNA preparation used, but for any one preparation was the same whether assayed in the wild type or the radiation-sensitive mutant. When recipient bacteria were irradiated with ionizing or UV radiation immediately before transformation, the frequency of transformation with unirradiated DNA fell, rapidly and exponentially in the case of the sensitive mutant but in a more complicated fashion in the wild type. The repair of DNA irradiated with ionizing radiation was approximately the same whether assayed in unirradiated or irradiated hosts. Thus, irradiation of the host reduced the integration of DNA but not its repair.     

Mutants of Diplococcus pneumoniae that Lack Deoxyribonucleases and Other Activities Possibly Pertinent to Genetic Transformation

Mutants of Diplococcus pneumoniae that lacked the two major deoxyribonucleases of the cell—one an endonuclease, the other an exonuclease preferentially active on native deoxyribonucleic acid (DNA)—were obtained. The development of a method for detecting mutant colonies, based on the binding of methyl green to DNA, facilitated isolation of the mutants. Neither enzyme was essential for growth of the cells, for repair of ultraviolet damage, or for any phase of DNA-mediated transformation. Residual deoxyribonuclease activity in the double mutant corresponded to an exonuclease, approximately one-fifth as active as the major exonuclease, that attacked native and denatured DNA equally well. This activity appeared to be associated with the DNA-polymerase enzyme. A mutant that apparently lacked a cell wall lytic enzyme was also fully transformable. A mutant strain that was four times more sensitive to ultraviolet light than the wild type also transformed normally. Recipient cells of this strain were deficient in the repair of ultraviolet-irradiated transforming DNA. Mutants were found which, unlike the wild type, integrated donor markers only with high efficiency, thereby indicating that a particular cellular component that is susceptible to loss by mutation, such as an enzyme, is responsible for low integration efficiency.     

The in vitro photosensitivity of systemic lupus erythematosus skin fibroblasts

To investigate the role of DNA damage in the pathogenesis of systemic lupus erythematosus (SLE), we studied the ability of skin fibroblasts derived from SLE patients to recover from ultraviolet (UV) light radiation of varying wavelengths. Four of five SLE cell strains were more sensitive to UV-C (254 nm), sun lamp, and UV-A (320 to 400 nm) light than were normal cells. SLE cellular recovery was most sensitive to broad spectrum, long wavelength light. This hypersensitivity did not appear to result from the UV light activation of a clastogenic factor. Experiments which examined the DNA repair capacity of irradiated cells indicated that SLE fibroblasts may be able to excise certain DNA lesions as well as normal cells. The mechanisms responsible for the hypersensitivity of SLE cells remain under investigation.     

DNA repair after ultraviolet irradiation of ICR 2A frog cells. Pyrimidine dimers are long acting blocks to nascent DNA synthesis.

The ability of ICR 2A frog cells to repair DNA damage induced by ultraviolet irradiation was examined. These cells are capable of photoreactivation but are nearly totally deficient in excision repair. They have the ability to convert the small molecule weight DNA made after irradiation into large molecules but do not show an enhancement in this process when the UV dose is delivered in two separate exposures separated by a 3- or 24-h incubation. Total DNA synthesis is depressed and low molecular weight DNA continues to be synthesized during pulse-labeling as long as 48 h after irradiation. The effects of pyrimidine dimer removal through exposure of UV irradiated cells to photoreactivating light indicate that dimers act as the critical lesions blocking DNA synthesis.     

Nonphotoreactivating Repair of Ultraviolet Light-Damaged Transforming Deoxyribonucleic Acid by Micrococcus lysodeikticus Extracts.

Elder, Robert L. (Johns Hopkins University, Baltimore, Md.), and Roland F. Beers, Jr. Nonphotoreactivating repair of ultraviolet light-damaged transforming deoxyribonucleic acid by Micrococcus lysodeikticus extracts. J. Bacteriol. 90:681-686. 1965.-Extracts from Micrococcus lysodeikticus repair Haemophilus influenzae transforming deoxyribonucleic acid (DNA) damaged by ultraviolet light radiation. The repair is demonstrable over a wide dose range, with a constant dose reduction factor for a given concentration of DNA. The active component in the crude extract may be separated into a heat-stable dialyzable and a heat-labile nondialyzable component. The dialyzable fraction contains at least one component which appears to limit the maximal level of repair. Mg(2+) ions are required for the repair process.     

Repair of DNA damage in shuttle vectors, virus, and chromosomal DNAs may depend on their biological imprinting--a 'Pygmalion' effect

We have created a cell line that can repair damage in chromosomal DNA and in herpes virus, while not repairing the same damage in shuttle vectors (pZ189 and pRSVcat). This cell line, a xeroderma pigmentosum (XP) revertant, repairs the minor (6-4)-photoproducts, but not cyclobutane dimers, in chromosomal DNA. The phenotype of this revertant after irradiation with ultraviolet (UV) light is the same as that of normal cells for survival, repair replication, recovery of rates of DNA and RNA synthesis, and sister-chromatid exchange formation, which indicates that a failure to mend cyclobutane dimers may be irrelevant to the fate of irradiated human cells. The two shuttle vectors were grown in Escherichia coli and assayed during transient passage in human cells, whereas the herpes virus was grown and assayed exclusively in mammalian cells. The ability of the XP revertant to distinguish between the shuttle vector and herpes virus DNA molecules according to their 'cultural background', i.e., bacterial or mammalian, may indicate that one component of the repair of UV damage involves gene products that recognize DNA markers that are uniquely mammalian, such as DNA methylation patterns. This component of excision repair may be involved in the original defect and the reversion of XP group A cells.     

Effects of oxygen and sulphydryl-containing compounds on irradiated transforming DNA. III. Reaction rates

The absolute rate for the repair reaction of radiation-induced, oxygen-dependent lesions in bacterial transforming DNA with the sulphydryl (SH)-containing compound dithiothreitol (DTT) has been determined using a fast response method, the gas explosion technique, to be 1.6 X 10(6) mol-1 s-1. Glutathione reacts ten times slower than DTT with the irradiated transforming DNA. It can also be calculated that transforming DNA radicals react with O2 in a damage-fixing reaction with a rate of about 3 X 10(8) dm3 mol-1 s-1. These rates are compared with values in the literature for reaction rates of SH, compounds and O2 with irradiated DNA constituents and with bacterial cells.     

A comparison of the rates of reaction and function of UVRB in UVRABC- and UVRAB-mediated anthramycin-N2-guanine-DNA repair.

The repair of anthramycin-DNA adducts by the UVR proteins in Escherichia coli follows two pathways: the adducts may be incised by the combined actions of UVRA, UVRB, and UVRC, or alternatively, the anthramycin may be removed by UVRA and UVRB in the absence of UVRC and with no DNA strand incision. To assess the competition between these two competing pathways, the rate of UVRABC-mediated excision repair of anthramycin-N2-guanine DNA adducts and the rate of UVRAB-mediated removal of the adduct were measured with single end-labeled DNAs under identical reaction conditions. UVR protein concentrations of 15 nM UVRA, 100 nM UVRB, and 10 nM UVRC protein were chosen to mimic in vivo concentrations. With these UVR protein concentrations and anthramycin-DNA concentrations of 1-2 nM the incision reaction and the release reactions are described by first-order kinetics. The rate of the UVRABC reaction, measured as the increase in incised fragments, was six to seven times faster than the rate of the UVRAB reaction, measured as the decrease in incised fragments. The UVRABC incision rate on anthramycin-modified linear DNA was four to five times the incision rate measured on the same DNA irradiated with ultraviolet light. We also investigated the role of the ATPase function of UVRB in UVRAB-mediated anthramycin removal. We found that a UVRB analogue with alanine at arginine 51, which retains near wild type ATPase activity, supported removal of anthramycin in the presence of UVRA, whereas a UVRB analogue with alanine at lysine 45, which abolishes the ATPase activity, did not. UVRB*, a specific proteolytic cleavage product of UVRB which retains the ATPase activity, did support removal of anthramycin in the presence of UVRA.     

Further purification and characterization of T4 endonuclease V.

T4 endonuclease V, which is involved in repair of ultraviolet-damaged DNA, has been purified 3600 fold from T4D-infected Escherichia coli. The enzyme shows optimal activity at pH 7.2 and does not require added divalent ions. Endonuclease V attacks both native and heat-denatured DNA provided that the DNA has been irradiated, and the enzyme activity is dependent on the dose of ultraviolet irradiation. The rate and the extent of the reaction are greater with irradiated native DNA although the Km values for the two types of DNA are the same (2.25 - 10(-5) M). The enzyme is readily inactivated by heat and is sensitive to p-chloromercuribenzoate. Endonuclease V-treated irradiated DNA is degraded by spleen phosphodiesterase only when the DNA has been treated with alkaline phosphatase, suggesting that the enzyme produces 5'-phosphoryl termini.     

Repair of pyrimidine dimer ultraviolet light photoproducts by human cell extracts

A newly developed method allows human cell extracts to carry out repair synthesis on ultraviolet light irradiated closed circular plasmid DNA [Wood, R. D., Robins, P., & Lindahl, T. (1988) Cell 53, 97-106]. The identity of the photodamage that leads to this repair replication was investigated. Removal of stable pyrimidine hydrates from irradiated plasmid pAT153 did not significantly affect the amount of repair replication in the fluence range of 0-450 J/m2, because of the low yield of these products and their short DNA repair patch size. Photoreactivation of irradiated DNA using purified Escherichia coli DNA photolyase to remove more than 95% of the cyclobutane dimers from the DNA reduced the observed repair synthesis by 20-40%. The greater part of the repair synthesis is highly likely to be caused by (6-4) pyrimidine dimer photoproducts. This class of lesions is rapidly repaired by mammalian cells, and their removal is known to be important for cell survival after ultraviolet irradiation.     

A novel method for the genome-wide high resolution analysis of DNA damage

DNA damage occurs via endogenous and exogenous genotoxic agents and compromises a genome's integrity. Knowing where damage occurs within a genome is crucial to understanding the repair mechanisms which protect this integrity. This paper describes a new development based on microarray technology which uses ultraviolet light induced DNA damage as a paradigm to determine the position and frequency of DNA damage and its subsequent repair throughout the entire yeast genome.     

Repair of alkylation damage in the fungus Aspergillus nidulans

The repair of alkylation damage in Aspergillus nidulans was investigated. We have assayed soluble protein fractions for enzymes known to be involved in the repair of this type of damage in DNA. The presence of a glycosylase activity that can remove 3-methyladenine from DNA was demonstrated, as well as a DNA methyltransferase activity that appears to act against O6-methylguanine. In addition to this approach, a series of mutants were isolated which display increased sensitivity to alkylating agents (sag mutants). 5 such mutants were further characterized, and at least 4 are shown to map to genes which have not previously been characterized. The behaviour of double mutant combinations demonstrates the existence of at least 2 pathways for the repair of alkylation damage. The majority of the sag mutants (sagA1, sagB2, sag4 and sagE5) exhibit an increased sensitivity to a range of alkylating agents, but not to UV light, while sagC3, when irradiated at the germling stage, also shows sensitivity to UV. None of the mutants isolated are defective in either the 3-methyladenine DNA glycosylase activity, or the DNA methyltransferase activity, and the nature of the defects in these strains remains to be determined.     

Ultraviolet reactivation of lambda phage: assay of infectivity of DNA molecules by spheroplast transfection

Prior irradiation of non-lysogenic bacteria by ultraviolet light leads to an increase in the viability of infecting irradiated λ phage (ultraviolet reactivation). Similarly, u.v. irradiation of wild type or uvrD bacteria lysogenic for λcIind^? increased the fraction of closed circular duplex phage DNA molecules formed after infection with u.v.-irradiated λ phage. The closed circular molecules isolated from the irradiated lysogens were shown to be free from u.v. damage by a spheroplast transfection assay. The increase of closed circular molecules is sufficient to explain the ultraviolet reactivation observed by the increase of viability of irradiated phage.In ultraviolet reactivation, damage must be erased on irradiated DNA molecules and the repair is independent of total replication of phage genomes, exchange of sister chromatids or recombination between phage genomes. Protein synthesis is necessary to increase the level of closed circular molecules of irradiated λ phage after irradiation of bacteria.     

Transformation of ultraviolet-irradiated human fibroblasts by simian virus 40 is enhanced by cellular DNA repair functions

Human fibroblasts irradiated with ultraviolet light were either tested for survival (colony formation) or infected with simian virus 40 and examined for transformation (foci formation). For normal cell cultures, the fractions of surviving colonies which were also transformed increased with increasing irradiation dose. In contrast, little increase in the transformation of ultraviolet-irradiated repair-deficient (xeroderma pigmentosum and xeroderma pigmentosum variant) cells was observed. Similar experiments with xeroderma pigmentosum variant cells treated with caffeine following irradiation indicated that, under these conditions, the deficient cells produced more transformants among the survivors of ultraviolet irradiation than did unirradiated cells. These results suggest (1) that DNA repair functions, not DNA damage per se, are required for enhanced viral transformation in normal cells; (2) that functions involved in excision repair and functions needed for replication of ultraviolet-damaged DNA appear necessary for this stimulation; and (3) that blocking DNA replication in ultraviolet-irradiated xeroderma pigmentosum variant cells by caffeine enhances viral transformation.     

Continued Synthesis of Bacterial DNA After Infection by Bacteriophage T4

Early in infection by bacteriophage T4, before replication has commenced, one can detect the presence of newly synthesized DNA which cosediments with parental phage DNA on sucrose gradients. As shown earlier (R. E. Murray and C. K. Mathews, 1969), some of this represents covalent attachment of new material to parental phage DNA molecules. However, as shown herein, most of it is bacterial DNA, which is synthesized after infection and presumably degraded to T4 DNA-sized pieces. The small amount of phage-specific DNA synthesis which occurs is apparently a repair process, for its extent is greatly increased if the phage are irradiated with ultraviolet light prior to infection. Analysis by means of pulse labeling with [(3)H]thymidine and DNA-DNA hybridization shows that host DNA synthesis continues at a significant rate (40 to 80% of the preinfection rate) as late as 10 min after infection at 37 C. Very early in infection this is primarily replicative synthesis, but later a repair process predominates. Presumably this represents attempted repair of damage being inflicted on host DNA by phage-coded nucleases.