ENHANCEMENT OF ULTRAVIOLET-DNA REPAIR IN den V GENE TRANSFECTANTS and T4 ENDONUCLEASE V-LIPOSOME RECIPIENTS

The phage T4 denV gene, coding for the pyrimidine-dimer specific T4 endonuclease V, was transfected into human repair-proficient fibroblasts, repair-deficient xeroderma pigmentosum fibroblasts, and into wild type CHO hamster cells. Transfectants maintained denV DNA and expressed denV mRNA. Purified T4 endonuclease V encapsulated in liposomes was also used to treat repair-proficient and -deficient human cells. The denV transfected clones and liposome-treated cells showed increased unscheduled DNA synthesis and enhanced removal of pyrimidine dimers compared to controls. Both denV gene transfection and endonuclease V liposome treatment enhanced post-UV survival in xeroderma pigmentosum cells but had no effect on survival in repair-proficient human or hamster cells. The results demonstrate that an exogenous DNA repair enzyme can correct the DNA repair defect in xeroderma pigmentosum cells and enhance DNA repair in normal cells.     

SUBSTRATE SPECIFICITY OF A BACTERIAL UV ENDONUCLEASE AND THE OVERLAP WITH IN VITRO PHOTOENZYMATIC REPAIR

Abstract— The action of an endonuclease from Micrococcus luteus , that operates on ultraviolet (UV) radiation damage, overlaps greatly with that of the yeast photoreactivating enzyme: homo and hetero cyclobutyl pyrimidine dimers in DNA are substrate for both enzymes, but pyrimidine adducts or the 'spore photoproduct' in DNA are not.
As expected from this overlap, the action of the two enzymes is mutually interfering: single-strand nicks introduced by the endonuclease effectively preclude photoreactivation; conversely, formation of a photoreactivating enzyme-dimer complex can prevent nicking by the UV endonuclease. While complex formation between photoreactivating enzyme and dimers in UV-endonuclease-treated DNA is apparently normal, the light-dependent repair step either fails to occur or proceeds at a very low rate. Hence, besides the requirement of a minimum chain length for the function of the photoreactivating enzyme, there is the additional restriction on the position of the dimer in a polynucleotide strand.
Finally, rough approximations of the rate constants, k ₁ and k ₂, for the UV endonuclease indicate that the in vitro UV-endonuclease-dimer complex is relatively unstable, with dissociation of the complex being more probable than hydrolysis of the phosphodiester bond.     

IN VIVO EXCISION OF PYRIMIDINE DIMERS IS MEDIATED BY A DNA N-GLYCOSYLASE IN MICROCOCCUS LUTEUS BUT NOT IN HUMAN FIBROBLASTS

Abstract It has been previously shown that Micrococcus luteus possesses a pyrimidine dimer-specific endonuclease which in vitro , functions as both an endonuclease and DNA-glycosylase. To determine if these combined activities function in vivo , we have isolated and examined the excision products of UV-irradiated M. luteus . In addition, we have devised a procedure to isolate and examine the excision products from UV-irradiated human fibroblasts to determine if an endonuclease/glycosylase activity functions in the excision of UV-induced pyrimidine dimers in human fibroblasts. We find that, in vivo , an endonuclease/glycosylase mechanism is utilized extensively in the repair of pyrimidine dimers by M. luteus , but that human fibroblasts do not appear to use this mechanism.     

IS DNA TOPOISOMERASE INVOLVED IN THE UV EXCISION REPAIR PROCESS? NEW EVIDENCE FROM STUDIES WITH DNA INTERCALATING AND NON-INTERCALATING ANTITUMOR AGENTS

Abstract— The effects of selected DNA intercalating and non-intercalating drugs on the UV excision repair process in human fibroblasts have been examined. 9-Amino acridine, acridine orange, quinacrine, doxorubicin (adriamycin), ethidium bromide and actinomycin-D all inhibited the removal of pyrimidine dimers from cellular DNA by inhibiting the incision process as monitored by the nick translation assay and by an endonuclease-sensitive site assay. These agents also partially inhibited incision by the M. luteus endonuclease in an in vitro system. This is the only class of compounds tested to date that appears to block this early step of repair in mammalian cells. The DNA topoisomerase inhibitors, m -amsacrine and VP-16 (etoposide) and the bacterial gyrase inhibitors nalidixic acid and oxolinic acid were shown not to inhibit UV repair. As shown previously, however, novobiocin does block dimer removal and we show here that it is a potent inhibitor of the M. luteus UV endonuclease. While it has recently been demonstrated that many DNA intercalating agents block the strand-passing activity of DNA topoisomerase II giving rise to protein associated DNA strand breaks, the finding that the specific inhibitors of topoisomerase, m -AMSA and VP-16, do not inhibit repair, even though they block this strand passing activity, strongly suggests that inhibition of DNA topoisomerase is not associated with inhibition of DNA repair.     

WAVELENGTH DEPENDENCE OF DNA INCISION BY A HUMAN ULTRAVIOLET ENDONUCLEASE

The wavelength dependence of an ultraviolet irradiation of the DNA substrate for a human endonuclease was determined. Sites of DNA incision for all UVB and UVC wavelengths examined were at cytosines which were neither cyclobutane pyrimidine dimers nor 6-4'-(pyrimidin-2-one)pyrimidines. The optimal wavelengths for formation of these cytosine photoproducts were between 270 and 295 nm. This human endonuclease therefore has a similar ultraviolet substrate specificity to endonuclease III.     

SITE-SPECIFIC DELETION OF THE N-TERMINAL SEGMENTS FROM EcoRI ENDONUCLEASE USING THE POLYMERASE CHAIN REACTION

We developed a general and efficient method for directing the deletions of DNA sequences of any lengths using polymerase chain reaction (PCR). The method was based on in vitro amplification of target sequences with site-specific deletions, Klenow end-flushing and blunt-end cloning. As an example, it was used to delete the restriction gene encoding EcoRI endonuclease, resulting in plasmids expressing two truncated forms. Assays using SDS-PAGE and gel retardation revealed the important role of the amphipathic helix (29-43) of the EcoRI endonuclease in binding to its cognate substrate.     

PYRIMIDINE DIMER INDUCTION AND REMOVAL IN THE EPIDERMIS OF HAIRLESS MICE: INEFFICIENT REPAIR IN THE GENOME OVERALL AND RAPID REPAIR IN THE H-ras SEQUENCE

Excision repair of pyrimidine dimers was examined at the genome overall in three strains of hairless ( hr/hr ) and congenic wild-type mice, as well as in the expressed H- ras gene in hairless mice. The assay used a pyrimidine dimer-specific endonuclease from Micrococcus luteus and alkaline agarose gel electrophoresis. From 0 to 25% of endonuclease-sensitive sites were removed at the genome level in either hairy or hairless mice but about 50% were removed in the H- ras gene in hairless mice by 24 h after exposure to 5.4 J/cm² UV (290-400 nm) irradiation. No differences were observed in the repair capacity between hairy and hairless mice, thus eliminating defective DNA repair as the explanation for the greater susceptibility to UV carcinogenesis in hairless mice.     

Partial complementation of the DNA repair defects in cells from xeroderma pigmentosum groups A, C, D and F but not G by the denV gene from bacteriophage T4

Endonuclease V (denV) from bacteriophage T4 was examined for its ability to complement the DNA repair defect in xeroderma pigmentosum (XP) cells from complementation groups A, C, D, F and G. The denV gene was introduced into SV40-transformed normal and XP cells using a retroviral vector. Expression of denV resulted in partial correction of UV sensitivity and increased host cell reactivation (HCR) of a UV-damaged reporter gene for XP cells from groups A, C and D, but not those from group G. Expression of denV in XP-F cells resulted in enhanced HCR of a UV-damaged reporter but did not affect UV sensitivity. The observed partial complementation is thought to reflect denV-mediated repair of cyclobutane-pyrimidine dimers (CPD), and is incomplete as denV does not recognize other UV-induced lesions, and may not even efficiently remove all CPD. As XP-F cells are believed to retain near-normal levels of CPD repair in the bulk of the genome, we believe that the disparity in the ability of denV to complement the repair deficiency in these cells results from an increased rate, but not level, of CPD repair. Furthermore, we suggest that the lack of correction in the XP-G cells examined results from an inability to process denV-incised CPD by the base excision repair pathway, as has been suggested for cells from the related genetic disorder, Cockayne syndrome. Expression of denV in repair proficient normal cells also resulted in increased HCR of the UV-damaged reporter construct, possibly arising from an increased rate of CPD repair in these cells.     

WAVELENGTH DEPENDENCE OF THE FORMATION OF SINGLE-STRAND BREAKS AND BASE CHANGES IN DNA BY THE ULTRAVIOLET RADIATION ABOVE 150 nm

The wavelength dependence of the formation of two types of DNA damage, single-strand breaks and base changes, was investigated in the UV region from 150 nm to 254 nm using superhelical closed circular (form I) colicin El DNA with synchrotron radiation. Single-strand breaks were measured by agarose gel electrophoresis as a direct conversion of form I DNA to form II DNA (open circular). Base damages were defined as sensitive sites to a crude extract of endonuclease from Micrococcus luteus. They also were estimated using the same conversion, from form I to form II after the DNA was treated with endonuclease. The fluence-effect relationship could be fitted by a simple exponential function for both types of damage. Action spectra were constructed based on the reciprocal of the 37% fluence. The action spectrum for strand breaks increased rather monotonically over three decades from 254 nm to 150 nm in a logarithmic scale, while that for base damages showed a breaking point at 190 nm, being relatively flat above 190 nm. The characteristics of the action spectra are compared with the absorption spectra of the DNA and its main chain moiety calculated on the basis of data on calf thymus DNA and synthetic polynucleotides. Our main conclusions are (1) that the majority of single-strand breaks were induced by the absorption of photon in the sugar-phosphate group in the vacuum-UV region and (2) that the base changes were induced equally well by absorption in the vacuum-UV and in the far-UV region.     

Photorepair of Ultraviolet Radiation (UVR)-lnduced Pyrimidine Dimers in Lens Epithelial DNA of Monodelphis domestica

Abstract— The repair of UV radiation-induced pyrimidine dimers has been measured in lens epithelial DNA of the marsupial Monodelphis domestica using a pyrimidine dimerspecific endonuclease from Micrococcus luteus. Approximately 40% of the initially induced dimers were repaired during 90 min exposures to photoreactivating light. This capacity of the lens epithelium to photorepair pyrimidine dimers may provide a means with which to determine whether pyrimidine dimers in lens epithelial DNA are involved in UV radiation-induced pathologic changes of the lens.     

Excision-repair capacity of UV-irradiated strains of Escherichia coli and Streptococcus pneumoniae, estimated by plasmid recovery

Although the biological role of many bacterial repair genes is known, there is still an interest in evaluating the capacity of repair pyrimidine dimers in some strains. For this purpose, we have developed a rapid assay. Cells bearing a plasmid are UV irradiated and incubated to allow recovery. The plasmid DNA is extracted, purified and treated with UV endonuclease from Micrococcus luteus that specifically produces single strand breaks at the site of pyrimidine dimers. The amount of open circular and covalently closed circular forms of the plasmid DNA after treatment and post-incubation provides an estimate of the repair capability of the host strain. The wild type strain and the uvrA mutant of Escherichia coli were used to adjust the assay. The lexA mutant of E. coli has been tested and its repair capability is equivalent to that of wild-type strain. The assay has been extended to Streptococcus pneumoniae, which is naturally deficient in photoreactivation and SOS-like functions. This strain is efficient in the repair of pyrimidine dimers, formed after UV irradiation.     

Genetic diagnosis by polymerase chain reaction and electrospray ionization mass spectrometry: Detection of five base deletion from blood DNA of a familial adenomatous polyposis patient

A 5-base deleted mutation of adenomatous polyposis coli (APC) gene was detected by using electrospray ionization mass spectrometry of polymerase chain reaction (PCR) products. Genomic DNA was extracted from a familial adenomatous polyposis patient blood, and a 57-base pairs segment of APC gene was amplified by PCR. The PCR products were purified, digested with restriction endonuclease, purified, and determined by electrospray mass spectrometry.     

Multiphoton near-infrared femtosecond laser pulse-induced DNA damage with and without the photosensitizer proflavine

The excitation of pBr322 supercoiled plasmid DNA with intense near-IR 810 nm fs laser pulses by a simultaneous multiphoton absorption mechanism results in single-strand breaks after treatment of the irradiated samples with Micrococcus luteus UV endonuclease. This enzyme cleaves DNA strands at sites of cyclobutane dimers that are formed by the simultaneous absorption of three (or more) 810 nm IR photons (pulse width approximately 140 fs, 76 MHz pulse repetition, average power output focused through 10x microscope objective is approximately 1.2 MW/cm2). Direct single-strand breaks (without treatment with M. luteus) were not observed under these conditions. However, in the presence of 6 microM of the intercalator proflavine (PF), both direct single- and double-strand breaks are observed under conditions where substantial fractions of undamaged supercoiled DNA molecules are still present. The fraction of direct double-strand breaks is 30 +/- 5% of all measurable strand cleavage events, is independent of dosage (up to 6.4 GJ/cm2) and is proportional to In, where I is the average power/area of the 810 nm fs laser pulses, and n = 3 +/- 1. The nicking of two DNA strands in the immediate vicinity of the excited PF molecules gives rise to this double-strand cleavage. In contrast, excitation of the same samples under low-power, single-photon absorption conditions (approximately 400-500 nm) gives rise predominantly to single-strand breaks, but some double-strand breaks are observed at the higher dosages. Thus, single-photon excitation with 400-500 nm light and multiphoton activation of PF by near-IR fs laser pulses produces different distributions of single- and double-strand breaks. These results suggest that DNA strand cleavage originates from unrelaxed, higher excited states when PF is excited by simultaneous IR multiphoton absorption processes.     

REMOVAL OF THYMINE-CONTAINING PYRIMIDINE DIMERS FROM UV LIGHT-IRRADIATED DNA BY S1 ENDONUCLEASE

Abstract— S₁ endonuclease was shown to remove thymine-containing pyrimidine dimers from UV-irradiated human DNA, although efficient removal could be demonstated only by using long digestion times, relatively high enzyme concentrations, and irradiation sufficient to yield dimer substitutions in DNA of 1 per 1W300 (dimers/base pair). Neutral and alkaline sucrose gradient analysis of strand break induction by S, of UV-irradiated DNA suggests that recognition of the dimer by S, is the limiting factor in its removal and dimer removal usually results from attack on the dimer containing DNA strand without the induction of a double-strand break.     

SATURATION OF DNA REPAIR IN MAMMALIAN CELLS*

Abstract—Excision repair seems to reach a plateau in normal human cells at a 254 nm dose near 20J/m². We measured excision repair in normal human fibroblasts up to 80J/m². The four techniques used (unscheduled DNA synthesis, photolysis of BrdUrd incorporated during repair, loss of sites sensitive to a UV endonuclease from Micrococcus luteus , and loss of pyrimidine dimers from DNA) showed little difference between the two doses. Moreover, the loss of endonuclease sites in 24 h following two 20J/m² doses separated by 24 h was similar to the loss observed following one dose. Hence, we concluded that the observed plateau in excision repair is real and does not represent some inhibitory process at high doses but a true saturation of one of the, rate limiting steps in repair.     

MORE EFFICIENT EXCISION REPAIR OF PYRIMIDINE DIMERS IN THE SPECIFIC DNA SEQUENCE THAN IN THE GENOME OVERALL IN GOLDFISH CELLS

Excision repair of pyrimidine dimers induced by 254 nm UV was examined in the genome overall and in a specific sequence containing a transfected gene for hygromycin B resistance, in RBCF-1 cells derived from a goldfish, by the use of UV endonuclease of Micrococcus luteus and alkaline agarose gel electrophoresis. More than 40% of dimers were removed from the specific sequence, while about 20% were removed from the genome overall, within 24 h after exposure to UV (2.5-7.5 J/m2).     

CYCLOBUTANE DIMERS AND (6-4)PHOTOPRODUCTS IN HUMAN CELLS ARE MENDED WITH THE SAME PATCH SIZES

The size of excision repair patches corresponding to excision of (6-4) pyrimidine-pyrimidone photoproducts and (5-5, 6-6) cyclobutane dimers have been independently determined by using bromodeoxyuridine substitution and density increases in isopycnic gradients of small DNA fragments. The two classes of photoproducts were distinguished by using (a) a xeroderma pigmentosum (XP) revertant cell line that excises (6-4) photoproducts normally, but does not excise cyclobutane dimers from bulk DNA or from an actively transcribed sequence; (b) an XP cell line containing the denV gene of bacteriophage T4, which repairs only cyclobutane dimers by a unique glycosylase mechanism, and (c) normal cells analyzed during time intervals in which cyclobutane dimer repair is the main repair process in action. The patch sizes for the two lesions were similar under all conditions and were estimated to be approximately 30-40 bases. These values are slightly large than corresponding estimates for Escherichia coli and Saccharomyces cerevisiae but close to estimates from in vitro experiments with human cell extracts. The size of 30 bases may consequently be very close to the actual distance between cleavage sites made on either side of a photoproduct during repair.     

IRRADIATION OF CIRCULAR DNA WITH 254 nm RADIATION OR SENSITIZATION IN THE PRESENCE OF Ag+ EVIDENCE FOR UNWINDING BY PHOTOPRODUCTS OTHER THAN PYRIMIDINE DIMERS

Abstract— Structural alterations of DNA irradiated with UV light were analyzed by the agarose gel technique. Relaxed, circular pAT 153 DNA molecules were sensitized by broad band radiation with a maximum at 313 nm in the presence of silver ions or irradiated with 254 nm light in buffer only. In both cases the electrophoretic mobility of DNA topoisomers was altered as a linear function of UV exposure. For DNA irradiated in the sensitized reaction the unwinding angle per site sensitive to Micrococcus luteus pyrimidine dimer endonuclease was found tobe–11.4°. This value is significantly smaller thanthe–14.3° already known for DNA topoisomers irradiated with 254 nm light. The irradiated DNAs were a very good substrate for the Escherichia coli photoreactivating enzyme (PRE). However, the photoenzymic removal of all sites sensitive to the endonuclease specific for pyrimidine dimers was not coupled to a full restoration of the original electrophoretic mobility. Thirty and 23% of the unwinding were still present in the photoreactivated topoisomers and the unwinding angles per pyrimidine dimer were then recalculatedas–10.1°and–8.7° for DNAs irradiated with 254 nm and sensitized, respectively. The limited difference between these two values could result from the different base composition of the pyrimidine dimers generated in the conditions of irradiation used. These results show that the tertiary structure of DNA is measureably altered by UV photodamages other than pyrimidine dimers.     

ALFALFA SEEDLINGS GROWN OUTDOORS ARE MORE RESISTANT TO UV-INDUCED DNA DAMAGE THAN PLANTS GROWN IN A UV-FREE ENVIRONMENTAL CHAMBER

Abstract The relative UV sensitivities of alfalfa seedlings grown outdoors versus plants grown in a growth chamber under UV-filtered cool white fluorescent bulbs have been determined using three criteria: (1) level of endogenous DNA damage as sites for the UV endonuclease from Micrococcus luteus . (2) susceptibility to pyrimidine dimer induction by a UV challenge exposure and (3) ability to repair UV-induced damage. We find that outdoor-grown plants contain approximately equal frequencies of endogenous DNA damages, are less susceptible to dimer induction by a challenge exposure of broad-spectrum UV and photorepair dimers more rapidly than plants grown in an environmental chamber under cool white fluorescent lamps plus a filter that removes most UV radiation. These data suggest that plants grown in a natural environment would be less sensitive to UVB-induced damage than would be predicted on the basis of studies on plants grown under minimum UV.     

PHOTOCHEMISTRY OF DNA USING 193 nm EXCIMER LASER RADIATION

Photoproducts in double-stranded DNA induced by 193 nm radiation have been investigated. Double-stranded, supercoiled pBR322 DNA in buffered aqueous solution was exposed to varying fluences of 193 nm radiation from an ArF excimer laser. The quantum yields for formation of cyclobutylpyrimidine dimers, frank strand breaks and alkali labile sites were calculated from the conversion of supercoiled (Form I) DNA to relaxed (Form II) DNA after treatment with Micrococcus luteus dimer-specific endonuclease, no treatment, or treatment with alkali and heat, respectively. The quantum yields were 1.65 (+/- 0.03) X 10(-3) for pyrimidine dimers, 9.4 (+/- 3.2) X 10(-5) for frank strand breaks and 9.6 (+/- 3.6) X 10(-5) for alkali labile sites. The quantum yields for pyrimidine dimers and strand breaks and alkali labile sites were not affected by 10 nM mannitol. The relative quantum yields for these DNA photoproducts induced by 193 nm radiation differed markedly from those produced by 254 nm radiation.