Structure-function studies of the T4 endonuclease V repair enzyme

High Melanin Content in Melanoma Cells Contributes to Enhanced DNA Damage after Rose Bengal Photosensitization

Melanoma is a type of tumor that originates from melanocytes. Irradiation of melanin with UVA and visible light can produce reactive oxygen species (ROS) such as singlet molecular oxygen (¹ O₂ ). The objective of this study was to examine DNA damage in melanoma cells (B16-F10) with different melanin contents, subjected to ¹ O₂ generation. To this end, we used the photosensitizer Rose Bengal acetate (RBAc) and irradiation with visible light (526 nm) (RBAc-PDT). We used the modified comet assay with the repair enzymes hOGG1 and T4 endonuclease V to detect the DNA damage associated with 8-oxo-7,8-dihydro-2'-deoxyguanosine and cyclobutane pyrimidine dimers lesions, respectively. We observed increased formation of hOGG1- and T4endoV-sensitive DNA lesions after light exposure (with or without RBAc). Furthermore, 18 h after irradiation, hOGG1-sensitive DNA lesions increased compared to that at the initial time point (0 h), which shows that a high melanin content contributes to post-irradiation formation of them, mainly via sustained oxidative stress, as confirmed by the measurement of ROS levels and activity of antioxidant enzymes. Contrastingly, the number of T4endoV-sensitive DNA lesions decreased over time (18 h). Our data indicate that in melanoma cells, a higher amount of melanin may affect DNA damage levels when subjected to RBAc-PDT.

Xeroderma Pigmentosum: General Aspects and Management

Xeroderma Pigmentosum (XP) is a rare genetic syndrome with a defective DNA nucleotide excision repair. It is characterized by (i) an extreme sensitivity to ultraviolet (UV)-induced damages in the skin and eyes; (ii) high risk to develop multiple skin tumours; and (iii) neurologic alterations in the most severe form. To date, the management of XP patients consists of (i) early diagnosis; (ii) a long-life protection from ultraviolet radiation, including avoidance of unnecessary UV exposure, wearing UV blocking clothing, and use of topical sunscreens; and (iii) surgical resections of skin cancers. No curative treatment is available at present. Thus, in the last decade, in order to prevent or delay the progression of the clinical signs of XP, numerous strategies have been proposed and tested, in some cases, with adverse effects. The present review provides an overview of the molecular mechanisms featuring the development of XP and highlights both advantages and disadvantages of the clinical approaches developed throughout the years. The intention of the authors is to sensitize scientists to the crucial aspects of the pathology that could be differently targeted. In this context, the exploration of the process underlining the conception of liposomal nanocarriers is reported to focus the attention on the potentialities of liposomal technology to optimize the administration of chemoprotective agents in XP patients.

Ability of the Putative Decomposition Products of 2,3-dioxetanes of Indoles to Photosensitize Cyclobutane Pyrimidine Dimer (CPD) Formation and its Implications for the "Dark" (Chemisensitized) Pathway to CPDs in Melanocytes†

The formation of cyclobutane pyrimidine dimers (CPDs) by a "dark" pathway in melanocytes has been attributed to chemisensitization by dioxetanes produced from peroxynitrite oxidation of melanin or melanin precursors. These dioxetanes are proposed to decompose to triplet state compounds which sensitize CPD formation by triplet-triplet energy transfer. To determine whether such compounds are capable of sensitizing CPD formation, the putative decomposition products of 2,3-dioxetanes of variously substituted indoles were synthesized and their triplet state energies determined at 77 K. Their ability to photosensitize CPD formation was determined by an enzyme-coupled gel electrophoresis assay in comparison with norfloxacin (NFX) which has the lowest triplet energy known to sensitize CPD formation. The decomposition products of 2,3-dioxetanes of 5-hydroxy and 5,6-dimethoxy indoles used as models for melanin precursors had lower triplet energies and were incapable of photosensitizing CPD formation. Theoretical calculations suggest that the decomposition products of the 2,3-dioxetanes of melanin precursors DHI and DHICA will have similarly low triplet energies. Decomposition products of the 2,3-dioxetanes of indoles lacking oxygen substituents had higher triplet energies than NFX and were capable of photosensitizing CPD formation, suggesting that peroxynitrite oxidation of tryptophan could play a hitherto unrecognized role in the dark pathway to CPDs.

The epigenetic DNA modification 5-carboxylcytosine promotes high levels of cyclobutane pyrimidine dimer formation upon UVB irradiation

In mammals, DNA methyltransferases create 5-methylcytosines (5mC) predominantly at CpG dinucleotides. 5mC oxidases convert 5mC in three consecutive oxidation steps to 5-hydroxymethylcytosine (5hmC), 5-formylcytosine (5fC) and then 5-carboxylcytosine (5caC). Upon irradiation with UV light, dipyrimidines containing C, 5mC and 5hmC are known to form cyclobutane pyrimidine dimers (CPDs) as major DNA photolesions. However, the photobiology of 5fC and 5caC has remained largely unexplored. Here, we tested a series of oligonucleotides with single or multiple positions carrying cytosine (C), 5mC, 5hmC, 5fC or 5caC and irradiated them with different sources of UV irradiation. While UVC radiation produced CPDs near dipyrimidines containing all types of modified cytosine bases, UVB radiation produced by far the highest levels of CPDs near 5caC-containing sequences. Dipyrimidines one or two nucleotide positions adjacent to 5caC but not always those involving this modified base directly were the major sites for these prominent UVB photoproducts. This selectivity did not depend on whether 5caC was present on one or both DNA strands at CpG sequences. We also observed a tendency of the 5caC-containing DNA strands to undergo apparent covalent crosslinking. This reaction occurred with UVB or UVC but not with UVA irradiation. Our data show that 5-carboxylcytosine, although generally a rare base in the genome, can nonetheless make a strong contribution to sequence-specific DNA damage perhaps by acting as a DNA-intrinsic photosensitizer.

Chromosomal landscape of UV damage formation and repair at single-nucleotide resolution

UV-induced DNA lesions are important contributors to mutagenesis and cancer, but it is not fully understood how the chromosomal landscape influences UV lesion formation and repair. Genome-wide profiling of repair activity in UV irradiated cells has revealed significant variations in repair kinetics across the genome, not only among large chromatin domains, but also at individual transcription factor binding sites. Here we report that there is also a striking but predictable variation in initial UV damage levels across a eukaryotic genome. We used a new high-throughput sequencing method, known as CPD-seq, to precisely map UV-induced cyclobutane pyrimidine dimers (CPDs) at single-nucleotide resolution throughout the yeast genome. This analysis revealed that individual nucleosomes significantly alter CPD formation, protecting nucleosomal DNA with an inward rotational setting, even though such DNA is, on average, more intrinsically prone to form CPD lesions. CPD formation is also inhibited by DNA-bound transcription factors, in effect shielding important DNA elements from UV damage. Analysis of CPD repair revealed that initial differences in CPD damage formation often persist, even at later repair time points. Furthermore, our high-resolution data demonstrate, to our knowledge for the first time, that CPD repair is significantly less efficient at translational positions near the dyad of strongly positioned nucleosomes in the yeast genome. These findings define the global roles of nucleosomes and transcription factors in both UV damage formation and repair, and have important implications for our understanding of UV-induced mutagenesis in human cancers.

Immuno-capture of UVDE generated 3'-OH ends at UV photoproducts

A strategy amenable to the genome-wide study of DNA damage and repair kinetics is described. The ultraviolet damage endonuclease (UVDE) generates 3'-OH ends at the two major UV induced DNA lesions, cyclobutane pyrimidine dimers (CPDs) and 6,4 pyrimidine-pyrimidone dimers (6,4 PPs), allowing for their capture after biotin end-labeling. qPCR amplification of biotinylated DNA enables parallel measuring of DNA damage in several loci, which can then be combined with high-throughput screening of cell survival to test genotoxic reagents. Alternatively, a library of captured sequences could be generated for a genome wide study of damage sites and large-scale assessment of repair kinetics in different regions of the genome, using next-generation sequencing. The assay is suitable to study any DNA lesion that can be converted into 3'-OH by UVDE, or other enzymes. Toward these goals, we compared UVDE with the classical T4 endonuclease V (T4V) assay. We showed that there is a linear correlation between UV dose, 3'-OH formation and capture by immunoprecipitation, together with its potential application for in vivo studies.

The nucleotide excision repair system of Borrelia burgdorferi is the sole pathway involved in repair of DNA damage by UV light

To survive and avoid accumulation of mutations caused by DNA damage, the genomes of prokaryotes encode a variety of DNA repair pathways most well characterized in Escherichia coli. Some of these are required for the infectivity of various pathogens. In this study, the importance of 25 DNA repair/recombination genes for Borrelia burgdorferi survival to UV-induced DNA damage was assessed. In contrast to E. coli, where 15 of these genes have an effect on survival of UV irradiation, disruption of recombinational repair, transcription-coupled repair, methyl-directed mismatch correction, and repair of arrested replication fork pathways did not decrease survival of B. burgdorferi exposed to UV light. However, the disruption of the B. burgdorferi nucleotide excision repair (NER) pathway (uvrA, uvrB, uvrC, and uvrD) resulted in a 10- to 1,000-fold increase in sensitivity to UV light. A functional NER pathway was also shown to be required for B. burgdorferi resistance to nitrosative damage. Finally, disruption of uvrA, uvrC, and uvrD had only a minor effect upon murine infection by increasing the time required for dissemination.

Repair-independent chromatin assembly onto active ribosomal genes in yeast after UV irradiation

Chromatin rearrangements occur during repair of cyclobutane pyrimidine dimers (CPDs) by nucleotide excision repair (NER). Thereafter, the original structure must be restored to retain normal genomic functions. How NER proceeds through nonnucleosomal chromatin and how open chromatin is reestablished after repair are unknown. We analyzed NER in ribosomal genes (rDNA), which are present in multiple copies but only a fraction are actively transcribed and nonnucleosomal. We show that removal of CPDs is fast in the active rDNA and that chromatin reorganization occurs during NER. Furthermore, chromatin assembles on nonnucleosomal rDNA during the early events of NER but in the absence of DNA repair. The resumption of transcription after removal of CPDs correlates with the reappearance of nonnucleosomal chromatin. To date, only the passage of replication machinery was thought to package ribosomal genes in nucleosomes. In this report, we show that early events after formation of UV photoproducts in DNA also promote chromatin assembly.

Accommodation and repair of a UV photoproduct in DNA at different rotational settings on the nucleosome surface

Cyclobutane-thymine dimers (CTDs), the most common DNA lesion induced by UV radiation, cause 30 degrees bending and 9 degrees unwinding of the DNA helix. We prepared site-specific CTDs within a short sequence bracketed by strong nucleosome-positioning sequences. The rotational setting of CTDs over one turn of the helix near the dyad center on the histone surface was analyzed by hydroxyl radical footprinting. Surprisingly, the position of CTDs over one turn of the helix does not affect the rotational setting of DNA on the nucleosome surface. Gel-shift analysis indicates that one CTD destabilizes histone-DNA interactions by 0.6 or 1.1 kJ/mol when facing away or toward the histone surface, respectively. Thus, 0.5 kJ/mol energy penalty for a buried CTD is not enough to change the rotational setting of sequences with strong rotational preference. The effect of rotational setting on CTD removal by nucleotide excision repair (NER) was examined using Xenopus oocyte nuclear extracts. The NER rates are only 2-3 times lower in nucleosomes and change by only 1.5-fold when CTDs face away or toward the histone surface. Therefore, in Xenopus nuclear extracts, the rotational orientation of CTDs on nucleosomes has surprisingly little effect on rates of repair. These results indicate that nucleosome dynamics and/or chromatin remodeling may facilitate NER in gaining access to DNA damage in nucleosomes.

Interaction of T4 endonuclease V with DNA: importance of the flexible loop regions in protein-DNA interaction

T4 endonuclease V (T4 endo V), a thymine dimer-specific DNA repair enzyme, and its interaction with DNA were investigated by nuclear magnetic resonance (NMR) spectroscopy. Backbone resonance assignment, chemical shift mapping, and 15N relaxation measurements were employed to the free and DNA-bound enzymes. The secondary structure and the tertiary fold of T4 endo V in solution were consistent with those from the crystallographic study. The backbone 1H and 15N chemical shift perturbation upon the addition of DNA without a lesion revealed that the residues including Arg3, Arg22-Arg26, Lys45-Phe60, and Lys86-Thr88 participate in DNA binding. However, when DNA with a lesion was added to the enzyme and concomitantly the catalytic reaction was completed, the resonances of Arg22, Glu23, and Arg26, which constitute the catalytic active site, and the resonance of Thr88, were perturbed in a different manner. The region around Lys45-Ser47 was found to be involved in DNA binding, which have not been reported elsewhere. The backbone relaxation measurements of the free and DNA-bound enzymes indicated that two loop regions, Lys45-Phe60 and Lys86-Asp92, show the high degree of backbone flexibility. These results imply that two flexible loop regions may play an important role in DNA binding and in scanning along DNA duplex to search the thymine dimer sites in UV-damaged DNA.

Asymmetry of DNA replication and translesion synthesis of UV-induced thymine dimers

In vitro replication assays for detection and quantification of bypass of UV-induced DNA photoproducts were used to compare the capacity of extracts prepared from different human cell lines to replicate past the cis,syn cyclobutane thymine dimer ([c,s]TT). The results demonstrated that neither nucleotide excision repair (NER) nor mismatch repair (MMR) activities in the intact cells interfered with measurements of bypass replication efficiencies in vitro. Extracts prepared from HeLa (NER- and MMR-proficient), xeroderma pigmentosum group A (NER-deficient), and HCT116 (MMR-deficient) cells displayed similar capacity for translesion synthesis, when the substrate carried the site-specific [c,s]TT on the template for the leading or the lagging strand of nascent DNA. Extracts from xeroderma pigmentosum variant cells, which lack DNA polymerase eta, were devoid of bypass activity. Bypass-proficient extracts as a group (n=16 for 3 extracts) displayed higher efficiency (P=0.005) for replication past the [c,s]TT during leading strand synthesis (84+/-22%) than during lagging strand synthesis (64+/-13%). These findings are compared to previous results concerning the bypass of the (6-4) photoproduct [Biochemistry 40 (2001) 15215] and analyzed in the context of the reported characteristics of bypass DNA polymerases implicated in translesion synthesis of UV-induced DNA lesions. Models to explain how these enzymes might interact with the DNA replication machinery are considered. An alternative pathway of bypass replication, which avoids translesion synthesis, and the mutagenic potential of post-replication repair mechanisms that contribute to the duplication of the human genome damaged by UV are discussed.

Transcription-coupled repair in RNA polymerase I-transcribed genes of yeast

Nucleotide excision repair (NER) of UV-induced cyclobutane pyrimidine dimers (CPDs) was measured in the individual strands of transcriptionally active and inactive ribosomal genes of yeast. Ribosomal genes (rDNA) are present in multiple copies, but only a fraction of them is actively transcribed. Restriction enzyme digestion was used to specifically release the transcriptionally active fraction from yeast nuclei, and selective psoralen crosslinking was used to distinguish between active and inactive rDNA chromatin. Removal of CPDs was followed in both rDNA populations, and the data clearly show that strand-specific repair occurs in transcriptionally active rDNA while being absent in the inactive rDNA fraction. Thus, transcription-coupled repair occurs in RNA polymerase I-transcribed genes in yeast. Moreover, the nontranscribed strand of active rDNA is repaired faster than either strand of inactive rDNA, implying that NER has preferred access to the active, non-nucleosomal rDNA chromatin. Finally, restriction enzyme accessibility to active rDNA varies during NER, suggesting that there is a change in ribosomal gene chromatin structure during or soon after CPD removal.

DNA repair of a single UV photoproduct in a designed nucleosome

Eukaryotic DNA repair enzymes must interact with the architectural hierarchy of chromatin. The challenge of finding damaged DNA complexed with histone proteins in nucleosomes is complicated by the need to maintain local chromatin structures involved in regulating other DNA processing events. The heterogeneity of lesions induced by DNA-damaging agents has led us to design homogeneously damaged substrates to directly compare repair of naked DNA with that of nucleosomes. Here we report that nucleotide excision repair in Xenopus nuclear extracts can effectively repair a single UV radiation photoproduct located 5 bases from the dyad center of a positioned nucleosome, although the nucleosome is repaired at about half the rate at which the naked DNA fragment is. Extract repair within the nucleosome is >50-fold more rapid than either enzymatic photoreversal or endonuclease cleavage of the lesion in vitro. Furthermore, nucleosome formation occurs (after repair) only on damaged naked DNA (165-bp fragments) during a 1-h incubation in these extracts, even in the presence of a large excess of undamaged DNA. This is an example of selective nucleosome assembly by Xenopus nuclear extracts on a short linear DNA fragment containing a DNA lesion.

Improved method for measuring the ensemble average of strand breaks in genomic DNA

The cis-syn cyclobutane pyrimidine dimer (CPD) is the major photoproduct induced in DNA by low wavelength ultraviolet radiation. An improved method was developed to detect CPD formation and removal in genomic DNA that avoids the problems encountered with the standard method of endonuclease detection of these photoproducts. Since CPD-specific endonucleases make single-strand cuts at CPD sites, quantification of the frequency of CPDs in DNA is usually done by denaturing gel electrophoresis. The standard method of ethidium bromide staining and gel photography requires more than 10 microg of DNA per gel lane, and correction of the photographic signal for the nonlinear film response. To simplify this procedure, a standard Southern blot protocol, coupled with phosphorimage analysis, was developed. This method uses random hybridization probes to detect genomic sequences with minimal sequence bias. Because of the vast linearity range of phosphorimage detection, scans of the signal profiles for the heterogeneous population of DNA fragments can be integrated directly to determine the number-average size of the population.

Three-dimensional structural views of damaged-DNA recognition: T4 endonuclease V, E. coli Vsr protein, and human nucleotide excision repair factor XPA

Genetic information is frequently disturbed by introduction of modified or mismatch bases into duplex DNA, and hence all organisms contain DNA repair systems to restore normal genetic information by removing such damaged bases or nucleotides and replacing them by correct ones. The understanding of this repair mechanism is a central subject in cell biology. This review focuses on the three-dimensional structural views of damaged DNA recognition by three proteins. The first protein is T4 endonuclease V (T4 endo V), which catalyzes the first reaction step of the excision repair pathway to remove pyrimidine-dimers (PD) produced within duplex DNA by UV irradiation. The crystal structure of this enzyme complexed with DNA containing a thymidine-dimer provided the first direct view of DNA lesion recognition by a repair enzyme, indicating that the DNA kink coupled with base flipping-out is important for damaged DNA recognition. The second is very short patch repair (Vsr) endonuclease, which recognizes a TG mismatch within the five base pair consensus sequence. The crystal structure of this enzyme in complex with duplex DNA containing a TG mismatch revealed a novel mismatch base pair recognition scheme, where three aromatic residues intercalate from the major groove into the DNA to strikingly deform the base pair stacking but the base flipping-out does not occur. The third is human nucleotide excision repair (NER) factor XPA, which is a major component of a large protein complex. This protein has been shown to bind preferentially to UV- or chemical carcinogen-damaged DNA. The solution structure of the XPA central domain, essential for the interaction of damaged DNA, was determined by NMR. This domain was found to be divided mainly into a (Cys)4-type zinc-finger motif subdomain for replication protein A (RPA) recognition and the carboxyl terminal subdomain responsible for DNA binding.

Mitotic viability and metabolic competence in UV-irradiated yeast cells

Colony formation is the classic method for measuring survival of yeast cells. This method measures mitotic viability and can underestimate the fraction of cells capable of carrying out other DNA processing events. Here, we report an alternative method, based on cell metabolism, to determine the fraction of surviving cells after ultraviolet (UV) irradiation. The reduction of 2,3,5-triphenyl tetrazolium chloride (or TTC) to formazan in mitochondria was compared with cell colony formation and DNA repair capacity in wt cells and two repair-deficient strains (rad1Delta and rad7Delta). Both TTC reduction and cell colony formation gave a linear response with different ratios of mitotically viable cells and heat-inactivated cells. However, monitoring the formation of formazan in non-dividing yeast cells that are partially (rad7Delta) or totally (wt) proficient at DNA repair is a more accurate measure of cell survival after UV irradiation. Before repair of UV photoproducts (cis-syn cyclobutane pyrimidine dimers or CPDs) is complete, these two assays give very different results, implying that many damaged cells are metabolically competent but cannot replicate. For example, only 25% of the rad7Delta cells are mitotically viable after a UV dose of 12 J/m(2)75% of these cells are metabolically competent and remove over 55% of the CPDs from their genomic DNA. Moreover, repair of CPDs in wt cells dramatically decreases after the first few hours of liquid holding (L.H.; incubation in water) and correlates with a substantial decrease in cell metabolism over the same time period. In contrast, cell colony formation may be the more accurate indicator of cell survival after UV irradiation of rad1Delta cells (i.e., cells with little DNA repair activity). These results indicate that the metabolic competence of UV-irradiated, non-dividing yeast cells is a much better indicator of cell survival than mitotic viability in partially (or totally) repair proficient yeast cultures.

Ultraviolet damage and nucleosome folding of the 5S ribosomal RNA gene

The Xenopus borealis somatic 5S ribosomal RNA gene was used as a model system to determine the mutual effects of nucleosome folding and formation of ultraviolet (UV) photoproducts (primarily cis-syn cyclobutane pyrimidine dimers, or CPDs) in chromatin. We analyzed the preferred rotational and translational settings of 5S rDNA on the histone octamer surface after induction of up to 0.8 CPD/nucleosome core (2.5 kJ/m(2) UV dose). DNase I and hydroxyl radical footprints indicate that UV damage at these levels does not affect the average rotational setting of the 5S rDNA molecules. Moreover, a combination of nuclease trimming and restriction enzyme digestion indicates the preferred translational positions of the histone octamer are not affected by this level of UV damage. We also did not observe differences in the UV damage patterns of irradiated 5S rDNA before or after nucleosome formation, indicating there is little difference in the inhibition of nucleosome folding by specific CPD sites in the 5S rRNA gene. Conversely, nucleosome folding significantly restricts CPD formation at all sites in the three helical turns of the nontranscribed strand located in the dyad axis region of the nucleosome, where DNA is bound exclusively by the histone H3-H4 tetramer. Finally, modulation of the CPD distribution in a 14 nt long pyrimidine tract correlates with its rotational setting on the histone surface, when the strong sequence bias for CPD formation in this tract is minimized by normalization. These results help establish the mutual roles of histone binding and UV photoproducts on their formation in chromatin.

Synthesis and nucleosome structure of DNA containing a UV photoproduct at a specific site

A strategy was developed to assemble nucleosomes specifically damaged at only one site and one structural orientation. The most prevalent UV photoproduct, a cis-syn cyclobutane thymine dimer (cs CTD), was chemically synthesized and incorporated into a 30 base oligonucleotide harboring the glucocorticoid hormone response element. This oligonucleotide was assembled into a 165 base pair double stranded DNA molecule with nucleosome positioning elements on each side of the cs CTD-containing insert. Proton NMR verified that the synthetic photoproduct is the cis-syn stereoisomer of the CTD. Moreover, two different pyrimidine dimer-specific endonucleases cut approximately 90% of the dsDNA molecules. This cleavage is completely reversed by photoreactivation with E. coli UV photolyase, further demonstrating the correct stereochemistry of the photoproduct. Nucleosomes were reconstituted by histone octamer exchange from chicken erythocyte core particles, and contained a unique translational and rotational setting of the insert on the histone surface. Hydroxyl radical footprinting demonstrates that the minor groove at the cs CTD is positioned away from the histone surface about 5 bases from the nucleosome dyad. Competitive gel-shift analysis indicates there is a small increase in histone binding energy required for the damaged fragment (DeltaDeltaG approximately 0.15 kcal/mol), which does not prevent complete nucleosome loading under our conditions. Finally, folding of the synthetic DNA into nucleosomes dramatically inhibits cleavage at the cs CTD by T4 endonuclease V and photoreversal by UV photolyase. Thus, specifically damaged nucleosomes can be experimentally designed for in vitro DNA repair studies.

Tight correlation between inhibition of DNA repair in vitro and transcription factor IIIA binding in a 5S ribosomal RNA gene

UV-induced photoproducts (cyclobutane pyrimidine dimers, CPDs) in DNA are removed by nucleotide excision repair (NER), and the presence of transcription factors on DNA can restrict the accessibility of NER enzymes. We have investigatigated the modulation of NER in a gene promoter using the Xenopus transcription factor IIIA (TFIIIA)-5S rDNA complex and Xenopus oocyte nuclear extracts. TFIIIA alters CPD formation primarily in the transcribed strand of the 50 bp internal control region (ICR) of 5S rDNA. During NER in vitro, CPD removal is reduced at most sites in both strands of the ICR when TFIIIA is bound. Efficient repair occurs just outside the TFIIIA-binding site (within 10 bp), and in the absence of 5S rRNA transcription. Interestingly, three CPD sites within the ICR [+56, +75 (transcribed strand) and +73 (non-transcribed strand)] are repaired rapidly when TFIIIA is bound, while CPDs within approximately 5 bases of these sites are repaired much more slowly. CPDs at these three sites may partially displace TFIIIA, thereby enabling rapid repair. However, TFIIIA is not completely displaced during NER, at least at sites outside the ICR, even though the NER complex could be sterically hindered by TFIIIA. Such inefficient repair of transcription factor binding sites could increase mutation frequency in regulatory regions of genes.

Solution-state structure of a DNA dodecamer duplex containing a Cis-syn thymine cyclobutane dimer, the major UV photoproduct of DNA

The solution structures of a duplex DNA dodecamer containing a cis-syn cyclobutane thymine dimer d(GCACGAAT[cs]TAAG).d(CTTAATTCG TGC) and its native parent sequence were determined using NMR data collected at 750 MHz. The dodecamer sequence corresponds to the section of a site-specific cis-syn dimer containing 49-mer that was found to be the binding site for the dimer-specific T4 denV endonuclease V repair enzyme by chemical and enzymatic footprinting experiments. Structures of both sequences were derived from NOE restrained molecular dynamics/simulated annealing calculations using a fixed outer layer of water and an inner dynamic layer of water with sodium counterions. The resulting structures reveal a subtle distortion to the phosphodiester backbone in the dimer-containing sequence which includes a BII phosphate at the T9pA10 junction immediately 3' to the dimer. The BII phosphate, established experimentally by analysis of the 31P chemical shifts and interpretation of the 3JP-H3' values using an optimized Karplus relationship, enables the DNA helix to accommodate the dimer by destacking the base 3' to the dimer. Furthermore, the structures provide explanations for the unusually shifted T8-N3H imino, A16-H2 and T8-Me proton resonances and T9pA10 (31)P NMR resonance and are consistent with bending, unwinding, and thermodynamic data. The implications of the structural data for the mechanism by which cis-syn dimers are recognized by repair enzymes and bypassed by DNA polymerases are also discussed.

Altered UV resistance and UV mutational spectrum in repair-proficient murine fibroblasts expressing endonuclease V

In previously reported studies, we transfected repair-proficient murine fibroblasts with the denV gene of bacteriophage T4 and showed that expression of encoded endonuclease V markedly enhanced cyclobutane pyrimidine dimer (CPD) repair and reduced the frequency of ultraviolet radiation (UV)-induced mutations. In the present studies, we compared the spectra of UV-induced mutations at the hprt locus in denV-transfected and control cells. A significant difference in mutation types was observed. While multiple base deletions and single base insertions were found in denV-transfected but not control cells, multiple tandem and non-tandem point mutations identified in control cells were absent in denV-transfected cells. When we compared colony survival following UV exposure in the two cell lines, it appeared that endonuclease V expression did not enhance UV resistance, instead denV-transfected cells had increased susceptibility to low fluences of UV. The effects of endonuclease V expression on UV resistance and on UV mutational spectrum are likely to be due both to the removal of CPDs and to the novel enzymatic activity of endonuclease V.

Incomplete complementation of the DNA repair defect in cockayne syndrome cells by the denV gene from bacteriophage T4 suggests a deficiency in base excision repair

Endonuclease V (denV) from bacteriophage T4 has been examined for its ability to complement the repair defect in Cockayne syndrome (CS) cells of complementation groups A and B. CS is an autosomal recessive disorder characterized by hypersensitivity to UV light and a defect in the preferential repair of UV-induced lesions in transcriptionally active DNA by the nucleotide excision repair (NER) pathway. The denV gene was introduced into non-transformed normal and CS fibroblasts transiently via a recombinant adenovirus (Ad) vector and into SV40-transformed normal and CS cells via a retroviral vector. Expression of denV in CS-A cells resulted in partial correction of the UV-sensitive phenotype in assays of gene-specific repair and cell viability, while correction of CS-B cells by expression of denV in the same assays was minimal or non-existent. In contrast, denV expression led to enhanced host cell reactivation (HCR) of viral DNA synthesis in both CS complementation groups to near normal levels. DenV is a glycosylase which is specific for cyclobutane-pyrimidine dimers (CPDs) but does not recognize other UV-induced lesions. Previous work has indicated that CS cells can efficiently repair all non-CPD UV-induced transcription blocking lesions (S.F. Barrett et al.. Mutation Res. 255 (1991) 281-291 [1]) and that denV incised lesions are believed to be processed via the base excision repair (BER) pathway. The inability of denV to complement the NER defect in CS cells to normal levels implies an impaired ability to process denV incised lesions by the BER pathway, and suggests a role for the CS genes, particularly the CS-B gene, in BER.

Rad23 is required for transcription-coupled repair and efficient overrall repair in Saccharomyces cerevisiae

The repair of UV-induced photoproducts (cyclobutane pyrimidine dimers) in a well-characterized minichromosome, genomic DNA, and a transcribed genomic gene (RPB2) of a rad23delta mutant of Saccharomyces care was examined. Isogenic wild-type cells show a strong bias for the repair of the transcribed strands in both the plasmid and genomic genes and efficient overall repair of both DNAs (>80% of the dimers were removed in 6 h). However, the rad23delta mutant shows (i) no strand bias for repair in these genes and decreased repair of both strands, (ii) partial repair of genomic DNA (approximately 45% in 6 h), and (iii) very poor repair of the plasmid overall approximately 15% in 6 h). These features, coupled with the decreased UV survival of rad23delta cells, indicate that Rad23 is required for both transcription-coupled repair and efficient overall repair in S. cerevisiae.

Tobacco plants expressing T4 endonuclease V show enhanced sensitivity to ultraviolet light and DNA alkylating agents

DNA repair processes and UV-filtering pigments protect organisms from the cytotoxicity of UV light and endow plants with a high degree of natural UV resistance. In an attempt to further enhance this UV resistance we have constructed transgenic tobacco lines that express a DNA repair enzyme encoded by the bacteriophage T4 denV gene. The denV gene encodes endonuclease V, an enzyme which initiates base excision repair of cyclobutane pyrimidine dimers. Its presence is expected to provide transgenotes with a repair pathway complementary to, but likely distinct from, the repair pathways found in tobacco. The denV gene, flanked by a CaMV 35S promoter and poly(A) addition site, was introduced into tobacco and mature plants regenerated. The transgenotes expressed high levels of a UV-specific endonuclease and no such activity was found in control plants. Curiously, assays which detected several different biological endpoints showed that the denV+ transgenotes were also hypersensitive to UV-C light. This hypersensitivity segregated with the denV gene and was not caused by altered concentrations of UV-filtering pigments. Moreover, the denV+ transgenotes were also hypersensitive to high levels of baseless lesions that would be generated by a transgenically expressed beta-eliminating lyase such as endonuclease V.

Crystal structure of a pyrimidine dimer-specific excision repair enzyme from bacteriophage T4: refinement at 1.45 A and X-ray analysis of the three active site mutants

Crystallographic study of bacteriophage T4 endonuclease V, which is involved in the initial step of the pyrimidine dimer-specific excision repair pathway, has been carried out with respect to the wild-type and three different mutant enzymes. This enzyme catalyzes the cleavage of the N-glycosyl bond at the 5'-side of the pyrimidine dimer, and subsequently incises the phosphodiester bond at the apyrimidinic site through a beta-elimination reaction. The structure of the wild-type enzyme refined at 1.45 A resolution reveals the detailed molecular architecture. The enzyme is composed of a single compact domain classified as an all-alpha structure. The molecule is stabilized mainly by three hydrophobic cores, two of which include many aromatic side-chain interactions. The structure has a unique folding motif, where the amino-terminal segment penetrates between two major alpha-helices and prevents their direct contact, and it is incompatible with the close-packing category of helices for protein folding. The concave surface, covered with many positive charges, implies an interface for DNA binding. The glycosylase catalytic center, which comprises Glu23 and the surrounding basic residues Arg3, Arg22 and Arg26, lie in this basic surface. The crystal structures of the three active-site mutants, in which Glu23 was replaced by Gln(E23Q) and Asp (E23D), respectively, and Arg3 by Gln (R3Q), have been determined at atomic resolution. The backbone structures of the E23Q and R3Q mutants were almost identical with that of the wild-type, while the E23D mutation induces a small, but significant, change in the backbone structure, such as an increase of the central kink of the H1 helix at Pro25. In the catalytic center of the glycosylase, however, these three mutations do not generate notable movements of protein atoms, except for significant shifts of some bound water molecules. Thus, the structural differences between the wild-type and each mutant are confined to the remarkably small region around their replaced chemical groups. Combined with the biochemical studies and the difference circular dichroism measurements, these results allow us to conclude that the negatively charged carboxyl group of Glu23 is essential for the cleavage of the N-glycosyl bond, and that the positively charged guanidino group of Arg3 is crucial to bind the substrate, a DNA duplex containing a pyrimidine dimer. The amino terminal alpha-amino group is located at a position approximately 4.4 A away from the carboxyl group of Glu23. These structural features are generally consistent with the reaction scheme proposed by Dodson and co-workers.

Involvement of glutamic acid 23 in the catalytic mechanism of T4 endonuclease V

Bacteriophage T4 endonuclease V has both pyrimidine dimer-specific DNA glycosylase and abasic (AP) lyase activities, which are sequential yet biochemically separable functions. Previous studies using chemical modification and site-directed mutagenesis techniques have shown that the catalytic activities are mediated through the alpha-amino group of the enzyme forming a covalent (imino) intermediate. However, in addition to the amino-terminal active site residue, examination of the x-ray crystal structure of endonuclease V reveals the presence of Glu-23 near the active site, and this residue has been strongly implicated in the reaction chemistry. In order to understand the role of Glu-23 in the reaction mechanism, four different mutations (E23Q, E23C, E23H, E23D) were constructed, and the mutant proteins were evaluated for DNA glycosylase and AP lyase activities using defined substrates and specific in vitro and in vivo assays. Replacement of Glu-23 with Gln, Cys, or His completely abolished DNA glycosylase and AP lyase activities, while replacement with Asp retained negligible amounts of glycosylase activity, but retained near wild type levels of AP lyase activity. Gel shift assays revealed that all four mutant proteins can recognize and bind to thymine dimers. The results indicate that Glu-23 is the candidate for stabilizing the charge of the imino intermediate that is likely to require an acidic group in the active site of the enzyme.

Reduction of ultraviolet-induced skin cancer in mice by topical application of DNA excision repair enzymes

Ultraviolet (UV) irradiation produces two major photoproducts, cyclobutane pyrimidine dimers (CPD) and (6-4) photoproducts. T4 endonuclease V (T4N5), which specifically repairs CPD, is encapsulated in liposomes. A previous study has shown that UV-induced carcinogenesis in mice was suppressed by the application of T4N5 liposomes. To confirm the suppressive effect, we applied T4N5 liposomes with repeated UVB exposure to hairless mice. At the end of the experiment, mice treated with T4N5 liposomes had 3.5 +/- 1.3 tumors per mouse, and control mice had 6.3 +/- 2.8 tumors per mouse. In addition, the incidence of tumors was reduced in T4N5 liposome-treated mice compared with controls. The pathological diagnosis of the tumors was not significantly different between two groups. Immunohistochemical analysis of p53 protein in UV-induced tumors showed that nearly half of the tumors in both groups were positive. When the biopsied normal-looking skin taken during the experiment was stained with p53 antibody, there was no significant difference of the timing of p53 protein expression between the control mice and T4N5 liposome-treated mice. These results confirmed that CPD plays a pivotal role in UV carcinogenesis, although the molecular mechanisms of the suppression by T4N5 liposomes should be further clarified.

Enhanced pyrimidine dimer repair in cultured murine epithelial cells transfected with the denV gene of bacteriophage T4

The patch size for excision repair of ultraviolet radiation (UV)-induced pyrimidine dimers was determined in cultured murine epithelial cells with normal and enhanced pyrimidine dimer repair capabilities. Cells with enhanced pyrimidine dimer repair were produced by transfecting 308 cells with the denV gene of bacteriophage T4; this gene encodes the enzyme endonuclease V. Pyrimidine dimer repair following exposure to UV from an FS-40 sunlamp was determined by micrococcal dimer-specific nuclease digestion and alkaline sucrose ultracentrifugation. Patch size ws estimated based on the photolytic lability of bromodeoxyuridine-substituted DNA. Excision repair of UV-induced pyrimidine dimers in denV-transfected 308 cells was enhanced two- to threefold. Production of mRNA from the denV gene in cell lines with enhanced repair was confirmed by RNA blotting. In control cells, the patch size for excision repair of DNA photoproducts was estimated to be 34 nucleotides per photoproduct removed; in denV-transfected cells, a smaller average patch size of 10-16 nucleotides per photoproduct removed was calculated. Thus, endonuclease V activity appears to alter not only the extent, but also the nature of excision repair in UV-exposed mammalian epithelial cells.

Replication of UV-irradiated DNA in human cell extracts: evidence for mutagenic bypass of pyrimidine dimers

We have examined the efficiency and fidelity of simian virus 40-origin-dependent replication of UV-irradiated double-stranded DNA in extracts of human cells. Using as a mutational target the alpha-complementation domain of the Escherichia coli lacZ gene in bacteriophage M13mp2 DNA, replication of undamaged DNA in HeLa cell extracts was highly accurate, whereas replication of DNA irradiated with UV light (280-320 nm) was both less efficient and less accurate. Replication was inhibited by irradiation in a dose-dependent manner. Nonetheless, covalently closed, monomer-length circular products were generated that were resistant to digestion by Dpn I, showing that they resulted from semiconservative replication. These products were incised by T4 endonuclease V, whereas the undamaged replication products were not, suggesting that pyrimidine dimers were bypassed during replication. When replicated, UV-irradiated DNA was used to transfect an E. coli alpha-complementation host strain to score mutant M13mp2 plaques, the mutant plaque frequency was substantially higher than that obtained with either unirradiated, replicated DNA, or unreplicated, UV-irradiated DNA. Both the increased mutagenicity and the inhibition of replication associated with UV irradiation were reversed by treatment of the irradiated DNA with photolyase before replication. Sequence analysis of mutants resulting from replication of UV-irradiated DNA demonstrated that most mutants contained C-->T transition errors at dipyrimidine sites. A few mutants contained 1-nt frameshift errors or tandem double CC-->TT substitutions. The data are consistent with the interpretation that pyrimidine dimers are bypassed during replication by the multiprotein replication apparatus in human cell extracts and that this bypass is mutagenic primarily via misincorporation of dAMP opposite a cytosine (or uracil) in the dimer.

Structure/function analysis of the Ala116-->Lys121 region of endonuclease V by random targeted mutagenesis

Endonuclease V is the product of the denV gene of bacteriophage T4 and is responsible for the recognition and repair of pyrimidine dimers due to UV irradiation of DNA. This is accomplished by a two-step mechanism involving incision at the site of the lesion followed by cleavage of the phosphate backbone. In order to better understand this molecule, and to validate our new mutagenesis procedure, we have constructed a series of random mutations within the region Ala116-->Lys121 using a random targeted mutagenesis procedure developed for this study. The results presented here suggest an important role for this region in the stabilization of the thymine dimer-containing substrate. These mutants also confirm a direct correlation between survival and both DNA binding and pyrimidine dimer-DNA glycosylase activity. No such correlation exists between survival and AP lyase activity. The results are consistent with the recently published X-ray crystal structure.

Role of the basic amino acid cluster and Glu-23 in pyrimidine dimer glycosylase activity of T4 endonuclease V

T4 endonuclease V [endodeoxyribonuclease (pyrimidine dimer); deoxyribonuclease (pyrimidine dimer), EC 3.1.25.1] initiates repair of damaged DNA by hydrolysis of the N-glycosyl bond at the 5' side of a pyrimidine photodimer in double-stranded DNA. To study one of the active sites of T4 endonuclease V, systematic site-directed mutagenesis was performed on the synthetic T4 endonuclease V gene, in parallel with three-dimensional structure analysis by x-ray crystallography. The mutant proteins were evaluated for DNA glycosylase activity using an oligonucleotide duplex (14-mer) containing a single thymidine dimer as a substrate. Replacement of either Glu-23 with glutamine or asparatic acid or Arg-3 with glutamine completely abolished DNA glycosylase activity. Mutation of Arg-3 to lysine or of Arg-26 to glutamine or lysine in a basic amino acid cluster caused serious defects in DNA glycosylase activity, which are reflected in the increases in Km and decreases in kcat of DNA glycosylase activity. On the other hand, substitutions of lysine for Arg-22 or of glutamine for Arg-117 or Lys-121 resulted in increases in the Km value. The completely inactive mutant proteins, E23Q and R3Q, in which glutamine was substituted for Glu-23 and Arg-3, respectively, were further investigated by CD spectroscopy for their ability to bind the oligonucleotide substrate. It was found that the E23Q protein retained specific substrate-binding ability, whereas the R3Q protein did not. These results indicate that Glu-23 plays an important role in catalysis of the DNA glycosylase reaction, and that Arg-3 is a crucial residue for substrate binding. In addition, Arg-22, Arg-26, Arg-117, and Lys-121 in the basic amino acid cluster also participate in substrate binding. We conclude that the basic amino acid cluster in T4 endonuclease V is an essential structure for DNA glycosylase activity.

Cell cycle progression in denV-transfected murine fibroblasts exposed to ultraviolet radiation

Repair-proficient murine fibroblasts transfected with the denV gene of bacteriophage T4 repaired 70-80% of pyrimidine dimers within 24 h after exposure to 150 J/m2 ultraviolet radiation (UVR) from an FS-40 sunlamp. Under the same conditions, control cells repaired only about 20% of UVR-induced pyrimidine dimers. After UVR exposure, both control and denV-transfected cells exhibited some degree of DNA-synthesis inhibition, as determined by flow cytometric analysis of cell-cycle kinetics in propidium iodide-stained cells. DenV-transfected cells had a longer and more profound S phase arrest than control cells, but both control and denV-transfected cells had largely recovered from UVR effects on cell-cycle kinetics by 48 h after UVR exposure. Inhibition of DNA synthesis by UVR was also measured by determining post-UVR incorporation of bromodeoxyuridine (BrdU). The amount of BrdU incorporated was quantitated by determining with flow cytometry the quenching of Hoechst dye 33342 by BrdU incorporated in cellular DNA. DenV-transfected cells showed more marked inhibition of BrdU incorporation after low fluences of UVR than control cells. Differences between denV-transfected and control cells in cell-cycle kinetics following UVR exposure may be related to differences in mechanisms of repair when excision repair of pyrimidine dimers is initiated by endonuclease V instead of cellular repair enzymes.

X-ray structure of T4 endonuclease V: an excision repair enzyme specific for a pyrimidine dimer

The x-ray structure of T4 endonuclease V, an enzyme responsible for the first step of a pyrimidine-dimer-specific excision-repair pathway, was determined at a 1.6-angstrom resolution. The enzyme consists of a single compact domain classified into an all-alpha structure. This single domain has two distinct catalytic activities; it functions as a pyrimidine dimer glycosylase and as an apurinic-apyrimidinic endonuclease. The amino-terminal segment penetrates between two major helices and prevents their direct contact. The refined structure suggests the residues involved in the substrate binding and the catalysis of the glycosylation reaction.

A eukaryotic DNA glycosylase/lyase recognizing ultraviolet light-induced pyrimidine dimers

Cyclobutane pyrimidine dimers (CPDs) are the predominant product of photodamage in DNA after exposure of cells to ultraviolet light and are cytotoxic, mutagenic and carcinogenic in a variety of cellular and animal systems. In prokaryotes, enzymes and protein complexes have been characterized that remove or reverse CPDs in DNA. Micrococcus luteus and T4 phage-infected Escherichia coli contain a specific N-glycosylase/apurinic-apyrimidinic lyase that catalyses a two-step DNA incision process at sites of CPDs, thus initiating base excision repair of these lesions. It is well established that CPDs are recognized and removed from eukaryotic DNA by excision repair processes but very little information exists concerning the nature of the proteins involved in CPD recognition and DNA incision events. We report here that an enzyme functionally similar to the prokaryotic N-glycosylase/apurinic-apyrimidinic lyases exists in Saccharomyces cerevisiae. To our knowledge, this is the first time such an activity has been found in a eukaryote and is also the first example of an organism having both direct reversal and base excision repair pathways for the removal of CPDs from DNA.

DNA containing a chemically reduced apurinic site is a high affinity ligand for the E. coli formamidopyrimidine-DNA glycosylase

The E. coli Formamidopyrimidine-DNA Glycosylase (FPG protein), a monomeric DNA repair enzyme of 30.2 kDa, was purified to homogeneity in large quantities. The FPG protein excises imidazole ring-opened purines and 8-hydroxyguanine residues from DNA. Besides DNA glycosylase activity, the FPG protein is endowed with an EDTA-resistant activity which nicks DNA at apurinic/apyrimidic sites (AP sites). In contrast, DNAs containing chemically reduced AP sites are not incised by the FPG protein. However, the DNA glycosylase activity of the FPG protein is strongly inhibited in the presence of a purified synthetic 24 base-pair double-stranded oligonucleotide which contains a single apurinic site transformed chemically through borohydride reduction into a ring-opened deoxyribose derivative. The ability of the FPG protein to form a complex with this synthetically modified DNA was studied by electrophoresis in non-denaturing polyacrylamide gels. The FPG protein specifically binds the double-stranded oligonucleotide containing an apurinic site previously reduced in the presence of sodium borohydride. The complex was identified as a single retardation band on non-denaturing polyacrylamide gel electrophoresis. Complex formation is reversible and an apparent dissociation constant, KDapp, of 2.6 x 10(-10) M was determined. In contrast, no such retardation band was obtained between the FPG protein and double-stranded DNA containing an intact apurinic site or single-stranded DNA containing either an intact or a reduced apurinic site.

Mutations in endonuclease V that affect both protein-protein association and target site location

A general mechanism by which proteins locate their target sites within large domains of DNA is a one-dimensional facilitated diffusion process in which the protein scans DNA in a nonspecifically bound state. An electrostatic contribution to this type of mechanism has been previously established. This study was designed to question whether other characteristics of a protein's structure might contribute to the scanning mechanism of target site location. In this regard, T4 endonuclease V was shown to establish an ionic strength dependent monomer-dimer equilibrium in solution. A protein dimer interaction site was postulated to exist along a putative alpha-helix containing amino acid residues 54-62. The conservative substitutions of Phe-60----Leu-60 and Phe-59, Phe-60----Leu-59, Leu-60 resulted in mutant enzymes which remained in the monomeric state independent of the ionic strength of the solution. The target site location mechanism of these mutants has also been altered. Under conditions where wild-type endonuclease V processively scans nontarget DNA, the target location mechanism of the monomeric mutant proteins was shifted toward a less processive search. This decrease in the processivity of the mutants was especially surprising because the nontarget DNA binding affinity was found to be significantly increased. Thus, an additional component of the endonuclease V DNA scanning mechanism appears to be the formation of a stable endonuclease V dimer complex.

Site-directed deletion mutagenesis within the T4 endonuclease V gene: dispensable sequences within putative loop regions

Endonuclease V from bacteriophage T4 may be one of the first DNA-repair enzymes to have its three-dimensional structure determined by X-ray crystallography (Morikawa et al., 1988). However, since this structure is not yet available, analyses of the sequence of the protein were performed in order to guide site-directed mutational studies of enzyme structure-function relationships. The enzyme is predominantly alpha-helical, so that an algorithm which finds the locations of turns or loops in the structure would be expected to approximately locate the helices along the sequence. Two loop sites were identified which might be adjacent in the tertiary structure according to a model developed from the loop predictions and the derived secondary structure. Deletion of three residues at each loop site produced protein molecules which retained considerable in vitro enzyme activity and in vivo repair function. However, the mutant proteins did not accumulate as well within the cell as the wild-type enzyme, suggesting that the nascent molecules folded inefficiently. Combination of the two deletions yielded a molecule with activity enhanced over one of the individual mutants, a result which can be interpreted as a classic second-site mutational reversion. This result supports the hypothesis that these regions are adjacent in the enzyme tertiary structure.