T4 endonuclease V protects the DNA strand opposite a thymine dimer from cleavage by the footprinting reagents DNase I and 1,10-phenanthroline-copper

Understanding Active Photoprotection: DNA-Repair Enzymes and Antioxidants

The detrimental effects of ultraviolet radiation (UVR) on human skin are well-documented, encompassing DNA damage, oxidative stress, and an increased risk of carcinogenesis. Conventional photoprotective measures predominantly rely on filters, which scatter or absorb UV radiation, yet fail to address the cellular damage incurred post-exposure. To fill this gap, antioxidant molecules and DNA-repair enzymes have been extensively researched, offering a paradigm shift towards active photoprotection capable of both preventing and reversing UV-induced damage. In the current review, we focused on "active photoprotection", assessing the state-of-the-art, latest advancements and scientific data from clinical trials and in vivo models concerning the use of DNA-repair enzymes and naturally occurring antioxidant molecules.

Sequencing for oxidative DNA damage at single-nucleotide resolution with click-code-seq v2.0

Oxidative damage to DNA nucleotides has many cellular outcomes that could be aided by the development of sequencing methods. Herein, the previously reported click-code-seq method for sequencing a single damage type is redeveloped to enable the sequencing of many damage types by making simple changes to the protocol (i.e., click-code-seq v2.0).

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.

DNA repair enzymes in sunscreens and their impact on photoageing-A systematic review

BACKGROUND

DNA damage is one of the main factors responsible for photoageing and is predominantly attributed to ultraviolet irradiation (UV-R). Photoprotection by conventional sunscreens is exclusively prophylactic, and of no value, once DNA damage has occurred. As a result, the demand for DNA repair mechanisms inhibiting, reversing or delaying the pathologic events in UV-exposed skin has sparked research on anti-photoageing and strategies to improve the effect of conventional sunscreens. This review provides an overview of recent developments in DNA repair enzymes used in sunscreens and their impact on photoageing.

METHODS

A systematic review of the literature, up to March 2019, was conducted using the electronic databases, PubMed and Web of Science. Quality assessment was carried out using the Newcastle-Ottawa scale (NOS) to ensure inclusion of adequate quality studies only (NOS > 5).

RESULTS

Out of the 352 publications, 52 were considered relevant to the key question and included in the present review. Two major enzymes were found to play a major role in DNA damage repair in sunscreens: photolyase and T4 endonuclease V. These enzymes are capable of identifying and removing UV-R-induced dimeric photoproducts. Clinical studies revealed that sunscreens with liposome-encapsulated types of photolyase and/or T4 endonuclease V can enhance these repair mechanisms.

CONCLUSION

There is a lack of randomized controlled trials demonstrating the efficacy of DNA repair enzymes on photoageing, or a superiority of sunscreens with DNA repair enzymes compared to conventional sunscreens. Further studies are mandatory to further reveal pathogenic factors of photoageing and possible therapeutic strategies against it.

The N-terminal Extensions of Deinococcus radiodurans Dps-1 Mediate DNA Major Groove Interactions as well as Assembly of the Dodecamer

Dps (DNA protection during starvation) proteins play an important role in the protection of prokaryotic macromolecules from damage by reactive oxygen species. Previous studies have suggested that the lysine-rich N-terminal tail of Dps proteins participates in DNA binding. In comparison with other Dps proteins, Dps-1 from Deinococcus radiodurans has an extended N terminus comprising 55 amino acids preceding the first helix of the 4-helix bundle monomer. In the crystal structure of Dps-1, the first approximately 30 N-terminal residues are invisible, and the remaining 25 residues form a loop that harbors a novel metal-binding site. We show here that deletion of the flexible N-terminal tail obliterates DNA/Dps-1 interaction. Surprisingly, deletion of the entire N terminus also abolishes dodecameric assembly of the protein. Retention of the N-terminal metal site is necessary for formation of the dodecamer, and metal binding at this site facilitates oligomerization of the protein. Electrophoretic mobility shift assays using DNA modified with specific major/minor groove reagents further show that Dps-1 interacts through the DNA major groove. DNA cyclization assays suggest that dodecameric Dps-1 does not wrap DNA about itself. A significant decrease in DNA binding affinity accompanies a reduction in duplex length from 22 to 18 bp, but only for dodecameric Dps-1. Our data further suggest that high affinity DNA binding depends on occupancy of the N-terminal metal site. Taken together, the mode of DNA interaction by dodecameric Dps-1 suggests interaction of two metal-anchored N-terminal tails in successive DNA major grooves, leading to DNA compaction by formation of stacked protein-DNA layers.

Repair of DNA-polypeptide crosslinks by human excision nuclease

DNA-protein crosslinks are relatively common DNA lesions that form during the physiological processing of DNA by replication and recombination proteins, by side reactions of base excision repair enzymes, and by cellular exposure to bifunctional DNA-damaging agents such as platinum compounds. The mechanism by which pathological DNA-protein crosslinks are repaired in humans is not known. In this study, we investigated the mechanism of recognition and repair of protein-DNA and oligopeptide-DNA crosslinks by the human excision nuclease. Under our assay conditions, the human nucleotide excision repair system did not remove a 16-kDa protein crosslinked to DNA at a detectable level. However, 4- and 12-aa-long oligopeptides crosslinked to the DNA backbone were recognized by some of the damage recognition factors of the human excision nuclease with moderate selectivity and were excised from DNA at relatively efficient rates. Our data suggest that, if coupled with proteolytic degradation of the crosslinked protein, the human excision nuclease may be the major enzyme system for eliminating protein-DNA crosslinks from the genome.

Initiation of Repair of DNA−Polypeptide Cross-Links by the UvrABC Nuclease†

Although the biochemical pathways that repair DNA-protein cross-links have not been clearly elucidated, it has been proposed that the partial proteolysis of cross-linked proteins into smaller oligopeptides constitutes an initial step in removal of these lesions by nucleotide excision repair (NER). To test the validity of this repair model, several site-specific DNA-peptide and DNA-protein cross-links were engineered via linkage at (1) an acrolein-derived gamma-hydroxypropanodeoxyguanosine adduct and (2) an apurinic/apyrimidinic site, and the initiation of repair was examined in vitro using recombinant proteins UvrA and UvrB from Bacillus caldotenax and UvrC from Thermotoga maritima. The polypeptides cross-linked to DNA were Lys-Trp-Lys-Lys, Lys-Phe-His-Glu-Lys-His-His-Ser-His-Arg-Gly-Tyr, and the 16 kDa protein, T4 pyrimidine dimer glycosylase/apurinic/apyrimidinic site lyase. For the substrates examined, DNA incision required the coordinated action of all three proteins and occurred at the eighth phosphodiester bond 5' to the lesion. The incision rates for DNA-peptide cross-links were comparable to or greater than that measured on fluorescein-adducted DNA, an excellent substrate for UvrABC. Incision rates were dependent on both the site of covalent attachment on the DNA and the size of the bound peptide. Importantly, incision of a DNA-protein cross-link occurred at a rate approximately 3.5-8-fold slower than the rates observed for DNA-peptide cross-links. Thus, direct evidence has been obtained indicating that (1) DNA-peptide cross-links can be efficiently incised by the NER proteins and (2) DNA-peptide cross-links are preferable substrates for this system relative to DNA-protein cross-links. These data suggest that proteolytic degradation of DNA-protein cross-links may be an important processing step in facilitating NER.

Bacteriophage T4 genome

Phage T4 has provided countless contributions to the paradigms of genetics and biochemistry. Its complete genome sequence of 168,903 bp encodes about 300 gene products. T4 biology and its genomic sequence provide the best-understood model for modern functional genomics and proteomics. Variations on gene expression, including overlapping genes, internal translation initiation, spliced genes, translational bypassing, and RNA processing, alert us to the caveats of purely computational methods. The T4 transcriptional pattern reflects its dependence on the host RNA polymerase and the use of phage-encoded proteins that sequentially modify RNA polymerase; transcriptional activator proteins, a phage sigma factor, anti-sigma, and sigma decoy proteins also act to specify early, middle, and late promoter recognition. Posttranscriptional controls by T4 provide excellent systems for the study of RNA-dependent processes, particularly at the structural level. The redundancy of DNA replication and recombination systems of T4 reveals how phage and other genomes are stably replicated and repaired in different environments, providing insight into genome evolution and adaptations to new hosts and growth environments. Moreover, genomic sequence analysis has provided new insights into tail fiber variation, lysis, gene duplications, and membrane localization of proteins, while high-resolution structural determination of the "cell-puncturing device," combined with the three-dimensional image reconstruction of the baseplate, has revealed the mechanism of penetration during infection. Despite these advances, nearly 130 potential T4 genes remain uncharacterized. Current phage-sequencing initiatives are now revealing the similarities and differences among members of the T4 family, including those that infect bacteria other than Escherichia coli. T4 functional genomics will aid in the interpretation of these newly sequenced T4-related genomes and in broadening our understanding of the complex evolution and ecology of phages-the most abundant and among the most ancient biological entities on Earth.

Incision of DNA-protein crosslinks by UvrABC nuclease suggests a potential repair pathway involving nucleotide excision repair

DNA-protein crosslinks (DPCs) arise in biological systems as a result of exposure to a variety of chemical and physical agents, many of which are known or suspected carcinogens. The biochemical pathways for the recognition and repair of these lesions are not well understood in part because of methodological difficulties in creating site-specific DPCs. Here, a strategy for obtaining site-specific DPCs is presented, and in vitro interactions of the Escherichia coli nucleotide excision repair (NER) UvrABC nuclease at sites of DPCs are investigated. To create site-specific DPCs, the catalytic chemistry of the T4 pyrimidine dimer glycosylase/apurinic/apyrimidinic site lyase (T4-pdg) has been exploited, namely, its ability to be covalently trapped to apurinic/apyrimidinic sites within duplex DNA under reducing conditions. Incubation of the DPCs with UvrABC proteins resulted in DNA incision at the 8th phosphate 5' and the 5th and 6th phosphates 3' to the protein-adducted site, generating as a major product of the reaction a 12-mer DNA fragment crosslinked with the protein. The incision occurred only in the presence of all three protein subunits, and no incisions were observed in the nondamaged complementary strand. The UvrABC nuclease incises DPCs with a moderate efficiency. The proper assembly and catalytic function of the NER complex on DNA containing a covalently attached 16-kDa protein suggest that the NER pathway may be involved in DPC repair and that at least some subset of DPCs can be removed by this mechanism without prior proteolytic degradation.

Mechanistic link between DNA methyltransferases and DNA repair enzymes by base flipping

Rotation of a DNA nucleotide out of the double helix and into a protein binding pocket ("base flipping") was first observed in the structure of a DNA methyltransferase. There is now evidence that a variety of proteins, particularly DNA repair enzymes, use base flipping in their interactions with DNA. Though the mechanisms for base movement into extrahelical positions are still unclear, the focus of this review is how base recognition is modulated by the stringency of binding to the extrahelical base(s) or sugar moiety.

Methanobacterium thermoformicicum thymine DNA mismatch glycosylase: conversion of an N-glycosylase to an AP lyase

The thymine DNA mismatch glycosylase from Methanobacterium thermoformicicum, a member of the endonuclease III family of repair proteins, excises the pyrimidine base from T-G and U-G mismatches. Unlike endonuclease III, it does not cleave the phosphodiester backbone by a beta-elimination reaction. This cleavage event has been attributed to a nucleophilic attack by the conserved Lys120 of endonuclease III on the aldehyde group at C1' of the deoxyribose and subsequent Schiff base formation. The inability of TDG to perform this beta-elimination event appears to be due to the presence of a tyrosine residue at the position equivalent to Lys120 in endonuclease III. The purpose of this work was to investigate the requirements for AP lyase activity. We replaced Tyr126 in TDG with a lysine residue to determine if this replacement would yield an enzyme with an associated AP lyase activity capable of removing a mismatched pyrimidine. We observed that this replacement abolishes the glycosylase activity of TDG but does not affect substrate recognition. It does, however, convert the enzyme into an AP lyase. Chemical trapping assays show that this cleavage proceeds through a Schiff base intermediate and suggest that the amino acid at position 126 interacts with C1' on the deoxyribose sugar.

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.

Specific interaction of wild-type and truncated mouse N-methylpurine-DNA glycosylase with ethenoadenine-containing DNA

N-Methylpurine-DNA glycosylase (MPG), a ubiquitous DNA repair enzyme, is responsible for the removal of a wide variety of alkylated base lesions in DNA, e.g., N-alkylpurines and cyclic ethenoadducts of adenine, guanine, and cytosine. These lesions, some of which are mutagenic and toxic, are generated endogenously or by genotoxic agents such as N-alkylnitrosamines and vinyl chloride. Wild-type mouse MPG, expressed from recombinant baculovirus, was purified to near homogeneity for studying its specific interaction with substrate, 1,N6-ethenoadenine- (epsilonA-) containing DNA. Electrophoretic mobility shift assays (EMSA) indicated that MPG formed a specific complex with a 50-mer epsilonA-containing duplex oligonucleotide. This complex was shown to be a transient reaction intermediate, because it could be formed only with the unreacted substrate and contained active enzyme molecules. DNA footprinting studies confirmed the specific binding of the protein to the epsilonA-containing duplex oligonucleotide; eight nucleotides on the epsilonA-containing strand and 16-17 nucleotides in the complementary strand spanning the base adduct were protected from DNase I digestion. A systematic deletion analysis of MPG was carried out in order to determine the minimally sized polypeptide capable of forming a stable substrate complex that is also suitable for characterization by NMR spectroscopy and X-ray crystallography. A truncated polypeptide (NDelta100CDelta18) lacking 100 and 18 amino acid residues from the amino and carboxyl termini, respectively, was found to be the minimal size that retained activity. The truncated and wild-type enzymes have similar kinetic properties. Moreover, both EMSA and DNase I footprinting studies indicated identical pattern of specific binding by the truncated and full-length polypeptides. Removal of five and nine additional residues from the amino- and carboxyl-termini of this polypeptide, respectively, resulted in a complete loss of activity. These results suggest that minimal structural change occured as a result of truncation in the NDelta100CDelta18 mutant, which may thus be suitable for elucidating the structure and mechanism of MPG.

Role of specific amino acid residues in T4 endonuclease V that alter nontarget DNA binding

Endonuclease V is a pyrimidine dimer-specific DNA glycosylase-apurinic (AP)1 lyase which, in vivo or at low salt concentrations in vitro, binds nontarget DNA through electrostatic interactions and remains associated with that DNA until all dimers have been recognized and incised. On the basis of the analyses of previous mutants that effect this processive nicking activity, and the recently published cocrystal structure of a catalytically deficient endonuclease V with pyrimidine dimer-containing DNA [Vassylyev, D. G., et al. (1995) Cell 83, 773-782], four site-directed mutations were created, the mutant enzymes expressed in repair-deficient Escherichia coli, and the enzymes purified to homogeneity. Steady-state kinetic analyses revealed that one of the mutants, Q15R, maintained an efficiency (k(cat)/Km) near that of the wild-type enzyme, while R117N and K86N had a 5-10-fold reduction in efficiency and K121N was reduced almost 100-fold. In addition, K121N and K86N exhibited a 3-5-fold increase in Km, respectively. All the mutants experienced mild to severe reduction in catalytic activity (k(cat)), with K121N being the most severely affected (35-fold reduction). Two of the mutants, K86N and K121N, showed dramatic effects in their ability to scan nontarget DNA and processively incise at pyrimidine dimers in UV-irradiated DNA. These enzymes (K86N and K121N) appeared to utilize a distributive, three-dimensional search mechanism even at low salt concentrations. Q15R and R117N displayed somewhat diminished processive nicking activities relative to that of the wild-type enzyme. These results, combined with previous analyses of other mutant enzymes and the cocrystal structure, provide a detailed architecture of endonuclease V-nontarget DNA interactions.

T4 endonuclease V exists in solution as a monomer and binds to target sites as a monomer

Endonuclease V, a N-glycosylase/lyase from T4 bacteriophage that initiates the repair of cyclobutane pyrimidine dimers in DNA, has been reported to form a monomer-dimer equilibrium in solution [Nickell and Lloyd (1991) Biochemistry 30, 8638], although the enzyme has only been crystallized in the absence of substrate as a monomer [Morikawa et al. (1992) Science 256, 523]. In this study, analytical gel filtration and sedimentation equilibrium techniques were used to rigorously characterize the association state of the enzyme in solution. In contrast to the previous report, at 100 mM KCl endonuclease V was found to exist predominantly as a monomer in solution by both of these techniques; no evidence for dimerization was seen. To characterize the oligomeric state of the enzyme at its target sites on DNA, the enzyme was bound to oligonucleotides containing a single site specific pyrimidine dimer or tetrahydrofuran residue. These complexes were analyzed by nondenaturing gel electrophoresis at various acrylamide concentrations in order to determine the molecular weights of the enzyme-DNA complexes. The results from these experiments demonstrate that endonuclease V binds to cyclobutane pyrimidine dimer and tetrahydrofuran site containing DNA as a monomer.

The interaction of T4 endonuclease V E23Q mutant with thymine dimer- and tetrahydrofuran-containing DNA

The interaction between endonuclease V, the cyclobutane pyrimidine dimer-specific N-glycosylase/abasic lyase from bacteriophage T4, and DNA was investigated by DNase I footprinting methods. The catalytically inactive mutant E23Q was found to interact with a smaller region of DNA at the abasic site analog, tetrahydrofuran, than at a thymine dimer site. Like the wild-type enzyme, the mutant contacted the DNA substrates primarily on the strand opposite the damage. The various complexes examined by footprinting techniques represent distinct points along the catalytic pathway of endonuclease V: before catalysis at a dimer, after N-glycosylase action but before abasic lyase action, and before catalysis at an abasic site. The differences between the footprints of the mutant and wild-type enzymes on both DNA substrates likely represent subtly different conformations within these complexes.

Studies on the catalytic mechanism of five DNA glycosylases. Probing for enzyme-DNA imino intermediates

DNA glycosylases catalyze scission of the N-glycosylic bond linking a damaged base to the DNA sugar phosphate backbone. Some of these enzymes carry out a concomitant abasic (apyrimidinic/apurinic(AP)) lyase reaction at a rate approximately equal to that of the glycosylase step. As a generalization of the mechanism described for T4 endonuclease V, a repair glycosylase/AP lyase that is specific for ultraviolet light-induced cis-syn pyrimidine dimers, a hypothesis concerning the mechanism of these repair glycosylases has been proposed. This hypothesis describes the initial action of all DNA glycosylases as a nucleophilic attack at the sugar C-1' of the damaged base nucleoside, resulting in scission of the N-glycosylic bond. It is proposed that the enzymes that are only glycosylases differ in the chemical nature of the attacking nucleophile from the glycosylase/AP lyases. Those DNA glycosylases, which carry out the AP lyase reaction at a rate approximately equal to the glycosylase step, are proposed to use an amino group as the nucleophile, resulting in an imino enzyme-DNA intermediate. The simple glycosylases, lacking the concomitant AP lyase activity, are propose to use some nucleophile from the medium, e.g. an activated water molecule. This paper reports experimental tests of this hypothesis using five representative enzymes, and these data are consistent with this hypothesis.