The mechanism of DNA repair by uracil-DNA glycosylase: studies using nucleotide analogues

2',4'-Dideoxy-4'-methyleneuridine incorporated into oligodeoxynucleotides forms regular B-DNA duplexes as shown by Tm and CD measurements. Such oligomers are not cleaved by the DNA repair enzyme, UDG, which cleaves the glycosylic bond in dU but not in dT nor in dC nucleosides in single stranded and double stranded DNA. Differential binding of oligomers containing carbadU, 4'-thiodU, and dU residues to wild type and mutant UDG proteins identify an essential role for the furanose 4'-oxygen in recognition and cleavage of dU residues in DNA.     

Mutations at Arginine 276 transform human uracil-DNA glycosylase into a single-stranded DNA-specific uracil-DNA glycosylase

To investigate the role of Arginine 276 in the conserved leucine-loop of human uracil-DNA glycosylase (UNG), the effects of six R276 amino acid substitutions (C, E, H, L, W, and Y) on nucleotide flipping and enzyme conformational change were determined using transient and steady state, fluorescence-based, kinetic analysis. Relative to UNG, the mutant proteins exhibited a 2.6- to 7.7-fold reduction in affinity for a doubled-stranded oligonucleotide containing a pseudouracil residue opposite 2-aminopurine, as judged by steady-state DNA binding-base flipping assays. An anisotropy binding assay was utilized to determine the K(d) of UNG and the R276 mutants for carboxyfluorescein-labeled uracil-containing single- and double-stranded oligonucleotides; the binding affinities varied 11-fold for single-stranded uracil-DNA, and 43-fold for double-stranded uracil-DNA. Productive uracil-DNA binding was monitored by rapid quenching of UNG intrinsic protein fluorescence. Relative to UNG, the rate of intrinsic fluorescence quenching of five mutant proteins for binding double-stranded uracil-DNA was reduced approximately 50%; the R276E mutant exhibited 1% of the rate of fluorescence quenching of UNG. When reacted with single-stranded uracil-DNA, the rate of UNG fluorescence quenching increased. Moreover, the rate of fluorescence quenching for all the mutant proteins, except R276E, was slightly faster than UNG. The k(cat) of the R276 mutants was comparable to UNG on single-stranded DNA and differentially affected by NaCl; however, k(cat) on double-stranded DNA substrate was reduced 4-12-fold and decreased sharply at NaCl concentrations as low as 20 mM. Taken together, these results indicate that the effects of mutations at Arg276 were largely limited to enzyme interactions with double-stranded uracil-containing DNA, and suggested that mutations at Arg276 effectively transformed UNG into a single-stranded DNA-specific uracil-DNA glycosylase.     

Base-flipping mutations of uracil DNA glycosylase: substrate rescue using a pyrene nucleotide wedge

We recently introduced a new substrate rescue tool for investigating enzymatic base flipping by uracil DNA glycosylase (UDG) in which a bulky pyrene nucleotide wedge (Y) was placed opposite a uracil in duplex DNA (i.e., a U/Y pair), thereby preorganizing the target base in an extrahelical conformation [Jiang, Y. L., et al. (2001) J. Biol. Chem. 276, 42347-54]. The pyrene wedge completely rescued the large catalytic defects resulting from removal of the natural Leu191 wedge, presumably mimicking the pushing and plugging function of this group. Here we employ the pyrene rescue method in combination with transient kinetic approaches to assess the functional roles of six conserved enzymatic groups of UDG that have been implicated in the "pinch, push, plug, and pull" base-flipping mechanism (see the preceding paper in this issue). We find that a U/Y base pair increases the apparent second-order rate constant for damaged site recognition by L191G pushing mutation by 45-fold as compared to a U/A pair, thereby fully rescuing the kinetic effects of the mutation. Remarkably, the U/Y pair also allows L191G to proceed through the conformational docking step that is severely comprised with the normal U/A substrate, and allows the active site of UDG to clamp around the extrahelical base. Thus, pyrene also fulfills the plugging role of the Leu191 side chain. Preorganization of uracil in an extrahelical conformation by pyrene allows diffusion-controlled damage recognition by all of these base-flipping mutants, and allows the UDG conformational change to proceed as rapidly as the rate of uracil flipping with the natural U/A base pair. Thus, the pyrene wedge substrate allows UDG to recognize uracil by a lock-and-key mechanism, rather than the natural induced-fit mechanism. Unnatural pyrene base pairs may provide a general strategy to promote site-specific targeting of other enzymes that recognize extrahelical bases.     

Identification of a new uracil-DNA glycosylase family by expression cloning using synthetic inhibitors

BACKGROUND: The cellular environment exposes DNA to a wide variety of endogenous and exogenous reactive species that can damage DNA, thereby leading to genetic mutations. DNA glycosylases protect the integrity of the genome by catalyzing the first step in the base excision-repair of lesions in DNA. RESULTS: Here, we report a strategy to conduct genome-wide screening for expressed DNA glycosylases, based on their ability to bind to a library of four synthetic inhibitors that target the enzyme's active site. These inhibitors, used in conjunction with the in vitro expression cloning procedure, led to the identification of novel Xenopus and human proteins, xSMUG1 and hSMUG1, respectively, that efficiently excise uracil residues from DNA. Despite a lack of statistically significant overall sequence similarity to the two established classes of uracil-DNA glycosylases, the SMUG1 enzymes contain motifs that are hallmarks of a shared active-site structure and overall protein architecture. The unusual preference of SMUG1 for single-stranded rather than double-stranded DNA suggests a unique biological function in ridding the genome of uracil residues, which are potent endogenous mutagens. CONCLUSIONS: The 'proteomics' approach described here has led to the isolation of a new family of uracil-DNA glycosylases. The three classes of uracil-excising enzymes (SMUG1 being the most recently discovered) represent a striking example of structural and functional conservation in the almost complete absence of sequence conservation.     

Phylogenomic analysis of the uracil-DNA glycosylase superfamily

The spontaneous deamination of cytosine produces uracil mispaired with guanine in DNA, which will produce a mutation, unless repaired. In all domains of life, uracil-DNA glycosylases (UDGs) are responsible for the elimination of uracil from DNA. Thus, UDGs contribute to the integrity of the genetic information and their loss results in mutator phenotypes. We are interested in understanding the role of UDG genes in the evolutionary variation of the rate and the spectrum of spontaneous mutations. To this end, we determined the presence or absence of the five main UDG families in more than 1,000 completely sequenced genomes and analyzed their patterns of gene loss and gain in eubacterial lineages. We observe nonindependent patterns of gene loss and gain between UDG families in Eubacteria, suggesting extensive functional overlap in an evolutionary timescale. Given that UDGs prevent transitions at G:C sites, we expected the loss of UDG genes to bias the mutational spectrum toward a lower equilibrium G + C content. To test this hypothesis, we used phylogenetically independent contrasts to compare the G + C content at intergenic and 4-fold redundant sites between lineages where UDG genes have been lost and their sister clades. None of the main UDG families present in Eubacteria was associated with a higher G + C content at intergenic or 4-fold redundant sites. We discuss the reasons of this negative result and report several features of the evolution of the UDG superfamily with implications for their functional study. uracil-DNA glycosylase, mutation rate evolution, mutational bias, GC content, DNA repair, mutator gene.     

Suppression of uracil-DNA glycosylase induces neuronal apoptosis

A chronic imbalance in DNA precursors, caused by one-carbon metabolism impairment, can result in a deficiency of DNA repair and increased DNA damage. Although indirect evidence suggests that DNA damage plays a role in neuronal apoptosis and in the pathogenesis of neurodegenerative disorders, the underlying mechanisms are poorly understood. In particular, very little is known about the role of base excision repair of misincorporated uracil in neuronal survival. To test the hypothesis that repair of DNA damage associated with uracil misincorporation is critical for neuronal survival, we employed an antisense (AS) oligonucleotide directed against uracil-DNA glycosylase encoded by the UNG gene to deplete UNG in cultured rat hippocampal neurons. AS, but not a scrambled control oligonucleotide, induced apoptosis, which was associated with DNA damage analyzed by comet assay and up-regulation of p53. UNG mRNA and protein levels were decreased within 30 min and were undetectable within 6-9 h of exposure to the UNG AS oligonucleotide. Whereas UNG expression is significantly higher in proliferating as compared with nonproliferating cells, such as neurons, the levels of UNG mRNA were increased in brains of cystathionine beta-synthase knockout mice, a model for hyperhomocysteinemia, suggesting that one-carbon metabolism impairment and uracil misincorporation can induce the up-regulation of UNG expression.     

Multiple uracil-DNA glycosylase activities in Deinococcus radiodurans

The extremely radiation resistant bacterium, Deinococcus radiodurans, contains a spectrum of genes that encode for multiple activities that repair DNA damage. We have cloned and expressed the product of three predicted uracil-DNA glycosylases to determine their biochemical function. DR0689 is a homologue of the Escherichia coli uracil-DNA glycosylase, the product of the ung gene; this activity is able to remove uracil from a U : G and U : A base pair in double-stranded DNA and uracil from single-stranded DNA and is inhibited by the Ugi peptide. DR1751 is a member of the class 4 family of uracil-DNA glycosylases such as those found in the thermophiles Thermotoga maritima and Archaeoglobus fulgidus. DR1751 is also able to remove uracil from a U : G and U : A base pair; however, it is considerably more active on single-stranded DNA. Unlike its thermophilic relatives, the enzyme is not heat stable. Another putative enzyme, DR0022, did not demonstrate any appreciable uracil-DNA glycosylase activity. DR0689 appears to be the major activity in the organism based on inhibition studies with D. radiodurans crude cell extracts utilizing the Ugi peptide. The implications for D. radiodurans having multiple uracil-DNA glycosylase activities and other possible roles for these enzymes are discussed.     

Staphylococcus aureus protein SAUGI acts as a uracil-DNA glycosylase inhibitor

DNA mimic proteins are unique factors that control the DNA binding activity of target proteins by directly occupying their DNA binding sites. The extremely divergent amino acid sequences of the DNA mimics make these proteins hard to predict, and although they are likely to be ubiquitous, to date, only a few have been reported and functionally analyzed. Here we used a bioinformatic approach to look for potential DNA mimic proteins among previously reported protein structures. From ∼14 candidates, we selected the Staphylococcus conserved hypothetical protein SSP0047, and used proteomic and structural approaches to show that it is a novel DNA mimic protein. In Staphylococcus aureus, we found that this protein acts as a uracil-DNA glycosylase inhibitor, and therefore named it S. aureus uracil-DNA glycosylase inhibitor (SAUGI). We also determined and analyzed the complex structure of SAUGI and S. aureus uracil-DNA glycosylase (SAUDG). Subsequent BIAcore studies further showed that SAUGI has a high binding affinity to both S. aureus and human UDG. The two uracil-DNA glycosylase inhibitors (UGI and p56) previously known to science were both found in Bacillus phages, and this is the first report of a bacterial DNA mimic that may regulate SAUDG’s functional roles in DNA repair and host defense.     

Computational design of a thermolabile uracil-DNA glycosylase of Escherichia coli

Polymerase chain reaction (PCR) is a powerful tool to diagnose infectious diseases. Uracil DNA glycosylase (UDG) is broadly used to remove carryover contamination in PCR. However, UDG can contribute to false negative results when not inactivated completely, leading to DNA degradation during the amplification step. In this study, we designed novel thermolabile UDG derivatives by supercomputing molecular dynamic simulations and residual network analysis. Based on enzyme activity analysis, thermolability, thermal stability, and biochemical experiments of Escherichia coli-derived UDG and 22 derivatives, we uncovered that the UDG D43A mutant eliminated the false negative problem, demonstrated high efficiency, and offered great benefit for use in PCR diagnosis. We further obtained structural and thermodynamic insights into the role of the D43A mutation, including perturbed protein structure near D43; weakened pairwise interactions of D43 with K42, N46, and R80; and decreased melting temperature and native fraction of the UDG D43A mutant compared with wild-type UDG.     

A novel uracil-DNA glycosylase family related to the helix-hairpin-helix DNA glycosylase superfamily

Cytosine bases can be deaminated spontaneously to uracil, causing DNA damage. Uracil-DNA glycosylase (UDG), a ubiquitous uracil-excising enzyme found in bacteria and eukaryotes, is one of the enzymes that repair this kind of DNA damage. To date, no UDG-coding gene has been identified in Methanococcus jannaschii, although its entire genome was deciphered. Here, we have identified and characterized a novel UDG from M.jannaschii designated as MjUDG. It efficiently removed uracil from both single- and double-stranded DNA. MjUDG also catalyzes the excision of 8-oxoguanine from DNA. MjUDG has a helix–hairpin–helix motif and a [4Fe–4S]-binding cluster that is considered to be important for the DNA binding and catalytic activity. Although MjUDG shares these features with other structural families such as endonuclease III and mismatch-specific DNA glycosylase (MIG), unique conserved amino acids and substrate specificity distinguish MjUDG from other families. Also, a homologous member of MjUDG was identified in Aquifex aeolicus. We report that MjUDG belongs to a novel UDG family that has not been described to date.     

Normal uracil-DNA glycosylase activity in Bloom's syndrome cells

Cells from patients with Bloom's syndrome, a rare human disease with autosomal recessive mode of inheritance, exhibit cytological abnormalities involving DNA metabolism. Bloom's syndrome is characterized by a greatly increased cancer frequency which may reflect a specific defect in DNA repair and replication. Evidence has recently been presented of the existence in Bloom's syndrome of an abnormality of the DNA ligase involved in semiconservative DNA replication. Another abnormality, in the excision-repair pathway of Bloom's syndrome cells, is reportedly due to an aberrant immunological reactivity of the DNA-repair enzyme uracil-DNA glycosylase. In this investigation we show, however, that the catalytic activity of uracil-DNA glycosylase appears to be normal in Bloom's syndrome lymphoblastoid cells.     

Structure and function in the uracil-DNA glycosylase superfamily

Deamination of cytosine to uracil is one of the major pro-mutagenic events in DNA, causing G:C-->A:T transition mutations if not repaired before replication. Repair of uracil-DNA is achieved in a base-excision pathway initiated by a uracil-DNA glycosylase (UDG) enzyme of which four families have so far been identified. Family-1 enzymes are active against uracil in ssDNA and dsDNA, and recognise uracil explicitly in an extrahelical conformation via a combination of protein and bound-water interactions. Extrahelical recognition requires an efficient process of substrate location by 'base-sampling' probably by hopping or gliding along the DNA. Family-2 enzymes are mismatch specific and explicitly recognise the widowed guanine on the complementary strand rather than the extrahelical scissile pyrimidine. This allows a broader specificity so that some Family-2 enzymes can excise uracil and 3, N(4)-ethenocytosine from mismatches with guanine. Although structures are not yet available for Family-3 (SMUG) and Family-4 enzymes, sequence analysis suggests similar overall folds, and identifies common active site motifs but with a surprising lack of conservation of catalytic residues between members of the super-family.     

Lessons learned from structural results on uracil-DNA glycosylase

Uracil-DNA glycosylase (UDG) functions as a sentry guarding against uracil in DNA. UDG initiates DNA base excision repair (BER) by hydrolyzing the uracil base from the deoxyribose. As one of the best studied DNA glycosylases, a coherent and complete functional mechanism is emerging that combines structural and biochemical results. This functional mechanism addresses the detection of uracil bases within a vast excess of normal DNA, the features of the enzyme that drive catalysis, and coordination of UDG with later steps of BER while preventing the release of toxic intermediates. Many of the solutions that UDG has evolved to overcome the challenges of policing the genome are shared by other DNA glycosylases and DNA repair enzymes, and thus appear to be general.     

Uracil-DNA glycosylase inhibitor gene of bacteriophage PBS2 encodes a binding protein specific for uracil-DNA glycosylase

The uracil-DNA glycosylase inhibitor gene (ugi) of the Bacillus subtilis bacteriophage PBS2 has been subcloned to a 720-base pair DNA fragment contained in pZW2-0.7 and its nucleotide sequence determined. Using nucleotide deletion analysis, we have located the cloned ugi gene along with potential regulatory elements. A promoter-like region (-10 and -35 consensus sequences) similar to other B. subtilis genes and the Shine-Dalgarno sequence characteristic of Gram-positive bacteria were both identified upstream from the initiator AUG codon. A 17-nucleotide exact inverted repeat followed by runs of adenine and thymine residues was positioned almost immediately downstream of the ochre codon. The ugi gene product was identified on sodium dodecyl sulfate-polyacrylamide gels using Escherichia coli minicells containing pZW2-0.7 and by recovering uracil-DNA glycosylase inhibitor activity following electrophoresis. The ugi gene codes for an acidic polypeptide of 9,477 molecular weight (84 amino acids) whose electrophoretic mobility was greater than predicted for a protein of this size. The mode of inhibition did not appear to involve a catalytic process nor did it directly involve inhibitor-DNA interaction. Rather, the inhibitor protein was shown to bind physically to the E. coli uracil-DNA glycosylase, forming a 36,000 molecular weight complex. This complex seems to be reversible, since inhibitor activity was recovered after heat treatment of the complex. In addition, we demonstrated that the inhibitor protein is active against uracil-DNA glycosylases isolated from several diverse biological sources but inactive against E. coli deoxyuridine triphosphatase, DNA polymerase I, and DNA polymerase alpha, beta, and gamma.     

Substrate specificity of homogeneous monkeypox virus uracil-DNA glycosylase

Weak or nonexistent smallpox immunity in today's human population raises concerns about the possibility of natural or provoked genetic modifications leading to re-emergence of variola virus and other poxviruses. Thus, the development of new antiviral strategies aimed at poxvirus infections in humans is a high priority. The DNA repair protein uracil-DNA glycosylase (UNG) is one of the viral enzymes important for poxvirus pathogenesis. Consequently, the inhibition of UNG is a rational therapeutic strategy for infections with poxviruses. Monkeypox virus, which occurs naturally in Africa, can cause a smallpox-like disease in humans. Here, the monkeypox virus UNG (mpUNG) is characterized and compared to vaccinia virus UNG (vUNG) and human UNG (hUNG). The mpUNG protein excises uracil preferentially from single-stranded DNA. Furthermore, mpUNG prefers the U.G pair over the U.A pair and does not excise oxidized bases. Both mpUNG and vUNG viral proteins are strongly inhibited by physiological concentrations of NaCl and MgCl2. Although the two viral DNA repair enzymes have similar substrate specificities, the kcat/KM values of mpUNG are higher than those of vUNG. The mpUNG protein was strongly inhibited by 5-azauracil and to a lesser extent by 4(6)-aminouracil and 5-halogenated uracil analogues, whereas uracil had no effect. To develop antiviral drugs toward mpUNG, we also validated a repair assay using the molecular beacons containing multiple uracil residues. Potential targets and strategies for combating pathogenic orthopoxviruses, including smallpox, are discussed.     

Quantitative assays for uracil-DNA glycosylase of high sensitivity

We have developed a sensitive fluorometric assay using bisulfite deaminated (C----U), covalently-closed circular PM2 DNA as the substrate. We describe a reliable way to prepare this substrate without nicking the PM2 DNA. Methods, which depend on toluenization of the cells, are described for reproducibly and quantitatively assaying uracil-DNA glycosylase. The sensitivity is such that only 200 EL4 mouse thymoma cells or 30,000 Escherichia coli cells are needed for each point in a kinetic assay.     

Functional changes in a novel uracil-DNA glycosylase determined by mutational analyses

Uracil-DNA glycosylase (UDG) is a ubiquitous enzyme found in bacteria and eukaryotes, which removes uracil residues from DNA strands. Methanococcus jannaschii UDG (MjUDG), a novel monofunctional glycosylase, contains a helix-hairpin-helix (HhH) motif and a Gly/Pro rich loop (GPD region), which is important for catalytic activity; it shares these features with other glycosylases, such as endonuclease III. First, to examine the role of two conserved amino acid residues (Asp150 and Tyr152) in the HhH-GPD region of MjUDG, mutant MjUDG proteins were constructed, in which Asp150 was replaced with either Glu or Trp (D150E and D150W), and Tyr152 was replaced with either Glu or Asn (Y152E and Y152N). Mutant D150W completely lacked DNA glycosylase activity, whereas D150E displayed reduced activity of about 70% of the wild type value. However, the mutants Y152E and Y152N retained unchanged levels of UDG activity. We also replaced Glu132 in the HhH motif with a lysine residue equivalent to Lys120 in endonuclease III. This mutation converted the enzyme into a bifunctional glycosylase/AP lyase capable of both removing uracil at a glycosylic bond and cleaving the phosphodiester backbone at an AP site. Mutant E132K catalyzes a β-elimination reaction at the AP site via uracil excision and forms a Schiff base intermediate in the form of a protein-DNA complex. This text was submitted by the authors in English.     

Protein mimicry of DNA from crystal structures of the uracil-DNA glycosylase inhibitor protein and its complex with Escherichia coli uracil-DNA glycosylase

Uracil-DNA glycosylase (UDG), which is a critical enzyme in DNA base-excision repair that recognizes and removes uracil from DNA, is specifically and irreversably inhibited by the thermostable uracil-DNA glycosylase inhibitor protein (Ugi). A paradox for the highly specific Ugi inhibition of UDG is how Ugi can successfully mimic DNA backbone interactions for UDG without resulting in significant cross-reactivity with numerous other enzymes that possess DNA backbone binding affinity. High-resolution X-ray crystal structures of Ugi both free and in complex with wild-type and the functionally defective His187Asp mutant Escherichia coli UDGs reveal the detailed molecular basis for duplex DNA backbone mimicry by Ugi. The overall shape and charge distribution of Ugi most closely resembles a midpoint in a trajectory between B-form DNA and the kinked DNA observed in UDG:DNA product complexes. Thus, Ugi targets the mechanism of uracil flipping by UDG and appears to be a transition-state mimic for UDG-flipping of uracil nucleotides from DNA. Essentially all the exquisite shape, electrostatic and hydrophobic complementarity for the high-affinity UDG-Ugi interaction is pre-existing, except for a key flip of the Ugi Gln19 carbonyl group and Glu20 side-chain, which is triggered by the formation of the complex. Conformational changes between unbound Ugi and Ugi complexed with UDG involve the beta-zipper structural motif, which we have named for the reversible pairing observed between intramolecular beta-strands. A similar beta-zipper is observed in the conversion between the open and closed forms of UDG. The combination of extremely high levels of pre-existing structural complementarity to DNA binding features specific to UDG with key local conformational changes in Ugi resolves the UDG-Ugi paradox and suggests a potentially general structural solution to the formation of very high affinity DNA enzyme-inhibitor complexes that avoid cross- reactivity.