Contrasting effects of mutating active site residues, aspartic acid 64 and histidine 187 of Escherichia coli uracil-DNA glycosylase on uracil excision and interaction with an inhibitor protein

Uracil, a promutagenic base, arises in DNA by spontaneous deamination of cytosine or by the malfunctioning of DNA polymerases. To maintain the genomic integrity, cells possess a highly conserved base excision repair enzyme, uracil-DNA glycosylase (UDG). UDGs have a notably high turnover number and strict specificity for uracil in DNA. UDGs are inhibited by a small proteinaceous inhibitor, Ugi, which acts as a transition state substrate mimic. Crystal structure studies have identified the residues crucial in catalysis, and in their interaction with Ugi. Here, we report on the mutational analyses of D64 (D64H and D64N) and H187 (H187C, H187L and H187R) in the active site pocket of Escherichia coli UDG. The mutants were compromised in uracil excision by approximately 200-25,000 fold when compared to the native protein. In contrast, our analysis of the in vivo formed UDG-Ugi complexes on urea gels shows that D64 and H187 contribute minimally to the interaction of the two proteins. Thus, our findings provide further evidence to the primary function of D64 and H187 in catalysis.     

Mutational analysis of the uracil DNA glycosylase inhibitor protein and its interaction with Escherichia coli uracil DNA glycosylase

Uracil DNA glycosylase inhibitor (Ugi), a protein of 9.4 kDa consists of a five-stranded antiparallel beta sheet flanked on either side by single alpha helices, forms an exclusive complex with uracil DNA glycosylases (UDGs) that is stable in 8M urea. We report on the mutational analysis of various structural elements in Ugi, two of which (hydrophobic pocket and the beta1 edge) establish key interactions with Escherichia coli UDG. The point mutations in helix alpha1 (amino acid residues 3-14) do not affect the stability of the UDG-Ugi complexes in urea. And, while the complex of the deltaN13 mutant with UDG is stable in only approximately 4M urea, its overall structure and thermostability are maintained. The identity of P37, stacked between P26 and W68, was not important for the maintenance of the hydrophobic pocket or for the stability of the complex. However, the M24K mutation at the rim of the hydrophobic pocket lowered the stability of the complex in 6M urea. On the other hand, non-conservative mutations E49G, D61G (cancels the only ionic interaction with UDG) and N76K, in three of the loops connecting the beta strands, conferred no such phenotype. The L23R and S21P mutations (beta1 edge) at the UDG-Ugi interface, and the N35D mutation far from the interface resulted in poor stability of the complex. However, the stability of the complexes was restored in the L23A, S21T and N35A mutations. These analyses and the studies on the exchange of Ugi mutants in preformed complexes with the substrate or the native Ugi have provided insights into the two-step mechanism of UDG-Ugi complex formation. Finally, we discuss the application of the Ugi isolates in overproduction of UDG mutants, toxic to cells.     

The role of leucine 191 of Escherichia coli uracil DNA glycosylase in the formation of a highly stable complex with the substrate mimic, ugi, and in uracil excision from the synthetic substrates

Uracil DNA glycosylase (UDG), a highly conserved DNA repair enzyme, initiates the uracil excision repair pathway. Ugi, a bacteriophage-encoded peptide, potently inhibits UDGs by serving as a remarkable substrate mimic. Structure determination of UDGs has identified regions important for the exquisite specificity in the detection and removal of uracils from DNA and in their interaction with Ugi. In this study, we carried out mutational analysis of the Escherichia coli UDG at Leu191 within the 187HPSPLS192 motif (DNA intercalation loop). We show that with the decrease in side chain length at position 191, the stability of the UDG-Ugi complexes regresses. Further, while the L191V and L191F mutants were as efficient as the wild type protein, the L191A and L191G mutants retained only 10 and 1% of the enzymatic activity, respectively. Importantly, however, substitution of Leu191 with smaller side chains had no effect on the relative efficiencies of uracil excision from the single-stranded and a corresponding double-stranded substrate. Our results suggest that leucine within the HPSPLS motif is crucial for the uracil excision activity of UDG, and it contributes to the formation of a physiologically irreversible complex with Ugi. We also envisage a role for Leu191 in stabilizing the productive enzyme-substrate complex.     

Crystal structure and functional insights into uracil-DNA glycosylase inhibition by phage ?29 DNA mimic protein p56

Uracil-DNA glycosylase (UDG) is a key repair enzyme responsible for removing uracil residues from DNA. Interestingly, UDG is the only enzyme known to be inhibited by two different DNA mimic proteins: p56 encoded by the Bacillus subtilis phage ϕ29 and the well-characterized protein Ugi encoded by the B. subtilis phage PBS1/PBS2. Atomic-resolution crystal structures of the B. subtilis UDG both free and in complex with p56, combined with site-directed mutagenesis analysis, allowed us to identify the key amino acid residues required for enzyme activity, DNA binding and complex formation. An important requirement for complex formation is the recognition carried out by p56 of the protruding Phe191 residue from B. subtilis UDG, whose side-chain is inserted into the DNA minor groove to replace the flipped-out uracil. A comparative analysis of both p56 and Ugi inhibitors enabled us to identify their common and distinctive features. Thereby, our results provide an insight into how two DNA mimic proteins with different structural and biochemical properties are able to specifically block the DNA-binding domain of the same enzyme.     

Excision of cytosine and thymine from DNA by mutants of human uracil-DNA glycosylase.

Uracil-DNA glycosylase (UDG) protects the genome by removing mutagenic uracil residues resulting from deamination of cytosine. Uracil binds in a rigid pocket at the base of the DNA-binding groove of human UDG and the specificity for uracil over the structurally related DNA bases thymine and cytosine is conferred by shape complementarity, as well as by main chain and Asn204 side chain hydrogen bonds. Here we show that replacement of Asn204 by Asp or Tyr147 by Ala, Cys or Ser results in enzymes that have cytosine-DNA glycosylase (CDG) activity or thymine-DNA glycosylase (TDG) activity, respectively. CDG and the TDG all retain some UDG activity. CDG and TDG have kcat values in the same range as typical multisubstrate-DNA glycosylases, that is at least three orders of magnitude lower than that of the highly selective and efficient wild-type UDG. Expression of CDG or TDG in Escherichia coli causes 4- to 100-fold increases in the yield of rifampicin-resistant mutants. Thus, single amino acid substitutions in UDG result in less selective DNA glycosylases that release normal pyrimidines and confer a mutator phenotype upon the cell. Three of the four new pyrimidine-DNA glycosylases resulted from single nucleotide substitutions, events that may also happen in vivo.     

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.     

Increased spontaneous mutation frequency in human cells expressing the phage PBS2-encoded inhibitor of uracil-DNA glycosylase

The Ugi protein inhibitor of uracil-DNA glycosylase encoded by bacteriophage PBS2 inactivates human uracil-DNA glycosylases (UDG) by forming a tight enzyme:inhibitor complex. To create human cells that are impaired for UDG activity, the human glioma U251 cell line was engineered to produce active Ugi protein. In vitro assays of crude cell extracts from several Ugi-expressing clonal lines showed UDG inactivation under standard assay conditions as compared to control cells, and four of these UDG defective cell lines were characterized for their ability to conduct in vivo uracil-DNA repair. Whereas transfected plasmid DNA containing either a U:G mispair or U:A base pairs was efficiently repaired in the control lines, uracil-DNA repair was not evident in the lines producing Ugi. Experiments using a shuttle vector to detect mutations in a target gene showed that Ugi-expressing cells exhibited a 3-fold higher overall spontaneous mutation frequency compared to control cells, due to increased C:G to T:A base pair substitutions. The growth rate and cell cycle distribution of Ugi-expressing cells did not differ appreciably from their parental cell counterpart. Further in vitro examination revealed that a thymine DNA glycosylase (TDG) previously shown to mediate Ugi-insensitive excision of uracil bases from DNA was not detected in the parental U251 cells. However, a Ugi-insensitive UDG activity of unknown origin that recognizes U:G mispairs and to a lesser extent U:A base pairs in duplex DNA, but which was inactive toward uracil residues in single-stranded DNA, was detected under assay conditions previously shown to be efficient for detecting TDG.     

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.     

A uracil-DNA glycosylase inhibitor encoded by a non-uracil containing viral DNA

Uracil-DNA glycosylase (UDG) is an enzyme involved in the base excision repair pathway. It specifically removes uracil from both single-stranded and double-stranded DNA. The genome of the Bacillus subtilis phage 29 is a linear double-stranded DNA with a terminal protein covalently linked at each 5'-end. Replication of 29 DNA starts by a protein-priming mechanism and generates intermediates that have long stretches of single-stranded DNA. By using in vivo chemical cross-linking and affinity chromatography techniques, we found that UDG is a cellular target for the early viral protein p56. Addition of purified protein p56 to B. subtilis extracts inhibited the endogenous UDG activity. Moreover, extracts from 29-infected cells were deficient in UDG activity. We suggested that inhibition of the cellular UDG is a defense mechanism developed by 29 to prevent the action of the base excision repair pathway if uracil residues arise in their replicative intermediates. Protein p56 is the first example of a UDG inhibitor encoded by a non-uracil-containing viral DNA.     

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.     

Substitutions at tyrosine 66 of Escherichia coli uracil DNA glycosylase lead to characterization of an efficient enzyme that is recalcitrant to product inhibition

Uracil DNA glycosylase (UDG), a ubiquitous and highly specific enzyme, commences the uracil excision repair pathway. Structural studies have shown that the tyrosine in a highly conserved GQDPY water-activating loop of UDGs blocks the entry of thymine or purines into the active site pocket. To further understand the role of this tyrosine (Y66 in Escherichia coli UDG), we have overproduced and characterized Y66F, Y66H, Y66L and Y66W mutants. The complexes of the wild-type, Y66F, Y66H and Y66L UDGs with uracil DNA glycosylase inhibitor (Ugi) (a proteinaceous substrate mimic) were stable to 8 M urea. However, some dissociation of the complex involving the Y66W UDG occurred at this concentration of urea. The catalytic efficiencies (V_max / K_m) of the Y66L and Y66F mutants were similar to those of the wild-type UDG. However, the Y66W and Y66H mutants were ~7- and ~173-fold compromised, respectively, in their activities. Interestingly, the Y66W mutation has resulted in an enzyme which is resistant to product inhibition. Preferential utilization of a substrate enabling a long range contact between the –5 phosphate (upstream to the scissile uracil) and the enzyme, and the results of modeling studies showing that the uracil-binding cavity of Y66W is wider than those of the wild type and other mutant UDGs, suggest a weaker interaction between uracil and the Y66W mutant. Furthermore, the fluorescence spectroscopy of UDGs and their complexes with Ugi, in the presence of uracil or its analog, 5-bromouracil, suggests compromised binding of uracil in the active site pocket of the Y66W mutant. Lack of inhibition of the Y66W UDG by apyrimidinic DNA (AP-DNA) is discussed to highlight a potential additional role of Y66 in shielding the toxic effects of AP-DNA, by lowering the rate of its release for subsequent recognition by an AP endonuclease.     

Base excision repair initiation revealed by crystal structures and binding kinetics of human uracil-DNA glycosylase with DNA.

Three high-resolution crystal structures of DNA complexes with wild-type and mutant human uracil-DNA glycosylase (UDG), coupled kinetic characterizations and comparisons with the refined unbound UDG structure help resolve fundamental issues in the initiation of DNA base excision repair (BER): damage detection, nucleotide flipping versus extrahelical nucleotide capture, avoidance of apurinic/apyrimidinic (AP) site toxicity and coupling of damage-specific and damage-general BER steps. Structural and kinetic results suggest that UDG binds, kinks and compresses the DNA backbone with a 'Ser-Pro pinch' and scans the minor groove for damage. Concerted shifts in UDG simultaneously form the catalytically competent active site and induce further compression and kinking of the double-stranded DNA backbone only at uracil and AP sites, where these nucleotides can flip at the phosphate-sugar junction into a complementary specificity pocket. Unexpectedly, UDG binds to AP sites more tightly and more rapidly than to uracil-containing DNA, and thus may protect cells sterically from AP site toxicity. Furthermore, AP-endonuclease, which catalyzes the first damage-general step of BER, enhances UDG activity, most likely by inducing UDG release via shared minor groove contacts and flipped AP site binding. Thus, AP site binding may couple damage-specific and damage-general steps of BER without requiring direct protein-protein interactions.     

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.     

Physical and functional interactions between uracil-DNA glycosylase and proliferating cell nuclear antigen from the euryarchaeon Pyrococcus furiosus

Uracil-DNA glycosylase (UDG) is an important repair enzyme in all organisms to remove uracil bases from DNA. Recent biochemical studies have revealed that human nuclear UDG (UNG2) forms a multiprotein complex in replication foci and initiates the base excision repair pathway by interacting with proliferating cell nuclear antigen (PCNA). Here, we show the physical and functional interactions between UDG and PCNA from the hyperthermophilic euryarchaeon, Pyrococcus furiosus. The physical interaction between the two proteins was identified by a surface plasmon resonance analysis. Furthermore, the uracil glycosylase activity of P. furiosus UDG is stimulated by P. furiosus PCNA (PfuPCNA) in vitro. This stimulatory effect was observed only when wild type PfuPCNA, but not a monomeric PCNA mutant, was present in the reaction. Mutational analyses revealed that our predicted PCNA-binding region (AKTLF) in P. furiosus UDG is actually important for the interaction with PfuPCNA. This is the first report describing the functional interaction between archaeal UDG and PCNA.     

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.     

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.     

Turning On uracil-DNA glycosylase using a pyrene nucleotide switch

Base flipping is a highly conserved process by which enzymes swivel an entire nucleotide from the DNA base stack into their active site pockets. Uracil DNA glycosylase (UDG) is a paradigm enzyme that uses a base flipping mechanism to catalyze the hydrolysis of the N-glycosidic bond of 2'-deoxyuridine (2'-dUrd) in DNA as the first step in uracil base excision repair. Flipping of 2'-dUrd by UDG has been proposed to follow a "pushing" mechanism in which a completely conserved leucine side chain (Leu-191) is inserted into the DNA minor groove to expel the uracil. Here we report a novel implementation of the "chemical rescue" approach to show that the weak binding affinity and low catalytic activity of L191A or L191G can be completely or partially restored by substitution of a pyrene (Y) nucleotide wedge on the DNA strand opposite to the uracil base (U/A to U/Y). These results indicate that pyrene acts both as a wedge to push the uracil from the base stack in the free DNA and as a "plug" to hinder its reinsertion after base flipping. Pyrene rescue should serve as a useful and novel tool to diagnose the functional roles of other amino acid side chains involved in base flipping.     

A kinetic analysis of substrate recognition by uracil-DNA glycosylase from herpes simplex virus type 1

Uracil-DNA glycosylase (UDG) is responsible for the removal of uracil from DNA. It has previously been demonstrated that UDG exhibits some sequence dependence in its activity, although this has not been well characterised. This study has investigated the sequence-dependent activity of UDG from herpes simplex virus type-1 (HSV-1). A more detailed analysis has been possible by using both kinetic and binding assays with a variety of different oligonucleotide substrates. The target uracil has been placed in substrates with either A-T-rich or G-C-rich flanking sequences and analyses have been performed on both the single- and double-stranded forms of each substrate. In the latter the uracil has been placed in both a U·A base pair and a U·G mismatch. It is observed that the sequences flanking the target uracil have a greater effect on UDG activity than the partner base of the uracil. Furthermore, the sequence context effects extend to single-stranded DNA. Systematic examination of the kinetics and binding of UDG with these different substrates has enabled us to examine the origin of the sequence preferences. We conclude that the damage recognition step in the HSV-1 UDG reaction pathway is modulated by local DNA sequence.     

Recognition of an unnatural difluorophenyl nucleotide by uracil DNA glycosylase

The DNA repair enzyme uracil DNA glycosylase (UDG) utilizes base flipping to recognize and remove unwanted uracil bases from the genome but does not react with its structural congener, thymine, which differs by a single methyl group. Two factors that determine whether an enzyme flips a base from the duplex are its shape and hydrogen bonding properties. To probe the role of these factors in uracil recognition by UDG, we have synthesized a DNA duplex that contains a single difluorophenyl (F) nucleotide analogue that is an excellent isostere of uracil but possesses no hydrogen bond donor or acceptor groups. By using binding affinity measurements, solution (19)F NMR, and solid state (31)P[(19)F] rotational-echo double-resonance (REDOR) NMR measurements, we establish that UDG partially unstacks F from the duplex. However, due to the lack of hydrogen bonding groups that are required to support an open-to-closed conformational transition in UDG, F cannot stably dock in the UDG active site. We propose that F attains a metastable unstacked state that mimics a previously detected intermediate on the uracil-flipping pathway and suggest structural models of the metastable state that are consistent with the REDOR NMR measurements.     

Thermostable uracil-DNA glycosylase from Thermotoga maritima a member of a novel class of DNA repair enzymes.

Uracil-DNA glycosylase (UDG) is a ubiquitous enzyme found in eukaryotes and prokaryotes [1][2][3]. This enzyme removes uracil bases that are present in DNA as a result of either deamination of cytosine or misincorporation of dUMP instead of dTMP [4] [5], and it is the primary activity in the DNA base excision repair pathway. Although UDG activities have been shown to be present in several thermophiles [6][7][8], no sequences have been found that are complementary to the Escherichia coli ung gene, which encodes UDG [9]. Here, we describe a UDG from the thermophile Thermotoga maritima. The T. maritima UDG gene has a low level of homology to the E. coli G-T/U mismatch-specific DNA glycosylase gene (mug). The expressed protein is capable of removing uracil from DNA containing either a U-A or a U-G base pair and is heat-stable up to 75 degrees C. The enzyme is also active on single-stranded DNA containing uracil. Analogous genes appear to be present in several prokaryotic organisms, including thermophilic and mesophilic eubacteria as well as archaebacteria, the human-disease pathogens Treponema palladium and Rickettsia prowazekii, and the extremely radioresistant organism Deinococcus radiodurans. These findings suggest that the T. maritima UDG is a member of a new class of DNA repair enzymes.