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.     

Optimisation of the surface electrostatics as a strategy for cold adaptation of uracil-DNA N-glycosylase (UNG) from Atlantic cod (Gadus morhua)

Cold-adapted enzymes are characterised by an increased catalytic efficiency and reduced temperature stability compared to their mesophilic counterparts. Lately, it has been suggested that an optimisation of the electrostatic surface potential is a strategy for cold adaptation for some enzymes. A visualisation of the electrostatic surface potential of cold-adapted uracil-DNA N-glycosylase (cUNG) from Atlantic cod indicates a more positively charged surface near the active site compared to human UNG (hUNG). In order to investigate the importance of the altered surface potential for the cold-adapted features of cod UNG, six mutants have been characterised and compared to cUNG and hUNG. The cUNG quadruple mutant (V171E, K185V, H250Q and H275Y) and four corresponding single mutants all comprise substitutions of residues present in the human enzyme. A human UNG mutant, E171V, comprises the equivalent residue found in cod UNG. In addition, crystal structures of the single mutants V171E and E171V have been determined. Results from the study show that a more negative electrostatic surface potential reduces the activity and increases the stability of cod UNG, and suggest an optimisation of the surface potential as a strategy for cold-adaptation of this enzyme. Val171 in cod UNG is especially important in this respect.     

A comparative study of uracil-DNA glycosylases from human and herpes simplex virus type 1

Uracil-DNA glycosylase (UNG) is the key enzyme responsible for initiation of base excision repair. We have used both kinetic and binding assays for comparative analysis of UNG enzymes from humans and herpes simplex virus type 1 (HSV-1). Steady-state fluorescence assays showed that hUNG has a much higher specificity constant (k(cat)/K(m)) compared with the viral enzyme due to a lower K(m). The binding of UNG to DNA was also studied using a catalytically inactive mutant of UNG and non-cleavable substrate analogs (2'-deoxypseudouridine and 2'-alpha-fluoro-2'-deoxyuridine). Equilibrium DNA binding revealed that both human and HSV-1 UNG enzymes bind to abasic DNA and both substrate analogs more weakly than to uracil-containing DNA. Structure determination of HSV-1 D88N/H210N UNG in complex with uracil revealed detailed information on substrate binding. Together, these results suggest that a significant proportion of the binding energy is provided by specific interactions with the target uracil. The kinetic parameters for human UNG indicate that it is likely to have activity against both U.A and U.G mismatches in vivo. Weak binding to abasic DNA also suggests that UNG activity is unlikely to be coupled to the subsequent common steps of base excision repair.     

Characterization of human cytomegalovirus uracil DNA glycosylase (UL114) and its interaction with polymerase processivity factor (UL44)

Here, we report the molecular characterization of the human cytomegalovirus uracil DNA glycosylase (UNG) UL114. Purified UL114 was shown to be a DNA glycosylase, which removes uracil from double-stranded and single-stranded DNA. However, kinetic analysis has shown that viral UNG removed uracil more slowly compared with the core form of human UNG (Δ84hUNG), which has a catalytic efficiency (k_cat/K_M) 350- to 650-fold higher than that of UL114. Furthermore, UL114 showed a maximum level of DNA glycosylase activity at equimolar concentrations of the viral polymerase processivity factor UL44. Next, UL114 was coprecipitated with DNA immobilized to magnetic beads only in the presence of UL44, suggesting that UL44 facilitated the loading of UL114 on DNA. Moreover, mutant analysis demonstrated that the C-terminal part of UL44 (residues 291-433) is important for the interplay with UL114. Immunofluorescence microscopy revealed that UL44 and UL114 colocalized in numerous small punctuate foci at the immediate-early (5 and 8 hpi) phases of infection and that these foci grew in size throughout the infection. Furthermore, coimmunoprecipitation assays with cellular extracts of infected cells confirmed that UL44 associated with UL114. Finally, the nuclear concentration of UL114 was estimated to be 5- to 10-fold higher than that of UL44 in infected cells, which indicated a UL44-independent role of UL114. In summary, our data have demonstrated a catalytically inefficient viral UNG that was highly enriched in viral replication foci, thus supporting an important role of UL114 in replication rather than repair of the viral genome.     

Direct interaction between uracil-DNA glycosylase and a proliferating cell nuclear antigen homolog in the crenarchaeon Pyrobaculum aerophilum

Proliferating cell nuclear antigen (PCNA) acts as a sliding clamp on duplex DNA. Its homologs, present in Eukarya and Archaea, are part of protein complexes that are indispensable for DNA replication and DNA repair. In Eukarya, PCNA is known to interact with more than a dozen different proteins, including a human major nuclear uracil-DNA glycosylase (hUNG2) involved in immediate postreplicative repair. In Archaea, only three classes of PCNA-binding proteins have been reported previously: replication factor C (the PCNA clamp loader), family B DNA polymerase, and flap endonuclease. In this study, we report a direct interaction between a uracil-DNA glycosylase (Pa-UDGa) and a PCNA homolog (Pa-PCNA1), both from the hyperthermophilic crenarchaeon Pyrobaculum aerophilum (T(opt) = 100 degrees C). We demonstrate that the Pa-UDGa-Pa-PCNA1 complex is thermostable, and two hydrophobic amino acid residues on Pa-UDGa (Phe(191) and Leu(192)) are shown to be crucial for this interaction. It is interesting to note that although Pa-UDGa has homologs throughout the Archaea and bacteria, it does not share significant sequence similarity with hUNG2. Nevertheless, our results raise the possibility that Pa-UDGa may be a functional analog of hUNG2 for PCNA-dependent postreplicative removal of misincorporated uracil.     

Post-replicative base excision repair in replication foci.

Base excision repair (BER) is initiated by a DNA glycosylase and is completed by alternative routes, one of which requires proliferating cell nuclear antigen (PCNA) and other proteins also involved in DNA replication. We report that the major nuclear uracil-DNA glycosylase (UNG2) increases in S phase, during which it co-localizes with incorporated BrdUrd in replication foci. Uracil is rapidly removed from replicatively incorporated dUMP residues in isolated nuclei. Neutralizing antibodies to UNG2 inhibit this removal, indicating that UNG2 is the major uracil-DNA glycosylase responsible. PCNA and replication protein A (RPA) co-localize with UNG2 in replication foci, and a direct molecular interaction of UNG2 with PCNA (one binding site) and RPA (two binding sites) was demonstrated using two-hybrid assays, a peptide SPOT assay and enzyme-linked immunosorbent assays. These results demonstrate rapid post-replicative removal of incorporated uracil by UNG2 and indicate the formation of a BER complex that contains UNG2, RPA and PCNA close to the replication fork.     

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.     

Identification,cloning, and expression of uracil-DNA glycosylase from Atlantic cod (<Emphasis Type="Italic">Gadus morhua</Emphasis>): characterization and homology modeling of the cold-active catalytic domain

Two distinct forms of the highly conserved uracil-DNA glycosylase (UNG) have been isolated from Atlantic cod (Gadus morhua) liver cDNA by rapid amplification of cDNA ends (RACE). From the cDNA sequences, both forms were deduced to encode an open reading frame of 301 amino acids, with an identical 267-amino-acid C-terminal region and different N-terminal regions of 34 amino acids. By comparison with the human UNG sequences, the two forms were identified as possible mitochondrial (cUNG1) and nuclear (cUNG2) forms. Several constructs of recombinant cUNG (rcUNG) were expressed in Escherichia coli in order to optimize the yield. The recombinant enzyme was purified to apparent homogeneity as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Activity and stability experiments showed that rcUNG was similar to cUNG previously purified from Atlantic cod liver, and was more pH- and temperature labile than a recombinant human UNG (rhUNG). Under optimal assay conditions for both rcUNG and rhUNG, the turnover number (k(cat)) was three times higher for rcUNG compared with rhUNG, with an identical K(M), resulting in a threefold higher catalytic efficiency (k(cat)/K(M)) for rcUNG. These activity and stability experiments reveal cold-adapted features in rcUNG. Homology models of the catalytic domains of Atlantic cod (cUNG) and mouse uracil-DNA glycosylase (mUNG) were built using the human UNG (hUNG) crystal structure as a template. The unique amino acid substitutions observed in cod UNG were mainly located in the N- and C-terminal parts of the sequence. The analysis indicated a more stable N-terminal, a more flexible C-terminal, and a less stabilized core in cUNG as compared with the mammalian UNGs. Substitution of several amino acids in or near the DNA-binding site in cUNG could give rise to a more positively charged surface and a higher electrostatic potential near the active site compared with the mammalian UNGs. The higher potential may increase the electrostatic interactions between the enzyme and DNA, and may explain the increased substrate affinity and, in combination with the higher flexibility, the higher catalytic efficiency observed for rcUNG.     

Human mitochondrial uracil-DNA glycosylase preform (UNG1) is processed to two forms one of which is resistant to inhibition by AP sites.

The preform of human mitochondrial uracil-DNA glycosylase (UNG1) contains 35 N-terminal residues required for mitochondrial targeting. We have examined processing of human UNG1 expressed in insect cells and processing in vitro by human mitochondrial extracts . In insect cells we detected a major processed form lacking 29 of the 35 unique N-terminal residues (UNG1Delta29, 31 kDa) and two minor forms lacking the 75 and 77 N-terminal residues, respectively (UNG1Delta75 and UNG1Delta77, 26 kDa). Purified UNG1Delta29 was effectively cleaved in vitro to a fully active 26 kDa form by human mitochondrial extracts. Furthermore, endogenous forms of 31 and 26 kDa were also observed in HeLa mitochondrial extracts. The sequences at the cleavage sites, as identified by peptide sequencing, were compatible with the known specificity of mitochondrial processing peptidase (MPP). However, in vitro cleavage of UNG1Delta29 by mitochondrial extracts did not require divalent cations and was stimulated by EDTA, indicating the involvement of a processing peptidase distinct from MPP at the second site. Interestingly, while UNG1Delta29 generally has the typical properties reported for other uracil-DNA glycosylases, it is not inhibited by apurinic/apyrimidinic sites. Our results indicate that the preform of human mitochondrial uracil-DNA glycosylase is processed to distinctly different forms lacking 29 or 75/77 N-terminal residues, respectively.     

Excision of deaminated cytosine from the vertebrate genome: role of the SMUG1 uracil-DNA glycosylase

Gene-targeted mice deficient in the evolutionarily conserved uracil-DNA glycosylase encoded by the UNG gene surprisingly lack the mutator phenotype characteristic of bacterial and yeast ung(-) mutants. A complementary uracil-DNA glycosylase activity detected in ung(-/-) murine cells and tissues may be responsible for the repair of deaminated cytosine residues in vivo. Here, specific neutralizing antibodies were used to identify the SMUG1 enzyme as the major uracil-DNA glycosylase in UNG-deficient mice. SMUG1 is present at similar levels in cell nuclei of non-proliferating and proliferating tissues, indicating a replication- independent role in DNA repair. The SMUG1 enzyme is found in vertebrates and insects, whereas it is absent in nematodes, plants and fungi. We propose a model in which SMUG1 has evolved in higher eukaryotes as an anti-mutator distinct from the UNG enzyme, the latter being largely localized to replication foci in mammalian cells to counteract de novo dUMP incorporation into DNA.     

New insights on the role of the gamma-herpesvirus uracil-DNA glycosylase leucine loop revealed by the structure of the Epstein-Barr virus enzyme in complex with an inhibitor protein

Epstein-Barr virus (EBV) is a human gamma-herpesvirus. Within its 86 open reading frame containing genome, two enzymes avoiding uracil incorporation into DNA can be found: uracil triphosphate hydrolase and uracil-DNA glycosylase (UNG). The latter one excises uracil bases that are due to cytosine deamination or uracil misincorporation from double-stranded DNA substrates. The EBV enzyme belongs to family 1 UNGs. We solved the three-dimensional structure of EBV UNG in complex with the uracil-DNA glycosylase inhibitor protein (Ugi) from bacteriophage PBS-2 at a resolution of 2.3 A by X-ray crystallography. The structure of EBV UNG encoded by the BKRF3 reading frame shows the excellent global structural conservation within the solved examples of family 1 enzymes. Four out of the five catalytic motifs are completely conserved, whereas the fifth one, the leucine loop, carries a seven residue insertion. Despite this insertion, catalytic constants of EBV UNG are similar to those of other UNGs. Modelling of the EBV UNG-DNA complex shows that the longer leucine loop still contacts DNA and is likely to fulfil its role of DNA binding and deformation differently than the enzymes with previously solved structures. We could show that despite the evolutionary distance of EBV UNG from the natural host protein, bacteriophage Ugi binds with an inhibitory constant of 8 nM to UNG. This is due to an excellent specificity of Ugi for conserved elements of UNG, four of them corresponding to catalytic motifs and a fifth one corresponding to an important beta-turn structuring the catalytic site.     

Requirement for Uracil-DNA Glycosylase during the Transition to Late-Phase Cytomegalovirus DNA Replication

Cytomegalovirus gene UL114, a homolog of mammalian uracil-DNA glycosylase (UNG), is required for efficient viral DNA replication. In quiescent fibroblasts, UNG mutant virus replication is delayed for 48 h and follows the virus-induced expression of cellular UNG. In contrast, mutant virus replication proceeds without delay in actively growing fibroblasts that express host cell UNG. In the absence of viral or host cell UNG expression, mutant virus fails to proceed to late-phase DNA replication, characterized by rapid DNA amplification. The data suggest that uracil incorporated early during wild-type viral DNA replication must be removed by virus or host UNG prior to late-phase amplification and encapsidation into progeny virions. The process of uracil incorporation and excision may introduce strand breaks to facilitate the transition from early-phase replication to late-phase amplification.     

Concerted action of activation-induced cytidine deaminase and uracil-DNA glycosylase reduces covalently closed circular DNA of duck hepatitis B virus

Covalently closed circular DNA (cccDNA) forms a template for the replication of hepatitis B virus (HBV) and duck HBV (DHBV). Recent studies suggest that activation-induced cytidine deaminase (AID) functions in innate immunity, although its molecular mechanism of action remains unclear, particularly regarding HBV restriction. Here we demonstrated that overexpression of chicken AID caused hypermutation and reduction of DHBV cccDNA levels. Inhibition of uracil-DNA glycosylase (UNG) by UNG inhibitor protein (UGI) abolished AID-induced cccDNA reduction, suggesting that the AID/UNG pathway triggers the degradation of cccDNA via cytosine deamination and uracil excision.     

A mollicute (mycoplasma) DNA repair enzyme: purification and characterization of uracil-DNA glycosylase.

The DNA repair enzyme uracil-DNA glycosylase from Mycoplasma lactucae (831-C4) was purified 1,657-fold by using affinity chromatography and chromatofocusing techniques. The only substrate for the enzyme was DNA that contained uracil residues, and the Km of the enzyme was 1.05 +/- 0.12 microM for dUMP containing DNA. The product of the reaction was uracil, and it acted as a noncompetitive inhibitor of the uracil-DNA glycosylase with a Ki of 5.2 mM. The activity of the enzyme was insensitive to Mg2+, Mn2+, Zn2+, Ca2+, and Co2+ over the concentration range tested, and the activity was not inhibited by EDTA. The enzyme activity exhibited a biphasic response to monovalent cations and to polyamines. The enzyme had a pI of 6.4 and existed as a nonspherical monomeric protein with a molecular weight of 28,500 +/- 1,200. The uracil-DNA glycosylase from M. lactucae was inhibited by the uracil-DNA glycosylase inhibitor from bacteriophage PBS-2, but the amount of inhibitor required for 50% inhibition of the mycoplasmal enzyme was 2.2 and 8 times greater than that required to cause 50% inhibition of the uracil-DNA glycosylases from Escherichia coli and Bacillus subtilis, respectively. Previous studies have reported that some mollicutes lack uracil-DNA glycosylase activity, and the results of this study demonstrate that the uracil-DNA glycosylase from M. lactucae has a higher Km for uracil-containing DNA than those of the glycosylases of other procaryotic organisms. Thus, the low G + C content of the DNA from some mollicutes and the A.T-biased mutation pressure observed in these organisms may be related to their decreased capacity to remove uracil residues from DNA.     

Immunoglobulin isotype switching is inhibited and somatic hypermutation perturbed in UNG-deficient mice

BACKGROUND: We have previously proposed that deamination of cytosine to uracil at sites within the immunoglobulin loci by activation-induced deaminase (AID) triggers antibody diversification. The pattern of diversification (phase 1 or 2 hypermutation, gene conversion, or switch recombination) is viewed as depending on the mode of resolution of the dU/dG lesion. A major resolution mode involves excising the uracil, an activity that at least four different enzymes can accomplish in the mouse. RESULTS: Deficiency in UNG uracil-DNA glycosylase alone is sufficient to distort the pathway of hypermutation in mice. In ung(-/-) animals, mutations at dC/dG pairs are dramatically shifted toward transitions (95%), indicating that the generation of abasic sites (which can induce transversions) has been inhibited. The pattern of substitutions at dA/dT pairs is unaffected. Class-switch recombination is substantially, but not totally, inhibited. CONCLUSIONS: The results provide strong support for the DNA deamination model for antibody diversification with respect to class-switching as well as hypermutation and, in the context of this model, suggest that (i) UNG is the major mouse DNA glycosylase responsible for processing the programmed dU/dG lesions within the immunoglobulin locus; (ii) the second (dA/dT-biased) phase of mutation is probably triggered by recognition of the initiating dU/dG lesion; and (iii) switch recombination largely proceeds via formation of an abasic site, although (iv) an UNG-independent pathway of switch recombination exists, which could reflect action by another uracil-DNA glycosylase but might alternatively be explained by a distinct pathway of resolution, for example, one involving MSH2/MSH6 recognition of the dU/dG lesion.     

Physical and functional interaction of human nuclear uracil-DNA glycosylase with proliferating cell nuclear antigen

Uracil residues arise in DNA by the misincorporation of dUMP in place of dTMP during DNA replication or by the deamination of cytosine in DNA. Uracil-DNA glycosylase initiates DNA base excision repair of uracil residues by catalyzing the hydrolysis of the N-glycosylic bond linking the uracil base to deoxyribose. In human cells, the nuclear form of uracil-DNA glycosylase (UNG2) contains a conserved PCNA-binding motif located at the N-terminus that has been implicated experimentally in binding PCNA. Here we use purified preparations of UNG2 and PCNA to demonstrate that UNG2 physically associates with PCNA. UNG2 co-eluted with PCNA during size exclusion chromatography and bound to a PCNA affinity column. Association of UNG2 with PCNA was abolished by the addition of 100 mM NaCl, and significantly decreased in the presence of 10 mM MgCl(2). The functional significance of the UNG2.PCNA association was demonstrated by UNG2 activity assays. Addition of PCNA (30-810 pmol) to standard uracil-DNA glycosylase reactions containing linear [uracil-(3)H]DNA stimulated UNG2 catalytic activity up to 2.6-fold. UNG2 activity was also stimulated by 7.5 mM MgCl(2). The stimulatory effect of PCNA was increased by the addition of MgCl(2); however, the dependence on PCNA concentration was the same, indicating that the effects of MgCl(2) and PCNA on UNG2 activity occurred by independent mechanisms. Loading of PCNA onto the DNA substrate was required for stimulation, as the activity of UNG2 on circular DNA substrates was not affected by the addition of PCNA. Addition of replication factor C and ATP to reactions containing 90 pmol of PCNA resulted in two-fold stimulation of UNG2 activity on circular DNA.     

Repair of U/G and U/A in DNA by UNG2-associated repair complexes takes place predominantly by short-patch repair both in proliferating and growth-arrested cells

Nuclear uracil-DNA glycosylase UNG2 has an established role in repair of U/A pairs resulting from misincorporation of dUMP during replication. In antigen-stimulated B-lymphocytes UNG2 removes uracil from U/G mispairs as part of somatic hypermutation and class switch recombination processes. Using antibodies specific for the N-terminal non-catalytic domain of UNG2, we isolated UNG2-associated repair complexes (UNG2-ARC) that carry out short-patch and long-patch base excision repair (BER). These complexes contain proteins required for both types of BER, including UNG2, APE1, POLbeta, POLdelta, XRCC1, PCNA and DNA ligase, the latter detected as activity. Short-patch repair was the predominant mechanism both in extracts and UNG2-ARC from proliferating and less BER-proficient growth-arrested cells. Repair of U/G mispairs and U/A pairs was completely inhibited by neutralizing UNG-antibodies, but whereas added recombinant SMUG1 could partially restore repair of U/G mispairs, it was unable to restore repair of U/A pairs in UNG2-ARC. Neutralizing antibodies to APE1 and POLbeta, and depletion of XRCC1 strongly reduced short-patch BER, and a fraction of long-patch repair was POLbeta dependent. In conclusion, UNG2 is present in preassembled complexes proficient in BER. Furthermore, UNG2 is the major enzyme initiating BER of deaminated cytosine (U/G), and possibly the sole enzyme initiating BER of misincorporated uracil (U/A).     

Effect of the thymidylate synthase inhibitors on dUTP and TTP pool levels and the activities of DNA repair glycosylases on uracil and 5-fluorouracil in DNA

5-Fluorouracil (5-FU), 5-fluorodeoxyuridine (5-dUrd), and raltitrixed (RTX) are anticancer agents that target thymidylate synthase (TS), thereby blocking the conversion of dUMP into dTMP. In budding yeast, 5-FU promotes a large increase in the dUMP/dTMP ratio leading to massive polymerase-catalyzed incorporation of uracil (U) into genomic DNA, and to a lesser extent 5-FU, which are both excised by yeast uracil DNA glycosylase (UNG), leading to DNA fragmentation and cell death. In contrast, the toxicity of 5-FU and RTX in human and mouse cell lines does not involve UNG, but, instead, other DNA glycosylases that can excise uracil derivatives. To elucidate the basis for these divergent findings in yeast and human cells, we have investigated how these drugs perturb cellular dUTP and TTP pool levels and the relative abilities of three human DNA glycosylases (hUNG2, hSMUG1, and hTDG) to excise various TS drug-induced lesions in DNA. We found that 5-dUrd only modestly increases the dUTP and dTTP pool levels in asynchronous MEF, HeLa, and HT-29 human cell lines when growth occurs in standard culture media. In contrast, treatment of chicken DT40 B cells with 5-dUrd or RTX resulted in large increases in the dUTP/TTP ratio. Surprisingly, even though UNG is the only DNA glycosylase in DT40 cells that can act on U·A base pairs derived from dUTP incorporation, an isogenic ung(-/-) DT40 cell line showed little change in its sensitivity to RTX as compared to control cells. In vitro kinetic analyses of the purified human enzymes show that hUNG2 is the most powerful catalyst for excision of 5-FU and U regardless of whether it is found in base pairs with A or G or present in single-stranded DNA. Fully consistent with the in vitro activity assays, nuclear extracts isolated from human and chicken cell cultures show that hUNG2 is the overwhelming activity for removal of both U and 5-FU, despite its bystander status with respect to drug toxicity in these cell lines. The diverse outcomes of TS inhibition with respect to nucleotide pool levels, the nature of the resulting DNA lesion, and the DNA repair response are discussed.     

Uracil-DNA glycosylase inhibitor of bacteriophage PBS2: cloning and effects of expression of the inhibitor gene in Escherichia coli.

The uracil-DNA glycosylase inhibitor gene of bacteriophage PBS2 was cloned, and the effects of this inhibitor on Escherichia coli cells that contain uracil-DNA glycosylase activity were determined. A PBS2 genomic library was constructed by inserting EcoRI restriction fragments of PBS2 DNA into a plasmid pUC19 vector. The library was used to transform wild-type (ung+) E. coli, and the presence of the functional inhibitor gene was determined by screening for colonies that supported growth of M13mp19 phage containing uracil-DNA. A clone was identified that carried a 4.1-kilobase EcoRI DNA insert in the vector plasmid. Extracts of cells transformed with this recombinant plasmid lacked detectable uracil-DNA glycosylase activity and contained a protein that inhibited the activity of purified E. coli uracil-DNA glycosylase in vitro. The uracil-DNA glycosylase inhibitor expressed in these E. coli was partially purified and characterized as a heat-stable protein with a native molecular weight of about 18,000. Hence, we conclude that the PBS2 uracil-DNA glycosylase inhibitor gene was cloned and that the gene product has properties similar to those from PBS2-infected Bacillus subtilis cells. Inhibitor gene expression in E. coli resulted in (i) a weak mutator phenotype, (ii) a growth rate similar to that of E. coli containing pUC19 alone, (iii) a sensitivity to the antifolate drug aminopterin similar to that of cells lacking the inhibitor gene, and (iv) an increased resistance to the lethal effects of 5-fluoro-2'-deoxyuridine. These physiological properties are consistent with the phenotypes of other ung mutants.     

DNA-uracil and human pathology

Uracil is usually an inappropriate base in DNA, but it is also a normal intermediate during somatic hypermutation (SHM) and class switch recombination (CSR) in adaptive immunity. In addition, uracil is introduced into retroviral DNA by the host as part of a defence mechanism. The sources of uracil in DNA are spontaneous or enzymatic deamination of cytosine (U:G mispairs) and incorporation of dUTP (U:A pairs). Uracil in DNA is removed by a uracil-DNA glycosylase. The major ones are nuclear UNG2 and mitochondrial UNG1 encoded by the UNG-gene, and SMUG1 that also removes oxidized pyrimidines, e.g. 5-hydroxymethyluracil. The other ones are TDG that removes U and T from mismatches, and MBD4 that removes U from CpG contexts. UNG2 is found in replication foci during the S-phase and has a distinct role in repair of U:A pairs, but it is also important in U:G repair, a function shared with SMUG1. SHM is initiated by activation-induced cytosine deaminase (AID), followed by removal of U by UNG2. Humans lacking UNG2 suffer from recurrent infections and lymphoid hyperplasia, and have skewed SHM and defective CSR, resulting in elevated IgM and strongly reduced IgG, IgA and IgE. UNG-defective mice also develop B-cell lymphoma late in life. In the defence against retrovirus, e.g. HIV-1, high concentrations of dUTP in the target cells promotes misincorporation of dUMP-, and host cell APOBEC proteins may promote deamination of cytosine in the viral DNA. This facilitates degradation of viral DNA by UNG2 and AP-endonuclease. However, viral proteins Vif and Vpr counteract this defense by mechanisms that are now being revealed. In conclusion, uracil in DNA is both a mutagenic burden and a tool to modify DNA for diversity or degradation.