Crystal structure and mutational analysis of human uracil-DNA glycosylase: structural basis for specificity and catalysis

Nontarget DNA binding shapes the dynamic landscape for enzymatic recognition of DNA damage

The DNA repair enzyme human uracil DNA glycosylase (UNG) scans short stretches of genomic DNA and captures rare uracil bases as they transiently emerge from the DNA duplex via spontaneous base pair breathing motions. The process of DNA scanning requires that the enzyme transiently loosen its grip on DNA to allow stochastic movement along the DNA contour, while engaging extrahelical bases requires motions on a more rapid timescale. Here, we use NMR dynamic measurements to show that free UNG has no intrinsic dynamic properties in the millisecond to microsecond and subnanosecond time regimes, and that the act of binding to nontarget DNA reshapes the dynamic landscape to allow productive millisecond motions for scanning and damage recognition. These results suggest that DNA structure and the spontaneous dynamics of base pairs may drive the evolution of a protein sequence that is tuned to respond to this dynamic regime.

Further evidence for involvement of a noncanonical function of uracil DNA glycosylase in class switch recombination

Activation-induced cytidine deaminase (AID) introduces DNA cleavage in the Ig gene locus to initiate somatic hypermutation (SHM) and class switch recombination (CSR) in B cells. The DNA deamination model assumes that AID deaminates cytidine (C) on DNA and generates uridine (U), resulting in DNA cleavage after removal of U by uracil DNA glycosylase (UNG). Although UNG deficiency reduces CSR efficiency to one tenth, we reported that catalytically inactive mutants of UNG were fully proficient in CSR and that several mutants at noncatalytic sites lost CSR activity, indicating that enzymatic activity of UNG is not required for CSR. In this report we show that CSR activity by many UNG mutants critically depends on its N-terminal domain, irrespective of their enzymatic activities. Dissociation of the catalytic and CSR activity was also found in another UNG family member, SMUG1, and its mutants. We also show that Ugi, a specific peptide inhibitor of UNG, inhibits CSR without reducing DNA cleavage of the S (switch) region, confirming dispensability of UNG in DNA cleavage in CSR. It is therefore likely that UNG is involved in a repair step after DNA cleavage in CSR. Furthermore, requirement of the N terminus but not enzymatic activity of UNG mutants for CSR indicates that the UNG protein structure is critical. The present findings support our earlier proposal that CSR depends on a noncanonical function of the UNG protein (e.g., as a scaffold for repair enzymes) that might be required for the recombination reaction after DNA cleavage.

Generation, biological consequences and repair mechanisms of cytosine deamination in DNA

Base moieties in DNA are spontaneously threatened by naturally occurring chemical reactions such as deamination, hydrolysis and oxidation. These DNA modifications have been considered to be major causes of cell death, mutations and cancer induction in organisms. Organisms have developed the DNA base excision repair pathway as a defense mechanism to protect them from these threats. DNA glycosylases, the key enzyme in the base excision repair pathway, are highly conserved in evolution. Uracil constantly occurs in DNA. Uracil in DNA arises by spontaneous deamination of cytosine to generate pro-mutagenic U:G mispairs. Uracil in DNA is also produced by the incorporation of dUMP during DNA replication. Uracil-DNA glycosylase (UNG) acts as a major repair enzyme that protects DNA from the deleterious consequences of uracil. The first UNG activity was discovered in E. coli in 1974. This was also the first discovery of base excision repair. The sequence encoded by the ung gene demonstrates that the E. coli UNG is highly conserved in viruses, bacteria, archaea, yeast, mice and humans. In this review, we will focus on central and recent findings on the generation, biological consequences and repair mechanisms of uracil in DNA and on the biological significance of uracil-DNA glycosylase.

Insights from xanthine and uracil DNA glycosylase activities of bacterial and human SMUG1: switching SMUG1 to UDG

Single-strand-selective monofunctional uracil DNA glycosylase (SMUG1) belongs to Family 3 of the uracil DNA glycosylase (UDG) superfamily. Here, we report that a bacterial SMUG1 ortholog in Geobacter metallireducens (Gme) and the human SMUG1 enzyme are not only UDGs but also xanthine DNA glycosylases (XDGs). In addition, mutational analysis and molecular dynamics (MD) simulations of Gme SMUG1 identify important structural determinants in conserved motifs 1 and 2 for XDG and UDG activities. Mutations at M57 (M57L) and H210 (H210G, H210M, and H210N), both of which are involved in interactions with the C2 carbonyl oxygen in uracil or xanthine, cause substantial reductions in XDG and UDG activities. Increased selectivity is achieved in the A214R mutant of Gme SMUG1, which corresponds to a position involved in base flipping. This mutation results in an activity profile resembling a human SMUG1-like enzyme as exemplified by the retention of UDG activity on mismatched base pairs and weak XDG activity. MD simulations indicate that M57L increases the flexibility of the motif 2 loop region and specifically A214, which may account for the reduced catalytic activity. G60Y completely abolishes XDG and UDG activity, which is consistent with a modeled structure in which G60Y blocks the entry of either xanthine or uracil to the base binding pocket. Most interestingly, a proline substitution at the G63 position switches the Gme SMUG1 enzyme to an exclusive UDG as demonstrated by the uniform excision of uracil in both double-stranded and single-stranded DNA and the complete loss of XDG activity. MD simulations indicate that a combination of a reduced free volume and altered flexibility in the active-site loops may underlie the dramatic effects of the G63P mutation on the activity profile of SMUG1. This study offers insights on the important role that modulation of conformational flexibility may play in defining specificity and catalytic efficiency.

Human cytomegalovirus DNA replication: antiviral targets and drugs

Human cytomegalovirus (HCMV) infection is associated with severe morbidity and mortality in immunocompromised individuals, in particular transplant recipients and AIDS patients, and is the most frequent congenital viral infection in humans. There are currently five drugs approved for HCMV treatment: ganciclovir and its prodrug valganciclovir, foscarnet, cidofovir and fomivirsen. These drugs have provided a major advance in HCMV disease management, but they suffer from poor bioavailability, significant toxicity and limited effectiveness, mainly due to the development of drug resistance. Fortunately, there are several novel and potentially very effective new compounds which are under pre-clinical and clinical evaluation and may address these limitations. This review focuses on HCMV proteins that are directly or indirectly involved in viral DNA replication and represent already established or potential novel antiviral targets, and describes both currently available drugs and new compounds against such protein targets.

Uracil DNA glycosylase: revisiting substrate-assisted catalysis by DNA phosphate anions

Uracil DNA glycosylase (UNG) is a powerful DNA repair enzyme that has been shown to stabilize a glycosyl cation reaction intermediate and a related tight binding inhibitor using electrostatic interactions with the +1 and -1, but not the +2, phosphodiester group of the single-stranded DNA substrate Ap (2+)Ap (1+)Up (1-)ApA. These experimental results differed considerably from computational findings using duplex DNA, where the +2 phosphate was found to stabilize the transition state by approximately 5 kcal/mol, suggesting that UNG uses different catalytic strategies with single-stranded and double-stranded DNA substrates. In addition, the computational studies indicated that the conserved and positively charged His148 (which hydrogen bonds to the +2 phosphate) destabilized the glycosyl cation intermediate by 6-8 kcal/mol through anticatalytic electrostatic interactions. To evaluate these interesting proposals, we measured the kinetic effects of neutral methylphosphonate (MeP) stereoisomers at the +1 and +2 positions of a 12-mer dsDNA substrate and also the catalytic contribution and ionization state of His148. For MeP substitutions at the +1 position, single-turnover kinetic studies showed that the activation barrier was increased by 9.8 and 3.1 kcal/mol, corresponding to a stereoselectivity of nearly 40000-fold for the respective MeP isomers. Identical to the findings with ssDNA, MeP substitutions at the +2 position resulted in only small changes in the activation barrier (+/-0.3 kcal/mol), with little stereoselectivity ( approximately 4-fold). However, the H148A mutation destabilizes both the ground state and transition states by 2.4 and 4.3 kcal/mol, respectively. Thus, His148 is catalytic because it stabilizes the transition state to a greater extent (1.9 kcal/mol) than the ground state. Heteronuclear NMR studies established that His148 was neutral in the free enzyme at neutral pH, and in conformational exchange in a specific DNA complex containing uracil. We conclude that the +1 and +2 phosphate esters play identical catalytic roles in the reactions of single-stranded and double-stranded DNA substrates, and that His148 serves a catalytic role by positioning the substrate and catalytic water, or by an environmental effect.

A new protein architecture for processing alkylation damaged DNA: the crystal structure of DNA glycosylase AlkD

DNA glycosylases safeguard the genome by locating and excising chemically modified bases from DNA. AlkD is a recently discovered bacterial DNA glycosylase that removes positively charged methylpurines from DNA, and was predicted to adopt a protein fold distinct from from those of other DNA repair proteins. The crystal structure of Bacillus cereus AlkD presented here shows that the protein is composed exclusively of helical HEAT-like repeats, which form a solenoid perfectly shaped to accommodate a DNA duplex on the concave surface. Structural analysis of the variant HEAT repeats in AlkD provides a rationale for how this protein scaffolding motif has been modified to bind DNA. We report 7mG excision and DNA binding activities of AlkD mutants, along with a comparison of alkylpurine DNA glycosylase structures. Together, these data provide important insight into the requirements for alkylation repair within DNA and suggest that AlkD utilizes a novel strategy to manipulate DNA in its search for alkylpurine bases.

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 (Delta84hUNG), 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.

Prolylproline unit in model peptides and in fragments from databases

The prolylproline sequence unit is found in several naturally occurring linear and cyclic peptides with immunosuppressive and toxic activity. Furthermore, Pro-Pro units are abundant in collagen, in ligand motifs binding to SH3 or WW domains, as well as in vital enzymes such as DNA glycosylase and thrombin. In all these sequence units a special role is dedicated to conformation in order to successfully fulfill the appropriate biological function. Therefore, a detailed analysis of the basic conformational properties of Pro-Pro is expected to reveal the versatile structural role of this sequence. PCM (polarizable continuum model) calculations on the basis of ab initio and density functional theory investigations using the model peptide HCO-L-Pro-L-Pro-NH2 are presented. Cis-trans isomerism, backbone conformation and ring puckering are studied. A systematic comparison is made to experimental data gained on L-prolyl-L-proline sequence units retrieved from the Protein Data Bank as well as from the Cambridge Structural Database. PCM data are in good agreement with high-resolution X-ray crystallography. Population data derived from energy calculations and those gained directly from statistics predict that 87% of the Pro-Pro sequence units adopt elongated structures, while 13% form beta-turns. Both approaches prefer the same 6 out of the 36 ideally possible backbone folds. Polyproline II unit (t epsilonL t epsilonL), other elongated structures (c epsilonL t epsilonL, t epsilonL t alphaL and t epsilonL t gammaL), type VIa (t epsilonL c alphaL) and type I or III beta-turns (t alphaL t alphaL) altogether describe 96% of the prolylproline sequences. In disordered proteins or domains, Pro-Pro sequence units may sample the various conformers and contribute to the segmental motions.

Electrostatic interactions play an essential role in DNA repair and cold-adaptation of uracil DNA glycosylase

Life has adapted to most environments on earth, including low and high temperature niches. The increased catalytic efficiency and thermoliability observed for enzymes from organisms living in constantly cold regions when compared to their mesophilic and thermophilic cousins are poorly understood at the molecular level. Uracil DNA glycosylase (UNG) from cod (cUNG) catalyzes removal of uracil from DNA with an increased k(cat) and reduced K(m) relative to its warm-active human (hUNG) counterpart. Specific issues related to DNA repair and substrate binding/recognition (K(m)) are here investigated by continuum electrostatics calculations, MD simulations and free energy calculations. Continuum electrostatic calculations reveal that cUNG has surface potentials that are more complementary to the DNA potential at and around the catalytic site when compared to hUNG, indicating improved substrate binding. Comparative MD simulations combined with free energy calculations using the molecular mechanics-Poisson Boltzmann surface area (MM-PBSA) method show that large opposing energies are involved when forming the enzyme-substrate complexes. Furthermore, the binding free energies obtained reveal that the Michaelis-Menten complex is more stable for cUNG, primarily due to enhanced electrostatic properties, suggesting that energetic fine-tuning of electrostatics can be utilized for enzymatic temperature adaptation. Energy decomposition pinpoints the residual determinants responsible for this adaptation.

Eukaryotic nucleotide excision repair: from understanding mechanisms to influencing biology

Repair of bulky DNA adducts by the nucleotide excision repair (NER) pathway is one of the more versatile DNA repair pathways for the removal of DNA lesions. There are two subsets of the NER pathway, global genomic-NER (GG-NER) and transcription-coupled NER (TC-NER), which differ only in the step involving recognition of the DNA lesion. Following recognition of the damage, the sub-pathways then converge for the incision/excision steps and subsequent gap filling and ligation steps. This review will focus on the GGR sub-pathway of NER, while the TCR sub-pathway will be covered in another article in this issue. The ability of the NER pathway to repair a wide array of adducts stems, in part, from the mechanisms involved in the initial recognition step of the damaged DNA and results in NER impacting an equally wide array of human physiological responses and events. In this review, the impact of NER on carcinogenesis, neurological function, sensitivity to environmental factors and sensitivity to cancer therapeutics will be discussed. The knowledge generated in our understanding of the NER pathway over the past 40 years has resulted from advances in the fields of animal model systems, mammalian genetics and in vitro biochemistry, as well as from reconstitution studies and structural analyses of the proteins and enzymes that participate in this pathway. Each of these avenues of research has contributed significantly to our understanding of how the NER pathway works and how alterations in NER activity, both positive and negative, influence human biology.

Dependence of antibody gene diversification on uracil excision

Activation-induced deaminase (AID) catalyses deamination of deoxycytidine to deoxyuridine within immunoglobulin loci, triggering pathways of antibody diversification that are largely dependent on uracil-DNA glycosylase (uracil-N-glycolase [UNG]). Surprisingly efficient class switch recombination is restored to ung(-/-) B cells through retroviral delivery of active-site mutants of UNG, stimulating discussion about the need for UNG's uracil-excision activity. In this study, however, we find that even with the overexpression achieved through retroviral delivery, switching is only mediated by UNG mutants that retain detectable excision activity, with this switching being especially dependent on MSH2. In contrast to their potentiation of switching, low-activity UNGs are relatively ineffective in restoring transversion mutations at C:G pairs during hypermutation, or in restoring gene conversion in stably transfected DT40 cells. The results indicate that UNG does, indeed, act through uracil excision, but suggest that, in the presence of MSH2, efficient switch recombination requires base excision at only a small proportion of the AID-generated uracils in the S region. Interestingly, enforced expression of thymine-DNA glycosylase (which can excise U from U:G mispairs) does not (unlike enforced UNG or SMUG1 expression) potentiate efficient switching, which is consistent with a need either for specific recruitment of the uracil-excision enzyme or for it to be active on single-stranded DNA.

Cell cycle-specific UNG2 phosphorylations regulate protein turnover, activity and association with RPA

Human UNG2 is a multifunctional glycosylase that removes uracil near replication forks and in non-replicating DNA, and is important for affinity maturation of antibodies in B cells. How these diverse functions are regulated remains obscure. Here, we report three new phosphoforms of the non-catalytic domain that confer distinct functional properties to UNG2. These are apparently generated by cyclin-dependent kinases through stepwise phosphorylation of S23, T60 and S64 in the cell cycle. Phosphorylation of S23 in late G1/early S confers increased association with replication protein A (RPA) and replicating chromatin and markedly increases the catalytic turnover of UNG2. Conversely, progressive phosphorylation of T60 and S64 throughout S phase mediates reduced binding to RPA and flag UNG2 for breakdown in G2 by forming a cyclin E/c-myc-like phosphodegron. The enhanced catalytic turnover of UNG2 p-S23 likely optimises the protein to excise uracil along with rapidly moving replication forks. Our findings may aid further studies of how UNG2 initiates mutagenic rather than repair processing of activation-induced deaminase-generated uracil at Ig loci in B cells.

Crystal structure of family 5 uracil-DNA glycosylase bound to DNA

Uracil-DNA glycosylase (UDG) removes uracil generated by the deamination of cytosine or misincorporation of deoxyuridine monophosphate. Within the UDG superfamily, a fifth UDG family lacks a polar residue in the active-site motif, which mediates the hydrolysis of the glycosidic bond by activation of a water molecule in UDG families 1-4. We have determined the crystal structure of a novel family 5 UDG from Thermus thermophilus HB8 complexed with DNA containing an abasic site. The active-site structure suggests this enzyme uses both steric force and water activation for its excision reaction. A conserved asparagine residue acts as a ligand to the catalytic water molecule. The structure also implies that another water molecule acts as a barrier during substrate recognition. Based on no significant open-closed conformational change upon binding to DNA, we propose a "slide-in" mechanism for initial damage recognition.

Crystal structure of vaccinia virus uracil-DNA glycosylase reveals dimeric assembly

Background

Uracil-DNA glycosylases (UDGs) catalyze excision of uracil from DNA. Vaccinia virus, which is the prototype of poxviruses, encodes a UDG (vvUDG) that is significantly different from the UDGs of other organisms in primary, secondary and tertiary structure and characteristic motifs. It adopted a novel catalysis-independent role in DNA replication that involves interaction with a viral protein, A20, to form the processivity factor. UDG:A20 association is essential for assembling of the processive DNA polymerase complex. The structure of the protein must have provisions for such interactions with A20. This paper provides the first glimpse into the structure of a poxvirus UDG.

Results

Results of dynamic light scattering experiments and native size exclusion chromatography showed that vvUDG is a dimer in solution. The dimeric assembly is also maintained in two crystal forms. The core of vvUDG is reasonably well conserved but the structure contains one additional β-sheet at each terminus. A glycerol molecule is found in the active site of the enzyme in both crystal forms. Interaction of this glycerol molecule with the protein possibly mimics the enzyme-substrate (uracil) interactions.

Conclusion

The crystal structures reveal several distinctive features of vvUDG. The new structural features may have evolved for adopting novel functions in the replication machinery of poxviruses. The mode of interaction between the subunits in the dimers suggests a possible model for binding to its partner and the nature of the processivity factor in the polymerase complex.

Comparative unfolding studies of psychrophilic and mesophilic uracil DNA glycosylase: MD simulations show reduced thermal stability of the cold-adapted enzyme

Uracil DNA glycosylase (UDG) is a DNA repair enzyme involved in the base excision repair (BER) pathway, removing misincorporated uracil from the DNA strand. The native and mutant forms of Atlantic cod and human UDG have previously been characterized in terms of kinetic and thermodynamic properties as well as the determination of several crystal structures. This data shows that the cold-adapted enzyme is more catalytically efficient but at the same time less resistant to heat compared to its warm-active counterpart. In this study, the structure-function relationship is further explored by means of comparative molecular dynamics (MD) simulations at three different temperatures (375, 400 and 425K) to gain a deeper insight into the structural features responsible for the reduced thermostability of the cold-active enzyme. The simulations show that there are distinct structural differences in the unfolding pathway between the two homologues, particularly evident in the N- and C-terminals. Distortion of the mesophilic enzyme is initiated simultaneously in the N- and C-terminal, while the C-terminal part plays a key role for the stability of the psychrophilic enzyme. The simulations also show that at certain temperatures the cold-adapted enzyme unfolds faster than the warm-active homologues in accordance with the lower thermal stability found experimentally.

Uracil-DNA glycosylases SMUG1 and UNG2 coordinate the initial steps of base excision repair by distinct mechanisms

DNA glycosylases UNG and SMUG1 excise uracil from DNA and belong to the same protein superfamily. Vertebrates contain both SMUG1 and UNG, but their distinct roles in base excision repair (BER) of deaminated cytosine (U:G) are still not fully defined. Here we have examined the ability of human SMUG1 and UNG2 (nuclear UNG) to initiate and coordinate repair of U:G mismatches. When expressed in Escherichia coli cells, human UNG2 initiates complete repair of deaminated cytosine, while SMUG1 inhibits cell proliferation. In vitro, we show that SMUG1 binds tightly to AP-sites and inhibits AP-site cleavage by AP-endonucleases. Furthermore, a specific motif important for the AP-site product binding has been identified. Mutations in this motif increase catalytic turnover due to reduced product binding. In contrast, the highly efficient UNG2 lacks product-binding capacity and stimulates AP-site cleavage by APE1, facilitating the two first steps in BER. In summary, this work reveals that SMUG1 and UNG2 coordinate the initial steps of BER by distinct mechanisms. UNG2 is apparently adapted to rapid and highly coordinated repair of uracil (U:G and U:A) in replicating DNA, while the less efficient SMUG1 may be more important in repair of deaminated cytosine (U:G) in non-replicating chromatin.

A rapid reaction analysis of uracil DNA glycosylase indicates an active mechanism of base flipping

Uracil DNA glycosylase (UNG) is the primary enzyme for the removal of uracil from the genome of many organisms. A key question is how the enzyme is able to scan large quantities of DNA in search of aberrant uracil residues. Central to this is the mechanism by which it flips the target nucleotide out of the DNA helix and into the enzyme-active site. Both active and passive mechanisms have been proposed. Here, we report a rapid kinetic analysis using two fluorescent chromophores to temporally resolve DNA binding and base-flipping with DNA substrates of different sequences. This study demonstrates the importance of the protein–DNA interface in the search process and indicates an active mechanism by which UNG glycosylase searches for uracil residues.

Discovery of activation-induced cytidine deaminase, the engraver of antibody memory

Discovery of activation-induced cytidine deaminase (AID) paved a new path to unite two genetic alterations induced by antigen stimulation; class switch recombination (CSR) and somatic hypermutation (SHM). AID is now established to cleave specific target DNA and to serve as engraver of these genetic alterations. AID of a 198-residue protein has four important domains: nuclear localization signal and SHM-specific region at the N-terminus; the alpha-helical segment (residue 47-54) responsible for dimerization; catalytic domain (residues 56-94) shared by all the other cytidine deaminase family members; and nuclear export signal overlapping with class switch-specific domain at the C-terminus. Two alternative models have been proposed for the mode of AID action; whether AID directly attacks DNA or indirectly through RNA editing. Lines of evidence supporting RNA editing hypothesis include homology in various aspects with APOBEC1, a bona fide RNA editing enzyme as well as requirement of de novo protein synthesis for DNA cleavage by AID in CSR and SHM. This chapter critically evaluates DNA deamination hypothesis and describes evidence to indicate UNG is involved not in DNA cleavage but in DNA repair of CSR. In addition, UNG appears to have a noncanonical function through interaction with an HIV Vpr-like protein at the WXXF motif. Taken together, RNA editing hypothesis is gaining the ground.

Overexpression, purification, crystallization and preliminary X-ray analysis of uracil N-glycosylase from Mycobacterium tuberculosis in complex with a proteinaceous inhibitor

Uracil N-glycosylase is an enzyme which initiates the pathway of uracil-excision repair of DNA. The enzyme from Mycobacterium tuberculosis was co-expressed with a proteinaceous inhibitor from Bacillus subtilis phage and was crystallized in monoclinic space group C2, with unit-cell parameters a = 201.14, b = 64.27, c = 203.68 A, beta = 109.7 degrees. X-ray data from the crystal have been collected for structure analysis.

Switching base preferences of mismatch cleavage in endonuclease V: an improved method for scanning point mutations

Endonuclease V (endo V) recognizes a broad range of aberrations in DNA such as deaminated bases or mismatches. It nicks DNA at the second phosphodiester bond 3′ to a deaminated base or a mismatch. Endonuclease V obtained from Thermotoga maritima preferentially cleaves purine mismatches in certain sequence context. Endonuclease V has been combined with a high-fidelity DNA ligase to develop an enzymatic method for mutation scanning. A biochemical screening of site-directed mutants identified mutants in motifs III and IV that altered the base preferences in mismatch cleavage. Most profoundly, a single alanine substitution at Y80 position switched the enzyme to essentially a C-specific mismatch endonuclease, which recognized and cleaved A/C, C/A, T/C, C/T and even the previously refractory C/C mismatches. Y80A can also detect the G13D mutation in K-ras oncogene, an A/C mismatch embedded in a G/C rich sequence context that was previously inaccessible using the wild-type endo V. This investigation offers insights on base recognition and active site organization. Protein engineering in endo V may translate into better tools in mutation recognition and cancer mutation scanning.

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.

DNA mimicry by proteins

It has been discovered recently, via structural and biophysical analyses, that proteins can mimic DNA structures in order to inhibit proteins that would normally bind to DNA. Mimicry of the phosphate backbone of DNA, the hydrogen-bonding properties of the nucleotide bases and the bending and twisting of the DNA double helix are all present in the mimics discovered to date. These mimics target a range of proteins and enzymes such as DNA restriction enzymes, DNA repair enzymes, DNA gyrase and nucleosomal and nucleoid-associated proteins. The unusual properties of these protein DNA mimics may provide a foundation for the design of targeted inhibitors of DNA-binding proteins.

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.

The Crystal Structure of Mismatch-specific Uracil-DNA Glycosylase (MUG) from Deinococcus radiodurans Reveals a Novel Catalytic Residue and Broad Substrate Specificity

Deinococcus radiodurans is extremely resistant to the effects of ionizing radiation. The source of the radiation resistance is not known, but an expansion of specific protein families related to stress response and damage control has been observed. DNA repair enzymes are among the expanded protein families in D. radiodurans, and genes encoding five different uracil-DNA glycosylases are identified in the genome. Here we report the three-dimensional structure of the mismatch-specific uracil-DNA glycosylase (MUG) from D. radiodurans (drMUG) to a resolution of 1.75 angstroms. Structural analyses suggest that drMUG possesses a novel catalytic residue, Asp-93. Activity measurements show that drMUG has a modified and broadened substrate specificity compared with Escherichia coli MUG. The importance of Asp-93 for activity was confirmed by structural analysis and abolished activity for the mutant drMUGD93A. Two other microorganisms, Bradyrhizobium japonicum and Rhodopseudomonas palustris, possess genes that encode MUGs with the highest sequence identity to drMUG among all of the bacterial MUGs examined. A phylogenetic analysis indicates that these three MUGs form a new MUG/thymidine-DNA glycosylase subfamily, here called the MUG2 family. We suggest that the novel catalytic residue (Asp-93) has evolved to provide drMUG with broad substrate specificity to increase the DNA repair repertoire of D. radiodurans.

Uracil-directed ligand tethering: an efficient strategy for uracil DNA glycosylase (UNG) inhibitor development

Uracil DNA glycosylase (UNG) is an important DNA repair enzyme that recognizes and excises uracil bases in DNA using an extrahelical recognition mechanism. It is emerging as a desirable target for small-molecule inhibitors given its key role in a wide range of biological processes including the generation of antibody diversity, DNA replication in a number of viruses, and the formation of DNA strand breaks during anticancer drug therapy. To accelerate the discovery of inhibitors of UNG we have developed a uracil-directed ligand tethering strategy. In this efficient approach, a uracil aldehyde ligand is tethered via alkyloxyamine linker chemistry to a diverse array of aldehyde binding elements. Thus, the mechanism of extrahelical recognition of the uracil ligand is exploited to target the UNG active site, and alkyloxyamine linker tethering is used to randomly explore peripheral binding pockets. Since no compound purification is required, this approach rapidly identified the first small-molecule inhibitors of human UNG with micromolar to submicromolar binding affinities. In a surprising result, these uracil-based ligands are found not only to bind to the active site but also to bind to a second uncompetitive site. The weaker uncompetitive site suggests the existence of a transient binding site for uracil during the multistep extrahelical recognition mechanism. This very general inhibitor design strategy can be easily adapted to target other enzymes that recognize nucleobases, including other DNA repair enzymes that recognize other types of extrahelical DNA bases.

DNA base damage recognition and removal: new twists and grooves

The discoveries of nucleotide excision repair and transcription-coupled repair led by Phil Hanawalt and a few colleagues sparked a dramatic evolution in our understanding of DNA and molecular biology by revealing the intriguing systems of DNA repair essential to life. In fact, modifications of the cut-and-patch principles identified by Phil Hanawalt and colleagues underlie many of the common themes for the recognition and removal of damaged DNA bases outlined in this review. The emergence of these common themes and a unified understanding have been greatly aided from the direct visualizations of repair proteins and their interactions with damaged DNA by structural biology. These visualizations of DNA repair structures have complemented the increasing wealth of biochemical and genetic information on DNA base damage responses by revealing general themes for the recognition of damaged bases, such as sequence-independent DNA recognition motifs, minor groove reading heads for initial damage recognition, and nucleotide flipping from the major groove into active-site pockets for high specificity of base damage recognition and removal. We know that repair intermediates are as harmful as the initial damage itself, and that these intermediates are protected from one repair step to the next by the enzymes involved, such that pathway-specific handoffs must be efficiently coordinated. Here we focus on the structural biology of the repair enzymes and proteins that recognize specific base lesions and either initiate the base excision repair pathway or directly repair the damage in one step. This understanding of the molecular basis for DNA base integrity is fundamental to resolving key scientific, medical, and public health issues, including the evaluation of the risks from inherited repair protein mutations, environmental toxins, and medical procedures.

The DNA trackwalkers: principles of lesion search and recognition by DNA glycosylases

DNA glycosylases, the pivotal enzymes in base excision repair, are faced with the difficult task of recognizing their substrates in a large excess of unmodified DNA. We present here a kinetic analysis of DNA glycosylase substrate specificity, based on the probability of error. This novel approach to this subject explains many features of DNA surveillance and catalysis of lesion excision by DNA glycosylases. This approach also is applicable to the general issue of substrate specificity. We discuss determinants of substrate specificity in damaged DNA and in the enzyme, as well as methods by which these determinants can be identified.

B cells from hyper-IgM patients carrying UNG mutations lack ability to remove uracil from ssDNA and have elevated genomic uracil

The generation of high-affinity antibodies requires somatic hypermutation (SHM) and class switch recombination (CSR) at the immunoglobulin (Ig) locus. Both processes are triggered by activation-induced cytidine deaminase (AID) and require UNG-encoded uracil-DNA glycosylase. AID has been suggested to function as an mRNA editing deaminase or as a single-strand DNA deaminase. In the latter model, SHM may result from replicative incorporation of dAMP opposite U or from error-prone repair of U, whereas CSR may be triggered by strand breaks at abasic sites. Here, we demonstrate that extracts of UNG-proficient human B cell lines efficiently remove U from single-stranded DNA. In B cell lines from hyper-IgM patients carrying UNG mutations, the single-strand–specific uracil-DNA glycosylase, SMUG1, cannot complement this function. Moreover, the UNG mutations lead to increased accumulation of genomic uracil. One mutation results in an F251S substitution in the UNG catalytic domain. Although this UNG form was fully active and stable when expressed in Escherichia coli, it was mistargeted to mitochondria and degraded in mammalian cells. Our results may explain why SMUG1 cannot compensate the UNG2 deficiency in human B cells, and are fully consistent with the DNA deamination model that requires active nuclear UNG2. Based on our findings and recent information in the literature, we present an integrated model for the initiating steps in CSR.

Functionality of human thymine DNA glycosylase requires SUMO-regulated changes in protein conformation

BACKGROUND

Base excision repair initiated by human thymine-DNA glycosylase (TDG) results in the generation of abasic sites (AP sites) in DNA. TDG remains bound to this unstable repair intermediate, indicating that its transmission to the downstream-acting AP endonuclease is a coordinated process. Previously, we established that posttranslational modification of TDG with Small Ubiquitin-like MOdifiers (SUMOs) facilitates the dissociation of the DNA glycosylase from the product AP site, but the underlying molecular mechanism remained unclear.

RESULTS

We now show that upon DNA interaction, TDG undergoes a dramatic conformational change, which involves its flexible N-terminal domain and accounts for the nonspecific DNA binding ability of the enzyme. This function is required for efficient processing of the G.T mismatch but then cooperates with the specific DNA contacts established in the active site pocket of TDG to prevent its dissociation from the product AP site after base release. SUMO1 conjugation to the C-terminal K330 of TDG modulates the DNA binding function of the N terminus to induce dissociation of the glycosylase from the AP site while it leaves the catalytic properties of base release in the active site pocket of the enzyme unaffected.

CONCLUSION

Our data provide insight into the molecular mechanism of SUMO modification mediated modulation of enzymatic properties of TDG. A conformational change, involving the N-terminal domain of TDG, provides unspecific DNA interactions that facilitate processing of a wider spectrum of substrates at the expense of enzymatic turnover. SUMOylation then reverses this structural change in the product bound TDG.

Crystal structure of thymine DNA glycosylase conjugated to SUMO-1

Members of the small ubiquitin-like modifier (SUMO) family can be covalently attached to the lysine residue of a target protein through an enzymatic pathway similar to that used in ubiquitin conjugation, and are involved in various cellular events that do not rely on degradative signalling via the proteasome or lysosome. However, little is known about the molecular mechanisms of SUMO-modification-induced protein functional transfer. During DNA mismatch repair, SUMO conjugation of the uracil/thymine DNA glycosylase TDG promotes the release of TDG from the abasic (AP) site created after base excision, and coordinates its transfer to AP endonuclease 1, which catalyses the next step in the repair pathway. Here we report the crystal structure of the central region of human TDG conjugated to SUMO-1 at 2.1 A resolution. The structure reveals a helix protruding from the protein surface, which presumably interferes with the product DNA and thus promotes the dissociation of TDG from the DNA molecule. This helix is formed by covalent and non-covalent contacts between TDG and SUMO-1. The non-covalent contacts are also essential for release from the product DNA, as verified by mutagenesis.

The contested role of uracil DNA glycosylase in immunoglobulin gene diversification

Class switch recombination (CSR) and somatic hypermutation (SHM) of immunoglobulin (Ig) genes are initiated by the activation-induced cytosine deaminase AID. The resulting uracils in Ig genes were believed to be removed by the uracil glycosylase (UNG) and the resulting abasic sites treated in an error-prone fashion, creating breaks in the Ig switch regions and mutations in the variable regions. A recent report suggests that UNG does not act as a glycosylase in CSR and SHM but rather has unknown activity subsequent to DNA breaks that were created by other mechanisms.

Increased Flexibility as a Strategy for Cold Adaptation

Uracil DNA glycosylase (UDG) is a DNA repair enzyme in the base excision repair pathway and removes uracil from the DNA strand. Atlantic cod UDG (cUDG), which is a cold-adapted enzyme, has been found to be up to 10 times more catalytically active in the temperature range 15-37 degrees C as compared with the warm-active human counterpart. The increased catalytic activity of cold-adapted enzymes as compared with their mesophilic homologues are partly believed to be caused by an increase in the structural flexibility. However, no direct experimental evidence supports the proposal of increased flexibility of cold-adapted enzymes. We have used molecular dynamics simulations to gain insight into the structural flexibility of UDG. The results from these simulations show that an important loop involved in DNA recognition (the Leu(272) loop) is the most flexible part of the cUDG structure and that the human counterpart has much lower flexibility in the Leu(272) loop. The flexibility in this loop correlates well with the experimental k(cat)/K(m) values. Thus, the data presented here add strong support to the idea that flexibility plays a central role in adaptation to cold environments.

HIV-1-associated uracil DNA glycosylase activity controls dUTP misincorporation in viral DNA and is essential to the HIV-1 life cycle

Uracilation of DNA represents a constant threat to the survival of many organisms including viruses. Uracil may appear in DNA either by cytosine deamination or by misincorporation of dUTP. The HIV-1-encoded Vif protein controls cytosine deamination by preventing the incorporation of host-derived APOBEC3G cytidine deaminase into viral particles. Here, we show that the host-derived uracil DNA glycosylase UNG2 enzyme, which is recruited into viral particles by the HIV-1-encoded integrase domain, is essential to the viral life cycle. We demonstrate that virion-associated UNG2 catalytic activity can be replaced by the packaging of heterologous dUTPase into virion, indicating that UNG2 acts to counteract dUTP misincorporation in the viral genome. Therefore, HIV-1 prevents incorporation of dUTP in viral cDNA by UNG2-mediated uracil excision followed by a dNTP-dependent, reverse transcriptase-mediated endonucleolytic cleavage and finally by strand-displacement polymerization. Our findings indicate that pharmacologic strategies aimed toward blocking UNG2 packaging should be explored as potential HIV/AIDS therapeutics.

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.

DNA glycosylase recognition and catalysis

DNA glycosylases are the enzymes responsible for recognizing base lesions in the genome and initiating base excision DNA repair. Recent structural and biochemical results have provided novel insights into DNA damage recognition and repair. The basis of the recognition of the oxidative lesion 8-oxoguanine by two structurally unrelated DNA glycosylases is now understood and has been revealed to involve surprisingly similar strategies. Work on MutM (Fpg) has produced structures representing three discrete reaction steps. The NMR structure of 3-methyladenine glycosylase I revealed its place among the structural families of DNA glycosylases and the X-ray structure of SMUG1 likewise confirmed that this protein is a member of the uracil DNA glycosylase superfamily. A novel disulfide cross-linking strategy was used to obtain the long-anticipated structure of MutY bound to DNA containing an A*oxoG mispair.

Mutational analysis of the damage-recognition and catalytic mechanism of human SMUG1 DNA glycosylase

Single-strand selective monofunctional uracil-DNA glycosylase (SMUG1), previously thought to be a backup enzyme for uracil-DNA glycosylase, has recently been shown to excise 5-hydroxyuracil (hoU), 5-hydroxymethyluracil (hmU) and 5-formyluracil (fU) bearing an oxidized group at ring C5 as well as an uracil. In the present study, we used site-directed mutagenesis to construct a series of mutants of human SMUG1 (hSMUG1), and tested their activity for uracil, hoU, hmU, fU and other bases to elucidate the catalytic and damage-recognition mechanism of hSMUG1. The functional analysis of the mutants, together with the homology modeling of the hSMUG1 structure based on that determined recently for Xenopus laevis SMUG1, revealed the crucial residues for the rupture of the N-glycosidic bond (Asn85 and His239), discrimination of pyrimidine rings through pi-pi stacking to the base (Phe98) and specific hydrogen bonds to the Watson-Crick face of the base (Asn163) and exquisite recognition of the C5 substituent through water-bridged (uracil) or direct (hoU, hmU and fU) hydrogen bonds (Gly87-Met91). Integration of the present results and the structural data elucidates how hSMUG1 accepts uracil, hoU, hmU and fU as substrates, but not other oxidized pyrimidines such as 5-hydroxycytosine, 5-formylcytosine and thymine glycol, and intact pyrimidines such as thymine and cytosine.

Contribution of a conserved phenylalanine residue to the activity of Escherichia coli uracil DNA glycosylase

Uracil DNA glycosylase (UDG) excises uracil from DNA to initiate repair of this lesion. This important DNA repair enzyme is conserved in viruses, bacteria, and eukaryotes. One residue that is conserved among all the members of the UDG family is a phenylalanine that stacks with uracil when it is flipped out of the DNA helix into the enzyme active site. To determine what contribution this conserved Phe residue makes to the activity of UDG, Phe-77 in the Escherichia coli enzyme was mutated to three different amino acid residues, alanine (UDG-F77A), asparagine (UDG-F77N), and tyrosine (UDG-F77Y). The effects of these mutations were measured on the steady-state and pre-steady-state kinetics of uracil excision in addition to enzyme.DNA binding kinetics. The overall excision activity of each of the mutants was reduced relative to the wild-type enzyme; however, each mutation gave rise to a different kinetic phenotype with different effects on substrate binding and catalysis. The excision activity of UDG-F77N was the most severely compromised, but this enzyme still bound to uracil-containing DNA at about the same rate as wild-type UDG. In contrast, the decrease in the excision activity of UDG-F77A is likely to reflect a greater reduction in uracil-DNA binding than in the catalytic step. Overall, the effects of the mutations on catalysis are best correlated with the polarity of the substituted residue such that an increase in polarity decreases the efficiency of uracil excision.

Molecular analysis of a large cohort of patients with the hyper immunoglobulin M (IgM) syndrome

The hyper immunoglobulin M (IgM) syndrome (HIGM), characterized by recurrent infections, low serum IgG and IgA, normal or elevated IgM, and defective class switch recombination and somatic hypermutation, is a heterogenous disorder with at least 5 distinct molecular defects, including mutations of the genes coding for the CD40 ligand (CD40L) and IKK-gamma (NEMO) genes, both X-linked; and mutations of CD40, activation-induced cytidine deaminase (AICDA), and uracil-DNA glycosylase (UNG), associated with autosomal recessive HIGM syndromes. To investigate the molecular basis of HIGM, we determined the prevalence of mutations affecting these 5 genes in a cohort of 140 patients (130 males and 10 females). Those patients without a molecular diagnosis were subsequently evaluated for mutations of the following genes: inducible CO-stimulator molecule (ICOS), ICOS ligand (ICOSL), and if male, Bruton tyrosine kinase (Btk) and SLAM-associated protein (SAP/SH2D1A). We found mutations of CD40L in 98 males; AICDA in 4 patients (3 males, 1 female); UNG in one adult male; and Btk in 3 boys. Of the remaining 25 males, one infant with hypohidrotic ectodermal dysplasia had a mutation of NEMO. None of the remaining 33 patients (24 males/9 females) had mutations affecting CD40, ICOS, ICOSL, or SH2D1, and are best classified as common variable immune deficiency (CVID), although other genes, including some not yet identified, may be responsible.