An iron-sulfur cluster loop motif in the Archaeoglobus fulgidus uracil-DNA glycosylase mediates efficient uracil recognition and removal

The family 4 uracil-DNA glycosylase from the hyperthermophilic organism Archaeoglobus fulgidus (AFUDG) is responsible for the removal of uracil in DNA as the first step in the base excision repair (BER) pathway. AFUDG contains a large solvent-exposed peptide region containing an α helix and loop anchored on each end via ligation of two cysteine thiolates to a [4Fe-4S](2+) cluster. We propose that this region plays a similar role in DNA damage recognition as a smaller iron-sulfur cluster loop (FCL) motif in the structurally unrelated BER glycosylases MutY and Endonuclease III and therefore refer to this region as the "pseudo-FCL" in AFUDG. In order to evaluate the importance of this region, three positively charged residues (Arg 86, Arg 91, Lys 100) and the anchoring Cys residues (Cys 85, Cys 101) within this motif were replaced with alanine, and the effects of these replacements on uracil excision in single- and double-stranded DNA were evaluated. These results show that this region participates and allows for efficient recognition and excision of uracil within DNA. Notably, R86A AFUDG exhibited reduced activity for uracil removal only within double-stranded DNA, suggesting an importance in duplex disruption and extrusion of the base as part of the excision process. In addition, mutation of the [4Fe-4S](2+) cluster cysteine ligands at the ends of the pseudo-FCL to alanine reduced the uracil excision efficiency, suggesting the importance of anchoring the loop via coordination to the cluster. In contrast, K100A AFUDG exhibited enhanced uracil excision activity, providing evidence for the importance of the loop conformation and flexibility. Taken together, the results herein provide evidence that the pseudo-FCL motif is involved in DNA binding and catalysis, particularly in duplex DNA contexts. This work underscores the requirement of an ensemble of interactions, both distant and in proximity to the damaged site, for accurate and efficient uracil excision.     

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.     

Human endonuclease III acts preferentially on DNA damage opposite guanine residues in DNA

The human endonuclease III homologue (hNTH1) removes premutagenic cytosine damage from DNA. This includes 5-hydroxycytosine, which has increased potential for pairing with adenine, resulting in C --> T transition mutations. Here we report that hNTH1 acts on both 5-hydroxycytosine and abasic sites preferentially when these are situated opposite guanines in DNA. Discrimination against other opposite bases is strongly dependent on the presence of magnesium. To further elucidate this effect, we have introduced mutations in the helix-hairpin-helix domain of hNTH1 (K212S, P211R, +G212, and DeltaP211), and measured the kinetics of 5-hydroxycytosine removal of the mutants relative to wild type. The K212S and DeltaP211 (truncated hairpin) mutant proteins were both inactive, whereas the extended hairpin in the +G212 mutant diminished recognition and binding to 5-hydroxycytosine-containing DNA. The P211R mutant resembled native hNTH1, except for decreased specificity of binding. Despite the altered kinetic parameters, the active mutants retained the ability to discriminate against the pairing base, indicating that enzyme interactions with the opposite strand relies on other domains than the active site helix-hairpin-helix motif.     

Crystal structure of bacteriophage T4 5' nuclease in complex with a branched DNA reveals how flap endonuclease-1 family nucleases bind their substrates

Bacteriophage T4 RNase H, a flap endonuclease-1 family nuclease, removes RNA primers from lagging strand fragments. It has both 5' nuclease and flap endonuclease activities. Our previous structure of native T4 RNase H (PDB code 1TFR) revealed an active site composed of highly conserved Asp residues and two bound hydrated magnesium ions. Here, we report the crystal structure of T4 RNase H in complex with a fork DNA substrate bound in its active site. This is the first structure of a flap endonuclease-1 family protein with its complete branched substrate. The fork duplex interacts with an extended loop of the helix-hairpin-helix motif class 2. The 5' arm crosses over the active site, extending below the bridge (helical arch) region. Cleavage assays of this DNA substrate identify a primary cut site 7-bases in from the 5' arm. The scissile phosphate, the first bond in the duplex DNA adjacent to the 5' arm, lies above a magnesium binding site. The less ordered 3' arm reaches toward the C and N termini of the enzyme, which are binding sites for T4 32 protein and T4 45 clamp, respectively. In the crystal structure, the scissile bond is located within the double-stranded DNA, between the first two duplex nucleotides next to the 5' arm, and lies above a magnesium binding site. This complex provides important insight into substrate recognition and specificity of the flap endonuclease-1 enzymes.     

Conformational Dynamics of Damage Processing by Human DNA Glycosylase NEIL1

Endonuclease VIII-like protein 1 (NEIL1) is a DNA repair enzyme found in higher eukaryotes, including humans. It belongs to the helix–two turn–helix (H2TH) structural superfamily together with Escherichia coli formamidopyrimidine–DNA glycosylase (Fpg) and endonuclease VIII (Nei), and removes a variety of oxidized purine and pyrimidine bases from DNA. Structural, modeling and kinetic studies have established that the bacterial H2TH superfamily enzymes proceed through several conformational intermediates while recognizing and removing their cognate lesions. Here we apply stopped-flow kinetics with detection of intrinsic Trp fluorescence and Förster resonance energy transfer fluorescence to follow the conformational dynamics of human NEIL1 and DNA when the enzyme interacts with undamaged DNA, or DNA containing cleavable or non-cleavable abasic sites, or dihydrouracil lesions. NEIL1 processed a natural abasic site and a damaged base in DNA equally well but showed an additional fluorescently discernible step when DHU was present, likely reflecting additional rearrangements during base eversion into the enzyme's active site. With undamaged DNA and DNA containing a non-cleavable abasic site analog, (3-hydroxytetrahydrofuran-2-yl)methyl phosphate, NEIL1 was diverted to a non-productive DNA conformation early in the reaction. Our results support the view of NEIL1 as an enzyme that actively destabilizes damaged DNA and uses multiple checkpoints along the reaction coordinate to drive substrate lesions into the active site while rejecting normal bases and non-substrate lesions.     

The Saccharomyces cerevisiae homologues of endonuclease III from Escherichia coli, Ntg1 and Ntg2, are both required for efficient repair of spontaneous and induced oxidative DNA damage in yeast

Endonuclease III from Escherichia coli is the prototype of a ubiquitous DNA repair enzyme essential for the removal of oxidized pyrimidine base damage. The yeast genome project has revealed the presence of two genes in Saccharomyces cerevisiae, NTG1 and NTG2, encoding proteins with similarity to endonuclease III. Both contain the highly conserved helix-hairpin-helix motif, whereas only one (Ntg2) harbors the characteristic iron-sulfur cluster of the endonuclease III family. We have characterized these gene functions by mutant and enzyme analysis as well as by gene expression and intracellular localization studies. Targeted gene disruption of NTG1 and NTG2 produced mutants with greatly increased spontaneous and hydrogen peroxide-induced mutation frequency relative to the wild type, and the mutation response was further increased in the double mutant. Both enzymes were found to remove thymine glycol and 2, 6-diamino-4-hydroxy-5-N-methylformamidopyrimidine (faPy) residues from DNA with high efficiency. However, on UV-irradiated DNA, saturating concentrations of Ntg2 removed only half of the cytosine photoproducts released by Ntg1. Conversely, 5-hydroxycytosine was removed efficiently only by Ntg2. The enzymes appear to have different reaction modes, as judged from much higher affinity of Ntg2 for damaged DNA and more efficient borhydride trapping of Ntg1 to abasic sites in DNA despite limited DNA binding. Northern blot and promoter fusion analysis showed that NTG1 is inducible by cell exposure to DNA-damaging agents, whereas NTG2 is constitutively expressed. Ntg2 appears to be a nuclear enzyme, whereas Ntg1 was sorted both to the nucleus and to the mitochondria. We conclude that functions of both NTG1 and NTG2 are important for removal of oxidative DNA damage in yeast.     

Mechanism of action of a mammalian DNA repair endonuclease

The mechanism of action of a DNA repair endonuclease isolated from calf thymus was determined. The calf thymus endonuclease possesses a substrate specificity nearly identical with that of Escherichia coli endonuclease III following DNA damage by high doses of UV light, osmium tetroxide, and other oxidizing agents. The calf thymus enzyme incises damaged DNA at sites of pyrimidines. A cytosine photoproduct was found to be the primary monobasic UV adduct. The calf thymus endonuclease and E. coli endonuclease III were found to possess similar, but not identical, DNA incision mechanisms. The mechanism of action of the calf thymus endonuclease was deduced by analysis of the 3' and 5' termini of the enzyme-generated DNA scission products with DNA sequencing methodologies and HPLC analysis of the material released by the enzyme following DNA damage. The calf thymus endonuclease removes UV light and osmium tetroxide damaged bases via an N-glycosylase activity followed by a 3' apurinic/apyrimidinic (AP) endonuclease activity. The calf thymus endonuclease also possesses a novel 5' AP endonuclease activity not possessed by endonuclease III. The product of this three-step mechanism is a nucleoside-free site flanked by 3'-and 5'-terminal phosphate groups. These results indicate the conservation of both substrate specificity and mechanism of action in the enzymatic removal of oxidative base damage between prokaryotes and eukaryotes. We propose the name redoxy endonucleases for this group of enzymes.     

Hsc70 contacts helix III of the J domain from polyomavirus T antigens: addressing a dilemma in the chaperone hypothesis of how they release E2F from pRb

Hsc70's expected binding site on helix II of the J domain of T antigens appears to be blocked in its structure bound to tumor suppressor pRb. We used NMR to map where mammalian Hsc70 binds the J domain of murine polyomavirus T antigens (PyJ). The ATPase domain of Hsc70 unexpectedly has its biggest effects on the NMR peak positions of the C-terminal end of helix III of PyJ. The Hsc70 ATPase domain protects the C-terminal end of helix III of PyJ from an uncharged paramagnetic probe of chelated Gd(III), clearly suggesting the interface. Effects on the conserved HPD loop and helix II of PyJ are smaller. The NMR results are supported by a novel assay of Hsc70's ATP hydrolysis showing that mutations of surface residues in PyJ helix III impair PyJ-dependent stimulation of Hsc70 activity. Evolutionary trace analysis of J domains suggests that helix III usually may join helix II in contributing specificities for cognate hsp70s. Our novel evidence implicating helix III differs from evidence that Escherichia coli DnaK primarily affects helix II and the HPD loop of DnaJ. We find the pRb-binding fragment of E2F1 to be intrinsically unfolded and a good substrate for Hsc70 in vitro. This suggests that E2F1 could be a substrate for Hsc70 recruited by T antigen to an Rb family member. Importantly, our results strengthen the chaperone hypothesis for E2F release from an Rb family member by Hsc70 recruited by large T antigen. That is, it now appears that Hsc70 can freely access helix III and the HPD motif of large T antigen bound to an Rb family member.     

Structural characterization of viral ortholog of human DNA glycosylase NEIL1 bound to thymine glycol or 5-hydroxyuracil-containing DNA

Thymine glycol (Tg) and 5-hydroxyuracil (5-OHU) are common oxidized products of pyrimidines, which are recognized and cleaved by two DNA glycosylases of the base excision repair pathway, endonuclease III (Nth) and endonuclease VIII (Nei). Although there are several structures of Nei enzymes unliganded or bound to an abasic (apurinic or apyrimidinic) site, until now there was no structure of an Nei bound to a DNA lesion. Mimivirus Nei1 (MvNei1) is an ortholog of human NEIL1, which was previously crystallized bound to DNA containing an apurinic site (Imamura, K., Wallace, S. S., and Doublié, S. (2009) J. Biol. Chem. 284, 26174-26183). Here, we present two crystal structures of MvNei1 bound to two oxidized pyrimidines, Tg and 5-OHU. Both lesions are flipped out from the DNA helix. Tg is in the anti conformation, whereas 5-OHU adopts both anti and syn conformations in the glycosylase active site. Only two protein side chains (Glu-6 and Tyr-253) are within hydrogen-bonding contact with either damaged base, and mutating these residues did not markedly affect the glycosylase activity. This finding suggests that lesion recognition by Nei occurs before the damaged base flips into the glycosylase active site.     

Crystallographic structure of the amino terminal domain of yeast initiation factor 4A, a representative DEAD-box RNA helicase

The eukaryotic translation initiation factor 4A (elF4A) is a representative of the DEAD-box RNA helicase protein family. We have solved the crystallographic structure of the amino-terminal domain (residues 1-223) of yeast elF4A. The domain is built around a core scaffold, a parallel alpha-beta motif with five beta strands, that is found in other RNA and DNA helicases, as well as in the RecA protein. The amino acid sequence motifs that are conserved within the helicase family are localized to the beta strand-->alpha helix junctions within the core. The core of the amino terminal domain of elF4A is amplified with additional structural elements that differ from those of other helicases. The phosphate binding loop (the Walker A motif) is in an unusual closed conformation. The crystallographic structure reveals specific interactions between amino acid residues of the phosphate binding loop, the DEAD motif, and the SAT motif, whose alteration is known to impair coupling between the ATPase cycle and the RNA unwinding activity of elF4A.     

Novel DNA binding motifs in the DNA repair enzyme endonuclease III crystal structure.

The 1.85 A crystal structure of endonuclease III, combined with mutational analysis, suggests the structural basis for the DNA binding and catalytic activity of the enzyme. Helix-hairpin-helix (HhH) and [4Fe-4S] cluster loop (FCL) motifs, which we have named for their secondary structure, bracket the cleft separating the two alpha-helical domains of the enzyme. These two novel DNA binding motifs and the solvent-filled pocket in the cleft between them all lie within a positively charged and sequence-conserved surface region. Lys120 and Asp138, both shown by mutagenesis to be catalytically important, lie at the mouth of this pocket, suggesting that this pocket is part of the active site. The positions of the HhH motif and protruding FCL motif, which contains the DNA binding residue Lys191, can accommodate B-form DNA, with a flipped-out base bound within the active site pocket. The identification of HhH and FCL sequence patterns in other DNA binding proteins suggests that these motifs may be a recurrent structural theme for DNA binding proteins.     

The structure of the human ERCC1/XPF interaction domains reveals a complementary role for the two proteins in nucleotide excision repair

The human ERCC1/XPF complex is a structure-specific endonuclease with defined polarity that participates in multiple DNA repair pathways. We report the heterodimeric structure of the C-terminal domains of both proteins responsible for ERCC1/XPF complex formation. Both domains exhibit the double helix-hairpin-helix motif (HhH)2, and they are related by a pseudo-2-fold symmetry axis. In the XPF domain, the hairpin of the second motif is replaced by a short turn. The ERCC1 domain folds properly only in the presence of the XPF domain, which implies a role for XPF as a scaffold for the folding of ERCC1. The intersubunit interactions are largely hydrophobic in nature. NMR titration data show that only the ERCC1 domain of the ERCC1/XPF complex is involved in DNA binding. On the basis of these findings, we propose a model for the targeting of XPF nuclease via ERCC1-mediated interactions in the context of nucleotide excision repair.     

Structural details of ribonuclease H from Escherichia coli as refined to an atomic resolution.

The crystal structure of RNase H from Escherichia coli has been determined by the multiple isomorphous replacement method, and refined by the stereochemically restrained least-squares procedure to a crystallographic R-factor of 0.196 at 1.48 A resolution. In the final structure, the root-mean-square (r.m.s.) deviation for bond lengths is 0.017 A, and for angle distances 0.036 A. The structure is composed of a five-stranded beta-sheet and five alpha-helices, and reveals the details of hydrogen bonding, electrostatic and hydrophobic interactions between intra- and intermolecular residues. The refined structure allows an explanation of the particular interactions between the basic protrusion, consisting of helix alpha III and the following loop, and the remaining major domain. The beta-sheet, alpha II, alpha III and alpha IV form a central hydrophobic cleft that contains all six tryptophan residues, and presumably serves to fix the orientation of the basic protrusion. Two parallel adjacent helices, alpha I and alpha IV, are associated with a few triads of hydrophobic interactions, including many leucine residues, that are similar to the repeated leucine motif. The well-defined electron density map allows detailed discussion of amino acid residues likely to be involved in binding a DNA/RNA hybrid, and construction of a putative model of the enzyme complexed with a DNA/RNA hybrid oligomer. In this model, a protein region, from the Mg(2+)-binding site to the basic protrusion, covers roughly two turns of a DNA/RNA hybrid double helix. A segment (11-23) containing six glycine residues forms a long loop between the beta A and beta B strands. This loop, which protrudes into the solvent region, lies on the interface between the enzyme and a DNA/RNA hybrid in the model of the complex. The mean temperature factors of main-chain atoms show remarkably high values in helix alpha III that constitutes the basic protrusion, suggesting some correlation between its flexibility and the nucleic acid binding function. The Mg(2+)-binding site, surrounded by four invariant acidic residues, can now be described more precisely in conjunction with the catalytic activity. The arrangement of molecules within the crystal appears to be dominated by the cancelling out of a remarkably biased charge distribution on the molecular surface, which is derived in particular from the separation between the acidic Mg(2+)-binding site and the basic protrusion.     

Mismatch repair in methylated DNA. Structure and activity of the mismatch-specific thymine glycosylase domain of methyl-CpG-binding protein MBD4

MBD4 is a member of the methyl-CpG-binding protein family. It contains two DNA binding domains, an amino-proximal methyl-CpG binding domain (MBD) and a C-terminal mismatch-specific glycosylase domain. Limited in vitro proteolysis of mouse MBD4 yields two stable fragments: a 139-residue fragment including the MBD, and the other 155-residue fragment including the glycosylase domain. Here we show that the latter fragment is active as a glycosylase on a DNA duplex containing a G:T mismatch within a CpG sequence context. The crystal structure confirmed the C-terminal domain is a member of the helix-hairpin-helix DNA glycosylase superfamily. The MBD4 active site is situated in a cleft that likely orients and binds DNA. Modeling studies suggest the mismatched target nucleotide will be flipped out into the active site where candidate residues for catalysis and substrate specificity are present.     

X-ray and biochemical anatomy of an archaeal XPF/Rad1/Mus81 family nuclease: similarity between its endonuclease domain and restriction enzymes

The XPF/Rad1/Mus81-dependent nuclease family specifically cleaves branched structures generated during DNA repair, replication, and recombination, and is essential for maintaining genome stability. Here, we report the domain organization of an archaeal homolog (Hef) of this family and the X-ray crystal structure of the middle domain, with the nuclease activity. The nuclease domain architecture exhibits remarkable similarity to those of restriction endonucleases, including the correspondence of the GDX(n)ERKX(3)D signature motif in Hef to the PDX(n)(E/D)XK motif in restriction enzymes. This structural study also suggests that the XPF/Rad1/Mus81/ERCC1 proteins form a dimer through each interface of the nuclease domain and the helix-hairpin-helix domain. Simultaneous disruptions of both interfaces result in their dissociation into separate monomers, with strikingly reduced endonuclease activities.     

Repair of abasic sites in DNA

Repair of both normal and reduced AP sites is activated by AP endonuclease, which recognizes and cleaves a phosphodiester bond 5' to the AP site. For a short period of time an incised AP site is occupied by poly(ADP-ribose) polymerase and then DNA polymerase beta adds one nucleotide into the repair gap and simultaneously removes the 5'-sugar phosphate. Finally, the DNA ligase III/XRCC1 complex accomplishes repair by sealing disrupted DNA ends. However, long-patch BER pathway, which is involved in the removal of reduced abasic sites, requires further DNA synthesis resulting in strand displacement and the generation of a damage-containing flap that is later removed by the flap endonuclease. Strand-displacement DNA synthesis is accomplished by DNA polymerase delta/epsilon and DNA ligase I restores DNA integrity. DNA synthesis by DNA polymerase delta/epsilon is dependent on proliferating cell nuclear antigen, which also stimulates the DNA ligase I and flap endonuclease. These repair events are supported by multiple protein-protein interactions.     

Structural Insights into the Mechanism of Base Excision by MBD4

DNA glycosylases remove damaged or modified nucleobases by cleaving the N-glycosyl bond and the correct nucleotide is restored through subsequent base excision repair. In addition to excising threatening lesions, DNA glycosylases contribute to epigenetic regulation by mediating DNA demethylation and perform other important functions. However, the catalytic mechanism remains poorly defined for many glycosylases, including MBD4 (methyl-CpG binding domain IV), a member of the helix-hairpin-helix (HhH) superfamily. MBD4 excises thymine from G·T mispairs, suppressing mutations caused by deamination of 5-methylcytosine, and it removes uracil and modified uracils (e.g., 5-hydroxymethyluracil) mispaired with guanine. To investigate the mechanism of MBD4 we solved high-resolution structures of enzyme-DNA complexes at three stages of catalysis. Using a non-cleavable substrate analog, 2′-deoxy-pseudouridine, we determined the first structure of an enzyme-substrate complex for wild-type MBD4, which confirms interactions that mediate lesion recognition and suggests that a catalytic Asp, highly conserved in HhH enzymes, binds the putative nucleophilic water molecule and stabilizes the transition state. Observation that mutating the Asp (to Gly) reduces activity by 2700-fold indicates an important role in catalysis, but probably not one as the nucleophile in a double-displacement reaction, as previously suggested. Consistent with direct-displacement hydrolysis, a structure of the enzyme-product complex indicates a reaction leading to inversion of configuration. A structure with DNA containing 1-azadeoxyribose models a potential oxacarbenium-ion intermediate and suggests the Asp could facilitate migration of the electrophile towards the nucleophilic water. Finally, the structures provide detailed snapshots of the HhH motif, informing how these ubiquitous metal-binding elements mediate DNA binding.     

An evolutionary analysis of the helix-hairpin-helix superfamily of DNA repair glycosylases

The helix-hairpin-helix (HhH) superfamily of base excision repair DNA glycosylases is composed of multiple phylogenetically diverse enzymes that are capable of excising varying spectra of oxidatively and methyl-damaged bases. Although these DNA repair glycosylases have been widely studied through genetic, biochemical, and biophysical approaches, the evolutionary relationships of different HhH homologs and the extent to which they are conserved across phylogeny remain enigmatic. We provide an evolutionary framework for this pervasive and versatile superfamily of DNA glycosylases. Six HhH gene families (named AlkA: alkyladenine glycosylase; MpgII: N-methylpurine glycosylase II; MutY/Mig: A/G-specific adenine glycosylase/mismatch glycosylase; Nth: endonuclease III; OggI: 8-oxoguanine glycosylase I; and OggII: 8-oxoguanine glycosylase II) are identified through phylogenetic analysis of 234 homologs found in 94 genomes (16 archaea, 64 bacteria, and 14 eukaryotes). The number of homologs in each gene family varies from 117 in the Nth family (nearly every genome surveyed harbors at least one Nth homolog) to only five in the divergent OggII family (all from archaeal genomes). Sequences from all three domains of life are included in four of the six gene families, suggesting that the HhH superfamily diversified very early in evolution. The phylogeny provides evidence for multiple lineage-specific gene duplication events, most of which involve eukaryotic homologs in the Nth and AlkA gene families. We observe extensive variation in the number of HhH superfamily glycosylase genes present in different genomes, possibly reflecting major differences among species in the mechanisms and pathways by which damaged bases are repaired and/or disparities in the basic rates and spectra of mutation experienced by different genomes.