Purification and characterization of DNA ligase III from bovine testes. Homology with DNA ligase II and vaccinia DNA ligase

Human DNA ligases I and IIIα as determinants of accuracy and efficiency of base excision DNA repair

Mammalian Base Excision Repair (BER) DNA ligases I and IIIα (LigI, LigIIIα) are major determinants of DNA repair fidelity, alongside with DNA polymerases. Here we compared activities of human LigI and LigIIIα on specific and nonspecific substrates representing intermediates of distinct BER sub-pathways. The enzymes differently discriminate mismatches in the nicked DNA, depending on their identity and position, but are both more selective against the 3'-end non-complementarity. LigIIIα is less active than LigI in premature ligation of one-nucleotide gapped DNA and more efficiently discriminates misinsertion products of DNA polymerase β-catalyzed gap filling, that reinforces a leading role of LigIIIα in the accuracy of short-patch BER. LigI and LigIIIα reseal the intermediate of long-patch BER containing an incised synthetic AP site (F) with different efficiencies, depending on the DNA sequence context, 3'-end mismatch presence and coupling of the ligation reaction with DNA repair synthesis. Processing of this intermediate in the absence of flap endonuclease 1 generates non-canonical DNAs with bulged F site, which are very inefficiently repaired by AP endonuclease 1 and represent potential mutagenic repair products. The extent of conversion of the 5'-adenylated intermediates of specific and nonspecific substrates is revealed to depend on the DNA sequence context; a higher sensitivity of LigI to the sequence is in line with the enzyme structural feature of DNA binding. LigIIIα exceeds LigI in generation of potential abortive ligation products, justifying importance of XRCC1-mediated coordination of LigIIIα and aprataxin activities for the efficient DNA repair.

Mammalian DNA ligases; roles in maintaining genome integrity

The joining of breaks in the DNA phosphodiester backbone is essential for genome integrity. Breaks are generated during normal processes such as DNA replication, cytosine demethylation during differentiation, gene rearrangement in the immune system and germ cell development. In addition, they are generated either directly by a DNA damaging agent or indirectly due to damage excision during repair. Breaks are joined by a DNA ligase that catalyzes phosphodiester bond formation at DNA nicks with 3' hydroxyl and 5' phosphate termini. Three human genes encode ATP-dependent DNA ligases. These enzymes have a conserved catalytic core consisting of three subdomains that encircle nicked duplex DNA during ligation. The DNA ligases are targeted to different nuclear DNA transactions by specific protein-protein interactions. Both DNA ligase IIIα and DNA ligase IV form stable complexes with DNA repair proteins, XRCC1 and XRCC4, respectively. There is functional redundancy between DNA ligase I and DNA ligase IIIα in DNA replication, excision repair and single-strand break repair. Although DNA ligase IV is a core component of the major double-strand break repair pathway, non-homologous end joining, the other enzymes participate in minor, alternative double-strand break repair pathways. In contrast to the nucleus, only DNA ligase IIIα is present in mitochondria and is essential for maintaining the mitochondrial genome. Human immunodeficiency syndromes caused by mutations in either LIG1 or LIG4 have been described. Preclinical studies with DNA ligase inhibitors have identified potentially targetable abnormalities in cancer cells and evidence that DNA ligases are potential targets for cancer therapy.

Structures of LIG1 active site mutants reveal the importance of DNA end rigidity for mismatch discrimination

ATP-dependent DNA ligases catalyze phosphodiester bond formation in the conserved three-step chemical reaction of nick sealing. Human DNA ligase I (LIG1) finalizes almost all DNA repair pathways following DNA polymerase-mediated nucleotide insertion. We previously reported that LIG1 discriminates mismatches depending on the architecture of the 3'-terminus at a nick, however the contribution of conserved active site residues to faithful ligation remains unknown. Here, we comprehensively dissect the nick DNA substrate specificity of LIG1 active site mutants carrying Ala(A) and Leu(L) substitutions at Phe(F)635 and Phe(F)F872 residues and show completely abolished ligation of nick DNA substrates with all 12 non-canonical mismatches. LIG1 ^EE/AA structures of F635A and F872A mutants in complex with nick DNA containing A:C and G:T mismatches demonstrate the importance of DNA end rigidity, as well as uncover a shift in a flexible loop near 5'-end of the nick, which causes an increased barrier to adenylate transfer from LIG1 to the 5'-end of the nick. Furthermore, LIG1 ^EE/AA /8oxoG:A structures of both mutants demonstrated that F635 and F872 play critical roles during steps 1 or 2 of the ligation reaction depending on the position of the active site residue near the DNA ends. Overall, our study contributes towards a better understanding of the substrate discrimination mechanism of LIG1 against mutagenic repair intermediates with mismatched or damaged ends and reveals the importance of conserved ligase active site residues to maintain ligation fidelity.

Interplay between DNA Polymerases and DNA Ligases: Influence on Substrate Channeling and the Fidelity of DNA Ligation

DNA ligases are a highly conserved group of nucleic acid enzymes that play an essential role in DNA repair, replication, and recombination. This review focuses on functional interaction between DNA polymerases and DNA ligases in the repair of single- and double-strand DNA breaks, and discusses the notion that the substrate channeling during DNA polymerase-mediated nucleotide insertion coupled to DNA ligation could be a mechanism to minimize the release of potentially mutagenic repair intermediates. Evidence suggesting that DNA ligases are essential for cell viability includes the fact that defects or insufficiency in DNA ligase are casually linked to genome instability. In the future, it may be possible to develop small molecule inhibitors of mammalian DNA ligases and/or their functional protein partners that potentiate the effects of chemotherapeutic compounds and improve cancer treatment outcomes.

Kinetic mechanism and fidelity of nick sealing by Escherichia coli NAD+-dependent DNA ligase (LigA)

Escherichia coli DNA ligase (EcoLigA) repairs 3′-OH/5′-PO₄ nicks in duplex DNA via reaction of LigA with NAD⁺ to form a covalent LigA-(lysyl-Nζ)–AMP intermediate (step 1); transfer of AMP to the nick 5′-PO₄ to form an AppDNA intermediate (step 2); and attack of the nick 3′-OH on AppDNA to form a 3′-5′ phosphodiester (step 3). A distinctive feature of EcoLigA is its stimulation by ammonium ion. Here we used rapid mix-quench methods to analyze the kinetic mechanism of single-turnover nick sealing by EcoLigA–AMP. For substrates with correctly base-paired 3′-OH/5′-PO₄ nicks, k_step2 was fast (6.8–27 s⁻¹) and similar to k_step3 (8.3–42 s⁻¹). Absent ammonium, k_step2 and k_step3 were 48-fold and 16-fold slower, respectively. EcoLigA was exquisitely sensitive to 3′-OH base mispairs and 3′ N:abasic lesions, which elicited 1000- to >20000-fold decrements in k_step2. The exception was the non-canonical 3′ A:oxoG configuration, which EcoLigA accepted as correctly paired for rapid sealing. These results underscore: (i) how EcoLigA requires proper positioning of the nick 3′ nucleoside for catalysis of 5′ adenylylation; and (ii) EcoLigA's potential to embed mutations during the repair of oxidative damage. EcoLigA was relatively tolerant of 5′-phosphate base mispairs and 5′ N:abasic lesions.

Alternative Okazaki Fragment Ligation Pathway by DNA Ligase III

Higher eukaryotes have three types of DNA ligases: DNA ligase 1 (Lig1), DNA ligase 3 (Lig3) and DNA ligase 4 (Lig4). While Lig1 and Lig4 are present in all eukaryotes from yeast to human, Lig3 appears sporadically in evolution and is uniformly present only in vertebrates. In the classical, textbook view, Lig1 catalyzes Okazaki-fragment ligation at the DNA replication fork and the ligation steps of long-patch base-excision repair (BER), homologous recombination repair (HRR) and nucleotide excision repair (NER). Lig4 is responsible for DNA ligation at DNA double strand breaks (DSBs) by the classical, DNA-PKcs-dependent pathway of non-homologous end joining (C-NHEJ). Lig3 is implicated in a short-patch base excision repair (BER) pathway, in single strand break repair in the nucleus, and in all ligation requirements of the DNA metabolism in mitochondria. In this scenario, Lig1 and Lig4 feature as the major DNA ligases serving the most essential ligation needs of the cell, while Lig3 serves in the cell nucleus only minor repair roles. Notably, recent systematic studies in the chicken B cell line, DT40, involving constitutive and conditional knockouts of all three DNA ligases individually, as well as of combinations thereof, demonstrate that the current view must be revised. Results demonstrate that Lig1 deficient cells proliferate efficiently. Even Lig1/Lig4 double knockout cells show long-term viability and proliferate actively, demonstrating that, at least in DT40, Lig3 can perform all ligation reactions of the cellular DNA metabolism as sole DNA ligase. Indeed, in the absence of Lig1, Lig3 can efficiently support semi-conservative DNA replication via an alternative Okazaki-fragment ligation pathway. In addition, Lig3 can back up NHEJ in the absence of Lig4, and can support NER and HRR in the absence of Lig1. Supporting observations are available in less elaborate genetic models in mouse cells. Collectively, these observations raise Lig3 from a niche-ligase to a universal DNA ligase, which can potentially substitute or backup the repair and replication functions of all other DNA ligases in the cell nucleus. Thus, the old model of functionally dedicated DNA ligases is now replaced by one in which only Lig4 remains dedicated to C-NHEJ, with Lig1 and Lig3 showing an astounding functional flexibility and interchangeability for practically all nuclear ligation functions. The underlying mechanisms of Lig3 versus Lig1 utilization in DNA repair and replication are expected to be partly different and remain to be elucidated.

Effects of 3'-OH and 5'-PO4 base mispairs and damaged base lesions on the fidelity of nick sealing by Deinococcus radiodurans RNA ligase

Deinococcus radiodurans RNA ligase (DraRnl) is the founding member of a family of end-joining enzymes encoded by diverse microbes and viruses. DraRnl ligates 3'-OH, 5'-PO4 nicks in double-stranded nucleic acids in which the nick 3'-OH end is RNA. Here we gauge the effects of 3'-OH and 5'-PO4 base mispairs and damaged base lesions on the rate of nick sealing. DraRnl is indifferent to the identity of the 3'-OH nucleobase, provided that it is correctly paired. With 3'-OH mispairs, the DraRnl sealing rate varies widely, with G-T and A-C mispairs being the best substrates and G-G, G-A, and A-A mispairs being the worst. DraRnl accepts 3' A-8-oxoguanine (oxoG) to be correctly paired, while it discriminates against U-oxoG and G-oxoG mispairs. DraRnl displays high activity and low fidelity in sealing 3'-OH ends opposite an 8-oxoadenine lesion. It prefers 3'-OH adenosine when sealing opposite an abasic template site. With 5'-PO4 mispairs, DraRnl seals a 5' T-G mispair as well as it does a 5' C-G pair; in most other respects, the ligation fidelity at 5' mispairs is similar to that at 3' mispairs. DraRnl accepts a 5' A-oxoG end to be correctly paired, yet it is more tolerant of 5' T-oxoG and 5' G-oxoG mispairs than the equivalent configurations on the 3' side of the nick. At 5' nucleobase-abasic site nicks, DraRnl prefers to ligate when the nucleobase is a purine. The biochemical properties of DraRnl are compatible with its participation in the templated repair of RNA damage or in the sealing of filled DNA gaps that have a 3' ribopatch.

Kinetic mechanism of nick sealing by T4 RNA ligase 2 and effects of 3'-OH base mispairs and damaged base lesions

T4 RNA ligase 2 (Rnl2) repairs 3'-OH/5'-PO4 nicks in duplex nucleic acids in which the broken 3'-OH strand is RNA. Ligation entails three chemical steps: reaction of Rnl2 with ATP to form a covalent Rnl2-(lysyl-Nζ)-AMP intermediate (step 1); transfer of AMP to the 5'-PO4 of the nick to form an activated AppN- intermediate (step 2); and attack by the nick 3'-OH on the AppN- strand to form a 3'-5' phosphodiester (step 3). Here we used rapid mix-quench methods to analyze the kinetic mechanism and fidelity of single-turnover nick sealing by Rnl2-AMP. For substrates with correctly base-paired 3'-OH nick termini, kstep2 was fast (9.5 to 17.9 sec(-1)) and similar in magnitude to kstep3 (7.9 to 32 sec(-1)). Rnl2 fidelity was enforced mainly at the level of step 2 catalysis, whereby 3'-OH base mispairs and oxoguanine, oxoadenine, or abasic lesions opposite the nick 3'-OH elicited severe decrements in the rate of 5'-adenylylation and relatively modest slowing of the rate of phosphodiester synthesis. The exception was the noncanonical A:oxoG base pair, which Rnl2 accepted as a correctly paired end for rapid sealing. These results underscore (1) how Rnl2 requires proper positioning of the 3'-terminal ribonucleoside at the nick for optimal 5'-adenylylation and (2) the potential for nick-sealing ligases to embed mutations during the repair of oxidative damage.

Structure and function of the DNA ligases encoded by the mammalian LIG3 gene

Among the mammalian genes encoding DNA ligases (LIG), the LIG3 gene is unique in that it encodes multiple DNA ligase polypeptides with different cellular functions. Notably, this nuclear gene encodes the only mitochondrial DNA ligase and so is essential for this organelle. In the nucleus, there is significant functional redundancy between DNA ligase IIIα and DNA ligase I in excision repair. In addition, DNA ligase IIIα is essential for DNA replication in the absence of the replicative DNA ligase, DNA ligase I. DNA ligase IIIα is a component of an alternative non-homologous end joining (NHEJ) pathway for DNA double-strand break (DSB) repair that is more active when the major DNA ligase IV-dependent pathway is defective. Unlike its other nuclear functions, the role of DNA ligase IIIα in alternative NHEJ is independent of its nuclear partner protein, X-ray repair cross-complementing protein 1 (XRCC1). DNA ligase IIIα is frequently overexpressed in cancer cells, acting as a biomarker for increased dependence upon alternative NHEJ for DSB repair and it is a promising novel therapeutic target.

Human Mre11/human Rad50/Nbs1 and DNA ligase IIIalpha/XRCC1 protein complexes act together in an alternative nonhomologous end joining pathway

Recent studies have implicated a poorly defined alternative pathway of nonhomologous end joining (alt-NHEJ) in the generation of large deletions and chromosomal translocations that are frequently observed in cancer cells. Here, we describe an interaction between two factors, hMre11/hRad50/Nbs1 (MRN) and DNA ligase IIIα/XRCC1, that have been linked with alt-NHEJ. Expression of DNA ligase IIIα and the association between MRN and DNA ligase IIIα/XRCC1 are altered in cell lines defective in the major NHEJ pathway. Most notably, DNA damage induced the association of these factors in DNA ligase IV-deficient cells. MRN interacts with DNA ligase IIIα/XRCC1, stimulating intermolecular ligation, and together these proteins join incompatible DNA ends in a reaction that mimics alt-NHEJ. Thus, our results provide novel mechanistic insights into the alt-NHEJ pathway that not only contributes to genome instability in cancer cells but may also be a therapeutic target.

Human DNA ligase III recognizes DNA ends by dynamic switching between two DNA-bound states

Human DNA ligase III has essential functions in nuclear and mitochondrial DNA replication and repair and contains a PARP-like zinc finger (ZnF) that increases the extent of DNA nick joining and intermolecular DNA ligation, yet the bases for ligase III specificity and structural variation among human ligases are not understood. Here combined crystal structure and small-angle X-ray scattering results reveal dynamic switching between two nick-binding components of ligase III: the ZnF-DNA binding domain (DBD) forms a crescent-shaped surface used for DNA end recognition which switches to a ring formed by the nucleotidyl transferase (NTase) and OB-fold (OBD) domains for catalysis. Structural and mutational analyses indicate that high flexibility and distinct DNA binding domain features in ligase III assist both nick sensing and the transition from nick sensing by the ZnF to nick joining by the catalytic core. The collective results support a "jackknife model" in which the ZnF loads ligase III onto nicked DNA and conformational changes deliver DNA into the active site. This work has implications for the biological specificity of DNA ligases and functions of PARP-like zinc fingers.

Distinct kinetics of human DNA ligases I, IIIalpha, IIIbeta, and IV reveal direct DNA sensing ability and differential physiological functions in DNA repair

The three human LIG genes encode polypeptides that catalyze phosphodiester bond formation during DNA replication, recombination and repair. While numerous studies have identified protein partners of the human DNA ligases (hLigs), there has been little characterization of the catalytic properties of these enzymes. In this study, we developed and optimized a fluorescence-based DNA ligation assay to characterize the activities of purified hLigs. Although hLigI joins DNA nicks, it has no detectable activity on linear duplex DNA substrates with short, cohesive single-strand ends. By contrast, hLigIIIbeta and the hLigIIIalpha/XRCC1 and hLigIV/XRCC4 complexes are active on both nicked and linear duplex DNA substrates. Surprisingly, hLigIV/XRCC4, which is a key component of the major non-homologous end joining (NHEJ) pathway, is significantly less active than hLigIII on a linear duplex DNA substrate. Notably, hLigIV/XRCC4 molecules only catalyze a single ligation event in the absence or presence of ATP. The failure to catalyze subsequent ligation events reflects a defect in the enzyme-adenylation step of the next ligation reaction and suggests that, unless there is an in vivo mechanism to reactivate DNA ligase IV/XRCC4 following phosphodiester bond formation, the cellular NHEJ capacity will be determined by the number of adenylated DNA ligaseIV/XRCC4 molecules.

In vitro ligation of oligodeoxynucleotides containing C8-oxidized purine lesions using bacteriophage T4 DNA ligase

Ligases conduct the final stage of repair of DNA damage by sealing a single-stranded nick after excision of damaged nucleotides and reinsertion of correct nucleotides. Depending upon the circumstances and the success of the repair process, lesions may remain at the ligation site, either in the template or at the oligomer termini to be joined. Ligation experiments using bacteriophage T4 DNA ligase were carried out with purine lesions in four positions surrounding the nick site in a total of 96 different duplexes. The oxidized lesion 8-oxo-7,8-dihydroguanosine (OG) showed, as expected, that the enzyme is most sensitive to lesions on the 3' end of the nick compared to the 5' end and to lesions located in the intact template strand. In general, substrates containing the OG.A mismatch were more readily ligated than those with the OG.C mismatch. Ligations of duplexes containing the OA.T base pair (OA = 8-oxo-7,8-dihydroadenosine) that could adopt an anti-anti conformation proceeded with high efficiencies. An OI.A mismatch-containing duplex (OI = 8-oxo-7,8-dihydroinosine) behaved like OG.A. Due to its low reduction potential, OG is readily oxidized to secondary oxidation products, such as the guanidinohydantoin (Gh) and spiroiminodihydantoin (Sp) nucleosides; these lesions also contain an oxo group at the original C8 position of the purine. Ligation of oligomers containing Gh and Sp occurred when opposite A and G, although the overall ligation efficiencies were much lower than those of most OG base pairs. Steady-state kinetic studies were carried out for representative examples of lesions in the template. Km increased by 90-100-fold for OG.C-, OI.C-, OI.A-, and OA.T-containing duplexes compared to that of a G.C-containing duplex. Substrates containing Gh.A, Gh.G, Sp.A, and Sp.G base pairs exhibited Km values 20-70-fold higher than that of the substrate containing a G.C base pair, while the Km value for OG.A was 5 times lower than that for G.C.

Site-directed combinatorial construction of chimaeric genes: general method for optimizing assembly of gene fragments

Site-directed construction of chimaeric genes by in vitro recombination "mixes-and-matches" precise building blocks from multiple parent proteins, generating libraries of hybrids to be tested for structure-function relationships and/or screened for favorable properties and novel enzymatic activities. A direct annealing and ligation method can construct chimaeric genes without requiring sequence identity between parents, except for the short (approximately 3 nt) sequences of the fragment overhangs used for specific ligation. Careful planning of the assembly process is necessary, though, in order to ensure effective construction of desired fragment assemblies and to avoid undesired assemblies (e.g., repetition of fragments, fragments out of order). We develop algorithms for specific planned ligation of short overhangs (SPLISO) that efficiently explore possible assembly plans, varying the fragment overhangs and the order of ligation steps in the assembly pathway. While there is a combinatorial explosion in the number of possible assembly plans as the number of breakpoints and parent genes increases, we employ a dynamic programming approach to find globally optimal ones in low-order polynomial time (in practice, taking only seconds for basic assembly plans). We demonstrate the effectiveness of our algorithms in planning the assembly of hybrid libraries, under a variety of experimental options and restrictions, including flexibility in the position and amino acid sequence of breakpoints. Our method promises to enable more effective application of site-directed recombination to protein investigation and engineering.

No association of DNA ligase-I polymorphism with the risk of lung cancer in north-Indian population

DNA ligases play an essential role in repair, replication, and recombination of DNA, and catalyzes the formation of a phosphodiester bond at a nick junction on single- and double-strand breaks. We have conducted a hospital-based case-control study to examine the role of polymorphism of DNA repair gene ligase I (LIGI) in the context of lung cancer risk for north Indian population. One hundred, fifty-one primary lung cancer cases and an equal number of matching hospital controls were collected. The LIGI polymorphism was determined by using the PCR-RFLP method. The association between polymorphisms in the LIGI gene with the risk of lung cancer was estimated by computing odds ratios (ORs) and a 95% confidence interval (CI) using a Multivariate Logistic Regression Analysis. The risk for lung cancer was not associated for individuals featuring LIGI (AC) (OR -0.8, 95% CI = 0.44-1.40) and (AA) (OR -0.8, 95% CI = 0.41-1.80) genotypes. The DNA repair gene (LIGI) may not be playing an important role in modulating the risk of lung cancer in the north Indian population.

Early embryonic lethality due to targeted inactivation of DNA ligase III

DNA ligases catalyze the joining of strand breaks in the phosphodiester backbone of duplex DNA and play essential roles in DNA replication, recombination, repair, and maintenance of genomic integrity. Three mammalian DNA ligase genes have been identified, and their corresponding ligases play distinct roles in DNA metabolism. DNA ligase III is proposed to be involved in the repairing of DNA single-strand breaks, but its precise role has not yet been demonstrated directly. To determine its role in DNA repair, cellular growth, and embryonic development, we introduced targeted interruption of the DNA ligase III (LIG3) gene into the mouse. Mice homozygous for LIG3 disruption showed early embryonic lethality. We found that the mutant embryonic developmental process stops at 8.5 days postcoitum (dpc), and excessive cell death occurs at 9.5 dpc. LIG3 mutant cells have relatively normal XRCC1 levels but elevated sister chromatid exchange. These findings indicate that DNA ligase III is involved in essential DNA repair activities required for early embryonic development and therefore cannot be replaced by other DNA ligases.

An error-prone viral DNA ligase

Our recent demonstration that DNA polymerase X (Pol X), the DNA repair polymerase encoded by the African swine fever virus (ASFV), is extremely error prone during single-nucleotide gap filling led us to hypothesize that it might contribute to genetic variability in ASFV. For the infidelity of Pol X to be relevant, however, the DNA ligase working downstream of it would need to be capable of sealing nicks containing 3'-OH mismatches. We therefore examined the nick ligation capabilities of the ASFV-encoded DNA ligase and here report the first complete 3' fidelity analysis, employing catalytic parameters, for any DNA ligase. The catalytic efficiency of nick sealing by both ASFV DNA ligase and bacteriophage T4 DNA ligase was determined in the steady state for substrates containing all 16 possible matched and mismatched base pair combinations at the 3' side of a nick. Our results indicate that ASFV DNA ligase is the lowest-fidelity DNA ligase ever reported, capable of ligating a 3' C:T mismatched nick (where C and T are the templating and nascent nucleotides, respectively) more efficiently than nicks containing Watson-Crick base pairs. Comparison of the mismatch specificity of Pol X with that of ASFV DNA ligase suggests that the latter may have evolved toward low fidelity for the purpose of generating the broadest possible spectrum of sealed mismatches. These findings are discussed in light of the genetic and antigenic variability observed among some ASFV isolates. Two novel assays for determining the concentration of active DNA ligase are also reported.

Unique ligation properties of eukaryotic NAD+-dependent DNA ligase from Melanoplus sanguinipes entomopoxvirus

The eukaryotic Melanoplus sanguinipes entomopoxvirus (MsEPV) genome reveals a homologous sequence to eubacterial nicotinamide adenine dinucleotide (NAD(+))-dependent DNA ligases [J. Virol. 73 (1999) 533]. This 522-amino acid open reading frame (ORF) contains all conserved nucleotidyl transferase motifs but lacks the zinc finger motif and BRCT domain found in conventional eubacterial NAD(+) ligases. Nevertheless, cloned MsEPV ligase seals DNA nicks in a NAD(+)-dependent fashion, while adenosine 5'-monophosphate (ATP) cannot serve as an adenylation cofactor. The ligation activity of MsEPV ligase requires Mg(2+) or Mn(2+). MsEPV ligase seals sticky ends efficiently, but has little activity on 1-nucleotide gap or blunt-ended DNA substrates even in the presence of polyethylene glycol. In comparison, bacterial NAD(+)-dependent ligases seal blunt-ended DNA substrates in the presence of polyethylene glycol. MsEPV DNA ligase readily joins DNA nicks with mismatches at either side of the nick junction, except for mismatches at the nick junction containing an A base in the template strand (A/A, G/A, and C/A). MsEPV NAD(+)-dependent DNA ligase can join DNA probes on RNA templates, a unique property that distinguishes this enzyme from other conventional bacterial NAD(+) DNA ligases. T4 ATP-dependent DNA ligase shows no detectable mismatch ligation at the 3' side of the nick but substantial 5' T/G mismatch ligation on an RNA template. In contrast, MsEPV ligase joins mismatches at the 3' side of the nick more frequently than at the 5' side of the nick on an RNA template. The complementary specificities of these two enzymes suggest alternative primer design for genomic profiling approaches that use allele-specific detection directly from RNA transcripts.

Nonhomologous end joining of complementary and noncomplementary DNA termini in mouse testicular extracts

Mammalian somatic cells are known to repair DNA double-strand breaks (DSBs) by nonhomologous end joining (NHEJ) and homologous recombination (HR); however, how male germ cells repair DSBs is not yet characterized. We have previously reported the highly efficient and mostly precise DSB joining ability of mouse testicular germ cell extracts for cohesive and blunt ends, with only a minor fraction undergoing terminal deletion [Mutat. Res. 433 (1999) 1]; however, the precise mechanism of joining was not established. In the present study, we therefore tested the ability of testicular extracts to join noncomplementary ends; we have also sequenced the junctions of both complementary and noncomplementary termini and established the joining mechanisms. While a major proportion of complementary and blunt ends were joined by simple ligation, the small fraction having noncleavable junctions predominantly utilized short stretches of direct repeat homology with limited end processing. For noncomplementary ends, the major mechanism was "blunt-end ligation" subsequent to "fill-in" or "blunting", with no insertions or large deletions; the microhomology-dependent joining with end deletion was less frequent. This is the first functional study of the NHEJ mechanism in mammalian male germ cell extracts. Our results demonstrate that testicular germ cell extracts promote predominantly accurate NHEJ for cohesive ends and very efficient blunt-end ligation, perhaps to preserve the genomic sequence with minimum possible alteration. Further, we demonstrate the ability of the extracts to catalyze in vitro plasmid homologous recombination, which suggests the existence of both NHEJ and HR pathways in germ cells.

Role of DNA replication proteins in double-strand break-induced recombination in Saccharomyces cerevisiae

Mitotic double-strand break (DSB)-induced gene conversion involves new DNA synthesis. We have analyzed the requirement of several essential replication components, the Mcm proteins, Cdc45p, and DNA ligase I, in the DNA synthesis of Saccharomyces cerevisiae MAT switching. In an mcm7-td (temperature-inducible degron) mutant, MAT switching occurred normally when Mcm7p was degraded below the level of detection, suggesting the lack of the Mcm2-7 proteins during gene conversion. A cdc45-td mutant was also able to complete recombination. Surprisingly, even after eliminating both of the identified DNA ligases in yeast, a cdc9-1 dnl4 Delta strain was able to complete DSB repair. Previous studies of asynchronous cultures carrying temperature-sensitive alleles of PCNA, DNA polymerase alpha (Pol alpha), or primase showed that these mutations inhibited MAT switching (A. M. Holmes and J. E. Haber, Cell 96:415-424, 1999). We have reevaluated the roles of these proteins in G(2)-arrested cells. Whereas PCNA was still essential for MAT switching, neither Pol alpha nor primase was required. These results suggest that arresting cells in S phase using ts alleles of Pol alpha-primase, prior to inducing the DSB, sequesters some other component that is required for repair. We conclude that DNA synthesis during gene conversion is different from S-phase replication, involving only leading-strand polymerization.

DNA ligases ensure fidelity by interrogating minor groove contacts

DNA ligases, found in both prokaryotes and eukaryotes, covalently link the 3'-hydroxyl and 5'-phosphate ends of duplex DNA segments. This reaction represents a completion step for DNA replication, repair and recombination. It is well established that ligases are sensitive to mispairs present on the 3' side of the ligase junction, but tolerant of mispairs on the 5' side. While such discrimination would increase the overall accuracy of DNA replication and repair, the mechanisms by which this fidelity is accomplished are as yet unknown. In this paper, we present the results of experiments with Tth ligase from Thermus thermophilus HB8 and a series of nucleoside analogs in which the mechanism of discrimination has been probed. Using a series of purine analogs substituted in the 2 and 6 positions, we establish that the apparent base pair geometry is much more important than relative base pair stability and that major groove contacts are of little importance. This result is further confirmed using 5-fluorouracil (FU) mispaired with guanine. At neutral pH, the FU:G mispair on the 3' side of a ligase junction is predominantly in a neutral wobble configuration and is poorly ligated. Increasing the solution pH increases the proportion of an ionized base pair approximating Watson-Crick geometry, substantially increasing the relative ligation efficiency. These results suggest that the ligase could distinguish Watson-Crick from mispaired geometry by probing the hydrogen bond acceptors present in the minor groove as has been proposed for DNA polymerases. The significance of minor groove hydrogen bonding interactions is confirmed with both Tth and T4 DNA ligases upon examination of base pairs containing the pyrimidine shape analog, difluorotoluene (DFT). Although DFT paired with adenine approximates Watson-Crick geometry, a minor groove hydrogen bond acceptor is lost. Consistent with this hypothesis, we observe that DFT-containing base pairs inhibit ligation when on the 3' side of the ligase junction. The NAD+-dependent ligase, Tth, is more sensitive to the DFT analog on the unligated strand whereas the ATP-dependent T4 ligase is more sensitive to substitutions in the template strand. Electrophoretic gel mobility-shift assays demonstrate that the Tth ligase binds poorly to oligonucleotide substrates containing analogs with altered minor groove contacts.

Physical and functional interaction between DNA ligase IIIalpha and poly(ADP-Ribose) polymerase 1 in DNA single-strand break repair

The repair of DNA single-strand breaks in mammalian cells is mediated by poly(ADP-ribose) polymerase 1 (PARP-1), DNA ligase IIIalpha, and XRCC1. Since these proteins are not found in lower eukaryotes, this DNA repair pathway plays a unique role in maintaining genome stability in more complex organisms. XRCC1 not only forms a stable complex with DNA ligase IIIalpha but also interacts with several other DNA repair factors. Here we have used affinity chromatography to identify proteins that associate with DNA ligase III. PARP-1 binds directly to an N-terminal region of DNA ligase III immediately adjacent to its zinc finger. In further studies, we have shown that DNA ligase III also binds directly to poly(ADP-ribose) and preferentially associates with poly(ADP-ribosyl)ated PARP-1 in vitro and in vivo. Our biochemical studies have revealed that the zinc finger of DNA ligase III increases DNA joining in the presence of either poly(ADP-ribosyl)ated PARP-1 or poly(ADP-ribose). This provides a mechanism for the recruitment of the DNA ligase IIIalpha-XRCC1 complex to in vivo DNA single-strand breaks and suggests that the zinc finger of DNA ligase III enables this complex and associated repair factors to locate the strand break in the presence of the negatively charged poly(ADP-ribose) polymer.

The Arabidopsis AtLIG4 gene is required for the repair of DNA damage, but not for the integration of Agrobacterium T-DNA

The joining of breaks in the chromosomal DNA backbone by ligases in processes of replication, recombination and repair plays a crucial role in the maintenance of genomic stability. Four ATP-dependent ligases, designated DNA ligases I-IV, have been identified in higher eukaryotes, and each one has distinct functions. In mammals and yeast, DNA ligase IV is exclusively involved in the repair of DNA double-strand breaks by non-homologous end joining. Recently, an Arabidopsis thaliana orthologue of the yeast and mammalian DNA ligase IV gene was found and termed AtLIG4. Here we describe the isolation and functional characterisation of a plant line with a T-DNA insertion in the AtLIG4 gene. Plants homozygous for the T-DNA insertion did not display any growth or developmental defects and were fertile. However, mutant seedlings were hypersensitive to the DNA-damaging agents methyl methanesulfonate and X-rays, demonstrating that AtLIG4 is required for the repair of DNA damage. Recently, we showed that a yeast lig4 mutant is deficient in Agrobacterium T-DNA integration. However, using tumorigenesis and germline transformation assays, we found that the plant AtLIG4 mutant is not impaired in T-DNA integration. Thus, in contrast to yeast, DNA ligase IV is not required for T-DNA integration in plants.

Canonical nucleosides can be utilized by T4 DNA ligase as universal template bases at ligation junctions

T4 DNA ligase catalyzes the template-dependent ligation of DNA. Using T4 DNA ligase under specific experimental conditions, we demonstrate that each of the four canonical nucleosides, centrally located on a template molecule such that they flank the site of ligation, can direct the ligation of nucleic acids regardless of the identity of the terminal nucleosides being covalently joined. This universal templating capability extends to those positions adjacent to the ligation junction. This is the first report, irrespective of the ligation method used or the identity of the template nucleosides (including analogs), which shows that nucleosides can act essentially as universal templates at ligation junctions in vitro. The canonical nucleosides do, however, differ in their ability to template sequence- independent ligations, with thymidine and guanosine being equally effective, yet more effective than adenosine and cytidine. Results indicate that hybridization strength surrounding the ligation junction is an important factor. The implications of this previously undiscovered property of T4 DNA ligase with canonical nucleosides are discussed.

An exonucleolytic activity of human apurinic/apyrimidinic endonuclease on 3' mispaired DNA

Human apurinic/apyrimidinic endonuclease (APE1) is an essential enzyme in DNA base excision repair that cuts the DNA backbone immediately adjacent to the 5' side of abasic sites to facilitate repair synthesis by DNA polymerase beta (ref. 1). Mice lacking the murine homologue of APE1 die at an early embryonic stage. Here we report that APE1 has a DNA exonuclease activity on mismatched deoxyribonucleotides at the 3' termini of nicked or gapped DNA molecules. The efficiency of this activity is inversely proportional to the gap size in DNA. In a base excision repair system reconstituted in vitro, the rejoining of nicked mismatched DNA depended on the presence of APE1, indicating that APE1 may increase the fidelity of base excision repair and may represent a new 3' mispaired DNA repair mechanism. The exonuclease activity of APE1 can remove the anti-HIV nucleoside analogues 3'-azido-3'-deoxythymidine and 2',3'-didehydro-2', 3'-dideoxythymidine from DNA, suggesting that APE1 might have an impact on the therapeutic index of antiviral compounds in this category.

Uracil-initiated base excision DNA repair synthesis fidelity in human colon adenocarcinoma LoVo and Escherichia coli cell extracts

The error frequency of uracil-initiated base excision repair (BER) DNA synthesis in human and Escherichia coli cell-free extracts was determined by an M13mp2 lacZ alpha DNA-based reversion assay. Heteroduplex M13mp2 DNA was constructed that contained a site-specific uracil target located opposite the first nucleotide position of opal codon 14 in the lacZ alpha gene. Human glioblastoma U251 and colon adenocarcinoma LoVo whole-cell extracts repaired the uracil residue to produce form I DNA that was resistant to subsequent in vitro cleavage by E. coli uracil-DNA glycosylase (Ung) and endonuclease IV, indicating that complete uracil-initiated BER repair had occurred. Characterization of the BER reactions revealed that (1) the majority of uracil-DNA repair was initiated by a uracil-DNA glycosylase-sensitive to Ugi (uracil-DNA glycosylase inhibitor protein), (2) the addition of aphidicolin did not significantly inhibit BER DNA synthesis, and (3) the BER patch size ranged from 1 to 8 nucleotides. The misincorporation frequency of BER DNA synthesis at the target site was 5.2 x 10(-4) in U251 extracts and 5.4 x 10(-4) in LoVo extracts. The most frequent base substitution errors in the U251 and LoVo mutational spectrum were T to G > T to A >> T to C. Uracil-initiated BER DNA synthesis in extracts of E. coli BH156 (ung) BH157 (dug), and BH158 (ung, dug) was also examined. Efficient BER occurred in extracts of the BH157 strain with a misincorporation frequency of 5.6 x 10(-4). A reduced, but detectable level of BER was observed in extracts of E. coli BH156 cells; however, the mutation frequency of BER DNA synthesis was elevated 6.4-fold.

Completion of base excision repair by mammalian DNA ligases

Three mammalian genes encoding DNA ligases--LIG1, LIG3, and LIG4--have been identified. Genetic, biochemical, and cell biology studies indicate that the products of each of these genes play a unique role in mammalian DNA metabolism. Interestingly, cell lines deficient in either DNA ligase I (46BR.1G1) or DNA ligase III (EM9) are sensitive to simple alkylating agents. One interpretation of these observations is that DNA ligases I and III participate in functionally distinct base excision repair (BER) subpathways. In support of this idea, extracts from both DNA ligase-deficient cell lines are defective in catalyzing BER in vitro and both DNA ligases interact with other BER proteins. DNA ligase I interacts directly with proliferating cell nuclear antigen (PCNA) and DNA polymerase beta (Pol beta), linking this enzyme with both short-patch and long-patch BER. In somatic cells, DNA ligase III alpha forms a stable complex with the DNA repair protein Xrcc1. Although Xrcc1 has no catalytic activity, it also interacts with Pol beta and poly(ADP-ribose) polymerase (PARP), linking DNA ligase III alpha with BER and single-strand break repair, respectively. Biochemical studies suggest that the majority of short-patch base excision repair events are completed by the DNA ligase III alpha/Xrcc1 complex. Although there is compelling evidence for the participation of PARP in the repair of DNA single-strand breaks, the role of PARP in BER has not been established.

Substrate recognition and fidelity of strand joining by an archaeal DNA ligase

We have previously identified a DNA ligase (LigTk) from a hyperthermophilic archaeon, Thermococcus kodakaraensis KOD1. The enzyme is the only characterized ATP-dependent DNA ligase from a hyperthermophile, and allows the analysis of enzymatic DNA ligation reactions at temperatures above the melting point of the substrates. Here we have focused on the interactions of LigTk with various DNA substrates, and its specificities toward metal cations. LigTk could utilize Mg2+, Mn2+, Sr2+ and Ca2+ as a metal cation, but not Co2+, Zn2+, Ni2+, or Cu2+. The enzyme displayed typical Michaelis-Menten steady-state kinetics with an apparent Km of 1.4 microm for nicked DNA. The kcat value of the enzyme was 0.11*s-1. Using various 3' hydroxyl group donors (L-DNA) and 5' phosphate group donors (R-DNA), we could detect ligation products as short as 16 nucleotides, the products of 7 + 9 nucleotide or 8 + 8 nucleotide combinations at 40 degrees C. An elevation in temperature led to a decrease in reaction efficiency when short oligonucleotides were used, suggesting that the formation of a nicked, double-stranded DNA substrate preceded enzyme-substrate recognition. LigTk was not inhibited by the addition of excess duplex DNA, implying that the enzyme did not bind strongly to the double-stranded ligation product after nick-sealing. In terms of reaction fidelity, LigTk was found to ligate various substrates with mismatched base-pairing at the 5' end of the nick, but did not show activity towards the 3' mismatched substrates. LigTk could not seal substrates with a 1-nucleotide or 2-nucleotide gap. Small amounts of ligation products were detected with DNA substrates containing a single nucleotide insertion, relatively more with the 5' insertions. The results revealed the importance of proper base-pairing at the 3' hydroxyl side of the nick for the ligation reaction by LigTk.

Two forms of mitochondrial DNA ligase III are produced in Xenopus laevis oocytes

Full-length cDNAs for DNA ligase IV and the alpha and beta isoforms of DNA ligase III were cloned from Xenopus laevis to permit study of the genes encoding mitochondrial DNA ligase. DNA ligase III alpha and III beta share a common NH(2) terminus that encodes a mitochondrial localization signal capable of targeting green fluorescent protein to mitochondria while the NH(2) terminus of DNA ligase IV does not. Reverse transcriptase-polymerase chain reaction analyses with adult frog tissues demonstrate that while DNA ligase III alpha and DNA ligase IV are ubiquitously expressed, DNA ligase III beta expression is restricted to testis and ovary. Mitochondrial lysates from X. laevis oocytes contain both DNA ligase III alpha and III beta but no detectable DNA ligase IV. Gel filtration, sedimentation, native gel electrophoresis, and in vitro cross-linking experiments demonstrate that mtDNA ligase III alpha exists as a high molecular weight complex. We discuss the possibility that DNA ligase III alpha exists in mitochondria in association with novel mitochondrial protein partners or as a homodimer.

Mixed spermatogenic germ cell nuclear extracts exhibit high base excision repair activity

Spermatogenic cells exhibit a lower spontaneous mutation frequency than somatic tissues in a lacI transgene and many base excision repair (BER) genes display the highest observed level of expression in the testis. In this study, uracil-DNA glycosylase-initiated BER activity was measured in nuclear extracts prepared from tissues obtained from each of three mouse strains. Extracts from mixed spermatogenic germ cells displayed the greatest activity followed by liver then brain for all three strains, and the activity for a given tissue was consistent among the three strains. Levels of various BER proteins were examined by western blot analyses and found to be consistent with activity levels. Nuclear extracts prepared from purified Sertoli cells, a somatic component of the seminiferous epithelium, exhibited significantly lower activity than mixed spermatogenic cell-type nuclear extracts, thereby suggesting that the high BER activity observed in mixed germ cell nuclear extracts was not a characteristic of all testicular cell types. Nuclear extracts from thymocytes and small intestines were assayed to assess activity in a mitotically active cell type and tissue. Overall, the order of tissues/cells exhibiting the greatest to lowest activity was mixed germ cells > Sertoli cells > thymocytes > small intestine > liver > brain.

Antisense-mediated decrease in DNA ligase III expression results in reduced mitochondrial DNA integrity

The human DNA ligase III gene encodes both nuclear and mitochondrial proteins. Abundant evidence supports the conclusion that the nuclear DNA ligase III protein plays an essential role in both base excision repair and homologous recombination. However, the role of DNA ligase III protein in mitochondrial genome dynamics has been obscure. Human tumor-derived HT1080 cells were transfected with an antisense DNA ligase III expression vector and clones with diminished levels of DNA ligase III activity identified. Mitochondrial protein extracts prepared from these clones had decreased levels of DNA ligase III relative to extracts from cells transfected with a control vector. Analysis of these clones revealed that the DNA ligase III antisense mRNA-expressing cells had reduced mtDNA content compared to control cells. In addition, the residual mtDNA present in these cells had numerous single-strand nicks that were not detected in mtDNA from control cells. Cells expressing antisense ligase III also had diminished capacity to restore their mtDNA to pre-irradiation levels following exposure to gamma-irradiation. An antisense-mediated reduction in cellular DNA ligase IV had no effect on the copy number or integrity of mtDNA. This observation, coupled with other evidence, suggests that DNA ligase IV is not present in the mitochondria and does not play a role in maintaining mtDNA integrity. We conclude that DNA ligase III is essential for the proper maintenance of mtDNA in cultured mammalian somatic cells.

DNA ligases in the repair and replication of DNA

DNA ligases are critical enzymes of DNA metabolism. The reaction they catalyse (the joining of nicked DNA) is required in DNA replication and in DNA repair pathways that require the re-synthesis of DNA. Most organisms express DNA ligases powered by ATP, but eubacteria appear to be unique in having ligases driven by NAD(+). Interestingly, despite protein sequence and biochemical differences between the two classes of ligase, the structure of the adenylation domain is remarkably similar. Higher organisms express a variety of different ligases, which appear to be targetted to specific functions. DNA ligase I is required for Okazaki fragment joining and some repair pathways; DNA ligase II appears to be a degradation product of ligase III; DNA ligase III has several isoforms, which are involved in repair and recombination and DNA ligase IV is necessary for V(D)J recombination and non-homologous end-joining. Sequence and structural analysis of DNA ligases has shown that these enzymes are built around a common catalytic core, which is likely to be similar in three-dimensional structure to that of T7-bacteriophage ligase. The differences between the various ligases are likely to be mediated by regions outside of this common core, the structures of which are not known. Therefore, the determination of these structures, along with the structures of ligases bound to substrate DNAs and partner proteins ought to be seen as a priority.

Biochemical properties of a high fidelity DNA ligase from Thermus species AK16D

NAD+-dependent DNA ligases from thermophilic bacteria Thermus species are highly homologous with amino acid sequence identities ranging from 85 to 98%. Thermus species AK16D ligase, the most divergent of the seven Thermus isolates collected worldwide, was cloned, expressed in Escherichia coli and purified to homogeneity. This Thermus ligase is similar to Thermus thermophilus HB8 ligase with respect to pH, salt, NAD+, divalent cation profiles and steady-state kinetics.However, the former is more discriminative toward T/G mismatches at the 3'-side of the ligation junction, as judged by the ratios of initial ligation rates of matched and mismatched substrates. The two wild-type Thermus ligases and a Tth ligase mutant (K294R) demonstrate 1-2 orders of magnitude higher fidelity than viral T4 DNA ligase. Both Thermus ligases are active with either the metal cofactor Mg2+, Mn2+or Ca2+but not with Co2+, Ni2+, Cu2+or Zn2+. While the nick closure step with Ca2+becomes rate-limiting which results in the accumulation of DNA-adenylate intermediate, Ni2+only supports intermediate formation to a limited extent. Both Thermus ligases exhibit enhanced mismatch ligation when Mn2+is substituted for Mg2+, but the Tsp. AK16D ligase remains more specific toward perfectly matched substrate.

Mouse testicular extracts process DNA double-strand breaks efficiently by DNA end-to-end joining

DNA double-strand break (DSB) processing was studied in mouse testicular extracts using a defined DSB created by cleaving supercoiled pUC12 DNA at a unique site as the substrate, and analysing the processed DNA by gel electrophoresis. Our results demonstrated that enzymatic activity in the extracts promoted multimerization of DNA and suppressed its circularization. This was distinctly different from T4 DNA ligase activity in the control and therefore the process must be more complex than simple ligation. Efficiency of this end-to-end joining was ATP and Mg(2+)-dependent and was much higher with cohesive (especially with 5') than with blunt ends. On recleaving, the joining was predominantly faithful, especially for cohesive ends; but a detectable fraction of DNA had undergone end-processed joining causing junctional deletions, mostly with blunt ends. Redigestion of end-joined products from time course experiments established that the end-deleted joining occurred concurrent to the faithful joining. Junctional segments were cloned and their restriction analysis confirmed the presence of large deletions from both the sides. These results suggested the association of an end-processing activity (exonuclease/helicase + flap endonuclease) along with the end-joining ligase(s). Suppression of end-edited joining on lowering the reaction temperature to 17 degrees or 14 degrees C, despite efficient faithful joining, indicated that this enzymatic activity is retarded at low temperature. Though the efficiency and fidelity of joining were termini-dependent, the orientation of joining was random. Lack of preference for homologous ends (H:H or T:T), as well as efficient joining of heterologous DNA (pUC12/pBR322) having two different blunt termini, showed that the end joining could occur independent of extensive/terminal homology. Retention of radioactivity on end joining of (alpha-32P)dCTP end-filled cohesive termini, and lack of their junctional cleavability, apparently due to restriction site duplication, suggested direct double strand ligation. Thus it is demonstrated that mouse male germ cells possess an efficient DNA end-joining activity, involving either a major pathway of precise joining, or a minor end-deleted joining, and it seems to be achieved by a multienzymatic complex as suggested also for somatic cells by others. These results show that mammalian male germ cells that are proficient in homologous recombination utilize nonhomologous end-joining (NHEJ) mechanism for DSB processing and therefore NHEJ is a conserved, universal pathway for the vital function of DSB repair.

Fidelity and mutational specificity of uracil-initiated base excision DNA repair synthesis in human glioblastoma cell extracts

The fidelity of DNA synthesis associated with uracil-initiated base excision repair was measured in human whole cell extracts. An M13mp2 lacZalpha DNA-based reversion assay was developed to assess the error frequency of DNA repair synthesis at a site-specific uracil residue. All three possible base substitution errors were detected at the uracil target causing reversion of opal codon 14 in the Escherichia coli lacZalpha gene. Using human glioblastoma U251 whole cell extracts, approximately 50% of the heteroduplex uracil-containing DNA substrate was completely repaired, as determined by the insensitivity of form I DNA reaction products to cleavage by a combined treatment of E. coli uracil-DNA glycosylase and endonuclease IV. The majority of repair occurred by the uracil-initiated base excision repair pathway, since the addition of the bacteriophage PBS2 uracil-DNA glycosylase inhibitor protein to extracts significantly blocked this process. In addition, the formation of repaired form I DNA molecules occurred concurrently with limited DNA synthesis, which was largely restricted to the HinfI DNA fragment initially containing the uracil residue and specific to the uracil-containing DNA strand. Based on the reversion frequency of repaired M13mp2 DNA, the fidelity of DNA repair synthesis at the target was determined to be about one misincorporated nucleotide per 1900 repaired uracil residues. The major class of base substitutions propagated transversion mutations, which were distributed almost equally between T to G and T to A changes in the template. A similar mutation frequency was also observed using whole cell extracts from human colon adenocarcinoma LoVo cells, suggesting that mismatch repair did not interfere with the fidelity measurements.

Fidelity of DNA ligation: a novel experimental approach based on the polymerisation of libraries of oligonucleotides

Complete libraries of oligonucleotides were used as substrates for Thermus thermophilus DNA ligase, on a M13mp18 ssDNA template. A 17mer primer was used to start a polymerisation process. Ladders of ligation products were analysed by gel electrophoresis. Octa-, nona- and decanucleotide libraries were compared. Nonanucleotides were optimum for polymerisation and up to 15 monomers were ligated. The fidelity of incorporation was studied by sequencing 28 clones (2268 bases) of nonanucleotide polymers, 12 monomers in length. Of the ligated monomers, 79% were the correct complementary sequence. In a total of 57 (2.5%) mispaired bases, there was a strong bias to G.T, G.A, G.G and A.G mismatches. Of the mismatches, 86% were found to be purines on the incoming oligonucleotide, of which 71% were G. There is evidence for clustering of mismatches within specific 9mers and at specific positions within these 9mers. The most frequent mismatches were at the 5'-terminus of the oligonucleotide, followed by the central position. We suggest that sequence selection was imposed by the ligase and not just by base pairing interactions. The ligase directs polymerisation in the 3' to 5' direction which we propose is linked to its role in lagging strand DNA replication.

Specificity and fidelity of strand joining by Chlorella virus DNA ligase

Chlorella virus PBCV-1 DNA ligase seals nicked duplex DNA substrates consisting of a 5'-phosphate-terminated strand and a 3'-hydroxyl-terminated strand annealed to a bridging template strand, but cannot ligate a nicked duplex composed of two DNAs annealed on an RNA template. Whereas PBCV-1 ligase efficiently joins a 3'-OH RNA to a 5'-phosphate DNA, it is unable to join a 3'-OH DNA to a 5'-phosphate RNA. The ligase discriminates at the substrate binding step between nicked duplexes containing 5'-phosphate DNA versus 5'-phosphate RNA strands. PBCV-1 ligase readily seals a nicked duplex DNA containing a single ribonucleotide substitution at the reactive 5'-phosphate end. These results suggest a requirement for a B-form helical conformation of the polynucleotide on the 5'-phosphate side of the nick. Single base mismatches at the nick exert disparate effects on DNA ligation efficiency. PBCV-1 ligase tolerates mismatches involving the 5'-phosphate nucleotide, with the exception of 5'-A:G and 5'-G:A mispairs, which reduce ligase activity by two orders of magnitude. Inhibitory configurations at the 3'-OH nucleotide include 3'-G:A, 3'-G:T, 3'-T:T, 3'-A:G, 3'-G:G, 3'-A:C and 3'-C:C. Our findings indicate that Chlorella virus DNA ligase has the potential to affect genome integrity by embedding ribonucleotides in viral DNA and by sealing nicked molecules with mispaired ends, thereby generating missense mutations.

Structure and function of mammalian DNA ligases

DNA joining events are required for the completion of DNA replication, DNA excision repair and genetic recombination. Five DNA ligase activities, I-V, have been purified from mammalian cell extracts and three mammalian LIG genes, LIG1 LIG3 and LIG4, have been cloned. During DNA replication, the joining of Okazaki fragments by the LIG1 gene product appears to be mediated by an interaction with proliferating cell nuclear antigen (PCNA). This interaction may also occur during the completion of mismatch, nucleotide excision and base excision repair (BER). In addition, DNA ligase I participates in a second BER pathway that is carried out by a multiprotein complex in which DNA ligase I interacts directly with DNA polymerase beta. DNA ligase III alpha and DNA ligase III beta, which are generated by alternative splicing of the LIG3 gene, can be distinguished by their ability to bind to the DNA repair protein, XRCC1. The interaction between DNA ligase III alpha and XRCC1, which occurs through BRCT motifs in the C-termini of these polypeptides, implicates this isoform of DNA ligase III in the repair of DNA single-strand breaks and BER. DNA ligase II appears to be a proteolytic fragment of DNA ligase III alpha. The restricted expression of DNA ligase III beta suggests that this enzyme may function in the completion of meiotic recombination or in a postmeiosis DNA repair pathway. Complex formation between DNA ligase IV and the DNA repair protein XRCC4 involves the C-terminal region of DNA ligase IV, which contains two BRCT motifs. This interaction, which stimulates DNA joining activity, implies that DNA ligase IV functions in V(D)J recombination and non-homologous end-joining of DNA double-strand breaks. At the present time, it is not known whether DNA ligase V is derived from one of the known mammalian LIG genes or is the product of a novel gene.

Nick sensing by vaccinia virus DNA ligase requires a 5' phosphate at the nick and occupancy of the adenylate binding site on the enzyme

Vaccinia virus DNA ligase has an intrinsic nick-sensing function. The enzyme discriminates at the substrate binding step between a DNA containing a 5' phosphate and a DNA containing a 5' hydroxyl at the nick. Further insights into nick recognition and catalysis emerge from studies of the active-site mutant K231A, which is unable to form the covalent ligase-adenylate intermediate and hence cannot activate a nicked DNA substrate via formation of the DNA-adenylate intermediate. Nonetheless, K231A does catalyze phosphodiester bond formation at a preadenylated nick. Hence, the active-site lysine of DNA ligase is not required for the strand closure step of the ligation reaction. The K231A mutant binds tightly to nicked DNA-adenylate but has low affinity for a standard DNA nick. The wild-type vaccinia virus ligase, which is predominantly ligase-adenylate, binds tightly to a DNA nick. This result suggests that occupancy of the AMP binding pocket of DNA ligase is essential for stable binding to DNA. Sequestration of an extrahelical nucleotide by DNA-bound ligase is reminiscent of the base-flipping mechanism of target-site recognition and catalysis used by other DNA modification and repair enzymes.

Mammalian DNA ligases

DNA joining enzymes play an essential role in the maintenance of genomic integrity and stability. Three mammalian genes encoding DNA ligases, LIG1, LIG3 and LIG4, have been identified. Since DNA ligase II appears to be derived from DNA ligase III by a proteolytic mechanism, the three LIG genes can account for the four biochemically distinct DNA ligase activities, DNA ligases I, II, III and IV, that have been purified from mammalian cell extracts. It is probable that the specific cellular roles of these enzymes are determined by the proteins with which they interact. The specific involvement of DNA ligase I in DNA replication is mediated by the non-catalytic amino-terminal domain of this enzyme. Furthermore, DNA ligase I participates in DNA base excision repair as a component of a multiprotein complex. Two forms of DNA ligase III are produced by an alternative splicing mechanism. The ubiqitously expressed DNA ligase III-alpha forms a complex with the DNA single-strand break repair protein XRCC1. In contrast, DNA ligase III-beta, which does not interact with XRCC1, is only expressed in male meiotic germ cells, suggesting a role for this isoform in meiotic recombination. At present, there is very little information about the cellular functions of DNA ligase IV.

Creation and removal of embedded ribonucleotides in chromosomal DNA during mammalian Okazaki fragment processing

Mammalian RNase HI has been shown to specifically cleave the initiator RNA of Okazaki fragments at the RNA-DNA junction, leaving a single ribonucleotide attached to the 5'-end of the downstream DNA segment. This monoribonucleotide can then be removed by the mammalian 5'- to 3'-exo-/endonuclease, a RAD2 homolog-1 (RTH-1) class nuclease, also known as flap endonuclease-1 (FEN-1). Although FEN-1/RTH-1 nuclease often requires an upstream primer for efficient activity, the presence of an upstream primer is usually inhibitory or neutral for removal of this 5'-monoribonucleotide. Using model Okazaki fragment substrates, we found that DNA ligase I can seal a 5'-monoribonucleotide into DNA. When both ligase and FEN-1/RTH-1 were present simultaneously, some of the 5'-monoribonucleotides were ligated into DNA, while others were released. Thus, a 5'-monoribonucleotide, particularly one that is made resistant to FEN-1/RTH-1-directed cleavage by extension of an inhibitory upstream primer, can be ligated into the chromosome, despite the presence of FEN-1/RTH-1 nuclease. DNA ligase I was able to seal different monoribonucleotides into the DNA for all substrates tested, with an efficiency of 1-13% that of ligating DNA. These embedded monoribonucleotides can be removed by the combined action of RNase HI, cutting on the 5'-side, and FEN-1/RTH-1 nuclease, cleaving on the 3'-side. After FEN-1/RTH-1 action and extension by polymerization, DNA ligase I can join the entirely DNA strands to complete repair.

Identification of Saccharomyces cerevisiae DNA ligase IV: involvement in DNA double-strand break repair

DNA ligases catalyse the joining of single and double-strand DNA breaks, which is an essential final step in DNA replication, recombination and repair. Mammalian cells have four DNA ligases, termed ligases I-IV. In contrast, other than a DNA ligase I homologue (encoded by CDC9), no other DNA ligases have hitherto been identified in Saccharomyces cerevisiae. Here, we report the identification and characterization of a novel gene, LIG4, which encodes a protein with strong homology to mammalian DNA ligase IV. Unlike CDC9, LIG4 is not essential for DNA replication, RAD52-dependent homologous recombination nor the repair of UV light-induced DNA damage. Instead, it encodes a crucial component of the non-homologous end-joining (NHEJ) apparatus, which repairs DNA double-strand breaks that are generated by ionizing radiation or restriction enzyme digestion: a function which cannot be complemented by CDC9. Lig4p acts in the same DNA repair pathway as the DNA end-binding protein Ku. However, unlike Ku, it does not function in telomere length homeostasis. These findings indicate diversification of function between different eukaryotic DNA ligases. Furthermore, they provide insights into mechanisms of DNA repair and suggest that the NHEJ pathway is highly conserved throughout the eukaryotic kingdom.

Mammalian DNA double-strand break repair protein XRCC4 interacts with DNA ligase IV

BACKGROUND

Mammalian cells deficient in the XRCC4 DNA repair protein are impaired in DNA double-strand break repair and are consequently hypersensitive to ionising radiation. These cells are also defective in site-specific V(D)J recombination, a process that generates the diversity of antigen receptor genes in the developing immune system. These features are shared by cells lacking components of the DNA-dependent protein kinase (DNA-PK). Although the XRCC4 gene has been cloned, the function(s) of XRCC4 in DNA end-joining has remained elusive.

RESULTS

We found that XRCC4 is a nuclear phosphoprotein and was an effective substrate in vitro for DNA-PK. Human XRCC4 associated extremely tightly with another protein(s) even in the presence of 1 M NaCl. Co-immunoprecipitation and adenylylation assays demonstrated that this associated factor was the recently identified human DNA ligase IV. Consistent with this, XRCC4 and DNA ligase IV copurified exclusively and virtually quantitatively over a variety of chromatographic steps. Protein mapping studies revealed that XRCC4 interacted with ligase IV via the unique carboxy-terminal ligase IV extension that comprises two tandem BRCT (BRCA1 carboxyl terminus) homology motifs, which are also found in other DNA repair-associated factors and in the breast cancer susceptibility protein BRCA1.

CONCLUSIONS

Our findings provide a function for the carboxy-terminal region of ligase IV and suggest that BRCT domains of other proteins may mediate contacts between DNA repair components. In addition, our data implicate mammalian ligase IV in V(D)J recombination and the repair of radiation-induced DNA damage, and provide a model for the potentiation of these processes by XRCC4.

Ligation of RNA-containing duplexes by vaccinia DNA ligase

Vaccinia virus DNA ligase repairs nicked duplex DNA substrates consisting of a 5'-phosphate-terminated strand and a 3'-hydroxyl-terminated strand annealed to a bridging template strand. This study addresses the ability of vaccinia DNA ligase to seal nicked substrates containing one or more RNA strands. We found that the viral enzyme rapidly and efficiently joined a 3'-OH RNA to 5'-phosphate DNA when the reacting polynucleotides were annealed to a bridging DNA strand. In contrast, ligation of 3'-OH DNA to 5'-phosphate RNA was slow (0.2% of the rate of RNA-to-DNA ligation) and entailed the accumulation of high levels of RNA-adenylate intermediate. A native gel mobility shift assay showed that vaccinia DNA ligase discriminates at the substrate binding step between ligands containing 5'-phosphate DNA versus 5'-phosphate RNA at the nick. The enzyme displayed weak activity in RNA-to-RNA ligation on a bridging DNA template (0.01% of RNA-to-DNA activity). Vaccinia DNA ligase was incapable of joining two DNAs annealed on an RNA template. These results can be explained by a requirement for B-form helical conformation on the 5'-phosphate side of the nick. The robust RNA-to-DNA strand joining activity underscores the potential for vaccinia DNA ligase to catalyze RNA-based integration of host cell genetic information into the genome of cytoplasmic poxviruses.

Two distinct DNA ligase activities in mitotic extracts of the yeast Saccharomyces cerevisiae

Four biochemically distinct DNA ligases have been identified in mammalian cells. One of these enzymes, DNA ligase I, is functionally homologous to the DNA ligase encoded by the Saccharomyces cerevisiae CDC9 gene. Cdc9 DNA ligase has been assumed to be the only species of DNA ligase in this organism. In the present study we have identified a second DNA ligase activity in mitotic extracts of S. cerevisiae with chromatographic properties different from Cdc9 DNA ligase, which is the major DNA joining activity. This minor DNA joining activity, which contributes 5-10% of the total cellular DNA joining activity, forms a 90 kDa enzyme-adenylate intermediate which, unlike the Cdc9 enzyme-adenylate intermediate, reacts with an oligo (pdT)/poly (rA) substrate. The levels of the minor DNA joining activity are not altered by mutation or by overexpression of the CDC9 gene. Furthermore, the 90 kDa polypeptide is not recognized by a Cdc9 antiserum. Since this minor species does not appear to be a modified form of Cdc9 DNA ligase, it has been designated as S. cerevisiae DNA ligase II. Based on the similarities in polynucleotide substrate specificity, this enzyme may be the functional homolog of mammalian DNA ligase III or IV.