Biochemical and genetic analysis of the four DNA ligases of mycobacteria

Mycobacterium tuberculosis encodes an NAD(+)-dependent DNA ligase (LigA) plus three distinct ATP-dependent ligase homologs (LigB, LigC, and LigD). Here we purify and characterize the multiple DNA ligase enzymes of mycobacteria and probe genetically whether the ATP-dependent ligases are required for growth of M. tuberculosis. We find significant differences in the reactivity of mycobacterial ligases with a nicked DNA substrate, whereby LigA and LigB display vigorous nick sealing activity in the presence of NAD(+) and ATP, respectively, whereas LigC and LigD, which have ATP-specific adenylyltransferase activity, display weak nick joining activity and generate high levels of the DNA-adenylate intermediate. All four of the mycobacterial ligases are monomeric enzymes. LigA has a low K(m) for NAD(+) (1 microm) and is sensitive to a recently described pyridochromanone inhibitor of NAD(+)-dependent ligases. LigA is able to sustain growth of Saccharomyces cerevisiae in lieu of the essential yeast ligase Cdc9, but LigB, LigC, and LigD are not. LigB is distinguished by its relatively high K(m) for ATP (0.34 mm) and its dependence on a distinctive N-terminal domain for nick joining. None of the three ATP-dependent ligases are essential for mycobacterial growth. M. tuberculosis ligDDelta cells are defective in nonhomologous DNA end joining.     

Structure-guided mutational analysis of the OB, HhH, and BRCT domains of Escherichia coli DNA ligase

NAD(+)-dependent DNA ligases (LigAs) are ubiquitous in bacteria and essential for growth. LigA enzymes have a modular structure in which a central catalytic core composed of nucleotidyltransferase and oligonucleotide-binding (OB) domains is linked via a tetracysteine zinc finger to distal helix-hairpin-helix (HhH) and BRCT (BRCA1-like C-terminal) domains. The OB and HhH domains contribute prominently to the protein clamp formed by LigA around nicked duplex DNA. Here we conducted a structure-function analysis of the OB and HhH domains of Escherichia coli LigA by alanine scanning and conservative substitutions, entailing 43 mutations at 22 amino acids. We thereby identified essential functional groups in the OB domain that engage the DNA phosphodiester backbone flanking the nick (Arg(333)); penetrate the minor grove and distort the nick (Val(383) and Ile(384)); or stabilize the OB fold (Arg(379)). The essential constituents of the HhH domain include: four glycines (Gly(455), Gly(489), Gly(521), Gly(553)), which bind the phosphate backbone across the minor groove at the outer margins of the LigA-DNA interface; Arg(487), which penetrates the minor groove at the outer margin on the 3 (R)-OH side of the nick; and Arg(446), which promotes protein clamp formation via contacts to the nucleotidyltransferase domain. We find that the BRCT domain is required in its entirety for effective nick sealing and AMP-dependent supercoil relaxation.     

Analysis of ligation and DNA binding by Escherichia coli DNA ligase (LigA)

NAD(+)-dependent DNA ligases are essential enzymes in bacteria, with the most widely studied of this class of enzymes being LigA from Escherichia coli. NAD(+)-dependent DNA ligases comprise several discrete structural domains, including a BRCT domain at the C-terminus that is highly-conserved in this group of proteins. The over-expression and purification of various fragments of E. coli LigA allowed the investigation of the different domains in DNA-binding and ligation by this enzyme. Compared to the full-length protein, the deletion of the BRCT domain from LigA reduced in vitro ligation activity by 3-fold and also reduced DNA binding. Using an E. coli strain harbouring a temperature-sensitive mutation of ligA, the over-expression of protein with its BRCT domain deleted enabled growth at the non-permissive temperature. In gel-mobility shift experiments, the isolated BRCT domain bound DNA in a stable manner and to a wider range of DNA molecules compared to full LigA. Thus, the BRCT domain of E. coli LigA can bind DNA, but it is not essential for DNA nick-joining activity in vitro or in vivo.     

Conserved residues in domain Ia are required for the reaction of Escherichia coli DNA ligase with NAD+.

NAD(+)-dependent DNA ligases are present in all bacteria and are essential for growth. Their unique substrate specificity compared with ATP-dependent human DNA ligases recommends the NAD(+) ligases as targets for the development of new broad-spectrum antibiotics. A plausible strategy for drug discovery is to identify the structural components of bacterial DNA ligase that interact with NAD(+) and then to isolate small molecules that recognize these components and thereby block the binding of NAD(+) to the ligase. The limitation to this strategy is that the structural determinants of NAD(+) specificity are not known. Here we show that reactivity of Escherichia coli DNA ligase (LigA) with NAD(+) requires N-terminal domain Ia, which is unique to, and conserved among, NAD(+) ligases but absent from ATP-dependent ligases. Deletion of domain Ia abolished the sealing of 3'-OH/5'-PO(4) nicks and the reaction with NAD(+) to form ligase-adenylate but had no effect on phosphodiester formation at a preadenylated nick. Alanine substitutions at conserved residues within domain Ia either reduced (His-23, Tyr-35) or abolished (Tyr-22, Asp-32, Asp-36) sealing of a 5'-PO(4) nick and adenylyl transfer from NAD(+) without affecting ligation of pre-formed DNA-adenylate. We suggest that these five side chains comprise a binding site for the nicotinamide mononucleotide moiety of NAD(+). Structure-activity relationships were clarified by conservative substitutions.     

NAD+-dependent DNA ligase (Rv3014c) from Mycobacterium tuberculosis: novel structure-function relationship and identification of a specific inhibitor

Mycobacterium tuberculosis codes for an essential NAD+-dependent DNA ligase (MtuLigA) which is a novel, validated, and attractive drug target. We created mutants of the enzyme by systematically deleting domains from the C-terminal end of the enzyme to probe for their functional roles in the DNA nick joining reaction. Deletion of just the BRCT domain from MtuLigA resulted in total loss of activity in in vitro assays. However, the mutant could form an AMP-ligase intermediate that suggests that the defects caused by deletion of the BRCT domain occur primarily at steps after enzyme adenylation. Furthermore, genetic complementation experiments using a LigA deficient E. coli strain demonstrates that the BRCT domain of MtuLigA is necessary for bacterial survival in contrast to E. coli and T. filiformis LigA, respectively. We also report the identification, through virtual screening, of a novel N-substituted tetracyclic indole that competes with NAD+ and inhibits the enzyme with IC50 in the low muM range. It exhibits approximately 15-fold better affinity for MtuLigA compared to human DNA ligase I. In vivo assays using LigA deficient S. typhimurium and E. coli strains suggest that the observed antibacterial activity of the inhibitor arises from specific inhibition of LigA over ATP ligases in the bacteria. In silico ligand-docking studies suggest that the exquisite specificity of the inhibitor arises on account of its mimicking the interactions of NAD+ with MtuLigA. An analysis of conserved water in the binding site of the enzyme suggests strategies for synthesis of improved inhibitors with better specificity and potency.     

Mycobacterium tuberculosis NAD+-dependent DNA ligase is selectively inhibited by glycosylamines compared with human DNA ligase I

DNA ligases are important enzymes which catalyze the joining of nicks between adjacent bases of double-stranded DNA. NAD+-dependent DNA ligases (LigA) are essential in bacteria and are absent in humans. They have therefore been identified as novel, validated and attractive drug targets. Using virtual screening against an in-house database of compounds and our recently determined crystal structure of the NAD+ binding domain of the Mycobacterium tuberculosis LigA, we have identified N1, N(n)-bis-(5-deoxy-alpha-D-xylofuranosylated) diamines as a novel class of inhibitors for this enzyme. Assays involving M.tuberculosis LigA, T4 ligase and human DNA ligase I show that these compounds specifically inhibit LigA from M.tuberculosis. In vitro kinetic and inhibition assays demonstrate that the compounds compete with NAD+ for binding and inhibit enzyme activity with IC50 values in the microM range. Docking studies rationalize the observed specificities and show that among several glycofuranosylated diamines, bis xylofuranosylated diamines with aminoalkyl and 1, 3-phenylene carbamoyl spacers mimic the binding modes of NAD+ with the enzyme. Assays involving LigA-deficient bacterial strains show that in vivo inhibition of ligase by the compounds causes the observed antibacterial activities. They also demonstrate that the compounds exhibit in vivo specificity for LigA over ATP-dependent ligase. This class of inhibitors holds out the promise of rational development of new anti-tubercular agents.     

ATP- and NAD+-dependent DNA ligases share an essential function in the halophilic archaeon Haloferax volcanii

DNA ligases join the ends of DNA molecules during replication, repair and recombination. ATP-dependent ligases are found predominantly in the eukarya and archaea whereas NAD+-dependent DNA ligases are found only in the eubacteria and in entomopoxviruses. Using the genetically tractable halophile Haloferax volcanii as a model system, we describe the first genetic analysis of archaeal DNA ligase function. We show that the Hfx. volcanii ATP-dependent DNA ligase family member, LigA, is non-essential for cell viability, raising the question of how DNA strands are joined in its absence. We show that Hfx. volcanii also encodes an NAD+-dependent DNA ligase family member, LigN, the first such enzyme to be identified in the archaea, and present phylogenetic analysis indicating that the gene encoding this protein has been acquired by lateral gene transfer (LGT) from eubacteria. As with LigA, we show that LigN is also non-essential for cell viability. Simultaneous inactivation of both proteins is lethal, however, indicating that they now share an essential function. Thus the LigN protein acquired by LGT appears to have been co-opted as a back-up for LigA function, perhaps to provide additional ligase activity under conditions of high genotoxic stress.     

Structural basis for nick recognition by a minimal pluripotent DNA ligase

Chlorella virus DNA ligase, the smallest eukaryotic ligase known, has pluripotent biological activity and an intrinsic nick-sensing function, despite having none of the accessory domains found in cellular ligases. A 2.3-A crystal structure of the Chlorella virus ligase-AMP intermediate bound to duplex DNA containing a 3'-OH-5'-PO4 nick reveals a new mode of DNA envelopment, in which a short surface loop emanating from the OB domain forms a beta-hairpin 'latch' that inserts into the DNA major groove flanking the nick. A network of interactions with the 3'-OH and 5'-PO4 termini in the active site illuminates the DNA adenylylation mechanism and the crucial roles of AMP in nick sensing and catalysis. Addition of a divalent cation triggered nick sealing in crystallo, establishing that the nick complex is a bona fide intermediate in the DNA repair pathway.     

Structure of the adenylation domain of an NAD+-dependent DNA ligase.

BACKGROUND: DNA ligases catalyse phosphodiester bond formation between adjacent bases in nicked DNA, thereby sealing the nick. A key step in the catalytic mechanism is the formation of an adenylated DNA intermediate. The adenyl group is derived from either ATP (in eucaryotes and archaea) or NAD+4 (in bacteria). This difference in cofactor specificity suggests that DNA ligase may be a useful antibiotic target. RESULTS: The crystal structure of the adenylation domain of the NAD+-dependent DNA ligase from Bacillus stearothermophilus has been determined at 2.8 A resolution. Despite a complete lack of detectable sequence similarity, the fold of the central core of this domain shares homology with the equivalent region of ATP-dependent DNA ligases, providing strong evidence for the location of the NAD+-binding site. CONCLUSIONS: Comparison of the structure of the NAD+4-dependent DNA ligase with that of ATP-dependent ligases and mRNA-capping enzymes demonstrates the manifold utilisation of a conserved nucleotidyltransferase domain within this family of enzymes. Whilst this conserved core domain retains a common mode of nucleotide binding and activation, it is the additional domains at the N terminus and/or the C terminus that provide the alternative specificities and functionalities in the different members of this enzyme superfamily.     

Two DNA-binding and nick recognition modules in human DNA ligase III

Human DNA ligase III contains an N-terminal zinc finger domain that binds to nicks and gaps in DNA. This small domain has been described as a DNA nick sensor, but it is not required for DNA nick joining activity in vitro. In light of new structural information for mammalian ligases, we measured the DNA binding affinity and specificity of each domain of DNA ligase III. These studies identified two separate, independent DNA-binding modules in DNA ligase III that each bind specifically to nicked DNA over intact duplex DNA. One of these modules comprises the zinc finger domain and DNA-binding domain, which function together as a single DNA binding unit. The catalytic core of ligase III is the second DNA nick-binding module. Both binding modules are required for ligation of blunt ended DNA substrates. Although the zinc finger increases the catalytic efficiency of nick ligation, it appears to occupy the same binding site as the DNA ligase III catalytic core. We present a jackknife model for ligase III that posits conformational changes during nick sensing and ligation to extend the versatility of the enzyme.     

Structure-guided mutational analysis of the nucleotidyltransferase domain of Escherichia coli NAD+-dependent DNA ligase (LigA)

NAD+-dependent DNA ligase (LigA) is essential for bacterial growth and a potential target for antimicrobial drug discovery. Here we queried the role of 14 conserved amino acids of Escherichia coli LigA by alanine scanning and thereby identified five new residues within the nucleotidyltransferase domain as being essential for LigA function in vitro and in vivo. Structure activity relationships were determined by conservative mutagenesis for the Glu-173, Arg-200, Arg-208, and Arg-277 side chains, as well as four other essential side chains that had been identified previously (Lys-115, Asp-117, Asp-285, and Lys-314). In addition, we identified Lys-290 as important for LigA activity. Reference to the structure of Enterococcus faecalis LigA allowed us to discriminate three classes of essential/important side chains that: (i) contact NAD+ directly (Lys-115, Glu-173, Lys-290, and Lys-314); (ii) comprise the interface between the NMN-binding domain (domain Ia) and the nucleotidyltransferase domain or comprise part of a nick-binding site on the surface of the nucleotidyltransferase domain (Arg-200 and Arg-208); or (iii) stabilize the active site fold of the nucleotidyltransferase domain (Arg-277). Analysis of mutational effects on the isolated ligase adenylylation and phosphodiester formation reactions revealed different functions for essential side chains at different steps of the DNA ligase pathway, consistent with the proposal that the active site is serially remodeled as the reaction proceeds.     

Identification through structure-based methods of a bacterial NAD+-dependent DNA ligase inhibitor that avoids known resistance mutations

In an attempt to identify novel inhibitors of NAD⁺-dependent DNA ligase (LigA) that are not affected by a known resistance mutation in the adenosine binding pocket, a detailed analysis of the binding sites of a variety of bacterial ligases was performed. This analysis revealed several similarities to the adenine binding region of kinases, which enabled a virtual screen of known kinase inhibitors. From this screen, a thienopyridine scaffold was identified that was shown to inhibit bacterial ligase. Further characterization through structure and enzymology revealed the compound was not affected by a previously disclosed resistance mutation in Streptococcus pneumoniae LigA, Leu75Phe. A subsequent medicinal chemistry program identified substitutions that resulted in an inhibitor with moderate activity across various Gram-positive bacterial LigA enzymes.     

Characterization of a thermophilic ATP-dependent DNA ligase from the euryarchaeon Pyrococcus horikoshii

Archaea encode a DNA ligase composed of a C-terminal catalytic domain typical of ATP-dependent ligases plus an N-terminal domain similar to that found in eukaryotic cellular and poxvirus DNA ligases. All archaeal DNA ligases characterized to date have ATP-dependent adenylyltransferase and nick-joining activities. However, recent reports of dual-specificity ATP/NAD+ ligases in two Thermococcus species and Pyrococcus abyssi and an ATP/ADP ligase in Aeropyrum pernix raise the prospect that certain archaeal enzymes might exemplify an undifferentiated ancestral stage in the evolution of ligase substrate specificity. Here we analyze the biochemical properties of Pyrococcus horikoshii DNA ligase. P. horikoshii ligase catalyzes auto-adenylylation and nick sealing in the presence of a divalent cation and ATP; it is unable to utilize NAD+ or ADP to promote ligation in lieu of ATP. P. horikoshii ligase is thermophilic in vitro, with optimal adenylyltransferase activity at 90 degrees C and nick-joining activity at 70 to 90 degrees C. P. horikoshii ligase resembles the ligases of Methanobacterium thermautotrophicum and Sulfolobus shibatae in its strict specificity for ATP.     

How an RNA ligase discriminates RNA versus DNA damage

T4 RNA ligase 2 (Rnl2) exemplifies a family of RNA-joining enzymes that includes protozoan RNA-editing ligases. Rnl2 efficiently seals 3'-OH/5'-PO4 RNA nicks in either a duplex RNA or an RNA:DNA hybrid but cannot seal DNA nicks. RNA specificity arises from a requirement for at least two ribonucleotides immediately flanking the 3'-OH of the nick; the rest of the nicked duplex can be replaced by DNA. The terminal 2'-OH at the nick is important for the attack of the 3'-OH on the 5'-adenylated strand to form a phosphodiester, but dispensable for nick recognition and adenylylation of the 5'-PO4 strand. The penultimate 2'-OH is important for nick recognition. Stable binding of Rnl2 at a nick depends on contacts to both the N-terminal adenylyltransferase domain and its signature C-terminal domain. Nick sensing also requires adenylylation of Rnl2. These results provide insights to the evolution of nucleic acid repair systems.     

Bacterial nonhomologous end joining ligases preferentially seal breaks with a 3'-OH monoribonucleotide

Many bacterial species have a nonhomologous end joining system of DNA repair driven by dedicated DNA ligases (LigD and LigC). LigD is a multifunctional enzyme composed of a ligase domain fused to two other catalytic modules: a polymerase that preferentially adds ribonucleotides to double-strand break ends and a phosphoesterase that trims 3'-oligoribonucleotide tracts until only a single 3'-ribonucleotide remains. LigD and LigC have a feeble capacity to seal 3'-OH/5'-PO(4) DNA nicks. Here, we report that nick sealing by LigD and LigC enzymes is stimulated by the presence of a single ribonucleotide at the broken 3'-OH end. The ribonucleotide effect on LigD and LigC is specific for the 3'-terminal nucleotide and is either diminished or abolished when additional vicinal ribonucleotides are present. No such 3'-ribonucleotide effect is observed for bacterial LigA or Chlorella virus ligase. We found that in vitro repair of a double-strand break by Pseudomonas LigD requires the polymerase module and results in incorporation of an alkali-labile ribonucleotide at the repair junction. These results illuminate an underlying logic for the domain organization of LigD, whereby the polymerase and phosphoesterase domains can heal the broken 3'-end to generate the monoribonucleotide terminus favored by the nonhomologous end joining ligases.     

NAD+-dependent DNA ligase encoded by a eukaryotic virus.

We report the production, purification, and characterization of an NAD(+)-dependent DNA ligase encoded by the Amsacta moorei entomopoxvirus (AmEPV), the first example of an NAD(+) ligase from a source other than eubacteria. AmEPV ligase lacks the zinc-binding tetracysteine domain and the BRCT domain that are present in all eubacterial NAD(+) ligases. Nonetheless, the monomeric 532-amino acid AmEPV ligase catalyzed strand joining on a singly nicked DNA in the presence of a divalent cation and NAD(+). Neither ATP, dATP, nor any other nucleoside triphosphate could substitute for NAD(+). Structure probing by limited proteolysis showed that AmEPV ligase is punctuated by a surface-accessible loop between the nucleotidyltransferase domain, which is common to all ligases, and the N-terminal domain Ia, which is unique to the NAD(+) ligases. Deletion of domain Ia of AmEPV ligase abolished the sealing of 3'-OH/5'-PO(4) nicks and the reaction with NAD(+) to form ligase-adenylate, but had no effect on phosphodiester formation at a pre-adenylated nick. Alanine substitutions at residues within domain Ia either reduced (Tyr(39), Tyr(40), Asp(48), and Asp(52)) or abolished (Tyr(51)) sealing of a 5'-PO(4) nick and adenylyl transfer from NAD(+) without affecting ligation of DNA-adenylate. We conclude that: (i) NAD(+)-dependent ligases exist in the eukaryotic domain of the phylogenetic tree; and (ii) ligase structural domain Ia is a determinant of cofactor specificity and is likely to interact directly with the nicotinamide mononucleotide moiety of NAD(+).     

Biochemical characterisation of LigN, an NAD+-dependent DNA ligase from the halophilic euryarchaeon Haloferax volcanii that displays maximal in vitro activity at high salt concentrations

Background  

DNA ligases are required for DNA strand joining in all forms of cellular life. NAD⁺-dependent DNA ligases are found primarily in eubacteria but also in some eukaryotic viruses, bacteriophage and archaea. Among the archaeal NAD⁺-dependent DNA ligases is the LigN enzyme of the halophilic euryarchaeon Haloferax volcanii, the gene for which was apparently acquired by Hfx.volcanii through lateral gene transfer (LGT) from a halophilic eubacterium. Genetic studies show that the LGT-acquired LigN enzyme shares an essential function with the native Hfx.volcanii ATP-dependent DNA ligase protein LigA.     

Dynamic mechanism of nick recognition by DNA ligase.

DNA ligases are the enzymes responsible for the repair of single-stranded and double-stranded nicks in dsDNA. DNA ligases are structurally similar, possibly sharing a common molecular mechanism of nick recognition and ligation catalysis. This mechanism remains unclear, in part because the structure of ligase in complex with dsDNA has yet to be solved. DNA ligases share common structural elements with DNA polymerases, which have been cocrystallized with dsDNA. Based on the observed DNA polymerase-dsDNA interactions, we propose a mechanism for recognition of a single-stranded nick by DNA ligase. According to this mechanism, ligase induces a B-to-A DNA helix transition of the enzyme-bound dsDNA motif, which results in DNA contraction, bending and unwinding. For non-nicked dsDNA, this transition is reversible, leading to dissociation of the enzyme. For a nicked dsDNA substrate, the contraction of the enzyme-bound DNA motif (a) triggers an opened-closed conformational change of the enzyme, and (b) forces the motif to accommodate the strained A/B-form hybrid conformation, in which the nicked strand tends to retain a B-type helix, while the non-nicked strand tends to form a shortened A-type helix. We propose that this conformation is the catalytically competent transition state, which leads to the formation of the DNA-AMP intermediate and to the subsequent sealing of the nick.     

An RNA ligase from Deinococcus radiodurans

Although DNA repair pathways have been the focus of much attention, there is an emerging appreciation that distinct pathways exist to maintain or manipulate RNA structure in response to breakage events. Here we identify an RNA ligase (DraRnl) from the radiation-resistant bacterium Deinococcus radiodurans. DraRnl seals 3'-OH/5'-PO4 RNA nicks in either a duplex RNA or an RNA: DNA hybrid, but it cannot seal 3'-OH/5'-PO4 DNA nicks. The specificity of DraRnl arises from a requirement for RNA on the 3'-OH side of the nick. DraRnl is a 342-amino acid monomeric protein with a distinctive structure composed of a C-terminal adenylyltransferase domain linked to an N-terminal module that resembles the OB-fold of phenylalanyl-tRNA synthetases. RNA sealing activity was abolished by mutation of the predicted lysine adenylylation site (Lys-165) in the C-terminal domain and was reduced by an order of magnitude by deletion of the N-terminal OB module. Our findings highlight the existence of an RNA repair capacity in bacteria and support the hypothesis that contemporary DNA ligases, RNA ligases, and RNA capping enzymes evolved by the fusion of ancillary effector domains to an ancestral catalytic module involved in RNA repair.