Essential constituents of the 3'-phosphoesterase domain of bacterial DNA ligase D, a nonhomologous end-joining enzyme

LigD: A Structural Guide to the Multi-Tool of Bacterial Non-Homologous End Joining

DNA double-strand breaks are the most lethal form of damage for living organisms. The non-homologous end joining (NHEJ) pathway can repair these breaks without the use of a DNA template, making it a critical repair mechanism when DNA is not replicating, but also a threat to genome integrity. NHEJ requires proteins to anchor the DNA double-strand break, recruit additional repair proteins, and then depending on the damage at the DNA ends, fill in nucleotide gaps or add or remove phosphate groups before final ligation. In eukaryotes, NHEJ uses a multitude of proteins to carry out processing and ligation of the DNA double-strand break. Bacterial NHEJ, though, accomplishes repair primarily with only two proteins-Ku and LigD. While Ku binds the initial break and recruits LigD, it is LigD that is the primary DNA end processing machinery. Up to three enzymatic domains reside within LigD, dependent on the bacterial species. These domains are a polymerase domain, to fill in nucleotide gaps with a preference for ribonucleotide addition; a phosphoesterase domain, to generate a 3'-hydroxyl DNA end; and the ligase domain, to seal the phosphodiester backbone. To date, there are no experimental structures of wild-type LigD, but there are x-ray and nuclear magnetic resonance structures of the individual enzymatic domains from different bacteria and archaea, along with structural predictions of wild-type LigD via AlphaFold. In this review, we will examine the structures of the independent domains of LigD from different bacterial species and the contributions these structures have made to understanding the NHEJ repair mechanism. We will then examine how the experimental structures of the individual LigD enzymatic domains combine with structural predictions of LigD from different bacterial species and postulate how LigD coordinates multiple enzymatic activities to carry out DNA double-strand break repair in bacteria.

Bacterial NHEJ: a never ending story

Double-strand breaks (DSBs) are the most detrimental DNA damage encountered by bacterial cells. DBSs can be repaired by homologous recombination thanks to the availability of an intact DNA template or by Non-Homologous End Joining (NHEJ) when no intact template is available. Bacterial NHEJ is performed by sets of proteins of growing complexity from Bacillus subtilis and Mycobacterium tuberculosis to Streptomyces and Sinorhizobium meliloti. Here, we discuss the contribution of these models to the understanding of the bacterial NHEJ repair mechanism as well as the involvement of NHEJ partners in other DNA repair pathways. The importance of NHEJ and of its complexity is discussed in the perspective of regulation through the biological cycle of the bacteria and in response to environmental stimuli. Finally, we consider the role of NHEJ in genome evolution, notably in horizontal gene transfer.

Double-Strand DNA Break Repair in Mycobacteria

Discontinuity of both strands of the chromosome is a lethal event in all living organisms because it compromises chromosome replication. As such, a diversity of DNA repair systems has evolved to repair double-strand DNA breaks (DSBs). In part, this diversity of DSB repair systems has evolved to repair breaks that arise in diverse physiologic circumstances or sequence contexts, including cellular states of nonreplication or breaks that arise between repeats. Mycobacteria elaborate a set of three genetically distinct DNA repair pathways: homologous recombination, nonhomologous end joining, and single-strand annealing. As such, mycobacterial DSB repair diverges substantially from the standard model of prokaryotic DSB repair and represents an attractive new model system. In addition, the presence in mycobacteria of a DSB repair system that can repair DSBs in nonreplicating cells (nonhomologous end joining) or when DSBs arise between repeats (single-strand annealing) has clear potential relevance to Mycobacterium tuberculosis pathogenesis, although the exact role of these systems in M. tuberculosis pathogenesis is still being elucidated. In this article we will review the genetics of mycobacterial DSB repair systems, focusing on recent insights.

Analysis of the distribution and evolution of the ATP-dependent DNA ligases of bacteria delineates a distinct phylogenetic group 'Lig E'

Prior to the discovery of a minimal ATP-dependent DNA ligase in Haemophilus influenzae, bacteria were thought to only possess a NAD-dependent ligase, which was involved in sealing of Okazaki fragments. We now know that a diverse range of bacterial species possess up to six of these accessory bacterial ATP-dependent DNA ligases (b-ADLs), which vary in size and enzymatic domain associations. Here we compare the domain structure of different types of b-ADLs and investigate their distribution among the bacterial domain to describe possible evolutionary trajectories that gave rise to the sequence and structural diversity of these enzymes. Previous biochemical and genetic analyses have delineated three main classes of these enzymes: Lig B, Lig C and Lig D, which appear to have descended from a common ancestor within the bacterial domain. In the present study, we delineate a fourth group of b-ADLs, Lig E, which possesses a number of unique features at the primary and tertiary structural levels. The biochemical characteristics, domain structure and inferred extracellular location sets this group apart from the other b-ADLs. The results presented here indicate that the Lig E type ligases were horizontally transferred into bacteria in a separate event from other b-ADLs possibly from a bacteriophage.

Molecular basis for DNA strand displacement by NHEJ repair polymerases

The non-homologous end-joining (NHEJ) pathway repairs DNA double-strand breaks (DSBs) in all domains of life. Archaea and bacteria utilize a conserved set of multifunctional proteins in a pathway termed Archaeo-Prokaryotic (AP) NHEJ that facilitates DSB repair. Archaeal NHEJ polymerases (Pol) are capable of strand displacement synthesis, whilst filling DNA gaps or partially annealed DNA ends, which can give rise to unligatable intermediates. However, an associated NHEJ phosphoesterase (PE) resects these products to ensure that efficient ligation occurs. Here, we describe the crystal structures of these archaeal (Methanocella paludicola) NHEJ nuclease and polymerase enzymes, demonstrating their strict structural conservation with their bacterial NHEJ counterparts. Structural analysis, in conjunction with biochemical studies, has uncovered the molecular basis for DNA strand displacement synthesis in AP-NHEJ, revealing the mechanisms that enable Pol and PE to displace annealed bases to facilitate their respective roles in DSB repair.

NHEJ enzymes LigD and Ku participate in stationary-phase mutagenesis in Pseudomonas putida

Under growth-restricting conditions bacterial populations can rapidly evolve by a process known as stationary-phase mutagenesis. Bacterial nonhomologous end-joining (NHEJ) system which consists of the DNA-end-binding enzyme Ku and the multifunctional DNA ligase LigD has been shown to be important for survival of bacteria especially during quiescent states, such as late stationary-phase populations or sporulation. In this study we provide genetic evidence that NHEJ enzymes participate in stationary-phase mutagenesis in a population of carbon-starved Pseudomonas putida. Both the absence of LigD or Ku resulted in characteristic spectra of stationary-phase mutations that differed from each other and also from the wild-type spectrum. This indicates that LigD and Ku may participate also in mutagenic pathways that are independent from each other. Our results also imply that both phosphoesterase (PE) and polymerase (POL) domains of the LigD protein are involved in the occurrence of mutations in starving P. putida. The participation of both Ku and LigD in the occurrence of stationary-phase mutations was further supported by the results of the analysis of mutation spectra in stationary-phase sigma factor RpoS-minus background. The spectra of mutations identified in the RpoS-minus background were also distinct if LigD or Ku was absent. Interestingly, the effects of the presence of these enzymes on the frequency of occurrence of certain types of mutations were different or even opposite in the RpoS-proficient and deficient backgrounds. These results imply that RpoS affects performance of mutagenic pathways in starving P. putida that utilize LigD and/or Ku.

Ribonucleotides in bacterial DNA

In all living cells, DNA is the storage medium for genetic information. Being quite stable, DNA is well-suited for its role in storage and propagation of information, but RNA is also covalently included in DNA through various mechanisms. Recent studies also demonstrate useful aspects of including ribonucleotides in the genome during repair. Therefore, our understanding of the consequences of RNA inclusion into bacterial genomic DNA is just beginning, but with its high frequency of occurrence the consequences and potential benefits are likely to be numerous and diverse. In this review, we discuss the processes that cause ribonucleotide inclusion in genomic DNA, the pathways important for ribonucleotide removal and the consequences that arise should ribonucleotides remain nested in genomic DNA.

Enzyme-adenylate structure of a bacterial ATP-dependent DNA ligase with a minimized DNA-binding surface

The enzyme–adenylate structure of a bacterial ATP-dependent DNA ligase (ADL), which does not have any additional DNA-binding domains, is similar to minimal viral ADLs that comprise only the core catalytic domains. The bacterial ADL also lacks the unstructured loops which are involved in DNA binding in the viral ADLs, implying that it must instead use short well structured motifs of the core domains to engage its substrate.

DNA ligases are a structurally diverse class of enzymes which share a common catalytic core and seal breaks in the phosphodiester backbone of double-stranded DNA via an adenylated intermediate. Here, the structure and activity of a recombinantly produced ATP-dependent DNA ligase from the bacterium Psychromonas sp. strain SP041 is described. This minimal-type ligase, like its close homologues, is able to ligate singly nicked double-stranded DNA with high efficiency and to join cohesive-ended and blunt-ended substrates to a more limited extent. The 1.65 Å resolution crystal structure of the enzyme–adenylate complex reveals no unstructured loops or segments, and suggests that this enzyme binds the DNA without requiring full encirclement of the DNA duplex. This is in contrast to previously characterized minimal DNA ligases from viruses, which use flexible loop regions for DNA interaction. The Psychromonas sp. enzyme is the first structure available for the minimal type of bacterial DNA ligases and is the smallest DNA ligase to be crystallized to date.

DNA ligase C1 mediates the LigD-independent nonhomologous end-joining pathway of Mycobacterium smegmatis

Nonhomologous end joining (NHEJ) is a recently described bacterial DNA double-strand break (DSB) repair pathway that has been best characterized for mycobacteria. NHEJ can religate transformed linear plasmids, repair ionizing radiation (IR)-induced DSBs in nonreplicating cells, and seal I-SceI-induced chromosomal DSBs. The core components of the mycobacterial NHEJ machinery are the DNA end binding protein Ku and the polyfunctional DNA ligase LigD. LigD has three autonomous enzymatic modules: ATP-dependent DNA ligase (LIG), DNA/RNA polymerase (POL), and 3' phosphoesterase (PE). Although genetic ablation of ku or ligD abolishes NHEJ and sensitizes nonreplicating cells to ionizing radiation, selective ablation of the ligase activity of LigD in vivo only mildly impairs NHEJ of linearized plasmids, indicating that an additional DNA ligase can support NHEJ. Additionally, the in vivo role of the POL and PE domains in NHEJ is unclear. Here we define a LigD ligase-independent NHEJ pathway in Mycobacterium smegmatis that requires the ATP-dependent DNA ligase LigC1 and the POL domain of LigD. Mycobacterium tuberculosis LigC can also support this backup NHEJ pathway. We also demonstrate that, although dispensable for efficient plasmid NHEJ, the activities of the POL and PE domains are required for repair of IR-induced DSBs in nonreplicating cells. These findings define the genetic requirements for a LigD-independent NHEJ pathway in mycobacteria and demonstrate that all enzymatic functions of the LigD protein participate in NHEJ in vivo.

The minimal Bacillus subtilis nonhomologous end joining repair machinery

It is widely accepted that repair of double-strand breaks in bacteria that either sporulate or that undergo extended periods of stationary phase relies not only on homologous recombination but also on a minimal nonhomologous end joining (NHEJ) system consisting of a dedicated multifunctional ATP-dependent DNA Ligase D (LigD) and the DNA-end-binding protein Ku. Bacillus subtilis is one of the bacterial members with a NHEJ system that contributes to genome stability during the stationary phase and germination of spores, having been characterized exclusively in vivo. Here, the in vitro analysis of the functional properties of the purified B. subtilis LigD (BsuLigD) and Ku (BsuKu) proteins is presented. The results show that the essential biochemical signatures exhibited by BsuLigD agree with its proposed function in NHEJ: i) inherent polymerization activity showing preferential insertion of NMPs, ii) specific recognition of the phosphate group at the downstream 5′ end, iii) intrinsic ligase activity, iv) ability to promote realignments of the template and primer strands during elongation of mispaired 3′ ends, and v) it is recruited to DNA by BsuKu that stimulates the inherent polymerization and ligase activities of the enzyme allowing it to deal with and to hold different and unstable DNA realignments.

Ribonucleolytic resection is required for repair of strand displaced nonhomologous end-joining intermediates

Nonhomologous end-joining (NHEJ) pathways repair DNA double-strand breaks (DSBs) in eukaryotes and many prokaryotes, although it is not reported to operate in the third domain of life, archaea. Here, we describe a complete NHEJ complex, consisting of DNA ligase (Lig), polymerase (Pol), phosphoesterase (PE), and Ku from a mesophillic archaeon, Methanocella paludicola (Mpa). Mpa Lig has limited DNA nick-sealing activity but is efficient in ligating nicks containing a 3' ribonucleotide. Mpa Pol preferentially incorporates nucleoside triphosphates onto a DNA primer strand, filling DNA gaps in annealed breaks. Mpa PE sequentially removes 3' phosphates and ribonucleotides from primer strands, leaving a ligatable terminal 3' monoribonucleotide. These proteins, together with the DNA end-binding protein Ku, form a functional NHEJ break-repair apparatus that is highly homologous to the bacterial complex. Although the major roles of Pol and Lig in break repair have been reported, PE's function in NHEJ has remained obscure. We establish that PE is required for ribonucleolytic resection of RNA intermediates at annealed DSBs. Polymerase-catalyzed strand-displacement synthesis on DNA gaps can result in the formation of nonligatable NHEJ intermediates. The function of PE in NHEJ repair is to detect and remove inappropriately incorporated ribonucleotides or phosphates from 3' ends of annealed DSBs to configure the termini for ligation. Thus, PE prevents the accumulation of abortive genotoxic DNA intermediates arising from strand displacement synthesis that otherwise would be refractory to repair.

Characterization of Mycobacterium smegmatis PolD2 and PolD1 as RNA/DNA polymerases homologous to the POL domain of bacterial DNA ligase D

Mycobacteria exploit nonhomologous end-joining (NHEJ) to repair DNA double-strand breaks. The core NHEJ machinery comprises the homodimeric DNA end-binding protein Ku and DNA ligase D (LigD), a modular enzyme composed of a C-terminal ATP-dependent ligase domain (LIG), a central 3'-phosphoesterase domain (PE), and an N-terminal polymerase domain (POL). LigD POL is proficient at adding templated and nontemplated deoxynucleotides and ribonucleotides to DNA ends in vitro and is the catalyst in vivo of unfaithful NHEJ events involving nontemplated single-nucleotide additions to blunt DSB ends. Here, we identify two mycobacterial proteins, PolD1 and PolD2, as stand-alone homologues of the LigD POL domain. Biochemical characterization of PolD1 and PolD2 shows that they resemble LigD POL in their monomeric quaternary structures, their ability to add templated and nontemplated nucleotides to primer-templates and blunt ends, and their preference for rNTPs versus dNTPs. Deletion of polD1, polD2, or both from a Mycobacterium smegmatis strain carrying an inactivating mutation in LigD POL failed to reveal a role for PolD1 or PolD2 in templated nucleotide additions during NHEJ of 5'-overhang DSBs or in clastogen resistance. Whereas our results document the existence and characteristics of new stand-alone members of the LigD POL family of RNA/DNA polymerases, they imply that other polymerases can perform fill-in synthesis during mycobacterial NHEJ.

Solution structure and DNA-binding properties of the phosphoesterase domain of DNA ligase D

The phosphoesterase (PE) domain of the bacterial DNA repair enzyme LigD possesses distinctive manganese-dependent 3′-phosphomonoesterase and 3′-phosphodiesterase activities. PE exemplifies a new family of DNA end-healing enzymes found in all phylogenetic domains. Here, we determined the structure of the PE domain of Pseudomonas aeruginosa LigD (PaePE) using solution NMR methodology. PaePE has a disordered N-terminus and a well-folded core that differs in instructive ways from the crystal structure of a PaePE•Mn²⁺• sulfate complex, especially at the active site that is found to be conformationally dynamic. Chemical shift perturbations in the presence of primer-template duplexes with 3′-deoxynucleotide, 3′-deoxynucleotide 3′-phosphate, or 3′ ribonucleotide termini reveal the surface used by PaePE to bind substrate DNA and suggest a more efficient engagement in the presence of a 3′-ribonucleotide. Spectral perturbations measured in the presence of weakly catalytic (Cd²⁺) and inhibitory (Zn²⁺) metals provide evidence for significant conformational changes at and near the active site, compared to the relatively modest changes elicited by Mn²⁺.

Sequence-specific 1H, 13C and 15N assignments of the phosphoesterase (PE) domain of Pseudomonas aeruginosa DNA ligase D (LigD)

DNA ligase D (LigD), consisting of polymerase, ligase and phosphoesterase domains, is the essential catalyst of the bacterial non-homologous end-joining pathway of DNA double-strand break repair. The phosphoesterase (PE) module performs manganese-dependent 3'-phosphomonoesterase and 3'-ribonucleoside resection reactions that heal broken ends in preparation for sealing. LigD PE exemplifies a structurally and mechanistically unique class of DNA end-processing enzymes. Here, we present the resonance assignments of the PE domain of Pseudomonas aeruginosa LigD comprising the N-terminal 177 residues.

Structural insights to the metal specificity of an archaeal member of the LigD 3'-phosphoesterase DNA repair enzyme family

LigD 3′-phosphoesterase (PE) enzymes perform end-healing reactions at DNA breaks. Here we characterize the 3′-ribonucleoside-resecting activity of Candidatus Korarchaeum PE. CkoPE prefers a single-stranded substrate versus a primer–template. Activity is abolished by vanadate (10 mM), but is less sensitive to phosphate (IC₅₀ 50 mM) or chloride (IC₅₀ 150 mM). The metal requirement is satisfied by manganese, cobalt, copper or cadmium, but not magnesium, calcium, nickel or zinc. Insights to CkoPE metal specificity were gained by solving new 1.5 Å crystal structures of CkoPE in complexes with Co²⁺ and Zn²⁺. His9, His15 and Asp17 coordinate cobalt in an octahedral complex that includes a phosphate anion, which is in turn coordinated by Arg19 and His51. The cobalt and phosphate positions and the atomic contacts in the active site are virtually identical to those in the CkoPE·Mn²⁺ structure. By contrast, Zn²⁺ binds in the active site in a tetrahedral complex, wherein the position, orientation and atomic contacts of the phosphate are shifted and its interaction with His51 is lost. We conclude that: (i) PE selectively binds to ‘soft’ metals in either productive or non-productive modes and (ii) PE catalysis depends acutely on proper metal and scissile phosphate geometry.

Structures and activities of archaeal members of the LigD 3'-phosphoesterase DNA repair enzyme superfamily

LigD 3′-phosphoesterase (PE) is a component of the bacterial NHEJ apparatus that performs 3′-end-healing reactions at DNA breaks. The tertiary structure, active site and substrate specificity of bacterial PE are unique vis–à-vis other end-healing enzymes. PE homologs are present in archaea, but their properties are uncharted. Here, we demonstrate the end-healing activities of two archaeal PEs—Candidatus Korarchaeum cryptofilum PE (CkoPE; 117 amino acids) and Methanosarcina barkeri PE (MbaPE; 151 amino acids)—and we report their atomic structures at 1.1 and 2.1 Å, respectively. Archaeal PEs are minimized versions of bacterial PE, consisting of an eight-stranded β barrel and a 3₁₀ helix. Their active sites are located in a crescent-shaped groove on the barrel’s outer surface, wherein two histidines and an aspartate coordinate manganese in an octahedral complex that includes two waters and a phosphate anion. The phosphate is in turn coordinated by arginine and histidine side chains. The conservation of active site architecture in bacterial and archaeal PEs, and the concordant effects of active site mutations, underscore a common catalytic mechanism, entailing transition state stabilization by manganese and the phosphate-binding arginine and histidine. Our results fortify the proposal that PEs comprise a DNA repair superfamily distributed widely among taxa.

Structure of bacterial LigD 3'-phosphoesterase unveils a DNA repair superfamily

The DNA ligase D (LigD) 3'-phosphoesterase (PE) module is a conserved component of the bacterial nonhomologous end-joining (NHEJ) apparatus that performs 3' end-healing reactions at DNA double-strand breaks. Here we report the 1.9 A crystal structure of Pseudomonas aeruginosa PE, which reveals that PE exemplifies a unique class of DNA repair enzyme. PE has a distinctive fold in which an eight stranded beta barrel with a hydrophobic interior supports a crescent-shaped hydrophilic active site on its outer surface. Six essential side chains coordinate manganese and a sulfate mimetic of the scissile phosphate. The PE active site and mechanism are unique vis à vis other end-healing enzymes. We find PE homologs in archaeal and eukaryal proteomes, signifying that PEs comprise a DNA repair superfamily.

Gap filling activities of Pseudomonas DNA ligase D (LigD) polymerase and functional interactions of LigD with the DNA end-binding Ku protein

Many bacterial pathogens, including Pseudomonas aeruginosa, have a nonhomologous end joining (NHEJ) system of DNA double strand break (DSB) repair driven by Ku and DNA ligase D (LigD). LigD is a multifunctional enzyme composed of a ligase domain fused to an autonomous polymerase module (POL) that adds ribonucleotides or deoxyribonucleotides to DSB ends and primer-templates. LigD POL and the eukaryal NHEJ polymerase lambda are thought to bridge broken DNA ends via contacts with a duplex DNA segment downstream of the primer terminus, a scenario analogous to gap repair. Here, we characterized the gap repair activity of Pseudomonas LigD POL, which is more efficient than simple templated primer extension and relies on a 5'-phosphate group on the distal gap strand end to confer apparent processivity in filling gaps of 3 or 4 nucleotides. Mutations of the His-553, Arg-556, and Lys-566 side chains implicated in DNA 5'-phosphate binding eliminate the preferential filling of 5'-phosphate gaps. Mutating Phe-603, which is imputed to stack on the nucleobase of the template strand that includes the 1st bp of the downstream gap duplex segment, selectively affects incorporation of the final gap-closing nucleotide. We find that Pseudomonas Ku stimulates POL-catalyzed ribonucleotide addition to a plasmid DSB end and promotes plasmid end joining by full-length Pseudomonas LigD. A series of incremental truncations from the C terminus of the 293-amino acid Ku polypeptide identifies Ku-(1-229) as sufficient for homodimerization and LigD stimulation. The slightly longer Ku-(1-253) homodimer forms stable complexes at both ends of linear plasmid DNA that protect the DSBs from digestion by 5'- and 3'-exonucleases.

Repairing DNA double-strand breaks by the prokaryotic non-homologous end-joining pathway

The NHEJ (non-homologous end-joining) pathway is one of the major mechanisms for repairing DSBs (double-strand breaks) that occur in genomic DNA. In common with eukaryotic organisms, many prokaryotes possess a conserved NHEJ apparatus that is essential for the repair of DSBs arising in the stationary phase of the cell cycle. Although the bacterial NHEJ complex is much more minimal than its eukaryotic counterpart, both pathways share a number of common mechanistic features. The relative simplicity of the prokaryotic NHEJ complex makes it a tractable model system for investigating the cellular and molecular mechanisms of DSB repair. The present review describes recent advances in our understanding of prokaryotic end-joining, focusing primarily on biochemical, structural and cellular aspects of the mycobacterial NHEJ repair pathway.

The pathways and outcomes of mycobacterial NHEJ depend on the structure of the broken DNA ends

Mycobacteria can repair DNA double-strand breaks (DSBs) via a nonhomologous end-joining (NHEJ) system that includes a dedicated DNA ligase (LigD) and the DNA end-binding protein Ku. Here we exploit an improved plasmid-based NHEJ assay and a collection of Mycobacterium smegmatis strains bearing deletions or mutations in Ku or the DNA ligases to interrogate the contributions of LigD's three catalytic activities (polymerase, ligase, and 3' phosphoesterase) and structural domains (POL, LIG, and PE) to the efficiency and molecular outcomes of NHEJ in vivo. By analyzing in parallel the repair of blunt, 5' overhang, and 3' overhang DSBs, we discovered a novel end-joining pathway specific to breaks with 3' overhangs that is Ku- and LigD-independent and perfectly faithful. This 3' overhang NHEJ pathway is independent of ligases B and C; we surmise that it relies on NAD(+)-dependent LigA, the essential replicative ligase. We find that efficient repair of blunt and 5' overhang DSBs depends stringently on Ku and the LigD POL domain, but not on the LigD polymerase activity, which mainly serves to promote NHEJ infidelity. The lack of an effect of PE-inactivating LigD mutations on NHEJ outcomes, especially the balance between deletions and insertions at blunt or 5' overhang breaks, argues against LigD being the catalyst of deletion formation. Ligase-inactivating LigD mutations (or deletion of the LIG domain) have a modest impact on the efficiency of blunt and 5' overhang DSB repair, because the strand sealing activity can be provided in trans by one of the other resident ATP-dependent ligases (likely LigC). Reliance on the backup ligase is accompanied by a drastic loss of fidelity during blunt end and 5' overhang DSB repair. We conclude that the mechanisms of mycobacterial NHEJ are many and the outcomes depend on the initial structures of the DSBs and the available ensemble of end-processing and end-sealing components, which are not limited to Ku and LigD.

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.

Nonhomologous end-joining in bacteria: a microbial perspective

In eukaryotic cells, repair of DNA double-strand breaks (DSBs) by the nonhomologous end-joining (NHEJ) pathway is critical for genomic stability. A functionally homologous repair apparatus, composed of Ku and a multifunctional DNA ligase (LigD), has recently been identified in many prokaryotes. Eukaryotic organisms employ a large number of factors to repair breaks by NHEJ. In contrast, the bacterial NHEJ complex is a two-component system that, despite its relative simplicity, possesses all of the break-recognition, end-processing, and ligation activities required to facilitate the complex task of DSB repair. Here, we review recent discoveries on the structure and function of the bacterial NHEJ repair apparatus. In particular, we discuss the evolutionary origins of this DSB repair pathway, how the diverse activities within the prokaryotic end-joining complex cooperate to facilitate DSB repair, the physiological roles of bacterial NHEJ, and finally, the essential function of NHEJ in the life cycle of mycobacteriophage.

Multiple Ku orthologues mediate DNA non-homologous end-joining in the free-living form and during chronic infection of Sinorhizobium meliloti

The bacterial non-homologous end-joining (NHEJ) apparatus is a two-component system that uses Ku and LigD to repair DNA double-strand breaks. Although the reaction mechanism has been extensively studied, much less is known about the physiological role of bacterial NHEJ. Recent studies suggest that NHEJ acts under conditions where DNA replication is reduced or absent (such as in a spore or stationary phase). Interestingly, genes encoding Ku and LigD have been identified in a wide range of bacteria that can chronically infect eukaryotic hosts. Strikingly, Sinohizobium meliloti, an intracellular symbiont of legume plants, carries four genes encoding Ku homologues (sku1 to sku4). Deletion analysis of the sku genes indicated that all Ku homologues are functional. One of these genes, sku2, is strongly expressed in free-living cells, as well as in bacteroid cells residing inside of the host plant. To visualize the NHEJ apparatus in vivo, SKu2 protein was fused to yellow fluorescent protein (YFP). Ionizing radiation (IR) induced focus formation of SKu2-YFP in free-living cells in a dosage-dependent manner. Moreover, SKu2-YFP foci formed in response to IR in non-dividing bacteroids, indicating that NHEJ system is functional even during the chronic infection phase of symbiosis.

Bacterial DNA repair by non-homologous end joining

The capacity to rectify DNA double-strand breaks (DSBs) is crucial for the survival of all species. DSBs can be repaired either by homologous recombination (HR) or non-homologous end joining (NHEJ). The long-standing notion that bacteria rely solely on HR for DSB repair has been overturned by evidence that mycobacteria and other genera have an NHEJ system that depends on a dedicated DNA ligase, LigD, and the DNA-end-binding protein Ku. Recent studies have illuminated the role of NHEJ in protecting the bacterial chromosome against DSBs and other clastogenic stresses. There is also emerging evidence of functional crosstalk between bacterial NHEJ proteins and components of other DNA-repair pathways. Although still a young field, bacterial NHEJ promises to teach us a great deal about the nexus of DNA repair and bacterial pathogenesis.

Characterization of Agrobacterium tumefaciens DNA ligases C and D

Agrobacterium tumefaciens encodes a single NAD⁺-dependent DNA ligase and six putative ATP-dependent ligases. Two of the ligases are homologs of LigD, a bacterial enzyme that catalyzes end-healing and end-sealing steps during nonhomologous end joining (NHEJ). Agrobacterium LigD1 and AtuLigD2 are composed of a central ligase domain fused to a C-terminal polymerase-like (POL) domain and an N-terminal 3′-phosphoesterase (PE) module. Both LigD proteins seal DNA nicks, albeit inefficiently. The LigD2 POL domain adds ribonucleotides or deoxyribonucleotides to a DNA primer-template, with rNTPs being the preferred substrates. The LigD1 POL domain has no detectable polymerase activity. The PE domains catalyze metal-dependent phosphodiesterase and phosphomonoesterase reactions at a primer-template with a 3′-terminal diribonucleotide to yield a primer-template with a monoribonucleotide 3′-OH end. The PE domains also have a 3′-phosphatase activity on an all-DNA primer-template that yields a 3′-OH DNA end. Agrobacterium ligases C2 and C3 are composed of a minimal ligase core domain, analogous to Mycobacterium LigC (another NHEJ ligase), and they display feeble nick-sealing activity. Ligation at DNA double-strand breaks in vitro by LigD2, LigC2 and LigC3 is stimulated by bacterial Ku, consistent with their proposed function in NHEJ.

Nucleotide misincorporation, 3'-mismatch extension, and responses to abasic sites and DNA adducts by the polymerase component of bacterial DNA ligase D

DNA ligase D (LigD) participates in a mutagenic pathway of nonhomologous end joining in bacteria. LigD consists of an ATP-dependent ligase domain fused to a polymerase domain (POL) and a phosphoesterase module. The POL domain performs templated and nontemplated primer extension reactions with either dNTP or rNTP substrates. Here we report that Pseudomonas LigD POL is an unfaithful nucleic acid polymerase. Although the degree of infidelity in nucleotide incorporation varies according to the mispair produced, we find that a correctly paired ribonucleotide is added to the DNA primer terminus more rapidly than the corresponding correct deoxyribonucleotide and incorrect nucleotides are added much more rapidly with rNTP substrates than with dNTPs, no matter what the mispair configuration. We find that 3' mispairs are extended by LigD POL, albeit more slowly than 3' paired primer-templates. The magnitude of the rate effect on mismatch extension varies with the identity of the 3' mispair, but it was generally the case that mispaired ends were extended more rapidly with rNTP substrates than with dNTPs. These results lend credence to the suggestion that LigD POL might fill in short 5'-overhangs with ribonucleotides when repairing double strand breaks in quiescent cells. We report that LigD POL can add a deoxynucleotide opposite an abasic lesion in the template strand, albeit slowly. Ribonucleotides are inserted more rapidly at an abasic lesion than are deoxys. LigD POL displays feeble activity in extending a preformed primer terminus opposing an abasic site, but can readily bypass the lesion by slippage of the primer 3' di- or trinucleotide and realignment to the template sequence distal to the abasic site. Covalent benzo[a]pyrene-dG and benzo[c]phenanthrene-dA adducts in the template strand are durable roadblocks to POL elongation. POL can slowly insert a dNMP opposite the adduct, but is impaired in the subsequent extension step.

Substrate specificity and structure-function analysis of the 3'-phosphoesterase component of the bacterial NHEJ protein, DNA ligase D

DNA ligase D (LigD) performs end remodeling and end sealing reactions during nonhomologous end joining in bacteria. Pseudomonas aeruginosa LigD consists of a central ATP-dependent ligase domain fused to a C-terminal polymerase domain and an N-terminal phosphoesterase (PE) module. The PE domain catalyzes manganese-dependent phosphodiesterase and phosphomonoesterase reactions at the 3' end of the primer strand of a primer-template. The phosphodiesterase cleaves a 3'-terminal diribonucleotide to yield a primer strand with a ribonucleoside 3'-PO4 terminus. The phosphomonoesterase converts a terminal ribonucleoside 3'-PO4 or deoxyribonucleoside 3'-PO4 of a primer-template to a 3'-OH. Here we report that the phosphodiesterase and phosphomonoesterase activities are both dependent on the presence and length of the 5' single-strand tail of the primer-template substrate. Although the phosphodiesterase activity is strictly dependent on the 2'-OH of the penultimate ribose, it is indifferent to a 2'-OH versus a2'-H on the terminal nucleoside. Incision at the ribonucleotide linkage is suppressed when the 2'-OH is moved by 1 nucleotide in the 5' direction, suggesting that LigD is an exoribonuclease that cleaves the 3'-terminal phosphodiester. We report the effects of conservative amino acid substitutions at residues: (i) His42, His48, Asp50, Arg52, His84, and Tyr88, which are essential for both the ribonuclease and 3'-phosphatase activities; (ii) Arg14, Asp15, Glu21, and Glu82, which are critical for 3'-phosphatase activity but not 3'-ribonucleoside removal; and (iii) at Lys66 and Arg76, which participate selectively in the 3'-ribonuclease reaction. The results suggest roles for individual functional groups in metal binding and/or phosphoesterase chemistry.

Crystal structure and nonhomologous end-joining function of the ligase component of Mycobacterium DNA ligase D

DNA ligase D (LigD) is a large polyfunctional enzyme involved in nonhomologous end-joining (NHEJ) in mycobacteria. LigD consists of a C-terminal ATP-dependent ligase domain fused to upstream polymerase and phosphoesterase modules. Here we report the 2.4 angstroms crystal structure of the ligase domain of Mycobacterium LigD, captured as the covalent ligase-AMP intermediate with a divalent metal in the active site. A chloride anion on the protein surface coordinated by the ribose 3'-OH and caged by arginine and lysine side chains is a putative mimetic of the 5'-phosphate at a DNA nick. Structure-guided mutational analysis revealed distinct requirements for the adenylylation and end-sealing reactions catalyzed by LigD. We found that a mutation of Mycobacterium LigD that ablates only ligase activity results in decreased fidelity of NHEJ in vivo and a strong bias of mutagenic events toward deletions instead of insertions at the sealed DNA ends. This phenotype contrasts with the increased fidelity of double-strand break repair in deltaligD cells or in a strain in which only the polymerase function of LigD is defective. We surmise that the signature error-prone quality of bacterial NHEJ in vivo arises from a dynamic balance between the end-remodeling and end-sealing steps.

Atomic structure and nonhomologous end-joining function of the polymerase component of bacterial DNA ligase D

DNA ligase D (LigD) is a large polyfunctional protein that participates in a recently discovered pathway of nonhomologous end-joining in bacteria. LigD consists of an ATP-dependent ligase domain fused to a polymerase domain (Pol) and a phosphoesterase module. The Pol activity is remarkable for its dependence on manganese, its ability to perform templated and nontemplated primer extension reactions, and its preference for adding ribonucleotides to blunt DNA ends. Here we report the 1.5-A crystal structure of the Pol domain of Pseudomonas LigD and its complexes with manganese and ATP/dATP substrates, which reveal a minimized polymerase with a two-metal mechanism and a fold similar to that of archaeal DNA primase. Mutational analysis highlights the functionally relevant atomic contacts in the active site. Although distinct nucleoside conformations and contacts for ATP versus dATP are observed in the cocrystals, the functional analysis suggests that the ATP-binding mode is the productive conformation for dNMP and rNMP incorporation. We find that a mutation of Mycobacterium LigD that uniquely ablates the polymerase activity results in increased fidelity of blunt-end double-strand break repair in vivo by virtue of eliminating nucleotide insertions at the recombination junctions. Thus, LigD Pol is a direct catalyst of mutagenic nonhomologous end-joining in vivo. Our studies underscore a previously uncharacterized role for the primase-like polymerase family in DNA repair.