Deoxyribonucleic Acid Ligase

Pol I DNA polymerases stimulate DNA end-joining by Escherichia coli DNA ligase

Klenow and Klentaq are the large fragment domains of the Pol I DNA polymerases from Escherichia coli and Thermus aquaticus, respectively. Herein, we show that both polymerases can significantly stimulate complementary intermolecular end-joining ligations by E.coli DNA ligase when the polymerases are present at concentrations lower than that of the DNA substrates. In contrast, high polymerase concentrations relative to the DNA substrates inhibit the intermolecular ligation activity of DNA ligase. Neither polymerase was able to stimulate the DNA ligase from T4 bacteriophage. Additionally, nick-closure by E. coli DNA ligase (but not T4 ligase) is slightly stimulated by both polymerases, but only at about 10% of the magnitude seen for end-joining enhancement. The data represent one of the first observations of direct polymerase-ligase interactions in prokaryotes, and suggest that the polymerases stabilize the associated DNA ends during intermolecular ligation, and that such a complex can be taken advantage of by some, but not all, DNA ligases.

Rapid Time Scale Analysis of T4 DNA Ligase-DNA Binding

DNA ligases, essential to both in vivo genome integrity and in vitro molecular biology, catalyze phosphodiester bond formation between adjacent 3'-OH and 5'-phosphorylated termini in dsDNA. This reaction requires enzyme self-adenylylation, using ATP or NAD⁺ as a cofactor, and AMP release concomitant with phosphodiester bond formation. In this study, we present the first fast time scale binding kinetics of T4 DNA ligase to both nicked substrate DNA (nDNA) and product-equivalent non-nicked dsDNA, as well as binding and release kinetics of AMP. The described assays utilized a fluorescein-dT labeled DNA substrate as a reporter for ligase·DNA interactions via stopped-flow fluorescence spectroscopy. The analysis revealed that binding to nDNA by the active adenylylated ligase occurs in two steps, an initial rapid association equilibrium followed by a transition to a second bound state prior to catalysis. Furthermore, the ligase binds and dissociates from nicked and nonsubstrate dsDNA rapidly with initial association affinities on the order of 100 nM regardless of enzyme adenylylation state. DNA binding occurs through a two-step mechanism in all cases, confirming prior proposals of transient binding followed by a transition to a productive ligase·nDNA (Lig·nDNA) conformation but suggesting that weaker nonproductive "closed" complexes are formed as well. These observations demonstrate the mechanistic underpinnings of competitive inhibition by rapid binding of nonsubstrate DNA, and of substrate inhibition by blocking of the self-adenylylation reaction through nick binding by deadenylylated ligase. Our analysis further reveals that product release is not the rate-determining step in turnover.

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.

Complete steady-state rate equation for DNA ligase and its use for measuring product kinetic parameters of NAD⁺-dependent DNA ligase from Haemophilus influenzae

Background

DNA ligase seals the nicks in the phosphodiester backbone between Okazaki fragments during DNA replication. DNA ligase has an unusual Bi Ter Ping Pong kinetic mechanism. Its substrates in eubacteria are NAD⁺ and nicked DNA (nDNA). Its products are nicotinamide mononucleotide (NMN), adenosine 5′-monophosphate (AMP), and sealed DNA. Investigation of the kinetic mechanism and measurement of the kinetic constants of DNA ligase using steady-state kinetics would benefit from the availability of the complete steady-state rate equation, including terms for product concentrations and product-related kinetic constants, which has not previously been published.

Results

The rate equations for two possible Bi Ter kinetic mechanisms for DNA ligase, including products, are reported. The mechanisms differ according to whether the last two products, AMP and sealed DNA, are released in an ordered or rapid-equilibrium random (RER) manner. Steady-state kinetic studies of product inhibition by NMN and AMP were performed with Haemophilus influenzae NAD⁺-dependent DNA ligase. The complete rate equation enabled measurement of dissociation constants for NAD⁺, NMN, and AMP and eliminated one of 3 possible product release mechanisms.

Conclusions

Steady-state kinetic product inhibition experiments and complete steady-state kinetic rate equations were used to measure dissociation constants of NAD⁺, NMN, and AMP and eliminate the possibility that AMP is the second product released in an ordered mechanism. Determining by steady-state kinetics whether the release of sealed DNA and AMP products goes by an ordered (AMP last off) or RER mechanism was shown to require a product inhibition study using sealed DNA.

Evaluation of DNA primase DnaG as a potential target for antibiotics

Mycobacteria contain genes for several DNA-dependent RNA primases, including dnaG, which encodes an essential replication enzyme that has been proposed as a target for antituberculosis compounds. An in silico analysis revealed that mycobacteria also possess archaeo-eukaryotic superfamily primases (AEPs) of unknown function. Using a homologous recombination system, we obtained direct evidence that wild-type dnaG cannot be deleted from the chromosome of Mycobacterium smegmatis without disrupting viability, even in backgrounds in which mycobacterial AEPs are overexpressed. In contrast, single-deletion AEP mutants or mutants defective for all four identified M. smegmatis AEP genes did not exhibit growth defects under standard laboratory conditions. Deletion of native dnaG in M. smegmatis was tolerated only after the integration of an extra intact copy of the M. smegmatis or Mycobacterium tuberculosis dnaG gene, under the control of chemically inducible promoters, into the attB site of the chromosome. M. tuberculosis and M. smegmatis DnaG proteins were overproduced and purified, and their primase activities were confirmed using radioactive RNA synthesis assays. The enzymes appeared to be sensitive to known inhibitors (suramin and doxorubicin) of DnaG. Notably, M. smegmatis bacilli appeared to be sensitive to doxorubicin and resistant to suramin. The growth and survival of conditional mutant mycobacterial strains in which DnaG was significantly depleted were only slightly affected under standard laboratory conditions. Thus, although DnaG is essential for mycobacterial viability, only low levels of protein are required for growth. This suggests that very efficient inhibition of enzyme activity would be required for mycobacterial DnaG to be useful as an antibiotic target.

Synthesis and activity of modified cytidine 5'-monophosphate probes for T4 RNA ligase 1

We describe the synthesis of a series of unique base modified ligation probes such as p(5')C-4-ethylenediamino 3, p(5')C-4-biotin 4, and pre-adenylated form A(5')pp(5')C-4-biotin 6 and tested their biological activity with T4 RNA ligase 1 using a standard pCp probe 1 as a control. The intermolecular ligation assay was developed using a 5'-FAM labeled 24 mer single-stranded (ss) RNA and the average ligation efficiencies for pCp 1, p(5')C-4-ethylenediamino 3, p(5')C-4-biotin 4, and pre-adenylated form A(5')pp(5')C-4-biotin 6 were found to be 44%, 81%, 39% and 16% respectively, as determined using a denaturing gel analysis. Furthermore, confirmation of the ligation activity of the biotinylated probes to the RNA substrate was confirmed by streptavidin conjugation and analysis by nondenaturing gel electrophoresis. These results strongly suggest that the new probes are valid substrates for T4 RNA ligase 1 and therefore could be useful for developing a miRNA detection system that includes rapid isolation, efficient labeling and detection of miRNAs on sensitivity-enhanced microarrays.

Dynamics of phosphodiester synthesis by DNA ligase

Ligases are essential actors in DNA replication, recombination, and repair by virtue of their ability to seal breaks in the phosphodiester backbone. Ligation proceeds through a nicked DNA-adenylate intermediate (AppDNA), which must be sealed quickly to avoid creating a potentially toxic lesion. Here, we take advantage of ligase-catalyzed AMP-dependent incision of a single supercoiled DNA molecule to observe the step of phosphodiester synthesis in real time. An exponentially distributed number of supercoils was relaxed per successful incision-resealing event, from which we deduce the torque-dependent ligation probability per DNA swivel. Premature dissociation of ligase from nicked DNA-adenylate accounted for approximately 10% of the observed events. The ability of ligase to form a C-shaped protein clamp around DNA is a key determinant of ligation probability per turn and the stability of the ligase-AppDNA intermediate. The estimated rate of phosphodiester synthesis by DNA ligase (400 s(-1)) is similar to the high rates of phosphodiester synthesis by replicative DNA polymerases.

Evaluation of NAD(+) -dependent DNA ligase of mycobacteria as a potential target for antibiotics

Mycobacteria contain genes for several DNA ligases, including ligA, which encodes a NAD(+)-dependent enzyme that has been postulated to be a target for novel antibacterial compounds. Using a homologous recombination system, direct evidence is presented that wild-type ligA cannot be deleted from the chromosome of Mycobacterium smegmatis. Deletions of native ligA in M. smegmatis could be obtained only after the integration of an extra copy of M. smegmatis or Mycobacterium tuberculosis ligA into the attB site of the chromosome, with expression controlled by chemically inducible promoters. The four ATP-dependent DNA ligases encoded by the M. smegmatis chromosome were unable to replace the function of LigA. Interestingly, the LigA protein from M. smegmatis could be substituted with the NAD(+)-dependent DNA ligase of Escherichia coli or the ATP-dependent ligase of bacteriophage T4. The conditional mutant strains allowed the analysis of the effect of LigA depletion on the growth of M. smegmatis. The protein level of the conditional mutants was estimated by Western blot analysis using antibodies raised against LigA of M. tuberculosis. This revealed that a strong overproduction or depletion of LigA did not affect the growth or survival of mycobacteria under standard laboratory conditions. In conclusion, although NAD(+)-dependent DNA ligase is essential for mycobacterial viability, only low levels of protein are required for growth. These findings suggest that very efficient inhibition of enzyme activity would be required if NAD(+)-dependent DNA ligase is to be useful as an antibiotic target in mycobacteria. The strains developed here will provide useful tools for the evaluation of the efficacy of any appropriate compounds in mycobacteria.

A high-throughput assay for the adenylation reaction of bacterial DNA ligase

DNA ligase catalyzes the closure of single-strand nicks in double-stranded DNA that arise during replication and recombination. Inhibition of bacterial ligase is expected to cause chromosome degradation and cell death, making it an attractive target for new antibacterials. The prototypical bacterial ligase couples the hydrolysis of NAD(+) to phosphodiester bond formation between an adjacent 3'OH and 5'-terminal phosphate of nicked duplex DNA. The first step is the reversible formation of a ligase-adenylate from the reaction between apoenzyme and NAD(+). Inhibitors that compete with NAD(+) are expected to be bacterial specific because eukaryotic DNA ligases use ATP and differ in the sequence composition of their adenylation domain. We report here a high-throughput assay that measures the adenylation reaction specifically by monitoring ligase-AMP formation via scintillation proximity technologies. Escherichia coli DNA ligase was biotinylated in vivo; after reaction with radiolabeled NAD(+), ligase-[(3)H]AMP could be captured onto the streptavidin-coated surface of the solid scintillant. The method was ideal for high-throughput screening because it required minimal manipulations and generated a robust signal with minimal scatter. Certain adenosine analogs were found to inhibit the adenylation assay and had similar potency of inhibition in a DNA ligation assay.

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.

Dual Mechanisms whereby a Broken RNA End Assists the Catalysis of Its Repair by T4 RNA Ligase 2

T4 RNA ligase 2 (Rnl2) efficiently seals 3'-OH/5'-PO4 RNA nicks via three nucleotidyl transfer steps. Here we show that the terminal 3'-OH at the nick accelerates the second step of the ligase pathway (adenylylation of the 5'-PO4 strand) by a factor of 1000, even though the 3'-OH is not chemically transformed during the reaction. Also, the terminal 2'-OH at the nick accelerates the third step (attack of the 3'-OH on the 5'-adenylated strand to form a phosphodiester) by a factor of 25-35, even though the 2'-OH is not chemically reactive. His-37 of Rnl2 is uniquely required for step 3, providing a approximately 10(2) rate acceleration. Biochemical epistasis experiments show that His-37 and the RNA 2'-OH act independently. We conclude that the broken RNA end promotes catalysis of its own repair by Rnl2 via two mechanisms, one of which (enhancement of step 3 by the 2'-OH) is specific to RNA ligation. Substrate-assisted catalysis provides a potential biochemical checkpoint during nucleic acid repair.

Staphylococcus aureus DNA ligase: characterization of its kinetics of catalysis and development of a high-throughput screening compatible chemiluminescent hybridization protection assay

DNA ligases are key enzymes involved in the repair and replication of DNA. Prokaryotic DNA ligases uniquely use NAD+ as the adenylate donor during catalysis, whereas eukaryotic enzymes use ATP. This difference in substrate specificity makes the bacterial enzymes potential targets for therapeutic intervention. We have developed a homogeneous chemiluminescence-based hybridization protection assay for Staphylococcus aureus DNA ligase that uses novel acridinium ester technology and demonstrate that it is an alternative to the commonly used radiometric assays for ligases. The assay has been used to determine a number of kinetic constants for S. aureus DNA ligase catalysis. These included the K(m) values for NAD+ (2.75+/-0.1 microM) and the acridinium-ester-labelled DNA substrate (2.5+/-0.2 nM). A study of the pH-dependencies of kcat, K(m) and kcat/K(m) has revealed values of kinetically influential ionizations within the enzyme-substrate complexes (kcat) and free enzyme (kcat/K(m)). In each case, the curves were shown to be composed of one kinetically influential ionization, for k(cat), pK(a)=6.6+/-0.1 and kcat/K(m), pK(a)=7.1+/-0.1. Inhibition characteristics of the enzyme against two Escherichia coli DNA ligase inhibitors have also been determined with IC50 values for these being 3.30+/-0.86 microM for doxorubicin and 1.40+/-0.07 microM for chloroquine diphosphate. The assay has also been successfully miniaturized to a sufficiently low volume to allow it to be utilized in a high-throughput screen (384-well format; 20 microl reaction volume), enabling the assay to be used in screening campaigns against libraries of compounds to discover leads for further drug development.

Specific and potent inhibition of NAD+-dependent DNA ligase by pyridochromanones

Pyridochromanones were identified by high throughput screening as potent inhibitors of NAD+-dependent DNA ligase from Escherichia coli. Further characterization revealed that eubacterial DNA ligases from Gram-negative and Gram-positive sources were inhibited at nanomolar concentrations. In contrast, purified human DNA ligase I was not affected (IC50 > 75 microm), demonstrating remarkable specificity for the prokaryotic target. The binding mode is competitive with the eubacteria-specific cofactor NAD+, and no intercalation into DNA was detected. Accordingly, the compounds were bactericidal for the prominent human pathogen Staphylococcus aureus in the low microg/ml range, whereas eukaryotic cells were not affected up to 60 microg/ml. The hypothesis that inhibition of DNA ligase is the antibacterial principle was proven in studies with a temperature-sensitive ligase-deficient E. coli strain. This mutant was highly susceptible for pyridochromanones at elevated temperatures but was rescued by heterologous expression of human DNA ligase I. A physiological consequence of ligase inhibition in bacteria was massive DNA degradation, as visualized by fluorescence microscopy of labeled DNA. In summary, the pyridochromanones demonstrate that diverse eubacterial DNA ligases can be addressed by a single inhibitor without affecting eukaryotic ligases or other DNA-binding enzymes, which proves the value of DNA ligase as a novel target in antibacterial therapy.

Making AppDNA using T4 DNA ligase

5('),5(')-Adenylyl pyrophosphoryl DNA (AppDNA) contains a high-energy pyrophosphate linkage and can be exploited as an activated DNA substrate to derive new DNA enzymes for carrying out various DNA modification reactions. For this reason, enzymatic synthesis of AppDNA is highly desirable. AppDNA is a known intermediate in DNA ligase mediated DNA ligation reactions, but rarely accumulates under normal reaction conditions. Here we report that T4 DNA ligase can quantitatively convert 5(')-phosphoryl DNA donor into AppDNA in the absence of acceptor DNA but in the presence of a template DNA that contains at least one unpaired nucleotide opposite the 5(')-phosphoryl DNA donor site. This adenylylation behavior of T4 DNA ligase is not observed with Thermus aquaticus (Taq) and Escherichia coli DNA ligases. We further found that a donor-template duplex of 11-bp in length is required by T4 DNA ligase for the formation of AppDNA.

Binding of nucleotides by T4 DNA ligase and T4 RNA ligase: optical absorbance and fluorescence studies

The interaction of nucleotides with T4 DNA and RNA ligases has been characterized using ultraviolet visible (UV-VIS) absorbance and fluorescence spectroscopy. Both enzymes bind nucleotides with the K(d) between 0.1 and 20 microM. Nucleotide binding results in a decrease of absorbance at 260 nm due to pi-stacking with an aromatic residue, possibly phenylalanine, and causes red-shifting of the absorbance maximum due to hydrogen bonding with the exocyclic amino group. T4 DNA ligase is shown to have, besides the catalytic ATP binding site, another noncovalent nucleotide binding site. ATP bound there alters the pi-stacking of the nucleotide in the catalytic site, increasing its optical extinction. The K(d) for the noncovalent site is approximately 1000-fold higher than for the catalytic site. Nucleotides quench the protein fluorescence showing that a tryptophan residue is located in the active site of the ligase. The decrease of absorbance around 298 nm suggests that the hydrogen bonding interactions of this tryptophan residue are weakened in the ligase-nucleotide complex. The excitation/emission properties of T4 RNA ligase indicate that its ATP binding pocket is in contact with solvent, which is excluded upon binding of the nucleotide. Overall, the spectroscopic analysis reveals important similarities between T4 ligases and related nucleotidyltransferases, despite the low sequence similarity.

Cloning and functional characterization of an NAD(+)-dependent DNA ligase from Staphylococcus aureus

A Staphylococcus aureus mutant conditionally defective in DNA ligase was identified by isolation of complementing plasmid clones that encode the S. aureus ligA gene. Orthologues of the putative S. aureus NAD(+)-dependent DNA ligase could be identified in the genomes of Bacillus stearothermophilus and other gram-positive bacteria and confirmed the presence of four conserved amino acid motifs, including motif I, KXDG with lysine 112, which is believed to be the proposed site of adenylation. DNA sequence comparison of the ligA genes from wild type and temperature-sensitive S. aureus strain NT64 identified a single base alteration that is predicted to result in the amino acid substitution E46G. The S. aureus ligA gene was cloned and overexpressed in Escherichia coli, and the enzyme was purified to near homogeneity. NAD(+)-dependent DNA ligase activity was demonstrated with the purified enzyme by measuring ligation of (32)P-labeled 30-mer and 29-mer oligonucleotides annealed to a complementary strand of DNA. Limited proteolysis of purified S. aureus DNA ligase by thermolysin produced products with apparent molecular masses of 40, 22, and 21 kDa. The fragments were purified and characterized by N-terminal sequencing and mass analysis. The N-terminal fragment (40 kDa) was found to be fully adenylated. A fragment from residues 1 to 315 was expressed as a His-tagged fusion in E. coli and purified for functional analysis. Following deadenylation with nicotinamide mononucleotide, the purified fragment could self-adenylate but lacked detectable DNA binding activity. The 21- and 22-kDa C-terminal fragments, which lacked the last 76 amino acids of the DNA ligase, had no adenylation activity or DNA binding activity. The intact 30-kDa C terminus of the S. aureus LigA protein expressed in E. coli did demonstrate DNA binding activity. These observations suggest that, as in the case with the NAD(+)-dependent DNA ligase from B. stearothermophilus, two independent functional domains exist in S. aureus DNA ligase, consisting of separate adenylation and DNA binding activities. They also demonstrate a role for the extreme C terminus of the ligase in DNA binding. As there is much evidence to suggest that DNA ligase is essential for bacterial survival, its discovery in the important human pathogen S. aureus indicates its potential as a broad-spectrum antibacterial target for the identification of novel antibiotics.

Nucleotide sequence, heterologous expression and novel purification of DNA ligase from Bacillus stearothermophilus(1)

The gene for DNA ligase (EC 6.5.1.2) from thermophilic bacterium Bacillus stearothermophilus NCA1503 has been cloned and the complete nucleotide sequence determined. The ligase gene encodes a protein 670 amino acids in length. The gene was overexpressed in Escherichia coli and the enzyme has been purified to homogeneity. Preliminary characterisation confirms that it is a thermostable, NAD(+)-dependent DNA ligase.

Footprinting of Chlorella virus DNA ligase bound at a nick in duplex DNA

The 298-amino acid ATP-dependent DNA ligase of Chlorella virus PBCV-1 is the smallest eukaryotic DNA ligase known. The enzyme has intrinsic specificity for binding to nicked duplex DNA. To delineate the ligase-DNA interface, we have footprinted the enzyme binding site on DNA and the DNA binding site on ligase. The size of the exonuclease III footprint of ligase bound a single nick in duplex DNA is 19-21 nucleotides. The footprint is asymmetric, extending 8-9 nucleotides on the 3'-OH side of the nick and 11-12 nucleotides on the 5'-phosphate side. The 5'-phosphate moiety is essential for the binding of Chlorella virus ligase to nicked DNA. Here we show that the 3'-OH moiety is not required for nick recognition. The Chlorella virus ligase binds to a nicked ligand containing 2',3'-dideoxy and 5'-phosphate termini, but cannot catalyze adenylation of the 5'-end. Hence, the 3'-OH is important for step 2 chemistry even though it is not itself chemically transformed during DNA-adenylate formation. A 2'-OH cannot substitute for the essential 3'-OH in adenylation at a nick or even in strand closure at a preadenylated nick. The protein side of the ligase-DNA interface was probed by limited proteolysis of ligase with trypsin and chymotrypsin in the presence and absence of nicked DNA. Protease accessible sites are clustered within a short segment from amino acids 210-225 located distal to conserved motif V. The ligase is protected from proteolysis by nicked DNA. Protease cleavage of the native enzyme prior to DNA addition results in loss of DNA binding. These results suggest a bipartite domain structure in which the interdomain segment either comprises part of the DNA binding site or undergoes a conformational change upon DNA binding. The domain structure of Chlorella virus ligase inferred from the solution experiments is consistent with the structure of T7 DNA ligase determined by x-ray crystallography.

Standard free energy for the hydrolysis of adenylylated T4 DNA ligase and the apparent pKa of lysine 159

Equilibrium constants for the adenylylation of T4 DNA ligase have been measured at 10 pH values. The values, when plotted against pH, fit a titration curve corresponding to a pKa of 8.4 +/- 0.1. The simplest interpretation is that the apparent pKa is that of the 6-amino group of the AMP-accepting residue Lys159. Based on the pH dependence of the equilibrium constants, the value at pH 7.0 is 0. 0213 at 25 degrees C, corresponding to DeltaG'o = +2.3 kcal mol-1. From this value and the standard free energy change of -10.9 kcal mol-1 for the hydrolysis of ATP to AMP and PPi, we calculate that DeltaG'o for the hydrolysis of the adenylyl-DNA ligase is -13.2 kcal mol-1. The presence of conserved basic amino acid residues in the catalytic domain, which are proximal to the active site in the homologous catalytic domain of T7 DNA ligase, suggests that the pKa of Lys159 is perturbed downward by the electrostatic effects of nearby positively charged amino acid side chains. The lower than normal pKa 8.4 compared with 10.5 for the 6-amino group of lysine and the high energy of the alpha,beta-phosphoanhydride linkage in ATP significantly facilitate adenylylation of the enzyme.

Functional domains of an NAD+-dependent DNA ligase

Limited proteolysis of the NAD+-dependent DNA ligase from Bacillus stearothermophilus with thermolysin results in two fragments which were resistant to further proteolysis. These fragments were characterised by N-terminal protein sequencing and electrospray mass spectrometry. The larger, N-terminal fragment consists of the first 318 residues and the smaller, C-terminal fragment begins at residue 397 and runs to the C terminus. Both fragments were over-expressed in Escherichia coli and purified to homogeneity from this source. The large fragment retains the full self-adenylation activity of the intact enzyme, has minimal DNA binding activity and vastly reduced ligation activity. The small fragment lacks adenylation activity but binds to nicked DNA with a similar affinity to that of the intact enzyme. It is unable to stimulate the ligation activity of the large fragment. Atomic absorption spectroscopy showed that the intact protein and the small fragment bind a zinc ion but the large fragment does not. No evidence of any interaction between the two fragments could be obtained. Thus, we conclude that NAD+-dependent DNA ligases consist of at least two discrete functional domains: an N-terminal domain which is responsible for cofactor binding and self adenylation, and a C-terminal DNA-binding domain which contains a zinc binding site.

Mutational analysis of Chlorella virus DNA ligase: catalytic roles of domain I and motif VI

A conserved catalytic core of the ATP-dependent DNA ligases is composed of an N-terminal domain (domain 1, containing nucleotidyl transferase motifs I, III, IIIa and IV) and a C-terminal domain (domain 2, containing motif VI) with an intervening cleft. Motif V links the two structural domains. Deletion analysis of the 298 amino acid Chlorella virus DNA ligase indicates that motif VI plays a critical role in the reaction of ligase with ATP to form ligase-adenylate, but is dispensable for the two subsequent steps in the ligation pathway; DNA-adenylate formation and strand closure. We find that formation of a phosphodiester at a pre-adenylated nick is subject to a rate limiting step that does not apply during the sealing of nicked DNA by ligase-adenylate. This step, presumably conformational, is accelerated or circumvented by deleting five amino acids of motif VI. The motif I lysine nucleophile (Lys27) is not required for strand closure by wild-type ligase, but this residue enhances the closure rate by a factor of 16 when motif VI is truncated. We find that a more extensively truncated ligase consisting of only N-terminal domain 1 and motif V is inert in ligase--adenylate formation, but competent to catalyze strand closure at a pre-adenylated nick. These results suggest that different enzymic catalysts facilitate the three steps of the DNA ligase reaction.

Crystal structure of an ATP-dependent DNA ligase from bacteriophage T7

The crystal structure of the ATP-dependent DNA ligase from bacteriophage T7 has been solved at 2.6 A resolution. The protein comprises two domains with a deep cleft running between them. The structure of a complex with ATP reveals that the nucleotide binding pocket is situated on the larger N-terminal domain, at the base of the cleft between the two domains of the enzyme. Comparison of the overall domain structure with that of DNA methyltransferases, coupled with other evidence, suggests that DNA also binds in this cleft. Since this structure is the first of the nucleotidyltransferase superfamily, which includes the eukaryotic mRNA capping enzymes, the relationship between the structure of DNA ligase and that of other nucleotidyltransferases is also discussed.

Bacteriophage T7 DNA ligase. Overexpression, purification, crystallization, and characterization

The bacteriophage T7 DNA ligase gene was amplified using polymerase chain reaction-based methods and cloned into a T7 promoter-based expression vector. The protein was overexpressed to greater than 15% of total soluble protein and purified to homogeneity, yielding 60-70 mg of protein per liter of bacterial culture. An initial physical and biochemical characterization of the enzyme reveals that it exists as a monomer and can ligate nicked, cohesive, and blunt-ended DNA fragments. Inhibition of the enzyme activity by a nonhydrolyzable ATP analogue was also investigated. The enzyme has been crystallized from methoxypolyethylene glycol. The crystals are of the orthorhombic space group P2(1)2(1)2 and diffract to 2.6 A. The unit cell dimensions are a = 66.1 A, b = 87.6 A, and c = 78.6 A, with one monomer in the asymmetric unit (Vm = 2.77 A3/Da). This is the first member of the DNA ligase family of enzymes to be crystallized.

Structurally complex and highly active RNA ligases derived from random RNA sequences

Seven families of RNA ligases, previously isolated from random RNA sequences, fall into three classes on the basis of secondary structure and regiospecificity of ligation. Two of the three classes of ribozymes have been engineered to act as true enzymes, catalyzing the multiple-turnover transformation of substrates into products. The most complex of these ribozymes has a minimal catalytic domain of 93 nucleotides. An optimized version of this ribozyme has a kcat exceeding one per second, a value far greater than that of most natural RNA catalysts and approaching that of comparable protein enzymes. The fact that such a large and complex ligase emerged from a very limited sampling of sequence space implies the existence of a large number of distinct RNA structures of equivalent complexity and activity.

Cloning, overexpression and nucleotide sequence of a thermostable DNA ligase-encoding gene

Thermostable DNA ligase has been harnessed for the detection of single-base genetic diseases using the ligase chain reaction [Barany, Proc. Natl. Acad. Sci. USA 88 (1991) 189-193]. The Thermus thermophilus (Tth) DNA ligase-encoding gene (ligT) was cloned in Escherichia coli by genetic complementation of a ligts 7 defect in an E. coli host. Nucleotide sequence analysis of the gene revealed a single chain of 676 amino acid residues with 47% identity to the E. coli ligase. Under phoA promoter control, Tth ligase was overproduced to greater than 10% of E. coli cellular proteins. Adenylated and deadenylated forms of the purified enzyme were distinguished by apparent molecular weights of 81 kDa and 78 kDa, respectively, after separation via sodium dodecyl sulfate-polyacrylamide-gel electrophoresis.

Variation in DNA ligase structure during repair and replication processes in monkey kidney cells

Using a method that detects catalytically active DNA ligase in NaDodSO4-polyacrylamide gels (activity gels) we have characterized ligase produced in CV1-P monkey kidney cells infected with SV40 or treated with mitomycin C. Purification on hydroxylapatite columns of DNA ligase from control cells results in two peaks of activity called ligases I and II, respectively. Analysis of ligase I on activity gels revealed major catalytic peptides with Mr of 120, 110, 70 and 58 kDa, while analysis of ligase II revealed two major peptides of 65 and 58 kDa. Infecting CV1-P cells with SV40 produced a significant increase in the 120, 110, 70 and 58 kDa peptides while treating them with mitomycin C produced a significant increase in the 70 and 58 kDa peptides and a decrease in the 120 and 110 kDa ones. Autoproteolysis of partially purified ligase under several conditions resulted in an increase in the 58 kDa peptide and in the disappearance of other peptides. These results suggest that at least one active polypeptide is common to ligases I and II.

Kinetic studies on the reaction catalyzed by DNA ligase from calf thymus

Kinetic analysis of the reaction catalyzed by calf thymus DNA ligase (EC 6.5.1.1) has been carried out using [5'-32P]nicked DNA as substrate. The results of initial velocity and product inhibition studies indicate that the ligase reaction is likely to proceed through the 'uni-uni uni-bi ping-pong' mechanism. The order of substrate addition and product release is as follows: ATP, PPi, nicked DNA, sealed DNA and 5'-AMP. The true Km values for ATP and for nicked DNA (5'-phosphoryl ends) were 2 microM and 0.11 microM, respectively. The turnover number was estimated to be 7 sealing events per min. dATP was an inhibitor competitive with ATP (Ki = 25 microM). The addition of 0.5 mM spermine or 5 mM spermidine resulted in an increase in the apparent Km for nicked DNA as well as in the apparent V, whereas 0.1 M KCl increased only the apparent Km for nicked DNA. Neither polyamine nor KCl affected the apparent Km for ATP. The ligase reaction was not significantly affected by aphidicolin and various phosphate compounds tested.

Regulation of the L-arabinose operon in strains of Escherichia coli containing ColE1-ara hybrid plasmids

Hybrid plasmids were constructed from fragments of F'ara episomes formed by the restriction endonuclease EcoRI and a linear form of the plasmid ColE1 created by cleavage with EcoRI. Hybrid plasmids were constructed containing the entire ara region or the ara region with various parts deleted. E. coli K12 host strains were constructed which contained different deletions of the ara region. The hybrid plasmids were transferred to those strains whose ara deletion complemented that of the plasmid. The initial differential rates of synthesis of L-arabinose isomerase, the product of the araA gene, were determined for the Ara+, plasmid containing strains. These studies demonstrated that strains containing delta(araOIBA)718 produce elevated levels of araC protein, suggesting the araC promoter has been altered by this deletion. Evidence is also presented which suggests that araC protein activates the ara-BAD operon to higher levels when it is present in cis rather than trans. Amplification of the products of the cloned genes is observed when compared to haploid levels in some cases.

Kinetics and effect of salts and polyamines on T4 polynucleotide ligase

The kinetics of T4 polynucleotide ligase has been investigated at pH 8,20 degrees C and using the double-stranded DNA substrate (dA)n - [(dT)10]n/10. Double-reciprocal plots of initial rates vs substrate concentrations as well as product inhibition studies have indicated that the enzyme reacts according to a ping-pong mechanism. The overall mechanism was found to be non-processive. The true Km for the DNA substrate was 0.6 muM and that of ATP 100 muM. Several attempts were made to reverse the T4 polynucleotide ligase joining reaction using 32-p-labelled (dA)n - [(DT)40]n/40 as substrate. No breakdown of this DNA could be detected. The joining reaction was inhibited by high concentrations, i.e. above approximately 70mM, of salts such as KCl, NaCl, NH4Cl and CsCl. At a concentration of 200 mM almost 100% inhibition was observed. Polyamines also caused inhibition of the enzyme, the most efficient inhibitor being spermine followed by spermidine. At a concentration of 1 mM spermine, virtually no joining took place. Addition of salts or polyamines resulted in a large increase in the apparent Km for the DNA substrate whereas the apparent Km for ATP remained unchanged. It is suggested that the affinity of the enzyme for the DNA substrate is decreased in the presence of inhibiting agents.

Properties of a DNA-adenylate complex formed in the reaction between mammalian DNA ligase I and DNA containing single-strand breaks

The major DNA ligase from calf thymus (mammalian DNA ligase I) forms a covalent enzyme-AMP complex on incubation with ATP [Söderhäll & Lindahl, J. Biol. Chem. 248, 672-675, (1973)]. The reaction of this complex with DNA has now been studied. When the ligase-adenylate complex is incubated at 0 degrees C for short time periods with DNA containing single-strand breaks, a DNA-AMP complex can be isolated from the reaction mixture by isopycnic centrifugation in CsCl. Incubation at pH 6.5 increased the amount of DNA-AMP complex that could be isolated 10-20-fold relative to that obtained at pH 7.4. Under the same conditions, incubation of the ligase-AMP complex with DNA free from single-strand breaks did not lead to detectable DNA-AMP formation. The DNA-AMP complex was resistant to treatment with dilute acid and alkali indicating the presence of a covalent linkage. Further, this complex was sensitive to DNase but resistant to pronase and RNase. Free AMP was released on further incubation of the isolated DNA-AMP complex with thymus DNA ligase I and Mg2+, suggesting that the complex is a reaction intermediate. Degradation of the DNA-AMP complex with several reagent enzymes indicated that the AMP residues were bound at the 5' ends of the single-strand breaks in DNA by pyrophosphate bonds.

The radiobiology of DNA strand breakage

The yield of single-strand breaks in lambda DNA within lysogenic host bacteria was measured after exposure to 4-MeV electrons (50 msec) and rapid transfer (45 msec) to alkaline detergent. In nitrogen anoxia the yield was 1.2 X 10(-12) DNA single-strand breaks per rad per dalton, and under full oxygenation the yield increased to 5 X 10(-12) breaks per rad per dalton. A search for the presence of fast repair of strand breaks operating within a fraction of a second. Strand breaks produced in the persence of oxygen were repaired in 30-40 sec, while breaks produced under anoxia were rejoined even slower. A functional product from the po[A] gene was needed for the rejoining of the broken molecules. Intermediate levels of DNA strand breakage seen at low concentrations of oxygen are dependent on the concentration of cellular sulfhydryl compounds, suggesting that in strand breakage oxygen donors compete for reactions with radiation-induced transients in the DNA. Intercomparisons of data on radiation-induced lethality of cells and single-strand breaks in episomal DNA allow the distinction between two classes of radiation-induced radicals, R-1 and R-2, with different chemical properties; R-1 reacts readily with oxygen and N-oxyls under formation of potentially lethal products. The reactivity of oxygen in this reaction is 30-40 times higher than that of TMPN. R-2 reacts 16 times more readily that R-1 with oxygen under formation of single-strand breaks in the DNA. R-2 does not react with N-oxyls.