Characterization of a temperature-sensitive DNA ligase from Escherichia coli

DNA ligases are essential enzymes in cells due to their ability to join DNA strand breaks formed during DNA replication. Several temperature-sensitive mutant strains of Escherichia coli, including strain GR501, have been described which can be complemented by functional DNA ligases. Here, it is shown that the ligA251 mutation in E. coli GR501 strain is a cytosine to thymine transition at base 43, which results in a substitution of leucine by phenylalanine at residue 15. The protein product of this gene (LigA251) is accumulated to a similar level at permissive and non-permissive temperatures. Compared to wild-type LigA, at 20 °C purified LigA251 has 20-fold lower ligation activity in vitro, and its activity is reduced further at 42 °C, resulting in 60-fold lower ligation activity than wild-type LigA. It is proposed that the mutation in LigA251 affects the structure of the N-terminal region of LigA. The resulting decrease in DNA ligase activity at the non-permissive temperature is likely to occur as the result of a conformational change that reduces the rate of adenylation of the ligase

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

New strategies for assessing the sequence selective binding of small molecules to DNA

We have developed two different approaches towards overcoming limitations of footprinting.REPSA: (Restriction Enzyme Protection Selection and Amplification) is a novel technique used to determine the binding sites of DNA binding ligands. This technique uses type IIs restriction enzymes (which cut several bases away from their recognition sites) to selectively cleave unbound DNA, while DNA fragments to which the ligand is bound are protected from digestion. The reaction is performed with oligonucleotides containing recognition sites for these enzymes which flank a central region of random bases around their cutting site. The uncut products of the reaction are amplified by PCR, and are subjected to further rounds of drug binding and enzyme cleavage, enriching for oligonucleotides containing the preferred ligand binding sites. After several rounds of selection the fragments are cloned and sequenced, revealing the preferred binding sites. We have successfully employed this technique for confirming the binding sites of TANDEM (TpA) and distamycin (AT), though it has been less successful for determining the binding sites of echinomycin (CpG).MULTISITE: We have prepared a DNA footprinting substrate which contains all 136 possible tetranucleotide sequences, and have used DNase I footprinting to examine the binding of some ligands with known recognition properties. These ligands include actinomycin, which is known to bind to GpC; echinomycin (CpG), TANDEM (TpA), mithramycin (GpC, GpG) and the AT-selective minor groove binding ligands distamycin and Hoechst 33258. These ligands show large differences in their binding to tetranucleotides which contain the preferred dinucleotide steps. For example ACGT and ACGG are much better binding sites for echinomycin than GCGC, CCGG and GCGG.</p

Characterization of an ATP-dependent DNA ligase from the acidophilic archaeon "Ferroplasma acidarmanus" Fer1

Analysis of the genome of "Ferroplasma acidarmanus" Fer1, an archaeon that is an extreme acidophile, identified an open reading frame encoding a putative ATP-dependent DNA ligase, which we termed FaLig. The deduced amino acid sequence of FaLig contains 595 amino acids, with a predicted molecular mass of 67.8 kDa. "F. acidarmanus" Fer1 is classified as a Euryarchaeote, but phylogenetic analysis using amino acid sequences showed that FaLig is more similar to DNA ligases from Crenarchaeota, suggesting that lateral transfer of these genes has occurred among archaea. The gene sequence encoding FaLig was cloned into a bacterial expression vector harbouring an upstream His-tag to aid purification. Conditions for expression and purification from Escherichia coli were identified and recombinant FaLig was confirmed to be an ATP-dependent DNA ligase. Optimal conditions for nick-joining by the protein were pH 6-7, 0.5 mM ATP, in the presence of either Mg2+ or Mn2+. Using a range of nicked, double-stranded nucleic acids, ligation was detected with the same substrates as previously determined for other DNA ligases. Although FaLig is the DNA ligase from one of the most extreme acidophilic organism yet studied, this characterization suggests that its biochemical mechanism is analogous to that of enzymes from other cellular systems

Tethered DNA hairpins facilitate electrochemical detection of DNA ligation

A novel electrochemical assay for DNA ligase activity is described. The assay exploits the properties of DNA hairpins tethered at one terminus to a gold electrode and labelled at the other with a ferrocene group for rapid characterisation of DNA status by cyclic voltammetry. Successful ligation of ‘nicked’ DNA hairpins is indicated by retention of the ferrocene couple when exposure to DNA ligase is followed by conditions that denature the hairpin. The results demonstrate the simplicity of integrating electrochemical detection with hairpin based biosensors and illustrate a new approach to the assay of DNA ligases, of which the NAD+-dependent enzymes represent a potential broad spectrum antibacterial drug target

Immobilized DNA hairpins for assay of sequential breaking and joining of DNA backbones

Immobilized DNA hairpins are exploited in a novel approach to assay DNA ligases and nucleases. A fundamental characteristic of the assay is that a fluorophore at the remote terminus of the hairpin reports on the integrity of the DNA backbone. The functionality of the protocol is confirmed using ATP- and NAD+-dependent DNA ligases and the nicking enzyme N.BbvCIA. The assay format is amenable to high-throughput analysis and quantitation of enzyme activity, and it is shown to be in excellent agreement with the more laborious electrophoretic approaches that are widely used for such analyses. Significantly, the assay is used to demonstrate sequential breaking and rejoining of a specific nucleic acid. Thus, a simple platform for biochemically innovative studies of pathways in cellular nucleic acid metabolism is demonstrated