Covalent Complex of DNA and Bacterial Topoisomerase: Implications in Antibacterial Drug Development

A topoisomerase-DNA transient covalent complex can be a druggable target for novel topoisomerase poison inhibitors that represent a new class of antibacterial or anticancer drugs. Herein, we have investigated molecular features of the functionally important Escherichia coli topoisomerase I (EctopoI)-DNA covalent complex (EctopoIcc) for molecular simulations, which is very useful in the development of new antibacterial drugs. To demonstrate the usefulness of our approach, we used a model small molecule (SM), NSC76027, obtained from virtual screening. We examined the direct binding of NSC76027 to EctopoI as well as inhibition of EctopoI relaxation activity of this SM via experimental techniques. We then performed molecular dynamics (MD) simulations to investigate the dynamics and stability of EctopoIcc and EctopoI-NSC76027-DNA ternary complex. Our simulation results show that NSC76027 forms a stable ternary complex with EctopoIcc. EctopoI investigated here also serves as a model system for investigating a complex of topoisomerase and DNA in which DNA is covalently attached to the protein.     

Microbial Type IA Topoisomerase C-Terminal Domain Sequence Motifs,Distribution and Combination

Type IA topoisomerases have highly conserved catalytic N-terminal domains for the cleaving and rejoining of a single DNA/RNA strand that have been extensively characterized. In contrast, the C-terminal region has been less covered. Two major types of small tandem C-terminal domains, Topo_C_ZnRpt (containing C4 zinc finger) and Topo_C_Rpt (without cysteines) were initially identified in Escherichia coli and Mycobacterium tuberculosis topoisomerase I, respectively. Their structures and interaction with DNA oligonucleotides have been revealed in structural studies. Here, we first present the diverse distribution and combinations of these two structural elements in various bacterial topoisomerase I (TopA). Previously, zinc fingers have not been seen in type IA topoisomerases from well-studied fungal species within the phylum Ascomycota. In our extended studies of C-terminal DNA-binding domains, the presence of zf-GRF and zf-CCHC types of zinc fingers in topoisomerase III (Top3) from fungi species in many phyla other than Ascomycota has drawn our attention. We secondly analyze the distribution and combination of these fungal zf-GRF- and zf-CCHC-containing domains. Their potential structures and DNA-binding mechanism are evaluated. The highly diverse arrangements and combinations of these DNA/RNA-binding domains in microbial type IA topoisomerase C-terminal regions have important implications for their interactions with nucleic acids and protein partners as part of their physiological functions.     

Mutations of vaccinia virus DNA topoisomerase I that stabilize the cleavage complex

Two mutations in vaccinia virus topoisomerase I, K167D and G226N, have been characterized. SOS induction was observed in Escherichia coli expressing vaccinia topoisomerase I with either one of these mutations. The mutant enzymes were purified to homogeneity and compared with the wild type enzyme for relaxation activity and the partial activities of substrate binding, site-specific DNA cleavage and DNA religation to determine the mechanism of SOS induction. The K167D mutant enzyme had reduced binding affinity for the DNA substrate with a Kapp that was 10-fold higher than wild type. Nevertheless, in reactions with high enzyme concentration, its substrate cleavage activity was 90% that of wild type. The G226N mutant enzyme had virtually wild type binding and cleavage activities. However, intermolecular religation by these two mutants were observed to be significantly reduced. The cleavage complexes formed with the K167D and G226N mutants were more stable to high salt than the wild type cleavable complex. We propose that these mutants in vivo induce the SOS response in E. coli due to the shift of topoisomerase cleavage-religation equilibrium towards cleavage and increased stability of the cleavage complex. The mutation thus has a similar effect as the topoisomerase-targeting inhibitors that turn topoisomerases into DNA damaging agents.