Cleavage of dT8 and dT8 phosphorothioyl analogues by Escherichia coli DNA topoisomerase I: product and rate analysis

Escherichia coli DNA topoisomerase I catalyzes the cleavage of short, single-stranded oligodeoxynucleotides with dT8 as the shortest cleavable oligo(thymidylic acid). The 5'-32P-labeled products formed from the cleavage of [5'-32P]dT8 are dT5, dT4, and dT3 with over 70% of the substrate cleaved to dT4. Mg(II) ions affect this product distribution by increasing the percentage of dT4 formed. The substitution of a sulfur atom for a nonbridging oxygen atom in a phosphodiester linkage yields oligodeoxynucleotide phosphorothioyl (PS) analogues. The epimers of the analogues were separated, and the position and stereochemistry of the phosphorothiodiester bond were determined. Topoisomerase I is stereospecific in its reactivity toward these analogues. With the oligodeoxynucleotide PS analogue substrates, the rate of cleavage, the stereospecificity, and the product distribution depend upon the position and the stereochemistry of the phosphorothiodiester linkage.     

Zinc (II) coordination in Escherichia coli DNA topoisomerase I is required for cleavable complex formation with DNA.

Escherichia coli DNA topoisomerase I catalyzes relaxation of negatively supercoiled DNA. The reaction proceeds through a covalent intermediate, the cleavable complex, in which the DNA is cleaved and the enzyme is linked to the DNA via a phosphotyrosine linkage. Each molecule of E. coli DNA topoisomerase I has been shown to have three tightly bound zinc(II) ions required for relaxation activity (Tse-Dinh, Y.-C., and Beran-Steed, R.K. (1988) J. Biol. Chem. 263, 15857-15859). It is shown here that Cd(II) could replace Zn(II) in reconstitution of active enzyme from apoprotein. The role of metal was analyzed by studying the partial reactions. The apoenzyme was deficient in sodium dodecyl sulfate-induced cleavage of supercoiled PM2 phage DNA. Formation of covalent complex with linear single-stranded DNA was also reduced in the absence of metal. However, the cleavage of small oligonucleotide was not affected, and the apoenzyme could religate the covalently bound oligonucleotide to another DNA molecule. Assay of noncovalent complex formation by retention of 5'-labeled DNA on filters showed that the apoenzyme was not inhibited in noncovalent binding to DNA. It is proposed that zinc(II) coordination in E. coli DNA topoisomerase I is required for the transition of the noncovalent complex with DNA to the cleavable state.     

Metal ion and inter-domain interactions as functional networks in E. coli topoisomerase I

Escherichia coli topoisomerase I (EcTopoI) is a type IA bacterial topoisomerase which is receiving large attention due to its potential application as novel target for antibacterial therapeutics. Nevertheless, a detailed knowledge of its mechanism of action at molecular level is to some extent lacking. This is partly due to the requirement of several factors (metal ions, nucleic acid) to the proper progress of the enzyme catalytic cycle. Additionally, each of them can differently affect the protein structure.     

Experimental and computational investigations of Ser10 and Lys13 in the binding and cleavage of DNA substrates by Escherichia coli DNA topoisomerase I

Ser10 and Lys13 found near the active site tyrosine of Escherichia coli DNA topoisomerase I are conserved among the type IA topoisomerases. Site-directed mutagenesis of these two residues to Ala reduced the relaxation and DNA cleavage activity, with a more severe effect from the Lys13 mutation. Changing Ser10 to Thr or Lys13 to Arg also resulted in loss of DNA cleavage and relaxation activity of the enzyme. In simulations of the open form of the topoisomerase–DNA complex, Lys13 interacts directly with Glu9 (proposed to be important in the catalytic mechanism). This interaction is removed in the K13A mutant, suggesting the importance of lysine as either a proton donor or a stabilizing cation during strand cleavage, while the Lys to Arg mutation significantly distorts catalytic residues. Ser10 forms a direct hydrogen bond with a phosphate group near the active site and is involved in direct binding of the DNA substrate; this interaction is disturbed in the S10A and S10T mutants. This combination of a lysine and a serine residue conserved in the active site of type IA topoisomerases may be required for correct positioning of the scissile phosphate and coordination of catalytic residues relative to each other so that DNA cleavage and subsequent strand passage can take place.     

SOS induction by stabilized topoisomerase IA cleavage complex occurs via the RecBCD pathway

Accumulation of mutant topoisomerase I cleavage complex can lead to SOS induction and cell death in Escherichia coli. The single-stranded break associated with mutant topoisomerase I cleavage complex is converted to double-stranded break, which then is processed by the RecBCD pathway, followed by association of RecA with the single-stranded DNA.     

Residues of E. coli topoisomerase I conserved for interaction with a specific cytosine base to facilitate DNA cleavage

Bacterial and archaeal topoisomerase I display selectivity for a cytosine base 4 nt upstream from the DNA cleavage site. Recently, the solved crystal structure of Escherichia coli topoisomerase I covalently linked to a single-stranded oligonucleotide revealed that R169 and R173 interact with the cytosine base at the −4 position via hydrogen bonds while the phenol ring of Y177 wedges between the bases at the −4 and the −5 position. Substituting R169 to alanine changed the selectivity of the enzyme for the base at the −4 position from a cytosine to an adenine. The R173A mutant displayed similar sequence selectivity as the wild-type enzyme, but weaker cleavage and relaxation activity. Mutation of Y177 to serine or alanine rendered the enzyme inactive. Although mutation of each of these residues led to different outcomes, R169, R173 and Y177 work together to interact with a cytosine base at the −4 position to facilitate DNA cleavage. These strictly conserved residues might act after initial substrate binding as a Molecular Ruler to form a protein–DNA complex with the scissile phosphate positioned at the active site for optimal DNA cleavage by the tyrosine hydroxyl nucleophile to facilitate DNA cleavage in the reaction pathway.