Uncoupling of the DNA breaking and rejoining steps of Escherichia coli type I DNA topoisomerase. Demonstration of an active covalent protein-DNA complex

Unravelling the mechanisms of Type 1A topoisomerases using single-molecule approaches

Topoisomerases are essential enzymes that regulate DNA topology. Type 1A family topoisomerases are found in nearly all living organisms and are unique in that they require single-stranded (ss)DNA for activity. These enzymes are vital for maintaining supercoiling homeostasis and resolving DNA entanglements generated during DNA replication and repair. While the catalytic cycle of Type 1A topoisomerases has been long-known to involve an enzyme-bridged ssDNA gate that allows strand passage, a deeper mechanistic understanding of these enzymes has only recently begun to emerge. This knowledge has been greatly enhanced through the combination of biochemical studies and increasingly sophisticated single-molecule assays based on magnetic tweezers, optical tweezers, atomic force microscopy and Förster resonance energy transfer. In this review, we discuss how single-molecule assays have advanced our understanding of the gate opening dynamics and strand-passage mechanisms of Type 1A topoisomerases, as well as the interplay of Type 1A topoisomerases with partner proteins, such as RecQ-family helicases. We also highlight how these assays have shed new light on the likely functional roles of Type 1A topoisomerases in vivo and discuss recent developments in single-molecule technologies that could be applied to further enhance our understanding of these essential enzymes.

Type IA Topoisomerases as Targets for Infectious Disease Treatments

Infectious diseases are one of the main causes of death all over the world, with antimicrobial resistance presenting a great challenge. New antibiotics need to be developed to provide therapeutic treatment options, requiring novel drug targets to be identified and pursued. DNA topoisomerases control the topology of DNA via DNA cleavage-rejoining coupled to DNA strand passage. The change in DNA topological features must be controlled in vital processes including DNA replication, transcription, and DNA repair. Type IIA topoisomerases are well established targets for antibiotics. In this review, type IA topoisomerases in bacteria are discussed as potential targets for new antibiotics. In certain bacterial pathogens, topoisomerase I is the only type IA topoisomerase present, which makes it a valuable antibiotic target. This review will summarize recent attempts that have been made to identify inhibitors of bacterial topoisomerase I as potential leads for antibiotics and use of these inhibitors as molecular probes in cellular studies. Crystal structures of inhibitor-enzyme complexes and more in-depth knowledge of their mechanisms of actions will help to establish the structure-activity relationship of potential drug leads and develop potent and selective therapeutics that can aid in combating the drug resistant bacterial infections that threaten public health.

Molecular dissection of Helicobacter pylori Topoisomerase I reveals an additional active site in the carboxyl terminus of the enzyme

DNA topoisomerases play a crucial role in maintaining DNA superhelicity, thereby regulating various cellular processes. Unlike most other species, the human pathogen Helicobacter pylori has only two topoisomerases, Topoisomerase I and DNA gyrase, the physiological roles of which remain to be explored. Interestingly, there is enormous variability among the C-terminal domains (CTDs) of Topoisomerase I across bacteria. H. pylori Topoisomerase I (HpTopoI) CTD harbors four zinc finger motifs (ZFs). We show here that sequential deletion of the third and/or fourth ZFs had only a marginal effect on the HpTopoI activity, while deletion of the second, third and fourth ZFs severely reduced DNA relaxation activity. Deletion of all ZFs drastically hampered DNA binding and thus abolished DNA relaxation. Surprisingly, mutagenesis of the annotated active site tyrosine residue (Y297 F) did not abrogate the enzyme activity and HpTopoI CTD alone (spanning the four ZFs) showed DNA relaxation activity. Additionally, a covalent linkage between the DNA and HpTopoI CTD was identified. The capacity of HpTopoI CTD to complement Escherichia coli topA mutant strains further supported the in vitro observations. Collectively these results imply that not all ZFs are dispensable for HpTopoI activity and unveil the presence of additional non-canonical catalytic site(s) within the enzyme.

Investigating mycobacterial topoisomerase I mechanism from the analysis of metal and DNA substrate interactions at the active site

We have obtained new crystal structures of Mycobacterium tuberculosis topoisomerase I, including structures with ssDNA substrate bound to the active site, with and without Mg²⁺ ion present. Significant enzyme conformational changes upon DNA binding place the catalytic tyrosine in a pre-transition state position for cleavage of a specific phosphodiester linkage. Meanwhile, the enzyme/DNA complex with bound Mg²⁺ ion may represent the post-transition state for religation in the enzyme's multiple-step DNA relaxation catalytic cycle. The first observation of Mg²⁺ ion coordinated with the TOPRIM residues and DNA phosphate in a type IA topoisomerase active site allows assignment of likely catalytic role for the metal and draws a comparison to the proposed mechanism for type IIA topoisomerases. The critical function of a strictly conserved glutamic acid in the DNA cleavage step was assessed through site-directed mutagenesis. The functions assigned to the observed Mg²⁺ ion can account for the metal requirement for DNA rejoining but not DNA cleavage by type IA topoisomerases. This work provides new structural insights into a more stringent requirement for DNA rejoining versus cleavage in the catalytic cycle of this essential enzyme, and further establishes the potential for selective interference of DNA rejoining by this validated TB drug target.

Direct observation of topoisomerase IA gate dynamics

Type IA topoisomerases cleave single-stranded DNA and relieve negative supercoils in discrete steps corresponding to the passage of the intact DNA strand through the cleaved strand. Although type IA topoisomerases are assumed to accomplish this strand passage via a protein-mediated DNA gate, opening of this gate has never been observed. We developed a single-molecule assay to directly measure gate opening of the Escherichia coli type IA topoisomerases I and III. We found that after cleavage of single-stranded DNA, the protein gate opens by as much as 6.6 nm and can close against forces in excess of 16 pN. Key differences in the cleavage, ligation, and gate dynamics of these two enzymes provide insights into their different cellular functions. The single-molecule results are broadly consistent with conformational changes obtained from molecular dynamics simulations. These results allowed us to develop a mechanistic model of interactions between type IA topoisomerases and single-stranded DNA.

Investigating direct interaction between Escherichia coli topoisomerase I and RecA

Protein-protein interactions are of special importance in cellular processes, including replication, transcription, recombination, and repair. Escherichia coli topoisomerase I (EcTOP1) is primarily involved in the relaxation of negative DNA supercoiling. E. coli RecA, the key protein for homologous recombination and SOS DNA-damage response, has been shown to stimulate the relaxation activity of EcTOP1. The evidence for their direct protein-protein interaction has not been previously established. We report here the direct physical interaction between E. coli RecA and topoisomerase I. We demonstrated the RecA-topoisomerase I interaction via pull-down assays, and surface plasmon resonance measurements. Molecular docking supports the observation that the interaction involves the topoisomerase I N-terminal domains that form the active site. Our results from pull-down assays showed that ATP, although not required, enhances the RecA-EcTOP1 interaction. We propose that E. coli RecA physically interacts with topoisomerase I to modulate the chromosomal DNA supercoiling.

Use of double-stranded DNA mini-circles to characterize the covalent topoisomerase-DNA complex

The enzymatic DNA relaxation requires the DNA to be transiently nicked and rejoined, the covalent topoisomerase-DNA complex being a key intermediate of the nicking-joining reaction. Practically, this reaction is most often characterized by oligonucleotides. However, the incision-religation of an oligonucleotide does not fully recapitulate the incision-religation occuring during relaxation and the preferred substrate for such reaction characterization is supercoiled DNA. We therefore developed a method that used radiolabeled supercoiled DNA mini-circles to characterize the covalent enzyme-DNA complex formed during a relaxation reaction. Resolution of the relaxation products under different conditions permitted to quantify the proportion of covalent complex formed during the relaxation catalyzed by two topoisomerase models, the Escherichia coli topoisomerase I and the calf thymus topoisomerase I. As expected, the covalent complex formed with the calf thymus topoisomerase I was significantly enriched by camptothecin, a widely-used inhibitor of this topoisomerase, and a salt jump permitted the multiple topoisomerases trapped per mini-circle to complete the reaction cycle. The identified positions of the camptothecin-induced incision sites were shown to be independent of the linking number and the substrate circular nature Overall, our results demonstrate that supercoiled mini-circles constitute a powerful and polyvalent substrate to characterize the mechanism of action of novel topoisomerases and inhibitors, including the incision-religation reaction.

Targeting Mycobacterium tuberculosis topoisomerase I by small-molecule inhibitors

We describe inhibition of Mycobacterium tuberculosis topoisomerase I (MttopoI), an essential mycobacterial enzyme, by two related compounds, imipramine and norclomipramine, of which imipramine is clinically used as an antidepressant. These molecules showed growth inhibition of both Mycobacterium smegmatis and M. tuberculosis cells. The mechanism of action of these two molecules was investigated by analyzing the individual steps of the topoisomerase I (topoI) reaction cycle. The compounds stimulated cleavage, thereby perturbing the cleavage-religation equilibrium. Consequently, these molecules inhibited the growth of the cells overexpressing topoI at a low MIC. Docking of the molecules on the MttopoI model suggested that they bind near the metal binding site of the enzyme. The DNA relaxation activity of the metal binding mutants harboring mutations in the DxDxE motif was differentially affected by the molecules, suggesting that the metal coordinating residues contribute to the interaction of the enzyme with the drug. Taken together, the results highlight the potential of these small molecules, which poison the M. tuberculosis and M. smegmatis topoisomerase I, as leads for the development of improved molecules to combat mycobacterial infections. Moreover, targeting metal coordination in topoisomerases might be a general strategy to develop new lead molecules.

Substrate-mediated proton relay mechanism for the religation reaction in topoisomerase II

The DNA religation reaction of yeast type II topoisomerase (topo II) was investigated to elucidate its metal-dependent general acid/base catalysis. Quantum mechanical/molecular mechanical calculations were performed for the topo II religation reaction, and the proton transfer pathway was examined. We found a substrate-mediated proton transfer of the topo II religation reaction, which involves the 3' OH nucleophile, the reactive phosphate, water, Arg781, and Tyr782. Metal A stabilizes the transition states, which is consistent with a two-metal mechanism in topo II. This pathway may be required for the cleavage/religation reaction of topo IA and II and will provide a general explanation for the catalytic mechanism in the topo IA and II.

3,4-dimethoxyphenyl bis-benzimidazole, a novel DNA topoisomerase inhibitor that preferentially targets Escherichia coli topoisomerase I

OBJECTIVES

Antibiotic resistance in bacterial pathogens is a serious clinical problem. Novel targets are needed to combat increasing drug resistance in Escherichia coli. Our objective is to demonstrate that 2-(3,4-dimethoxyphenyl)-5-[5-(4-methylpiperazin-1-yl)-1H-benzimidazol-2yl]-1H-benzimidazole (DMA) inhibits E. coli DNA topoisomerase I more strongly than human topoisomerase I. In addition, DMA is non-toxic to mammalian cells at antibiotic dosage level.

METHODS

In the present study, we have established DMA as an antibacterial compound by determining MICs, post-antibiotic effects (PAEs) and MBCs for different standard as well as clinical strains of E. coli. We have described the differential catalytic inhibitory mechanism of bis-benzimidazole, DMA, for human and E. coli topoisomerase I and topoisomerase II by performing different assays, including relaxation assays, cleavage-religation assays, DNA unwinding assays, ethidium bromide displacement assays, decatenation assays and DNA gyrase supercoiling assays.

RESULTS

DMA significantly inhibited bacterial growth at a very low concentration, but did not affect human cell viability at higher concentrations. Activity assays showed that it preferentially targeted E. coli topoisomerase I over human topoisomerase I, topoisomerase II and gyrase. Cleavage-religation assays confirmed DMA as a poison inhibitor of E. coli topoisomerase I. This study illuminates new properties of DMA, which may be further modified to develop an efficient topoisomerase inhibitor that is selective towards bacterial topoisomerase I.

CONCLUSIONS

This is the first report of a bis-benzimidazole acting as an E. coli topoisomerase I inhibitor. DMA is a safe, non-cytotoxic molecule to human cells at concentrations that are needed for antibacterial activity.

The strictly conserved Arg-321 residue in the active site of Escherichia coli topoisomerase I plays a critical role in DNA rejoining

The strictly conserved arginine residue proximal to the active site tyrosine of type IA topoisomerases is required for the relaxation of supercoiled DNA and was hypothesized to be required for positioning of the scissile phosphate for DNA cleavage to take place. Mutants of recombinant Yersinia pestis topoisomerase I with hydrophobic substitutions at this position were found in genetic screening to exhibit a dominant lethal phenotype, resulting in drastic loss in Escherichia coli viability when overexpressed. In depth biochemical analysis of E. coli topoisomerase I with the corresponding Arg-321 mutation showed that DNA cleavage can still take place in the absence of this arginine function if Mg(2+) is present to enhance the interaction of the enzyme with the scissile phosphate. However, DNA rejoining is inhibited in the absence of this conserved arginine, resulting in accumulation of the cleaved covalent intermediate and loss of relaxation activity. These new experimental results demonstrate that catalysis of DNA rejoining by type IA topoisomerases has a more stringent requirement than DNA cleavage. In addition to the divalent metal ions, the side chain of this arginine residue is required for the precise positioning of the phosphotyrosine linkage for nucleophilic attack by the 3'-OH end to result in DNA rejoining. Small molecules that can interfere or distort the enzyme-DNA interactions required for DNA rejoining by bacterial type IA topoisomerases could be developed into novel antibacterial drugs.

Deciphering the distinct role for the metal coordination motif in the catalytic activity of Mycobacterium smegmatis topoisomerase I

Mycobacterium smegmatis topoisomerase I (MstopoI) is distinct from typical type IA topoisomerases. The enzyme binds to both single- and double-stranded DNA with high affinity, making specific contacts. The enzyme comprises conserved regions similar to type IA topoisomerases from Escherichia coli and other eubacteria but lacks the typically found zinc fingers in the carboxy-terminal domain. The enzyme can perform DNA cleavage in the absence of Mg(2+), but religation needs exogenously added Mg(2+). One molecule of Mg(2+) tightly bound to the enzyme has no role in DNA cleavage but is needed only for the religation reaction. The toprim (topoisomerase-primase) domain in MstopoI comprising the Mg(2+) binding pocket, conserved in both type IA and type II topoisomerases, was subjected to mutagenesis to understand the role of Mg(2+) in different steps of the reaction. The residues D108, D110, and E112 of the enzyme, which form the acidic triad in the DXDXE motif, were changed to alanines. D108A mutation resulted in an enzyme that is Mg(2+) dependent for DNA cleavage unlike MstopoI and exhibited enhanced DNA cleavage property and reduced religation activity. The mutant was toxic for cell growth, most likely due to the imbalance in cleavage-religation equilibrium. In contrast, the E112A mutant behaved like wild-type enzyme, cleaving DNA in a Mg(2)(+)-independent fashion, albeit to a reduced extent. Intra- and intermolecular religation assays indicated specific roles for D108 and E112 residues during the reaction. Together, these results indicate that the D108 residue has a major role during cleavage and religation, while E112 is important for enhancing the efficiency of cleavage. Thus, although architecturally and mechanistically similar to topoisomerase I from E. coli, the metal coordination pattern of the mycobacterial enzyme is distinct, opening up avenues to exploit the enzyme to develop inhibitors.

Asp-to-Asn substitution at the first position of the DxD TOPRIM motif of recombinant bacterial topoisomerase I is extremely lethal to E. coli

The TOPRIM domain found in many nucleotidyl transferases contains a DxD motif involved in magnesium ion coordination for catalysis. Medium- to high-copy-number plasmid clones of Yersinia pestis topoisomerase I (YpTOP) with Asp-to-Asn substitution at the first aspartate residue (D117N) of this motif could not be generated in Escherichia coli without second-site mutation even when expression was under the control of the tightly regulated BAD promoter and suppressed by 2% glucose in the medium. Arabinose induction of a single-copy YpTOP-D117N mutant gene integrated into the chromosome resulted in approximately 10(5)-fold of cell killing in 2.5 h. Attempt to induce expression of the corresponding E. coli topoisomerase I mutant (EcTOP-D111N) encoded on a high-copy-number plasmid resulted in either loss of viability or reversion of the clone to wild type. High-copy-number plasmid clones of YpTOP-D119N and EcTOP-D113N with the Asn substitution at the second Asp of the TOPRIM motif could be stably maintained, but overexpression also decreased cell viability significantly. The Asp-to-Asn substitutions at these TOPRIM residues can selectively decrease Mg(2+) binding affinity with minimal disruption of the active-site geometry, leading to trapping of the covalent complex with cleaved DNA and causing bacterial cell death. The extreme sensitivity of the first TOPRIM position suggested that this might be a useful site for binding of small molecules that could act as topoisomerase poisons.

Inhibition of Mg2+ binding and DNA religation by bacterial topoisomerase I via introduction of an additional positive charge into the active site region

Among bacterial topoisomerase I enzymes, a conserved methionine residue is found at the active site next to the nucleophilic tyrosine. Substitution of this methionine residue with arginine in recombinant Yersinia pestis topoisomerase I (YTOP) was the only substitution at this position found to induce the SOS response in Escherichia coli. Overexpression of the M326R mutant YTOP resulted in ∼4 log loss of viability. Biochemical analysis of purified Y. pestis and E. coli mutant topoisomerase I showed that the Met to Arg substitution affected the DNA religation step of the catalytic cycle. The introduction of an additional positive charge into the active site region of the mutant E. coli topoisomerase I activity shifted the pH for optimal activity and decreased the Mg²⁺ binding affinity. This study demonstrated that a substitution outside the TOPRIM motif, which binds Mg²⁺directly, can nonetheless inhibit Mg²⁺ binding and DNA religation by the enzyme, increasing the accumulation of covalent cleavage complex, with bactericidal consequence. Small molecules that can inhibit Mg²⁺ dependent religation by bacterial topoisomerase I specifically could be developed into useful new antibacterial compounds. This approach would be similar to the inhibition of divalent ion dependent strand transfer by HIV integrase in antiviral therapy.

Human topoisomerase I mediates illegitimate recombination leading to DNA insertion into the ribosomal DNA locus in Saccharomyces cerevisiae

Eukaryotic type I DNA topoisomerases catalyze the relaxation of supercoiled DNA, and play a critical role in DNA replication, transcription and recombination. They are highly conserved, both in sequence and mechanism of activity, from yeast to mammalian cells. We tested the effect of human topoisomerase I (hTOP1) on illegitimate insertion in yeast by expressing the hTOP1 gene in top1Delta yeast ( ytop1Delta) cells. hTOP1 increased the frequency of illegitimate recombination into genomic DNA by 20- to 90-fold relative to the level in ytop1Delta cells, while it had no effect on homologous integration. The addition of the topoisomerase I inhibitor camptothecin blocked this increase in the level of illegitimate insertion. The expression of hTOP1 also significantly enhanced the fraction of integration events in ribosomal DNA (rDNA)-from 16% to 60%, indicating that the rDNA is a highly preferred target for hTOP1. Integrations occurred at the consensus sequence 5' (T/A) (G/C/A) (T/A) (T/C/A) 3' in hTOP1 expressing cells. A similar preferred break-site consensus sequence was previously identified in vitro for topoisomerases from rat liver and wheat germ.

Biochemical characterization of an invariant histidine involved in Escherichia coli DNA topoisomerase I catalysis

An invariant histidine residue, His-365 in Escherichia coli DNA topoisomerase I, is located at the active site of type IA DNA topoisomerases and near the active site tyrosine. Its ability to participate in the multistep catalytic process of DNA relaxation was investigated. His-365 was mutated to alanine, arginine, asparagine, aspartate, glutamate, and glutamine to study its ability to participate in general acid/base catalysis and bind DNA. The mutants were examined for pH-dependent DNA relaxation and cleavage, salt-dependent DNA relaxation, and salt-dependent DNA binding affinity. The mutants relax DNA in a pH-dependent manner and at low salt concentrations. The pH dependence of all mutants is different from the wild type, suggesting that His-365 is responsible for the pH dependence of the enzyme. Additionally, whereas the wild type enzyme shows pH-dependent oligonucleotide cleavage, cleavage by both H365Q and H365A is pH-independent. H365Q cleaves DNA with rates similar to the wild type enzyme, whereas H365A has a slower rate of DNA cleavage than the wild type but can cleave more substrate overall. H365A also has a lower DNA binding affinity than the wild type enzyme. The binding affinity was determined at different salt concentrations, showing that the alanine mutant displaces half a charge less upon binding DNA than an inactive form of topoisomerase I. These observations indicate that His-365 participates in DNA binding and is responsible for optimal catalysis at physiological pH.

Site-directed mutagenesis of conserved aspartates, glutamates and arginines in the active site region of Escherichia coli DNA topoisomerase I

To catalyze relaxation of supercoiled DNA, DNA topoisomerases form a covalent enzyme-DNA intermediate via nucleophilic attack of a tyrosine hydroxyl group on the DNA phosphodiester backbone bond during the step of DNA cleavage. Strand passage then takes place to change the linking number. This is followed by DNA religation during which the displaced DNA hydroxyl group attacks the phosphotyrosine linkage to reform the DNA phosphodiester bond. Mg(II) is required for the relaxation activity of type IA and type II DNA topoisomerases. A number of conserved amino acids with acidic and basic side chains are present near Tyr-319 in the active site of the crystal structure of the 67-kDa N-terminal fragment of Escherichia coli DNA topoisomerase I. Their roles in enzyme catalysis were investigated by site-directed mutation to alanine. Mutation of Arg-136 abolished all the enzyme relaxation activity even though DNA cleavage activity was retained. The Glu-9, Asp-111, Asp-113, Glu-115, and Arg-321 mutants had partial loss of relaxation activity in vitro. All the mutants failed to complement chromosomal topA mutation in E. coli AS17 at 42 degreesC, possibly accounting for the conservation of these residues in evolution.

Identification of active site residues in Escherichia coli DNA topoisomerase I

Alanine substitution mutagenesis of Escherichia coli DNA topoisomerase I, a member of the type IA subfamily of DNA topoisomerases, was carried out to identify amino acid side chains that are involved in transesterification between DNA and the active site tyrosine Tyr-319 of the enzyme. Twelve polar residues that are highly conserved among the type IA enzymes, Glu-9, His-33, Asp-111, Glu-115, Gln-309, Glu-313, Thr-318, Arg-321, Thr-322, Asp-323, His-365, and Thr-496, were selected for alanine substitution. Each of the mutant enzymes was overexpressed, purified, and characterized. Surprisingly, only substitution at Glu-9 and Arg-321 was found to reduce the DNA relaxation activity of the enzyme to an insignificant level. The R321A mutant enzyme, but not the E9A mutant enzyme, was found to retain a reduced level of DNA cleavage activity. Two additional mutant enzymes R321K and E9Q were also constructed and purified. Replacing Arg-321 by lysine has little effect on enzymatic activities; replacing Glu-9 by glutamine greatly reduces the supercoil removal activity but not the DNA cleavage and rejoining activities. From these results and the locations of the amino acids in the crystal structure of the enzyme, it appears that Glu-9 has a critical role in DNA breakage and rejoining, probably through its interaction with the 3' deoxyribosyl oxygen. The positively charged Arg-321 may also participate in these reactions by interacting with the scissile DNA phosphate as a monodentate. Because of the strict conservation of these residues, the findings for the E. coli enzyme are likely to apply to all type IA DNA topoisomerases.

Effect of Mg(II) binding on the structure and activity of Escherichia coli DNA topoisomerase I

Escherichia coli DNA topoisomerase I requires Mg(II) as a cofactor for the relaxation of negatively supercoiled DNA. Mg(II) binding to the enzyme was shown by fluorescence spectroscopy to affect the tertiary structure of the enzyme. Addition of 2 mM MgCl2 resulted in a 30% decrease in the maximum emission of tryptophan fluorescence of the enzyme. These Mg(II)-induced changes in fluorescence properties were reversible by the addition of EDTA and not obtained with other divalent cations. After incubation with Mg(II) and dialysis, inductively coupled plasma (ICP) analysis showed that each enzyme molecule could form a complex with 1-2 Mg(II) bound to each enzyme molecule. Such Mg(II).enzyme complexes were found to be active in the relaxation of negatively supercoiled DNA in the absence of additional Mg(II). Results from ICP analysis after equilibrium dialysis and relaxation assays with limiting Mg(II) concentrations indicated that both Mg(II) binding sites had to be occupied for the enzyme to catalyze relaxation of negatively supercoiled DNA.

Mitochondrial DNA topoisomerase I of Saccharomyces cerevisiae

A mitochondrial DNA topoisomerase (type I, ATP-independent) can be biochemically distinguished from the nuclear enzyme DNA topoisomerase I. This conclusion is based on the subcellular localization of the mitochondrial enzyme, its optimal reaction conditions and sensitivity to enzyme inhibitors. Unlike its nuclear counterpart, the mitochondrial DNA topoisomerase exhibits an absolute requirement for a divalent cation (Mg2+ and Ca2+ work equally well in vitro). In addition, it is slightly more sensitive to monovalent salts, with optimal activity obtained in 50-100 mM KCl. The mitochondrial enzyme is equally active at pH 7.5 or pH 9.5, but unlike its nuclear equivalent, is inactivated at higher pH values. The mitochondrial DNA topoisomerase is sensitive to coumermycin, berenil, camptothecin and 2,2,5,5-tetramethyl-4-imidazolidinone, a chemical that has no inhibitory effect on DNA topoisomerase I. Immunoblotting studies show that mitochondrial DNA topoisomerase activity is associated with a polypeptide (M(r) approximately 79,000) that cross-reacts with the antiserum against DNA topoisomerase I. Thus, the mitochondrial DNA topoisomerase may be derived by the differential expression of the DNA topoisomerase I gene or from the expression of a gene that is homologous to the DNA topoisomerase I gene.

Mechanistic studies on E. coli DNA topoisomerase I: divalent ion effects

E. coli DNA topoisomerase I catalyzes the hydrolysis of short, single stranded oligodeoxynucleotides. It also forms a covalent protein-DNA complex with negatively supercoiled DNA in the absence of Mg2+ but requires Mg2+ for the relaxation of negatively supercoiled DNA. In this paper we investigate the effects of various divalent metals on catalysis. For the relaxation reaction, maximum enzyme activity plateaus after 2.5 mM Mg2+. However, the rate of cleavage of short oligodeoxynucleotide increased linearly between 0 and 15 mM Mg2+. In the oligodeoxynucleotide cleavage reaction, Ca2+, Mn2+, Co2+, and Zn2+ inhibit enzymatic activity. When these metals are coincubated with Mg2+ at equimolar concentrations, the normal effect of Mg2+ is not detectable. Of these metals, only Ca2+ can be substituted for Mg2+ as a metal cofactor in the relaxation reaction. And when Mg2+ is coincubated with Mn2+, Co2+, or Zn2+ at equimolar concentrations, the normal effect of Mg2+ on relaxation is not detectable. We propose that Mg2+ allows the protein-DNA complex to assume a conformation necessary for strand passage and enhance the rate of enzyme turnover.

Peptide sequencing and site-directed mutagenesis identify tyrosine-319 as the active site tyrosine of Escherichia coli DNA topoisomerase I

Tyrosine 319 of E. coli topoisomerase I is shown to be the active site tyrosine that becomes covalently attached to a DNA 5' phosphoryl group during the transient breakage of a DNA internucleotide bond by the enzyme. The tyrosine was mapped by trapping the covalent complex between the DNA and DNA topoisomerase I, digesting the complex exhaustively with trypsin, and sequencing the DNA-linked tryptic peptide. Site-directed mutagenesis converting Tyr-319 to a serine or phenylalanine completely inactivates the enzyme. The structure of the enzyme and its catalysis of DNA strand breakage, passage, and rejoining are discussed in terms of the available information.

The carboxyl terminal domain of Escherichia coli DNA topoisomerase I confers higher affinity to DNA

Limited digestion of E. coli DNA topoisomerase I with trypsin or papain generated a DNA-binding domain of MW 14,000 corresponding to the carboxyl terminal of the enzyme. This fragment binds to single-stranded DNA agarose as tightly as the intact enzyme. It required around 400 mM NaCl for elution. A truncated topoisomerase that lacks this C-terminal domain was purified. It was eluted from the single-stranded DNA agarose column at around 150 mM NaCl. Although the truncated enzyme could relax negatively supercoiled DNA as efficiently as the intact enzyme at low ionic strength, its processivity was more sensitive to increasing salt concentration. Measurement of binding to fluorescent etheno-M13 DNA also demonstrated that the presence of the C-terminal domain confers higher affinity to DNA for the enzyme.

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.