Structural impact of the leukemia drug 1-beta-D-arabinofuranosylcytosine (Ara-C) on the covalent human topoisomerase I-DNA complex

1-beta-d-Arabinofuranosylcytosine (Ara-C) is a potent antineoplastic drug used in the treatment of acute leukemia. Previous biochemical studies indicated the incorporation of Ara-C into DNA reduced the catalytic activity of human topoisomerase I by decreasing the rate of single DNA strand religation by the enzyme by 2-3-fold. We present the 3.1 A crystal structure of human topoisomerase I in covalent complex with an oligonucleotide containing Ara-C at the +1 position of the non-scissile DNA strand. The structure reveals that a hydrogen bond formed between the 2'-hydroxyl of Ara-C and the O4' of the adjacent -1 base 5' to the damage site stabilizes a C3'-endo pucker in the Ara-C arabinose ring. The structural distortions at the site of damage are translated across the DNA double helix to the active site of human topoisomerase I. The free sulfhydryl at the 5'-end of the nicked DNA strand in this trapped covalent complex is shifted out of alignment with the 3'-phosphotyrosine linkage at the catalytic tyrosine 723 residue, producing a geometry not optimal for religation. The subtle structural changes caused by the presence of Ara-C in the DNA duplex may contribute to the cytotoxicity of this leukemia drug by prolonging the lifetime of the covalent human topoisomerase I-DNA complex.     

The structure of the transition state of the heterodimeric topoisomerase I of Leishmania donovani as a vanadate complex with nicked DNA

Type IB topoisomerases are essential enzymes that are responsible for relaxing superhelical tension in DNA by forming a transient covalent nick in one strand of the DNA duplex. Topoisomerase I is a target for anti-cancer drugs such as camptothecin, and these drugs also target the topoisomerases I in pathogenic trypanosomes including Leishmania species and Trypanosoma brucei. Most eukaryotic enzymes, including human topoisomerase I, are monomeric. However, for Leishmania donovani, the DNA-binding activity and the majority of residues involved in catalysis are located in a large subunit, designated TOP1L, whereas the catalytic tyrosine residue responsible for covalent attachment to DNA is located in a smaller subunit, called TOP1S. Here, we present the 2.27A crystal structure of an active truncated L.donovani TOP1L/TOP1S heterodimer bound to nicked double-stranded DNA captured as a vanadate complex. The vanadate forms covalent linkages between the catalytic tyrosine residue of the small subunit and the nicked ends of the scissile DNA strand, mimicking the previously unseen transition state of the topoisomerase I catalytic cycle. This structure fills a critical gap in the existing ensemble of topoisomerase I structures and provides crucial insights into the catalytic mechanism.     

A novel bipartite mode of binding of M. smegmatis topoisomerase I to its recognition sequence

We have investigated interaction of Mycobacterium smegmatis topoisomerase I at its specific recognition sequence. DNase I footprinting demonstrates a large region of protection on both the scissile and non-scissile strands of DNA. Methylation protection and interference analyses reveal base-specific contacts within the recognition sequence. Missing contact analyses reveal additional interactions with the residues in both single and double-stranded DNA, and hence underline the role for the functional groups associated with those bases. These interactions are supplemented by phosphate contacts in the scissile strand. Conformation specific probes reveal protein-induced structural distortion of the DNA helix at the T-A-T-A sequence 11 bp upstream to the recognition sequence. Based on these footprinting analyses that define parameters of topoisomerase I-DNA interactions, a model of topoisomerase I binding to its substrate is presented. Within the large protected region of 30 bp, the enzyme makes direct contact at two locations in the scissile strand, one around the cleavage site and the other 8-12 bases upstream. Thus the enzyme makes asymmetric recognition of DNA and could carry out DNA relaxation by either of the two proposed mechanisms: enzyme bridged and restricted rotation.     

Recombinogenic flap ligation mediated by human topoisomerase I

Aberration of eukaryotic topoisomerase I catalysis leads to potentially recombinogenic pathways by allowing the joining of heterologous DNA strands. Recently, a new ligation pathway (flap ligation) was presented for vaccinia virus topoisomerase I, in which blunt end cleavage complexes ligate the recessed end of duplex acceptors having a single-stranded 3'-tail. This reaction was suggested to play an important role in the repair of topoisomerase I-induced DNA double-strand breaks. Here, we characterize flap ligation mediated by human topoisomerase I. We demonstrate that cleavage complexes containing the enzyme at a blunt end allow invasion of a 3'-acceptor tail matching the scissile strand of the donor, which facilitates ligation of the recessed 5'-hydroxyl end. However, the reaction was strictly dependent on the length of double-stranded DNA of the donor complexes, and longer stretches of base-pairing inhibited strand invasion. The stabilization of the DNA helix was most probably provided by the covalently bound enzyme itself, since deleting the N-terminal domain of human topoisomerase I stimulated flap ligation. We suggest that stabilization of the DNA duplex upon enzyme binding may play an important role during normal topoisomerase I catalysis by preventing undesired strand transfer reactions. For flap ligation to function in a repair pathway, factors other than topoisomerase I, such as helicases, would be necessary to unwind the DNA duplex and allow strand invasion.     

Remote phosphate contacts trigger assembly of the active site of DNA topoisomerase IB

Vaccinia topoisomerase IB forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at its target site 5'-CCCTTp downward arrow in duplex DNA. The contributions of backbone electrostatics and individual phosphate oxygens to the transesterification reaction were probed by introducing 22 single Rp and Sp methylphosphonate diastereomers at 11 positions flanking the cleavage site. Methyl groups at eight positions (four on the scissile strand and four on the nonscissile strand) inhibited the rate of single-turnover cleavage by factors of 50-50,000. Stereospecific interference was observed at several phosphates, thereby distinguishing simple electrostatic contributions from putative specific polar contacts to either the pro-Sp or pro-Rp oxygens. The functionally relevant phosphate oxygens are located on the minor groove face of the helix on which the scissile phosphodiester resides. Our findings, combined with available crystal structures of vaccinia and human topoisomerase IB, show how specific phosphate contacts remote from where chemistry occurs are critical for assembly of the active site.     

Minimal DNA duplex requirements for topoisomerase I-mediated cleavage in vitro

The minimal DNA duplex requirements for topoisomerase I-mediated cleavage at a specific binding sequence were determined by analyzing the interaction of the enzyme with sets of DNA substrates varying successively by single nucleotides at the 5'- or 3' end of either strand. Topoisomerase I cleavage experiments showed a minimal region of nine nucleotides on the scissile strand and five nucleotides on the noncleaved strand. On the scissile strand, seven of the nine nucleotides were situated upstream to the cleavage site, while all five nucleotides required on the non-cleaved strand were located to this side. The results suggested that topoisomerase I bound tightly to this region, stabilizing the DNA duplex extensively. On minimal substrates which were partially single-stranded downstream to the cleavage site, cleavage was suicidal, that is, the enzyme was able to cleave the substrates, but unable to perform the final religation.     

Unmasking Anticooperative DNA-binding interactions of vaccinia DNA topoisomerase I

Vaccinia DNA topoisomerase (vTopo) catalyzes highly specific nucleophilic substitution at a single phosphodiester linkage in the pentapyrimidine recognition sequence 5'-(C/T)+5C4+C3+T+2T+1p \N-1 using an active-site tyrosine nucleophile, thereby expelling a 5' hydroxyl leaving group of the DNA. Here, we report the energetic effects of subtle modifications to the major-groove hydrogen-bond donor and acceptor groups of the 3'-GGGAA-5' consensus sequence of the nonscissile strand in the context of duplexes in which the scissile strand length was progressively shortened. We find that the major-groove substitutions become energetically more damaging as the scissile strand is shortened from 32 to 24 and 18 nucleotides, indicating that enzyme interactions with the duplex region present in the 32-mer but not the 24- or 18-mer weaken specific interactions with the DNA major groove. Regardless of strand length, the destabilizing effects of the major-groove substitutions increase as the reaction proceeds from the Michaelis complex to the transition state for DNA cleavage and, finally, to the phosphotyrosine-DNA covalent complex. These length-dependent anticooperative interactions involving the DNA major groove and duplex regions 3' to the cleavage site indicate that the major-groove binding energy is fully realized late during the reaction for full-length substrates but that smaller more flexible duplex substrates feel these interactions earlier along the reaction coordinate. Such anticooperative binding interactions may play a role in strand exchange and supercoil unwinding activities of the enzyme.     

Crystal structure of a bacterial type IB DNA topoisomerase reveals a preassembled active site in the absence of DNA

Type IB DNA topoisomerases are found in all eukarya, two families of eukaryotic viruses (poxviruses and mimivirus), and many genera of bacteria. They alter DNA topology by cleaving and resealing one strand of duplex DNA via a covalent DNA-(3-phosphotyrosyl)-enzyme intermediate. Bacterial type IB enzymes were discovered recently and are described as poxvirus-like with respect to their small size, primary structures, and bipartite domain organization. Here we report the 1.75-A crystal structure of Deinococcus radiodurans topoisomerase IB (DraTopIB), a prototype of the bacterial clade. DraTopIB consists of an amino-terminal (N) beta-sheet domain (amino acids 1-90) and a predominantly alpha-helical carboxyl-terminal (C) domain (amino acids 91-346) that closely resemble the corresponding domains of vaccinia virus topoisomerase IB. The five amino acids of DraTopIB that comprise the catalytic pentad (Arg-137, Lys-174, Arg-239, Asn-280, and Tyr-289) are preassembled into the active site in the absence of DNA in a manner nearly identical to the pentad configuration in human topoisomerase I bound to DNA. This contrasts with the apoenzyme of vaccinia topoisomerase, in which three of the active site constituents are either displaced or disordered. The N and C domains of DraTopIB are splayed apart in an "open" conformation, in which the surface of the catalytic domain containing the active site is exposed for DNA binding. A comparison with the human topoisomerase I-DNA cocrystal structure suggests how viral and bacterial topoisomerase IB enzymes might bind DNA circumferentially via movement of the N domain into the major groove and clamping of a disordered loop of the C domain around the helix.     

Two classes of DNA end-joining reactions catalyzed by vaccinia topoisomerase I.

The ability of a eukaryotic DNA topoisomerase I to catalyze DNA rearrangements was examined in vitro using defined substrates and purified enzyme. Site-specific DNA strand cleavage by vaccinia topoisomerase I across from a nick generated double-strand breaks that could be religated to a heterologous blunt-ended duplex DNA regardless of the sequence of the acceptor molecule. Topoisomerase bound covalently at internal positions could religate the bound strand to an incoming acceptor provided that DNA molecule had sequence homology to the region 3' of the scissile bond. These end-joining reactions suggest two potential modes of topoisomerase-mediated recombination that differ in their requirements for DNA homology.     

Requirements for noncovalent binding of vaccinia topoisomerase I to duplex DNA.

Vaccinia DNA topoisomerase binds duplex DNA and forms a covalent adduct at sites containing a conserved sequence element 5'(C/T)CCTT decreases in the scissile strand. Distinctive aspects of noncovalent versus covalent interaction emerge from analysis of the binding properties of Topo(Phe-274), a mutated protein which is unable to cleave DNA, but which binds DNA noncovalently. Whereas DNA cleavage by wild type enzyme is most efficient with 'suicide' substrates containing fewer than 10 base pairs distal to the scissile bond, optimal noncovalent binding by Topo(Phe-274) requires at least 10-bp of DNA 3' of the cleavage site. Thus, the region of DNA flanking the pentamer motif serves to stabilize the noncovalent topoisomerase-DNA complex. This result is consistent with the downstream dimensions of the DNA binding site deduced from nuclease footprinting. Topo(Phe-274) binds to duplex DNA lacking the consensus pentamer with 7-10-fold lower affinity than to CCCTT-containing DNA.     

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.     

DNA ligation catalyzed by human topoisomerase II alpha

The DNA ligation reaction of topoisomerase II is essential for genomic integrity. However, it has been impossible to examine many fundamental aspects of this reaction because ligation assays historically required the enzyme to cleave a DNA substrate before sealing the nucleic acid break. Recently, a cleavage-independent DNA ligation assay was developed for human topoisomerase IIalpha [Bromberg, K. D., Hendricks, C., Burgin, A. B., and Osheroff, N. (2002) J. Biol. Chem. 277, 31201-31206]. This assay overcomes the requirement for DNA cleavage by monitoring the ability of the enzyme to ligate a nicked oligonucleotide in which the 5'-terminal phosphate at the nick has been activated by covalent attachment to the tyrosine mimic, p-nitrophenol. The cleavage-independent ligation assay was used to more fully characterize the DNA ligation activity of human topoisomerase IIalpha. Results suggest that the active site tyrosine contributes little to the catalysis of DNA ligation beyond its primary role as an activating/leaving group. Although arginine 804 (the residue immediately N-terminal to the active site tyrosine) has been proposed to help anchor the 5'-DNA terminus during cleavage, conversion of this residue to alanine had only a modest effect on DNA ligation. Thus, it appears that arginine 804 does not play an essential role in DNA strand joining. In contrast, disruption of base pairing at the 5'-DNA terminus abrogated DNA ligation in the absence of a covalent enzyme-DNA bond. Therefore, it is proposed that base pairing represents a secondary mechanism for aligning the 5'-DNA termini for ligation. Finally, the human enzyme appears to ligate the two scissile bonds of a cleavage site in a nonconcerted fashion.     

Mechanism of strand passage by Escherichia coli topoisomerase I. The role of the required nick in catenation and knotting of duplex DNA

We studied the interaction between topoisomerase I and a nicked DNA substrate to determine how the nick permits Escherichia coli topoisomerase I to catenate and knot duplex DNA rings. The presence of just a single nick in a 6600-base pair DNA increased the amount of DNA bound to topoisomerase I by 6-fold. The enzyme acts at the nick, as shown by linearization of nicked circles and covalent attachment of an enzyme molecule opposite the nick. DNA breaks are also introduced by the enzyme at sites not opposite to a nick, but three orders of magnitude less efficiently. The break induced by the enzyme is within several base pairs of the nick and on the complementary strand, but the exact site cut is dictated by DNA sequence requirements. Because these sequence requirements are identical to those for cutting of single-stranded DNA, we conclude that the enzyme stabilizes a denatured region at the nick. Breaks in single-stranded DNA occur 98% of the time when a C residue is four bases to the 5' side unless G is adjacent and 5' to the break. For a DNA circle nicked at a unique location, the efficiency of DNA breakage opposite the nick correlates with the rate of catenation. We present a unified model for the relaxation, catenation, and knotting reactions of topoisomerase I in which the enzyme induces a break in a single-stranded region, but bridges that break with covalent and noncovalent interactions and allows passage of one duplex or single-stranded DNA segment.     

Sequence specific interaction of Mycobacterium smegmatis topoisomerase I with duplex DNA.

We have identified strong topoisomerase sites (STS) for Mycobacteruim smegmatis topoisomerase I in double-stranded DNA context using electrophoretic mobility shift assay of enzyme-DNA covalent complexes. Mg2+, an essential component for DNA relaxation activity of the enzyme, is not required for binding to DNA. The enzyme makes single-stranded nicks, with transient covalent interaction at the 5'-end of the broken DNA strand, a characteristic akin to prokaryotic topoisomerases. More importantly, the enzyme binds to duplex DNA having a preferred site with high affinity, a property similar to the eukaryotic type I topoisomerases. The preferred cleavage site is mapped on a 65 bp duplex DNA and found to be CG/TCTT. Thus, the enzyme resembles other prokaryotic type I topoisomerases in mechanistics of the reaction, but is similar to eukaryotic enzymes in DNA recognition properties.     

Topoisomerase I-DNA complexes contribute to arsenic trioxide-induced apoptosis

Topoisomerase I is an essential enzyme that relaxes DNA supercoiling by forming covalent DNA cleavage complexes, which are normally transient. Topoisomerase I-DNA complexes can be trapped by anticancer drugs (camptothecins) as well as by endogenous and exogenous DNA lesions. We show here that arsenic trioxide (a potent inducer of apoptosis that induces the intracellular accumulation of reactive oxygen species and targets mitochondria) induces cellular topoisomerase I cleavage complexes. Bcl-2 overexpression and quenching of reactive oxygen species, which prevent arsenic trioxide-induced apoptosis, also prevent the formation of topoisomerase I-DNA complexes, whereas enhancement of reactive oxygen species accumulation promotes these complexes. The caspase inhibitor, benzyloxycarbonyl-VAD partially prevents arsenic trioxide-induced topoisomerase I-DNA complexes and apoptosis, suggesting that activated caspases further maintain intracellular levels of reactive oxygen species that induce the formation of topoisomerase I-DNA complexes. Down-regulation of topoisomerase I expression decreases arsenic trioxide-induced apoptotic DNA fragmentation. Thus, we propose that arsenic trioxide induces topoisomerase I-DNA complexes that participate in chromatin fragmentation and programmed cell death during apoptosis.