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.     

On the role of E-ring oxygen atoms in the binding of camptothecin to the topoisomerase I-DNA covalent binary complex

A recent X-ray crystallographic analysis of the binding of a water soluble camptothecin analogue to the human topoisomerase I-DNA covalent binary complex has suggested the existence of some novel features in the way that camptothecin is bound to the binary complex. Four additional models based on chemical and biochemical data have also been proposed. Presently we describe S-containing analogues of camptothecin prepared on the basis of these models, and report their ability to form stable ternary complexes with human topoisomerase I, and to mediate cytotoxicity at the locus of topoisomerase I. The results indicate that replacement of the 20-OH group of CPT with a SH functionality results in diminution of the potency of CPT as a topoisomerase I poison, while replacement of the O atoms at positions 20 and 21 with S atoms results in essentially complete loss of topoisomerase I inhibitory activity.     

Role of the 20-hydroxyl group in camptothecin binding by the topoisomerase I-DNA binary complex

Recent findings concerning the structure of the covalent binary complex formed by DNA topisomerase I and its DNA substrate, as well as the nature of interactions with inhibitors that bind reversibly to this binary complex, have led to two proposed models for the binding of the prototype inhibitor camptothecin to the DNA-topisomerase I binary complex. While these models differ in many regards, they both suggest the involvement of the 20-OH group of camptothecin in a donor hydrogen bond with an enzyme side chain functional group. Presently, five analogues of camptothecin that differ only at C-20 have been evaluated for their ability to bind to the topoisomerase I-DNA binary complex and thereby inhibit enzyme function. Both 20-chloro- and 20-bromocamptothecin bound as well to the enzyme-DNA binary complex as 20-aminoCPT despite the absence of a substituent at C-20 capable of contributing a donor hydrogen bond.     

Kinetic studies of human tyrosyl-DNA phosphodiesterase, an enzyme in the topoisomerase I DNA repair pathway.

Tyrosyl-DNA phosphodiesterase (TDP) cleaves the phosphodiester bond linking the active site tyrosine residue of topoisomerase I with the 3' terminus of DNA in topoisomerase I-DNA complexes which accumulate during treatment of cancer with camptothecin. In yeast, TDP mutation confers a 1000-fold hypersensitivity to camptothecin in the presence of an additional mutation of RAD9 gene [Pouliot, J.J., Yao, K.C., Robertson, C.A. & Nash, H.A. (1999) Science 286, 552-555]. Based on the recently solved crystal structure, human TDP belongs to a distinct class within the phospholipase D superfamily in spite of very low sequence homology [Interthal, H., Pouliot, J.J. & Champoux, J.J. (2001) Proc. Natl Acad. Sci. USA 98, 12009-12014, and Davies, D.R., Interthal, H., Champoux, J.J. & Hol, W.G.J. (2002) Structure 10, 237-248]. To understand the enzymatic mechanism of this novel enzyme, and to facilitate inhibitor screening of human TDP, we have expressed and purified recombinant human TDP variants carrying deletions of 1-39 or 1-174 amino acids. Furthermore, a continuous colorimetric assay in a 96-well format was also developed using p-nitrophenyl-thymidine-3'-phosphate as substrate. This assay system is able to detect enzymatic activity at enzyme concentrations as low as 15 nm. Purified recombinant human TDPNDelta39 cleaved p-nitrophenyl-thymidine-3'-phosphate with Km and kcat values of 211.14 +/- 23.83 micro m and 8.82 +/- 0.57 per min in the presence of Mn2+.     

Apoptotic topoisomerase I-DNA complexes induced by staurosporine-mediated oxygen radicals

Topoisomerase I (Top1), an abundant nuclear enzyme expressed throughout the cell cycle, relaxes DNA supercoiling by forming transient covalent DNA cleavage complexes. We show here that staurosporine, a ubiquitous inducer of apoptosis in mammalian cells, stabilizes cellular Top1 cleavage complexes. These complexes are formed indirectly as staurosporine cannot induce Top1 cleavage complexes in normal DNA with recombinant Top1 or nuclear extract from normal cells. In treated cells, staurosporine produces oxidative DNA lesions and generates reactive oxygen species (ROS). Quenching of these ROS by the antioxidant N-acetyl-l-cysteine or inhibition of the mitochondrial dependent production of ROS by the caspase inhibitor benzyloxycarbonyl-VAD prevents staurosporine-induced Top1 cleavage complexes. Down-regulation of Top1 by small interfering RNA decreases staurosporine-induced apoptotic DNA fragmentation. We propose that Top1 cleavage complexes resulting from oxidative DNA lesions generated by ROS in staurosporine-treated cells contribute to the full apoptotic response.     

AP-site cleavage activity of tyrosyl-DNA phosphodiesterase 1

APE-independent base excision repair (BER) pathway plays an important role in the regulation of DNA repair mechanisms. In this study it has been found that recently discovered tyrosyl-DNA phosphodiesterase 1 (Tdp1) catalyzes the AP site cleavage reaction to generate breaks with the 3'- and 5'-phosphate termini. The removal of the 3'-phosphate is performed by polynucleotide kinase phosphatase (PNKP). Tdp1 is known to interact stably with BER proteins: DNA polymerase beta (Pol β), XRCC1, PARP1 and DNA ligase III. The data suggest a role of Tdp1 in the new APE-independent BER pathway in mammals.     

Mutation of a conserved active site residue converts tyrosyl-DNA phosphodiesterase I into a DNA topoisomerase I-dependent poison

Tyrosyl-DNA phosphodiesterase 1 (Tdp1) catalyzes the resolution of 3' and 5' phospho-DNA adducts. A defective mutant, associated with the recessive neurodegenerative disease SCAN1, accumulates Tdp1-DNA complexes in vitro. To assess the conservation of enzyme architecture, a 2.0 A crystal structure of yeast Tdp1 was determined that is very similar to human Tdp1. Poorly conserved regions of primary structure are peripheral to an essentially identical catalytic core. Enzyme mechanism was also conserved, because the yeast SCAN1 mutant (H(432)R) enhanced cell sensitivity to the DNA topoisomerase I (Top1) poison camptothecin. A more severe Top1-dependent lethality of Tdp1H(432)N was drug-independent, coinciding with increased covalent Top1-DNA and Tdp1-DNA complex formation in vivo. However, both H(432) mutants were recessive to wild-type Tdp1. Thus, yeast H(432) acts in the general acid/base catalytic mechanism of Tdp1 to resolve 3' phosphotyrosyl and 3' phosphoamide linkages. However, the distinct pattern of mutant Tdp1 activity evident in yeast cells, suggests a more severe defect in Tdp1H(432)N-catalyzed resolution of 3' phospho-adducts.     

Interaction of the human topoisomerase I-DNA complex with oligo-1,3-thiazolecarboxamides and their oligonucleotide conjugates

Nonnatural thiazole-containing oligopeptides (TCOs) bind to the DNA minor groove and inhibit the reaction catalyzed by human topoisomerase I (TopoI). The effect is directly proportional to the number of thiazole monomers in TCO. Several TCOs with three or four thiazole monomers act 3–10 times more efficiently than distamycin A, a natural antibiotic containing pyrrole rings. Additional groups at the N and C termini only slightly affect TopoI inhibition by TCO. The inhibitory effect of TCOs is higher than that of homo-or heterooligopeptides containing imidazole or pyrrole monomers, and the most potent are oligopeptide-oligonucleotide conjugates. The plausible causes of the different effects of distamycin and the nonnatural peptides on DNA relaxation catalyzed by TopoI are discussed.     

Eukaryotic topoisomerase I-DNA interaction is stabilized by helix curvature.

The influence of DNA structure on topoisomerase I-DNA interaction has been investigated using a high affinity binding site and mutant derivatives thereof. Parallel determinations of complex formation and helix structure in the absence of superhelical stress suggest that the interaction is intensified by stable helix curvature. Previous work showed that a topoisomerase I binding site consists of two functionally distinct subdomains. A region located 5' to the topoisomerase I cleavage site is essential for binding. The region 3' to the cleavage site is covered by the enzyme, but not essential. We report here that the helix conformation of the latter region is an important modulator of complex formation. Thus, complex formation is markedly stimulated, when an intrinsically bent DNA segment is installed in this region. A unique pattern of phosphate ethylation interferences in the 3'-part of the binding site indicates that sensing of curvature involves backbone contacts. Since dynamic curvature in supercoiled DNA may substitute for stable curvature, our findings suggest that topoisomerase I is able to probe DNA topology by assessment of writhe, rather than twist.     

Analysis of human tyrosyl-DNA phosphodiesterase I catalytic residues

Tyrosyl-DNA phosphodiesterase I (Tdp1) is involved in the repair of DNA lesions created by topoisomerase I in vivo. Tdp1 is a member of the phospholipase D (PLD) superfamily of enzymes and hydrolyzes 3'-phosphotyrosyl bonds to generate 3'-phosphate DNA and free tyrosine in vitro. Here, we use synthetic 3'-(4-nitro)phenyl, 3'-(4-methyl)phenyl, and 3'-tyrosine phosphate oligonucleotides to study human Tdp1. Kinetic analysis of human Tdp1 (hTdp1) shows that the enzyme has nanomolar affinity for all three substrates and the overall in vitro reaction is diffusion-limited. Analysis of active-site mutants using these modified substrates demonstrates that hTdp1 uses an acid/base catalytic mechanism. The results show that histidine 493 serves as the general acid during the initial transesterification, in agreement with hypotheses based on previous crystal structure models. The results also argue that lysine 495 and asparagine 516 participate in the general acid reaction, and the analysis of crystal structures suggests that these residues may function in a proton relay. Together with previous crystal structure data, the new functional data provide a mechanistic understanding of the conserved histidine, lysine and asparagine residues found among all PLD family members.     

Structure and hydration of the DNA-human topoisomerase I covalent complex.

The structure and hydration of reconstituted human topoisomerase I comprising the core and the carboxyl-terminal domains in covalent complex with 22-basepair DNA duplex has been investigated by molecular dynamics simulation. The structure and the intermolecular interactions were found to be well maintained over the simulation. The complex displays a high degree of flexibility of the contact area, confirmed by the presence of numerous water-mediated protein-DNA hydrogen bonds comparable in quantity and distribution to the direct ones. The interaction between the enzyme and the solvent also provides the key for interpreting the experimental reduction of activity or affinity observed upon single residue mutation. Finally, four long lasting water molecules are observed in the proximity of the active site, one of which in the appropriate position to accept a proton from the active Tyr723.     

Differential induction of Leishmania donovani bi-subunit topoisomerase I-DNA cleavage complex by selected flavones and camptothecin: activity of flavones against camptothecin-resistant topoisomerase I

Emergence of the bi-subunit topoisomerase I in the kinetoplastid family (Trypanosoma and Leishmania) has brought a new twist in topoisomerase research related to evolution, functional conservation and preferential sensitivities to the specific inhibitors of type IB topoisomerase family. In the present study, we describe that naturally occurring flavones baicalein, luteolin and quercetin are potent inhibitors of the recombinant Leishmania donovani topoisomerase I. These compounds bind to the free enzyme and also intercalate into the DNA at a very high concentration (300 µM) without binding to the minor grove. Here, we show that inhibition of topoisomerase I by these flavones is due to stabilization of topoisomerase I–DNA cleavage complexes, which subsequently inhibit the religation step. Their ability to stabilize the covalent topoisomerase I–DNA complex in vitro and in living cells is similar to that of the known topoisomerase I inhibitor camptothecin (CPT). However, in contrast to CPT, baicalein and luteolin failed to inhibit the religation step when the drugs were added to pre-formed enzyme substrate binary complex. This differential mechanism to induce the stabilization of cleavable complex with topoisomerase I and DNA by these selected flavones and CPT led us to investigate the effect of baicalein and luteolin on CPT-resistant mutant enzyme LdTOP1Δ39LS lacking 1–39 amino acids of the large subunit [B. B. Das, N. Sen, S. B. Dasgupta, A. Ganguly and H. K. Majumder (2005) J. Biol. Chem. 280, 16335–16344]. Baicalein and luteolin stabilize duplex oligonucleotide cleavage with LdTOP1Δ39LS. This observation was further supported by the stabilization of in vivo cleavable complex by baicalein and luteolin with highly CPT-resistant L.donovani strain. Taken together, our data suggest that the interacting amino acid residues of topoisomerase I may be partially overlapping or different for flavones and CPT. This study illuminates new properties of the flavones and provide additional insights into the ligand binding properties of L.donovani topoisomerase I.     

Repair of DNA damage induced by the mycotoxin alternariol involves tyrosyl-DNA phosphodiesterase 1

Alternariol (AOH) was reported recently to act as a topoisomerase poison. To underline the relevance of topoisomerase targeting for the genotoxic properties of AOH, we addressed the question whether human tyrosyl-DNA phosphodiesterase 1 (TDP1), an enzyme vital to the repair of covalent DNA-topoisomerase adducts, affects AOH-mediated genotoxicity. The relevance of TDP1 activity on AOH-induced genotoxicity was investigated by the comet assay in human cells overexpressing GFP chimera of TDP1 or the inactive mutant TDP1^H263A as well as in cells subjected to siRNA-mediated knock-down of endogenous TDP1. Cells overexpressing TDP1 exhibited significantly less DNA damage after treatment with AOH in comparison to cells expressing the inactive mutant TDP1^H263A. In accordance with these results, levels of AOH inducing DNA strand breaks were increased in TDP1-suppressed cells in comparison to cells transfected with control siRNA. The specific topoisomerase poisons camptothecin and etoposide caused comparable effects, underlining that TDP1 plays an important role in the repair of topoisomerase-mediated DNA damage. In summary, the repair enzyme TDP1 was identified as a factor for the modulation of AOH-mediated DNA damage in human cells.     

Usnic acid derivatives are effective inhibitors of tyrosyl-DNA phosphodiesterase 1

The synthesis of (+)-usnic acid derivatives is described. The derivatives contain one or two cyano groups, connected to the acetophenone fragment of dibenzofuran core by linkers of different length and character, or some other modifications. The influence of these compounds on the activity of recombinant human tyrosyl-DNA phosphodiesterase 1 and MCF-7 tumor cells’ viability has been estimated. The data indicate a distinct dependence of functional characteristics of the compounds on their structure.     

The crystal structure of human tyrosyl-DNA phosphodiesterase, Tdp1

Tyrosyl-DNA phosphodiesterase (Tdp1) catalyzes the hydrolysis of a phosphodiester bond between a tyrosine residue and a DNA 3' phosphate. The enzyme appears to be responsible for repairing the unique protein-DNA linkage that occurs when eukaryotic topoisomerase I becomes stalled on the DNA in the cell. The 1.69 A crystal structure reveals that human Tdp1 is a monomer composed of two similar domains that are related by a pseudo-2-fold axis of symmetry. Each domain contributes conserved histidine, lysine, and asparagine residues to form a single active site. The structure of Tdp1 confirms that the protein has many similarities to the members of the phospholipase D (PLD) superfamily and indicates a similar catalytic mechanism. The structure also suggests how the unusual protein-DNA substrate binds and provides insights about the nature of the substrate in vivo.     

Substrate specificity of tyrosyl-DNA phosphodiesterase I (Tdp1)

Tyrosyl-DNA phosphodiesterase I (Tdp1) hydrolyzes 3'-phosphotyrosyl bonds to generate 3'-phosphate DNA and tyrosine in vitro. Tdp1 is involved in the repair of DNA lesions created by topoisomerase I, although the in vivo substrate is not known. Here we study the kinetic and binding properties of human Tdp1 (hTdp1) to identify appropriate 3'-phosphotyrosyl DNA substrates. Genetic studies argue that Tdp1 is involved in double and single strand break repair pathways; however, x-ray crystal structures suggest that Tdp1 can only bind single strand DNA. Separate kinetic and binding experiments show that hTdp1 has a preference for single-stranded and blunt-ended duplex substrates over nicked and tailed duplex substrate conformations. Based on these results, we present a new model to explain Tdp1/DNA binding properties. These results suggest that Tdp1 only acts upon double strand breaks in vivo, and the roles of Tdp1 in yeast and mammalian cells are discussed.