Critical roles of tyrosyl‐DNA phosphodiesterases in cell tolerance to carnosol‐induced DNA damage

Carnosol is a natural compound with pharmacological action due to its anti‐cancer properties. However, the precise mechanism for its anti‐carcinogenic effect remains elusive. In this study, we used lymphoblastoid TK6 cell lines to identify the DNA damage and repair mechanisms of carnosol. Our results showed that carnosol induced DNA double‐strand breaks (DSBs). We also found that cells lacking tyrosyl‐DNA phosphodiesterase 1 (TDP1), an enzyme related to topoisomerase 1 (TOP1), and tyrosyl‐DNA phosphodiesterase 2 (TDP2), an enzyme related to topoisomerase 2 (TOP2), were supersensitive to carnosol. Carnosol was found to induce the formation of the TOP1‐DNA cleavage complex (TOP1cc) and TOP2‐DNA cleavage complex (TOP2cc). When comparing the accumulation of γ‐H2AX foci and the number of chromosomal aberrations (CAs) with wild‐type (WT) cells, the susceptivity of the TDP1^?/? and TDP2^?/? cells were associated with an increased DNA damage. Our results provided evidence of carnosol inducing DNA lesions in TK6 cells and demonstrated that the damage induced by carnosol was associated with abnormal topoisomerase activity. We conclude that TDP1 and TDP2 play important roles in the anti‐cancer effect of carnosol.     

Green tea constituent (--)-epigallocatechin-3-gallate inhibits topoisomerase I activity in human colon carcinoma cells

DNA topoisomerases I and II are essential for cell survival and play critical roles in DNA metabolism and structure. Inhibitors of topoisomerase constitute a novel family of antitumor agents with demonstrated clinical activity in human malignancies. The clinical use of these agents is limited due to severe toxic effects on normal cells. Therefore, there is a need to develop novel, nontoxic topoisomerase inhibitors that have the ability to spare normal cells. Recent studies have shown that green tea and its major polyphenolic constituent, epigallocatechin-3-gallate (EGCG), impart growth inhibitory responses to cancer cells but not to normal cells. Based on the knowledge that EGCG induces DNA damage, cell cycle arrest, and apoptosis, we considered the possibility of the involvement of topoisomerase in the antiproliferative response of EGCG. Here, for the first time, we show that EGCG inhibits topoisomerase I, but not topoisomerase II in several human colon carcinoma cell lines. Based on this study it is tempting to suggest that combination of EGCG with other conventional topoisomerase inhibitors could be an improved strategy for treatment of colon cancer. The possible role of EGCG as a chemotherapeutic agent needs to be investigated.     

Identification of the yeast TOP3 gene product as a single strand-specific DNA topoisomerase.

The TOP3 gene of the yeast Saccharomyces cerevisiae was postulated to encode a DNA topoisomerase, based on its sequence homology to Escherichia coli DNA topoisomerase I and the suppression of the poor growth phenotype of top3 mutants by the expression of the E. coli enzyme (Wallis, J.W., Chrebet, G., Brodsky, G., Golfe, M., and Rothstein, R. (1989) Cell 58, 409-419). We have purified the yeast TOP3 gene product to near homogeneity as a 74-kDA protein from yeast cells lacking DNA topoisomerase I and overexpressing a plasmid-borne TOP3 gene linked to a phosphate-regulated yeast PHO5 gene promoter. The purified protein possesses a distinct DNA topoisomerase activity: similar to E. coli DNA topoisomerases I and III, it partially relaxes negatively but not positively supercoiled DNA. Several experiments, including the use of a negatively supercoiled heteroduplex DNA containing a 29-nucleotide single-stranded loop, indicate that the activity has a strong preference for single-stranded DNA. A protein-DNA covalent complex in which the 74-kDa protein is linked to a 5' DNA phosphoryl group has been identified, and the nucleotide sequences of 30 sites of DNA-protein covalent complex formation have been determined. These sequences differ from those recognized by E. coli DNA topoisomerase I but resemble those recognized by E. coli DNA topoisomerase III. Based on these results, the yeast TOP3 gene product can formally be termed S. cerevisiae DNA topoisomerase III. Analysis of supercoiling of intracellular yeast plasmids in various DNA topoisomerase mutants indicates that yeast DNA topoisomerase III has at most a weak activity in relaxing negatively supercoiled double-stranded DNA in vivo, in accordance with the characteristics of the purified enzyme.     

Molecular cloning and characterization of the human topoisomerase IIalpha and IIbeta genes: evidence for isoform evolution through gene duplication

Human DNA topoisomerase II is essential for chromosome segregation and is the target for several clinically important anticancer agents. It is expressed as genetically distinct alpha and beta isoforms encoded by the TOP2alpha and TOP2beta genes that map to chromosomes 17q21-22 and 3p24, respectively. The genes display different patterns of cell cycle- and tissue-specific expression, with the alpha isoform markedly upregulated in proliferating cells. In addition to the fundamental role of TOP2alpha and TOP2beta genes in cell growth and development, altered expression and rearrangement of both genes are implicated in anticancer drug resistance. Here, we report the complete structure of the human topoisomerase IIalpha gene, which consists of 35 exons spanning 27.5 kb. Sequence data for the exon-intron boundaries were determined and examined in the context of topoisomerase IIalpha protein structure comprising three functional domains associated with energy transduction, DNA breakage-reunion activity and nuclear localization. The organization of the 3' half of human TOP2beta, including sequence specifying the C-terminal nuclear localization domain, was also elucidated. Of the 15 introns identified in this 20 kb region of TOP2beta, the first nine and the last intron align in identical positions and display the same phases as introns in TOP2alpha. Though their extreme 3' ends differ, the striking conservation suggests the two genes diverged recently in evolutionary terms consistent with a gene duplication event. Access to TOP2alpha and TOP2beta gene structures should aid studies of mutations and gene rearrangements associated with anticancer drug resistance.     

Two independent amsacrine-resistant human myeloid leukemia cell lines share an identical point mutation in the 170 kDa form of human topoisomerase II.

Cloning and sequencing of cDNA segments of human TOP2 gene encoding the 170 kDa form of human DNA topoisomerase II show that Arg486 of the enzyme has been mutated to a lysine in the enzyme from two human leukemia cell lines HL-60/AMSA and KBM-3/AMSA, which were independently selected for resistance to the antitumor drug amsacrine (4'-[9-acridinylamino]-methanesulfon-m-anisidide, mAMSA). Sequence identity comparisons between eukaryotic DNA topoisomerase II and bacterial gyrase (bacterial DNA topoisomerase II) indicate that the position of the common mutation observed in mAMSA-resistant human TOP2 corresponds to that of the point mutation nal-31 in the Escherichia coli gyrase B gene, which confers resistance to nalidixic acid. Because mAMSA and nalidixic acid are known to act on their respective targets by a common mechanism of trapping the covalent enzyme-DNA intermediates, these results provide strong evidence that the 170 kDa form of human DNA topoisomerase II is a major cellular target of mAMSA, and that Arg486 of this enzyme is involved in mAMSA-mediated trapping of the covalent enzyme-DNA complex.     

Hydrogen peroxide induces topoisomerase I-mediated DNA damage and cell death

Reactive oxygen species modify DNA, generating various DNA lesions including modified bases such as 8-oxoguanine (8-oxoG). These base-modified DNA lesions have been shown to trap DNA topoisomerase I (TOP1) into covalent cleavage complexes. In this study, we have investigated the role of TOP1 in hydrogen peroxide toxicity. We showed that ectopic expression of TOP1 in Saccharomyces cerevisiae conferred sensitivity to hydrogen peroxide, and this sensitivity was dependent on RAD9 checkpoint function. Moreover, in the mammalian cell culture system, hydrogen peroxide-induced growth inhibition and apoptosis were shown to be partly TOP1-dependent as evidenced by a specific increase in resistance to hydrogen peroxide in TOP1-deficient P388/CPT45 murine leukemia cells as compared with their TOP1-proficient parental cell line P388. In addition, hydrogen peroxide was shown to induce TOP1-DNA cross-links. These results support a model in which hydrogen peroxide promotes the trapping of TOP1 on oxidative DNA lesions to form TOP1-DNA cleavage complexes that contribute to hydrogen peroxide toxicity.     

Overexpression of type I topoisomerases sensitizes yeast cells to DNA damage

DNA topoisomerases play essential roles in many DNA metabolic processes. It has been suggested that topoisomerases play an essential role in DNA repair. Topoisomerases can introduce DNA damage upon exposure to drugs that stabilize the covalent protein-DNA intermediate of the topoisomerase reaction. Lesions in DNA are also able to trap topoisomerase-DNA intermediates, suggesting that topoisomerases have the potential to either assist in DNA repair by locating sites of damage or exacerbating DNA damage by generation of additional damage at the site of a lesion. We have shown that overexpression of yeast topoisomerase I (TOP1) conferred hypersensitivity to methyl methanesulfonate and other DNA-damaging agents, whereas expression of a catalytically inactive enzyme did not. Overexpression of topoisomerase II did not change the sensitivity of cells to these DNA-damaging agents. Yeast cells lacking TOP1 were not more resistant to DNA damage than cells expressing wild type levels of the enzyme. Yeast topoisomerase I covalent complexes can be trapped efficiently on UV-damaged DNA. We suggest that TOP1 does not participate in the repair of DNA damage in yeast cells. However, the enzyme has the potential of exacerbating DNA damage by forming covalent DNA-protein complexes at sites of DNA damage.     

Identification of DNA topoisomerase-II activity in terminally differentiated mammalian organs and in non-growing cultured cells

DNA topoisomerase-II activity was measured in a variety of rat organs and in two types of cultured mammalian cells at different stages of growth. The assay for enzyme activity is based on the ability of DNA topoisomerase II to catenate relaxed, circular double-stranded [3H]DNA into huge networks of interlocked circles which can be selectively trapped on a nitrocellulose filter. This catenation requires ATP and provides a sensitive, specific, and quantitative way to measure topoisomerase-II activity in crude extracts of nuclei. The level of type-II topoisomerase activity showed little variation at different stages of growth in either Chinese hamster ovary cells or human skin fibroblasts. In both cell types, growth-arrested cells contain levels of topoisomerase II very similar to those seen in actively growing cells. In addition, substantial levels of type-II topoisomerase are found not only in those rat organs expected to contain large populations of growing cells (testis, spleen), but also in organs composed primarily of cells in G0 (brain, liver, lung). These data indicate that total nuclear type-II topoisomerase activity does not vary dramatically with the state of cell growth or degree of cell differentiation.     

NPRL-Z-1, as a New Topoisomerase II Poison,Induces Cell Apoptosis and ROS Generation in Human Renal Carcinoma Cells

NPRL-Z-1 is a 4β-[(4″-benzamido)-amino]-4′-O-demethyl-epipodophyllotoxin derivative. Previous reports have shown that NPRL-Z-1 possesses anticancer activity. Here NPRL-Z-1 displayed cytotoxic effects against four human cancer cell lines (HCT 116, A549, ACHN, and A498) and exhibited potent activity in A498 human renal carcinoma cells, with an IC₅₀ value of 2.38 µM via the MTT assay. We also found that NPRL-Z-1 induced cell cycle arrest in G1-phase and detected DNA double-strand breaks in A498 cells. NPRL-Z-1 induced ataxia telangiectasia-mutated (ATM) protein kinase phosphorylation at serine 1981, leading to the activation of DNA damage signaling pathways, including Chk2, histone H2AX, and p53/p21. By ICE assay, the data suggested that NPRL-Z-1 acted on and stabilized the topoisomerase II (TOP2)–DNA complex, leading to TOP2cc formation. NPRL-Z-1-induced DNA damage signaling and apoptotic death was also reversed by TOP2α or TOP2β knockdown. In addition, NPRL-Z-1 inhibited the Akt signaling pathway and induced reactive oxygen species (ROS) generation. These results demonstrated that NPRL-Z-1 appeared to be a novel TOP2 poison and ROS generator. Thus, NPRL-Z-1 may present a significant potential anticancer candidate against renal carcinoma.     

A novel DNA topoisomerase I inhibitor with different mechanism from camptothecin induces G2/M phase cell cycle arrest to K562 cells

DNA topoisomerase I (Top1) is an essential nuclear enzyme and a validated target for anticancer agent screening. In a previous study, we found that indolizinoquinoline-5,12-dione derivatives show significant biological activity against several human cancer cell lines. To understand their mechanism of inhibition of cancer cell growth, one indolizinoquinoline-5,12-dione derivative, CY13II, was further studied as lead. Our present results indicate that CY13II shows more potent antiproliferative activity against K562 cells than camptothecin. Additionally, K562 cells were arrested in G2/M, and their growth rate decreased after treatment with CY13II at micromolar concentration. Biochemical Top1 assays indicate that CY13II exhibits a different inhibitory mechanism from camptothecin. Unlike camptothecin, CY13II specifically inhibits the catalytic cleavage activity of Top1 instead of forming the drug-enzyme-DNA covalent ternary complex.     

DNA topoisomerase II as the target for the anticancer drug TOP-53: mechanistic basis for drug action

TOP-53 is a promising anticancer agent that displays high activity against non-small cell lung cancer in animal tumor models [Utsugi, T., et al. (1996) Cancer Res. 56, 2809-2814]. Compared to its parent compound, etoposide, TOP-53 is considerably more toxic to non-small cell lung cancer cells, is more active at generating chromosomal breaks, and displays improved cellular uptake and pharmacokinetics in animal lung tissues. Despite the preclinical success of TOP-53, several questions remain regarding its cytotoxic mechanism. Therefore, this study characterized the basis for drug action. Results indicate that topoisomerase II is the primary cytotoxic target for TOP-53. Furthermore, the drug kills cells by acting as a topoisomerase II poison. TOP-53 exhibits a DNA cleavage site specificity that is identical to that of etoposide. Like its parent compound, the drug increases the number of enzyme-mediated DNA breaks by interfering with the DNA religation activity of the enzyme. TOP-53 is considerably more efficient than etoposide at enhancing topoisomerase II-mediated DNA cleavage and exhibits high activity against human topoisomerase IIalpha and IIbeta in vitro and in cultured cells. Therefore, at least in part, the enhanced cytotoxic activity of TOP-53 can be attributed to an enhanced activity against topoisomerase II. Finally, TOP-53 displays nearly wild-type activity against a mutant yeast type II enzyme that is highly resistant to etoposide. This finding suggests that TOP-53 can retain activity against systems that have developed resistance to etoposide, and indicates that substituents on the etoposide C-ring are important for topoisomerase II-drug interactions.     

DNA damage response during chromatin remodeling in elongating spermatids of mice

A precise packaging of the paternal genome during spermiogenesis is essential for fertilization and embryogenesis. Most of the nucleosomal DNA supercoiling must be eliminated in elongating spermatids (ES), and transient DNA strand breaks are observed that facilitate the process. Topoisomerases have been considered as ideal candidates for the removal of DNA supercoiling, but their catalytic activity, in the context of such a major chromatin remodeling, entails genetic risks. Using immunofluorescence, we confirmed that topoisomerase II beta (TOP2B) is the type II topoisomerase present in ES between steps 9 and 13. Interestingly, the detection of TOP2B was found coincident with detection of tyrosyl-DNA phosphodiesterase 1 (TDP1), an enzyme known to resolve topoisomerase-mediated DNA damage. The presence of gamma-H2AX (also known as H2AFX) coincident with DNA strand breakage was also confirmed at these steps and indicates that a DNA damage response is triggered. Active DNA repair in ES was demonstrated using a fluorescent in situ DNA polymerase activity assay on squash preparations of staged tubules. In the context of haploid spermatids, any unresolved double-strand breaks, resulting from a failure in the rejoining process of TOP2B, must likely rely on the error-prone nonhomologous end joining, because homologous recombination cannot proceed in the absence of a sister chromatid. Because this process is part of the normal developmental program of the spermatids, dramatic consequences for the genomic integrity of the developing male gamete may arise should any alteration in the process occur.     

Molecular docking studies of the interaction between propargylic enol ethers and human DNA topoisomerase IIα

Having identified a novel human DNA topoisomerase IIα (TOP2) catalytic inhibitor from a small and structure-focused library of propargylic enol ethers, we decided to analyze if the chirality of these compounds plays a determinant role in their antiproliferative activity. In this study, we describe for the first time the synthesis of the corresponding enantiomers and the biological evaluation against a panel of representative human solid tumor cell lines. Experimental results show that chirality does not influence the reported antiproliferative activity of these compounds. Docking studies of corresponding enantiomers against TOP2 reinforce the finding that the biological effect is not chiral-dependent and that these family of compounds seem to act as TOP2 catalytic inhibitors.