A three-dimensional quantitative structure-activity analysis of a new class of bisphenol topoisomerase IIalpha inhibitors.

After the identification of a new lead bisphenol compound that had good topoisomerase IIalpha (EC 5.99.1.3) inhibitory activity, a series of bisphenol analogs were synthesized and tested to identify the structural features that were responsible for their activity. The bisphenols represent a new structural class of topoisomerase II inhibitor that potently inhibited the growth of Chinese hamster ovary and K562 leukemia cells in the low micromolar range. The fact that cell growth inhibition was significantly correlated with topoisomerase IIalpha inhibition suggests that the catalytic inhibition of topoisomerase IIalpha probably contributed to their growth inhibitory activity. Only one of the bisphenols (O3OH) tested significantly induced topoisomerase IIalpha-mediated cleavage of DNA. Most of the bisphenols displayed only low-fold cross-resistance to a K562 subline containing reduced levels of topoisomerase IIalpha Thus, it is likely that most of the bisphenols inhibited cell growth, not by acting as topoisomerase II poisons, but rather by acting as catalytic inhibitors of topoisomerase IIalpha. Three-dimensional quantitative structure-activity analysis (3D-QSAR) was carried out on the bisphenols using comparative molecular field analysis (CoMFA) and comparative molecular similarity index analysis (CoMSIA) to determine the structural features responsible for their activity. The CoMSIA analysis of the topoisomerase IIalpha inhibitory activity yielded a statistically significant model upon partial least-squares analyses. The 3D-QSAR CoMSIA analysis showed that polar meta hydrogen bond acceptor substituents on the phenyl rings favored inhibition of topoisomerase IIalpha. For the hydrogen bond donor field, para- and meta-substituted hydroxyl groups favored inhibition. Hydrophobic substituents on the bridge atoms disfavored inhibition.

Origin and evolution of DNA topoisomerases.

The DNA topoisomerases are essential for DNA replication, transcription, recombination, as well as for chromosome compaction and segregation. They may have appeared early during the formation of the modern DNA world. Several families and subfamilies of the two types of DNA topoisomerases (I and II) have been described in the three cellular domains of life (Archaea, Bacteria and Eukarya), as well as in viruses infecting eukaryotes or bacteria. The main families of DNA topoisomerases, Topo IA, Topo IB, Topo IC (Topo V), Topo IIA and Topo IIB (Topo VI) are not homologous, indicating that they originated independently. However, some of them share homologous modules or subunits that were probably recruited independently to produce different topoisomerase activities. The puzzling phylogenetic distribution of the various DNA topoisomerase families and subfamilies cannot be easily reconciled with the classical models of early evolution describing the relationships between the three cellular domains. A possible scenario is based on a Last Universal Common Ancestor (LUCA) with a RNA genome (i.e. without the need for DNA topoisomerases). Different families of DNA topoisomerases (some of them possibly of viral origin) would then have been independently introduced in the different cellular domains. We review here the main characteristics of the different families and subfamilies of DNA topoisomerases in a historical and evolutionary perspective, with the hope to stimulate further works and discussions on the origin and evolution of these fascinating enzymes.

Ability of viral topoisomerase II to discern the handedness of supercoiled DNA: bimodal recognition of DNA geometry by type II enzymes.

Previous studies with human and bacterial topoisomerases suggest that the type II enzyme utilizes two distinct mechanisms to recognize the handedness of DNA supercoils. It has been proposed that the ability of some type II enzymes, such as human topoisomerase IIalpha and Escherichia coli topoisomerase IV, to distinguish supercoil geometry during DNA relaxation is mediated by elements in the variable C-terminal domain of the protein. In contrast, the ability of human topoisomerase IIalpha and topoisomerase IIbeta to discern the handedness of supercoils during DNA cleavage suggests that residues in the conserved N-terminal or central domain of the protein are involved in this process. To test this hypothesis, the ability of Paramecium bursaria chlorella virus-1 (PBCV-1) and chlorella virus Marburg-1 (CVM-1) topoisomerase II to relax and cleave negatively and positively supercoiled plasmids was assessed. These enzymes display a high degree of sequence identity with the N-terminal and central domains of eukaryotic topoisomerase II but naturally lack the C-terminal domain. While PBCV-1 and CVM-1 topoisomerase II relaxed under- and overwound substrates at similar rates, they were able to discern the handedness of supercoils during the cleavage reaction and preferentially cut negatively supercoiled DNA. Preferential cleavage was not due to a change in site specificity, DNA binding, or religation. These findings are consistent with a bimodal recognition of DNA geometry in which topoisomerase II uses elements in the C-terminal domain to sense the handedness of supercoils during DNA relaxation and elements in the conserved N-terminal or central domain during DNA cleavage.

Identification, characteristic and phylogenetic analysis of type II DNA topoisomerase gene in Giardia lamblia.

The genes encoding type II DNA topoisomerases were investigated in Giardia lamblia genome, and a type IIA gene, GlTop 2 was identified. It is a single copy gene with a 4476 bp long ORF without intron. The deduced amino acid sequence shows strong homology to eukaryotic DNA Top 2. However, some distortions were found, such as six insertions in the ATPase domain and the central domain, a approximately 100 aa longer central domain; a approximately 200 aa shorter C-terminal domain containing rich charged residues. These features revealed by comparing with Top 2 of the host, human, might be helpful in exploiting drug selectivity for antigiardial therapy. Phylogenetic analysis of eukaryotic enzymes showed that kinetoplastids, plants, fungi, and animals were monophyletic groups, and the animal and fungi lineages shared a more recent common ancestor than either did with the plant lineage; microsporidia grouped with fungi. However, unlike many previous phylogenetic analyses, the "amitochondriate"G. lamblia was not the earliest branch but diverged after mitochondriate kinetoplastids in our trees. Both the finding of typical eukaryotic type IIA topoisomerase and the phylogenetic analysis suggest G. lamblia is not possibly as primitive as was regarded before and might diverge after the acquisition of mitochondria. This is consistent with the recent discovery of mitochondrial remnant organelles in G. lamblia.

Improvements of PCR-based identification targeting the DNA topoisomerase II gene to determine major species of the opportunistic fungi Candida and Aspergillus fumigatus.

For the simple and rapid detection/identification of major pathogenic fungal species such as Candida albicans, C. tropicalis, C. parapsilosis, C. glabrata and Aspergillus fumigatus, common primers for these species and specific primers for each species, designed on the basis on the genomic nucleotide sequences of the DNA topoisomerase II genes, were prepared and tested for their specificities in PCR amplifications. Twelve specific primers were pooled and designated PsVI. Genomic DNAs were amplified by the common primer pair, and followed by PCR amplification using PsVI. Using PsVI, six unique DNA fragments, all of which corresponded to a Candida or A. fumigatus species, were specifically and acceptably amplified from each template DNA even in the presence of other DNAs. Similarly, the results of identification of clinical samples based on the PCR amplification coincided with those of conventional identification techniques. The sensitivities of the direct PCR and the nested PCR using PsVI were found to be 1,000 and 50 yeast cells, respectively.

Structure and mechanism of DNA topoisomerases.

DNA topoisomerases are ubiquitous enzymes that control the level of supercoiling of DNA in cells. There are several classes, each with distinct properties, which are briefly discussed in this review. High-resolution X-ray crystallographic structures have been obtained for fragments of two classes of these enzymes, which when combined with biochemical data, reveal a great deal about the gymnastics that the enzymes undergo during catalysis and provide fascinating snapshots of their mechanisms. These mechanisms are discussed in detail. Finally, the first structure of a topoisomerase in a complex with an antibiotic was recently solved. This structure is briefly discussed with regard to the biochemical activity of the compound.

The localization of topoisomerase II cleavage sites on DNA in the presence of antitumor drugs.

Type II topoisomerase are enzymes that break and religate DNA phosphodiester bonds while crossing over DNA strands and altering DNA topology. They also are structural proteins that play a role in the spatial organization of chromatin and are involved in several crucial biological functions, such as DNA replication and transcription, chromosome segregation and recombination. Many drugs interfere with type II topoisomerases and can be assigned to two groups. Coumarin derivatives and synthetic quinolones act at the level of ATP binding or hydrolysis and are used for controlling bacterial infections. Drugs belonging to the second group produce DNA lesions by trapping a "cleavable complex" consisting of the normal transient topoisomerase II-DNA reaction intermediate in which the enzyme and the DNA are joined by two covalent bonds. There are four main categories of antitumour drugs that form cleavable complexes in eukaryotes: acridines, anthracyclines, ellipticines and epipodophyllotoxins. These drugs are cytotoxic and many--but not all--are endowed with antitumoral properties. The mechanisms of this pharmacological activity are not understood. Topoisomerase II-induced DNA breaks generated from cleavable complexes display different levels of cytotoxicity depending on their localization on DNA. The primary structure of DNA is not the only parameter that determines this localization. The spatial organization of the enzyme-DNA complex and both the topology and the structure of the underlying chromatin fiber constitute additional critical factors. It, therefore, may be unrealistic to expect that the actual pharmacological potency of antitumor drugs that act on type II topoisomerases can be accurately predicted solely on the basis of simple in vitro test tube experiments carried out using pure enzymes and naked DNA.

Isolation and characterization of a human cDNA clone encoding a novel DNA topoisomerase II homologue from HeLa cells.

We have isolated and sequenced 3 human DNA topoisomerase II (topo II) partial cDNA clones from a HeLa carcinoma cell cDNA library. Two clones were identical to an internal fragment of HeLa topo II cDNA. The third clone, CAA5, had a different and novel sequence which shared significant nucleotide (62%) and predicted peptide (70%) homologies with a region of the HeLa topo II cDNA. Our results suggest that HeLa cells express at least two homologous forms of DNA topoisomerase II. The new HeLa topo II homologue is discussed in relation to topo II isoenzymes recently described in a Burkitt lymphoma and other cell lines.

Differences between normal and ras-transformed NIH-3T3 cells in expression of the 170kD and 180kD forms of topoisomerase II.

The activity of topoisomerase II and the cellular content of the 170kD and 180kD forms of the enzyme were studied as functions of transformation and growth state by using normal and ras-transformed NIH-3T3 cells. Total topoisomerase II activity, as measured by the unknotting of P4 DNA, was higher in ras-transformed than in normal cells in similar growth states, and was higher in exponentially growing than in plateau cells for both cell lines. Total topoisomerase II levels, as measured by immunoblotting, showed a similar dependence on transformation and growth state. The relative amounts of the 170kD and 180kD forms of the enzyme varied as a function of transformation and growth state. The proportion of 170kD topoisomerase II was higher in ras-transformed than in untransformed cells and depended much less on growth state in the ras-transformed cells. The topoisomerase II activity in extracts of ras-transformed cells was more sensitive to inhibition by teniposide and merbarone, drugs which selectively inhibit the 170kD form of topoisomerase II. The ras-transformed cells were also more sensitive to the cytotoxic effects of these drugs. An increase in the relative cellular content of 170kD topoisomerase II is characteristic of ras-transformed 3T3 cells, and the levels of this form of the enzyme appear to be less dependent on proliferation state than in untransformed cells. The susceptibility of certain tumors to killing by topoisomerase II-directed drugs may be due to a higher proportion of 170kD enzyme as well as a higher level of total topoisomerase II activity.