In vitro evolution of preferred topoisomerase II DNA cleavage sites

Phytochemical Profiling, In Vitro and In Silico Anti-Microbial and Anti-Cancer Activity Evaluations and Staph GyraseB and h-TOP-IIβ Receptor-Docking Studies of Major Constituents of Zygophyllum coccineum L. Aqueous-Ethanolic Extract and Its Subsequent Fractions: An Approach to Validate Traditional Phytomedicinal Knowledge

Zygophyllum coccineum, an edible halophytic plant, is part of the traditional medicine chest in the Mediterranean region for symptomatic relief of diabetes, hypertension, wound healing, burns, infections, and rheumatoid arthritis pain. The current study aimed to characterize Z. coccineum phytoconstituents, and the evaluations of the anti-microbial-biofilm, and anti-cancers bioactivities of the plant’s mother liquor, i.e., aqueous-ethanolic extract, and its subsequent fractions. The in silico receptors interaction feasibility of Z. coccineum major constituents with Staph GyraseB, and human topoisomerase-IIβ (h-TOP-IIβ) were conducted to confirm the plant’s anti-microbial and anti-cancer biological activities. Thirty-eight secondary metabolites of flavonoids, stilbene, phenolic acids, alkaloids, and coumarin classes identified by LC-ESI-TOF-MS spectrometric analysis, and tiliroside (kaempferol-3-O-(6′′′′-p-coumaroyl)-glucoside, 19.8%), zygophyloside-F (12.78%), zygophyloside-G (9.67%), and isorhamnetin-3-O-glucoside (4.75%) were identified as the major constituents. A superior biofilm obliteration activity established the minimum biofilm eradication concentration (MBEC) for the chloroform fraction at 3.9–15.63 µg/mL, as compared to the positive controls (15.63–31.25 µg/mL) against all the microbial strains that produced the biofilm under study, except the Aspergillus fumigatus. The aqueous-ethanolic extract showed cytotoxic effects with IC₅₀ values at 3.47, 3.19, and 2.27 µg/mL against MCF-7, HCT-116, and HepG2 cell-lines, respectively, together with the inhibition of h-TOP-IIβ with IC₅₀ value at 45.05 ng/mL in comparison to its standard referral inhibitor (staurosporine, IC₅₀, 135.33 ng/mL). This conclusively established the anti-cancer activity of the aqueous-ethanolic extract that also validated by in silico receptor-binding predicted energy levels and receptor-site docking feasibility of the major constituents of the plant’s extract. The study helped to authenticate some of the traditional phytomedicinal properties of the anti-infectious nature of the plant.

Selection of DNA Cleavage Sites by Topoisomerase II Results from Enzyme-Induced Flexibility of DNA

Topoisomerase II cleaves DNA at preferred sequences with different efficiencies; however, the mechanism of cleavage site selection is not known. Here we used single-molecule fluorescence assays that monitor several critical steps of DNA-topoisomerase II interactions, including binding/dissociation, bending/straightening, and cleavage/religation, and reveal that the cleavage site is selected mainly during the bending step. Furthermore, despite the sensitivity of the bending rate to the DNA sequence, it is not an intrinsic property of the DNA itself. Rather, it is determined by protein-DNA interactions.

The regulatory role of DNA supercoiling in nucleoprotein complex assembly and genetic activity

We argue that dynamic changes in DNA supercoiling in vivo determine both how DNA is packaged and how it is accessed for transcription and for other manipulations such as recombination. In both bacteria and eukaryotes, the principal generators of DNA superhelicity are DNA translocases, supplemented in bacteria by DNA gyrase. By generating gradients of superhelicity upstream and downstream of their site of activity, translocases enable the differential binding of proteins which preferentially interact with respectively more untwisted or more writhed DNA. Such preferences enable, in principle, the sequential binding of different classes of protein and so constitute an essential driver of chromatin organization.

E. coli Gyrase Fails to Negatively Supercoil Diaminopurine-Substituted DNA

Type II topoisomerases modify DNA supercoiling, and crystal structures suggest that they sharply bend DNA in the process. Bacterial gyrases are a class of type II topoisomerases that can introduce negative supercoiling by creating a wrap of DNA before strand passage. Isoforms of these essential enzymes were compared to reveal whether they can bend or wrap artificially stiffened DNA. Escherichia coli gyrase and human topoisomerase IIα were challenged with normal DNA or stiffer DNA produced by polymerase chain reaction reactions in which diaminopurine (DAP) replaced adenine deoxyribonucleotide triphosphates. On single DNA molecules twisted with magnetic tweezers to create plectonemes, the rates or pauses during relaxation of positive supercoils in DAP-substituted versus normal DNA were distinct for both enzymes. Gyrase struggled to bend or perhaps open a gap in DAP-substituted DNA, and segments of wider DAP DNA may have fit poorly into the N-gate of the human topoisomerase IIα. Pauses during processive activity on both types of DNA exhibited ATP dependence consistent with two pathways leading to the strand-passage-competent state with a bent gate segment and a transfer segment trapped by an ATP-loaded and latched N-gate. However, E. coli DNA gyrase essentially failed to negatively supercoil 35% stiffer DAP DNA.

DNA thermodynamics shape chromosome organization and topology

How much information is encoded in the DNA sequence of an organism? We argue that the informational, mechanical and topological properties of DNA are interdependent and act together to specify the primary characteristics of genetic organization and chromatin structures. Superhelicity generated in vivo, in part by the action of DNA translocases, can be transmitted to topologically sensitive regions encoded by less stable DNA sequences.

Effect of Bending Rigidity on the Knotting of a Polymer under Tension

A coarse-grained computational model is used to investigate how the bending rigidity of a polymer under tension affects the formation of a trefoil knot. Thermodynamic integration techniques are applied to demonstrate that the free-energy cost of forming a knot has a minimum at nonzero bending rigidity. The position of the minimum exhibits a power-law dependence on the applied tension. For knotted polymers with nonuniform bending rigidity, the knots preferentially localize in the region with a bending rigidity that minimizes the free energy.

Topoisomerase assays

Topoisomerases are nuclear enzymes that play essential roles in DNA replication, transcription, chromosome segregation, and recombination. All cells have two major forms of topoisomerases: type I enzymes, which make single-stranded cuts in DNA, and type II enzymes, which cut and pass double-stranded DNA. DNA topoisomerases are important targets of approved and experimental anti-cancer agents. The protocols described in this unit are for assays used to assess new chemical entities for their ability to inhibit both forms of DNA topoisomerase. Included are an in vitro assay for topoisomerase I activity based on relaxation of supercoiled DNA, and an assay for topoisomerase II based on the decatenation of double-stranded DNA. The preparation of mammalian cell extracts for assaying topoisomerase activity is described, along with a protocol for an ICE assay to examine topoisomerase covalent complexes in vivo, and an assay for measuring DNA cleavage in vitro.

Topoisomerase IIbeta activates a subset of neuronal genes that are repressed in AT-rich genomic environment

DNA topoisomerase II (topo II) catalyzes a strand passage reaction in that one duplex is passed through a transient brake or gate in another. Completion of late stages of neuronal development depends on the presence of active β isoform (topo IIβ). The enzyme appears to aid the transcriptional induction of a limited number of genes essential for neuronal maturation. However, this selectivity and underlying molecular mechanism remains unknown. Here we show a strong correlation between the genomic location of topo IIβ action sites and the genes it regulates. These genes, termed group A1, are functionally biased towards membrane proteins with ion channel, transporter, or receptor activities. Significant proportions of them encode long transcripts and are juxtaposed to a long AT-rich intergenic region (termed LAIR). We mapped genomic sites directly targeted by topo IIβ using a functional immunoprecipitation strategy. These sites can be classified into two distinct classes with discrete local GC contents. One of the classes, termed c2, appears to involve a strand passage event between distant segments of genomic DNA. The c2 sites are concentrated both in A1 gene boundaries and the adjacent LAIR, suggesting a direct link between the action sites and the transcriptional activation. A higher-order chromatin structure associated with AT richness and gene poorness is likely to serve as a silencer of gene expression, which is abrogated by topo IIβ releasing nearby genes from repression. Positioning of these genes and their control machinery may have developed recently in vertebrate evolution to support higher functions of central nervous system.

Identification of intrinsic dynamics in a DNA sequence preferentially cleaved by topoisomerase II enzyme

Topoisomerase II enzymes are essential enzymes that modulate DNA topology and play a role in chromatin compaction. While these enzymes appear to recognize and cleave the DNA in a nonrandom fashion, factors that underlie enzyme specificity remain an enigma. To gain new insights on these topics, we undertake, using NMR and molecular dynamics methods, studies of the structural and dynamic features of a 21 bp DNA segment preferentially cleaved by topoisomerases II. The large size of the oligonucleotide did not hamper the determination of structures of sufficient quality, and numerous interesting correlations between helicoidal parameters already depicted in crystals and molecular dynamics simulations are recovered here. The main feature of the sequence is the occurrence of a large opening of the base pairs in a four-residue AT-rich region located immediately at the 5' end of one of the cleaved sites. This opening seems to be largely dependent on sequence context, since a similar opening is not found in the other AT base pairs of the sequence. Furthermore, two adenine nucleotides of the same portion of the oligonucleotide present slow internal motions at the NMR timescale, revealing particular base dynamics. In conclusion, this AT-rich region presents the most salient character in the sequence and could be involved in the preferential cleavage by topoisomerase II. The examination of preferred sites in the literature pointed out the frequent occurrence of AT-rich sequences, namely matrix attachment region and scaffold attachment region sequences, at the sites cleaved by topoisomerase II. We could infer that the particular flexibility of these sequences plays an important role in enabling the formation of a competent cleavage complex. The sequences could then be selected based on their facility to undertake conformational change during the complex formation, rather than purely based on binding affinity.

DNA topoisomerase II selects DNA cleavage sites based on reactivity rather than binding affinity

DNA topoisomerase II modulates DNA topology by relieving supercoil stress and by unknotting or decatenating entangled DNA. During its reaction cycle, the enzyme creates a transient double-strand break in one DNA segment, the G-DNA. This break serves as a gate through which another DNA segment is transported. Defined topoisomerase II cleavage sites in genomic and plasmid DNA have been previously mapped. To dissect the G-DNA recognition mechanism, we studied the affinity and reactivity of a series of DNA duplexes of varied sequence under conditions that only allow G-DNA to bind. These DNA duplexes could be cleaved to varying extents ranging from undetectable (<0.5%) to 80%. The sequence that defines a cleavage site resides within the central 20 bp of the duplex. The DNA affinity does not correlate with the ability of the enzyme to cleave DNA, suggesting that the binding step does not contribute significantly to the selection mechanism. Kinetic experiments show that the selectivity interactions are formed before rather than subsequent to cleavage. Presumably the binding energy of the cognate interactions is used to promote a conformational change that brings the enzyme into a cleavage competent state. The ability to modulate the extent of DNA cleavage by varying the DNA sequence may be valuable for future structural and mechanistic studies that aim to determine topoisomerase structures with DNA bound in pre- and post-cleavage states and to understand the conformational changes associated with DNA binding and cleavage.

Does topoisomerase II specifically recognize and cleave hairpins, cruciforms and crossovers of DNA?

DNA topoisomerase II is an enzyme that specializes in DNA disentanglement. It catalyzes the interconversion of DNA between different topological states. This event requires the passage of one duplex through another one via a transient double-strand break. Topoisomerase II is able to process any type of DNA, including structures such as DNA juxtapositions (crossovers), DNA hairpins or cruciforms, which are recognized with high specificity. In this review, we focused our attention on topoisomerase II recognizing DNA substrates that possess particular geometries. A strong cleavage site, as we identified in pBR322 DNA in the presence of ellipticine (site 22), appears to be characterized by a cruciform structure formed from two stable hairpins. The same sequence could also constitute a four-way junction structure stabilized by interactions involving ATC sequences. The latter have been shown to be able to promote Holliday junctions. We reviewed the recent literature that deals with the preferential recognition of crossovers by various topoisomerases. The single molecule relaxation experiments have demonstrated the differential abilities of the topoisomerases to recognize crossovers. It appears that enzymes, which distinguish the chirality of the crossovers, possess specialized domains dedicated to this function. We also stress that the formation of crossovers is dependent on the presence of adequate stabilizing sequences. Investigation of the impact of such structures on enzyme activity is important in order to both improve our knowledge of the mechanism of action of the topoisomerase II and to develop new inhibitors of this enzyme.

Association of Arabidopsis topoisomerase IIA cleavage sites with functional genomic elements and T-DNA loci

Topoisomerase IIA (Topo IIA) is an essential ubiquitous enzyme involved in controlling DNA topology during multiple processes of genome function, and has been implicated in the generation of double-stranded breaks (DSB) in genomic DNA prior to DNA integration in plant genomes. Despite extensive characterization of type II topoisomerases from bacteria, viruses and animals, no studies on the specificity of plant Topo IIA-mediated DNA cleavage have been reported. We mapped and characterized Arabidopsis thaliana Topo IIA (AtTopoIIA) cleavage sites and demonstrated that they were cleaved in vivo. The consensus for the AtTopoIIA cleavage sites (ANNNRN downward arrowGTACNTNNNY) was significantly different from recognition sequences reported for Topo IIA from other organisms. The mapped cleavage sites were abundant in the Arabidopsis genome, exhibited a weak consensus, and were cleaved with relatively low efficiency. Use of the systematic evolution of ligands by exponential enrichment (SELEX) protocol identified a single, efficiently cleaved sequence TATATATATGTATATATATA that was over-represented in the genome. The mapped AtTopoIIA cleavage sites and the SELEX sites differed in their genomic distribution and associations with gene regulatory elements, matrix attachment regions, stress-induced DNA duplex destabilization sequences and T-DNA loci, suggesting different genome functions. Mapped AtTopoIIA sites but not SELEX sites were strongly associated with T-DNA integration sites, providing evidence for the involvement of AtTopoIIA-mediated DSB formation in T-DNA integration.

Fusion oncogenes in tumor development

Currently, all identified fusion oncogenes are found in rare tumor forms, and most of them only in specific tumor types. Some fusion oncogenes are frequent in healthy individuals suggesting that they rarely induce tumor growth. Multiple double-strand breaks that cluster in time and space increases the risk for formation of fusion oncogenes genes. The normal cell type specific spatial distribution of chromatin and genes in interphase nuclei may affect the risk for fusion of specific genes. Transcriptional orientation, splicing of reading frames, size and sequences of breakpoint introns are other risk factors. The biological activity of fusion oncoproteins is the most important factor for penetrance. The effects in specific target cells may explain the tumor type specificity of most fusion oncogenes.

Transcriptional Repressor CopR: use of SELEX to study the copR operator indicates that evolution was directed at maximal binding affinity

CopR is one of the two copy number control elements of the streptococcal plasmid pIP501. It represses transcription of the repR mRNA encoding the essential replication initiator protein about 10- to 20-fold by binding to its operator region upstream of the repR promoter pII. CopR binds at two consecutive sites in the major groove of the DNA that share the consensus motif 5'-CGTG. Previously, the minimal operator was narrowed down to 17 bp, and equilibrium dissociation constants for DNA binding and dimerization were determined to be 0.4 nM and 1.4 microM, respectively. In this work, we used a SELEX procedure to study copR operator sequences of different lengths in combination with electrophoretic mobility shift assays of mutated copR operators as well as copy number determinations to assess the sequence requirements for CopR binding. The results suggest that in vivo evolution was directed at maximal binding affinity. Three simultaneous nucleotide exchanges outside the bases directly contacted by CopR only slightly affected CopR binding in vitro or copy numbers in vivo. Furthermore, the optimal spacer sequence was found to comprise 7 bp, to be AT rich, and to need an A/T and a T at the 3' positions, whereas broad variations in the sequences flanking the minimal 17-bp operator were well tolerated.

The RING finger protein SNURF is a bifunctional protein possessing DNA binding activity

The small nuclear C(3)HC(4) finger protein (SNURF), RNF4, acts as transcriptional coactivator for both steroid-dependent and -independent promoters such as those driven by androgen response elements and GC boxes, respectively. However, SNURF does not possess intrinsic transcription activation function, and the precise molecular mechanism of its action is unknown. We have studied herein the interaction of SNURF with DNA in vitro. SNURF binds to linear double-stranded DNA with no apparent sequence specificity in a cooperative fashion that is highly dependent on the length of the DNA fragment used. SNURF interacts efficiently with both supercoiled circular and four-way junction DNA, and importantly, it also recognizes nucleosomes. An intact RING structure of SNURF is not mandatory for DNA binding, whereas mutations of specific positively charged residues in the N terminus (amino acids 8-11) abolish DNA binding. Interestingly, the ability of SNURF to interact with DNA is associated with its capability to enhance transcription from promoters containing GC box elements. Because SNURF can interact with both DNA and protein (transcription) factors, it may promote assembly of nucleoprotein structures.

Genotoxicity of several clinically used topoisomerase II inhibitors

DNA topoisomerase II is an essential nuclear enzyme that modulates DNA topology during multiple cellular processes such as DNA replication and chromosome segregation. Several important clinical antitumor drugs and antibiotics act through inhibition of topoisomerase II. There are a number of different steps in the action of topoisomerase II, all of which are potential targets for inhibition through drugs and also for cellular and genetic toxicity as well as for mutagenesis. We have investigated and compared the genotoxicity and mutagenicity of the mechanistically different topoisomerase II inhibitors m-amsacrine, mitoxantrone, etoposide, genistein, ICRF 193, and berenil using the in vitro micronucleus test, single cell gelelectrophoresis (comet assay) and the mutation assay (tk-locus) in L5178Y mouse lymphoma cells. All six compounds induced micronuclei and all except berenil were mutagenic. M-amsacrine, mitoxantrone, etopside and genistein induced DNA migration in the comet assay, whereas ICRF 193 was only weakly positive and berenil was negative in this test. Our results are in good agreement with the compounds' proposed mechanisms of interaction with topoisomerase II.

Topoisomerase II as a target for anticancer drugs: when enzymes stop being nice

Topoisomerase II is an essential enzyme that plays a role in virtually every cellular DNA process. This enzyme interconverts different topological forms of DNA by passing one nucleic acid segment through a transient double-stranded break generated in a second segment. By virtue of its double-stranded DNA passage reaction, topoisomerase II is able to regulate DNA over- and underwinding, and can resolve knots and tangles in the genetic material. Beyond the critical physiological functions of the eukaryotic enzyme, topoisomerase II is the target for some of the most successful anticancer drugs used to treat human malignancies. These agents are referred to as topoisomerase II poisons, because they transform the enzyme into a potent cellular toxin. Topoisomerase II poisons act by increasing the concentration of covalent enzyme-cleaved DNA complexes that normally are fleeting intermediates in the catalytic cycle of topoisomerase II. As a result of their action, these drugs generate high levels of enzyme-mediated breaks in the genetic material of treated cells and ultimately trigger cell death pathways. Topoisomerase II is also the target for a second category of drugs referred to as catalytic inhibitors. Compounds in this category prevent topoisomerase II from carrying out its required physiological functions. Drugs from both categories vary widely in their mechanisms of actions. This review focuses on topoisomerase II function and how drugs alter the catalytic cycle of this important enzyme.

Mechanism of fluoroquinolone action

When fluoroquinolones bind to gyrase or topoisomerase IV in the presence of DNA, they alter protein conformation. DNA cleavage results with diminished religation, so the enzymes are trapped in ternary complexes with drug and cleaved DNA. Preferential localization of gyrase ahead of replication forks and topoisomerase IV behind them causes fluoroquinolone-mediated complexes with the two enzymes to have different physiological consequences.