DNA breakage detection-FISH (DBD-FISH) in human spermatozoa: technical variants evidence different structural features

Non-irradiated and X-irradiated (80 Gy) human spermatozoa were processed for in situ DNA breakage detection-FISH (DBD-FISH) of the whole genome, following two alternative variations of the basic technique. In the first, cells were initially incubated in the alkaline unwinding solution for transformation of DNA breaks into single-stranded DNA (ssDNA) to be hybridized, followed by the lysing solutions for protein removal. In the second, incubation in the lysing solutions was carried out before the denaturation step. The first approach yielded two subpopulations. While most sperm nuclei were faintly labeled and had chromocenters, a small subpopulation was strongly and homogeneously labeled, due to extensive DNA breakage. X-ray exposure increased the surface and mean fluorescence intensity. Otherwise, when the denaturation step was performed after protein extraction, all sperm nuclei yielded strong and dispersed FISH signals. Protein removal allows access of the unwinding solution to the DNA, which has abundant alkali-labile sites, and thus gives rise to large areas of ssDNA that are labeled by FISH. X-ray exposure increased the dispersion of FISH signals but decreased their mean fluorescence intensity. A linear dose-response was generated using the second experimental variant, being 30 Gy the lowest dose for detecting induction of damage by X-rays in mature sperm chromatin. These results indicate that DBD-FISH is not only useful for in situ detection of DNA breakage but also for revealing structural features of chromatin.     

Evaluation of oxidative DNA damage in pigeon erythrocytes using DNA breakage detection-fluorescence in situ hybridization (DBD-FISH)

ABSTRACT

DNA breakage detection-fluorescence in situ hybridization (DBD-FISH) enables detection and quantification of DNA breakage in the entire genome or within specific DNA sequences in single cells. We used this method to visualize and evaluate DNA damage in pigeon erythrocytes that were induced by elevated temperature and hydrogen peroxide. We also examined morphological changes in the cell nuclei. DBD-FISH demonstrated a significant increase of DNA damage in a temperature dependent manner, which resulted in nuclear abnormalities associated with apoptotic cells. These cells gave strong nuclear fluorescent signals that indicated cell death.     

Copper(II) facilitates bleomycin-mediated unwinding of plasmid DNA

The unwinding of plasmid DNA by bleomycin A2 (BLM A2) was investigated by use of two-dimensional gel electrophoresis. It was found that Cu2+ ions greatly facilitated the unwinding of topoisomers of plasmid DNA by BLM A2 at concentrations where cupric ions alone had no effect on DNA supercoiling. The concentration of BLM A2 required for observable unwinding was reduced at least 100-fold in the presence of equimolar Cu2+. A plot of [Cu2+] vs extent of DNA unwinding in the presence of 10(-4) M BLM A2 gave a curve consistent with the action of cupric ions on BLM in an allosteric fashion, possibly rearranging the drug into a conformation that facilitates DNA unwinding. The participation of the metal center in enhancing DNA unwinding via direct ionic interaction with one or more negatively charged groups on the DNA duplex also seems possible. Further analysis of the structural factors required for BLM-mediated DNA unwinding was carried out with Cu2+ + BLM demethyl A2, the latter of which differs from BLM A2 only in that it lacks a methyl group, and associated positive charge, at the C-terminus. Cu(II).BLM demethyl A2 was found to be much less effective than Cu(II).BLM A2 as a DNA unwinding agent, emphasizing the strong dependence of this process on the presence of positively charged groups within the BLM molecule. These findings constitute the first direct evidence that the metal center of BLM can participate in DNA interaction, as well as in the previously recognized role of oxygen binding and activation.     

Escherichia coli DNA helicases: mechanisms of DNA unwinding

DNA helicases are ubiquitous enzymes that catalyse the unwinding of duplex DNA during replication, recombination and repair. These enzymes have been studied extensively; however, the specific details of how any helicase unwinds duplex DNA are unknown. Although it is clear that not all helicases unwind duplex DNA in an identical way, many helicases possess similar properties, which are thus likely to be of general importance to their mechanism of action. For example, since helicases appear generally to be oligomeric enzymes, the hypothesis is presented in this review that the functionally active forms of DNA helicases are oligomeric. The oligomeric nature of helicases provides them with multiple DNA-binding sites, allowing the transient formation of ternary structures, such that at an unwinding fork, the helicase can bind either single-stranded and duplex DNA simultaneously or two strands of single-stranded DNA. Modulation of the relative affinities of these binding sites for single-stranded versus duplex DNA through ATP binding and hydrolysis would then provide the basis for a cycling mechanism for processive unwinding of DNA by helicases. The properties of the Escherichia coli DNA helicases are reviewed and possible mechanisms by which helicases might unwind duplex DNA are discussed in view of their oligomeric structures, with emphasis on the E. coli Rep, RecBCD and phage T7 gene 4 helicases.     

DNA binding of dinuclear iron(II) metallosupramolecular cylinders. DNA unwinding and sequence preference

[Fe₂L₃]⁴⁺ (L = C₂₅H₂₀N₄) is a synthetic tetracationic supramolecular cylinder (with a triple helical architecture) that targets the major groove of DNA and can bind to DNA Y-shaped junctions. To explore the DNA-binding mode of [Fe₂L₃]⁴⁺, we examine herein the interactions of pure enantiomers of this cylinder with DNA by biochemical and molecular biology methods. The results have revealed that, in addition to the previously reported bending of DNA, the enantiomers extensively unwind DNA, with the M enantiomer being the more efficient at unwinding, and exhibit preferential binding to regular alternating purine–pyrimidine sequences, with the M enantiomer showing a greater preference. Also, interestingly, the DNA binding of bulky cylinders [Fe₂(L-CF₃)₃]⁴⁺ and [Fe₂(L-Ph)₃]⁴⁺ results in no DNA unwinding and also no sequence preference of their DNA binding was observed. The observation of sequence-preference in the binding of these supramolecular cylinders suggests that a concept based on the use of metallosupramolecular cylinders might result in molecular designs that recognize the genetic code in a sequence-dependent manner with a potential ability to affect the processing of the genetic code.     

Copper(II) complexes of diclofenac: Spectroscopic studies and DNA strand breakage

Copper(II) complexes of diclofenac with interesting anti-inflammatory profiles have been prepared and studied by infrared and electronic spectroscopy. In the solid state and in polar and coordinating solvents, all the complexes are solvated binuclear carboxylato-bridged complexes, [Cu(L)²(S)]², where L is monodeprotonated diclofenac and S is the axially bonded solvent. The effect of the copper(II) complexes on the in vitro DNA strand breakeage was studied by agarose gel electrophoresis. Relaxation or double stranded scissions of pDNA were observed leading to the formation of linear pDNA. Treatment of pDNA with high concentrations of these compounds caused a disappearance of pDNA. For the parent drug, sodium diclofenac, no effect on the pDNA was observed. This study presents some indications that the binuclear copper(II) complexes, [Cu(L)²(S)]², could have some relevance in the treatment of tumor cell lines.     

Rate of unwinding small DNA

The kinetics of the helix-coil transition of low molecular weight DNA was investigated using temperature-jump techniques. The material was sonicated or sheared, then fractionated according to molecular weight using differential solubility in an isopropanol-buffer mixture. To prevent irreversible strand separation the samples were cross-linked with mitomycin C.     

Theory of friction-limited DNA unwinding

The theory of friction-limited DNA unwinding is developed explicitly for moderate tind large perturbations. This extension of the earlier theory of the relaxation kinetics is necessary because of the complex nature of the rate limitation for small perturbations. The assumption of the theory that is violated under relaxation conditions is that base pairing reactions occurring at a constant local degree of twist of the strands are fast compared to the net unwinding of the molecule. However, these reactions that are slow for small perturbations have a large activation energy, and become faster than friction-limited un winding for large enough temperature jumps and sufficiently large DXA molecules. Thus only the rate for moderate and large perturbations is clearly limited by frictional resistance to turning the molecule in solution. The model used is a diffusional unwinding of the two strands, driven by the accompanying decrease in free energy. For large perturbations a numerical solution of the diffusion equation is required, since the diffusion coefficient is not constant. Two new parameters must be introduced into the equilibrium statistical theory to describe friction-limited unwinding kinetics. These are the force constant b, for winding up coil regions and the frictional coefficient per base pair β_cfor rotating coil regions in solution. We find by fitting the theory to experiment that b = 1.8 × 10^?13 ergs/ rad²- and β_c = 3.5 × 10^?21 erg see/base pair, both for DNA melted in alkali at 0.4.M Na ⁺ and ～30 °C. The latter value is in agreement with predictions based on the viscosity of single stranded DNA in alkali. The quoted value of bcan be interpreted to mean that the number of conformational states of a nucleolide is reduced by an average factor of 1.55 when it is wound around another strand to the degree of twist in a double helix, but without forming a base pair.     

The function of poly (ADP-ribosylation) in DNA breakage and rejoining

Poly (ADP-ribose) polymerase has an obligatory requirement for DNA strand-breaks in order to show full enzyme activity. Exposure of cells to DNA damaging agents activates this enzyme presumably through the production of DNA strand-breaks, either directly or via cellular enzymes. Recent evidence from manipulations of the cloned cDNA of this enzyme confirm the earlier evidence, obtained using enzyme inhibitors, that this enzyme is involved in DNA excision repair, probably at or near the ligation step. A very unusual human genetic disease has provided direct evidence for a link between the enzyme activities of poly (ADP-ribose) polymerase and of DNA ligase I. There is also some evidence that this enzyme may be involved in other cases of DNA breakage and rejoining, such as homologous and non-homologous DNA recombination, for example, in sister chromatid exchanges, in DNA transfection, in the intergration of retroviral proviral DNA and in variable antigen switching in African trypanosomes.     

Interaction of bleomycin A2 with deoxyribonucleic acid: DNA unwinding and inhibition of bleomycin-induced DNA breakage by cationic thiazole amides related to bleomycin A2

The association of the antitumor antibiotic bleomycin A2 with DNA has been investigated by employing several 2-substituted thiazole-4-carboxamides, structurally related to the cationic terminus of the drug. With a 5'-32P-labeled DNA restriction fragment from plasmid pBR322 as substrate, these compounds have been shown to inhibit bleomycin-induced DNA breakage. Analogues possessing 2'-aromatic substituents on the bithiazole ring were more potent inhibitors than those carrying 2'-aliphatic groups, e.g., the acetyl dipeptide A2. The degree of inhibition was similar at all scission sites on DNA, and inclusion of the analogues did not induce bleomycin cleavage at new sites. DNA binding of bithiazole derivatives has also been studied by two complementary topological methods. Two-dimensional gel electrophoresis using a population of DNA topoisomers and DNA relaxation experiments involving calf thymus DNA topoisomerase I and pBR322 DNA reveal that bleomycin bithiazole analogues unwind closed circular duplex DNA. The inhibition and unwinding studies together support recent NMR studies suggesting that both bleomycin A2 and synthetic bithiazole derivatives bind to DNA by an intercalative mechanism. The results are discussed in relation to the DNA breakage properties of bleomycin A2.     

Unwinding of supercoiled DNA by cis- and trans-diamminedichloroplatinum(II): influence of the torsional strain on DNA unwinding.

The effective unwinding angle, phi, for cis-diamminedichloroplatinum(II) (cis-DDP) and trans-DDP was determined by utilizing high resolution gel electrophoresis and supercoiled phi X174 RF DNA as a substrate. The effective unwinding angle was calculated by equating the reduction in mobility of the DDP-modified DNA to the removal of a number of superhelical turns. The value of the effective unwinding angle for both DDP isomers was greatest at the low levels of DDP bound and decreased with increasing amounts of unwinding agent. The cis-isomer is a better unwinding agent than is the trans-isomer, being nearly twice as effective in unwinding the supercoiled DNA at the DDP levels investigated. A comparison of the magnitude of phi below rb values of 0.005 and those at high levels of binding reveals that the extent of torsional strain in the supercoiled DNA influences the magnitude of the unwinding of the DNA by these complexes. When this method is used in the analysis of the unwinding angle for a covalently bound species on supercoiled DNA, it may provide a more reliable estimate of the magnitude of phi at high degrees of supercoiling and at low levels of modification.     

Poly(ADP-ribose)polymerase: a perplexing participant in cellular responses to DNA breakage

Poly(ADP-ribose) polymerase is a major nuclear protein of 116 kd, coded by a gene on chromosome 1, that plays a role in cellular responses to DNA breakage. The polymerase binds to DNA at single- and double-strand breaks and synthesizes long branched chains of poly(ADP-ribose), which covalently, but transiently, modifies itself and numerous other cellular proteins and depletes cells of NAD+. This much is known, but the physiological role of the polymerization-degradation cycle is still unclear. Poly(ADP-ribosyl)ation of proteins generally inhibits their function and can dissociated chromatin proteins from DNA. Inhibition of poly(ADP-ribose) polymerase increases to toxicity of alkylating agents and some other DNA-damaging agents and increases sister-chromatid exchange frequencies. During repair of alkylation damage, inhibition of poly(ADP-ribose) polymerase makes no change in excision of damaged products. increases the total number of repair patches, accelerates the rejoining of DNA breaks, and makes variable increases or decreases in net break frequencies. The polymerization cycle consequently is a major player in the response of cells to DNA breakage, but the game it plays is yet to be explained.     

Enzymic unwinding of DNA. 2. Chain separation by an ATP-dependent DNA unwinding enzyme.

The DNA-stimulated ATPase characterized in the accompanying paper is shown to be a DNA unwinding enzyme. Substrates employed were DNA, RNA hybrid duplexes and DNA-DNA partial duplexes prepared by polymerization on fd phage single-stranded DNA template. The enzyme was found to denature these duplexes in an ATP-dependent reaction, without detectably degrading. EDTA, an inhibitor of the Mg2+-requiring ATPase, was found to prevent denaturation suggesting that dephosphorylation of the ATP and not only its presence is required. These results together with those from enzyme-DNA binding studies lead to ideas regarding the mode of enzymic action. It is proposed that the enzyme binds, in an initial step, to a single-stranded part of the DNA substrate molecule and that from here, energetically supported by ATP dephosphorylation, it invades double-stranded parts separating base-paired strands by processive, zipper-like action. It is further proposed that chain separation results from the combined action of several enzyme molecules and that a tendency of the enzyme to aggregate with itself reflects a tendency of the molecules to cooperate. Various functions are conceivable for the enzyme.     

DNA unwinding produced by site-specific intrastrand cross-links of the antitumor drug cis-diamminedichloroplatinum(II)

The DNA unwinding produced by specific adducts of the antitumor drug cis-diamminedichloroplatinum(II) has been quantitatively determined. Synthetic DNA duplex oligonucleotides of varying lengths with two base pair cohesive ends were synthesized and characterized that contained site-specific intrastrand N7-purine/N7-purine cross-links. Included are cis-[Pt(NH3)2[d(GpG)]], cis-[Pt(NH3)2(d(ApG)]], and cis-[Pt(NH3)2[d(GpTpG)]] adducts, respectively referred to as cis-GG, cis-AG, and cis-GTG. Local DNA distortions at the site of platination were amplified by polymerization of these monomers and quantitatively evaluated by using polyacrylamide gel electrophoresis. The extent of DNA unwinding was determined by systematically varying the interplatinum distance, or phasing, in polymers containing the adducts. The multimer that migrates most slowly gives the optimal phasing for cooperative bending, from which the degree of unwinding can be obtained. We find that the cis-GG and cis-AG adducts both unwind DNA by 13 degrees, while the cis-GTG adduct unwinds DNA by 23 degrees. In addition, experiments are presented that support previous studies revealing that a hinge joint forms at the sites of platination in DNA molecules containing trans-GTG adducts. On the basis of an analysis of the present and other published studies of site-specifically modified DNA, we propose that local duplex unwinding is a major determinant in the recognition of DNA damage by the Escherichia coli (A)BC excinuclease. In addition, local duplex unwinding of 13 degrees and bending by 35 degrees are shown to correlate well with the recognition of platinated DNA by a previously identified damage recognition protein (DRP) in human cells.     

Mechanism of DNA strand breakage induced by photosensitized tetracycline-Cu(II) complex

Tetracyclines (TCs) in combination with Cu(II) ions exhibited significant DNA damaging potential vis a vis tetracyclines per se. Interaction of tetracyclines with DNA resulted in alkylation at N-7 and N-3 positions of adenine and guanine bases, and caused destabilization of DNA secondary structure. Significant release of acid-soluble nucleotides from tetracycline-modified DNA upon incubation with S(1) nuclease ascertained the formation of single stranded regions in the DNA. Also, the treatment of tetracycline-modified DNA with 0.1 and 0.5M NaOH resulted in 62 and 76% hydrolysis compared to untreated control. Comparative alkaline hydrolysis of DNA modified with tetracycline derivatives showed differential DNA damaging ability in the order as DOTC > DMTC > TC > OTC > CTC. Addition of Cu(II) invariably augmented the extent of tetracycline-induced DNA damage. The alkaline unwinding assay clearly demonstrated the formation of approximately six strand breaks per unit DNA at 1:10 DNA nucleotide/TC molar ratio in the presence of 0.1mM Cu(II) ions. At a similar Cu(II) concentration, a progressive transformation of covalently closed circular (CCC) (form-I) plasmid pBR322 DNA to forms-II and -III was noticed with increasing tetracycline concentrations. The results obtained with the free-radical quenchers viz. mannitol, thiourea, sodium benzoate and superoxide dismutase (SOD) suggested the involvement of reactive oxygen species in the DNA strand breakage. It is concluded that the tetracycline-Cu(II)-induced DNA damage occurs due to (i) significant binding of tetracycline and Cu(II) with DNA, (ii) methyl group transfer from tetracycline to the putative sites on nitrogenous bases, and (iii) metal ion catalyzed free-radical generation in close vicinity of DNA backbone upon tetracycline photosensitization. Albeit, the DNA alkylation and strand cleavage are repairable lesions, but any defect in the critical repair pathway may augment the damage accumulation and mutagenesis.     

DNA unwinding enzyme II of Escherichia coli. 2. Characterization of the DNA unwinding activity.

The DNA-stimulated 75000-Mr ATPase described in the preceding paper is shown to be a further catalytic DNA unwinding principle (DNA unwinding enzyme II) made in Escherichia coli cells (the first being the 180000-Mr ATPase of the cells: DNA unwinding enzyme I). Unwinding depends strictly, on the supply of ATP. It occurs only under conditions permitting ATP dephosphorylation and it proceeds as long as enzyme molecules are permitted to enter the enzyme - DNA complex. The enzyme binds specifically to single-stranded DNA yielding a complex of only limited stability. These results are interpreted in terms of a distributive mode of action of the enzyme. It is argued that chain separation starts near a single-stranded DNA region and that, forced by continued adsorption of enzyme molecules to the DNA, it develops along the duplex. This mechanism is different from that deduced previously for DNA unwinding enzyme I. Complicated results were obtained using ATPase prepared from rep3 mutant cells.