Effect of neocarzinostatin-induced strand scission on the template activity of DNA for DNA polymerase I.

Neocarzinostatin (NCS), an antitumor protein antibiotic that causes strand scissions of DNA both in vitro and in vivo, is shown to lower the template activity of DNA for DNA polymerase Iin vitro. There is a correlation between the extent of strand scission and the degree of inhibition, maximal inhibition of the polymerase reaction being obtained under conditions promoting maximal strand scission. These effects can be related to the concentrations of NCS and of 2-mercaptoethanol and are maximized by pretreatment of the DNA with drug. Results from polymerase assays in which the amount of drug-treated DNA template was varied at a constant level of the enzyme suggest that the sites associated with NCS-induced breaks are nonfunctional in DNA synthesis but bind DNA polymerase I. The binding of the enzyme to the inactive sites is further confirmed using [203 Hg] polymerase. It is shown that the lowering of the template activity of DNA by NCS under conditions of strand scission is due to the generation of a large number of inactive sites that block, competitively, the binding of DNA polymerase to the active sites on the template. Furthermore, the inhibition of DNA synthesis, which depends on the extent of strand breakage and on the relative amounts of template and enzyme, can be reversed by increasing the levels of template or polymerase. The finding that DNA synthesis directed by poly [d(A-T)] is much more sensitive to NCS than that primed by poly [d(G-C)] suggests that the drug preferentially interacts at regions containing adenine and/or thymine residues.     

Free radical mechanisms in neocarzinostatin-induced DNA damage

The molecular mechanisms by which the antitumor protein antibiotic, neocarzinostatin, interacts with DNA and causes DNA sugar damage is discussed. Physical binding of the nonprotein chromophore of neocarzinostatin to DNA, involving an intercalative process and dependent on the microheterogeneity of DNA structure, is followed by thiol activation of the drug to a probable radical species. The latter attacks the deoxyribose, especially at thymidylate residues, by abstracting a hydrogen atom from C-5' to generate a carbon-centered radical on the DNA. This nascent form of DNA damage either reacts with dioxygen to form a peroxyl radical derivative, which eventuates in a strand break with a nucleoside 5'-aldehyde at the 5'-end or reacts with the bound drug to form a novel drug-deoxyribose covalent adduct. Nitroaromatic radiation sensitizers can substitute for dioxygen, but the DNA damage products are different. Similarities between the various biological effects of neocarzinostatin and ionizing radiation are reviewed.     

Activation and inactivation of neocarzinostatin-induced cleavage of DNA.

The possible role of free radicals in the mechanism of neocarzinostatin (NCS) action was studied. While mercaptene markedly stimulate the ability of NCS to degrade DNA, they also rapidly inactivate the antibiotic in a preincubation and at higher concentration inhibit the degradation reaction. The radiation protector S,2-aminoethylisothiuronium bromide-HBr is the most potent compound tested. Scavengers of diffusible OH radicals, O2- or H2O2 do not result in significant inhibition of the oxygen-dependent cleavage of DNA by NCS; in fact, alcohols and other organic solvents stimulate the reaction several-fold. By contrast, the potent peroxyl free radical scavenger, alpha-tocopherol, blocks the reaction 50% at 50 micron.     

Nitroxide-mediated protection against X-ray- and neocarzinostatin-induced DNA damage.

The stable free radical Tempol (4-hydroxy-2,2,6,6-tetramethyl-piperidinyloxy) has been shown to protect against X-ray-induced cytotoxicity and hydrogen peroxide- or xanthine oxidase-induced cytotoxicity and mutagenicity. The ability of Tempol to protect against X-ray- or neocarzinostatin (NCS)-induced mutagenicity or DNA double-strand breaks (dsb) was studied in Chinese hamster cells. Tempol (50 mM) provided a protection factor of 2.7 against X-ray-induced mutagenicity in Chinese hamster ovary (CHO) AS52 cells, with a protection factor against cytotoxicity of 3.5. Using the field inversion gel electrophoresis technique of measuring DNA dsb, 50 mM Tempol provides a threefold reduction in DNA damage at an X-ray dose of 40 Gy. For NCS-induced damage, Tempol increased survival from 9% to 80% at 60 ng/mL NCS and reduced mutation induction by a factor of approximately 3. DNA dsb were reduced by a factor of approximately 7 at 500 ng/mL NCS. Tempol is representative of a class of stable nitroxide free radical compounds that have superoxide dismutase-mimetic activity, can oxidize metal ions such as ferrous iron that are complexed to DNA, and may also detoxify radiation-induced organoperoxide radicals by competitive scvenging. The NCS chromophore is reduced by sulfhydryls to an active form. Electron spin resonance (ESR) spectroscopy shows that 2-mercaptoethanol-activated NCS reacts with Tempol 3.5 times faster than does unactivated NCS. Thus, Tempol appears to inactivate the NCS chromophore before a substantial amount of DNA damage occurs.     

Artificial restriction DNA cutter for site-selective scission of double-stranded DNA with tunable scission site and specificity

The artificial restriction DNA cutter (ARCUT) method to cut double-stranded DNA at designated sites has been developed. The strategy at the base of this approach, which does not rely on restriction enzymes, is comprised of two stages: (i) two strands of pseudo-complementary peptide nucleic acid (pcPNA) anneal with DNA to form 'hot spots' for scission, and (ii) the Ce(IV)/EDTA complex acts as catalytic molecular scissors. The scission fragments, obtained by hydrolyzing target phosphodiester linkages, can be connected with foreign DNA using DNA ligase. The location of the scission site and the site-specificity are almost freely tunable, and there is no limitation to the size of DNA substrate. This protocol, which does not include the synthesis of pcPNA strands, takes approximately 10 d to complete. The synthesis and purification of the pcPNA, which are covered by a related protocol by the same authors, takes an additional 7 d, but pcPNA can also be ordered from custom synthesis companies if necessary.     

DNA scission and repair during pachytene in Lilium

Sedimentation characteristics of native and denatured DNA were determined for sequential stages of meiosis in Lilium. Degradation of DNA during its preparation for analysis was minimized by extracting it from meiocytes that had been converted to protoplasts. Native DNA sedimented with a major peak in the 250s region of a glycerol gradient. The profiles for all meiotic stages were essentially the same. Denatured DNA showed a bimodal profile at pachytene (104s and 62s) and a more or less unimodal profile at other stages (104s). The difference was consistently observed regardless of the particular techniques used for preparation and measurement. The 62s component was not observed in achiasmatic cells or in cells which had been arrested by cycloheximide at prepachytene stages. Isotopic studies of pachytene DNA synthesis showed that DNA label accumulated in the 100s region and that it was present in both the old and new strands derived from premeiotic S-phase. The significance of the endogenous nicking of DNA is related to the timing and mechanics of crossing-over.     

DNA strand scission activity of metalloporphyrins

The iron porphyrin derivatives, iron (III) meso-tetra(4-N-methylpyridyl)-porphine (Fe(III)T4MPyP), aceto-iron (III) meso-tetra(3-N-methylpyridyl)porporphine (AcO-Fe(III)T3MPyP), and iron (III) meso-tetra(p-sulfonatophenyl)-porphine (Fe(III)TSPP), have been shown to induce strand scissions in DNA. Incubation of these porphyrins with PM2 DNA results in the conversion of circular supercoiled DNA to the nicked circular duplex form. The presence of dithiothreitol increases the extent of the nicking reaction. Fe(III)TSPP, which, unlike Fe(III)T4MPyP and AcO-Fe(III)T3MPyP, does not bind to DNA, is the least effective of the three porphyrins in inducing strand scissions in PM2. Both Fe(III)T4MPyP and AcO-Fe(III)T3MPyP induce strand scissions in cellular DNA of pre-labeled HeLa S₃ cells while Fe(III)TSPP has a very limited effect.     

双歧杆菌试管内生物拮抗作用研究

目的 本实验从正常青少年体内分离出1株双歧杆菌,通过试管内研究双歧杆菌对大肠埃希菌和粪肠球菌的生物拮抗作用.为双歧杆菌临床应用及食品开发提供一定的基础理论依据和广阔的市场前景.方法 本项研究以从佳木斯大学健康学生体内分离出1株双歧杆菌为试材,将大肠埃希菌、粪肠球菌接种于PYG液体培养基中,37℃厌氧培养48 h,将菌液浓度利用分光光度计法调到2麦氏.将大肠埃希菌对照组分为10支,分离的双歧杆菌+大肠埃希菌组10支,分离的双歧杆菌对照组10支,分离的双歧杆菌+粪肠球菌组10支,粪肠球菌对照组10支,将以上50个试管全部置于厌氧培养箱内37℃培养48 h,将培养好的大肠埃希菌和粪肠球菌进行梯度稀释,然后用微量移液器吸取标本于每个培养基上滴3滴,每滴滴上由高稀释度向低稀释度,液体量为10 μL的菌液.晾干滴种好的培养基于适宜条件进行培养并选出适合菌落生长的稀释度,计算同一稀释度平均菌落数(x).结果 双歧杆菌12 h时对大肠埃希菌生长无显著性,在24h时检测不到大肠埃希菌的存在.12和24h时粪肠球菌与双歧杆菌混合组与粪肠球菌对照组相比,差异均无统计学意义(P＞0.05).结论 体外对照实验研究该双歧杆菌对大肠埃希菌和粪肠球菌的生物拮抗作用,此株双歧杆菌只对大肠埃希菌有抑制作用,而对粪肠球菌无抑制作用,机制需要深入研究.     

Nitroxides inhibit peroxyl radical-mediated DNA scission and enzyme inactivation

Nitroxides are cell-permeable stable radicals that protect biomolecules from oxidative damage in several ways. The mechanisms of protection studied to date include removal of superoxide radicals as SOD-mimics, oxidation of transition metal ions to preempt the Fenton reaction, and scavenging carbon-centered radicals. However, there is no agreement regarding the reaction of piperidine nitroxides with peroxyl radicals. The question of whether they can protect by scavenging peroxyl radicals is important because these radicals are formed in the presence of oxygen abundant in biological tissues. To further our understanding of the antioxidative behavior of piperidine nitroxides, we studied their effect on biochemical systems exposed to the water soluble radical initiator 2,2'-azobis (2-amidinopropane) hydrochloride (AAPH). AAPH thermally decomposes to yield tert-amidinopropane radicals (t-AP(*)) that readily react with oxygen to form peroxyl radicals (t-APOO(*)). It has recently been reported that piperidine nitroxides protect plasmid DNA from t-AP(*) though not from t-APOO(*). The present study was directed at the question of whether these nitroxides can protect biological systems from damage inflicted by peroxyl radicals. The reaction of nitroxides with AAPH-derived radicals was followed by cyclic voltammetry and electron paramagnetic resonance spectroscopy, whereas the accumulation of peroxide was iodometrically assayed. Assaying DNA damage in vitro, we demonstrate that piperidine nitroxides protect from both t-AP(*) and t-APOO(*). Similarly, nitroxides inhibit AAPH-induced enzyme inactivation. The results indicate that piperidine nitroxides protect the target molecule by reacting with and detoxifying peroxyl radicals.     

Strand scission of DNA in KB cells by macromomycin.

Macromomycin, an antitumor protein, produces strand scission of DNA in KB cells, which might appear to correlate with its concommitant inhibition of thymidine and uridine incorporation into nucleic acids. However, an acetyl derivative of macromomycin does not cause the same extent of strand breakage, yet it shows inhibitory and cytotoxic properties similar to the native protein. This is also seen in a derivative of macromomycin resulting from its reaction with the Bolton-Hunter reagent. Cesalin, another antitumor protein, does not possess DNA cleavage activity.     

Stoichiometry of DNA strand scission and aldehyde formation by bleomycin

A colorimetric assay of DNA breakage by bleomycin has been standardized and indicates that strand scission is stoichiometric with the formation of a single equivalent of an aldehyde compound consisting of base plus deoxyribose carbons 1' to 3'. Both strand scission and aldehyde formation require the presence of O2. An alternate DNA lesion inflicted by bleomycin, alkali labilization, is O2-dependent, as is the accompanying release of free bases.     

Radiation-induced DNA single-strand scission and its rejoining in spermatogonia and spermatozoa of mouse

Gamma-ray-induced DNA single-strand scissions and the ability to repair the scissions in spermatogonia from young mice and in spermatozoa from adult mice were studied quantitatively by an alkaline sucrose density-gradient centrifugation method. The average size of DNAs in non-irradiated spermatogonia was 2.6–3.0 × 10⁸ daltons, similar to those of a spermatid-rich population, and the size of DNA in non-irradiated spermatozoa was 1.2 × 10⁸ daltons.In spermatogonia, the radiosensitivity of DNA was 0.42 single-strand breaks/ 10¹² daltons of DNA/rad in oxic conditions and only 0.24 under anoxic conditions. In spermatozoa the break efficiency of DNA was 0.22 single-strand breaks/10¹² daltons of DNA/rad under oxic conditions and altered little under anoxic irradiation. The DNA scissions were efficiently repaired in spermatogonia within 10 min, whereas the breaks in spermatozoa were not rejoined at all even after two days of post-irradiation time.The radiosensitivities of DNA, repair capability and non- and/or slow-reparable DNA scissions were compared in spermatogonium-rich, spermatid-rich and spermatozoan-rich populations.     

Photoinduced DNA cleavage by naphthalimide hydroperoxide-specific strand scission at -GG- site of DNA

We have prepared a series of naphthalene hydroperoxides (1-3) which possess hydroperoxy group at gamma-position of imide carbonyl. Upon photoirradiation (greater than 350 nm) hydroperoxides (1-3) decomposed with efficient generation of hydroxyl radical, which was confirmed by esr spin trapping technique using dimethylpyrroline oxide as a spin trapper. All these hydroperoxides induced DNA strand scission upon photoirradiation (greater than 350 nm), especially hydroperoxide 3 cleaved plasmid phi X 174 DNA (Form I) to give nicked (Form II) and linear (Form III) DNA even at 1 microM concentration. Further, it was observed that 3 exclusively cleaved DNA at the 5'-G site of -GG-sequence.     

DNA strand scission and ADP-ribosyltransferase activity during murine erythroleukemia cell differentiation

The accumulation of DNA strand breaks and activation of ADP-ribosyltransferase (ADPRT) have recently been associated with cellular differentiation. Murine erythroleukemia (MEL) cells undergo erythropoietic differentiation when exposed to dimethyl sulfoxide (Me2SO) and several studies have suggested that DNA strand scission induced by this agent is a prerequisite for expression of the differentiated phenotype. Me2SO induction of MEL cells has also been associated with increases in ADPRT activity in one study, but not in another. We have monitored the effects of Me2SO on DNA strand breaks in preformed and replicating MEL cell DNA. The results clearly demonstrate that DNA fragmentation is not detectable during Me2SO induction of MEL differentiation, even in the presence of 3-aminobenzamide, an inhibitor of ADPRT. Further, these results are consistent with an absence of detectable changes in both endogenous and total potential ADPRT activity during Me2SO-induced MEL differentiation. These findings would argue against Me2SO induction of DNA strand scission and ADPRT in MEL cells undergoing differentiation.     

Radiation-induced double-strand scission of the DNA of mammalian metaphase chromosomes

The molecular weight distribution of double-stranded mammalian (hamster) DNA was determined by ultracentrifugation of isolated metaphase chromosomes previously layered onto sucrose gradients containing high salt concentrations to dissociate the protein and nucleic acid components. In untreated controls the distribution (as determined by counting the incorporated radioactivity in the resultant fractions) exhibited a peak at 225 X 10(6) daltons. Inclusion of mercaptoethanol and hydroxylamine into the gradients produced no significant change of these sedimentation patterns. Gamma-radiation-induced reduction in the number and weight average molecular weights was used to calculate a value of 1.05 X 10(11) double-strand breaks/gram rad, equivalent to about 600 eV/break. No significant difference was observed for chromosomes irradiated either before or after isolation from intact mitotic cells. Irradiation in the presence of cystamine resulted in at least a sevenfold reduction in the apparent double-strand scission. The observed sedimentation patterns were compared with those generated by a theoretical computer simulation of radiation-induced degradation which assumed random selection and breakage of molecules. These results suggested that at least 80 to 90 % of the isolated DNA was distributed approximately normally with a mean molecular weight of about 200 X 10(6) daltons and a standard deviation of about 50 X 10(6) daltons.     

Release of nucleosomes from nuclei by bleomycin-induced DNA strand scission

Mononucleosomes were released from both isolated mammalian (hog thyroid) and protozoan (Tetrahymena) nuclei by the bleomycin-induced DNA-strand breaking reaction. Trout sperm nuclei, on the other hand, were protected from the bleomycin-mediated DNA degradation. The mononucleosomes released from the bleomycin-treated nuclei contained the core histones H2A, H2B, H3, and H4; while HMG1 and HMG2 proteins, in addition to the core histones, were detected in the mononucleosomes obtained by micrococcal nuclease digestion of nuclei. HMGs, but not H1 histone, were dissociated into the supernatant by cleavage of chromatin DNA with bleomycin, whereas both HMGs and H1 were found in that fraction by digestion of nuclei with micrococcal nuclease. HMG1 and HMG2 were exclusively dissociated from chromatin with 1 mM bleomycin under the solvent condition where the DNA strand-breaking activity of the drug is repressed. These observations suggest the possibility that bleomycin preferentially binds to linker DNA regions not occupied by H1 histone in chromatin and exclusively dissociates HMG proteins and breaks the DNA strand. The results of the effects on bleomycin-induced DNA cleavage of nuclei of various drugs including polyamines, chelating agents, intercalating antibiotics such as mitomycin C or adriamycin, and radical scavengers are also presented.     

Ozonolysis of supercoiled pBR322 DNA resulting in strand scission to open circular DNA.

Treatment of supercoiled pBR322 DNA with ozone resulted in the conversion of closed circular DNA to open circular DNA. Restriction analysis of the resulting open circular DNA showed that ozonolysis in the absence of salt caused single strand cleavage at specific sites.     

Efficient double-strand scission of plasmid DNA by quaternized-chitosan zinc complex

N-[(2-Hydroxy-3-trimethylammonium) propyl] chitosan chloride (HTACC) was prepared to construct a chitosan-based zinc complex (HTACC-Zn(II)) as a catalyst with good water solubility for rapid DNA cleavage. Results indicated that the observed rate constant (k(obs)) of plasmid DNA cleaved by HTACC-Zn(II) could be enhanced by 10(7)-fold compared with that of uncatalyzed DNA cleavage. The kinetic behavior of HTACC-Zn(II) for DNA cleavage is well fitted by Michaelis-Menten model. The results of gel electrophoresis suggested that HTACC-Zn(II) preferentially perform double-strand break of plasmid DNA.     

Nitroxides block DNA scission and protect cells from oxidative damage.

The protective effect of cyclic stable nitroxide free radicals, having SOD-like activity, against oxidative damage was studied by using Escherichia coli xthA DNA repair-deficient mutant hypersensitive to H2O2. Oxidative damage induced by H2O2 was assayed by monitoring cell survival. The metal chelator 1,10-phenanthroline (OP), which readily intercalates into DNA, potentiated the H2O2-induced damage. The extent of in vivo DNA scission and degradation was studied and compared with the loss of cell viability. The extent of DNA breakage correlated with cell killing, supporting previous suggestions that DNA is the crucial cellular target of H2O2 cytotoxicity. The xthA cells were protected by catalase but not by superoxide dismutase (SOD). Both five- and six-membered ring nitroxides, having SOD-like activity, protected growing and resting cells from H2O2 toxicity, without lowering H2O2 concentration. To check whether nitroxides protect against O2.(-)-independent injury also, experiments were repeated under hypoxia. These nitroxides also protected hypoxic cells against H2O2, suggesting alternative modes of protection. Since nitroxides were found to reoxidize DNA-bound iron(II), the present results suggest that nitroxides protect by oxidizing reduced transition metals, thus interfering with the Fenton reaction.