Single-strand and double-strand deoxyribonucleic acid breaks produced by several bleomycin analogues

Production of single-strand breaks (ssb) and double-strand breaks (dsb) of PM2 phage DNA by several structurally related bleomycin (BLM) analogues was studied by gel electrophoresis. BLM A2 and BLM B2 produced a comparable extent of dsb. In various experiments, BLM A2 and BLM B2, at 22-41 ng/mL, degraded 50% of the form I DNA into 33-38% form II and 12-17% form III DNA. BLM B1' produced ssb and dsb at a ratio similar to that of BLM A2, but both at a rate less than half that of BLM A2. Phleomycin (PLM) D1 induced an equivalent amount of ssb but only one-eighth of dsb induced by BLM B2. The relatively lower extent dsb production for PLM D1 was observed either in borate buffer (pH 9.5) or in Tris-HCl buffer (pH 7.5) and in the presence or absence of exogenous Fe(II). Deamido-BLM A2 produced ssb to an extent approximately half that of BLM A2 and dsb to less than one-eighth that of BLM A2. The following conclusions were drawn. (1) BLM analogues produced ssb and dsb to different extents and ratios. (2) The ratio of dsb to ssb varied depending on the analogue, indicating a lack of a direct correlation between ssb and dsb. (3) The extent of ssb and dsb was affected by modifications on both the C- and N-terminal half-molecules of BLM: modification of either the N-terminal amide or the bithiazole greatly reduced dsb, whereas changes in structure or charge in the C-terminal amine affected ssb and dsb to a similar extent.     

On the reaction of iron bleomycin with thiols and oxygen.

Iron(III)bleomycin undergoes a redox reaction with thiols. Evidence from epr and UV-visible absorbance spectra indicate that the metal complex forms an intermediate with sulfhydryl groups presumably by adding a sixth ligand. In the presence of oxygen iron bleomycin cycles between its two oxidation states to catalyze the generation of oxygen free radicals using thiols as a source of electrons.     

Copper(II).bleomycin, iron(III).bleomycin, and copper(II).phleomycin: comparative study of deoxyribonucleic acid binding

The kinetics and mechanism of binding of Cu-(II).bleomycin, Fe(III).bleomycin, and Cu(II).phleomycin to DNA were studied by using fluorometry, equilibrium dialysis, electric dichroism, and temperature-jump and stopped-flow spectrophotometry. The affinity of Cu(II).bleomycin for DNA was greater than that of metal-free bleomycin but less than that of Fe(III).bleomycin. Cu(II).bleomycin exhibited a two-step binding process, with the slow step indicating a lifetime of 0.1 s for the Cu(II).bleomycin.DNA complex. Fe(III).bleomycin binding kinetics indicated the presence of complexes having lifetimes of up to 22 s. DNA was lengthened by 4.6 A/molecule of bound Cu(II).bleomycin and by 3.2 A/bound Fe(III).bleomycin but not at all by Cu(II).phleomycin, suggesting that both bleomycin complexes intercalate while the phleomycin complex does not. However, phleomycin exhibited nearly the same specificity of DNA base release as bleomycin. These results suggest that the coordinated metal ion plays a major role in the binding of metal-bleomycin complexes to DNA but that intercalation is neither essential for DNA binding and degradation nor primarily responsible for the specificity of DNA base release by these drugs.     

Effect of ascorbic acid on the production of singlet oxygen by purified human myeloperoxidase

We have previously studied purified human myeloperoxidase-hydrogen peroxide-halide ion systems as models of possible singlet oxygen production by granulocytes. While myeloperoxidase could efficiently produce singlet oxygen, the yield of singlet oxygen at a physiological pH with Cl- was very small due to enzyme inactivation. In that Bolscher et al. [(1984) Biochim. Biophys. Acta 784, 189-191] observed that micromolar concentrations of ascorbic acid prevented inactivation of myeloperoxidase and increased the production of hypochlorous acid, we examined whether ascorbic acid would augment singlet oxygen production by the myeloperoxidase-hydrogen peroxide-halide ion systems. Ascorbic acid, however, fails to increase the singlet oxygen yield, suggesting that it does not augment singlet oxygen production in the intact granulocyte by a myeloperoxidase-dependent mechanism.     

Singlet oxygen production by bleomycin. A comparison with heme-containing compounds

Fe(III)-bleomycin catalyzes the decomposition of 13-hydroperoxylinoleic acid and of 15-hydroperoxyarachidonic acid to produce small quantities of singlet oxygen. No singlet oxygen is produced when hydrogen peroxide, ethyl hydroperoxide, cumene hydroperoxide, and t-butyl hydroperoxide are used as substrates. The heme-containing catalysts, methemoglobin and hematin, have identical hydroperoxide substrate requirements for singlet oxygen production. The hydroperoxide requirements for singlet oxygen production correlate with those reported by Dix et al. (Dix, T.A., Fontana, R., Panthani, A., and Marnett, L.J. (1985) J. Biol. Chem. 260, 5358-5365) for the production of peroxyl radicals in the hematin-catalyzed decomposition of hydroperoxides. The bimolecular reaction of peroxyl radicals is a plausible reaction mechanism for the singlet oxygen production in the systems studied.     

Bifunctional intercalation of antitumor antibiotics BBM-928A and echinomycin with deoxyribonucleic acid. Effects of intercalation on deoxyribonucleic acid degradative activity of bleomycin and phleomycin

The binding of peptide antitumor antibiotics, BBM-928A and echinomycin, to superhelical PM2 DNA and the effects of the resulting conformational changes of DNA on the DNA-degradative activity of two related antitumor antibiotics, bleomycin A2 and phleomycin D1, have been studied. The bifunctional intercalative mode of the DNA binding of BBM-928A concluded previously from viscometric and fluorometric studies has been confirmed by gel electrophoretic analysis. Under the employed electrophoretic conditions, DNA-bound BBM-928A showed little dissociation whereas echinomycin and ethidium bromide showed partial and nearly complete dissociation, respectively. BBM-928A induced neither single-strand nor double-strand breaks in DNA. Competitive binding studies by fluorescence changes suggested that binding sites on DNA molecules for BBM-928A (or echinomycin) may differ from those for ethidium bromide, since binding to DNA by the two drugs was not competitive even at saturating concentrations. The lack of such a competition between the two drugs is not consistent with the neighbor-exclusion principle. The DNA-degradative activity of both bleomycin A2 and phleomycin D1 increased with the removal of the negative superhelicity of DNA by the BBM-928A intercalation and decreased with the formation of positive superhelical turns induced by high concentrations of BBM-928A. Thus the degradative activity of both bleomycin A2 and phleomycin D1 is sensitive in a similar manner to the degree of superhelicity rather than the double helicity of DNA, although there are differences between these two drugs in interaction with DNA.     

Iron . bleomycin . DNA system evidence of a long-lived bleomycin . iron . oxygen intermediate

When Fe(II) is added to a bleomycin. DNA mixture in the presence of air a long-lived $\text{(}\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{= 45}\text{minutes}\text{)}$ EPR silent species (I′) is formed; the circular dichroism and absorption spectra of which have been characterized. This complex slowly decays yielding a ferric complex (III′) analogous to the well known low spin Fe(III). BLM species.     

Effect of reduced oxygen tension on reactive oxygen species production and activity of antioxidant enzymes in swine granulosa cells

During follicle growth swine granulosa cells are physiologically exposed to a progressive oxygen shortage. It has already been shown that hypoxia stimulates angiogenesis through an increase of VEGF production, however, despite considerable progress in the understanding of the final events induced by cellular hypoxia, the signal transduction pathway remains elusive. Recent evidence suggest a role for Reactive Oxygen Species (ROS) as hypoxia signal transducer. Granulosa cells were isolated from pig follicles (> 5 mm) and cultured for 18 h in normoxic (19% O2), hypoxic (5% O2) or anoxic (1% O2) conditions. Following the incubation ROS (O2- and H2O2) production and the activity of scavenging enzymes (SOD, catalase and peroxidase) were determined. It was apparent from our data that ROS generation was reduced by hypoxia. On the contrary, SOD and peroxidase, but not catalase, increased their activity. Further studies are needed to verify whether ROS are involved in signalling hypoxia.     

Strand scission of deoxyribonucleic acid by neocarzinostatin, auromomycin, and bleomycin: studies on base release and nucleotide sequence specificity

The nucleotide sequence specificity of neocarzinostatin (NCS), auromomycin (AUR), bleomycin (Blm), phleomycin (Phlm), and tallysomycin (Tlm) has been determined by using these antibiotics and their associated chromophores to create strand scissions in end-labeled restriction fragments of DNA and then determining the base sequence of the oligonucleotides formed. NCS and the NCS chromophore induce similar patterns of cleavage in DNA fragments labeled at the 5' terminus. The pattern produced by the AUR chromophore also resembles that of its holoantibiotic. Dithiothreitol enhances the rate of cleavage of DNA by the AUR chromophore but does not alter the sequence specificity. The results suggest that the polypeptide component of AUR and NCS serves primarily as a carrier for the chromophore. When tested with a fragment labeled at the 3' terminus, the products of NCS and AUR cleavage do not display the patterns of chemically produced oligonucleotides cleaved at phosphodiester bonds, suggesting that the 5' terminus is modified by a sugar fragment. NCS primarily attacks thymine (75% of the total bases attacked) and, to a lesser extent, adenine (19%) and cytosine (6%). AUR preferentially attacks guanine (67% of total bases), while attacking less often thymine (24%) and adenine (9%). Bleomycin and its analogues preferentially cleave purine--pyrimidine (5' leads to 3') and pyrimidine--pyrimidine (3' leads to 5') sequences. All (5' leads to 3') GT and GC sequences were cleaved. Phlm G and Phlm-Pep are less active than bleomycin toward purines while Tlm was more active. The patterns of cleavage produced by Blm A2 and Blm B6 are similar, while those produced by Phlm-Pep, Phlm G, Blm-B1', and Blm-Pep resemble one another. The cleavage pattern of Tlm shows quantitative differences from the other analogues tested. Differences between bleomycin and its analogues may be related to structural differences in these molecules.     

Hydrogen cyanide production by Pseudomonas aeruginosa at reduced oxygen levels

Hydrogen cyanide production by Pseudomonas aeruginosa growing in a synthetic medium required aerobosis but operated efficiently at low dissolved oxygen concentration. Half maximum levels of cyanogenesis occurred at 0.015 microM oxygen; maximum cyanogenesis occurred over a wide range, 0.1-180 microM, of oxygen concentrations. These cells lost the ability to produce cyanide upon aerobic incubation in the absence of both the carbon energy source (L-glutamate) and the metabolic precursor of hydrogen cyanide (glycine). This loss of cyanogenesis was dependent on oxygen concentration; 1.0 microM oxygen produced no detectable loss, whereas 180 microM oxygen caused a rapid decline in cyanogenic ability. The endogenous cyanide production rate of cells in the presence of carbon energy source was not significantly influenced by oxygen concentration. During the batch culture cycle, the acquisition of the ability to produce HCN was preceded by oxygen reduction to growth-limiting levels. Cells which had lost the ability to produce hydrogen cyanide by oxygen treatment required protein synthesis before they could again become cyanogenic.     

Effect of dissolved oxygen concentration and impeller tip speed on itaconic acid production by Aspergillus terreus

Summary Effect of aeration rate and impeller tip speed on mycelium growth and itaconic acid production was investigated in a batch culture of Aspergillus terreus IFO-6365. When impeller tip speed was 94.2 cm/sec at a fixed aeration rate of 0.5 vvm, itaconic acid concentration was 3.6 and 1.6 times higher than those in the impeller tip speed of 62.8 and 125.7 cm/sec, respectively. When an oxygen-enriched air was supplied at a fixed impeller tip speed of 94.2 cm/sec and dissolved oxygen concentration was maintained in the 20–60 % range, both itaconic acid concentration and mycelium growth were not affected by the dissolved oxygen concentration.     

On the fidelity of deoxyribonucleic acid synthesis directed by chromatin-associated deoxyribonucleic acid polymerase beta

Accuracy of poly[d(A-T)] synthesis catalyzed by chromatin-bound deoxyribonucleic acid (DNA) polymerase beta was measured with several types. A new procedure was developed for the isolation of copied poly[d(A-T)] from chromatin DNA. This method involved in vitro copying of poly[d(A-T)] by native chromatin and subsequent selective fragmentation of chromatin by restriction nucleases, proteinase K, and heat denaturation. The fragmented natural DNA is then separated from the high molecular weight poly[d(A-T)] by gel filtration. The efficacy of DNA removal by this procedure was validated by cesium chloride gradient and nearest-neighbor analysis of the product of the reaction and by measurement of the fidelity of poly[d(A-T)] synthesis by Escherichia coli DNA Pol I contaminated with increasing amounts of DNA. Also, DNA polymerases dissociated from chromatin retain the same accuracy as that of native chromatin. Synthesis of poly[d(A-T)] by chromatin is catalyzed mainly by DNA polymerase-beta. By use of the described technique, we find that the fidelity of this reaction is exceptionally low; approximately one dGTP was incorporated for every thousand complementary nucleotides polymerized.     

Effects of reduced oxygen on growth and antibiotic production inStreptomyces clavuligerus

Summary The effects of reduced oxygen on growth and antibiotic production were studied in batch cultures ofStreptomyces clavuligerus in defined media. Antibiotic levels were unaffected by reduced oxygen for the first 50 hours of fermentation. After growth ceased, antibiotic concentrations dropped by a factor of about three under reduced oxygen, while the antibiotic concentration was stable when air was used. This suggests that enzymes for hydrolyzing antibiotics may be regulated by the aeration conditions.     

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.