Studies related to antitumor antibiotics. Part IX. Reactions of carzinophillin with DNA assayed by ethidium fluorescence.

The reactions of the antitumor antibiotic carzinophillin (CZ) with native DNAs and synthetic polynucleotides have been examined by an ethidium fluorescence assay. CZ rapidly produces covalent linkage of the complementary strands of a variety of DNAs without activation. This process is accompanied by extensive alkylation, as detected by reduced fluorescence due to destruction of potential intercalation sites for ethidium. These processes which occur without loss of purine or pyrimidine bases show a preference for bonding to guanine groups (but not at the N-7 position). Examination of the reversibility of the cross-links suggests they involve one 'permanent' link to guanine and a second weaker linkage, possibly to a cytosine residue. Both cross-linking and alkylation show strong pH dependence and are favored at lower pH, suggesting that reactive sites on the antibiotic are basic. The addition of intercalating agents to DNA before treatment with CZ inhibits the cross-linking.     

竹红菌甲素敏化嘌呤和嘧啶碱的光氧化作用及其影响因素

本工作利用光吸收和高效液相色谱(HPLC)技术研究了甲素对DNA分子中四种碱基A、G、C和T光氧化的敏化作用,发现在反应体系的pH为9.0、甲素浓度为3×10~(-5)mol/L、光照40分钟时,G和T紫外吸收明显降低;HPLC分析发现甲素敏化的G光氧化体系比对照体系多出现一组分峰(滞留时间0.927分钟),该峰用475nm波长检测比260nm波长检测灵敏。根据反应机制推测是G环破裂产物。在反应条件固定时,甲素敏化G的光氧化作用受pH、光照时间及甲素浓度影响极大。单线态氧淬灭剂——叠氮钠浓度在40—110mmol/L可部分抑制甲素敏化G的光氧化作用,>110mmol/L时反应完全被阻断,提示甲素对G光氧化的敏化作用主要通过单线态氧(~1O_2)即Ⅱ型机制起作用。本文还讨论了G光氧化的可能途径。     

The nucleic acids of some insect viruses

Purine and pyrimidine bases have been estimated from the desoxyribonucleic acids of eleven insect viruses. Their proportions vary in the different species in a balanced way so that the molar ratios adenine:thymine and guanine:cytosine are constant and close to unity, whereas adenine + thymine:guanine + cytosine ranges from 0.71 to 1.87. This ratio is identical for some biologically dissimilar viruses, and no general parallelism is evident between DNA composition and biological relationship. Two different viruses from one host have distinct DNA's.     

Further characterization of a depurinated DNA-purine base insertion activity from cultured human fibroblasts.

The purification from cultured human fibroblasts of a protein that binds specifically to partially depurinated DNA and inserts purines into those sites is described. The purine insertion, but not the binding, requires K+. The DNA binding can be saturated with increasing apurinic sites and is weakened by the presence of adenine or guanine. Base insertion into depurinated DNA is specific for adenine or guanine; none is observed with dATP or dGTP. When the depurinated DNA substrate is specifically cleaved with apurinic endonuclease, no purine insertion occurs. Guanine insertion does not occur into tRNA or depyrimidinated DNA, and thymine is not inserted into either depyrimidinated DNA or depurinated DNA. Purine insertion activity follows Michaelis-Menten kinetics with respect to purintes; the apparent Km values for both adenine and guanine are 5 microM. The enzyme binds the purine bases very tightly. Adenine binding saturates at less than 1 microM adenine, perhaps reflecting the low intracellular adenine concentration. The binding protein specific for UV-irradiated DNA (Feldberg, R.S., and Grossman, L. (1976) Biochemistry 15, 2402-2408) had no detectable purine or pyrimidine base insertion activity with depurinated or depyrimidinated DNAs.     

The structure and application of oligodeoxyribonucleotides containing modified, degenerate bases.

Oligodeoxynucleotides containing modified pyrimidine bases which can stably hydrogen-bond to adenine and guanine and also purine bases which pair with thymine and cytosine residues in duplexes have been synthesised, as have oligomers with both such analogues. Structures have been investigated by melting transitions, n.m.r. spectroscopy and crystallography and then interpreted in terms of tautomeric equilibria. Applications to hybridisation probes and primers will be discussed.     

离子注入诱变莲花突变体分子机理的初步研究

低能离子注入技术作为生物物理诱变的一种新型技术, 在园艺植物育种方面具有很大的应用潜力, 但其诱变的分子机理目前知之甚少。文章对Fe+ 离子注入诱变的白洋淀红莲(Nelumbium speciosum Willd)突变体及其对照的基因组进行RAPD研究, 并将突变体和对照在辐射敏感位点的条带进行克隆测序及DNA序列分析。在已优化好的RAPD体系下扩增, 从110条随机引物中筛选出了10条可以稳定扩增出显著特异条带的引物, 引物多态性为9.09%。将这10条引物扩增出的辐射敏感位点的条带进行克隆测序, 并进行序列比对。结果显示: 突变体的总碱基突变频率为0.87%, 6个突变体的碱基突变频率存在着差异; 碱基突变类型包括碱基的颠换、转换、缺失、插入, 在检测到的159个碱基突变中, 单碱基置换的频率(61.01%)高于碱基插入或者缺失的频率(38.99%), 在碱基置换中, 转换的频率(44.65%)是颠换频率(16.35%)的2.7倍, 其中C/T之间的转换所占比例最大, A→G和A→T也具有较高的替换频率; 构成DNA的4种碱基均可以被离子束辐照诱变发生变异, 除了没有C→G的置换外, 每一种碱基都可以被其他的几种碱基所置换, 但是胸腺嘧啶(T)具有较高的辐射敏感性。通过对碱基突变位点周边序列的分析发现, 嘌呤突变位点的周围嘌呤碱居多, 嘧啶突变位点的周围嘧啶碱居多。研究结果为揭示低能离子注入诱变作用分子机理提供了依据。     

Hydroxyl radicals and DNA base damage

Modified purine and pyrimidine bases constitute one of the major classes of hydroxyl-radical-mediated DNA damage together with oligonucleotide strand breaks, DNA-protein cross-links and abasic sites. A comprehensive survey of the main available data on both structural and mechanistic aspects of.OH-induced decomposition pathways of both purine and pyrimidine bases of isolated DNA and model compounds is presented. In this respect, detailed information is provided on both thymine and guanine whereas data are not as complete for adenine and cytosine. The second part of the overview is dedicated to the formation of.OH-induced base lesions within cellular DNA and in vivo situations. Before addressing this major point, the main available methods aimed at singling out.OH-mediated base modifications are critically reviewed. Unfortunately, it is clear that the bulk of the chemical and biochemical assays with the exception of the high performance liquid chromatographic-electrochemical detection (HPLC/ECD) method have suffered from major drawbacks. This explains why there are only a few available accurate data concerning both the qualitative and quantitative aspects of the.OH-induced formation of base damage within cellular DNA. Therefore, major efforts should be devoted to the reassessment of the level of oxidative base damage in cellular DNA using appropriate assays including suitable conditions of DNA extraction.     

Structural characterization and corepressor binding of the Escherichia coli purine repressor.

The Escherichia coli purine repressor, PurR, binds to a 16-bp operator sequence and coregulates the genes for de novo synthesis of purine and pyrimidine nucleotides, formation of a one-carbon unit for biosynthesis, and deamination of cytosine. We have characterized the purified repressor. Chemical cross-linking indicates that PurR is dimeric. Each subunit has an N-terminal domain of 52 amino acids for DNA binding and a C-terminal 289-residue domain for corepressor binding. Each domain was isolated after cleavage by trypsin. Sites for dimer formation are present within the corepressor binding domain. The corepressors hypoxanthine and guanine bind cooperatively to distinct sites in each subunit. Competition experiments indicate that binding of one purine abolishes cooperativity and decreases the affinity and the binding of the second corepressor. Binding of each corepressor results in a conformation change in the corepressor binding domain that was detected by intrinsic fluorescence of three tryptophan residues. These experiments characterize PurR as a complex allosteric regulatory protein.     

Nitrite-induced deamination and hypochlorite-induced oxidation of DNA in intact human respiratory tract epithelial cells

No modification of purine or pyrimidine bases was observed when isolated DNA was incubated with 1 mM nitrite at pH 7.4. However, exposure of human bronchial epithelial cells in culture medium at pH 7.4 to nitrite at concentrations of 100 microM or greater led to deamination of purine bases in cellular DNA. Deamination was more extensive in cells exposed to lower extracellular pH values and higher nitrite concentrations. Significant increases in the levels of xanthine and hypoxanthine, putative deamination products of guanine and adenine, respectively, were observed in DNA from nitrite-treated cells but no rise in any base oxidation products such as 8-hydroxyguanine. This pattern of damage suggests that exposure of cells to nitrite (even at pH 7.4) leads to intracellular generation of "reactive nitrogen species" capable of deaminating purines in DNA. In addition, significant DNA strand breakage occurred in nitrite-treated cells. The time course of base damage suggested that the repair of deaminated purine lesions in these cells is slow. By contrast, DNA isolated from cells exposed to hypochlorous acid (HOCl) has significant oxidation of pyrimidine bases and chlorination of cytosine but little oxidation of purines. Exposure of cells to both species (NO(2)(-) plus HOCl) potentiated the oxidative DNA base damage observed but decreased the extent of deamination. We hypothesize that this is due to the formation of nitryl chloride (NO(2)Cl) from reaction of HOCl with *NO(2)(-). The relevance of our observations to events in the stomach and respiratory tract, at sites of inflammation, and in ischemic tissues is discussed.     

Photodynamic protein cross-linking

Exposure of spectrin to visible light in the presence of a photosensitizer results in photo-oxidation of sensitive amino acid residues and covalent cross-linking of the polypeptides. In a previous paper the cross-linking was ascribed to a secondary reaction between photo-oxidized histidine residues and amino groups. The following observations, described in this paper, are in accordance with this supposition. (1) During illumination of spectrin in the presence of a photosensitizer a pronounced photo-oxidation of histidine residues takes place. (2) Simultaneously a decrease of free amino groups is observed. (3) Semicarbazide protects against cross-linking and is bound to a histidine photo-oxidation product in spectrin. (4) The pH profile of histidine photo-oxidation and subsequent reaction with amino groups is similar to the pH profile of spectrin cross-linking. Amidination of NH₂ groups in spectrin does not inhibit cross-linking, as visualized by gel electrophoresis. On the other hand aminidation of denatured myoglobin causes a 50% inhibition of cross-linking. These observations support the notion of NH₂-involvement in cross-linking but also demonstrate, that other photodynamic cross-linking mechanisms exist.     

Specificity of DNA base release by bleomycin.

DNA was treated with bleomycin in the presence of Fe2+ and 2-mercaptoethanol under conditions where only a few percent of the bases were released. Release of all four bases was a linear function of bleomycin concentration, but the amount of thymine released was twice that of cytosine, 7 times that of adenine, and twelve times that of guanine. Unidentified minor products of thymine, of cytosine and of a purine were also released. Bromouracil did not sensitize DNA to bleomycin-induced breakage, and was released at the same rate as thymine.     

Pyrimidine scavenging by Mycobacterium leprae

Mycobacterium leprae incorporated exogenously supplied pyrimidines as bases or nucleosides, but not as a nucleotide, into its nucleic acids. Notably, thymine was incorporated approximately 5 times more rapidly than thymidine by both suspensions of, or intracellular M. leprae. Thymine incorporation was significantly inhibited by clofazamine and dapsone at near-pharmacological levels. Therefore, incorporation of thymine is preferable as an activity for assessing viability of M. leprae. Nucleosides were converted to nucleotides through kinases, bases through phosphoribosyltransferases. Alternatively, thymine and uracil could first be converted to nucleosides. Cytosine and uracil bases were interconvertible, and uracil alone could supply all the pyrimidine requirements of M. leprae, though conversion to the thymine base was extremely slow. Overall, pyrimidine scavenging occurs at a slower rate than, and appears not to be so important as purine scavenging in M. leprae.     

Determination of ribonucleosides,deoxyribonucleosides, and purine and pyrimidine bases in adult rabbit cerebrospinal fluid and plasma

Purine and pyrimidine base and nucleoside levels were measured in adult rabbit cisternal CSF and plasma by reversed-phase high-performance liquid chromatography. The concentrations of bases, nucleosides, and nucleoside phosphates were similar in plasma and CSF except for the adenosine phosphates and uracil which were higher in the plasma. In plasma and CSF, adenosine levels were low (0.12 microM) and guanosine, deoxyadenosine, deoxyguanosine, and deoxyinosine were not detectable (less than 0.1 microM); inosine and xanthine concentrations were 1-2 microM and hypoxanthine concentrations were approximately 5 microM; uridine (approximately 8 microM), cytidine (2-3 microM), and thymidine, deoxyuridine, and deoxycytidine (0.5-1.4 microM) were easily detectable. In both plasma and CSF, guanine, and thymine were undetectable (less than 0.1 microM), adenine and cytosine were less than 0.2 microM, but uracil was present (greater than 1 microM). Adenosine, inosine, and guanosine phosphates were also detectable at low concentrations in CSF and plasma. These results are consistent with the hypothesis that purine deoxyribonucleosides are synthesized in situ in the adult rabbit brain. In contrast, pyrimidine deoxyribonucleosides and ribonucleosides, and purine and pyrimidine bases are available in the CSF for use by the brain.     

Iron requirement of Lactobacillus spp. in completely chemically defined growth media

A completely chemically-defined growth medium, containing guanine, thymine, cytidine, 2'-deoxyadenosine and 2'-deoxyuridine as DNA precursors, was developed for Lactobacillus johnsonii, on the basis of statistically designed techniques suitable for other lactobacilli. Particular focus was given to the nucleotide composition of different defined media, and to the specific nucleotide requirements of Lact. johnsonii. Most of the lactobacilli tested grew in a medium containing five free bases, four ribonucleosides or five deoxyribonucleosides. Adenine and guanine were replaceable by inosine. The requirement for thymine and cytosine was satisfied with uracil. The presence of inosine and uracil was identified as being essential for the growth of different Lactobacillus species, displaying their inability to synthesize purines and pyrimidines de novo. Defined recipes with different nucleotide composition were used to investigate iron requirements of lactobacilli. Only marginal differences in growth were observed in iron-depleted media supplemented with five free bases, four ribonucleosides or five deoxyribonucleosides; iron depletion had a greater effect on growth when inosine and uracil were supplied as the only nucleotide sources. The results suggest that iron plays a role in the pyrimidine and purine metabolism of lactobacilli. Lactobacillus spp., particularly Lact. johnsonii, require iron under particular environmental conditions with limited or specific nucleotide sources.     

Binding of enantiomers of trans-7,8-dihydroxy-anti-9,10-epoxy-7,8,9,10-tetrahydro-benzo[a]pyrene to polynucleotides

DNA covalent binding studies with enantiomers of trans-7,8-dihydroxy- anti-9,10-epoxy-7,8,9,10-tetrahydro-benzo[a]pyrene (anti-BPDE) have been carried out by means of spectroscopic techniques (UV, CD, and fluorescence). Synthetic polynucleotides are employed to investigate binding differences between the G.C and A.T base pairs and to elucidate the bases for the stereoselective covalent binding of DNA toward anti-BPDE. The results indicate that of all the polynucleotides studied, only poly(dA-dT).poly(dA-dT) exhibits predominant intercalative covalent binding towards (+)-anti-BPDE and suffers the least covalent modification. Only minor intercalative covalent contributions are found in alternating polymer poly(dA-dC).poly(dG-dT). These observations parallel the DNA physical binding results of anti-BPDE and its hydrolysis products. They support the hypothesis that intercalative covalent adducts derive from intercalative physical binding while the external covalent adducts derive from external bimolecular associations. In contrast to the A.T polymers, the guanine containing polymers exhibit pronounced reduction in covalent modification by (-)-anti-BPDE. The intercalative covalent binding mode becomes relatively more important in the adducts formed by the (-) enantiomer as a consequence of decreased external guanine binding. These findings are consistent with the guanine specificity, stereoselective covalent binding at dG, the absence of stereoselectivity at dA for anti-BPDE, and the enhanced binding heterogeneity for the (-) enantiomer as found in the native DNA studies. The possible sequence and/or conformational dependence of such stereoselective covalent binding is indicated by the opposite pyrenyl CD sign exhibited by (+)-anti-BPDE bound to polynucleotides with pyrimidine on one strand and purine on another vs. that bound to polymers containing alternating purine-pyrimidine sequences.     

Structural, energetic and dynamic properties of guanine(C8)-thymine(N3) cross-links in DNA provide insights on susceptibility to nucleotide excision repair

The one-electron oxidation of guanine in DNA by carbonate radical anions, a decomposition product of peroxynitrosocarbonate which is associated with the inflammatory response, can lead to the formation of intrastrand cross-links between guanine and thymine bases [Crean et al. (Oxidation of single-stranded oligonucleotides by carbonate radical anions: generating intrastrand cross-links between guanine and thymine bases separated by cytosines. Nucleic Acids Res. 2008; 36: 742-755.)]. These involve covalent bonds between the C8 positions of guanine (G*) and N3 of thymine (T*) in 5'-d(…G*pT*…) and 5'-d(…G*pCpT*…) sequence contexts. We have performed nucleotide excision repair (NER) experiments in human HeLa cell extracts which show that the G*CT* intrastrand cross-link is excised with approximately four times greater efficiency than the G*T* cross-link embedded in 135-mer DNA duplexes. In addition, thermal melting studies reveal that both lesions significantly destabilize duplex DNA, and that the destabilization induced by the G*CT* cross-link is considerably greater. Consistent with this difference in NER, our computations show that both lesions dynamically distort and destabilize duplex DNA. They disturb Watson-Crick base-pairing and base-stacking interactions, and cause untwisting and minor groove opening. These structural perturbations are much more pronounced in the G*CT* than in the G*T* cross-link. Our combined experimental and computational studies provide structural and thermodynamic understanding of the features of the damaged duplexes that produce the most robust NER response.     

Binding of Enantiomers of Trans-7, 8-dihydroxy-anti-9,10-epoxy-7,8,9,10- tetrahydro-benzo [a]pyrene to Polynucleotides

Abstract

DNA covalent binding studies with enantiomers of trans-7,8-dihydroxy- anti-9,10-epoxy- 7,8,9,10-tetrahydro-benzo [a] pyrene (anti-BPDE) have been carried out by means of spectroscopic techniques (UV, CD, and fluorescence). Synthetic polynucleotides are employed to investigate binding differences between the G · C and A · T base pairs and to elucidate the bases for the stereoselective covalent binding of DNA toward anti-BPDE. The results indicate that of all the polynucleotides studied, only poly(dA-dT) · poly(dA-dT) exhibits predominant intercalative covalent binding towards (+)-anti-BPDE and suffers the least covalent modification. Only minor intercalative covalent contributions are found in alternating polymer poly(dA-dC) · poly(dG-dT). These observations parallel the DNA physical binding results of anti-BPDE and its hydrolysis products. They support the hypothesis that intercalative covalent adducts derive from intercalative physical binding while the external covalent adducts derive from external bimolecular associations. In contrast to the A · T polymers, the guanine containing polymers exhibit pronounced reduction in covalent modification by (-)-anti-BPDE. The intercalative covalent binding mode becomes relatively more important in the adducts formed by the (-) enantiomer as a consequence of decreased external guanine binding. These findings are consistent with the guanine specificity, stereoselective covalent binding at dG, the absence of stereoselectivity at dA for anti-BPDE, and the enhanced binding heterogeneity for the (-) enantiomer as found in the native DNA studies. The possible sequence and/or conformational dependence of such stereoselective covalent binding is indicated by the opposite pyrenyl CD sign exhibited by (+)-anti-BPDE bound to polynucleotides with pyrimidine on one strand and purine on another vs. that bound to polymers containing alternating purine-pyrimidine sequences.     

A silver stain for the rapid quantitative detection of proteins or nucleic acids on membranes or thin layer plates

A relatively simple silver stain which takes less than 15 min to perform has been developed for the detection of nanogram quantities of proteins and DNA on cellulose membranes and thin layer plates. This stain demonstrates a reproducible curvilinear relationship between silver density and the amount of protein or DNA, over an averaged concentration range from 1 to 300 ng for proteins and 10 to 710 ng for DNA. The ease of staining proteins and DNA on membranes, combined with the stain's sensitivity and reproducibility, permits the use of this procedure for the quantitative determination of nanogram amounts of proteins and DNA. The simplicity of this silver stain has also permitted a survey of the staining properties of individual amino acids, purine and pyrimidine bases, nucleosides, nucleotides, homopolymers, and small peptides of known sequence. This survey demonstrated the importance of the basic amino acids, particularly lysine and histidine, and the sulfur-containing amino acids in the detection of proteins. It also indicated that the purine bases may play an important role in the detection of DNA.     

Inhibition of enzymic incision of thymine dimers by covalently bound 2-[N-[(deoxyguanosin-8-yl)acetyl]amino]fluorene in deoxyribonucleic acid

The effects of DNA adducts of the carcinogen 2-[N-(acetoxyacetyl)amino]fluorene on enzymic incision of thymine dimers was investigated. Escherichia coli DNA labeled with [3H]thymidine was reacted with the carcinogen. Thymine dimers were then introduced into the modified DNA by irradiation with monochromatic 254-nm light in the presence of the photosensitizer silver nitrate. This DNA containing both types of damages, mainly 2-[N-[(deoxyguanosin-8-yl)acetyl]fluorene and thymine dimers, was then used as substrate for pyrimidine dimer-DNA glycosylase, purified from E. coli infected by bacteriophage T4. Activity was assayed by measuring release of free labeled thymine after photoreversal of the enzyme-reacted DNA by 254-nm light. The Vmax of the enzyme was decreased when it was reacted with the extensively arylamidated substrate. This inhibition of incision of pyrimidine dimers was increased with the number of carcinogen-DNA adducts, although no enzymic activity against modified guanines was present. Therefore, carcinogen-modified purine moieties can interfere with initiation of excision repair of ultraviolet-induced pyrimidine dimers. This suggests an indirect pathway by which modified DNA bases can be mutagenic.     

Oxidative DNA damage photo-induced by 3-carbethoxypsoralen and other furocoumarins. Mechanisms of photo-oxidation and recognition by repair enzymes

DNA photosensitization by several furocoumarins (including 3-carbethoxypsoralen (3-CPs), 8-methoxypsoralen (8-MOP), 5-methoxypsoralen (5-MOP) and angelicin was investigated by using DNA sequencing methodology. 3-CPs induces photo-oxidation of guanine residues leading to alkali-labile sites in DNA (revealed by hot piperidine), whereas 8-MOP, 5-MOP and angelicin do not. There is a preferential photo-oxidation of G when located on the 5' side of GG doublets, likely to reflect a better accessibility of the G moiety in such a context. Mechanisms operating via both radicals (type I) and singlet oxygen (type II) are involved in the photo-oxidation of G residues by 3-CPs. Photo-oxidized G residues are produced independently of the formation of photoadducts, and scavengers of singlet oxygen or radicals do not inhibit photobinding of 3-CPs to DNA. This leads us to propose that covalent photoadducts arise from the intercalated excited sensitizer molecules, whereas G photo-oxidations are produced either by electron transfer reactions involving bound 3-CPs or by energy transfer to molecular oxygen, thereby producing singlet oxygen that subsequently reacts with guanine bases. Quantification of both types of DNA lesions indicated that in vitro photo-oxidized G residues are produced in DNA by 3-CPs plus ultraviolet light at least to the same extent as photoadducts, under our conditions. A calf thymus redoxyendonuclease, equivalent to the endonuclease III of Escherichia coli, specific for oxidative DNA damages, recognizes and cleaves DNA at sites of photo-oxidized G residues. The extent of the cleavage by this enzyme was close to that observed by hot piperidine and followed the amount of photo-oxidized G residues produced when the lifetime of excited oxygen species is modified. The redoxyendonuclease did not incise DNA treated with 8-MOP, 5-MOP or angelicin plus ultraviolet light. The exonuclease III and endonuclease IV of E. coli also involved in the repair of oxidative DNA damage, convert the replicative form I of 3-CPs-treated DNA to replicative form II. This suggests that the lesions recognized by these enzymes are apurinic-like lesions. In view of the low toxicity and mutagenicity of 3-CPs, DNA photo-oxidation products induced by the photodynamic effect of 3-CPs are likely to be efficiently taken care of by the DNA repair system(s). It is clear that 3-CPs photo-induces several classes of DNA damage, including oxidative damage.(ABSTRACT TRUNCATED AT 400 WORDS)