Effect of the amine non-leaving group on the structure and stability of DNA complexes with cis-[Pt(R-NH2)2(NO3)2]

The antitumor compound cis-[Pt(NH3)2Cl2] (cisplatin), conserves two ammine ligands during the reaction with its cellular target DNA. Modifications of these non-leaving groups change the antineoplastic properties of this compound and its genotoxic effects. It is therefore of interest to determine the influence of non-leaving groups on the structure and stability of DNA in vitro. We have investigated platinum-DNA adducts formed by cis-[Pt(R-NH2)2(NO3)2] (where R-NH2 = NH3, methylamine, cyclobutylamine, cyclopentylamine and cyclohexylamine) as a function of DNA binding. All compounds quantitatively reacted with DNA in less than 1 h at 37 degrees C. They formed bifunctional adducts with adjacent nucleotides judging from the displacement of the intercalating molecule ethidium bromide, ultraviolet absorption spectroscopy and circular dichroism. Substitution of a H on the NH3 ligand by alkyl groups dramatically destabilized the platinum-DNA complex. Thermal stability decreased progressively with an increasing number of carbon atoms, delta tm = -4.4 degrees C for 3 cyclohexylamine-platinum-DNA adducts/1000 nucleotides, conditions where cisplatin had no effect. DNA adducts with cyclobutylamine and cyclohexylamine ligands inhibited the hydrolysis of platinum-DNA complexes by S1 nuclease. Km for the digestion of DNA containing these lesions was 2.3 times greater than for cisplatin, indicating steric inhibition of enzyme-substrate complex formation. These results show that the non-leaving groups of substituted cis-Pt(II) compounds may destabilize DNA and interfere with protein-DNA interactions. These perturbations may have consequences for the genotoxic and antitumor activities of platinum compounds.     

Biophysical studies of the modification of DNA by antitumour platinum coordination complexes

Cisplatin (cis-diamminedichloroplatinum(II] is widely used in the treatment of various human tumours. A large body of experimental evidence indicates that the reaction of cisplatin with DNA is responsible for the cytostatic action of this drug. Several platinum-DNA adducts have been identified and their effect on the conformation of DNA has been investigated. Structural studies of platinum-DNA adducts now permit a reasonably good explanation of the biophysical properties of platinated DNA. Antitumouractive platinum compounds induce in DNA, at low levels of binding, local conformational alterations which have the character of non-denaturing distortions. It is likely that these changes occur in DNA due to the formation of intrastrand cross-links between two adjacent purine residues. On the other hand, the modification of DNA by antitumour-inactive complexes results in the formation of more severe local denaturation changes. Conformational alterations induced in DNA by antitumour-active platinum compounds may be reparable with greater difficulty than those induced by the inactive complexes. Alternatively, non-denaturation change induced in DNA by antitumour platinum drugs could represent more significant steric hindrance against DNA replication as compared with inactive complexes.     

Partial purification and properties of an endonuclease from germinating pea seeds specific for single-stranded DNA.

An enzyme that rapidly catalyzes the hydrolysis of denatured DNA has been partially purified from germinated pea (Pisum sativum) seeds. The nuclease has been characterised as having endonucleolytic activity degrading single stranded DNA at a 15- to 20-fold higher rate than native DNA. From exclusion chromatography on Sephadex G-200 the molecular weight of the enzyme was calculated to be 42,000. The small extent of hydrolysis of native DNA is suggested to be due to the degradation of partially denatured areas in the native molecule. The enzyme shows activity over a broad range of pH but was most active between pH 6.5 and 8.0. The maximum hydrolysis of denatured DNA was observed at 45 °C while with native DNA the temperature optima was 60 °C. The nuclease does not show an absolute requirement for added divalent cations. However, the addition of Mg²⁺ and Ca²⁺ results in 40 and 60% stimulation, respectively. EDTA has no effect on enzymatic activity, whereas 8-hydroxyquinoline was inhibitory.     

Modification of deoxyribonucleic acid by a diol epoxide of benzo[a]pyrene. Relation to deoxyribonucleic acid structure and conformation and effects on transfectional activity.

The effects of secondary structure on DNA modification by (+/-)-7 beta, 9 alpha-dihydroxy-9 alpha, 10 alpha-epoxy-7,8,9,10-tetrahydrobenzol[a]pyrene [(+/-)BPDE I] were investigated. No differences in the total extent of (+/-) BPDE I binding to double- and single-stranded calf thymus DNA were found. High-performance liquid chromatography (LC) of the nucleoside adducts obtained from hydrolysates of native and denatured calf thymus, as well as from superhelical and linear plasmid DNA, indicated that in all cases the major adduct (60--80% of total adducts) was formed by reaction of the (+) enantiomer of BPDE I with the N-2 position of dG residues in the DNA. A minor adduct formed from the reaction of the (-) enantiomer with dG residues was also detected and was present in greater amounts in denautred DNA than in native DNA. Small amounts of BPDE I--dA and BPDE I--dC adducts were also detected in both the single- and double-stranded DNAs. Restriction enzyme analysis of BPDE I modified SV40 and phage lambda DNA provided evidence that the modification of DNA by this carcinogen is fairly random with respect to nucleotide sequence. Partial hydrolysis of modified plasmid DNA by the single-strand-specific S1 nuclease and LC analysis of the nucleoside adducts in the digested and undigested fractions of the DNA revealed no preferential excision by the S1 nuclease of the different BPDE I--deoxynucleoside adducts. Functional changes in BPDE I modified DNA were demonstrated. With increasing extents of modification, there was a decrease in the ability of plasmid DNA to transfect a receptive Escherichia coli strain to antibiotic resistance.     

Nucleotide excision repair from site-specifically platinum-modified nucleosomes

Nucleotide excision repair is a major cellular defense mechanism against the toxic effects of the anticancer drug cisplatin and other platinum-based chemotherapeutic agents. In this study, mononucleosomes were prepared containing either a site-specific cis-diammineplatinum(II)-DNA intrastrand d(GpG) or a d(GpTpG) cross-link. The ability of the histone core to modulate the excision of these defined platinum adducts was investigated as a model for exploring the cellular response to platinum-DNA adducts in chromatin. Comparison of the extent of repair by mammalian cell extracts of free and nucleosomal DNA containing the same platinum-DNA adduct reveals that the nucleosome significantly inhibits nucleotide excision repair. With the GTG-Pt DNA substrate, the nucleosome inhibits excision to about 10% of the level observed with free DNA, whereas with the less efficient GG-Pt DNA substrate the nucleosome inhibited excision to about 30% of the level observed with free DNA. The effects of post-translational modification of histones on excision of platinum damage from nucleosomes were investigated by comparing native and recombinant nucleosomes containing the same intrastrand d(GpTpG) cross-link. Excision from native nucleosomal DNA is approximately 2-fold higher than the level observed with recombinant material. This result reveals that post-translational modification of histones can modulate nucleotide excision repair from damaged chromatin. The in vitro system established in this study will facilitate the investigation of platinum-DNA damage by DNA repair processes and help elucidate the role of specific post-translational modification in NER of platinum-DNA adducts at the physiologically relevant nucleosome level.     

Conversion of monofunctional DNA adducts of cis-diamminedichloroplatinum (II) to bifunctional lesions. Effect on the in vitro replication of single-stranded DNA by Escherichia coli DNA polymerase I and eukaryotic DNA polymerases alpha

Reaction of cis-diamminedichloroplatinum (II) with single-stranded M13 phage DNA in vitro produced monofunctional platinum-DNA adducts on guanine and bifunctional lesions with either two guanine bases (GG) or one adenine and one guanine (AG). When DNA containing a majority of monofunctional platinum-DNA lesions was dialyzed against 10 mM NaCIO4 at 37 degrees C, conversion of monoadducts to bifunctional lesions was observed. We examined the effect of post-treatment formation of bifunctional lesions on DNA synthesis by Escherichia coli DNA polymerase I and highly purified eukaryotic DNA polymerase alpha from Drosophila melanogaster and calf thymus. Arrest sites on the platinated template were determined by polyacrylamide gel electrophoresis. Monofunctional lesions did not appear to block DNA synthesis. Inhibition of replication increased as bifunctional platinum-DNA lesions formed during post-treatment incubation; GG adducts inhibited replication more than AG. These results suggest that bifunctional GG platinum-DNA adducts may be the major toxic damage of cisplatin.     

Caffeine enhancement of digestion of DNA by nuclease S1.

The activity of Aspergillus orzae nuclease S1 on DNA has been investigated under varying pH and metal ion conditions. Nuclease S1 was found to preferentially digest denatured DNA. With native DNA as substrate the enzyme could only digest the DNA when caffeine was added to the reaction mixture. The enzyme was more active in sodium acetate buffer (pH 4.5), than in either standard saline citrate (PH 7.0) or sodium phosphate buffer (pH 6.8). Caffeine was also found to affect the thermal stability of DNA, resulting in a melting profile characterized by two transitions. The first transition (poorly defined) was below the normal melting temperature of the DNA, while the next transition was at the normal melting temperature of the DNA, while the next transition was at the normal melting temperature of the DNA. The susceptibility of caffeine-treated DNA to nuclease digestion seems to be a result of the local unwinding that caffeine causes in the regions of DNA that melt in the first transition. This selective destabilization presumably sensitizes the unwound regions to nuclease hydrolysis. The hydrolysates of the DNA digested by nuclease S1 were subjected first to ion exchange chromatography followed by paper chromatography. The results from this partial characterization of the digestion products showed that they contain mononucleotides as well as oligonucleotides of varying lengths. The base composition of the mononucleotide digests suggests that caffeine has greater preference for interacting with A-T base-pairs in DNA.     

Detection of platinum-DNA adducts by 32P-postlabelling.

We developed a sensitive 32P-postlabeling method for the detection of bifunctional intrastrand crosslinks d(Pt-GpG) and d(Pt-ApG) in DNA in vitro and in vivo. After enzymatic digestion of DNA the positively charged platinum adducts were purified from unplatinated products, using strong cation exchange chromatography. Subsequently the samples were deplatinated with cyanide, because platinated dinucleotides are very poor substrates for polynucleotide kinase. The excess of cyanide was removed using Sep-pak C18 cartridges, and the resulting dinucleoside monophosphates d(GpG) and d(ApG) were subsequently postlabelled. Analysis of the postlabelling mixture was performed by a combined TLC and HPLC-procedure. Good correlations with existing methods (AAS, immunocytochemistry and ELISA) were found in DNA samples treated in vitro and in vivo with cis- or carboplatin. The detection limit of the assay was 1 adduct/10(7) nucleotides in a 10 micrograms DNA sample.     

Parameters influencing the flow cytometric analysis of DNA sensitivity to nuclease S1

Some parameters that influence the analysis in situ of DNA sensitivity to digestion with nuclease S1 have been studied in isolated HeLa nuclei with flow cytometry. DNA staining with the intercalating fluorochrome propidium iodide allowed the nucleolytic activity on double-stranded (ds) DNA to be determined by monitoring the relative reduction in nuclear fluorescence intensity. Nuclei isolated in buffer at low ionic strength in order to decondense chromatin fibres, showed a lower fluorescence intensity than nuclei with native chromatin, after digestion with nuclease S1 under identical conditions. Nuclei prepared with dispersed chromatin and digested with increasing amounts of enzyme showed a decrease in fluorescence intensity that reached a limit value at about 50% of the value of undigested control samples. On the other hand, in nuclei with native chromatin, fluorescence intensity decreased only about 18%. The NaCl concentration in the reaction buffer strongly influenced the DNA sensitivity to S1 nuclease. By increasing salt molarity from 5 mM to 200 mM, the digestion of dsDNA was significantly reduced as also shown by the amount of released nucleotides from purified calf thymus DNA. The detection of DNA sensitivity to nuclease S1, as assessed by the cytometric method, was shown to be more sensitive than a biochemical technique involving hydrolysis of purines. These results indicate that both the procedure for nuclei isolation and the digestion conditions have to be carefully controlled when evaluating in situ the presence of S1-sensitive sites.     

Effect of riboflavin and light on the secondary structure of DNA

S1 nuclease hydrolysis and benzoylated naphthoylated DEAE cellulose (BND-cellulose) chromatography have been used to study the effect of riboflavin and visible light on DNA. Native calf thymus DNA was incubated with riboflavin in the presence of fluorescent light for various time periods and subjected to S1 nuclease hydrolysis. An increasing degree of DNA degradation was seen suggesting a destabilization of the secondary structure. A decrease in melting temperature was also observed. Incubation with riboflavin and illumination caused adherence to BND-cellulose indicating the production of single stranded regions or breaks in the native double stranded molecules. However, when incubation was done in dark and in the presence of triplet excited state quencher, potassium iodide, a reduced adherence of DNA to BND-cellulose was seen. Plasmid pBR322 DNA was also treated with riboflavin under these conditions and subjected to agarose gel electrophoresis. No degradation could be seen in dark incubated and potassium iodide treated samples. These results indicate that the adherence of DNA to BND-cellulose in dark is possibly due to the binding of aromatic residues to the resin suggesting the formation of a complex between riboflavin and DNA.     

Purification and characterization of a DNA-dependent ATPase from Bacillus cereus

A DNA-dependent ATPase (molecular weight 71 000) free of nuclease activity has been purified from Bacillus cereus. The enzyme shows similar characteristics as the enzyme isolated from Escherichia coli and Bacillus subtilis. Heat denatured DNA stimulates the rate of ATP hydrolysis to ADP and Pi to an extent about tenfold higher than the native DNA. Double stranded DNA without single stranded regions is not a suitable cofactor for the enzyme. The ATPase is inhibited by adenosine 5'-(beta, gamma-imino)-diphosphate, while another ATP analogue, adenosine 5'-(beta, gamma-methylene)-diphosphate has no effect on ATPase activity. KM for ATP is 0.38 mM, the apparent KM for nucleotide equivalent DNA is 1.2 microM. Evidence of the unwinding function of the enzyme is presented.     

Osmium-induced alteration in DNA structure

In the presence of pyridine and other ligands osmium tetroxide binds covalently to pyrimidine bases in DNA. Properties of osmium-modified native and denatured calf thymus DNA, and plasmid Co1E1 DNA were investigated by means of differential pulse polarography, absorption spectrophotometry, circular dichroism, agarose gel electrophoresis, and nuclease S1 digestion. A great difference in the reaction kinetics of native and denatured DNAs with osmium, pyridine was observed. On the ground of the slow stepwise reaction kinetics of native DNA in the initial stage of its modification by osmium it has been suggested that the primary reaction sites do not include bases contained in the intact double helix. Osmium binding to sporadic primary reaction sites (represented e.g. by bases in the vicinity of a single-strand break) in native calf thymus DNA resulted in local changes in DNA conformation limited to a close neighbourhood of the binding site. At higher osmium/nucleotide ratios disordering of the DNA structure over a region extending beyond the immediate binding site was observed. With denatured DNA the same type of structure disordering was detected already in the initial stage of the reaction at osmium/nucleotide ratios as low as 0.01. Osmium binding to the supercoiled Co1E1 DNA resulted in its relaxation without nicking and it increased its sensitivity to linearization by cleavage with nuclease S1. The behaviour of Co1E1 DNA has been explained by the formation of a denatured region in the molecule (accompanied by a coupled loss of duplex and superhelical turns). It has been suggested that osmium can be used to label and to visualize distorted regions in the DNA double helix.     

Parameters influencing the flow cytometric analysis of DNA sensitivity to nuclease S1

Summary Some parameters that influence the analysis in situ of DNA sensitivity to digestion with nuclease S1 have been studied in isolated HeLa nuclei with flow cytometry. DNA staining with the intercalating fluorochrome propidium iodide allowed the nucleolytic activity on double-stranded (ds) DNA to be determined by monitoring the relative reduction in nuclear fluorescence intensity. Nuclei isolated in buffer at low ionic strength in order to decondense chromatin fibres, showed a lower fluorescence intensity than nuclei with native chromatin, after digestion with nuclease S1 under identical conditions. Nuclei prepared with dispersed chromatin and digested with increasing amounts of enzyme showed a decrease in fluorescence intensity that reached a limit value at about 50% of the value of undigested control samples. On the other hand, in nuclei with native chromatin, fluorescence intensity decreased only about 18%. The NaCl concentration in the reaction buffer strongly influenced the DNA sensitivity to S1 nuclease. By increasing salt molarity from 5 mM to 200 mM, the digestion of dsDNA was significantly reduced as also shown by the amount of released nucleotides from purified calf thymus DNA. The detection of DNA sensitivity to nuclease S1, as assessed by the cytometric method, was shown to be more sensitive than a biochemical technique involving hydrolysis of purines. These results indicate that both the procedure for nuclei isolation and the digestion conditions have to be carefully controlled when evaluating in situ the presence of S1-sensitive sites.     

Isolation of foldback DNA utilizing nuclease S1 digestion in aqueous dioxane.

An improved method for the isolation of the inverted repetitive (foldback) sequences present in mammalian DNAs is described. It makes use of the new observation that nuclease S1 digestion of denatured DNA occurred at a faster rate and was more extensive in medium containing dioxane. The temperature-absorbance characteristics of nuclease S1-resistant DNA were systematically studied as a function of the temperature employed during the step of enzymic hydrolysis. Specimens of human placental and calf thymus DNA which had been denatured and renatured to C₀t ≤ 10^?3 mol s liter^?1 were used as substrates. Foldback DNA was isolated from the enzymic digests by means of hydroxylapatite chromatography. Temperature-absorbance studies showed the enzyme-resistant DNA had a high degree of thermal stability; the hyperchromic rises equaled those obtained in the native speciments. The amount of foldback DNA which could be obtained was not influenced by the fragment size of the starting material, above a certain molecular weight range. Foldback DNA represented about 4% of the human genome and at least 5% of the bovine genome. The size distributions of these strands were studied by means of polyacrylamide gel electrophoresis.     

Interaction of metallothionein-2 with platinum-modified 5'-guanosine monophosphate and DNA

Human metallothioneins (MTs), a family of cysteine- and metal-rich metalloproteins, play an important role in the acquired resistance to platinum drugs. MTs occur in the cytosol and the nucleus of the cells and sequester platinum drugs through interaction with their zinc-thiolate clusters. Herein, we investigate the ability of human Zn 7MT-2 to form DNA-Pt-MT cross-links using the cisplatin- and transplatin-modified plasmid DNA pSP73. Immunochemical analysis of MT-2 showed that the monofunctional platinum-DNA adducts formed DNA- cis/ trans-Pt-MT cross-links and that platinated MT-2 was released from the DNA- trans-Pt-MT cross-links with time. The DNA- cis/ trans-Pt-MT cross-links were also formed in the presence of 2 mM glutathione, a strong S-donor ligand. Independently, we used 5'-guanosine monophosphate (5'-GMP) platinated at the N7 position as a model of monofunctional platinum-DNA adducts. Comparison of reaction kinetics revealed that the formation of ternary complexes between Zn 7MT-2 and cis-Pt-GMP was faster than that of the trans isomer. The analysis of the reaction products with time showed that while the formation of ternary GMP- trans-Pt-MT complex(es) is accompanied by 5'-GMP release, a stable ternary GMP- cis-Pt-MT complex is formed. In the latter complex, a fast initial formation of two Pt-S bonds was followed by a slow formation of an additional Pt-S bond yielding an unusual Pt(II)S 3N coordination with N7-GMP as the only N-donor ligand. The ejection of negligible zinc from the zinc-thiolate clusters implies the initial formation of Zn-(mu-SCys)-Pt bridges involving the terminal thiolate ligands. The biological implications of these studies are discussed.     

Preliminary characterization of chelation-sensitive nucleoprotein particles

Nucleoprotein particles (B2), isolated following digestion of calf thymus chromatin with micrococcal nuclease, are resolved on a non-chelating Bio-Gel A-5m column. B2 protein electrophoresis showed the presence of several H1 species and several nonhistone proteins but was depleted in core histones. DNA electrophoresis demonstrated that native B2 DNA has a length of about 46 base pairs. On DNA sequencing gels, the length distribution of denatured B2 DNA ranged from 12 to 35 bases with a weighted average chain length of about 26 bases. Depletion of a 20 base band in B2 DNA suggested specific protection of internucleosomal DNA sites during the nuclease digestion.     

Secondary structure in heterogeneous nuclear RNA: involvement of regions from repeated DNA sites

Heterogeneous nuclear RNA was found to contain regions of secondary structure based on a relative resistance to nuclease treatment compared with mRNA or poliovirus RNA and a shift in density toward double-stranded RNA early in the course of nuclease digestion. The regions involved in this secondary structure are enriched for RNA segments transcribed from repeated sites in the DNA. Thus, to maximize hybridization to repetitive sites heterogeneous nuclear RNA molecules must be both denatured and fragmented. Some of the self-complementary regions in heterogeneous nuclear RNA are released by alkali denaturation and fragmentation below 1500 nucleotides but maximum release is not achieved until fragmentation below 500 nucleotides. These results indicate that these self-complementary regions (“loops” plus “stems”) are mainly below 500 nucleotides in length.     

Mechanistic studies of the modulation of cleavage activity of topoisomerase I by DNA adducts of mono- and bi-functional PtII complexes

Using electrophoresis and replication mapping, we show that the presence of DNA adducts of bifunctional antitumor cisplatin or monodentate [PtCl(dien)]Cl (dien = diethylenetriamine) in the substrate DNA inhibits eukaryotic topoisomerase 1 (top1) action, the adducts of cisplatin being more effective. The presence of camptothecin in the samples of platinated DNA markedly enhances effects of Pt–DNA adducts on top1 activity. Interestingly, the effects of Pt–DNA adducts on the catalytic activity of top1 in the presence of camptothecin differ depending on the sequence context. A multiple metallation of the short nucleotide sequences on the scissile strand, immediately downstream of the cleavage site impedes the cleavage by top1. On the other hand, DNA cleavage by top1 at some cleavage sites which were not platinated in their close proximity is notably enhanced as a consequence of global platination of DNA. We suggest that this enhancement of DNA cleavage by top1 may consist in its inability to bind to other cleavage sites platinated in their close neighborhood; thus, more molecules of top1 may become available for cleavage at the sites where top1 normally cleaves and where platination does not interfere.     

Effect of alkylation on the secondary structure of DNA

S1 nuclease hydrolysis and bezoylated naphthoylated DEAE-cellulose (BND-cellulose) chromatography have been used to demonstrate that alkylation of DNA by dimethyl sulfate at neutral pH leads to the production of partially denatured molecules under conditions where no significant depurination occurs. DNA was alkylated with increasing concentrations of the alkylating agent, and subjected to enzymatic degradation and binding to BND cellulose. An increasing degree of DNA hydrolysis and adherence to BND cellulose was seen. On hydroxyapatite chromatography the alkylated DNA still eluted at the position of double-stranded molecules suggesting the presence of partially denatured regions. The presence of salt had a preventive effect on such denaturation.