Investigations into the sequence-selective binding of mithramycin and related ligands to DNA.

The preferred binding sites for mithramycin on four different DNA fragments have been investigated by DNAase I footprinting. Sites containing at least two contiguous GC base pairs are protected by the antibiotic, the preferred binding site consisting of the dinucleotide step GpG (or CpC). Related antibiotics chromomycin and olivomycin produce similar, but not identical footprinting patterns suggesting that they can recognize other sequences as well. All three antibiotics induce enhanced rates of enzyme cleavage at regions flanking some of their binding sites. These effects are generally observed in runs of A and T and are attributed to DNA structural variations induced in the vicinity of the ligand binding site. The reaction of dimethylsulphate with N7 of guanine was modified by the presence of mithramycin so that we cannot exclude the possibility that these antibiotics bind to DNA via the major groove.     

Cleavage of DNA with methidiumpropyl-EDTA-iron(II): reaction conditions and product analyses

The synthesis of methidiumpropyl-EDTA (MPE) is described. The binding affinities of MPE, MPE.Ni(II), and MPE.Mg(II) to calf thymus DNA are 2.4 X 10(4) M-1, 1.5 X 10(5) M-1, and 1.2 X 10(5) M-1, respectively, in 50 mM NaCl, pH 7.4. The binding site size is two base pairs. MPE.Mg(II) unwinds PM2 DNA 11 +/- 3 degrees per bound molecule. MPE.Fe(II) in the presence of O2 efficiently cleaves DNA and with low sequence specificity. Reducing agents significantly enhance the efficiency of the cleavage reaction in the order sodium ascorbate greater than dithiothreitol greater than NADPH. At concentrations of 0.1-0.01 microM in MPE.Fe(II) and 10 microM in DNA base pairs, optimum ascorbate and dithiothreitol concentrations for DNA cleavage are 1-5 mM. Efficient cleavage of DNA (10 microM in base pairs) with MPE.Fe(II) (0.1-0.01 microM) occurs over a pH range of 7-10 with the optimum at 7.4 (Tris-HCl buffer). The optimum cleavage time is 3.5 h (22 degrees C). DNA cleavage is efficient in a Na+ ion concentration range of 5 mM to 1 M, with the optimum at 5 mM NaCl. The number of single-strand scissions on supercoiled DNA per MPE.Fe(II) under optimum conditions is 1.4. Metals such as Co(II), Mg(II), Ni(II), and Zn(II) inhibit strand scission by MPE. The released products from DNA cleavage by MPE.Fe(II) are the four nucleotide bases. The DNA termini at the cleavage site are 5'-phosphate and roughly equal proportions of 3'-phosphate and 3'-(phosphoglycolic acid). The products are consistent with the oxidative degradation of the deoxyribose ring of the DNA backbone, most likely by hydroxy radical.     

Methidiumpropyl-EDTA.Fe(II) and DNase I footprinting report different small molecule binding site sizes on DNA.

DNase I and MPE.Fe (II) footprinting both employ partial cleavage of ligand-protected DNA restriction fragments and Maxam-Gilbert sequencing gel methods of analysis. One method utilizes the enzyme, DNase I, as the DNA cleaving agent while the other employs the synthetic molecule, methidium-propyl-EDTA (MPE). For actinomycin D, chromomycin A3 and distamycin A, DNase I footprinting reports larger binding site sizes than MPE.Fe (II). DNase I footprinting appears more sensitive for weakly bound sites. MPE.Fe (II) footprinting appears more accurate in determining the actual size and location of the binding sites for small molecules on DNA, especially in cases where several small molecules are closely spaced on the DNA. MPE.Fe (II) and DNase I report the same sequence and binding site size for lac repressor protein on operator DNA.     

DNA sequence specificity of the pyrrolo[1,4]benzodiazepine antitumor antibiotics. Methidiumpropyl-EDTA-iron(II) footprinting analysis of DNA binding sites for anthramycin and related drugs

Anthramycin, tomaymycin, and sibiromycin are members of the pyrrolo[1,4]benzodiazepine [P(1,4)B] antitumor antibiotic group. These drugs bind covalently through N2 of guanine and lie within the minor groove of DNA [Petrusek, R. L., Anderson, G. L., Garner, T. F., Fannin, Q. L., Kaplan, D. J., Zimmer, S. G., & Hurley, L. H. (1981) Biochemistry 20, 1111-1119]. The DNA sequence specificity of the P(1,4)B antibiotics has been determined by a footprinting method using methidiumpropyl-EDTA-iron(II) [MPE.Fe(II)], and the results show that each of the drugs has a two to three base pair sequence specificity that includes the covalently modified guanine residue. While 5'PuGPu is the most preferred binding sequence for the P(1,4)Bs, 5'PyGPy is the least preferred sequence. Footprinting analysis by MPE.Fe(II) reveals a minimum of a three to four base pair footprint size for each of the drugs on DNA with a larger than expected offset (two to three base pairs) on opposite strands to that observed in previous analyses of noncovalently bound small molecules. There is an extremely large enhancement of MPE.Fe(II) cleavage between drug binding sites in AT rich regions, probably indicating a drug-induced change in the conformational features of DNA which encourages interaction with MPE.Fe(II). In the presence of sibiromycin or tomaymycin the normally guanine-specific methylene blue reaction used in Maxam and Gilbert sequencing cleaves at other bases in defined positions relative to the drug binding sites. Finally, modeling studies are used to rationalize the differences and similarities in sequence specificities between the various drugs in the P(1,4)B group and their reactions with DNA.     

Nonintercalative DNA-binding antitumour compounds

Summary A family of compounds which appear to bind reversibly to double stranded DNA without intercalation between DNA base pairs has been defined. Methods are described by which this non-intercalative binding can be characterised using ultraviolet spectrometry, fluorimetry with ethidium as a probe, viscometry and other hydrodynamic techniques, circular dichroism and nuclear magnetic resonance spectrometry. Antibiotics which fall into this family include the antibiotics distamycin A, netropsin, mithramycin, chromomycin and olivomycin. Synthetic antitumour agents include diarylamidines such as berenil, phthalanilides, aromatic bisguanylhydrazones and bisquaternary ammonium heterocycles. A survey has been made of the general requirements of this family of compounds for DNA binding and biological activity. Binding of drugs to the minor groove of the DNA double helix appears to be the most likely mechanism for the antitumour action of these compounds.     

Interactions of chromomycin A3 and mithramycin with the sequence d(TAGCTAGCTA)2

Anti-cancer antibiotics, chromomycin A3 (CHR) and mithramycin (MTR) inhibit DNA directed RNA synthesis in vivo by binding reversibly to template DNA in the minor groove with GC base specificity, in the presence of divalent cations like Mg2+. Under physiological conditions, (drug)2Mg2+ complexes formed by the antibiotics are the potential DNA binding ligands. Structures of CHR and MTR differ in their saccharide residues. Scrutiny of the DNA binding properties reveal significant differences in their sequence selectivity, orientation and stoichiometry of binding. Here, we have analyzed binding and thermodynamic parameters for the interaction of the antibiotics with a model oligonucleotide sequence, d(TAGCTAGCTA)2 to understand the role of sugars. The oligomer contains two potential binding sites (GpC) for the ligands. The study illustrates that the drugs bind differently to the sequence. (MTR)2Mg2+ binds to both sites whereas (CHR)2Mg2+ binds to a single site. UV melting profiles for the decanucleotide saturated with the ligands show that MTR bound oligomer is highly stabilized and melts symmetrically. In contrast, with CHR, loss of symmetry in the oligomer following its association with a single (CHR)2Mg2+ complex molecule leads to a biphasic melting curve. Results have been interpreted in the light of saccharide dependent differences in ligand flexibility between the two antibiotics.     

Spectrofluorometry of dyes with DNAs of different base composition and conformation

The increase in fluorescence, upon interaction with several fluorescent dyes was found to depend on the base composition of DNA. 4',6-Diamidino-2-phenylindole-2 HCl and Hoechst 33258 which bind to AT base pairs show a logarithmic relation. This relation is linear when DNAs interact with mithramycin, chromomycin A3, and olivomycin, which bind to GC base pairs. Deviations from these relationships were observed for T2 DNA, containing hydroxymethylcytosine, and for 2C DNA, containing hydroxymethyluracil. On the basis of these data, a simple technique is proposed for determination of base composition. The presence of abnormal bases can be monitored by the use of given fluorophores. Fluorescence intensities were not modified upon linearization of covalently closed circular plasmid pBR322. Denaturation of lambda DNA was accompanied by a decrease of fluorescence, when complexed with the five dyes tested.     

Transferring the purine 2-amino group from guanines to adenines in DNA changes the sequence-specific binding of antibiotics.

The proposition that the 2-amino group of guanine plays a critical role in determining how antibiotics recognise their binding sites in DNA has been tested by relocating it, using tyrT DNA derivative molecules substituted with inosine plus 2,6-diaminopurine (DAP). Irrespective of their mode of interaction with DNA, such GC-specific antibiotics as actinomycin, echinomycin, mithramycin and chromomycin find new binding sites associated with DAP-containing sequences and are excluded from former canonical sites containing I.C base pairs. The converse is found to be the case for a group of normally AT-selective ligands which bind in the minor groove of the helix, such as netropsin: their preferred sites become shifted to IC-rich clusters. Thus the binding sites of all these antibiotics strictly follow the placement of the purine 2-amino group, which accordingly must serve as both a positive and negative effector. The footprinting profile of the 'threading' intercalator nogalamycin is potentiated in DAP plus inosine-substituted DNA but otherwise remains much the same as seen with natural DNA. The interaction of echinomycin with sites containing the TpDAP step in doubly substituted DNA appears much stronger than its interaction with CpG-containing sites in natural DNA.     

Differential interactions of antitumor antibiotics chromomycin A(3) and mithramycin with d(TATGCATA)(2) in presence of Mg(2+)

The antitumor antibiotics chromomycin A(3) (CHR) and mithramycin (MTR) are known to inhibit macromolecular biosynthesis by reversibly binding to double stranded DNA with a GC base specificity via the minor groove in the presence of a divalent cation such as Mg(2+). Earlier reports from our laboratory showed that the antibiotics form two types of complexes with Mg(2+): complex I with 1:1 stoichiometry and complex II with 2:1 stoichiometry in terms of the antibiotic and Mg(2+). The binding potential of an octanucleotide, d(TATGCATA)(2), which contains one potential site of association with the above complexes of the two antibiotics, was examined using spectroscopic techniques such as absorption, fluorescence, and circular dichroism. We also evaluated thermodynamic parameters for the interaction. In spite of the presence of two structural moieties of the antibiotic in complex II, a major characteristic feature was the association of a single ligand molecule per molecule of octameric duplex in all cases. This indicated that the modes of association for the two types of complexes with the oligomeric DNA were different. The association was dependent on the nature of the antibiotics. Spectroscopic characterization along with analysis of binding and thermodynamic parameters showed that differences in the mode of recognition by complexes I and II of the antibiotics with polymeric DNA existed at the oligomeric level. Analysis of the thermodynamic parameters led us to propose a partial accommodation of the ligand in the groove without the displacement of bound water molecules and supported earlier results on the DNA structural transition from B --> A type geometry as an obligatory requirement for the accommodation of the bulkier complex II of the two drugs. The role of the carbohydrate moieties of the antibiotics in the DNA recognition process was indicated when we compared the DNA binding properties with the same type of Mg(2+) complex for the two antibiotics.     

NMR investigation of mithramycin A binding to d(ATGCAT)2: a comparative study with chromomycin A3

The binding of mithramycin A to the d(A1T2G3C4A5T6) duplex was investigated by 1H NMR and found to be similar to that of its analogue chromomycin A3. In the presence of Mg2+, mithramycin binds strongly to d(ATGCAT)2. On the basis of the two-dimensional NOESY spectrum, the complex formed possesses C2 symmetry at a stoichiometry of two drugs per duplex (2:1) and is in slow chemical exchange on the NMR time scale. NOESY experiments reveal contacts from the E-pyranose of mithramycin to the terminal and nonterminal adenine H2 proton of DNA and from the drug hydroxyl proton to both G3NH2 protons, C4H1' proton, and A5H1' proton. These data place the drug chromophore and E pyranose on the minor groove side of d(ATGCAT)2. NOE contacts from the A-, B-, C-, and D-pyranoses of mithramycin to several deoxyribose protons suggest that the A- and B-rings are oriented along the sugar-phosphate backbone of G3-C4, while the C- and D-rings are located along the sugar-phosphate backbone of A5-T6. These drug-DNA contacts are very similar to those found for chromomycin binding to d(ATGCAT)2. Unlike chromomycin, the NOESY spectrum of mithramycin at the molar ratio of one drug per duplex reveals several chemical exchange cross-peaks corresponding to the drug-free and drug-bound proton resonances. From the intensity of these cross-peaks and the corresponding diagonal peaks, the off-rate constant was estimated to be 0.4 s-1. These data suggest that the exchange rate of mithramycin binding to d(ATGCAT)2 is faster than that of chromomycin.     

Cleavage of tRNA by Fe(II)-bleomycin.

We have investigated the action of the chemotherapeutic agent Fe(II)-bleomycin on yeast tRNA(Phe), an RNA of known three-dimensional structure. In the absence of Mg2+ ions, the RNA is cleaved preferentially at two major positions, A31 and G53, both of which are located at the terminal base pairs of hairpin loops, and coincide with the location of tight Mg2+ binding sites. A fragment of the tRNA (residues 47-76) containing the T stem-loop is also cleaved specifically at G53. Cleavage of both the intact tRNA and the tRNA fragment is abolished in the presence of physiological concentrations of Mg2+ (> 0.5 mM). Since Fe(II) is not displaced from bleomycin under these conditions, we infer that tight binding of Mg2+ to tRNA excludes productive interactions between Fe(II)-bleomycin and the RNA. These results also show that loss of cleavage is not due to Mg(2+)-dependent formation of tertiary interactions between the D and T loops. In contrast, cleavage of synthetic DNA analogs of the anticodon and T stem-loops is not detectably inhibited by Mg2+, even at concentrations as high as 50 mM. In addition, the site specificities observed in cleavage of RNA and DNA differ significantly. From these results, and from similar findings with other representative RNA molecules, we suggest that the cleavage of RNA by Fe(II)-bleomycin is unlikely to be important for its therapeutic action.     

DNA sequence selectivities in the covalent bonding of antibiotic saframycins Mx1, Mx3, A, and S deduced from MPE.Fe(II) footprinting and exonuclease III stop assays.

DNA sequence selectivities in the covalent binding of the antitumor antibiotic saframycins Mx1, Mx3, A, and S have been determined by complementary strand MPE.Fe(II) footprinting and exonuclease III stop assays on two different 545 and 135 base pair long HindIII/RsaI restriction fragments of pBR322 DNA. Saframycins Mx1, Mx3, A, and S recognize primarily 5'-GGG sequences. All four antibiotics also recognize 5'-GGPy sequences, however a cytosine is preferred over a thymine at the 3'-end of this recognition site in all cases. Saframycins Mx1, Mx3 and S, which possess the OH leaving group, also recognize the 5'-CCG sequence, in contrast to saframycin A, which contains the CN leaving group. In contrast, the OH-containing saframycins also recognize the 5'-CTA sequence. Saframycins Mx2, B and C, which lack the critical CN or OH leaving group, do not show any footprints on the restriction fragments examined in this study. The measured binding site size for all four antibiotics is three base pairs. The exonuclease III stop assay independently confirmed the formation of a covalent bond and the strong preference of the antibiotics for 5'-GGG and 5'-GCC sequences. The latter enzyme assay also suggests that the 5'-terminal or central G of the triad binding site is the base to which reversible covalent attachment of the antibiotic takes place.     

Circular dichroism studies of complexes of the antibiotics daunomycin, nogalamycin, chromomycin, and mithramycin with DNA

The circular dichroism spectra of complexes of the antibiotics daunomycin, nogalamycin, chromomycin, and mithramycin with calf thymus DNA have been measured over a range of drug/DNA ratios. The similarity of the CD spectra of bound chromomycin and mithramycin suggests that they have very similar binding sites, which produce strong effects on the CD spectra of the bound drugs, and remove the differences arising from local stereochemistry in the free drugs. It was found that it was not possible to predict whether the antibiotics intercalated, from studies of the CD spectra alone, even when comparisons were made with the CD spectra of aminoacridine–DNA complexes with intercalating or nonintercalating ligands.     

Species specific differences in the toxicity of mithramycin, chromomycin A3, and olivomycin towards cultured mammalian cells

Three structurally related anticancer drugs, mithramycin, chromomycin A3, and olivomycin, showed large unexpected differences (up to more than 1000 fold) in their toxicity towards cultured cells from various species (human, Chinese hamster, Syrian hamster, and mouse). Among the cell types examined, human cells (both a diploid fibroblast cell strain and HeLa cells) were maximally sensitive to all these drugs, followed by the Syrian hamster kidney cells (BHK 21). The mouse (LMTK- cells) and Chinese hamster (CHO) cells, which were more resistant, showed interesting differences in their sensitivity towards these drugs. For example, whereas the mouse cells were more resistant to mithramycin than CHO cells, the sensitivity pattern was reversed for both chromomycin A3 and olivomycin. In cell extracts derived from human, mouse, and Chinese hamster cells RNA synthesis, which is the cellular target of these drugs, showed identical sensitivity to both mithramycin and chromomycin A3, indicating that the species specific differences in the toxicity to these drugs are at the level of cellular entry of these compounds. Based on the structures of these glycosidic antibiotics and their patterns of toxicity, it is suggested that the intracellular transport of these drugs involves specific interactions between the sugar residues on these compounds and some type of cell surface receptor(s), which differ among different cell types. Some implications of these results for toxicity studies are discussed.     

Fluorescent DNA probes for flow cytometry. Considerations and prospects.

Techniques employing base specific deoxyribonucleic acid (DNA)-binding fluorochromes and flow cytometry (FCM) are potentially useful for obtaining information of the compositional features of chromatin or chromosomes of mammalian cells. Fluorescent compounds which form complexes preferentially at the A-T rich regions (i.e., DNA-reactive Hoechst dyes) or the G-C rich regions (i.e., mithramycin, chromomycin, olivomycin) in DNA are available and compatible with current FCM technology as are other compounds (i.e., ethidium bromide, propidium iodide) which show little or no base specificity and bind by intercalation in the double stranded regions of helical DNA. Energy transfer between appropriate DNA-bound dyes is a reflection of the quantity and proximity of regions containing the respective base pair segments. Since extrinsic fluorescent probes provide only a measure of available binding sites or regions unobstructed by chromatin-associated or chromosomal-associated proteins, interpretations of fluorescence measurements need to be substantiated by adequate control measures.     

Detailed Studies on the Application of Three Fluorescent Antibiotics for Dna Staining in Flow Cytometry

The effects of pH, ionic strength, stain concentration, magnesium concentration, and various fixative agents on DNA staining with the fluorescent antibiotics olivomycin, chromomycin A3, and mithramycin were examined with DNA in solution and in mammalian cells. Ethanol-fixed Chinese hamster cell populations (line CHO) stained with mithramycin and analyzed by flow cytometry provided DNA distribution patterns with a high degree of resolution. Glutaraldehyde-fixed cells exhibited about one-half the fluorescence intensity of ethanol-fixed cells; however, the percentages of cells in G₁, S, and G₂ + M were comparable. DNA distributions obtained for formalin-fixed cells were unacceptable for computer analysis. Cell staining over a pH range of 5-9 in solutions containing 0.15-1 M NaCl and 15-200 mM MgCl₂ provided optimal results based on the DNA profiles obtained by flow cytometry. The intensity of cells stained in 1 M NaCl was one and one-half times greater than cells stained in the absence of NaCl; however, spectrophotofluorometric analysis of mithramycin-magnesium-DNA complexes in solution revealed no significant changes in fluorescence intensity over a range of 0-1.75 M NaCl. These results and those obtained by flow cytometry analysis indicate that the increase in fluorescence of stained cells as a function of increasing ionic strength is due to changes in chromatin structure, providing a larger number of binding sites for the dye-magnesium complex.     

Molecular recognition of B-DNA by Hoechst 33258.

The binding sites of Hoechst 33258, netropsin and distamycin on three DNA restriction fragments from plasmid pBR322 were compared by footprinting with methidiumpropyl-EDTA X Fe(II) [MPE X Fe(II)]. Hoechst, netropsin and distamycin share common binding sites that are five +/- one bp in size and rich in A X T DNA base pairs. The five base pair protection patterns for Hoechst may result from a central three base pair recognition site bound by two bisbenzimidazole NHs forming a bridge on the floor of the minor groove between adjacent adenine N3 and thymine O2 atoms on opposite helix strands. Hydrophobic interaction of the flanking phenol and N-methylpiperazine rings would afford a steric blockade of one additional base pair on each side.     

Mithramycin forms a stable dimeric complex by chelating with Fe(II): DNA-interacting characteristics, cellular permeation and cytotoxicity

Mith (mithramycin) forms a 2:1 stoichiometry drug–metal complex through the chelation with Fe(II) ion as studied using circular dichroism spectroscopy. The binding affinity between Mith and Fe(II) is much greater than other divalent metal ions, including Mg(II), Zn(II), Co(II), Ni(II) and Mn(II). The [(Mith)₂–Fe(II)] complex binds to DNA and induces a conformational change of DNA. Kinetic analysis of surface plasmon resonance studies revealed that the [(Mith)₂–Fe(II)] complex binds to DNA duplex with higher affinity compared with the [(Mith)₂–Mg(II)] complex. A molecular model of the Mith-DNA–Metal(II) complex is presented. DNA-break assay showed that the [(Mith)₂–Fe(II)] complex was capable of promoting the one-strand cleavage of plasmid DNA in the presence of hydrogen peroxide. Intracellular Fe(II) assays and fluorescence microscopy studies using K562 indicated that this dimer complex maintains its structural integrity and permeates into the inside of K562 cells, respectively. The [(Mith)₂–Fe(II)] complex exhibited higher cytotoxicity than the drug alone in some cancer cell lines, probably related to its higher DNA-binding and cleavage activity. Evidences obtained in this study suggest that the biological effects caused by the [(Mith)₂–Fe(II)] complex may be further explored in the future.