Netropsin Binding Research Articles

Nuclease activity of 1,10-phenanthroline-copper ion: reaction with CGCGAATTCGCG and its complexes with netropsin and EcoRI.

The self-complementing dodecamer 5'-CGCGAATTCGCG-3' and its complexes with the antibiotic netropsin and the restriction endonuclease EcoRI provide substrates of known three-dimensional structure to study the stereochemistry and mechanism of the artificial nuclease of 1,10-phenanthroline-copper ion [(OP)2Cu+]. Analysis of the reaction products with the 5'-32P dodecamer on 20% sequencing gels has demonstrated the presence of 3'-phosphoglycolate ends in addition to 3'-phosphomonoester ends expected from previous studies. A reaction intermediate, which is a precursor to 3'-phosphomonoester termini, has been trapped; in contrast, no comparable species for the 5'-phosphomonoester termini can be detected when 3'-labeled DNAs are utilized as substrates. The reactive oxidative species formed by the coreactants (OP)2Cu+ and hydrogen peroxide is distinguishable in its chemistry from the hydroxyl radicals produced by cobalt-60 gamma-irradiation. The freely diffusible hydroxyl radicals generated by cobalt-60 irradiation produce equivalent amounts of 3'-phosphomonoester and 3'-phosphoglycolate termini whereas the 3'-phosphomonoesters are the preferred product of (OP)2Cu+ and H2O2. On the basis of the structures of the products obtained, the principal site of attack of the coordination complex is on the C-1 of the deoxyribose within the minor groove. This conclusion is supported by the footprinting of netropsin binding to the dodecamer. Crystallographic results have demonstrated that netropsin binds to the minor groove at the central AATT residue. A clear protection of attack by the coordination complex at the deoxyriboses associated with A-5, T-6, T-7, and C-9 is fully consistent with attack from the minor groove without intercalation during the course of the cleavage reaction.(ABSTRACT TRUNCATED AT 250 WORDS)

Sequence-dependent recognition of DNA duplexes: netropsin complexation to the TATA site of the d(G-G-T-A-T-A-C-C) duplex in aqueous solution.

AbstractWe have recorded one‐dimensional exchangeable proton and two‐dimensional nonexchangeable proton nmr spectra on the complex of netropsin with the self‐complementary d(G‐G‐T‐A‐T‐A‐C‐C) duplex in aqueous solution between 25° and 35°C. The antibiotic amide, pyrrole, and methylene protons, and the nucleic acid base and sugar H1′, H2′, H2″, and H3′ protons, have been assigned from an analysis of the two‐dimensional nuclear Overhauser effect (NOESY) spectra of the complex. We observe intermolecular NOEs between the antibiotic concave face amide, pyrrole, and CH2 resonances, and the adenosine H2 and sugar H1′ protons of base‐pairs T3·A6 and A4·T5 in the central TATA core of the d(G1‐G2‐T3‐A4‐T5‐A6‐C7‐C8) duplex. We present a molecular model outlining these seven antibiotic‐DNA contacts for the complex in solution. The observed line‐broadening of several base and sugar protons at the TATA minor groove netropsin binding site in the complex at 35°C are interpreted in terms of intermediate exchange between two orientations of bound netropsin on the duplex.

Structure of poly(dA).poly(dT) is not identical to the AT rich regions of the single crystal structure of CGCGAATTBrCGCG. The consequence of this to netropsin binding to poly(dA).poly(dT).

The basic assumption of Dickerson and Kopka (J. Biomole. Str. Dyns. 2, 423, 1985) that the conformation of poly(dA).poly(dT) in solution is identical to the AT rich region of the single crystal structure of the Dickerson dodecamer is not supported by any experimental data. In poly(dA).poly(dT), NOE and Raman studies indicate that the dA and dT units are conformationally equivalent and display the (anti-S-type sugar)-conformation; incorporation of this nucleotide geometry into a double helix leads to a conventional regular B-helix in which the width of the minor groove is 8A. The derived structure is consistent with all available experimental data on poly(dA).poly(dT) obtained under solution conditions. In the crystal structure of the dodecamer, the dA and dT units have distinctly different conformations-dA residues adopt (anti, S-type sugar pucker), while dT residues belong to (low anti, N-type sugar pucker). These different conformations of the dA and dT units along with the large propeller twist can be accommodated in a double helix in which the minor groove is shrunk from 8A to less than 4A. In the conventional right handed B-form of poly(dA).poly(dT) with the 8A wide minor groove, netropsin has to bind asymmetrically along the dA strand to account for the NOE and chemical shift data and to generate a stereochemically sound structure (Sarma et al, J. Biomole. Str. Dyns. 2, 1085, 1985).

Effect of netropsin on plasmid DNA cleavage by BAL 31 nuclease

BAL 31 nuclease is known to possess two sorts of catalytic activities: one is a single-strand-specific endonuclease activity that converts negatively supercoiled UNA to the unit-length linear form, the other being a quasi-processive exonuclease activity that simultaneously degrades both 3'- and 5'-termini of linear dúplex DNA. Netropsin, a bactericidal and antiviral compound, was found to enhance the former activity but inhibit the latter. Netropsin-bound supercoiled plasmid DNA had a tendency to be fragmented by BAL 31 into several species of linear DNAs smaller than full-length size. Size reduction of linear plasmid DNA by BAL 31 was significantly inhibited by netropsin binding.

Theoretical exploration of netropsin binding to tRNA(Phe).

Theoretical exploration of the possible interaction of netropsin with tRNAPhe indicates that binding should occur preferentially with the major groove of the T psi C stem of the macromolecule, specifically with the bases G51, U52, G53 and phosphates 52, 53, 61 and 62. This agrees with the recent crystallographic result of Rubin and Sundaralingam. It is demonstrated that the difference with respect to netropsin binding with B-DNA, where it occurs specifically in the minor groove of AT sequences, is due to the differences in the distribution of the electrostatic molecular potential generated by these different types of DNA: this potential is sequence dependent in B-DNA (located in the minor groove of AT sequences and the major groove of GC sequences), while it is sequence independent and always located in the major groove in A-RNA. The result demonstrates the major role of electrostatics in determining the location of the binding site.

An unexpected major groove binding of netropsin and distamycin A to tRNA(phe).

Crystalline complexes of yeast tRNA(phe) and the oligopeptide antibiotics netropsin and distamycin A were prepared by diffusing drugs into crystals of tRNA. X-ray structure analyses of these complexes reveal a single common binding site for both drugs which is located in the major or deep groove of the tRNA T-stem. The netropsin-tRNA complex is stabilized by specific hydrogen bonds between the amide groups of the drug and the tRNA bases G51 O(6), U52 O(4) and G53 N(7) on one strand, and is further stabilized by electrostatic interactions between the positively charges guanidino side chain of the drug and the tRNA phosphate P53 on the same strand and the positively charged amidino propyl side chain and the phosphates P61, P62 and P63 on the opposite strand of the double helix. These results are in contrast to the implicated minor groove binding of these drugs to non-guanine sequences in DNA. The binding to the GUG sequence in tRNA implies that major groove binding to certain DNA sequences is possible.

Interaction of nucleic acids with a non-intercalative anti-leukemic compound containing bisquarternary heterocycles

The binding of an antitumour drug with bisquarternary ammonium heterocyclic structure, NSC-101327, to nucleic acids has been examined by using ultraviolet absorption and CD measurements. Like the minor groove-binding oligopeptides, netropsin and distamycin A, the optically inactive chromophoric system of NSC-101327 shows induced Cotton effects in the CD spectra of complexes with various DNAs, RNA and single-stranded polynucleotides. This property directly reflects interaction of NSC-101327 with different types of nucleic acids at moderate ionic strength, which contrasts with previous findings of a higher selective binding of netropsin to B-DNA. However, an efficient interactin of NSC-101327 with dA·dT basepair sequences is demonstrated by a large melting temperature increase of dA·dT-rich DNAs. NSC-101327 also reacts with dG·dC base pairs of B-DNA and forms a complex with Z-DNA of poly(br 8dG-dC)·poly(br 8DG-dC). The affinity of NSC-101327 to poly(dG-dC)·poly(dG-dC) is, however, lower, and the CD spectral binding effect depends on the ionic strength. The CD results of the complex with poly(dA-dT)·poly(dA-dT) suggests at least two binding modes, in accordance with previous conclusions. This is indicated by a clear-cut initial increase of the CD signal and a subsequent large decrease to negative CD signals. Competition experiments with netropsin suggest that binding of NSC-101327 occurs preferentially in the minor groove without intercalation. NSC-101327 also tends to interact with lower binding affinity to dG-dC pairs in B-DNA, with rA·rU pairs of RNA and with single-stranded polynucleotides. Thus our results suggest that NSC-101327 represents a DNA groove-binding ligand of lower basepair specificity and lower conformational selectivity compared to the B-specific netropsin probe.

Thermodynamics of drug-DNA interactions.

Batch calorimetry, differential scanning calorimetry (DSC), uv/vis absorption spectroscopy, fluorescence spectroscopy, and circular dichroism (CD), have been used to detect, monitor, and thermodynamically characterize the binding of daunomycin, dipyrandenium, dipyrandium, and netropsin to poly d(AT) and actinomycin D to salmon testes (ST) DNA. The following thermodynamic binding profiles have been obtained. (table; see text) All the poly d(AT) binding studies were done at 25 degrees C while actinomycin binding to ST DNA was performed at 1 degree C to enhance drug solubility. These thermodynamic parameters are interpreted in terms of specific interactions that have been proposed as part of models for the binding of each drug.

Sequence specificity of actinomycin D and Netropsin binding to pBR322 DNA analyzed by protection from DNase I.

A direct approach to determining the sequence specificities of equilibrium binding drugs by using the DNase protection technique is described. The method utilizes singly end-labeled restriction fragments and partial digestion of the drug fragment complex with DNase I. Microdensitometry of autoradiograms produced after electrophoretic separation of digestion products allows determination of sequences that are affected by drug binding. The feasibility of the technique for locating small ligands bound to DNA and its eventual use as a quantitative thermodynamic approach to studying ligand binding to heterogeneous DNA as a function of sequence is illustrated by using actinomycin D and Netropsin.

Kinetics for exchange of the imino protons of the d(C-G-C-G-A-A-T-T-C-G-C-G) double helix in complexes with the antibiotics netropsin and/or actinomycin.

The lifetimes for exchange of the imino protons in the dodecanucleotide d(C-G-C-G-A-A-T-T-C-G-C-G) upon binding of netropsin and/or actinomycin have been measured by proton nuclear magnetic resonance experiments. At high temperature these lifetimes were found to measure the lifetimes for opening of the base pairs in the double helix. Comparison of the opening rates in the dodecamer with those in the complex with netropsin (which binds at the -A-A-T-T- sequence) shows that there is not only a large kinetic stabilization of the A . T base pairs at the binding site but also a significant stabilization of the G . C base pairs adjacent to the netropsin binding site. For the complex with actinomycin, which intercalates at the G-C sites in the double strand, the lifetimes of the base pairs at the binding site increase upon binding of actinomycin, and the A . T base pairs in the central core are slightly kinetically destabilized by the actinomycin binding. The activation energies for exchange of the imino protons were also measured in the complexes and indicate that the mechanism for exchange of the imino protons is individual base-pair opening, where one base pair opens independently of the others. The effects of drug binding on the dynamics of individual base pairs in a double-stranded helix are discussed.

Calorimetric and spectroscopic investigation of drug-DNA interactions. I. The binding of netropsin to poly d(AT).

We report the first calorimetric investigation of netropsin binding to poly d(AT). Temperature-dependent uv absorption, circular dichroism (CD), batch calorimetry, and differential scanning calorimetry (DSC) were used to detect, monitor, and thermodynamically characterize the binding process. The following results have been obtained: 1) Netropsin groove binding is accompanied by a large exothermic enthalpy of 9.2 kcal/mol of drug bound at 25 degrees C. This indicates that a large negative binding enthalpy may be a necessary but not a sufficient criterion for drug intercalation. We suggest that the exothermic binding might be correlated with specific H-bonding interactions. 2) From the difference in DSC transition enthalpies in the presence and absence of netropsin, we calculate a binding enthalpy of -10.7 kcal/mol of netropsin at 88 degrees C. 3) We calculate a positive delta S for netropsin binding to poly d(AT) at 25 degrees C. This positive entropy change may reflect netropsin-induced release of condensed cations and/or bound water. 4) The netropsin-saturated duplex monophasically melts 46 degrees C higher than the free duplex. The unsaturated duplex melts through two thermally-resolved transitions that correspond to netropsin-free and netropsin-bound regions. These two regions interact dynamically with no substantial influence on the thermal stabilities of the separate domains. 5) Netropsin binding decreases the cooperativity of the duplex to single strand transition.

Footprinting with MPE.Fe(II). Complementary-strand analyses of distamycin- and actinomycin-binding sites on heterogeneous DNA.

We recently reported a direct technique for determining the binding sites of small molecules on naturally occurring heterogeneous DNA (Van Dyke et al. 1982). Methidiumpropyl-EDTA·Fe(II) (MPE·Fe[II]) (Hertzberg and Dervan 1982) cleaves double-helical DNA with low sequence-specificity (Van Dyke et al. 1982). Using a combination of MPE·Fe(II) partial cleavage of drug-protected DNA fragments and Maxam-Gilbert sequencing methods, we determined the drug-protected sites on one strand of a double-helical fragment from pBR322 for the intercalator actinomycin D (Goldberg et al. 1962; Muller and Crothers 1968; Wells and Larson 1970; Sobell 1973; Krugh 1981; Patel et al. 1981; Takusagawa et al. 1982) and the minor-groove binders netropsin and distamycin A (Luck et al. 1974; Wartell et al. 1974; Zimmer 1975; Berman et al. 1979; Krylov et al. 1979). Netropsin and distamycin A gave identical DNA-cleavage inhibition patterns or footprints in regions rich in dA·dT base pairs. Actinomycin D afforded a completely different footprint...

A theoretical evaluation of the effect of netropsin binding on the reactivity of DNA towards alkylating agents.

The effect of netropsin binding on the electrostatic potential of DNA reactive sites is presented. Calculations are performed for atoms N7 and O6 of guanine, N3 and N7 of adenine of model, 25 base pair long, DNA-netropsin complexes. An important weakening of the potential is found spreading along all the oligonucleotide chain studied. The results are discussed in connection with the inhibitory effect of a related ligand, distamycin A, on DNA methylation.

The effect of netropsin on the electrochemical oxidation of DNA at a graphite electrode

The interaction of netropsin with calf thymus, Bacillus cereus and Micrococcus luteus DNAs and with the RNA of phage f2 was studied by means of differential pulse voltammetry at a paraffin-wax-impregnated spectroscopic graphite electrode. It was found that the oxidation voltammetric peaks of double-helical calf thymus and Bacillus cereus DNAs were lowered when netropsin was added to the DNA solution. The peak corresponding to electro-oxidation of adenine residues was lowered more than that corresponding to electro-oxidation of guanine residues. Under the same experimental conditions the oxidation peaks of double-helical Micrococcus luteus DNA, double-helical RNA and thermally denatured samples of all DNAs used were almost uninfluenced by the addition of netropsin. The results observed were explained by ( i) decreased flexibility of the segments to which netropsin was bound, and ( ii) the specific binding of netropsin to the segments of double-helical DNA rich in adenine.thymine pairs.

459—The effect of netropsin on the electrochemical oxidation of DNA at a graphite electrode

The interaction of netropsin with calf thymus, Bacillus cereus and Micrococcus luteus DNAs and with the RNA of phage f2 was studied by means of differential pulse voltammetry at a paraffin-wax-impregnated spectroscopic graphite electrode. It was found that the oxidation voltammetric peaks of double-helical calf thymus and Bacillus cereus DNAs were lowered when netropsin was added to the DNA solution. The peak corresponding to electro-oxidation of adenine residues was lowered more than that corresponding to electro-oxidation of guanine residues. Under the same experimental conditions the oxidation peaks of double-helical Micrococcus luteus DNA, double-helical RNA and thermally denatured samples of all DNAs used were almost uninfluenced by the addition of netropsin. The results observed were explained by ( i) decreased flexibility of the segments to which netropsin was bound, and ( ii) the specific binding of netropsin to the segments of double-helical DNA rich in adenine thymine pairs.

Mutual interaction between adjacent dG . dC actinomycin binding sites and dA . dT netropsin binding sites on the self-complementary d(C-G-C-G-A-A-T-T-C-G-C-G) duplex in solution.

The Watson-Crick imino protons, the backbone phosphodiester resonances, and the antibiotic exchangeable protons have been used as markers to monitor the separate and simultaneous binding of actinomycin and netropsin to the d(C-G-C-G-A-A-T-T-C-G-C-G) self-complementary duplex in aqueous solution. We demonstrate that intercalation of actinomycin at dG(3'-5')dC sites at either end of the duplex results in a conformational perturbation at the dA . dT tetranucleotide core of the dodecanucleotide duplex. Parallel studies of the groove binding of netropsin at dA . dT sites in the interior of the duplex reveal a conformational perturbation which extends to adjacent dG . dC base pairs in the dodecanucleotide duplex. The NMR markers demonstrate that the d(C-G-C-G-A-A-T-T-C-G-C-G) duplex can accommodate actinomycin and netropsin simultaneously at adjacent dG . dC and dA . dT tetranucleotide blocks along its length with some mutual interaction between neighboring antibiotic binding sites.

Binding of netropsin to DNA in complexes with polypeptides containing repetitive lysine sequences

The interaction of the antibiotic netropsin with calf thymus DNA, T4 DNA and poly(dA-dT) · poly(dA-dT) in complexes with sequential polypeptides containing repetitive lysine sequences and histone H1 was investigated using circular dichroism spectroscopy and equilibrium dialysis. Both soluble DNA-polypeptide complexes and insoluble complexes showed binding of netropsin. The possibility of displacement of polypeptides from DNA binding sites by competition with netropsin molecules was eliminated by experiments using 14C-labelled polypeptides. From the analysis of CD titration behavior as well as from the results of equilibrium dialysis studies it follows that netropsin does not compete with polypeptides for DNA binding sites, which suggests that these two ligands occupy different sites. Various explanations for minor differences in the CD behavior of the bound netropsin in the saturation region are also discussed.

Magnetic circular dichroism study of the binding of netropsin and distamycin-A with DNA

The magnetic circular dichroism (MCD) of netropsin and distamycin-A is reported. New data for the interaction with dA · dT base pairs in DNA were obtained from the MCD of their complexes with DNA duplex polymers. The MCD results allow an interpretation of the induced Cotton effects in the natural CD spectra of netropsin and distamycin-A complexes with DNA. While large distortions of the bases in DNA by the oligopeptide interaction is excluded, some subtle conformational variations of the DNA might explain the inhibition of the enzyme function of netropsin and distamycin-A on DNA.

Protection of (dA.dT) cluster regions in the DNAase I cleavage of DNA by specific interaction with netropsin.

The specific DNA binding ligand netropsin selectively blocks dA-dT base pairs in clusters containing two or more consecutive thymine residues at the dNAase I cleavage sites of DNA. Using CD and UV absorption measurements it is shown, that at various ratios of netropsin to nucleotide concentrations and even at satuation of ligand interaction the enzyme cuts along regions containing dG-dC pairs sandwiched between dA-dT pairs. This follows a slow kinetics and is associated with a release of netropsin from those segments. These facts suggests the usefulness of the partial protection of certain DNA sequences in DNAase I cleavage sites in producing DNA fragments in structural studies of the genome. A possible interpretation of the effect of netropsin binding on the enzymatic hydrolysis of phosphodiester bonds of the helix is discussed.

Aspects of specific protein-DNA interaction; multi-mode binding of the oligopeptide antibiotic netropsin to (A·T)-rich DNA segments

By means of titration viscometry a number of distinct modes could be resolved for the interaction between the antibiotic netropsin and DNA species of 50, 58, and 69 mole + (A+T) below r = 0.04 netropsin molecules bound per DNA phosphate group. The number of corresponding binding sites increases with a high power of the (A+T) content. The apparent association constants are very high (greater than 10(6) M-1, some perhaps greater than 10(6) M-1) and also rather different for most of the binding sites. It is suggested that some of these interaction modes differ in the number of hydrogen bonds formed between donors of the ligand and acceptors of the binding sites. The interaction modes were characterized quantitatively by their (species-independent) changes of DNA contour length and by the percentage of local DNA stiffening.