On the kinetics of distamycin binding to its target sites on duplex DNA (original) (raw)
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Nucleic Acids Research, 1979
Interaction of DNA with the analogs of the antibiotic distazycin A having different numbers of pyrrolcarboxamide groups and labeled with dansyl was studied. The bindin isoterms of the analogs to synthetic polydeoxyribonucleotides were obtained. Analysis of the experimental data leads to the following conclusions: (1) the free energy of binding of the analogs to po1y(dA)-poly(dT) depends linearly on the number of amide groups in the molecule of the analog whereas attachment of each pyrrolcarboxamide group produces changes of 2 kcal/mole in the free energy; (2) attachment of a pyrrolcarboxamide unit to the GO pair results in the free energy change of 0.95 kcal/mole; (3) the binding of analogs to poly(dA).poly(dT) is a cooperative process, presumbly, dependent on conformational changes induced by the binding of analogs to DNA.
Journal of Molecular Modeling, 2007
A 3D-QSAR analysis has been carried out by comparative molecular field analysis (CoMFA) on a series of distamycin analogs that bind to the DNA of drug-resistant bacterial strains MRSA, PRSP and VSEF. The structures of the molecules were derived from the X-ray structure of distamycin bound to DNA and were aligned using the Database alignment method in Sybyl. Statistically significant CoMFA models for each activity were generated. The CoMFA contours throw light on the structure activity relationship (SAR) and help to identify novel features that can be incorporated into the distamycin framework to improve the activity. Common contours have been gleaned from the three models to construct a unified model that explains the steric and electrostatic requirements for antimicrobial activity against the three resistant strains. Figure A unified CoMFA model for broad-spectrum DNA minor-groove binders
DNA-induced distamycin a fluorescence
Histochemistry, 1990
The fluorescent properties of the antibiotic distamycin A were investigated in a range of materials including Trypanosorna cruzi epimastigotes, chicken erythrocytes, calf thymus D N A and synthetic polynucleotides using both microscopic and spectroscopic techniques. A bright blue-white fluorescence was observed from kinetoplast D N A and chromatin after treatment with distamycin A under ultraviolet (365 nm) excitation. Considerable enhancement of distamycin A fluorescence (emission peak at 4 5 5 n m under 320-340 nm excitation) was found in the presence of D N A and poly(dA-dT).poly(dA-dT). We discuss a possible explanation for this unexpected fluorescent emission, as well as its implications for microscopic and fluorimetric studies.
Biochemical and Biophysical Research Communications, 2000
First examples of distamycin (Dst) analogs which lack hydrogen bond donor or acceptor groups at the N-terminus have been synthesized. The first molecule of this series, which is a bispyrrole peptide, did not exhibit any detectable binding with double-stranded (ds) DNA. However, all other analogs did bind strongly to AT-rich sequences of ds-DNA, with the binding affinities increasing as a function of the number of repeating pyrrole carboxamide units. These results imply that a hydrogen bond donor or acceptor atom per se at the N-terminus is not a prerequisite for DNA binding in the case of pyrrole carboxamide-based Dst analogs. However, in the absence of H-bond donor or acceptor at the N-terminus, a minimum of three pyrrole carboxamide units is necessary for the onset of DNA binding. Beyond this minimum number, the binding affinity increases as a function of the number of pyrrole units, as a result of the greater availability of hydrogen bonding and van der Waals surface. Experiments with poly[d(G-C)] have shown that the presence of the N-terminus formamide group is not inevitable for GC binding of this class of molecules. The observation that the N-terminus formamide unit can be dispensed with suggests that these molecules, which are much easier to synthesize and functionalize, can be used in place of the conventional analogs of distamycin for the development of novel minor groove binders with extended sequence recognition properties.
Fluorescence assay of polyamide–DNA interactions
Analytical Biochemistry, 2012
Polyamides (PA) are distamycin-type ligands of DNA that bind the minor groove and are capable of sequence selective recognition. This capability provides a viable route to their development as therapeutics. Presented here is a simple and convenient fluorescence assay for polyamide-DNA binding. PAs are titrated into a sample of a hairpin DNA featuring a TAMRA dye attached to an internal dU near the PA binding site. In a study of 6 polyamides, PA binding leads to a steady, reproducible decrease in fluorescence intensity that can be used to generate binding isotherms. The assay works equally well with both short (6-8 ring) and long (14 ring) polyamides, and K d values ranging from about 1 nM to at least 140 nM were readily obtained using a simple monochromator or filter configuration. Competition assays provide a means to assessing possible dye interference, which can be negligible. The assay can also be used to determine polyamide extinction coefficients, and to measure binding kinetics, and thus is an accessible and versatile tool for the study of polyamide properties and polyamide-DNA interactions.
Nucleic Acids Research, 1991
The binding between Distamycin 3 and the palindromic duplexes d(CGTTTAAACG)2 and d(CGTACGTACG)2 was investigated by two indipendent techniques: UV-Vis absorption in the Job's plot approach and Induced Circular Dichroism. Both decamers bind two molecules of peptide per duplex, with close overall affinities. This result indicates that a row of six A:T base pairs can accommodate two molecules of drug and that the minimal binding site of Distamycin 3 can consist of just two A:T base pairs.
Site and sequence specificity of the daunomycin-DNA interaction
Biochemistry, 1987
The site and sequence specificity of the daunomycin-DNA interaction was examined by equilibrium binding methods, by deoxyribonuclease I footprinting studies, and by examination of the effect of the antibiotic on the cleavage of linearized pBR322 DNA by restriction endonucleases PDUI and EcoRI.
Biopolymers, 1988
The interaction of daunomycin with ctDNA and six purine-pyrimidine alternating polydeoxymcleotides has been studied using fluorometric and uv-visible absorption methods. In the explored binding range of r > 0.05, the intercalation of the drug into the DNAs proved to be anticooperative, as indicated by the pronounced upward curvature of all the Scatchard plots obtained. The experimental data have been analyzed according to the recent theory of Friedman and Manning, which describes the polyelectrolyte effects on the site binding equilibria, drug intercalation included. We found that, accounting for the polyelectrolyte effects in the neighbor site exclusion model, the experimental data were nearly equally well described, in a wide range of binding ratias, by assuming the presence of sequence specificity effects (site size = 2 base pairs, exclusion parameter n = 1) or its absence (site size = 1 base pair, n = 1.7). The relevant results are as follows: (a) Daunomycin binds to all the DNAs considered with a stoichiometry of approximately 1 drug for every two base pairs. (b) The anticooperative nature of the interaction is essentially polyelectrolytic in origin. (c) The binding afEnity shown by the drug for the different sites considered decreases in the order of Gm5C > AT > AC-GT > IC > GC > AU, indicating a stabilizing effect of the-CH, group in pasition 5 of the pyrimidines. (d) The extent of quenching of the intrinsic fluorescence of daunomycin in the presence of DNA is bound to the presence, at the intercalation site, of a guanine residue, since GC, Gm'C, and AC-GT sites induce a nearly total quenching, whereas AT, AU, and IC sites act only partially in this respect. The structural results obtained from the daunomycin-d[(CGTACG)], crystal suggest that the 2-NH2 group of guanine might be responsible for such a phenomenon. The influence of both the temperature and the ionic strength on the free energy of drug intercalation into ctDNA, poly[d(G-C)] : poly[d(G-C)], and poly[d(A-C)] : poly[d(G-T)] is examined and d i s c u s s e d .
European Journal of Organic Chemistry, 2002
An efficient, simple and general route towards the solutionphase synthesis of four distamycin analogues containing 2−5 N-methylcarboxamide units without the leading amide unit at the N-terminus is described. The binding abilities of these molecules to calf thymus DNA, poly d(AT), poly dA.poly dT and poly d(GC) were evaluated by duplex DNA melting temperature (T m) analysis, fluorescence probe displacement assay, footprinting studies and induced circular dichroism (ICD) measurements. A minimum of three N-methylpyrrolecarboxamide units was found to be necessary for the onset of DNA binding. The other three analogues exhibited AT-specific footprints on DNA at a salt concentration of 40 mM NaCl. Interestingly, intense ICD spectra were obtained not only with AT-rich DNA tracts, but also with poly d(GC). Though these