Non stacking binding of 7-amino-actinomycin D and actinomycin D to DNA and model nucleotide systems in solutions

Mechanism of actinomycin D (AMD) and 7-aminoactinomycin D (7AAMD) interaction with DNA and model nucleotide compounds was studied by absorption and fluorescence spectroscopy (steady-state, phase-modulation, and polarization). It was shown that complex formation does not result in energy transfer from photoexcited nucleotides to phenoxazone chromophore of 7AAMD that indicates the absence of stacking-like intercalation. This fact is fundamentally important to explain the biological effect of actinomycin on cells. It was revealed a fundamental difference in the complex-forming properties of AMD and 7AAMD. Thus AMD is capable of binding to guanine micelles to destroy them. 7AAMD forms complexes neither guanine micelles nor polyguanilic acid. 7AAMD binding sites on DNA can differ substantially from AMD binding sites. However, a strong competition is observed between AMD and 7AAMD for binding site in oligonucleotide HP1 used as DNA hairpin model. The efficient diameters of 7AAMD-HP1 complex and free 7AAMD were determined using the Levshin-Perren equation.     

Prompt non-stacking binding of actinomycin D to hairpin oligonucleotide HP1 and slow redistribution from HP1 to DNA

Complexes of actinomycin D (AMD) and 7-amino-actinomycin D (7AAMD) with model hairpin oligonucleotide HP1 and various types of DNA in aqueous solutions were investigated by steady-state, polarized, time-resolved and stopped-flow fluorimetry, and photometry. Prompt non-stacking binding of the actinomycins inside HP1 was observed. No energy transfer from nucleotides to 7AAMD in the complex was detected, most likely because of the absence of stacking intercalation. Complex formation of AMD or 7AAMD and HP1 was followed by the transition from a random flexible conformation of the hairpin to a more compact rigid structure, and subsequently to hypochromism. Strong competition between AMD and 7AAMD for a cavity in HP1 was observed. The decrease in the 7AAMD emission after addition of DNA to the 7AAMD/HP1 complex indicates that actinomycins can be redistributed from HP1 to DNA, i.e. hairpin oligonucleotides can serve as molecular carriers of actinomycins.     

Fluorescence study of the energetics of nucleotide-actinomycin complexes

Complexes of 7-aminoactinomycin D (7AAMD), a fluorescent analogue of the natural antitumor antibiotic actinomycin D (AMD), with its potential carriers: purine nucleotides (guanine and adenine), caffeine, and fragmented DNA have been studied by fluorescence spectroscopy. It has been shown that 7AAMD binds on the surface of purine aggregates and caffeine clusters and is particularly well incorporated into unwound DNA regions. The process is accompanied by a strong long-wavelength shift of the excitation spectrum of 7AAMD. From the magnitude of the shift, the energy of interaction has been found. In the case of the interaction of 7AAMD with guanine, adenine, and caffeine, it is about 7 kcal/mol, which differs little from the energy of its interaction with DNA (7.7 kcal/mol). This indicates that the contribution of deoxyribose and phosphate to the energy of interaction is very small. On interaction with all compounds examined, except DNA, 7AAMD emits from the water phase, as judged from emission spectra. It has been concluded that, upon photoexcitation, 7AAMD passes readily from all clusters to the polar water phase but does not leave DNA and remains in the hydrophobic surroundings. Presumably, the rigidity of the binding of 7AAMD is determined not only by the enthalpic energy of interaction but also the entropic steric factor, the location of the antibiotic in the hydrophobic part of the unwound region.     

Formation of DNA Complexes with Actinomycins in Aqueous Solutions and Films

The mechanisms of DNA interaction with actinomycin D (AMD), 7-amino-actinomycin D (7-AAMD), and ethidium bromide (EtBr) were studied in aqueous solutions and in the condensed state (films coating plates). The use of the methods of absorption (UV, IR, and visible spectral ranges) and fluorescence (steady-state, polarization, and phase-modulation) spectroscopy revealed that (1) the formation of DNA complexes with 7-AAMD in solution was not accompanied by energy transfer from photoexcited nucleotides to phenoxazone chromophore and (2) the mechanism of ligand incorporation was distinct from stacking. In the film of the DNA–7-AAMD complex, which simulated the native state in a biological cell, the energy transfer efficiency was high. This indicates that a stacking-type mechanism underlies actinomycin intercalation into DNA. In the presence of high concentrations of 7-AAMD in the film, DNA denatured and its double-helical structure degraded. In the DNA–AMD complex, the native B-form of DNA molecule was conserved both in films and in solution.     

Fluorescence microscopic and autoradiographic analyses of the differential reaction of various regions of polytene chromosomes in Chironomus to prolonged exposure to 7-amino-actinomycin D and 3H-actinomycin D

Dynamics of binding of a fluorescent analogue of actinomycin D -- 7-amino-actinomycin D -- and 3H-actinomycin D with polytene chromosomes of Ch. thummi was studied. Biological effects of AMD, 7-amino-AMD, and 3H-AMD on polytene chromosomes were found to be similar. These ligands provoke the reduction of the nucleolus and Balbiani rings and the appearance of giant pseudo-puffs in heterochromatic centromere regions of polytene chromosomes. There was no intermediate binding of 7-amino-AMD to DNA in vivo both after a longterm treatment of larvae with fluorochrome and in chase experiments. It was found that a loosening of chromatin in centromere regions accompanied by a weakening of its fluorescence took place in the formation of pseudo-puffs. Possible mechanisms of pseudo-puff formation under the influence of AMD and 7-amino-AMD are discussed. Essential factors may be peculiarities of DNA nucleotide composition in centromere regions, DNA packing, alteration of physico-chemical properties of DNA in the complex with AMD (despiralizations and elongation), and an inhibition of RNA synthesis necessary for the maintenance of normal structure of polytene chromosomes.     

Binding of actinomycin D analogues containing some substituents at position 7 of the antibiotic chromophore to DNA

Spectrophotometric methods are used to study the binding to DNA of Actinomycin D (AMD) and its analogues: 7-nitro-AMD; 7-amino-AMD; 7-(Z-Val-Glo-NH)-AMD; 7-(AcO- . +H2-Val-Glo-NH)-AMD; 7-(AcO- . +H2-Val-Glo-Val-Glo-NH)-AMD. The binding constants are calculated from the binding isotherm of AMD and those of the AMD analogues to calf thymus DNA obtained by spectrophotometric titration. Introduction of smaller substituents such as the nitro or amino groups into position 7 of chromophore influences insignificantly the antibiotic binding to DNA, whereas bulky substituents cause a decrease in the affinity of the AMD analogues for DNA, although the spectral characteristics are not affected.     

7-Aminoactinomycin as a fluorescent probe for DNA unwinding and denaturation

A fluorescent analogue of antibiotic actinomycin D, 7-aminoactinomycin D (7AAMD), which is widely used in molecular biology, was shown by steady-state, polarization, and phase fluorescent spectroscopy to bind primarily in the unwound regions of DNA with concomitant increase in its emission intensity. The maximum emission intensity of 7AAMD is observed for denatured DNA. Thus, 7AAMD may serve as a good indicator of DNA unwinding, denaturation, and fragmentation.     

Inhibition of cyclin D1 gene transcription by Brg-1

The evolutionarily conserved SWI-SNF chromatin remodeling complex regulates cellular proliferation. A catalytic subunit, BRG-1, is frequently down regulated, silenced or mutated in malignant cells, however, the mechanism by which BRG-1 may function as a tumor suppressor or block breast cancer cellular proliferation is not understood. The cyclin D1 gene is a collaborative oncogene overexpressed in greater than 50% of human breast cancers. Herein, BRG-1 inhibited DNA synthesis and cyclin D1 expression in human MCF-7 breast cancer epithelial cells. The cyclin D1 promoter AP-1 and CRE sites were required for repression by BRG-1 in promoter assays. BRG-1 deficient cells abolished and siRNA to BRG-1 reduced, formation of the BRG-1 chromatin complex. The endogenous cyclin D1 promoter AP-1 site bound BRG-1. Estradiol treatment of MCF7 cells induced recruitment of BRG-1 to the endogenous hpS2 gene promoter. Estradiol, which induced cyclin D1 abundance, was associated with a reduction in recruitment of the co-repressors HP1α/HDAC1 to the endogenous cyclin D1 promoter AP-1/BRG-1 binding sites. These studies suggest the endogenous cyclin D1 promoter BRG-1 binding site functions as a molecular scaffold in the context of local chromatin upon which coactivators and corepressors are recruited to regulate cyclin D1.     

Autoradiographic and ultrastructural study of Cucurbita pepo root cells during their growth and differentiation

Summary Cortex cells of the root meristem of Cucurbita pepo (0.0–0.5 mm from the cap junction), in the 3–4, 5–6 and 7–8 mm segments above the root tip, and the cells of the first three layers of lateral part of root cap were the object of the present study. The volume of cortex cells increases more than 20 times in the 7–8 mm segment as compared with meristematic cells, and the volume of cytoplasm about sevenfold. The largest increment of the cytoplasmic volume occurs between 0.5–6.0 mm. In consecutive root segments the sustained increase of the volume of nuclei takes place. By applying autoradiography the following processess have been investigated: DNA synthesis (³H thymidine uptake), template activity of DNA (³H actinomycin D(³H AMD)-binding), RNA synthesis (³H uridine incorporation), and protein synthesis (³H leucine). In the root cap cells and in segments where meristematic activity is over, DNA is replicated by endomitosis. On the basis of nuclear labelling it appears that nuclei in the 3–4 mm segment reach 4C ploidy state, but in the 7–8 mm segment half of the nuclei reach the 8C ploidy state. Most of the root cap cells are 4C, the remaining cells are 8C. Considering the uptake of ³H thymidine into nucleoli one may suppose that in the root cap cells nucleolar DNA is underreplicated, and to a lesser degree in 5–6 and 7–8 mm segments, while in 3–4 mm segment DNA is overreplicated as compared to meristem cells. Measurements of nucleolar volume, ³H uridine uptake, ³H AMD binding and quantity of granular component, indicate that the most noticeable nucleolar activity takes place in meristematic zone and in root parts showing the highest increase of cytoplasmic volume (3–4 and 5–6 mm segments). ³H leucine is still incorporated intensely into 7–8 mm segment, in which the concentration of ribosomes is low, however they are present in the form of polysomes. Comparison of ³H thymidine uptake into nuclear DNA with ³H AMD binding and ³H uridine incorporation into nuclei indicates that endomitotic DNA replication results in an increase of DNA template activity in root cap cells as well as in 3–4 and 5–6 mm segments; in the 7–8 mm segment binding of ³H AMD slightly decreases, while ³H uridine incorporation is considerably reduced. Divergence between the ploidy state, ³H AMD binding and ³H uridine incorporation can be due to the increment of the condensed chromatin area in differentiated cells. Plastids and mitochondria reach full maturity in 3–4 mm segment. The increasing volume density of ER and diminishing volume density of Golgi structures is accompanied by differentiation of cortex cells.This work was partly supported by Polish Academy of Sciences, Botanical Committee, Grant 217/II     

Caffeine clusters as transmitters of actinomycin antibiotics to DNA in solution

Using the screening model of hypochromism, we showed that caffeine forms regular clusters consisting of 8–12 molecules. Addition of 7-aminoactinomycin D (7AAMD, a fluorescent analogue of actinomycin D) to the clusters leads to its sorption on the cluster surface. Photoexcitation of 7AAMD leads to its desorption from the surface into the aqueous phase and emission of a quantum. Fluorescence of 7AAMD in the presence of caffeine clusters is quenched by dinitrophenol more weakly than without clusters (the quenching constants are ～ 85 and ～280 M^?1, respectively) due to decreased steric availability of the antibiotic to the quencher. Addition of 7AAMD-caffeine complexes to DNA leads to a long-wavelength shift in the excitation spectrum and an increase in the fluorescence intensity along with a shift of the fluorescence spectrum to the short-wavelength area. This fact reflects redistribution of the antibiotic from the caffeine surface to the hydrophobic areas inside DNA.     

Actinomycin D and 7-aminoactinomycin D binding to single-stranded DNA

The potent RNA polymerase inhibitors actinomycin D and 7-aminoactinomycin D are shown to bind to single-stranded DNAs. The binding occurs with particular DNA sequences containing guanine residues and is characterized by hypochromic UV absorption changes similar to those observed in interactions of the drugs with double-stranded duplex DNAs. The most striking feature of the binding is the dramatic (ca. 37-fold) enhancement in fluorescence that occurs when the 7-aminoactinomycin is bound to certain single-stranded DNAs. This fluorescence of the complex is also characterized by a 40-nm hypsochromic shift in the emission spectrum of the drug and an increase in the emission anisotropy relative to the free drug or the drug bound to calf thymus DNA. The fluorescence lifetimes change in the presence of the single-stranded DNA in a manner compatible with the intensity difference. Thus, there is an increase in the fraction of the emission corresponding to a 2-ns lifetime component compared to the predominant approximately 0.5-ns lifetime of the free drug. The 7-aminoactinomycin D comigrates in polyacrylamide gels with the single-stranded DNAs, and the fluorescence of the bound drug can be visualized by excitation with 540-nm light. The binding interactions are characterized by association constants of 2.0 x 10(6) to 1.1 x 10(7) M-1.     

Protein and DNA requirements of the bacteriophage HP1 recombination system: a model for intasome formation

A fundamental step in site-specific recombination reactions involves the formation of properly arranged protein–DNA structures termed intasomes. The contributions of various proteins and DNA binding sites in the intasome determine not only whether recombination can occur, but also in which direction the reaction is likely to proceed and how fast the reaction will go. By mutating individual DNA binding sites and observing the effects of various mixtures of recombination proteins on the mutated substrates, we have begun to categorize the requirements for intasome formation in the site-specific recombination system of bacteriophage HP1. These experiments define the binding site occupancies in both integrative and excisive recombination for the three recombination proteins: HP1 integrase, HP1 Cox and IHF. This data has allowed us to create a model which explains many of the biochemical features of HP1 recombination, demonstrates the importance of intasome components on the directionality of the reaction and predicts further ways in which the role of the intasome can be explored.     

Footprinting of echinomycin and actinomycin D on DNA molecules asymmetrically substituted with inosine and/or 2,6-diaminopurine.

In order to clarify the role of the purine 2-amino group in the recognition of DNA by small molecules we have examined the binding of actinomycin D and echinomycin to artificial DNA molecules asymmetrically substituted with inosine and/or 2,6-diaminopurine (DAP) in one of the complementary strands. These DNAs, prepared by a method based upon PCR, present various potential sites for antibiotic binding, including several containing only a single purine 2-amino group in different configurations. The results show unambiguously that the presence of two 2-amino groups is mandatory for binding of actinomycin D to double-stranded DNA. In the case of echinomycin only one purine 2-amino group is required for remarkably strong binding to the asymmetric TpDAP.TpA dinucleotide step, but the CpDAP.TpI step (which also contains only a single purine-2 amino group) does not afford a binding site. Evidently, removing a 2-amino group (G-->I substitution) is dominant over adding one (A-->DAP substitution). No sequences containing just a single guanine residue are acceptable. The possibility is raised that replacing guanosine with inosine may do more than remove a group endowed with hydrogen bonding capability and interfere with ligand binding in other ways. The new methodology developed to construct asymmetrically substituted DNA substrates for this work provides a novel strategy that should be generally applicable for studying ligand-DNA interactions, beyond the specific interest in drug binding to DNA, and may help to elucidate how proteins and oligonucleotides recognize their target sites.     

Differential zinc and DNA binding by partial peptides of human protamine HP2

The Zn(II) binding by partial peptides of human protamine HP2: HP2_1–15; HP2_1–25, HP2_26–40, HP2_37–47, and HP2_43–57 was studied by circular dichroism (CD). Precipitation of a 20mer DNA by these partial peptides and the effects of Zn(II) thereon were investigated using polyacrylamide gel electrophoresis (GE). The results of this study suggest that reduced HP2 (thiol groups intact) can bind Zn(II) at various parts of the molecule. In the absence of DNA, the primary Zn(II) binding site in reduced HP2 is located in the 37–47 sequence (involving Cys37, His39, His43, and Cys47), while in the presence of DNA, the strongest Zn(II) binding is provided by sequences 12–22 (by His12, Cys13, His19, and His22) and 43–57 (His43, Cys47, Cys53, and His57). In its oxidized form, HP2 can bind zinc through His residues of the 7–22 sequence. Zn(II) markedly enhances DNA binding by all partial peptides. These findings suggest that Zn(II) ions may be a regulatory factor for sperm chromatin condensation processes.     

Selective association between a macrocyclic nickel complex and extrahelical guanine residues.

Nickel-dependent recognition and oxidation of guanine have been linked in part through the paramagnetic effects of nickel on the NMR of model oligonucleotide duplexes. Direct interaction between nickel and guanine N7 had originally been postulated from correlations between the efficiency of guanine oxidation and the environment surrounding its N7 position. (1)H and (31)P NMR spectra of DNA containing a single, isolated extrahelical guanine are consistent with selective binding of nickel to the N7 of this unique base over a background of nonspecific association to the phosphate backbone. The presence of a macrocyclic complex or simple salt of nickel did not detectably alter the structure of the duplex or extrahelical residue. Accordingly, nickel appeared to bind the extrahelical guanine N7 within the major groove as indicated by paramagnetic effects on the proton signals of nucleotides on the 5' but not 3' side of the nickel binding site. Similar (1)H NMR analysis of DNA containing a dynamic equilibrium of extrahelical guanine residues also suggested that the nickel complex did not affect the native distribution of structures. Oxidation of these sites by a nickel-mediated pathway consequently reflected their solvent accessibility in a general and metal-independent manner. The close proximity of the extrahelical guanines produced a composite of paramagnetic effects on each adjacent nucleotide resulting from both direct and proximal coordination of nickel.     

Caffeine clusters as transmitters of actinomycin antibiotics to DNA in solutions

Using the screening model of hypochromism, we showed that caffeine forms regular clusters consisting of 8-12 molecules. Addition of 7-aminoactinomycin D (7AAMD, a fluorescent analogue of actinomycin D) to the clusters leads to its sorption on the cluster surface. Photoexcitation of 7AAMD leads to its desorption from the surface into the aqueous phase and emission of a quantum. Fluorescence of 7AAMD in the presence of caffeine clusters is quenched by dinitrophenol more weakly than without clusters (the quenching constants are approximately 85 and approximately 280 M(-1), respectively) due to decreased steric availability of the antibiotic to the quencher. Addition of 7AAMD-caffeine complexes to DNA leads to a long-wavelength shift in the excitation spectrum and an increase in the fluorescence intensity along with a shift of the fluorescence spectrum to the short-wavelength area. This fact reflects redistribution of the antibiotic from the caffeine surface to the hydrophobic areas inside DNA. The English version of the paper: Russian Journal of Bioorganic Chemistry, 2008, vol. 34, no. 2; see also http://www.maik.ru.     

Molecular biological analysis of sequence-specific DNA recognition and cleavage by metallobleomycins

The DNase I footprinting analysis shows binding sites of approximately two or three base pairs, in particular 5'-XGC sequences, for the green-colored Co(III) and fully oxidized Fe(III) complexes of bleomycin (BLM). In contrast to covalent attachment of guanine N-7 with aflatoxin B1 or dimethyl sulfate, the modification of guanine 2-amino group with anthramycin remarkably inhibits the DNA cleavages at 5'-GC and 5'-GT sites by the iron and cobalt complex systems of BLM. The present results strongly indicate that metallobleomycin binds in minor groove of B-DNA and that the 2-amino group of guanine adjacent to 5'-side of the cleaved pyrimidine base is one key element of specific 5'-GC or 5'-GT recognition by metallobleomycin. On the basis of these experimental data, possible binding mode of metallobleomycin in B-DNA helix has been proposed by computer-constructed model building.     

DNA-copper (II) complex and the DNA conformation

Spectrophotometric, sedimentation, infrared, optical rotatory dispersion (ORD), and circular dichroism (CD) methods have been used to demonstrate the structural changes in DNA induced by the interaction of copper(II) with bases and to elucidate the complex binding sites. As shown by the electrolyte-induced reversion (addition of salts) of temperature-denatured copper DNA the effectiveness of re-formation of the double-stranded structure depends on the temperature, copper(II) ion concentration, and on the base composition of the DNA. Exposure of heat-denatured copper DNA to higher temperatures decreases the reversion effect on addition of electrolyte. The results indicate that a greater fraction with a cooperative transition appears on heating DNA to 80 or 100°C at a Cu²⁺/DNA-P ratio of 2 : 1 than at a Cu²⁺/DNA-P ratio of 1 : 1. With AT-rich copper DNA, reversion to the native DNA structure was not observed. Selective methylation of guanine residues in DNA also affects the electrolyte-induced reversion, indicating the importance of GC pairs for copper(II) binding and the reversion to the native structure. Temperature-denatured copper DNA shows an increased sedimentation coefficient Which decreases again after electrolyte-induced reversion. This change in s is reduced by selective methylation of DNA. Complex formation between copper(II) and the bases is accompanied by a conformational change of the DNA double-helical structure as demonstrated by ORD and CD experiments. The ORD profile of GC-rich DNA is much more affected by copper(II) than that of AT-rich ones. Even at very low copper(II) concentrations, e.g., at 0.02 and 0.2 Cu²⁺/DNA-P, the ORD and CD measurements exhibit conformational changes of the DNA secondary structure at room temperature. By comparing the infrared spectra of deoxynucleosides with that of DNA of different GC content it has been shown that both guanine and cytosine are involved in the formation of the complex of copper(II) with DNA. N-7 and O at C-6 in guanine and N-3 as well as O of C-2 in cytosine are discussed as the most probable binding sites in DNA. A binding model for the coordination of the copper(II) ion between guanine and cytosine of the opposite strands is suggested. The results are in good agreement with the assumptions and predictions made by Eichhorn and Clark about the complexing of copper(II) with DNA. The recent proposal made by Schreiber and Daune about an interaction of the type guanine–Cu²⁺–guanine cannot be excluded as an additional kind of coordination of copper(II) in DNA.