Cluster melting of DNA-actinomycin complexes

Sensitive methods of differential UV spectrophotometry and differential scanning microcalorimetry were used to study the interaction of small and large quantities of the natural antitumor antibiotic actinomycin D with clusters of native and fragmented calf thymus DNA during thermal melting. At micromolar (physiological) concentrations, actinomycin is incorporated in untwisted sites of DNA rather than in the double helix. Actinomycin stabilizes these sites and therefore slightly increases the overall melting temperature of DNA. The antibiotic effectively interacts with the nucleotides of native DNA at a ratio of 1: 868, especially strongly with the clusters of satellite fractions and DNA fragments. At low concentrations, it stabilizes the «loose» bilizes the double helix and causes DNA aggregation.     

Energy of interaction in actinomycin-nucleotide complexes

Complexes of the natural heterocyclic antibiotic actinomycin D (AMD) with its putative carriers: purine and pyrimidine nucleotides, as well as with fragmented DNA and phospholipid liposomes have been studied by high-sensitivity spectrophotometry. The antibiotic is not only adsorbed onto the surface of purine clusters but also is incorporated into them. It is especially readily incorporated into unwound DNA regions. The incorporation is accompanied by a long-wavelength shift of the absorption spectrum. From the magnitude of the shift, the energy of interaction was calculated. In the case of AMD in the complex with caffeine and adenosine, it is 2.4 and 2.7 kcal/mol, and in the complex with guanosine and fragmented DNA it is considerably higher, 3.3 and 3.7 kcal/mol. It is assumed that guanosine, adenosine, caffeine and fragmented DNA may serve as carriers of the antibiotic.     

Actinomycin D in low concentrations binds uniformly to human chromosomes

The binding of actinomycin D (actD) to fixed human metaphase chromosomes was studied by using autoradiography with [3H]actD and indirect immunofluorescence with a specific anti-actD antibody. At concentrations of 0.01 and 0.1 micrograms/ml there was a uniform distribution of drug along the chromosomes as observed by both methods. This is the first study to date characterizing actD binding at such low concentrations to human chromosomes. Since actD intercalates into the DNA helix with GC specificity, our observations indicate that detectable differences in base composition along the lengths of human chromosomes are minimal.     

Specific interactions between DNA left-handed supercoils and actinomycin D

The interactions between the natural cyclopentapeptide antibiotic actinomycin D (ACT) and circular pBR322 DNA have been studied by freezing the topological state of the DNA in the complex by topoisomerase I reaction. Both supercoiled and relaxed DNAs, in the complexes at low antibiotic/DNA base-pair ratios, showed a dramatic decrease in linking number that cannot be explained by taking into account only the generally accepted unwinding of 28 degrees for each ACT molecule bound. Recent results derived from the crystallographic analysis of the complex between GpC and ACT suggest that ACT could mediate non-covalent cross-links between distant sections of DNA. Bridges between ACT and different sections of the pBR322 double helix could also explain our results. Two-dimensional gel electrophoresis of ACT-relaxed pBR322 DNA complexes reveals that all supercoils induced by ACT are negative. Two models of the complexes which correspond to the stabilization of DNA crossing by one or two molecules of ACT are proposed. In both cases the ability of ACT to stabilize only DNA left-handed supercoils is derived from the chirality of ACT, when it interacts with DNA.     

Effect of low-molecular amines on DNA conformation and stability of the double helix]

Interaction of low-molecular amines (cystamine, cysteamine, cystaphose, asparagine, beta-alanine) with DNA was studied. The amines change the positive circular dichroism (CD) band of DNA as well as temperature and range width of melting. Effect of amines on DNA depends on ionic strength of the solvent, concentration and structure of the ligand. Monamines cause destabilization of DNA double helix followed by stabilization as ligand concentration increases. At concentrations stabilizing the double helix DNA conformation undergoes transition from the B- to C-form. The results obtained enable to relate the stabilizing effect of low-molecular amines and conformational B leads to C-transition to the non-specific interaction of ligand amino groups with DNA phosphates, and the destabilizing effect of monoamines of low concentrations to their interaction with bases, mainly in the denaturated sites of DNA. It is proposed that a stronger effectiveness of amines as compared to monovalent metals in the conformational shift of DNA towards the C-form is due to the additional effect of disturbance of hydrophobic interactions in DNA double helix.     

Mechanical stability of single DNA molecules

Using a modified atomic force microscope (AFM), individual double-stranded (ds) DNA molecules attached to an AFM tip and a gold surface were overstretched, and the mechanical stability of the DNA double helix was investigated. In lambda-phage DNA the previously reported B-S transition at 65 piconewtons (pN) is followed by a second conformational transition, during which the DNA double helix melts into two single strands. Unlike the B-S transition, the melting transition exhibits a pronounced force-loading-rate dependence and a marked hysteresis, characteristic of a nonequilibrium conformational transition. The kinetics of force-induced melting of the double helix, its reannealing kinetics, as well as the influence of ionic strength, temperature, and DNA sequence on the mechanical stability of the double helix were investigated. As expected, the DNA double helix is considerably destabilized under low salt buffer conditions (相似文献   

Ultrasonic Footprinting

Ligand binding influences the dynamics of the DNA helix in both the binding site and adjacent regions. This, in particular, is reflected in the changing pattern of cleavage of complexes under the action of ultrasound. The specificity of ultrasound-induced cleavage of the DNA sugar-phosphate backbone was studied in actinomycin D (AMD) complexes with double-stranded DNA restriction fragments. After antibiotic binding, the cleavage intensity of phosphodiester bonds between bases was shown to decrease at the chromophore intercalation site and to increase in adjacent positions. The character of cleavage depended on the sequences flanking the binding site and the presence of other AMD molecules bound in the close vicinity. A comparison of ultrasonic and DNase I cleavage patterns of AMD–DNA complexes provided more detail on the local conformation and dynamics of the DNA double helix in both binding site and adjacent regions. The results pave the way for developing a novel approach to studies of the nucleotide sequence dependence of DNA conformational dynamics and new techniques to identify functional genome regions.     

Stereochemistry of actinomycin binding to DNA : II. Detailed molecular model of actinomycin-DNA complex and its implications

The three-dimensional structure of a crystalline complex containing actinomycin D and deoxyguanosine (described in the previous paper) has shed light on the stereochemistry of actinomycin binding to DNA. The phenoxazone ring system on actinomycin intercalates between the base-paired dinucleotide sequence, GpC, while the peptide subunits lie in the narrow groove of the DNA helix and interact with deoxyguanosine residues on opposite chains through specific hydrogen bonds. The binding of actinomycin to DNA demonstrates a general principle which several classes of proteins may utilize in recognizing symmetrically arranged nucleotide sequences on the DNA helix.     

Nucleic acid helix-coil transitions mediated by helix-unwinding proteins from calf thymus.

We have studied nucleic acid double helix destabilization mediated by purified calf helix-unwinding proteins, measuring ultraviolet hyperchromicity to detect helix melting. Both calf unwinding protein 1 (UP1) and a high salt eluting protein fraction are found to depress strongly the helix melting temperature (Tm) of the synthetic alternating copolymers poly[d(AT)] and poly[r(AU)], indicating that both DNA and RNA are recognized by these proteins. UP1 also destabilizes natural, GC-containing DNA helices, but to a smaller extent than observed with the above polymers. A simple model is presented to aid in the qualitative interpretation of the data, outlining the expected effect on the helix-coil transition of a protein ligand with differential affinity for the helix or coil form of nucleic acid. The observed helix-destabilizing effect of UP1 is dependent on the protein to nucleic acid ratio in an expected manner. Competition studies demonstrate a low, but appreciable affinity of UP1 for native DNA, opening the possibility that protein-mediated denaturation might be initiated by protein binding to the double helix. "Hairpin" helical regions of denatured DNA are strongly destabilized by UP1. Despite the fact that removal of these hairpin helices might greatly facilitate DNA renaturation, we failed to observe renaturation from the UP1-DNA complex after a switch to helix-stabilizing conditions. Thus, UP1 shows an important difference from its presumed prokaryotic analogue, T4 gene 32-protein. Possible in vivo functions of the calf proteins are discussed in light of these observations.     

Comparison of the effects of zinc deprivation and actinomycin D on ribonucleic acid synthesis by stimulated lymphocytes.

1. EDTA inhibited incorporation of [3H]uridine into RNA of lymphocytes, but did not decrease uptake into the cold-acid-soluble fraction of the cells. The inhibition by EDTA was largely reversible by simultaneous addition of Zn2+. 2. Low concentrations pf actinomycin D (3 ng/ml) added at the time of stimulation of the cells inhibited [3H]uridine incorporation into RNA, but concentrations of 50-100 ng/ml were required to produce the same degree of inhibition if addition of actinomycin D was delayed until just before the incorporation was measured. This difference in sensitivity did not reg within the cells. 3. When added immediately before phytohaemagglutinin, actinomycin D (3 ng/ml) and EDTA produced similar time-courses of inhibition of uridine incorporation. 4. Uridine incorporation at 32h was inhibited when actinomycin D (3 ng/ml) or EDTA was added just before stimulation of the cells, but was only slightly affected when they were added at 32h. At intermediate times the incorporation of uridine remained sensitive to addition of EDTA for longer than it was sensitive to actinomycin D. 5. Polyacrylamide-gel separation of RNA synthesized in EDTA-treated cultures in the presence or absence of added Zn2+ showed that lower availability of Zn2+ resulted in a decreased rate of transfer of radioactivity from 32S to 28S rRNA and decreased survival of 28S rRNA relative to 18S rRNA. 6. Close similarities have been shown to exist between the effects of EDTA and low concentrations of actinomycin D. Not all the effects of EDTA could be explained by postulating that Zn2+ was a constituent of RNA polymerase I, nor were the effects of actinomycin D readily explained by previously suggested mechanisms of action of this antibiotic.     

Effect of actinomycin D on purified DNA-dependent RNA polymerases from normal and neoplastic tissues

The effect of low concentrations of actinomycin D was investigated, using two forms of DNA-dependent RNA polymerase (A and B) purified from normal tissues and experimental tumours, in the presence either of Mn2+ or Mg2+, and homologous DNA. The A enzyme activity was strongly inhibited by the antibiotic in presence of Mg2+ and much less in presence of Mn2+. The B enzyme activity was almost suppressed in presence of both cations. The results here reported provide support that the actinomycin D induce a cellular damage of the same extent in normal and tumour tissues.     

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.     

Use of the antibiotics actinomycin D and distamycin A to limit the action of restriction endonucleases and to map DNA

It is shown that distamycin A and actinomycin D protect the recognition sites of certain restriction endonucleases from the attack by these nucleases due to specific interaction of these antibiotics with double-stranded DNA. Distamycin A protects A-T containing sites and actinomycin G-C rich sites. Among Hind II recognition sites which have alternative structure (GTPyPuAC) distamycin A protects only Hpa I similar sites (GTTAAC). It is shown with several restriction endonucleases that antibiotic action depends on the nucleotide sequences in the recognition sites and in their closest environment. Proper concentrations of antibiotic give rise to larger fragments. Use of both distamycin A and actinomycin D allows to obtain a set of overlapping fragments. The data obtained with various DNAs and restriction endonucleases allow to conclude that these antibiotics may be useful for DNA mapping and for preparation of large functional fragments of DNA.     

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 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 efficiency of the energy transfer 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.     

Mode of Action of Antibiotic U-20,661

Antibiotic U-20,661 was shown to inhibit predominantly deoxyribonucleic acid (DNA)-directed ribonucleic acid (RNA) synthesis by binding to the double-stranded DNA template. Specific binding to DNA was verified by difference spectroscopy, reversal of the RNA polymerase inhibitory effect by increasing concentrations of DNA template, and by moderately increasing the melting temperature of double-stranded DNA in the presence of the antibiotic. The RNA polymerase reaction primed with synthetic poly dAT was inhibited considerably, but not completely even with high concentrations of antibiotic. Thus, the agent might bind to adenine or thymidine or both bases in the double-stranded DNA helix.     

Effect of magnesium ions on heat denaturation of DNA

The dependence of animal DNA denaturation on magnesium ion concentration has been studied in the range (10(-6)--10(-1) M with sodium ion content of 10(-3) and 10(-2) M. Special attention has been given to the effect of multivalent metallic impurities bound to DNA. An increase of DNA thermal stability has been shown to occur in the magnesium concentration rage of 10(-6)--10(-4) M. At concentrations exceeding 10(-3) M the T M begins to decrease. The dependence of the DNA melting range on magnesium ion concentration has a maximum at approximately 10(-5) M Mg2+. At low magnesium and sodium ion concentrations a strong asymmetry of the melting curves has been observed. This effect can be described in terms of the melting theory for DNA complexed with small molecules and is explained by magnesium ion redistribution from the denatured portions of DNA to native ones. The method for calculation of melting curves in the DNA-ligand system has been proposed. Studies of thermal denaturation parameters have been shown to be an effective method for the estimation of binding constants of ligands to native and denatured DNA.     

The effect of melittin on proliferation and death of thymocytes

The effect of melittin, an activator of phospholipase A₂, on proliferation and death of rat thymocytes in a broad concentration range was studied. Cell proliferation was estimated by the accumulation of colchicin metaphases, necrotic death was determined from lysis and staining of cells with trypan blue, and apoptosis was assessed from the type of DNA fragmentation, the amount of fragmented DNA, and the percentage of cells with subdiploid DNA. It was shown that low melittin concentrations (below 5 μg/ml) stimulate thymocyte proliferation. At high melittin concentrations, thymocytes die by the primary necrosis type. Throughout the concentration range studied, melittin does not produce apoptosis in thymocytes. Conversely, high melittin concentrations even inhibit thymocyte apoptosis in the control and after irradiation. An inhibitor of RNA synthesis actinomycin D does not affect thymocyte death in the presence of melittin. It is concluded that the activation of phospholipase A₂ can induce necrosis but not apoptosis and thus is not a necessary step in the signaling cascade that initiates apoptosis in thymocytes.     

Base-stacking and base-pairing contributions into thermal stability of the DNA double helix

Two factors are mainly responsible for the stability of the DNA double helix: base pairing between complementary strands and stacking between adjacent bases. By studying DNA molecules with solitary nicks and gaps we measure temperature and salt dependence of the stacking free energy of the DNA double helix. For the first time, DNA stacking parameters are obtained directly (without extrapolation) for temperatures from below room temperature to close to melting temperature. We also obtain DNA stacking parameters for different salt concentrations ranging from 15 to 100 mM Na⁺. From stacking parameters of individual contacts, we calculate base-stacking contribution to the stability of A•T- and G•C-containing DNA polymers. We find that temperature and salt dependences of the stacking term fully determine the temperature and the salt dependence of DNA stability parameters. For all temperatures and salt concentrations employed in present study, base-stacking is the main stabilizing factor in the DNA double helix. A•T pairing is always destabilizing and G•C pairing contributes almost no stabilization. Base-stacking interaction dominates not only in the duplex overall stability but also significantly contributes into the dependence of the duplex stability on its sequence.     

THE DIFFERENTIAL SENSITIVITY OF CULTURED CHICK MESODERMAL CELLS TO ACTINOMYCIN D

Cells were isolated from the somite mesoderm and from the unsegmented (presomite) mesoderm of early chick embryos and exposed to actinomycin D in single cell culture. Actinomycin D inhibited proliferation in cell cultures derived from the unsegmented mesoderm, although the same concentrations of this antibiotic did not inhibit cultures derived from the somite mesoderm. This differential sensitivity parallels the regionally specific necrosis and degeneration observed in the unsegmented mesoderm of intact chick embryos exposed to actinomycin D. In culture, both cell types exhibited approximately the same permeability to labeled actinomycin D and showed comparable inhibition of RNA, DNA, and protein syntheses in the presence of the antibiotic. However, freshly isolated mesodermal cells from the somite region had a higher content of RNA than did cells from the unsegmented region, and the somite cells maintained a higher rate of macromolecular synthesis in untreated cultures.     

Crystal structure of the 2:1 complex between d(GAAGCTTC) and the anticancer drug actinomycin D.

The crystal structures of the 2:1 complex of the self-complementary DNA octamer d(GAAGCTTC) with actinomycin D has been determined at 3.0 A resolution. This is the first example of a crystal structure of a DNA-drug complex in which the drug intercalates into the middle of a relatively long DNA segment. The results finally confirmed the DNA-actinomycin intercalation model proposed by Sobell & co-workers in 1971. The DNA molecule adopts a severely distorted and slightly kinked B-DNA-like structure with an actinomycin D molecule intercalated in the middle sequence, GC. The two cyclic depsipeptides, which differ from each other in overall conformation, lie in the minor groove. The complex is further stabilized by forming base-peptide and chromophore-backbone hydrogen bonds. The DNA helix appears to be unwound by rotating one of the base-pairs at the intercalation site. This single base-pair unwinding motion generates a unique asymmetrically wound helix at the binding site of the drug, i.e. the helix is loosened at one end of the intercalation site and tightened at the other end. The large unwinding of the DNA by the drug intercalation is absorbed mostly in a few residues adjacent to the intercalation site. The asymmetrical twist of the DNA helix, the overall conformation of the two cyclic depsipeptides and their interaction mode with DNA are correlated to each other and rationally explained.