Infrared linear dichroism studies of DNA-drug complexes: quantitative determination of the drug-induced restriction of the B-A transition.

The B-A transition of films or fibers of NaDNA occurs at a relative humidity of 75-85%. The fraction of DNA that changed the conformation from B to A form can be determined quantitatively by infrared linear dichroism. DNA-binding drugs can 'freeze' a fraction of DNA in the B form. This fraction of DNA is in the B form and cannot be converted to A-DNA even at a reduced relative humidity of 54%. The 'freezing' potentiality of various drugs can be described by the 'freezing' index, FI, expressed in base pairs per added drug. Drugs with a high value of FI (more than eight base pairs per drug) were observed among both intercalating and groove-binding drugs. High values of FI imply restriction of the conformational flexibility of DNA significantly going beyond the binding site of the drug. This long-range effect of drugs on the conformational flexibility of DNA may be connected with the molecular mechanism of drug action. The freezing index FI is a new quantitative parameter of drug-DNA interaction that should be considered as a valuable tool for drug design.     

IR spectroscopic research on the impact of chemical analogues of autoregulatory d1 factors of microorganisms on structural changes in DNA

Using IR spectroscopy, we investigated the impact of chemical analogues of autoregulatory d1 factors of microorganisms (methylresorcinol, hexylresorcinol, and tyrosol) on the conformational changes in DNA in films upon altering (decreasing) the relative humidity. We analyzed the appearance/disappearance of characteristic absorption bands of A and B DNA forms and determined D1080/D1224, the ratio between the band intensities of symmetrical and asymmetrical oscillations in their phosphate groups. The data obtained suggest the slowing down of the B-->A structural transition in DNA in the presence of methylresorcinol and its speeding up in the presence of tyrosol. We discuss the mechanisms of this phenomenon in relation to the chemical composition of d1 factors and their biological function.     

X-ray diffraction from DNA fibres under tension

When DNA fibres are stretched during drying, the polymer undergoes a conformational transition. We present quantitative results from X-ray diffraction studies on such fibres held at various ambient relative humidities. These indicate that the molecules are arranged in arrays which are crystalline in projection down the fibre axis. The packing can be explained in terms of a hexagonal cell with a lattice parameter, a, of approximately 13 A which varies with humidity. The patterns contain meridional intensities at 1/3.4 A(-1) and 1/6.5 A(-1), a strong off-meridional intensity at Z=1/5.6 A(-1) and diffuse scatter at Z=1/28 A(-1).     

Hydration of biological molecules: lipids versus nucleic acids

We used FTIR spectroscopy to comparatively study the hydration of films prepared from nucleic acids (DNA and double-stranded RNA) and lipids (phosphatidylcholines and phosphatidylethanolamines chosen as the most abundant ones) at room temperature by varying the ambient relative humidity in terms of solvent-induced structural changes. The nucleic acids and phospholipids both display examples of polymorphism on the one hand and structural conservatism on the other; even closely related representatives behave differently in this respect. DNA undergoes a hydration-driven A-B conformational transition, but RNA maintains an A-like structure independently of the water activity. Similarly, a main transition between the solid and liquid-crystalline phases can be induced lyotropically in certain phosphatidylcholines, while their phosphatidylethanolamine counterparts do not exhibit chain melting under the same conditions. A principal difference concerning the structural changes that occur in the studied biomolecules is given by the relevant water-substrate stoichiometries. These are rather high in DNA and often low in phospholipids, suggesting different mechanisms of action of the hydration water that appears to induce structural changes on global- and local-mode levels, respectively.     

Dynamic mechanical properties of solid films of deoxyribonucleic acid

Solid films of deoxyribonucleic acid (DNA) from salmon testes were prepared by a solvent-casting method. The thermal molecular motion of the DNA film was examined by dynamic mechanical analysis (DMA). Four absorption peaks and one shoulder of the loss modulus were observed in the temperature domain from approximately 150 to 490 K. To assign these, thermal analysis employing thermogravimetry (TG) and differential thermal analysis (DTA) was used in conjunction with ultraviolet (UV)-visible and Fourier-transform infrared (FT-IR) spectroscopy. It seems most likely that, in order of increasing temperature, they are a B(I)→B(II) conformational transition, a relatively large-scale movement associated with water molecules, water evaporation, thermal denaturation of DNA, and a glass transition.     

IR spectroscopic research on the impact of chemical analogues of autoregulatory d<Subscript>1</Subscript> factors of microorganisms on structural changes in DNA

Using IR spectroscopy, we investigated the impact of chemical analogues of autoregulatory d₁ factors of microorganisms (methylresorcinol, hexylresorcinol, and tyrosol) on the conformational changes in DNA in films upon altering (decreasing) the relative humidity. We analyzed the appearance/disappearance of characteristic absorption bands of A and B DNA forms and determined D ₁₀₈₈/D ₁₂₂₄, the ratio between the band intensities of symmetrical and asymmetrical oscillations in their phosphate groups. The data obtained suggest the slowing down of the B → A structural transition in DNA in the presence of methylresorcinol and its speeding up in the presence of tyrosol. We discuss the mechanisms of this phenomenon in relation to the chemical composition of d 1 factors and their biological function.     

Counterion effects on the physical properties and the A to B transition of calf-thymus DNA films

We report measurements of the water content and swelling of wet-spun films of Na-, K-, Rb-, and Cs-DNA as a function of relative humidity (rh). The water contents (number of water molecules per base pair of DNA) of these films are found to be quite similar, indicating that the identity of the counterion species is unimportant for the water content. Since the A to B transition for these DNAs occurs at different rhs, the corresponding water contents of the A to B transition are found to be quite different. These films swell as a function of rh in a very similar manner, implying that the changes in the intermolecular bonds in the different DNAs are similar. Dramatic changes are observed in the dimensions of the films above 84% rh for all types of DNA. Combining the water content and swelling measurements yields the dependence of the volume per base pair on water content. The volume per base pair is observed to be a nonlinear function of water content, indicating nonideal mixing of the water with the DNA.     

Conformational transition of DNA induced by cationic lipid vesicle in acidic solution: spectroscopy investigation

The conformational transition of DNA induced by the interaction between DNA and a cationic lipid vesicle, didodecyldimethylammonium bromide (DDAB), had been investigated by circular dichroism (CD) and UV spectroscopy methods. We used singular value decomposition least squares method (SVDLS) to analyze the experimental CD spectra. Although pH value influenced the conformation of DNA in solution, the results showed that upon binding to double helical DNA, positively charged liposomes induced a conformational transition of DNA molecules from the native B-form to more compact conformations. At the same time, no obvious conformational changes occurred at single-strand DNA (ssDNA). While the cationic lipid vesicles and double-strand DNA (dsDNA) were mixed at a high molar ratio of DDAB vesicles to dsDNA, the conformation of dsDNA transformed from the B-form to the C-form resulting in an increase in duplex stability (DeltaT(m)=8+/-0.4 degrees C). An increasing in T(m) was also observed while the cationic lipid vesicles interacted with ssDNA.     

Spectral analysis of chromatin and its components in the vacuum ultraviolet region of the spectrum

Electronic absorption spectra of thin films of chromatin and chromatin components in ultraviolet (140-280 nm) were investigated. The absorption coefficients mu (lambda) of chromatin, nucleosomes with and without histone H1, total histones (TH), DNA were compared. The spectra of nucleosomes and chromatin differ from summary spectra of DNA + TH. The lack of additivity of absorption coefficients at different wavelengths may be explained by different conformational changes of free DNA, TH and DNA, TH in nucleosomes and chromatin during the process of drying aqueous solutions for the preparations of thin films. The obtained mu (lambda) values are necessary for the estimation of the DNA and TH parts of absorption in chromatin and nucleosomes in the investigations of UV and VUV irradiation damages.     

Infrared linear dichroism of oriented DNA-ligand complexes prepared with the wet-spinning method.

Oriented DNA films prepared by the wet-spinning technique have been complexed with several ligands: the anthracycline antibiotic violamycin BI, the dipeptide L-carnosine, and the oligopeptide antibiotic netropsin. The formation of the DNA-ligand complexes is accompanied by dramatic changes of the conformational flexibility of DNA. The B-A transition which occurs usually between 80% and 70% relative humidity (RH) is more or less suppressed by the ligands. Violamycin BI at a total ligand per DNA base pair ratio, rt, of approximately 0.03 and L-carnosine at rt approximately 1.5 inhibit the B-A transition of approximately 18 and approximately 0.25 base pairs per ligand molecule, respectively. Netropsin at rt = 0.2 induces a very stable B-DNA even at rather low RH (23%). The total hydration of this complex is significantly higher than for a drug-free DNA film. Netropsin-DNA complexes at rt of 0.02 and 0.01 result in an inhibition of approximately 45 base pairs per drug molecule with respect to the B-A transition.     

Conformation and thermostability of double-stranded nucleic acids in aqueous urea solutions

The conformation and thermostability of DNA and double-helical synthetic RNA in aqueous solutions with 0-10 M urea have been investigated. A weak dependence of DNA conformation, realized in the presence of urea, on the GC-content has been found. The increase of urea concentration leads to destabilization of DNA and synthetic RNA. The character of changes in the spectra of RNA circular dichroism at the increase of urea concentration testifies that a conformational transition (different from A----A' transition) takes place. Urea stimulates the B----Z transition in poly(dG-dC).poly(dG-dC) molecules upon NaCl addition.     

Force-induced structural transitions in cross-linked DNA films

We report on the preparation and characterization of wet-spun films of sodium DNA in which intermolecular cross-links were introduced following formaldehyde treatment. Raman scattering shows that the DNA in moderately cross-linked films is mainly in the B conformation. Stretching experiments show a transition from plastic to elastomeric behavior with increasing exposure to the cross-linking agent. Elastomeric DNA films are strongly disordered. X-ray diffraction shows that stretching of moderately cross-linked films under controlled high humidity conditions results in increased molecular orientation as well as the appearance of meridional reflections at 7.4-7.8 and 8.2 A. These reflections are not observed for any of the classical conformations associated with mixed sequence DNA, and may arise from extended base-pair stacking in a stretched DNA structure.     

DNA conformation and thermostability of aqueous solutions of beta-alanine and gamma-aminobutyric acid

It has been shown that at low concentrations of rare amino acids (from 10(-3) M to 10(-1) M of the substance) stechiometric complexes amino acid -- DNA are formed, which bring about partial substitution of counterions screening phosphate groups and to a change of spatial structure of DNA water molecules. The DNA-solvent molecular interactions are changed, accompanied by an abrupt decrease of helix-coil enthalpy transition which leads to the unwinding of DNA double helix. In the region of amino acid high concentrations (greater than 1-1,5 M) a rise of thermostability and winding of DNA double helix is observed. It has been established that B----C-like conformational transition stimulated by the rise of DNA thermostability is a result of counterions dehydration and the increase of effective ionic strength of the solution which is due to the rise of amino acid-zwitterions content in it.     

Enhanced structural transformations in DNA macromolecules exposed to weak thermalized neutron field

We examined now an ultraweak thermalized neutron field (UTNF) affects the structural transformation in DNA macromolecules at room temperature. IR-spectroscopy, electrophoresis, and filtration through nitrocellulose filter measurements revealed that UTNF irradiation with a fluence of F(n) - 1.0 - 3.7 x 10(7) n/cm2 (the absorbed dose as low as 10 - 50 microGy) can induce non negligible structural changes in DNA macromolecules in film as well as in an aqueous solution. These structural changes appear as a type of reversible conformational transition from the A-form to a disordered state, as well as through intermolecular cross-link formations and the generation of double-strand breaks.     

A Raman study of the hydration of wet-spun films of Li-hyaluronate

Raman spectroscopy between 620 and 1700 cm(-1) has been performed on wet-spun films of Li-hyaluronate as a function of relative humidity between 54 and 93% at room temperature. The observed vibrational modes show no significant dependence on water content, suggesting that the molecule does not undergo any conformational transitions in this humidity range.     

Photochemical probing of the B--a conformational transition in a linearized pUC19 DNA and its polylinker region

We induced the B-to-A conformational transition by ethanol in a linearized pUC19 DNA. A primer extension method was used in combination with UV light irradiation to follow the transition, based on pausing of DNA synthesis due to the presence of damaged bases in the template. Primer extension data highly correlated with the results of another method monitoring the B-A transition, i.e. inhibition of restriction endonuclease cleavage of UV light-irradiated DNA. Primer extension enabled us to locate damaged nucleotides within the region of interest. Most damaged nucleotides were located in B-form trimers, exclusively containing both pyrimidine bases (TTC, TCT, CTC, and CTT), and in a cytosine tetramer. The amount of damaged bases decreased in the course of B-A transition. Some of the damage even disappeared in the A-form, which mainly concerns the C(4) and C(3) blocks. The cleavage was nearly restored in the A-form within this region (Eco88I). On the contrary the decrease of damage was less significant with thymine dimers, only dropping to 50-60% of the B-form level. Consequently, the cleavage with EcoRI and HindIII remained mostly as before the transition (75% and 60% of uncleaved DNA preserved). We found significant differences in the B- and A-form pattern of UV light-damaged bases within the same region (polylinker) of DNA embedded within long (plasmid) or short (127 bp fragment) DNA molecules. The B-A transition of the fragment was found less cooperative than with linearized plasmid, which was confirmed by both CD spectroscopy and restriction cleavage inhibition.     

Extent of equilibrium perturbation of the DNA helix upon enzymatic methylation of adenine residues

The extent of equilibrium perturbation of the DNA helix associated with enzymatic methylation of dA residues has been determined by the agarose gel electrophoresis band-shift method. Utilization of EcoRI methylase under conditions of reduced specificity together with Escherichia coli dam methylase permitted modification of up to 300 dA residues/plasmid pBR322 dimer. A conformational change associated with methylation was observed, with the magnitude of the transition being linear with extent of modification of relaxed DNA circles. The conformational change corresponds to an unwinding of the DNA helix by 0.5 degrees/methyl group transferred to relaxed molecules. The magnitude of the effect was independent of temperature from 5-37 degrees C indicating that it is not the consequence of a thermal transition within this range.     

AFM studies of DNA structures on mica in the presence of alkaline earth metal ions

As counterions of DNA on mica, Mg(2+), Ca(2+), Sr(2+) and Ba(2+) were used for clarifying whether DNA molecules equilibrate or are trapped on mica surface. End to end distance and contour lengths were determined from statistical analysis of AFM data. It was revealed that DNA molecules can equilibrate on mica when Mg(2+), Ca(2+) and Sr(2+) are counterions. When Ba(2+) is present, significantly crossovered DNA molecules indicate that it is most difficult for DNA to equilibrate on mica and the trapping degree is different under different preparation conditions. In the presence of ethanol, using AFM we have also observed the dependence of B-A conformational transition on counterion identities. The four alkaline earth metal ions cause the B-A transition in different degrees, in which Sr(2+) induces the greatest structural transition.     

Circular dichroism studies of salt- and alcohol- induced conformational changes in cyanophage S-2L DNA which contains amino 2 adenine instead of adenine.

DNA molecules containing AT pairs exhibit cesium cation specific conformational behavior. This specificity is shown to be cancelled with the title DNA, which not only concerns its conformational alterations in high-salt aqueous solutions but also the B-to-A transition induced by ethanol. S-2L DNA easily adopts the A-conformation in the presence of millimolar concentrations of CsCl which completely destabilize the A-conformation in calf thymus DNA. The present results demonstrate that the specific effects of cesium cations on DNA are connected with their binding to the AT pairs in the DNA minor groove.     

Ultraviolet dichroic ratio of DNA from T2 and T5 bacteriophages

The dichroic ratios of T5st-O and T2H bacteriophage DNA molecules were measured throughout the ultraviolet region of the spectrum. Two methods of DNA orientation were studied: (1) orientation in solution in a Shimadzu flow dichroism instrument attached to a Beckman DU spectrophotometer, and (2) alcohol precipitation of the DNA from solution and orientation in a thin film on the quartz face of a humidity chamber. Spectra in the latter case were recorded using a Gary Model 14 spectrophotomcter fitted with Glan prisms. The lower wavelength limit was 215 mμ in both systems. The DNA preparations were carefully characterized as to spectral purity, sedimentation coefficient, hyperchromicity, protein content, and DNA content. In addition, the structure of the DNA oriented in films was inferred from x-ray diffraction patterns of fibers of the precipitated DXA. The A and B configurations of DNA in films could not be distinguished by the dichroic ratio measuiements. The dichroic ratio obtained for the film-oriented DNA at high relative humidity shows the same wavelength dependence as for the flow-oriented DNA. The same wavelength dependence for DNA in the fibrous state and in solution, when considered together with the x-ray diffract ion results, indicates that DNA in solution maintains an orientation of bases which is similar to that in fibers. I¹Or both solutions and films of DNA, the dichroic ratio is constant from 290mμ to 240 mμ and increases at wavelengths below 240 mμ. The increased parallel absorption below 240 mμ is consistent with the existence of an n→π* transition. The inherent molecular dichroic ratio is found to be the same for T5st-O DNA and T2H DNA in solution, and is a maximum of 0.09 ± 0.02 at 260 mμ.