Long-range order of nucleic acids in aqueous solutions

The structural order of short nucleic acid fragments (having a mean length of 170 nm) in aqueous solution in the presence of high magnetic fields (up to 18.5 tesla) has been investigated by small-angle neutron scattering, light diffraction and by precision measurements of the magnetic birefringence. Our data give clear evidence that, above a critical concentration, the semi-rigid electrically charged fragments arrange themselves into a periodic lattice having an interparticle spacing of ～6 nm. Neighbouring rods show a nearly parallel orientation, but a slight twist seems to exist, leading to a well defined pitch of the order of 1000 nm, which gives rise to a strong diffraction of visible light. The unexpectedly low saturation of the birefringence in the high magnetic field, however, indicates that the order is not of the simple cholesteric type. The forces which are responsible for inducing the twist across the large interparticle distance are mainly anisotropic Van der Waals forces.     

Raman spectral studies of nucleic acids. XVI. Structures of polyribocytidylic acid in aqueous solution

Raman spectra of polyribocytidylic acid show the formation of an ordered single-stranded structure [poly(rC)] at neutral pH and an ordered double-stranded structure containing hemiprotonated bases [poly(rC)·poly(rC⁺)] in the range 5.5 > pH > 3.7. Below 40°C, poly(rC) contains stacked bases and a backbone geometry of the A-type, both of which are gradually eliminated by increasing the temperature to 90°C. Below 80°C, poly(rC)·poly(rC⁺) contains bases which are hydrogen bonded and stacked and a backbone geometry also of the A-type. In this structure the bases of each strand are shown to be structurally identical, i.e., hemiprotonated, and therefore distinct from both neutral and protonated cytosines. Infrared and Raman spectra indicate the existence of a center of symmetry with respect to the paired cytosine residues, which suggests that the additional proton per base pair is shared equally by the two hydrogen-bonded bases. Denaturation of poly(rC)·poly(rC⁺) occurs cooperatively (t_m ≈ 80°C) with elimination of base stacking, base pairing, and the A-helix geometry. Each of the separated strands of the denatured complex is shown to contain comparable amounts of both neutral and protonated cytosines, most likely in alternating sequence [poly(rC, rC⁺)]. In both poly(rC, rC⁺) and poly(rC), at 90°C, the backbones do not exhibit the phosphodiester Raman frequencies characteristic of other disordered polyribonucleotide chains. This is interpreted to mean that the single strands, though devoid of base stacking and A-type structure, contain uniformly ordered backbones of a specific type. Fully protonated poly(rC⁺), on the other hand, forms no ordered structure and may be characterized as a disordered (random chain) polynucleotide at all temperatures. Several Raman lines of poly(rC) are absent from the spectrum of poly(rC)·poly(rC⁺) and vice versa. These frequencies, assigned mainly to vibrations of the ribose groups, suggest that the furanose ring conformations are different in the single-stranded and double-stranded structures of polyribocytidylic acid. Several other Raman group frequencies have been identified and correlated with the polymer secondary structures.     

New perspectives on the use of nucleic acids in pharmacological applications: inhibitory action of extracellular self-DNA in biological systems

The research for new products against pathogens, parasites and infesting species, in both agriculture and medicine, implies huge and increasing scientific, industrial and economic efforts. Traditional approaches are based on random screening procedures searching for bioactive compounds. However, the success of such methodologies in most cases has been strongly limited by side-effects of the potential new drugs, especially toxicity and pharmacological resistance. The use of nucleic acids in drug development has been introduced searching for target-specific effect. In addition, a recent discovery revealed that randomly fragmented extracellular self-DNA may act as highly species-specific inhibitory product for different species, suggesting an unprecedented use of DNA for biological control. On this base, a new scenario of pharmacological applications is discussed.     

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.     

Interaction of nucleic acids. VI. Interaction of purine with nucleic acids

The interaction of purine with DNA, tRNA, poly A, poly C, and poly A. poly U complex was investigated. In the presence of purine, the nucleic acids in coil form (such as denatured DNA, poly A and poly C in neutral solutions, or tRNA) have lower optical rotations. In addition, hydrodynamic studies indicate that in purine solutions the denatured DNA has a higher viscosity and a decreased sedimentation coefficient. These findings indicate that through interaction with purine, the bases along the poly-nucleotide chain are unstacked and are separated farther from each other, resulting in increased assymmetry (and possibly volume) of the whole polymer. Thus, the de-naturation effect of purine reported previously can be explained by this preferential interaction of purine with the bases of nucleic acids in coil form through a hydrophobic-costacking mechanism. Results from studies on optical rotation and helix-coil transition show that the interaction of purine is greater with poly A than with poly C. The influence of temperature, Mg⁺⁺ concentration, ionic strength, and purine concentration on the effect of purine on nucleic acid conformation has also been investigated. In all these situations the unraveling of nucleic acid conformation occurs at much lower temperatures (20–40°C lower) in the presence of purine (0.2–0.6M).