Raman spectroscopy study of the interaction between biogenic polyamines and an alternating AT oligodeoxyribonucleotide.

The interaction between the 15-mer oligonucleotide d[A(TA)(7)].d[T(AT)(7)] and the three biogenic polyamines, putrescine, spermidine and spermine, under physiological conditions has been studied by Raman spectroscopy. Solutions containing 60 mM (phosphate) of the oligonucleotide and different polyamine concentrations ranging from 1 to 75 mM have been studied. Both natural and heavy water were used as solvents. Difference Raman spectra were computed by subtracting the sum of the separated component spectra from the experimental spectra of the complexes. The Raman data suggested that the interaction of biogenic polyamines with d[A(TA)(7)].d[T(AT)(7)] presents differences related with their sizes and electric charges. Preferential bindings through the oligonucleotide minor groove for putrescine and spermidine were proposed. Spermine would interact by both minor and major grooves, although interaction by the minor groove seems to be more favored. Main reactive sites were thymine-O2 and adenine-N3 atoms at the minor grooves and adenine-N7 and thymine-O4 at the major groove. Electrostatic attractions between the polyamine amino and oligonucleotide phosphodioxy groups were also proposed. Under our experimental conditions, no macromolecular effects on d[A(TA)(7)].d[T(AT)(7)] (changes on secondary or tertiary structures) were detected from Raman spectroscopy, contrary to what happened for GC sequences at the same experimental settings. This fact agrees with the role of the biogenic polyamines during the first steps of the macromolecular synthesis, which involve DNA opening in AT motifs.

Effects of aminooxy analogues of biogenic polyamines on aggregation and stability of calf thymus DNA.

The effect of a series of aminooxy analogues of the biogenic polyamines spermidine and spermine on the conformation of calf thymus DNA is studied. These new molecules are isosteric and charge insufficient analogues that are suitable to study the roles of both charge distribution and structural requirements in the molecular physiology of the biogenic polyamines. They are also evidenced as useful tools to inhibit polyamine biosynthesis and cell growth. Circular dichroism (CD) spectra of solutions containing DNA and the aminooxy analogues at different concentrations (100-1000 microM) and different pH values, (5-7.5) are recorded. We use both sonicated and highly polymerized calf thymus DNA. The CD spectra of sonicated DNA showed the formation of Psi-DNA, a highly ordered aggregated structure similar to liquid crystals, in the presence of the aminooxy analogues. Aggregation induced by an aminooxy derivative of spermine is followed by DNA collapse when increasing the polyamine concentration. The features of Psi-DNA are not detected for highly polymerized DNA. Temperature melting measurements support a high degree of structural order of the aggregates. The CD experiments indicate that dications are unable to induce major changes on the macromolecular structure of DNA. In addition, aggregation is only observed when the trimethylene moiety is present between two adjacent positive charges. The observed differences among the CD spectra of DNA solutions with different aminooxy derivatives of spermidine indicate different roles for different amino groups of this biogenic polyamine when interacting with DNA. Our results support the idea that aminooxy analogues can be used as good models in studying the physiological functions of biogenic polyamines.

Raman study of the interaction between polyamines and a GC oligonucleotide.

The interaction between the oligonucleotide d[G(CG)(7)]. d[C(GC)(7)] and the three biogenic polyamines putrescine, spermidine, and spermine under physiological conditions has been studied by Raman spectroscopy. The results indicate the formation of highly ordered aggregated structures in solution, largely stabilized by electrostatic attractions, which have been described as cholesteric phases. Aggregation seems to be preceded by a partial B --> Z conformational transition for spermidine and spermine, which would allow for a deeper oligonucleotide-polyamine interaction. Interaction with the nucleic bases has also been evidenced for aggregates. At low polyamine concentrations the preferential binding sites are similar to those proposed for their interactions with ct-DNA. With increasing the polyamine concentration, the oligonucleotide-polyamine interactions involve both minor and major grooves, which is consistent with the formation of cholesteric phases.

Fourier transform Raman study of the structural specificities on the interaction between DNA and biogenic polyamines.

Biogenic polyamines putrescine, spermidine, and spermine are essential molecules for proliferation in all living organisms. Direct interaction of polyamines with nucleic acids has been proposed in the past based on a series of experimental evidences, such as precipitation, thermal denaturation, or protection. However, binding between polyamines and nucleic acids is not clearly explained. Several interaction models have also been proposed, although they do not always agree with one another. In the present work, we make use of the Raman spectroscopy to extend our knowledge about polyamine-DNA interaction. Raman spectra of highly polymerized calf-thymus DNA at different polyamine concentrations, ranging from 1 to 50 mM, have been studied for putrescine, spermidine, and spermine. Both natural and heavy water were used as solvents. Difference Raman spectra have been computed by subtracting the sum of the separated component spectra from the experimental spectra of the complexes. The analysis of the Raman data has supported the existence of structural specificities in the interactions, at least under our experimental conditions. These specificities lead to preferential bindings through the DNA minor groove for putrescine and spermidine, whereas spermine binds by the major groove. On the other hand, spermine and spermidine present interstrand interactions, whereas putrescine presents intrastrand interactions in addition to exo-groove interactions by phosphate moieties.

DNA-chlorpheniramine interaction studied by spectroscopic techniques.

It was previously studied that the antihistaminic chlorpheniramine elicits a biphasic response on cell growth and regulates polyamine metabolism, as described for polyamines. In part, polyamine effects on macromolecular synthesis and cell growth are attributed to nucleic acid:polyamine interactions. In this work, we have tested the hypothesis of a DNA:chlorpheniramine interaction, using fluorometry, FTIR and Raman spectroscopic techniques. The results indicate that DNA:chlorpheniramine interaction occurs inducing conformational changes in the macromolecule by affecting both phosphodiester bonds and bases. Results open new perspectives for characterization of action mechanisms of natural or synthetic diamines with pharmacological or physiological importance.