Molecular aspects on the interaction of sanguinarine with B-form, Z-form and HL-form DNA structures.

The interaction of sanguinarine with right-handed (B-form), left-handed (Z-form) and left-handed (HL-form) structures of poly(dG-dC).poly(dG-dC) has been investigated by measuring the circular dichroism (CD) and UV-absorption spectral analysis. Sanguinarine binds strongly to the B-form DNA and does not bind to Z-form or HL-form, but it converts the Z-form and the HL-form back to the bound right handed form as evidenced from CD spectroscopy. Sanguinarine inhibits the rate of B to Z transition under ionic conditions that otherwise favour the left-handed conformation of the polynucleotides. UV absorption kinetic studies show that the Z-form reverses back to B-form to B-form on binding to sanguinarine. Binding isotherms obtained from spectrophotometric data show that sanguinarine binds strongly to the B-form polymer in a non-cooperative manner, in sharp contrast to the highly cooperative interaction under Z-form and HL-form polynucleotides. These studies reveal that the alternating GC sequence undergoes defined conformational changes and interacts with sanguinarine which may be an important aspect in understanding its extensive biological activities.

Interaction of the antitumour alkaloid coralyne with duplex deoxyribonucleic acid structures: spectroscopic and viscometric studies.

The interaction of coralyne, an antitumour alkaloid with natural and synthetic duplex DNAs was investigated under conditions where the drug existed fully as a true monomer for the first time using spectrophotometric, spectrofluorimetric, circular dichroic and viscometric techniques. The absorption spectrum of coralyne monomer showed hypochromic and bathochromic effects on binding to duplex DNAs. This effect was used to determine the binding parameters of coralyne. The binding constants for four natural DNAs and four synthetic polynucleotides obtained from spectrophotometric titration, according to an excluded site model, using McGhee-von Hippel analysis, were all in the range of (0.38-9.8) x 10(5) M-1, and showed a relatively high specificity for the GC rich ML DNA and the alternating GC polynucleotide. The binding of coralyne decreased with increasing ionic strength, indicating that the binding affinity has a strong electrostatic component. Coralyne stabilized all the DNAs against thermal strand separation. The intense steady state fluorescence of coralyne was effectively quenched on binding to DNAs and the quantitative data on the Stern-Volmer quenching constant obtained was sequence dependent, being maximum with the GC rich DNA and alternating GC polymer. Circular dichriosm studies further evidenced for a strong perturbation of the B-conformation of DNAs consequent to coralyne binding with the concomitant development of extrinsic circular dichroic bands for the bound drug molecules suggesting their strong intercalated geometry in duplex DNAs. Further tests of intercalation using viscosity measurements on linear and covalently closed plasmid DNA conclusively proved the strong intercalation of coralyne in duplex DNA. Binding of the closely related natural alkaloid, berberine under these conditions showed considerably lower affinity to duplex DNAs in all experiments. Taken together, these results suggest that coralyne binds strongly to duplex DNAs by a mechanism of intercalation with specificity towards alternating GC duplex structure.

1H NMR investigation of the interaction of berberine and sanguinarine with DNA.

Interaction of the alkaloids, berberine and sanguinarine with calf thymus DNA has been studied by 1H NMR. All proton resonances of the two compounds have been assigned using 2D-COSY, NOESY and ROESY spectra. Berberine has been found to partially intercalate into DNA, while sanguinarine shows normal intercalation and also binds more firmly to DNA. The NMR experiments indicate that sanguinarine is more potent than berberine in its activity.

Sensitivity of non-cooperative binding parameters of ligand-DNA complex by computer analysis.

A simple user-friendly computer programme has been developed to operate on an IBM-PC compatible machine to aid in the process of curve fitting using the McGhee and von Hippel equation [J. Mol Biol, 86 (1974), 469-489] for the analysis of ligand-DNA interactions and the experimental data on berberine-calf thymus DNA and berberine-poly(dI-dC). poly(dI-dC) for non-cooperative binding. A sensitivity analysis on binding constant (K0) and the number of binding sites (N0) show that a small variation in the latter remarkably alters the fitting curve. At a level of 1% change in N0 from the best fit value, the standard deviation grows by almost 4%, while, on the other hand, a 1% change in K0 affects the same value only by less than 0.4%.

Interaction of berberine chloride with deoxyribonucleic acids: evidence for base and sequence specificity.

The interaction of berberine chloride with natural and synthetic DNAs of differing base composition and sequences was followed by various spectroscopic and viscometric studies. The binding of berberine chloride was characterized by hypochromism and bathochromism in the absorption bands, enhancement of fluorescence intensity, stabilization against thermal denaturation, perturbations in the circular dichroic spectrum, increase in the contour length of sonicated rod-like DNA and induction of unwinding-rewinding process of covalently closed superhelical DNA, depending on the base composition and sequences of base pairs. Binding parameters determined from absorbance and fluorescence titration by Scatchard analysis, according to an excluded-site model, indicated a very high specificity of berberine to AT-rich DNAs and alternate AT polymer. Fluorescence quantum yield was maximum for the complexes with AT-rich DNAs and alternate AT polymer. Taken together, these results suggest that berberine chloride exhibits considerable specificity towards alternating AT polymer and binds to AT-rich DNAs by a mechanism of classical intercalation.