Interactions of meso-tetra-(4-N-oxyethylpyridyl) porphyrin (TOEPyP(4)), its 3-N analog (TOEPyP(3)) and their Co, Cu, Ni, Zn metallocomplexes with duplex DNA have been investigated by uv/visible absorbance and circular dichrosim spectroscopies. Results reveal the interactions of these complexes with duplex DNA are of two types. (1) External binding of duplex DNA by metalloporphyrins containing Zn and Co, and (2) Binding of duplex DNA both externally and internally (by intercalation) by porphyrins not containing metals, and metalloporphyrins containing Cu and Ni. Results indicate that (4N-oxyethylpyridyl) porphyrins intercalate more preferably in the structure of duplex DNA and have weaker external binding than 3N-porphyrins.
The influence of water soluble cationic meso-tetra(4N-hydroxyethyl)pyridyl porphyrin ( H 2 THOEtPyP 4) and it's metal complexes with Ni ( II ), Cu ( II ), Co ( II ) and Zn ( II ) on hydrodynamic and spectral behavior of DNA solutions has been studied by viscometry and UV-vis absorption methods. It was shown that the presence of planar porphyrins, such as H 2 THOEtPyP 4, NiTHOEtPyP 4 and CuTHOEtPyP 4 leads to an increase in viscosity at relatively small concentrations, and then decreases to stable values. Such behavior corresponds to intercalation of these porphyrins in DNA structure, which results in a decrease of helical twist and lengthening of the DNA molecule. In the case of porphyrins with axial ligands, such as ZnTHOEtPyP 4 and CoTHOEtPyP 4, the relative viscosity decreases, which is explained by self-stacking of these porphyrins on DNA surface. Calculation and interpretation of binding parameters (Kb and n) demonstrated good agreement of viscometric and spectrophotometric measurements.
The influence of porphyrin molecules configuration on their ability to affect on DNA structure were investigated for water-soluble cationic meso-tetra-(3N-hydroxyethylpyridyl) porphyrin (H2THOEtPyP3) and its metal complexes with Cu, Ni, Co, Zn using viscometry and UV-vis absorption spectroscopy. A comparative analysis was performed with the results of previously conducted similar studies of meso-tetra-(4N-hydroxyethylpyridyl) porphyrin (H2THOEtPyP4). Viscosity measurements show that the change in position of peripheral radicals on pyridylic ring has absolutely no effect on the laws of interaction of investigated porphyrins with DNA in case of outside binders such as CoTHOEPyP3 and ZnTHOEPyP3. In the presence of planar porphyrins, such as CuTHOEPyP3 and NiTHOEPyP3 the laws of structural changes of DNA are the same as in the case of H2THOEtPyP3, with some differences. Comparison of different locations of peripheral radicals on pyridylic rings leads to the conclusion that H2THOEtPyP3 and its metal complexes bind to DNA preferably more than H2THOEtPyP4 and its metal complexes. This fact may be explained only suggesting that porphyrins with hydroxyethyl groups at 3N-position are favorably located relative to the DNA helix axis than at 4N-position.
The effect of zinc oxide nanoparticles ($ \mathrm{ZnO} $) on the stability and conductivity of the bilayer lipid membrane (BLM) in solution was studied. It has been shown that $ \mathrm{ZnO} $ nanoparticles increase the stability of BLM in an electric field, and BLM becomes more stable with increasing their concentration. The increase in the stability of BLM in an electrical field is mainly due to the increase in the coefficient of linear tension of the pore edge, which is forming in BLM. It is also shown, that the presence of $ \mathrm{ZnO} $ nanoparticles in the solution surrounding BLM leads to a decrease in the BLM conductivity.
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