Role of structure-proteins in the porphyrin-DNA interaction.

We studied the complexation of meso-tetrakis(4-N-methylpyridyl)porphyrin (TMPyP) with HeLa nucleosomes and compared it to our earlier results on T7 phage nucleoprotein complex (NP) and isolated DNA. To identify binding modes and relative concentrations of the bound TMPyP forms, the porphyrin absorption spectra were analyzed at various base pair/porphyrin ratios. Spectral decomposition and circular dichroism measurements proved that the two main binding modes of TMPyP, i.e., external binding and intercalation occur also in the nucleosomes. The DNA superstructure maintained by the proteins decreases its accessibility for TMPyP similarly in both nucleoproteins. A difference is observed between the partitioning of the two binding modes: in the case of nucleosome the ratio of intercalation to groove-binding is changed from 60/40 to 40/60 as determined for T7 NP and for isolated DNA-s. Using UV and CD melting studies, we revealed that TMPyP destabilizes the DNA-protein interaction in the nucleosomes but not in the T7 phage. Lastly, photoinduced reaction of bound TMPyP caused alterations in DNA structures and DNA-protein interactions within both nucleoprotein complexes; the nucleosomes were found to be more sensitive to the photoreaction.

Comparison of the efficiency and the specificity of DNA-bound and free cationic porphyrin in photodynamic virus inactivation.

The risk of transmitting infections by blood transfusion has been substantially reduced. However, alternative methods for inactivation of pathogens in blood and its components are needed. Application of photoactivated cationic porphyrins can offer an approach to remove non-enveloped viruses from aqueous media. Here we tested the virus inactivation capability of meso-Tetrakis(4-N-methylpyridyl)porphyrin (TMPyP) and meso-Tri-(4-N-methylpyridyl)monophenylporphyrin (TMPyMPP) in the dark and upon irradiation. T7 bacteriophage, as a surrogate on non-enveloped viruses was selected as a test system. TMPyP and TMPyMPP reduce the viability of T7 phage already in the dark, which can be explained by their selective binding to nucleic acid. Both compounds proved to be efficient photosensitizers of virus inactivation. The binding of porphyrin to phage DNA was not a prerequisite of phage photosensitization, moreover, photoinactivation was more efficiently induced by free than by DNA bound porphyrin. As optical melting studies and agarose gel electrophoresis of T7 nucleoprotein revealed, photoreactions of TMPyP and TMPyMPP affect the structural integrity of DNA and also of viral proteins, despite their selective DNA binding.

Binding of cationic porphyrin to isolated DNA and nucleoprotein complex: quantitative analysis of binding forms under various experimental conditions.

We studied the complex formation of tetrakis(4-N-methylpyridyl)porphyrin (TMPyP) with double stranded DNAs and T7 phage nucleoprotein complex. We analyzed the effect of base pair composition of DNA, the presence of capsid protein, and the composition of the microenvironment on the distribution of TMPyP between binding forms as determined by the decomposition of porphyrin absorption spectra. No difference was found in the amount of bound TMPyP between DNAs of various base compositions; however, the ratio of TMPyP binding forms depends on the AT/GC ratio. The presence of protein capsid opposes the binding of TMPyP to DNA. This behavior offers a possibility to investigate the protein capsid integrity due to the analysis of porphyrin binding. Increasing ionic strength of monovalent ions decreases the amount of bound porphyrin through the inhibition of intercalation, but does not influence the quantity of groove-binding forms when TMPyP interacts with isolated DNA. In the case of the nucleoprotein complex the groove-binding is also inhibited already at 140 mM ionic strength. The presence of 1 mM divalent cations (Mg(2+), Ca(2+), Cu(2+) and Ni(2+)) in a buffer solution of 70 mM ionic strength does not influence significantly the free to bound ration of TMPyP when it interacts with isolated DNA. The contribution of binding forms is remarkably different in Mg(2+)/Ca(2+) and Cu(2+)/Ni(2+) containing solutions. Transition metals significantly decrease the binding sites for intercalation in both DNA and nucleoprotein complex, but facilitate the groove-binding of TMPyP to isolated DNA.

[Photodynamic inactivation of porphyrin sensitized T7 phages: efficiency and mechanism of action]. / Porfirin származékok alkalmazása T7 fág fotodinamikus inaktivációjában: a reakció hatékonysága és mechanizmusa.

We investigated the efficiency and the mechanism of action of two glycoconjugated tetraphenyl porphyrins in their photoreaction with T7 bacteriophage. Both types of porphyrins sensitized the photoinactivation of T7, but the slopes of inactivation kinetics were markedly different. Our result suggests that both type I and type II reaction play a role in the virus inactivation. Optical melting studies revealed structural changes in the protein part but not in the DNA of the photo-chemically treated nucleoprotein complex. Polymerase chain reaction (PCR) analysis failed to demonstrate any DNA damage.