Bacterial melanin interacts with double-stranded DNA with high affinity and may inhibit cell metabolism in vivo.

Melanin has been found to interact with a number of molecules including metal ions, antibiotics and proteins. In this study, we showed how melanin from bacteria can interact with double-stranded DNA. Investigation using capillary electrophoresis, various spectroscopic techniques and circular dichroism found that melanin interacts with DNA by intercalating between the base pairs of DNA. And this was further supported by simulating different forms of melanin docking to oligonucleotides. Transmission electron microscopy of recombinant Escherichia coli producing melanin suggested the interaction in vivo. Furthermore, we showed how the cytoplasmic localization of melanin may provide a novel function in inhibiting cellular metabolism using microcalorimetry. The implications of the interaction in prokaryotes and eukaryotes were discussed.

Protective action of bacterial melanin against DNA damage in full UV spectrums by a sensitive plasmid-based noncellular system.

The purpose of this study was to introduce a simple and sensitive plasmid-based noncellular system to evaluate the photoprotection of bacterial melanin on DNA damage against ultraviolet (UV) radiation. Plasmid DNA was used to assess the role of melanin in different ranges of UV using a series of in vitro assays. Fluorometric measurements suggested that melanin could efficiently scavenge reactive oxygen species (ROS) generated by UVA irradiation in solution, and the scavenging capability was proportional to the pigment concentration. The protective effect of melanin on plasmid DNA under UVB irradiation was confirmed by the transformation efficiency of the protected DNA, which was at least 10-fold higher than that of the non melanin protected DNA. After the UVC irradiation, the DNA damage of strand breaks was quantified by laser-induced fluorescence capillary electrophoresis. The percentage of supercoiled plasmid was reduced from 80% to less than 5% without melanin protection. In contrast, the percentage of supercoiled DNA only decreased to about 40% in the presence of melanin under the same radiation conditions. All these results demonstrated that bacterial melanin did protect DNA from being damaged throughout full UV irradiation. This system, avoiding the potential interference by cellular DNA repair machinery and intracellular substances, may provide a sensitive in vitro means to evaluate the functions of melanin and other photoprotective compounds from different sources.

Analysis of plasmid DNA damage induced by melanin with capillary electrophoresis.

Dilute linear poly(N-isopropylacrylamide) (PNIPAM) in Tris-Mes-EDTA (TME) buffer was used as sieving matrix for capillary electrophoresis (CE) of plasmid DNA and plasmid topological isomers induced by melanin in uncoated capillary. At the optimized condition of 0.1% (w/v) PNIPAM in TME buffer, base line separation of the plasmid DNA ladder (2-12 kbp) was achieved within 15 min. Three positive clones with inserts of 468, 1147 and 1566 bp can be distinguished from the plasmid pUC 18 vector within 13 min. The migration order of the plasmid topological isomers in the dynamic coating matrix was confirmed by the enzymatically prepared and UV-induced plasmids. The covalently closed circular form appeared firstly, followed by the linear plasmid form and then the open circular form. The effect of bacterial melanin obtained from Pseudomonas maltophilia AT18 on plasmid pUC 18 was investigated by CE in uncoated capillary in vitro. Plasmid pUC 18 incubated with either melanin or copper ions alone sustained little DNA damage. The combination of melanin with Cu(II) can cause the plasmid pUC 18 conformational changes from covalently closed circular form to open form. Understanding the damage effect of melanin with copper ions on DNA would be important for the melanin-related application, such as photoprotective antioxidant in protecting the skin from cancer, pathophysiology research in clinic. The investigation of melanin induced plasmid conformational changes by CE in uncoated capillary also revealed that the application of the dynamic coating matrix could be extended to the study of plasmid conformational changes in other plasmid-based biological technologies.

pH effect on dynamic coating for capillary electrophoresis of DNA.

A buffer consisting of tris(hydroxymethyl)aminomethane, 2-(N-moropholino)ethanesulfonic acid (Mes) and EDTA with constant ion strength was used to investigate the effect of buffer pH on the dynamic coating behavior of poly(N-isopropylacrylamide) (PNIPAM) for DNA separation. The atomic force microscopy (AFM) image illustrated that PNIPAM in lower-pH buffer was much more efficient in covering a silica wafer than that in higher-pH buffer. The coating performance of PNIPAM was also quantitatively analyzed by Fourier transform IR attenuated total reflectance spectroscopy and by measuring the electroosmotic flow (EOF). These results indicated that the stability of the dynamic coating was dependent on the pH of the sieving matrix and was improved by reducing the pH to the weak-acid range. The lower pH of the sieving buffer may induce the polymer more efficiently to adsorb on the capillary wall to suppress EOF and DNA-capillary wall interaction for DNA separation. The enhanced dynamic coating capacity of PNIPAM in lower-pH buffer may be attributed to the hydrogen bonds between the hydroxyl groups of the silica surface and the oxygen atom of the carbonyl groups of PNIPAM.