Mechanistic Insight into the Photodynamic Effect Mediated by Neutral Red and a New Azine Compound in Staphylococcus aureus Cells.

The photodynamic activity of Neutral Red and the new monobrominated Neutral Red was studied in suspensions of Staphylococcus aureus. The effect of mannitol and sodium azide in the presence of 25 µm photosensitizer on lethal photosensitization were investigated. The results of the mechanistic evaluation of Neutral Red showed that both mannitol and sodium azide produced a completed protective effect after irradiation without significant differences between them. The evaluation of monobrominated Neutral Red also showed a protective effect of microorganisms with the addition of mannitol. Although sodium azide produced a protective effect of the photoinactivation, it was incomplete and less than that exhibited by mannitol. The results indicate that the starting reagent, Neutral Red, is a producer of radical species, acting through a type I mechanism, whereas the halogenated derivative of Neutral Red produced reactive oxygen species and a contribution of singlet molecular oxygen cannot be discarded in the photoinactivation of Staphylococcus aureus cells. These results, analyzed together with the previously evaluated properties of the dyes, allow us to explain the differences observed in the photoinactivation of Staphylococcus aureus mediated by both azine photosensitizers.

Synthesis and physicochemical properties of polyacrylamide nanoparticles as photosensitizer carriers.

At present, polyacrylamide nanoparticles are attractive to drug delivery. However, some physicochemical characteristics of these nanoparticles still need to be further improved in practice. Polyacrylamide nanoparticles with an average size of 80nm and a zeta potential of -30mV were synthesized and used as photosensitizer carriers. The new monobrominated derivatives and parent compounds were the photosensitizers for the photodynamic therapy loaded in the nanocarrier. The physicochemical characterization of the prepared nanoparticles, drug loading, the ability to generate singlet oxygen and chemical stability were investigated. The novel tested nanoparticles exhibited a loading percentage of between 80 and 99%, higher generation of singlet oxygen and good stability in comparison with the corresponding starting reagent. According to these results, the novel polyacrylamide nanoparticles are excellent candidates for drug vehiculization.

The design of agents to control DNA methylation adducts. Enhanced major groove methylation of DNA by an N-methyl-N-nitrosourea functionalized phenyl neutral red intercalator.

An N-methyl-N-nitrosourea (MNU) moiety [CH3N(N=O)C(=O)NH-] linked to the C4'-position of the 5-substituted phenyl ring of phenyl neutral red (PNR), 2-methyl-3-amino-5-[p-[[2-[(N-nitroso-N-methylcarbamoyl)amino]ethy l] carbamoyl]phenyl]-7-(dimethylamino)phenazenium chloride (MNU-PNR), has been synthesized as an approach to design a molecule that will deliver alkylating agents with some preference to guanine (Gua) in the major groove of DNA. The PNR nucleus was chosen because previous studies suggested the following: (1) PNR binds with a slight preference for G/C rich sequences; and (2) PNR intercalates into DNA from the major groove with the 5-phenyl ring pointing out into the major groove (Müller, W., Bünemann, H., and Dattagupta, N. (1975) Eur. J. Biochem. 54, 279-291). It is demonstrated that MNU-PNR yields 2.6 and 6.0 times more N7-methylguanine (7-MeGua) than MNU at low salt (10 mM Tris buffer) and high salt (10 mM Tris buffer + 200 mM NaCl), respectively. It is also shown that the ratio of 7-MeGua (a major groove adduct) to N3-methyladenine (a minor groove adduct) is approximately 5 times higher for MNU-PNR than for MNU. The yield of the 7-MeGua adduct is decreased by the coaddition of a nonmethylating analogue of MNU-PNR or NaCl, but increased in the presence of the minor groove intercalator, ethidium bromide. Using a 32P-end-labeled restriction fragment, the enhanced methylation by MNU-PNR at 7-Gua is confirmed, and it is demonstrated that the sequence-dependent formation of 7-MeGua from MNU-PNR is the same as that seen with MNU. UV, circular dichrosism, and viscosity studies are consistent with MNU-PNR binding to DNA via an intercalation-based process.

Affinity chromatography of viroid RNAs.

The application of a structure- and GC-specific affinity adsorbent for the purification of viroid RNAs is described. Cross-linked bisacrylamide gels to which the intercalating dye phenyl neutral red is covalently attached [2] constitute a powerful tool for the rapid, quantitative, and selective isolation of viroid as well as viroid complementary RNAs from crude, plant polysaccharides containing nucleic acid fractions.

Synthesis and properties of acrylamide-substituted base pair specific dyes for deoxyribonucleic acid template mediated synthesis of dye polymers.

We have tried to construct synthetic polymers for sequence-specific recognition and complexation of longer deoxynucleotide sequences. For this purpose, we developed a method of template-directed polymerization of basic pair specific DNA ligands such as basic dyes. The template-directed polymerization consists in a copolymerization of various dyes of different specificities staying simultaneously in a binding equilibrium with DNA. In the present paper, we describe the synthesis and the properties of base pair specific monomers especially designed for performance of radical chain polymerization reactions in aqueous medium at room temperature. Different acrylamide derivatives of well-known dyes, such as AT-specific malachite green and GC-specific phenyl neutral red, were synthesized and studied for their ability of base pair specific complex formation with DNA of different base composition. Partition equilibrium dialysis and dye titration agarose gel electrophoresis were used to ensure for several dyes that they may be incorporated into different polymers via copolymerization of their acrylamido derivatives with various small base-unspecific monomers without substantial change of their binding parameters. Furthermore, we demonstrate that acrylamide and other small acrylamide derivatives can be used as building blocks for the synthesis of polymeric links between base pair specific monomers. The results and their consequences for template polymerization reactions are discussed.

Interactions of heteroaromatic compounds with nucleic acids. 2. Influence of substituents on the base and sequence specificity of intercalating ligands.

This paper presents the results of a systematic study on the effects of substituents on the base and sequence specificity of tricyclic heteroaromatic compounds interacting with DNA by intercalation. All the compounds tested are derived from proflavine and acridine orange analogs with different heteroatoms in the middle ring. Their base and sequence specificities were determined by differential dialysis of the ligand against DNA samples of differing G-C content. The main results indicate that (a) the introduction of a phenyl substituent into one of the two available positions of the middle ring increases or decreases the G-C specificity of the ligand depending on the position where the substitution takes place; (b) compounds of the substitution type of neutral red (2-methyl-3-amino-7-dimethyl-amino-phenazine) show unexpectedly high G-C specificities and (c) DNA ligands of pronounced sequence specificity for adjacent G-C pairs can be constructed by combining the structural elements of neutral red with an additional phenyl residue in the same molecule. The further study of compounds related to the phenylated neutral red revealed that the G-C specificity can be improved or destroyed by additional substituents. The comparison of the G-C specificity and the DNA-affinity data of the compounds studied leads to the suggestion that the specificity arises mainly from electronic factors which are strongly controlled through steric constraints on possible ocmplex geometries. As a basis for the discussion a possible structure for the DNA complex of the phenylated neutral red is considered in which the extra phenyl ring at N-5 of the phenazinium system, protrudes into the large groove of the DNA helix while the tricyclic part of the ligand is inserted between the DNA base-pairs.