Pyridoxine-derived bicyclic aminopyridinol antioxidants: synthesis and their antioxidant activities.

A few facile synthetic pathways for bicyclic aminopyridinol antioxidants are presented. Attachment of a long alkyl chain to the bicyclic pyridinol scaffold was established using ester linkage. Non-substituted pyrrolopyridinols and 1,3-oxazine-fused pyridinols were also synthesized as novel antioxidant scaffolds. Antioxidant activities were measured by a radical clock method and new compounds prepared are comparable to the best bicyclic aminopyridinol antioxidants.

Preparation and investigation of vitamin B6-derived aminopyridinol antioxidants.

3-Pyridinols bearing amine substitution para to the hydroxylic moiety have previously been shown to inhibit lipid peroxidation more effectively than typical phenolic antioxidants, for example, α-tocopherol. We report here high-yielding, large-scale syntheses of mono- and bicyclic aminopyridinols from pyridoxine hydrochloride (i.e., vitamin B(6)). This approach provides straightforward, scaleable access to novel, potent, molecular scaffolds whose antioxidant properties have been investigated in homogeneous solutions and in liposomal vesicles. These molecular aggregates mimic cell membranes that are the targets of oxidative damage in vivo.

Substituent effects on regioselectivity in the autoxidation of nonconjugated dienes.

Free radical oxidation of several 1,4-dienes was carried out in the presence of variable concentrations of alpha-tocopherol to investigate the effect of diene structure on product distribution. Oxidations carried out at low tocopherol concentration gave only C-1 and C-5 conjugated diene hydroperoxides, while higher concentrations of the antioxidant resulted in formation of substantial amounts of the nonconjugated C-3 diene hydroperoxide. Increasing size of the substituents at C-1 and C-5 of the diene favors kinetic products arising from oxygen addition at the nonconjugated position, C-3, of the pentadienyl radical intermediate. Substituents at C-1 or C-5 of the pentadienyl radical also have a significant effect on the regioselectivity of the conjugated diene hydroperoxides formed, larger substituents directing oxygen addition to the pentadienyl radical at the site of least steric hindrance. This trend is also observed in oxidations of omega-3 and omega-6 linolenate fatty acid esters. Groups at C-1 and C-5 of the diene can influence product distribution based upon (a) steric demand in the oxygen-radical reaction and (b) the influence of substituents on the rearrangement of the C-3 peroxyl radical to give conjugated diene products.

Determination of leukotriene A(4) stabilization by S100A8/A9 proteins using mass spectrometry.

Leukotriene A(4) (LTA(4)) is the precursor for the formation of bioactive leukotrienes, but is highly susceptible to nonenzymatic hydrolysis. Although it is chemically reactive, LTA(4) participates in the process of transcellular metabolism, which requires the transfer of LTA(4) from one cell to another for the production of additional leukotrienes. Due to the susceptibility of LTA(4) to hydrolysis, various methods have been used to measure the half-life of LTA(4) in the presence of different proteins in efforts to understand how it is transported between cells. In this work, a new liquid chromatography mass spectrometry technique was developed to improve upon these previous assays that analyzed LTA(4) directly. The new technique derivatizes LTA(4) to stable compounds for analysis and removes the potential for sample decomposition between analytical runs. This assay was used in measuring the capabilities of the S100A8/A9 protein complex isolated from human neutrophils to stabilize LTA(4). It was determined that the S100A8/A9 protein complex protects LTA(4) from hydrolysis in a Ca(2+) dependent manner and increases LTA(4) half-life to in excess of 35 and 5 min at 4 degrees C and 37 degrees C, respectively.

Identification of the peroxidation products of 13-hydroxy-gamma-linolenate and 15-hydroxyarachidonate: mechanistic studies on the formation of leukotriene-like diols.

Monohydroxy-gamma-linolenates and arachidonates were oxidized in the presence of alpha-tocopherol and free radical initiators at 37 degrees C. The dihydroxylinolenate products were analyzed and identified by use of a combination of liquid chromatography, mass spectrometry, and NMR techniques. A mechanism for the formation of the dihydroxylinolenates is proposed based on product analysis of oxidations using varied concentrations of alpha-tocopherol. The mechanism for monohydroxyarachidonate oxidation is the same as that of monohydroxylinolenates. However, arachidonate diol analysis is more complicated because of the formation of additional regioisomers that are a result of the parent arachidonate possessing multiple bisallylic hydrogens.

Tetrahydro-1,8-naphthyridinol analogues of alpha-tocopherol as antioxidants in lipid membranes and low-density lipoproteins.

Recently we demonstrated that the C(7)-unsubstituted tetrahydro-1,8-naphthyridin-3-ol has more than an order of magnitude better peroxyl radical trapping activity than alpha-tocopherol (alpha-TOH) in inhibited autoxidations in benzene. In order to prepare analogues more structurally related to alpha-TOH for further studies in vitro and in vivo, we developed synthetic approaches to C(7)-monoalkyl and C(7)-dialkyl analogues using a sequence involving (1) AgNO3-mediated hydroxymethyl radical addition to 1,8-naphthyridine, (2) regioselective alkyllithium addition by cyclic chelation in a nonpolar solvent, (3) iodination of the naphthyridine at C(3), and (4) CuI-medidated benzyloxylation of the aryl iodide followed by catalytic hydrogenolysis. An alpha-TOH isostere was prepared by a Wittig coupling of a C16 side chain identical to that of alpha-TOH to the naphthyridinols. The C(7)-mono- and dialkyl analogues exhibited more than an order of magnitude higher antioxidant activity (k(inh) = (5.3-6.1) x 10(7) M(-1) s(-1)) than alpha-TOH (k(inh) = 0.35 x 10(7) M(-) s(-1)) in benzene, as determined by a newly developed peroxyl radical clock. In addition to the strong antioxidant activity in benzene, the closest alpha-TOH analogue (naphthyridinol-based tocopherol, N-TOH) showed excellent inhibition of the oxidation of cholesteryl esters in human low-density lipoprotein and spared endogenous alpha-TOH in these experiments. Lateral diffusion of N-TOH in 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine liposomes was comparable to that of alpha-TOH, suggesting that it will have good antioxidant characteristics in both membranes and lipoproteins. Furthermore, a binding assay using a fluorescent tocopherol analogue showed that N-TOH binds to recombinant human tocopherol transfer protein better than alpha-TOH itself, suggesting that distribution of unnatural antioxidants such as N-TOH in vivo is possible.

Peroxyl radical clocks.

A series of peroxyl radical clocks has been developed and calibrated based on the competition between the unimolecular beta-fragmentation (k(beta)) of a peroxyl radical and its bimolecular reaction with a hydrogen atom donor (k(H)). These clocks are based on either methyl linoleate or allylbenzene and were calibrated directly with alpha-tocopherol or methyl linoleate, which have well-established rate constants for reaction with peroxyl radicals (k(H-tocopherol) = 3.5 x 10(6) M(-1) s(-1), k(H-linoleate) = 62 M(-1) s(-1)). This peroxyl radical clock methodology has been successfully applied to determine inhibition and propagation rate constants ranging from 10(0) to 10(7) M(-1) s(-1).

Peroxidation of polyunsaturated fatty acid methyl esters catalyzed by N-methyl benzohydroxamic acid: a new and convenient method for selective synthesis of hydroperoxides and alcohols.

A new catalytic system, based on N-methyl benzohydroxamic acid (NMBHA), was developed for the selective synthesis of lipid hydroperoxides and alcohols by aerobic oxidation of lipid precursors. The reactions were carried out under mild conditions with air at atmospheric pressure and 37 degrees C. The products were isolated in much better yields (50-60%) as compared to previously reported procedures. NMBHA can be recovered at the end of the reaction and recycled. The putative reactive intermediate, a nitroxyl radical, readily abstracts a hydrogen atom from polyunsaturated lipid precursors such as linoleate esters, and NMBHA itself is an excellent hydrogen atom donor, thus conferring high selectivity to oxidations catalyzed by this reagent.

Mechanism of action of non-cisplatin type DNA-targeted platinum anticancer agents: DNA interactions of novel acridinylthioureas and their platinum conjugates.

The DNA binding of two novel acridinylthioureas, ACR-NH-(CH(2))(2)-C(S)-NHCH(3) (1) and ACR-N(CH(3))-C(S)-NHCH(3) (3), and their platinum conjugates 4 and 5-derived from [PtCl(2)(en)]-was studied in cell-free model systems using various physico-chemical and biophysical methods. These included: spectrophotometric drug-DNA titrations, ethidium-DNA fluorescence quenching, competitive drug displacement, high-resolution NMR spectroscopy, and unwinding of plasmid DNA monitored by agarose gel electrophoresis. The acridinium cation of 1 showed strong binding to native DNA with K(i)=1.5 x 10(6)M(-1) and an excluded site size (n) of 2bp (McGhee-von Hippel fits of absorbance data). Compound 3 showed no measurable association with DNA. Binding of 1 was an order of magnitude stronger than that of simple 9-methylaminoacridine (2). In alternating copolymers, 1 exhibited slight AT preference. In poly(dA-dT)(2), enhanced association was accompanied by an increased binding site (approximately 3bp), while parameters in poly(dG-dC)(2) were consistent with classical intercalation. Displacement of 1 by distamycin from calf thymus DNA was suggestive of non-intercalating thiourea in 1 being located in the minor groove of the duplex. 1H NMR data of d(GGAGCTCC)(2) modified with 1 indicated intercalative binding of planar acridine, based on upfield shifts of aromatic proton signals relative to those in unbound 1 (Deltadelta approximately equal to -0.5 to -1ppm). Finally, 4 and 5 were found to unwind negatively supercoiled pUC19 plasmid by 21 degrees and 7 degrees per adduct, respectively (electrophoretic gel mobility assays). The difference in DNA binding modes of 4 and 5 is discussed as the ultimate source of the distinctly different biological activities of the conjugates.