Electron spin resonance study on the formation of ascorbate free radical from ascorbate: The effect of dehydroascorbic acid and ferricyanide

Summary Ascorbate free radical is considered to be a substrate for a plasma membrane redox system in eukaryotic cells. Moreover, it might be involved in stimulation of cell proliferation. Ascorbate free radical can be generated by autoxidation of the ascorbate dianion, by transition metal-dependent oxidation of ascorbate, or by an equilibrium reaction of ascorbate with dehydroascorbic acid. In this study, we investigated the formation of ascorbate free radical, at physiological pH, in mixtures of ascorbate and dehydroascorbic acid by electron spin resonance spectroscopy. It was found that at ascorbate concentrations lower than 2.5 mM, ascorbate-free radical formation was not dependent on the presence of dehydroascorbic acid. Removal of metal ions by treatment with Chelex 100 showed that autoxidation under these conditions was less than 20%. Therefore, it is concluded that at low ascorbate concentrations generation of ascorbate free radical mainly proceeds through metal-ion-dependent reactions. When ascorbate was present at concentrations higher than 2.5 mM, the presence of dehydroascorbic acid increased the ascorbate free-radical signal intensity. This indicates that under these conditions ascorbate free radical is formed by a disproportionation reaction between ascorbate and dehydroascorbic acid, having aK _equil of 6 × 10^–17 M. Finally, it was found that the presence of excess ferricyanide completely abolished ascorbate free-radical signals, and that the reaction between ascorbate and ferricyanide yields dehydroascorbic acid. We conclude that, for studies under physiological conditions, ascorbate free-radical concentrations cannot be calculated from the disproportionation reaction, but should be determined experimentally.Abbreviations AFR ascorbate free radical - DHA dehydroascorbic acid - EDTA ethylenediaminetetraacetic acid - DTPA diethylenetri-aminepentaacetic acid - TEMPO 2,2,6,6-tetramethylpiperidinoxy     

Base release in nucleosides induced by low-energy electrons: a DFT study

Low-energy electrons are known to induce strand breaks and base damage in DNA and RNA through fragmentation of molecular bonding. Recently the glycosidic bond cleavage of nucleosides by low-energy electrons has been reported. These experimental results call for a theoretical investigation of the strength of the C(1)'-N link in nucleosides (dA, dC and dT) between the base and deoxyribose before and after electron attachment. Through density functional theory (DFT) calculations, we compare the C(1)'-N bond strength, i.e., the bond dissociation energy of the neutral and its anionic radical, and find that an excess electron effectively weakens the C(1)'- N bond strength in nucleosides by 61-75 kcal/mol in the gas phase and 76-83 kcal/mol in the solvated environment. As a result, electron-induced fragmentation of the C(1)'-N bond in the gas phase is exergonic for dA (DeltaG=-14 kcal/mol) and for dT (DeltaG=-6 kcal/mol) and is endergonic (DeltaG=+1 kcal/ mol) only for dC. In the gas phase all the anionic nucleosides are found to be in valence states. Solvation is found to increase the exergonic nature by an additional 20 kcal, making the fragmentation both exothermic and exergonic for all nucleoside anion radicals. Thus C(1)'-N bond breaking in nucleoside anion radicals is found to be thermodynamically favorable both in the gas phase and under solvation. The activation barrier for the C(1)'-N bond breaking process was found to be about 20 kcal/mol in every case examined, suggesting that a 1 eV electron would induce spontaneous cleavage of the bond and that stabilized anion radicals on the DNA strand would undergo base release at only a modest rate at room temperature. These results suggest that base release from nucleosides and DNA is an expected consequence of low-energy electron-induced damage but that the high barrier would inhibit this process in the stable anion radicals.     

Vitamin C homeostasis in skeletal muscle cells

In skeletal muscle, vitamin C not only enhances carnitine biosynthesis but also protects cells against ROS generation induced by physical exercise. The ability to take up both ascorbic and dehydroascorbic acid from the extracellular environment, together with the ability to recycle the intracellular vitamin, maintains high cellular stores of ascorbate. In this study, we examined vitamin C transport and recycling, by using the mouse C2C12 and rat L6C5 muscle cell lines, which exhibit different sensitivity to oxidative stress and GSH metabolism. We found that: (1) both cell lines express SVCT2, whereas SVCT1 is expressed at very low levels only in proliferating L6C5 cells; furthermore L6C5 myoblasts are more efficient in ascorbic acid transport than C2C12 myoblasts; (2) C2C12 cells are more efficient in dehydroascorbic acid transport and ascorbyl free radical/dehydroascorbic acid reduction; (3) differentiation is paralleled by decreased ascorbic acid and dehydroascorbic acid transport and reduction and increased ascorbyl free radical reduction; (4) differentiated cells are more responsive to oxidative stress induced by glutathione depletion; indeed, myotubes showed increased SVCT2 expression and thioredoxin reductase-mediated dehydroascorbic acid reduction. From our data, SVCT2 and NADPH-thioredoxin-dependent DHA reduction appears to belong to an inducible system activated in response to oxidative stress.     

An electron spin resonance investigation and molecular orbital calculation of the anion radical intermediate in the enzymatic cis-trans isomerization of furylfuramide, a nitrofuran derivative of ethylene

The enzymatic cis-trans isomerization of nitrofuran derivatives has been proposed to occur via the formation of a radical anion intermediate. ESR investigations, in conjunction with intermediate neglect of differential overlap (INDO) molecular orbital calculations, support this concept by demonstrating the enzymatic generation of cis and trans radical anions of 3-(5-nitro-2-furyl)-2-(2-furyl) acrylamide. The INDO calculations further indicate that the rotational barrier between the cis and trans anion radicals of this compound is only 5--10 kcal/mol, whereas a 70 kcal/mol barrier exists for the parent geometric isomers. Hyperfine splitting constants for the cis-trans conformers have been assigned on the basis of INDO calculations. Surprisingly, only the nitrogen hyperfine splitting of the nitro group is distinguishably different in the two conformers, a result which is not inconsistent with the INDO calculations.     

Ascorbate system in plant development

By using lycorine, a specific inhibitor of ascorbate biosynthesis, it was possible to demonstrate that plant cells consume a high quantity of ascorbate (AA). Thein vivo metabolic reactions utilizing ascorbate are the elimination of H₂O₂ by ascorbate peroxidase and the hydroxylation of proline residues present in the polypeptide chains by means of peptidyl-proline hydroxylase.Ascorbate acts in the cell metabolism as an electron donor, and consequently ascorbate free radical (AFR) is continuously produced. AFR can be reconverted to AA by means of AFR reductase or can undergo spontaneous disproportion, thus generating dehydroascorbic acid (DHA).During cell division and cell expansion ascorbate consumption is more or less the same; however, the AA/DHA ratio is 6–10 during cell division and 1–3 during cell expansion. This ratio depends essentially on the different AFR reductase activity in these cells. In meristematic cells AFR reductase is very high, and consequently a large amount of AFR is reduced to AA and a small amount of AFR undergoes disproportionation; in expanding cells the AFR reductase activity is lower, and therefore AFR is massively disproportionated, thus generating a large quantity of DHA. Since the transition from cell division to cell expansion is marked by a large drop of AFR reductase activity in the ER, it is suggested here that AFR formed in this compartment may be involved in the enlargement of the ER membranes and provacuole acidification.DHA is a toxic compound for the cell metabolism and as such the cell has various strategies to counteract its effects: (i) meristematic cells, having an elevated AFR reductase, prevent large DHA production, limiting the quantity of AFR undergoing disproportionation. (ii) Expanding cells, which contain a lower AFR reductase, are, however, provided with a developed vacuolar system and segregate the toxic DHA in the vacuole. (iii) Chloroplast strategy against DHA toxicity is efficient DHA reduction to AA using GSH as electron donor. This strategy is usually poorly utilized by the surrounding cytoplasm.DHA reduction does play an important role at one point in the life of the plant, that is, during the early stage of seed germination. The dry seed does not store ascorbate, but contains DHA, and several DHA-reducing proteins are detectable. In this condition, DHA reduction is necessary to form a limited AA pool in the seed for the metabolic requirements of the beginning of germination. After 30–40h ascorbateex novo synthesis starts, DHA reduction declines until a single isoform remains, as is typical in the roots, stem, and leaves of seedlings. Finally, DHA recycling also appears to be important under adverse environmental conditions and ascorbate deficiency.     

Transient quinonimines and 1,4-benzothiazines of pheomelanogenesis: new pulse radiolytic and spectrophotometric evidence.

Biosynthetic and model in vitro studies have shown that pheomelanins, the distinctive pigments of red human hair, arise by oxidative cyclization of cysteinyldopas mainly 5-S-cysteinyldopa (1) via a critical o-quinonimine intermediate, which rearranges to unstable 1,4-benzothiazines. To get new evidence for these labile species, fast time resolution pulse radiolytic oxidation by dibromide radical anion of a suitable precursor, the dihydro-1,4-benzothiazine-3-carboxylic acid 7 was performed in comparison with that of 1. In the case of 7, dibromide radical anion oxidation leads over a few microseconds (k = 2.1 x 10(9) M(-1) s(-1)) to a phenoxyl radical (lambda(max) 330 nm, epsilon = 6300 M(-1) cm(-1)) which within tens of milliseconds gives rise with second-order kinetics (2k = 2.7 x 10(7) M(-1) s(-1)) to a species exhibiting an absorption maximum at 540 nm (epsilon = 2200 M(-1) cm(-1)). This was formulated as the o-quinonimine 3 arising from disproportionation of the initial radical. The quinonimine chromophore is converted over hundreds of milliseconds (k = 6.0 s(-1)) to a broad maximum at around 330 nm interpreted as due to a 1,4-benzothiazine or a mixture of 1,4-benzothiazines, which as expected are unstable and subsequently decay over a few seconds (k = 0.5 s(-1)). Interestingly, the quinonimine is observed as a labile intermediate also in the alternative reaction route examined, involving cyclization of the o-quinone (lambda(max) 390 nm, epsilon = 6900 M(-1) cm(-1)) arising by disproportionation (2k = 1.7 x 10(8) M(-1) s(-1)) of an o-semiquinone (lambda(max) 320 nm, epsilon = 4700 M(-1) cm(-1)) directly generated by dibromide radical anion oxidation of 1. Structural formulation of the 540 nm species as an o-quinonimine was further supported by rapid scanning diode array spectrophotometric monitoring of the ferricyanide oxidation of a series of model dihydrobenzothiazines.     

Glutathione and ascorbate reduction of the acetaminophen radical formed by peroxidase. Detection of the glutathione disulfide radical anion and the ascorbyl radical

The acetaminophen phenoxyl radical was generated by the oxidation of acetaminophen by horseradish peroxidase in a fast-flow ESR experiment, and its reaction with glutathione and ascorbate was studied. Glutathione reduces the phenoxyl radical of acetaminophen to regenerate acetaminophen and form the thiyl radical of glutathione. This thiyl radical reacts with the thiolate anion of glutathione to form the disulfide radical anion, which was detected and characterized by ESR spectroscopy. In the presence of ascorbate, the ascorbyl radical was produced by the reduction of the acetaminophen phenoxyl radical by ascorbate. This reaction results in the complete reduction of the free radical of acetaminophen, whereas the glutathione reduction of the phenoxyl radical of acetaminophen was not complete on the fast-flow ESR time scale of milliseconds. This suggests that ascorbate rather than glutathione is more likely to react with the acetaminophen phenoxyl free radical in vivo. In the presence of both ascorbate and higher concentrations of glutathione, the reaction with ascorbate is dominant. When cysteine was used in the place of reduced glutathione in the above assay system, the disulfide radical anion of cystine was observed in a manner similar to glutathione. These reactions may have significance in the detoxification of acetaminophen and the free radical metabolites of xenobiotics in general. Only in cells containing low levels of ascorbate can glutathione play a direct role in the detoxification of the acetaminophen phenoxyl radical.     

A marked stimulation of Fe(3+)-dependent lipid peroxidation in phospholipid liposomes under acidic conditions

Lipid peroxidation in phosphatidylcholine liposomes induced by Fe(3+) alone, assessed by thiobarbituric acid-reactive substances (TBARS) production, was markedly enhanced as the solution pH was lowered from 7.4 to 5.5. On the other hand, at physiological pH, TBARS production by Fe(3+) was almost negligible. Results of the radical scavenger experiments with superoxide dismutase, catalase and hydroxyl radical ((&z.rad;)OH) scavengers (sodium benzoate, mannitol and dimethylthiourea), deoxyribose degradation and ESR spectrometry suggest that the stimulation of Fe(3+)-dependent lipid peroxidation under acidic conditions is involved in generation of superoxide anion (O(2)(&z.rad;-)), hydrogen peroxide (H(2)O(2)) and (&z.rad;)OH during the reaction. The stimulation of Fe(3+)-dependent TBARS production by increasing the [H(+)] completely disappeared by triphenylphosphine (TPP) treatment of the liposomes, but the reaction was reversible with either incorporation of cumen hydroperoxide (CumOOH) into the TPP-treated liposomes or the addition of CumOOH to the treated liposomes. Incubation of the CumOOH-incorporated TPP-treated liposomes with Fe(3+) at pH 5.5 also resulted in (&z.rad;)OH generation. Based on these results, a possible mechanism of stimulatory effect of Fe(3+) on lipid peroxidation under acidic conditions is discussed.     

Selenium vitaminology: The connection between selenium,vitamin C,vitamin E,and ergothioneine

Selenium is connected to three small molecule antioxidant compounds, ascorbate, α-tocopherol, and ergothioneine. Ascorbate and α-tocopherol are true vitamins, while ergothioneine is a “vitamin-like” compound. Here we review how selenium is connected to all three. Selenium and vitamin E work together as a team to prevent lipid peroxidation. Vitamin E quenches lipid hydroperoxyl radicals and the resulting lipid hydroperoxide is then converted to the lipid alcohol by selenocysteine-containing glutathione peroxidase. Ascorbate reduces the resulting α-tocopheroxyl radical in this reaction back to α-tocopherol with concomitant production of the ascorbyl radical. The ascorbyl radical can be reduced back to ascorbate by selenocysteine-containing thioredoxin reductase. Ergothioneine and ascorbate are both water soluble, small molecule reductants that can reduce free radicals and redox-active metals. Thioredoxin reductase can reduce oxidized forms of ergothioneine. While the biological significance of this is not yet realized, this discovery underscores the centrality of selenium to all three antioxidants.     

Recycling of vitamin C from its oxidized forms by human endothelial cells

Endothelial cells encounter oxidant stress due to their location in the vascular wall, and because they generate reactive nitrogen species. Because ascorbic acid is likely involved in the antioxidant defenses of these cells, we studied the mechanisms by which cultures of EA.hy926 endothelial cells recycle the vitamin from its oxidized forms. Cell lysates reduced the ascorbate free radical (AFR) by both NADH- and NADPH-dependent mechanisms. Most NADH-dependent AFR reduction occurred in the particulate fraction of the cells. NADPH-dependent reduction resembled that due to NADH in having a high affinity for the AFR, but was mediated largely by thioredoxin reductase. Reduction of dehydroascorbic acid (DHA) required GSH and was both direct and enzyme dependent. The latter was saturable, half-maximal at 100 microM DHA, and comparable to rates of AFR reduction. Loading cells to ascorbate concentrations of 0.3-1.6 mM generated intracellular DHA concentrations of 20-30 microM, indicative of oxidant stress in culture. Whereas high-affinity AFR reduction is the initial and likely the preferred mechanism of ascorbate recycling, any DHA that accumulates during oxidant stress will be reduced by GSH-dependent mechanisms.     

A theoretical study of myoglobin working as a nitric oxide scavenger

The mechanism for the reaction between nitric oxide (NO) and O₂ bound to the heme iron of myoglobin (Mb), including the following isomerization to nitrate, has been investigated using hybrid density functional theory (B3LYP). Myoglobin working as a NO scavenger could be of importance, since NO reversibly inhibits the terminal enzyme in the respiration chain, cytochrome c oxidase. The concentration of NO in the cell will thus affect the respiration and thereby the synthesis of ATP. The calculations show that the reaction between NO and the heme-bound O₂ gives a peroxynitrite intermediate whose O–O bond undergoes a homolytic cleavage, forming a NO₂ radical and myoglobin in the oxo-ferryl state. The NO₂ radical then recombines with the oxo-ferryl, forming heme-bound nitrate. Nine different models have been used in the present study to examine the effect on the reaction both by the presence and the protonation state of the distal His64, and by the surroundings of the proximal His93. The barriers going from the oxy-Mb and nitric oxide reactant to the peroxynitrite intermediate and further to the oxo-ferryl and NO₂ radical are around 10 and 7 kcal/mol, respectively. Forming the product, nitrate bound to the heme iron has a barrier of less than ~7 kcal/mol. The overall reaction going from a free nitric oxide and oxy-Mb to the heme bound nitrate is exergonic by more than 30 kcal/mol.     

Free radical mediated interaction of ascorbic acid and ascorbate/Cu(II) with viral and plasmid DNAs

Previous studies indicate that ascorbic acid, when combined with copper or iron cleaves several viral DNA. ln this study, we generated the ascorbate radical anion electrochemically in a simple chemical environment without the participation of a metal ion. This solution possesses viral DNA scission activity. Ohe absence of catalytic metal ions [Fe (III) and Cu(II)] in the incubation medium was evidenced by metal chelating agents such as desferrioxamine and EDTA. Ohe radical quenching at high EDTA concentration was attributed to ionic strength of EDTA rather than metal chelation. Ohe effects of antioxidants, radical scavangers, catalase, superoxide dismutase and some proteins on DNA cleavage have been tested. Cleavage may not arise directly from ascorbate free radical but the reaction of the radical form of ascorbate with oxygen may produce the actual reactive species. Aerobic oxidation of ascorbate itself strictly requires transition metal catalysts, however electrochemically produced ascorbyl radical avoided the kinetic barrier that prevented direct oxidation of ascorbic acid with oxygen and eliminated the need for the transition metal ion catalysts.     

Ascorbate both activates and inactivates bleomycin by free radical generation.

The chemotherapeutic agent bleomycin (BLM) is activated by reducing agents to break isolated DNA. Paradoxically, these same reducing agents protect cellular DNA from BLM damage. To resolve this paradox, we have examined the reaction of FeIIIBLM with DNA in the presence of ascorbate. As expected, ascorbate augments FeIIIBLM-induced DNA damage. However, when ascorbate is added to FeIIIBLM prior to exposure to DNA, a redox-inactive BLM is produced in a reaction that generates the ascorbyl radical. This reaction occurs in both ascorbate-supplemented buffer and unsupplemented plasma. In buffered solution, this reaction was found to be stoichiometric; for each mole of BLM present, 6.9 mol of ascorbate was oxidized and 4.7 mol of oxygen was consumed. Iron was found to serve only as a catalyst for the reaction. These data suggest that both activation of BLM and the generation of redox-inactive BLM occur via the same reaction and that BLM-induced DNA damage depends upon BLM reaching DNA prior to its interaction with reducing agents.     

Effect of ionic strength on the binding of ascorbate to albumin

A fluorophore-nitroxide free radical dual-functional probe (FN) was utilized to study the kinetics of ascorbate (AH(-)) binding to Bovine Serum Albumin (BSA). Since the free radical fragment in the FN probe intramolecularly quenches fluorescence, ascorbate reduction of the nitroxide function is accompanied by a concomitant fluorescence intensity increase from the fluorophore. Thus, both fluorescence and the EPR techniques could be utilized to measure the reaction rate. In the presence of BSA protein, the observed rate of the overall process is the sum of that from at least two reactions: the reaction between free ascorbate and free probe, and the reaction between bound ascorbate and bound probe. Our findings show that the observed rate is strongly dependent on the ionic strength of the medium. A corollary of this observation is the indication of a purely electrostatic interaction between ascorbate and the BSA protein. This conclusion was further corroborated by 1H NMR measurement of the transverse relaxation time, T(2), of ascorbate protons in BSA solutions. Ascorbate ion was released from the ascorbate/BSA ensemble in the presence of increasing concentrations of NaCl. Binding constants of AH(-) to BSA were calculated at different ionic strengths at pH 7.4. Furthermore, an increase in ionic strength did not affect the ability of albumin to protect ascorbate against autoxidation. This suggests that the protein's protective antioxidant effect may be attributed to BSA binding of trace quantities of transition-metal cations (rather than ascorbate binding to BSA). This conclusion is supported by ascorbate UV-absorption measurements in the presence of albumin and Cu(2+) ions as a function of ionic strength.     

Radicals associated with the catalytic intermediates of bovine cytochrome c oxidase

Two radicals have been detected previously by electron paramagnetic resonance (EPR) and electron nuclear double resonance (ENDOR) spectroscopies in bovine cytochrome oxidase after reaction with hydrogen peroxide, but no correlation could be made with predicted levels of optically detectable intermediates (P(M), F and F(z.rad;)) that are formed. This work has been extended by optical quantitation of intermediates in the EPR/ENDOR sample tubes, and by comparison with an analysis of intermediates formed by reaction with carbon monoxide in the presence of oxygen. The narrow radical, attributed previously to a porphyrin cation, is detectable at low levels even in untreated oxidase and increases with hydrogen peroxide treatments generally. It is presumed to arise from a side-reaction unrelated to the catalytic intermediates. The broad radical, attributed previously to a tryptophan radical, is observed only in samples with a significant level of F(z.rad;) but when F(z.rad;) is generated with hydrogen peroxide, is always accompanied by the narrow radical. When P(M) is produced at high pH with CO/O(2), no EPR-detectable radicals are formed. Conversion of the CO/O(2)-generated P(M) into F(z.rad;) when pH is lowered is accompanied by the appearance of a broad radical whose ENDOR spectrum corresponds to a tryptophan cation. Quantitation of its EPR intensity indicates that it is around 3% of the level of F(z.rad;) determined optically. It is concluded that low pH causes a change of protonation pattern in P(M) which induces partial electron redistribution and tryptophan cation radical formation in F(z.rad;). These protonation changes may mimic a key step of the proton translocation process.     

Redox cycles of caffeic acid, alpha-tocopherol, and ascorbate: implications for protection of low-density lipoproteins against oxidation

This study addresses the dynamic interactions among alpha-tocopherol, caffeic acid, and ascorbate in terms of a sequence of redox cycles aimed at accomplishing optimal synergistic antioxidant protection. Several experimental models were designed to examine these interactions: UV irradiation of alpha-tocopherol-containing sodium dodecyl sulfate micelles, one-electron oxidations catalyzed by the hypervalent state of myoglobin, ferrylmyoglobin, and autoxidation at appropriate pHs. These models were assessed by ultraviolet (UV) and electron paramagnetic resonance (EPR), entailing direct- and continuous-flow experiments, spectroscopy and by separation and identification of products by HPLC. The alpha-tocopheroxyl radical EPR signal generated by UV irradiation of alpha-tocopherol-containing micelles was suppressed by caffeic acid and ascorbate; in the former case, no other EPR signal was observed at pH 7.4, whereas in the latter case, the alpha-tocopheroxyl radical EPR signal was replaced by a doublet EPR spectrum corresponding to the ascorbyl radical (A*-). The potential interactions between caffeic acid and ascorbate were further analyzed by assessing, on the one hand, the ability of ascorbate to reduce the caffeic acid o-semiquinone (generated by oxidation of caffeic acid by ferrylmyoglobin) and, on the other hand, the ability of caffeic acid to reduce ascorbyl radical (generated by autoxidation or oxidation of ascorbate by ferrylmyoglobin). The data presented indicate that the reductive decay of ascorbyl radical (A*-) and caffeic acid o-semiquinone (Caf-O*) can be accomplished by caffeic acid (Caf-OH) and ascorbate (AH-), respectively, thus pointing to the reversibility of the reaction Caf-O* + AH- <--> Caf-OH + A*-. Continuous-flow EPR measurements of mixtures containing ferrylmyoglobin, alpha-tocopherol-containing micelles, caffeic acid, and ascorbate revealed that ascorbate is the ultimate electron donor in the sequence encompassing transfer of the radical character from the micellar phase to the phase. In independent experiments, the effects of caffeic acid and ascorbate on the oxidation of two low-density lipoprotein (LDL) populations, control and alpha-tocopherol-enriched, were studied and results indicated that alpha-tocopherol, caffeic acid, and ascorbate acted synergistically to afford optimal protection of LDL against oxidation. These results are analyzed for each individual antioxidant in terms of three domains: its localization and that of the antioxidant-derived radical, its reduction potential, and the predominant decay pathways for the antioxidant-derived radical, that exert kinetic control on the process.     

Synthesis and antioxidant activity evaluation of novel antiparkinsonian agents,aminoadamantane derivatives of nitroxyl free radical

Two new analogues of the antiparkinsonian drug 1-aminoadamantane: 4-(1-adamantylamino)-2,2,6,6-tetramethylpiperidine-1-oxyl and 4-(1-adamantylammonio)-1-hydroxy-2,2,6,6-tetramethylpiperidinium dihydrochloride have been synthesized. Their antioxidant activity towards reactive oxygen species (ROS: (z.rad;)OH and O(2)(z.rad;-)) have been evaluated in three test systems. The compound with nitroxide substituent displays higher anti-oxidative capacity than those containing hydroxylamine. The in vivo study of ROS-involving 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-rat model of induced parkinsonism was undertaken to ascertain the neuroprotective ability of the novel synthesized compounds-antioxidants. The data clearly shows that the nitroxide free radical moiety of the molecule is necessary for their neuroprotective action on dopaminergic neurons under the applied conditions of deep oxidative stress caused by the neurotoxin (MPTP). The new synthesized analogues may find application in treatment of parkinsonian syndromes, either to block or to reduce the ROS-mediated neuronal damage and death.     

6-Bromo-6-deoxy-L-ascorbic acid: an ascorbate analog specific for Na+-dependent vitamin C transporter but not glucose transporter pathways

Vitamin C intracellular accumulation is mediated by Na(+)-dependent vitamin C transporters SVCT1 and -2 and dehydroascorbic acid transporters GLUT1 and -3. It is unclear which pathways dominate in vivo. As a new step to resolve this issue, we identified and tested 6-bromo-6-deoxy-L-ascorbic acid as a specific candidate for SVCTs. In high performance liquid chromatography and electron paramagnetic resonance analyses, the reduced compounds ascorbic acid and 6-bromo-6-deoxy-L-ascorbic acid were similar. The oxidized products 6-bromo-6-deoxy dehydroascorbic acid (BrDHA) and dehydroascorbic acid (DHA) had comparable stabilities, based on reduction recoveries. Upon expression of GLUT1 or GLUT3 in Xenopus oocytes, BrDHA was neither transported nor bound, in contrast to robust transport of DHA. The findings were not explained by differences in the oocyte reduction of DHA and BrDHA because lysed oocytes reduced both compounds equally. Further, there was no transport of the reduced compound, 6-bromo-6-deoxy-L-ascorbic acid, by GLUT1 or GLUT3. As a prerequisite for investigating 6-bromo-6-deoxy-L-ascorbic acid transported by SVCTs, SVCT2 transport activity in oocytes was enhanced 14-fold by construction and use of a vector that added a fixed poly(A) tail to the 3' end of cRNA. For SVCT1 and SVCT2 expressed in oocytes, similar K(m) and V(max) values were observed for ascorbic acid and 6-bromo-6-deoxy-L-ascorbic acid. In human fibroblasts, predicted to have SVCT-mediated ascorbate accumulation, K(m) and V(max) values were again comparable for ascorbic acid and 6-bromo-6-deoxy-L-ascorbic acid. Using activated human neutrophils, predicted to have ascorbate accumulation mediated predominantly by DHA and GLUT transporters, 6-bromo-6-deoxy-L-ascorbic acid accumulation was <1% of accumulation when compared with ascorbic acid. We conclude that 6-bromo-6-deoxy-L-ascorbic acid is the first transport substrate identified as completely specific for SVCTs, but not GLUTs, and provide a new strategy to determine the contribution of each pathway to ascorbate accumulation.     

Carbinolamine formation and dehydration in a DNA repair enzyme active site

In order to suggest detailed mechanistic hypotheses for the formation and dehydration of a key carbinolamine intermediate in the T4 pyrimidine dimer glycosylase (T4PDG) reaction, we have investigated these reactions using steered molecular dynamics with a coupled quantum mechanics-molecular mechanics potential (QM/MM). We carried out simulations of DNA abasic site carbinolamine formation with and without a water molecule restrained to remain within the active site quantum region. We recovered potentials of mean force (PMF) from thirty replicate reaction trajectories using Jarzynski averaging. We demonstrated feasible pathways involving water, as well as those independent of water participation. The water-independent enzyme-catalyzed reaction had a bias-corrected Jarzynski-average barrier height of approximately (6.5 kcal mol(-1) (27.2 kJ mol(-1)) for the carbinolamine formation reaction and 44.5 kcal mol(-1) (186 kJ mol(-1)) for the reverse reaction at this level of representation. When the proton transfer was facilitated with an intrinsic quantum water, the barrier height was approximately 15 kcal mol(-1) (62.8 kJ mol(-1)) in the forward (formation) reaction and 19 kcal mol(-1) (79.5 kJ mol(-1)) for the reverse. In addition, two modes of unsteered (free dynamics) carbinolamine dehydration were observed: in one, the quantum water participated as an intermediate proton transfer species, and in the other, the active site protonated glutamate hydrogen was directly transferred to the carbinolamine oxygen. Water-independent unforced proton transfer from the protonated active site glutamate carboxyl to the unprotonated N-terminal amine was also observed. In summary, complex proton transfer events, some involving water intermediates, were studied in QM/MM simulations of T4PDG bound to a DNA abasic site. Imine carbinolamine formation was characterized using steered QM/MM molecular dynamics. Dehydration of the carbinolamine intermediate to form the final imine product was observed in free, unsteered, QM/MM dynamics simulations, as was unforced acid-base transfer between the active site carboxylate and the N-terminal amine.     

The investigation of hydrocarbon cracking reaction energetics with composite energy methods

Hydrocarbo cracking reactions are one of the most commonly encountered reactions in the petroleum industry, and the energetics of the reactions are crucial in understanding the reaction mechanisms and predicting reaction rates. In this work, a modified composite energy method (CBS-RAD(MP2)) is created as a version of the CBS-RAD method which gives accurate energetics for hydrocarbon free radical reactions. It replaces the time consuming QCISD(fc)/6-31g* method in the geometry optimization and frequency calculation steps with MP2(full)/6-31g* level calculations. The accuracy of the new CBS-RAD(MP2) method is compared with the widely used G2, G3 and CBS-QB3 composite methods for predicting heats of reaction and activation barriers of 14 hydrocarbon cracking reactions. We find that the new CBS-RAD(MP2) method has the second least RMS error of 1.22 kcal/mol for heats of reaction calculations. For activation energy calculations, the new CBS-RAD(MP2) method has the least RMS error of 1.37 kcal/mol. Moreover, the CBS-RAD(MP2) method was found to require only 81% of the computational time required compared to the CBS-QB3 method, 32% of G3 and 15% of the G2 method, making it an attractive alternative for predicting hydrocarbon cracking reaction energetics.