Printer Friendly

Endogenous Generation of Singlet Oxygen and Ozone in Human and Animal Tissues: Mechanisms, Biological Significance, and Influence of Dietary Components.

1. Introduction

Singlet oxygen ([sup.1][O.sub.2]) is an electronically excited form of oxygen which is well known to be formed when photosensitizers such as chlorophyll or the aromatic dye rose bengal absorb light energy and transfer some of that energy to molecular oxygen [1,2]. Various nonphotosensitized mechanisms for its formation have also been reported and suggested to occur in biological systems, but the importance of such endogenous singlet oxygen formation has had a controversial history [1, 3]. Ozone ([O.sub.3]) is best known as occurring in the stratosphere where it shields organisms on earth from ultraviolet C and much of ultraviolet B radiations, which are the most damaging UV components of solar radiations because they are readily absorbed by DNA [4, 5]. It is also known as a respiratory system-damaging pollutant in the troposphere and ironically as a therapeutic agent in alternative medicine [6]. More recently, it was shown that antibodies or amino acids catalyze the conversion of singlet oxygen ([sup.1][O.sub.2]) to ozone ([O.sub.3]) and that this reaction occurs during the killing of bacteria by activated neutrophils [7, 8]. Since both singlet oxygen and ozone are highly reactive oxygen species, a full understanding of their mechanisms of formation and action in vivo is necessary. Hence, this paper reviews the various reported mechanisms of the endogenous formation of these reactive oxygen species (ROS), the potential relevance of such pathways in human physiology, and how dietary factors affect the generation and activity of these oxidants.

2. Radiation-Induced Formation of Singlet Oxygen

Human beings are frequently exposed to natural and artificial radiation, and most of this interacts primarily with the skin. The spectrum of solar radiation at the earth's surface consists of ultraviolet (UV) radiation (UVB: 290-320 nm and UVA: 320-400 nm), visible radiation (VIS: 400-760 nm), and near infrared radiation (IRA: 760-1440 nm and IRB: 1440-3000 nm) [9]. UV, VIS, and IR contribute 7%, 39%, and 54% of the solar energy reaching the skin [10]. Direct absorption of UVB by cellular DNA leads to formation of cyclobutane pyrimidine dimers and pyrimidine (6-4) pyrimidone products, while UVA is not readily absorbed by DNA, and its direct damage to DNA is therefore not important [5]. Nevertheless, both UVA and UVB as well as visible light convert various photosensitizing compounds to excited states which transfer energy to triplet oxygen, thereby generating reactive oxygen species, particularly singlet oxygen.

UVA makes up 95% of the UV reaching the human skin, and up to 50% of it can penetrate to the dermis, unlike UVB that only penetrates the epidermis [11]. The human skin is rich in UVA and visible light (particularly the blue region) photosensitizers such as porphyrins, bilirubin, flavins, melanin and melanin precursors, pterins, [B.sub.6] vitamers, and vitamin K [12, 13]. The formation of singlet oxygen in the skin as a result of the interaction of UVA with these photosensitizers has been demonstrated directly by luminescence [14] and by detection of cholesterol-5-hydroperoxide which is preferentially generated by singlet oxygen but not by free radical mediated cholesterol oxidation [2]. The interaction between UVB and various vitamins and fatty acids also results in the generation of singlet oxygen, and some compounds including vitamin E that are ordinarily not UVA photosensitizers can be converted to UVA photosensitizers if they are preirradiated with UVB [11]. Photosensitized formation of singlet oxygen also occurs in the retina, which contains endogenous photosensitizers and is exposed to light [15]. One of the singlet oxygen-generating photosensitizers is lipofuscin, which forms in the retinal pigment epithelium with age or genetic disorders such as Stargardt's disease [15, 16]. Ground state oxygen can directly absorb visible light of 765 nm, even in mammalian cells, leading to formation of singlet oxygen without the involvement of a photosensitizer [17]. Similarly, IRB of 1268 nm can cause direct conversion of ground state oxygen to singlet oxygen [18].

Both IRB and IRC penetrate the skin only shallowly, while IRA (which makes up 30% of the total IR radiation reaching the skin) penetrates deeply, with 65% of it reaching the dermis [19, 20]. Unlike UVA, IRA penetration of the skin does not cause photosensitized formation of singlet oxygen but initiates the formation of reactive oxygen species, mainly from the mitochondrial electron transport chain [9, 20, 21]. While singlet oxygen maybe one of these ROS [9], its specific detection under such circumstances has not been studied. However, both UVA and IR induce upregulation of matrix metalloproteinases (MMPs) and thereby promote photoaging [9, 19]. The UV-induced MMP expression is dependent on cholesterol-5 hydroperoxide, a product of oxidation of cholesterol by singlet oxygen [2, 22]. Whether IR-induced metalloproteinase activation also depends to a great extent on singlet oxygen and cholesterol-5 hydroperoxide remains to be demonstrated. In this case, the role of IR in singlet oxygen formation may simply involve initiating the formation of superoxide anions, from which singlet oxygen would be generated by various types of radiation-independent reactions (vide infra). Singlet oxygen formation in organs other than the skin and eye mainly depends on such "dark" reactions.

Artificial sources of radiation may also contribute to endogenous singlet oxygen formation in humans. For example, during photodynamic therapy, a photosensitizer is inserted into cancerous tissue and irradiated with UV to produce singlet oxygen which serves the purpose of destroying cancer cells [23]. IR irradiation is commonly used in medicine to warm muscle tissue [24] and might also contribute to singlet oxygen formation.

3. Leukocyte-Mediated Formation of Singlet Oxygen

Neutrophils, including human neutrophils, produce singlet oxygen [7, 35-37] and this has been suggested to be important for bacterial killing through the formation of ozone [7]. It is generally considered that production of singlet oxygen by neutrophils is dependent on myeloperoxidase (MPO) which catalyzes the formation of hypochlorous acid (HOCl) from hydrogen peroxide ([H.sub.2][O.sub.2]) and chloride ion (see equation (1)), followed by reaction of HOCl with hydrogen peroxide anion (H[O.sub.2.sup-]) (see equation (2)) [7, 37]. However, the significance of the reaction between H[O.sub.2.sup-] and HOCl under physiological environments such as the intraphagosomal milieu may be limited by the presence of other reactive partners for HOCl [36], and it was suggested that alternative pathways of singlet oxygen generation by neutrophils may exist, including the spontaneous dismutation of superoxide anions (see equation (3)) [36, 37]. However, the yield of singlet oxygen from the latter reaction was also found to be minor [38]. Peritoneal macrophages, which are MPO deficient, produce higher yield of singlet oxygen than neutrophils [37]. In the macrophage phagosome, the reaction between nitric oxide (NO*) and superoxide anion ([sup.*-][O.sub.2]) occurs at diffusion-controlled rates to form peroxynitrite (ONO[O.sup.-]) (see equation (4)) [39], which reacts with [H.sub.2][O.sub.2] to produce singlet oxygen (see equation (5)) [40]. The reaction of NO* with [H.sub.2][O.sub.2] was also found to generate singlet oxygen in a purely chemical system and in a superoxide generating system (see equation (6)) [41, 42]. The eosinophil peroxidase system generates singlet oxygen by a reaction between HOBr and H[O.sub.2.sup-], analogously to (2) [30]:

[H.sub.2][O.sub.2] + [Cl.sup.-] + [H.sup.+] [right arrow] HOCl + [H.sub.2]O (1)

HOCl + H[O.sub.2.sup.-] [right arrow] [H.sub.2]O + [Cl.sup.-] + [sup.1][O.sub.2] (2)

[sup.*-][O.sub.2] + [sup.*-][O.sub.2] + 2[H.sup.+] [right arrow] [sup.1][O.sub.2] + [H.sub.2][O.sub.2] (3)

[sup.*-][O.sub.2] + NO* [right arrow] ONO[O.sup.-] (4)

ONO[O.sup.-] + [H.sub.2][O.sub.2] [right arrow] ON[O.sup.-] + [H.sub.2]O + [sup.1][O.sub.2] (5)

[sup.*-][O.sub.2] + [H.sub.2][O.sub.2] [right arrow] [sup.1][O.sub.2] + HO* + H[O.sup.-] (6)

[mathematical expression not reproducible] (7)

4. Singlet Oxygen Formation by the Russel Mechanism

Russell [43] proposed the idea that two peroxyl radicals can react to form an unstable tetroxide whose decomposition affords singlet oxygen, an alcohol, and a carbonyl compound, and this mechanism is now believed to contribute to singlet oxygen formation from various biomolecules including proteins, lipids, and nucleic acids [44]. The oxidation of DNA was found to result in singlet oxygen by this mechanism as illustrated in Figure 1, whereby thymine peroxyl radicals 1 react to generate tetroxide 2 whose decomposition produces alcohol 3, carbonyl 4, and [sup.1][O.sub.2] [25].

Cysteine residues in glutathione (RSH) were found to be readily oxidized by superoxide anions to form singlet oxygen, glutathione disulfide (RSSR), and glutathione sulfonate (RS[O.sub.3.sup.-]) in a reaction that was suggested to involve the peroxysulphenyl radical (RSOO*) [26] and can be considered as a special type of Russel mechanism (Figure 2). This mechanism may also apply to cysteine residues in proteins. Hydroxyl radicals may also initiate the conversion of amino acids to peroxyl radicals which then participate in the Russell mechanism [44].

As reviewed by Miyamoto et al. [45], various studies have demonstrated the formation of singlet oxygen by the Russel mechanism during the decomposition of lipid hydroperoxides (ROOH) in the presence of species such as [Fe.sup.3+], [Cu.sup.2+], peroxynitrite, HOCl, or cytochrome c, which oxidize the hydroperoxides to the corresponding peroxyl radicals (ROO*). However, while singlet oxygen formation by the Russell mechanism in such purely chemical systems is established, its importance in tissues has been considered debatable because high concentrations of peroxyl radicals are unlikely to develop under such systems [46, 47]. On the other hand, the fact that peroxyl radicals derived from phospholipid and cholesterol hydroperoxides in liposomes produced singlet oxygen was considered as an indication that this phenomenon may occur in cellular membranes [45]. Moreover, cytochrome c was found to promote oxidation of polyunsaturated fatty acid-containing cardiolipin, with concomitant singlet oxygen formation, and this may be relevant in the mitochondria where both species exist [45].

Peroxynitrite (ONO[O.sup.-]) reacts with glyoxal to produce singlet oxygen, and this was proposed to involve cleavage of glyoxal 6 to formic acid 7 and formyl radical 8, with subsequent conversion of the latter to peroxyformyl radical 9, and reaction of two such peroxyacyl radicals by the Russel mechanism as shown in Figure 3 [27]. Even in the absence of peroxynitrite, aldehydes formed during lipid autoxidation are easily converted to the corresponding acids via acyl and peroxyacyl radicals [48], and these may similarly produce singlet oxygen, as illustrated for the conversion of lipid oxidation-derived formaldehyde 10 to formic acid and singlet oxygen (Figure 3).

5. Singlet Oxygen Formation via the Dismutation of Alkoxyl Radicals

Two alkoxyl radicals (R[O.sup.*]) can undergo dismutation to form a carbonyl and an alcohol (Figure 4), and some of the carbonyls are formed in the excited triplet state, with a yield of up to 8% [28]. The triplet carbonyls can transfer energy to triplet oxygen, thereby generating singlet oxygen [28]. Because alkoxyl radicals are major intermediates during decomposition of biological hydroperoxides [28, 48], the potential contribution of this pathway to singlet oxygen formation cannot be ignored.

6. Singlet Oxygen Formation via the Oxidation of Phenolic Substances

Phenolic substances are important components of the human diet, and one of such compounds is the amino acid tyrosine. In many physiological situations, tyrosine 11 gets converted to the tyrosyl radical 12, which in turn gets converted by superoxide anions to tyrosine hydroperoxide 13, whose decomposition may produce singlet oxygen and regenerate tyrosine (Figure 5) [40]. However, tyrosine hydroperoxide 13 also gets converted to its bicyclic isomer 14, whose decomposition does not produce singlet oxygen, and this greatly reduces the amount of singlet oxygen formed from this system [29]. Nevertheless, this mechanism may be important because tyrosine and tryptophan residues are known to be major contributors to protein-dependent singlet oxygen formation [32].

It is reasonable to expect that singlet oxygen will be formed from other phenolic substances analogously to its formation from tyrosine according to Figure 5. For example, Figure 6 illustrates singlet oxygen formation from catechol or a catechol derivative 15 via a semiquinone radical 16 and a hydroperoxy semiquinone 17. Consistent with this, the 2-hydroxycatechol of estradiol was found to be oxidized by Cu + ions to produce superoxide ion, hydrogen peroxide, and singlet oxygen, and its DNA-strand breaking activity was diminished by singlet oxygen quenchers but not by hydroxyl radical quenchers [52]. Similarly, the substantial formation of singlet oxygen during [Cu.sup.2+]-mediated oxidation of catecholamines, derivatives of catechol, was reported by Kruk et al. [53]. These authors proposed the following sequence of events to be involved in singlet oxygen formation: (i) [Cu.sup.2+] oxidizes the catecholamine (represented by 15 in Figure 6) to the semiquinone radical 16; (ii) [Cu.sup.+] generated in the process reduces [O.sub.2] to superoxide anion ([sup.*-][O.sub.2]) and triplet oxygen may also oxidize 16 to quinone 18, with formation of [sup.*-][O.sub.2]; (iii) dismutation of the latter affords [H.sub.2][O.sub.2]; (iv) Cu+ reduces [H.sub.2][O.sub.2] to hydroxyl radicals COH) whose reaction with [sup.*- ][O.sub.2] affords singlet oxygen (Figure 6).

Akagawa et al. [31] further found that at 37[degrees]C and pH 7.4 various phenolic substances such as pyrogallol, pyrocatechol, 1,2,4-benzenetriol, and catechin, as well as polyphenol rich extracts of tea and coffee, generated significant amounts of [H.sub.2][O.sub.2] in both the presence and the absence of metal ions. Thus, they suggested a metal ion-free mechanism for generation of the semiquinone radical 16, consisting of an initiation step involving a noncatalyzed oxidation of the phenolic substance 15 by oxygen to form superoxide anion, followed by a propagation stage involving oxidation of the phenolic substance by superoxide anion as illustrated in Figure 6. The generation of superoxide anion and hydrogen peroxide is not unique to polyphenols, since even ascorbic acid undergoes such a reaction [54]. Tyihaket al. [6] reported that the antimicrobial activity of phenolic substances such as cinnamic acid and transresveratrol depends on their generation of singlet oxygen, and this may involve reactions as depicted in Figure 6.

7. Singlet Oxygen Formation via Dioxetanes

Dioxetanes are high energy 1,2-peroxides whose decomposition affords excited carbonyls in high yields [32]. Rac et al. [47] recently suggested that their observed formation of singlet oxygen in U937 human leukemic cells treated with [H.sub.2][O.sub.2] or the Fenton reagent was mainly due to decomposition of dioxetane intermediates.

Singlet oxygen formation during protein oxidation to a large extent involves tryptophan and tyrosine residues, and the chemiluminescence from tryptophan has long been regarded to potentially involve a dioxetane intermediate whose decomposition affords N-formylkynurenine [32]. Michalski et al. [33] recently reported on the peroxynitrite and superoxide-mediated conversion of tryptophan 19 via radical 20 to bicyclic tryptophan hydroperoxide 21 (Figure 7). Hydroperoxide 21 is also a known product of the singlet oxygen-mediated oxidation of tryptophan, and it gets converted via its hydroperoxide isomer 22, zwitterion 23, and dioxetane 24 to N-formylkynurenine 25 [34, 55]. The latter has a high chance of being formed in a triplet state, which will transfer energy to [O.sub.2] and generate [sup.1][O.sub.2]. As explained later, hydroperoxide 23 may also participate in ozone-generating reactions via intermediates 26 and 27.

The formation of some fatty acid oxidation products may be rationalized by pathways involving dioxetanyl derivatives formed by cyclization of peroxyl radicals. The cyclization of a model peroxyl radical derived from 3-hydroperoxy-2,3-dimethyl-1-butene (TMEOOH), and its subsequent conversion to excited carbonyls via a dioxetanyl intermediate was demonstrated by Timmins et al. [56]. Kaur et al. [49] postulated that such peroxycylization was an important pathway for the formation of major aldehydic products of linoleic acid oxidation, such as 9-oxononanoic acid and 4-hydroperoxy-2-nonenal. The latter is a precursor of the highly reactive and biologically active products, 4-hydroxy-2-nonenal and 4-oxo-2-nonenal, hence the great interest in its mechanism of formation [49, 50, 56-58]. It was proposed that linoleic acid 28 gets converted to peroxyl radical 29, whose cyclization affords dioxetanyl radical 30 as a precursor of hydroperoxy dioxetane 31, whose decomposition affords 9-oxononanoic acid32 and 4-hydroperoxy-2-nonenal33 (Figure 8) [50]. One of the latter aldehydes may be in the triplet state and thus may be a source of energy for conversion of triplet oxygen to singlet oxygen. Lee et al. [57] found that the 13-hydroperoxide of linoleic acid (13-LA-OOH, 34) was a major precursor of aldehydes 32 and 33, with retention of the -OOH group of 34 in 33. Schneider et al. [58] further found that, during conversion of 13-LA-OOH 34 to aldehydes 32 and 33, there was facile conversion of hydroperoxide 34 via radicals 35 and 36 to its 8,13-dihydroperoxy-derivative 37 (Figure 8) and 8-oxooctanoic acid was also formed. This is consistent with another postulated pathway for the formation of hydroperoxyaldehyde 33 involving cyclization of peroxyl radical 36 to form dioxetanyl derivative 38, whose decomposition affords 8-oxooctanoic acid 39 and radical 40, a precursor 33 [50].

On the other hand, there is no evidence for the formation of dioxetanyl derivatives during cholesterol oxidation (Figure 9).

The autoxidation of cholesterol 41 proceeds via carbon-centered radical 42 and peroxyl radical 43 to generate cholesterol-7-hydroperoxide 44 as a major product [59, 60]. While carbon-centered radical 42 might also be expected to isomerize and subsequently be converted via peroxyl radical 45 to cholesterol 5-hydroperoxide 46, formation of the latter during cholesterol autoxidation is negligible, even though 46 is the major product of cholesterol oxidation by singlet oxygen [59,60]. Lack of formation of 46 during autoxidation has been attributed to a fast rate of dissociation of oxygen from peroxyl radical 45 [60], indicating higher stability of radical 43 than 45. Although peroxyl radical 43 is easily converted to hydroperoxide 44, there is no evidence that the former undergoes cyclization to form dioxetanyl derivatives 47 and 48, because aldehydic products expected from the decomposition of the latter two have not been reported. This might likewise be due to a much higher stability of radical 43 than radicals 47 and 48. Ozone directly converts cholesterol 41 to the secosterol aldehyde 49 (secosterol A), which undergoes some conversion to its aldolization product 50 (secosterol B) [61]. Hock cleavage of cholesterol 5-hydroperoxide 46 under acidic conditions affords mainly secosterol B 50 with minor amounts of secosterol A 49 [61]. However, no analogous C-C cleavage products attributable to decomposition of dioxetanyl derivatives arising from cholesterol peroxyl radical cyclizations are known. Thus, decomposition of cholesterol hydroperoxides by the Russell mechanism [62] may be the only major pathway for singlet oxygen generation from cholesterol.

8. Singlet Oxygen Formation by the Reaction of Superoxide Anion with Hydrogen Peroxide

The reaction of superoxide anion with hydrogen peroxide to form singlet oxygen, hydroxyl radical, and hydroxide ion (see equation (6)), a modified form of the Haber-Weiss reaction, was proposed by Kellogg and Fridovich [63] and demonstrated upon the reaction of potassium superoxide with hydrogen peroxide in a simple reaction system [64]. However, this reaction is controversial: Koppenol [65] registered strong disapproval for it, mainly based on the fact that various studies found that the rate constant for the Haber-Weiss reaction is in the order of 1 [M.sup.-1] [s.sup.-1] or less.

9. Singlet Oxygen Formation via Cytochrome c-Mediated Formation of Triplet Carbonyls

Cytochrome c converts carbonyls such as lipid-derived aldehydes to triplet carbonyls, which then transfer energy to oxygen, thus generating singlet oxygen [66]. In fact, singlet oxygen formation from a model membrane having polyunsaturated fatty acid-containing cardiolipin in association with cytochrome C was found to be more dependent on triplet carbonyls than on the decomposition of hydroperoxides via the Russel mechanism [66].

10. Singlet Oxygen Formation by the Reaction of Hydroperoxides with Carbonyls

Under certain conditions such as in the presence of pyrogallol, lysine, tryptophan, or superoxide anions, the interaction of [H.sub.2][O.sub.2] with carbonyls such as formaldehyde, acetaldehyde, glyoxal, methyl-glyoxal, and even glucose was demonstrated to produce singlet oxygen and reactive aldehydes [51, 67-72], and such conditions should be common in vivo: considering that carbonyls are major lipid oxidation and glycoxidation products, all cells have formaldehyde generating pathways referred to as the formaldehydome [6, 69, 71], and hydrogen peroxide is also generated through many enzymatic and nonenzymatic reactions. The biological relevance of the reaction of [H.sub.2][O.sub.2] with carbonyls has been demonstrated in several studies. For example, brewed coffee and instant coffee give strong chemiluminescence due to singlet oxygen and reactive aldehydes [73], and the mutagenicity of coffee has been partly attributed to its content of both methylglyoxal and hydrogen peroxide [74]. The mutagenicity of glyoxal in Salmonella was found to be dependent on singlet oxygen generation and that catalase or scavengers of [H.sub.2][O.sub.2] reduced the mutagenic effect [75]. Kim et al. [76] found mixtures of glucose and lysine or arginine to be mutagenic and that such activity greatly depended on the formation of hydrogen peroxide and singlet oxygen. Maillard reaction products prepared by heating equimolar mixtures of glucose and amino acids, when incubated with DNA under physiological conditions, were reported to have DNA-strand breaking activity accompanied by singlet oxygen formation [77].

Hydroperoxides are very good nucleophiles because of the alpha effect, whereby interaction of lone electron pairs on two adjacent oxygen atoms increases nucleophilicity [78], and this explains the reactivity of hydrogen peroxide with aldehydes. Trezl and Pipek [51] proposed the pathways illustrated in Figure 10 for the generation of singlet oxygen during such [H.sub.2][O.sub.2]-carbonyl reactions. First, the facile hydration of an aldehyde (RCHO) produces a gem diol 51 which reacts with [H.sub.2][O.sub.2] to form a 1-hydroxyalkylhydroperoxide 52. The latter may react with another molecule of aldehyde to form bis-1-hydroxyalkylperoxide 53 whose decomposition affords an acid and an excited aldehyde which then participates in singlet oxygen formation. Alternatively the 1-hydroxyalkylhydroperoxide 52 is oxidized to form a 1-hydroxyalkylperoxyl radical 54 that undergoes Russel-type decomposition. The oxidation of formaldehyde C[H.sub.2]O by [H.sub.2][O.sub.2] in the presence of pyrogallol is called the Trautz-Schorigin reaction, a very efficient source of singlet oxygen whereby the semiquinone radical derived from pyrogallol is responsible for oxidizing the 1-hydroxyalkylhydroperoxide 52 to form 54 [79]. Superoxide anion also enhances formation of 54 [79].

The mechanism involved in the lysine or tryptophan-catalyzed formation of singlet oxygen from hydrogen peroxide and aldehyde has not been clearly defined. However, it is conceivable that this involves the pathways suggested in Figure 11, which is based on several known reactions.

First, the carbonyl (RCHO) reacts with the lysine (RN[H.sub.2]) to form Schiff's base 55, which then adds [H.sub.2][O.sub.2] to form hydroperoxide 56. The latter reacts with another [H.sub.2][O.sub.2] molecule, resulting in regeneration of lysine and formation of a 1,1-dihydroperoxide 57. Gem dihydroperoxide 57 may also be formed in an uncatalyzed reaction between [H.sub.2][O.sub.2] and 1- hydroxyhydroperoxide 52 [80, 81]. Hang et al. [82] reported that some monosubstituted 1,1-dihydroperoxides undergo decomposition to produce singlet oxygen in high yield. A reaction of 57 with a gem diol may generate such monosubstituted 1,1-dihydroperoxide 58 as a precursor of singlet oxygen. A reaction of 57 with Schiff's base may similarly lead to singlet oxygen formation via monosubstituted 1,1-dihydroperoxide 59.

The reaction of [H.sub.2][O.sub.2] with formaldehyde or acrolein in the presence of lysine also leads to the formation of formyl lysine while acetaldehyde generates acetyl lysine [68]. Dehydration of hydroperoxide 56 may lead to such carbonylated lysine products represented by isomeric structures 61 and 62 (this involves a hydride transfer from carbon to oxygen in 56). The fact that, like formaldehyde, acrolein (2-propenal) generates formyl lysine maybe explained by the reaction illustrated in Figure 12, whereby the acrolein-derived hydroperoxide 63 rearranges to a dioxetane intermediate 64 whose decomposition affords formyl lysine 65 and a triplet acetaldehyde which may also be a source of energy for singlet oxygen production.

Eukaryotic cells synthesize polyamines such as spermine and spermidine, which are essential for normal cell growth and development [83, 84]. These compounds are catabolized by polyamine oxidases such as spermine oxidase (SMO) which catalyzes the conversion of spermine 66 to spermidine 67, [H.sub.2][O.sub.2], and 3-aminopropanal 68 (Figure 13) [83-85].

The coformation of these three products creates an ideal situation for singlet oxygen according to Figure 10 or Figure 11, since both aminopropanal and spermidine contain the amino group, like lysine. This might be a key aspect in the mechanism of the known polyamine-dependent development of cancers such as gastric cancer [83, 84]. A recent study reported that Cu (II) polypyridyl complexes reduced the growth of breast cancer cells, and it was suggested that this was partly due to the production of singlet oxygen or a singlet oxygen-like compound that cleaved supercoiled DNA [86]. The expression of SMO in these cells also reduces their growth [87], which could likewise be due to singlet oxygen generation.

Neutrophils employ myeloperoxidase to oxidize nearly all amino acids found in plasma to aldehydes in high yield [88]. The reactions of these aldehydes with neutrophil-generated hydrogen peroxide may thus be another important mechanism for singlet oxygen production by neutrophils.

Organic hydroperoxides (ROOH) may participate in singlet oxygen generation through reactions related to Figures 11 and 12. For example, Kato et al. [89] reported that the 13-hydroperoxide of linoleic acid (13-hydroperoxy-9, 11-octadecadienoic acid, and HPODE) reacts with lysine to form [N.sup.[epsilon]]-(hexanoyl) lysine and that this product is not formed by reaction of preformed aldehyde with lysine in the absence of the hydroperoxide. However, the exact mechanism of formation of this product, which is regarded to be proatherogenic and a marker of lipid hydroperoxide-derived modifications of biomolecules [89], has not been elucidated. As suggested in Figure 14, formation of this adduct may begin with lysine-catalyzed conversion of HPODE 34 to a dioxetane 69, whose decomposition affords hexanal 70 and 12-oxo-9-dodecenoic acid 71, and one of these aldehydes may be in an excited state and thus contribute to singlet oxygen formation via energy transfer to triplet oxygen. Subsequent reaction of hexanal 70 with lysine (RN[H.sub.2]) affords corresponding Schiff's base 72, whose reaction with another HPODE molecule affords peroxide 73 which decomposes to form an alcohol and hexanoyl-lysine 74. Formation of hexanoyl-lysine in this manner is analogous to the formation of formyl lysine in the reaction system consisting of formaldehyde, hydrogen peroxide, and lysine (vide supra, [68]). 12-oxo-9-dodecenoic acid 71 may subsequently undergo oxidation to form 12-oxo-9-hydroperoxy-dodecenoic acid 75 analogously to the known conversion of 3-nonenal to 4-hydroperoxy-2-nonenal [90]. The possibility that lysine catalyzes formation of dioxetane 69 suggests that proteins can promote formation of toxic aldehydic lipid oxidation products. It also indirectly supports the feasibility of cyclization of fatty acid peroxyl radicals into dioxetanyl radicals as shown in Figure 8.

Wang et al. [91] recently found that thermal treatment of pure glucose or fructose solutions up to 70[degrees] Cled to formation of both hydrogen peroxide and singlet oxygen. Using glucose as an example, the potential mechanism for singlet oxygen generation during heating of such solutions is suggested in Figure 15. It starts with enolization of glucose 76 to form 1,2-dienol 77. Enediols naturally transfer one electron to an oxygen molecule, especially in the presence of oxidized metals such as [Cu.sup.2+], with formation of superoxide anion [92]. Thus, enediol 77 will be converted to dicarbonyl 78, while dismutation of the superoxide anions will produce [H.sub.2][O.sub.2]. Subsequent reaction of [H.sub.2][O.sub.2] with dicarbonyl 78 generates keto-hydroxy-hydroperoxide 79, whose decomposition may produce singlet oxygen analogously to the decomposition of tyrosine hydroperoxide 13 in Figure 5.

The Maillard reaction has also been found to lead to the production of [H.sub.2][O.sub.2] and singlet oxygen both in vitro and in vivo, and the Amadori product was identified as one of the precursors of hydrogen peroxide [93]. As shown in Figure 15, Amadori product 80 may be converted via enediol 81 to dicarbonyl 82, with coformation of [H.sub.2][O.sub.2]. Reaction of the latter two affords hydroxy-hydroperoxide 83 which may release [sup.1][O.sub.2] and convert back to enediol 81. Alternatively, 83 may release lysine and may be converted to dioxetane 84, whose decomposition affords ketoacid 85 and formaldehyde, which may be in the excited state and thus contribute to singlet oxygen formation. Enediol 81 may also react with singlet oxygen to form dioxetane 86 whose decomposition produces erythronic acid 87 and carboxymethyllysine 88. The latter is one of the most commonly formed advanced glycation end products(AGEs) that are known to contribute to various physiological disorders [94]. Dehydration of erythronic acid 87 may produce two regioisomeric deoxy-ketonic acids 89 and 90. The latter may react with singlet oxygen to produce dioxetane 91 as a precursor of oxalic acid (HOOC-COOH), glycolaldehyde 92, and glyoxal 93, all of which are known products of glycoxidation [95]. Deoxy-ketonic acid 89 may, via its ketoform, decarboxylate to form monohydroxyacetone 94 (via the enol form of the latter), whose oxidation produces methylglyoxal 95. Since the formation of the highly reactive glyoxal 93 and methylglyoxal 95 is accompanied by [H.sub.2][O.sub.2] formation, singlet oxygen formation according to Figures 10 and 11 will thus also occur during Maillard reaction.

Treatment of cultured U937 human leukemic cells or human multiple myeloma cells with [H.sub.2][O.sub.2] was found to cause singlet oxygen from both the cells and medium components, and this was not dependent on lipid oxidation [47, 96]. The mechanisms in Figures 10, 11, and 15 may be involved in such systems.

11. Evidence for Endogenous Ozone Formation and the Potential Mechanisms Involved

Wentworth et al. [7] were the first to suggest the possibility of the formation of ozone ([O.sub.3]) in biological systems. One of their key pieces of evidence was that, in solutions of antibodies exposed to singlet oxygen, there was generation of a large amount of hydrogen peroxide, the occurrence of higher bactericidal activity than what could be attributed exclusively to [H.sub.2][O.sub.2], as well as the oxidation of cholesterol to secosterol aldehyde A (49 in Figure 9), a well-known product of the ozonolysis of cholesterol. They referred to the generation of [H.sub.2][O.sub.2] and ozone under such circumstances as the antibody-catalyzed water oxidation pathway and proposed the idea that this involves an initial reaction of water with 1 [O.sub.2] to form dihydrogen trioxide ([H.sub.2][O.sub.3]) and that decomposition of the latter affords [H.sub.2][O.sub.2] and [O.sub.3] (see equation (7)). This reaction was suggested to occur in a hydrophobic site in the antibody molecule, where the [H.sub.2][O.sub.3] would be shielded from hydrolysis and facilitated to undergo the conversion to [H.sub.2][O.sub.2] and [O.sub.3] [97]. Although antibodies produce much more [H.sub.2][O.sub.2] and [O.sub.3] than other proteins [7], Yamashita et al. [8] reported that antibody catalysis is not essential for this reaction, but rather the presence of one of four amino acids: histidine, tryptophan, cysteine, or methionine. On the other hand, various authors have expressed reservations concerning the generation of ozone under such systems, for example, based on the fact that the catalytic mechanisms for the antibody- or amino acid-catalyzed water oxidation remain ill-defined [1, 3, 35, 37]. Others have reported that cholesterol 5-hydroperoxide 46, a product of the oxidation of cholesterol by singlet oxygen, can also decompose to generate secosterol aldehydes [98, 99]. On the other hand, it has been shown that reaction of cholesterol with ozone predominantly generates secosterol A while decomposition of cholesterol-5 hydroperoxide predominantly generates secosterol B [61]. The fact that secosterol A is the predominant secosterol detected in human tissues and is formed by neutrophils in vitro thus supports the formation of endogenous ozone [61, 100]. There is also indirect evidence consistent with the formation of ozone in plant leaves or in the cyanobacterium Synechocystis PCC 6803 during light-induced damage to their PS II, because singlet oxygen and tryptophan or histidine residues, respectively, are involved [34]. Unlike other commonly generated ROS that only generate single strand breaks in DNA, ozone generates both single strand and double strand breaks [101, 102]. The addition of L-histidine to cultured mammalian cells exposed to [H.sub.2][O.sub.2] results in DNA double strand breaks [103-105], and this might be related to histidine-mediated ozone generation in the presence of singlet oxygen.

A BioArena system is an overpressured layer chromatography (OPLC) system which enables observation of biochemical interactions between microorganisms and biologically active compounds in an adsorbent layer covered with the microorganisms [106]. Using such a system, it was found that formaldehyde, singlet oxygen, and ozone are formed in the interaction between microorganisms and antibiotic substances such as resveratrol and cinnamic acid and that ozone-trapping compounds greatly reduce the antimicrobial effect [6, 69, 71, 72]. Based on results from the BioArena system, ozone is considered to be an indispensable endogenous molecule that can be detected and measured in practically all biological systems [6, 71, 72]. Moreover, in directly detecting ozone formation by plant leaves through GC-MS-SIM, Balla and Tyihak [4] have added direct proof for the formation of ozone in biological systems. Thus, the current evidence for endogenous ozone is enough to warrant further studies on the mechanisms of its formation and biological effects.

As already mentioned, a number of questions remain unanswered regarding the antibody-/amino acid-catalyzed water oxidation pathway for ozone generation. Moreover, decomposition of dihydrogen trioxide ([H.sub.2][O.sub.3]), the proposed key precursor of ozone in both aqueous and organic solvents, has only been shown to produce singlet oxygen and water rather than hydrogen peroxide and ozone [107]. In response to these challenges, a new concept for ozone formation was recently suggested, involving the oxidation of organic substrates such as aldehydes or amino acids to form oxidized intermediates, and the subsequent singlet oxygen-mediated deoxidation of the oxidized intermediates to produce ozone, whose subsequent decomposition in water affords hydrogen peroxide [34]. For example, an aldehyde (RCHO) may be converted to a peroxyacid [RC(O)OOH] through a radical pathway [48] or by reacting with singlet oxygen [108], and the peroxyacid may undergo a Bayer-Villiger type reaction with singlet oxygen to produce an acid and [O.sub.3] (Figure 16) [34]. The significance of this mechanism is that it might generate ozone in many of the situations where singlet oxygen is formed in the presence of aldehydic compounds such as in Figures 10-15. Detailed potential mechanisms for histidine-, methionine-, and tryptophan-mediated ozone production have been proposed [34]. As an example, part of the reaction scheme for the tryptophan-dependent ozone generation is given in Figure 7. Thus, [O.sub.2], acting as an electrophile, deoxidizes zwitterion 23 and alkoxide 26, resulting in formation of two [O.sub.3] molecules and regeneration of tryptophan.

12. The Significance of Endogenous Singlet Oxygen and Ozone in Human Health

Harman [109] proposed the free radical theory of aging (FRTA) that considers free radical-induced damage to key biomolecules such as DNA and proteins as having a causative role in aging and reduced lifespan. A modified version of the FRTA is the mitochondrial free radical theory of aging (MFRTA), which considers the mitochondrion as the primary source and target of the damaging free radicals [110]. Formation of reactive oxygen species (ROS) from the electron transport chain (ECT) is the basis of the FRTA and MFRTA [111].

As high as 1-5% of consumed oxygen maybe converted to superoxide anions, which are readily converted to [H.sub.2][O.sub.2], and the latter is the principal mediator of cellular oxidative stress [111-113]. Reactive nitrogen species are also formed in the mitochondrion, since there is facile diffusion of nitric oxide (NO) to this organelle [114], and the presence of nitric oxide synthases has been demonstrated in mitochondria from various tissues in rats or mice [115, 116] as well as in cultured human cells [117]. In mitochondria, NO increases the formation of superoxide anions and [H.sub.2][O.sub.2] [118]. Thus, there exists suitable conditions in the mitochondria for the diffusion-controlled reaction of NO and superoxide anions to form peroxynitrite (see equation (4)) [114, 119] and subsequent reaction of the latter with [H.sub.2][O.sub.2] to generate singlet oxygen (see equation (5)) as one of the mitochondrial ROS. Peroxynitrite also initiates lipid oxidation [120] and may thus lead to further formation of singlet oxygen in the mitochondria by the Russel mechanism, or activation of lipid-derived carbonyls by cytochrome c oxidase, or the reaction of hydrogen peroxide with such carbonyls. In agreement with the operation of such mechanisms of singlet oxygen formation in the mitochondria, the superoxide anion-dependent formation of this ROS was demonstrated in mitochondria of rat liver and small intestine [121]. Additionally, Berneburg et al. [122] found that exposing normal human fibroblasts to sublethal doses of UVA led to singlet oxygen-dependent deletion of a 4,977-base pair in mitochondrial DNA, which is a common mutation associated with photoaging of human skin. The major product of mitochondrial DNA oxidation is 7,8-dihydro-8-oxoguanine (8-oxoG) [111, 123], and singlet oxygen contributes predominantly to the formation of this compound in DNA [124]. Although the reaction of hydroxyl radical with DNA also produces some 8-oxoG, this is a minor reaction [124, 125]. Thus, singlet oxygen should be an important contributor to aging according to the MFRTA. Besides, generation of singlet oxygen in the presence of carbonyls, amino acids, and proteins in the mitochondrion provides an environment for the generation of mitochondrial ozone, which might contribute to mitochondrial DNA double strand breaks.

The MFRTA has been used to explain the fact that dietary supplementation with antioxidants has not clearly shown antiaging effects, in that the dietary antioxidants may not effectively reach the mitochondria, the main sites of ROS generation, and age-related damage [110, 126]. In support of this, mice overexpressing mitochondria-targeted catalase were found to have improved lifespan, delayed cardiac pathology, and delayed cataract development [126, 127]. The beneficial effects of mitochondria-directed catalase might in part be due to reduced singlet oxygen and ozone, since [H.sub.2][O.sub.2] participates in a good number of the singlet oxygen-generating pathways (vide supra).

Another concept that is currently gaining ground is that of mitochondrial hormesis or mitohormesis, which suggests that low levels of reactive oxygen species such as superoxide anions are in fact part of normal physiology and are beneficial for longevity and metabolic health [126, 128-130]. The essence of this is that, at low levels, ROS act as signaling molecules that promote resistance to oxidative stress through increased endogenous antioxidant defense [126]. Hence, effects of ROS may be biphasic, whereby low levels are considered to be beneficial while high levels are detrimental [129]. Such an effect was demonstrated by treatment of elderly patients with a small amount of ozone by rectal sufflation, which resulted in improved antioxidant status and reduced biomarkers of lipid and protein oxidation [131]. A similar treatment was found to reduce the glycemic index and oxidative stress in diabetic patients [132]. Such beneficial effects of ozone therapy were suggested to be a result of the moderate oxidative stress under such conditions activating the nuclear factor-erythroid 2-related factor 2 (Nrf2), which then induces transcription of the antioxidant response elements (ARE), resulting in the production of numerous antioxidant enzymes including catalase as well as phase II detoxification enzymes and heat shock proteins [133]. However, more work is needed to determine the boundaries between the beneficial levels of ROS and the deleterious levels that promote physiological disorders.

As already mentioned, singlet oxygen generated photodynamically in the skin contributes to photoaging of the skin, and this at least partly occurs as follows: [sup.1][O.sub.2] reacts with cholesterol to form cholesterol-5-hydroperoxide, which induces expression of matrix metalloproteinase-9 (MMP-9), which in turn degrades collagen and thereby induces the formation of wrinkles and sagging [2,22]. Singlet oxygen also induces photoaging-associated mutations in mitochondrial DNA [122]. Porphyrias are rare diseases involving a disorder in heme synthesis and are manifested by accumulation of porphyrins in tissues [134]. During cutaneous porphyrias, there is enhanced photosensitivity due to singlet oxygen formation [134].

Singlet oxygen-specific linoleic acid oxidation products, 10-hydroperoxy-8(E), 12(Z)-octadecadienoic acid (10-(E,Z)-HPODE), and 12-hydroperoxy-9(Z), 13(E)-octadecadienoic acid (12-(Z,E)-HPODE) have been found to be suitable biomarkers for the evaluation of the early stages of diabetes, underscoring the role of singlet oxygen in the pathogenesis of this disorder [135, 136]. Further, fasting levels of 10-(E,Z-HPODE) and 12-(Z,E)-HPODE, together with insulin and leptin/adiponectin, are excellent predictors of the risk for type II diabetes, glucose intolerance, and insulin resistance [137, 138]. Patients with diabetes are prone to other diseases and physiological disorders including atherosclerosis, cardiovascular diseases, chronic kidney disease, retinopathy, and skin disorders [139]. Therefore, by contributing to glucose intolerance, insulin resistance, and type II diabetes, singlet oxygen may be contributing to a much wider range of chronic diseases.

Recently, the catabolism of polyamines has been linked to the development of some cancers such as gastric cancer, prostate cancer, and colon cancer [84, 85, 140]. Human spermine oxidase isoforms were found to be localized in the nucleus where they generate reactive oxygen species close to DNA and nuclear proteins [85]. Spermine oxidase-catalyzed catabolism of spermine thus generates products that can react to produce singlet oxygen and ozone in the nucleus. Hence, singlet oxygen and ozone might play a key role in spermine oxidase-dependent cancers.

Since singlet oxygen is a precursor of endogenous ozone, some of the biological activities attributed to singlet oxygen might be directly mediated by ozone or ozonolysis products. High levels of cholesterol secosterols A and B have been detected in human atherosclerotic tissues and shown to be proatherogenic [141]. The fact that secosterol A is the predominant secosterol in human tissues [61, 62, 100] indicates a much greater role for ozone than singlet oxygen in the in vivo formation of the secosterols because even the secosterol B detected in such systems is at least partly formed by aldolization of secosterol A. A possible reason for the in vivo predominance of secosterol A is that, while cholesterol hydroperoxide-5, a direct precursor of secosterol B, may be easily formed in tissues, its Hock cleavage is favored by acidic conditions, which may not be common in most tissues. The fact that Tomono et al. [142] observed a time-dependent increase of the secosterols in plasma of mice after injection of lipopolysaccharide indicates that ozone formation is easily initiated during inflammation.

The secosterols A and B induce endothelial cell dysfunction by promoting apoptosis and inhibiting endothelial-dependent arterial relaxation [143]. These products are elevated in brain tissues of Alzheimer's disease patients, and it was demonstrated that they may trigger the disease by inducing protein misfolding [144]. Elevated levels of the secosterols are found in Lewy body dementia brain tissues, where they accelerate alpha-synuclein fibrillization [145]. The secosterols bind to the p53 protein and induce it to misfold and lose the ability to bind to a consensus DNA sequence, signifying that they may contribute to cancers where wild-type inactivation of p53 occurs, such as breast cancer, colon cancer, colon adenoma, and neuroblastoma [146]. The secosterols and their acidic oxidation products are strongly cytotoxic against various human cell lines, and it was concluded that, during inflammation, cell death caused by them may contribute to further tissue damage and development of disease [147]. Formation of Schiff's bases between the secosterols and myelin basic protein (MBP) induces myelin instability and might contribute to the onset and progression of multiple sclerosis [148].

Despite the generally harmful effects of high levels of ROS, organisms employ high ROS levels in certain pathological situations in an attempt to restore normal physiological conditions. For example, singlet oxygen and ozone are produced by activated human neutrophils, where they are important for the destruction of bacteria during acute infections [7, 149]. The use of photodynamic therapy (PDT) in cancer treatment relies on the generation of singlet oxygen in the tissues to destroy cancer cells, and when PDT involves use of sensitizers conjugated to antibodies, ozone generation might be equally important [34].

13. The Influence of Dietary Factors on the Formation and Effects of Endogenous Singlet Oxygen and Ozone

Some dietary factors promote inflammation and oxidative stress, while others are anti-inflammatory and protective against oxidative stress. Generally, the proinflammatory factors may promote while the anti-inflammatory factors may inhibit the formation of singlet oxygen and ozone. More specifically, some of the dietary factors, such as carotenoids, act as quenchers of singlet oxygen. Such substances will prevent ozone formation and dysfunctions associated with singlet oxygen. Dietary carotenoids have been shown to easily accumulate in the skin, where they prevent the singlet oxygen-associated photoaging [2, 22, 150]. Just as singlet oxygen plays a role in the development of diabetes (vide supra), adequate dietary carotenoids have been reported to reduce the risk for type II diabetes and the metabolic syndrome [151-153]. Besides their singlet oxygen-quenching ability, carotenoids also have anti-inflammatory activity by interfering with the NF-[kappa]B pathway [154]. Beta carotene was reported to prevent ozone-induced proinflammatory markers in murine skin [155].

On the other hand, alcohol consumption lowers the levels of carotenoids in the human skin and increases the risk for sunburn and potentially skin cancer [156]. Alcohol consumption and cigarette smoking also lower serum carotenoid levels [157]. By lowering carotenoids, alcohol consumption and cigarette smoking reduce singlet oxygen quenching and may promote ozone formation. Moreover, since ethanol is metabolized to acetaldehyde, there are increased blood levels of acetaldehyde after alcohol consumption [158] and this may promote production of ROS. Alcohol consumption is also associated with oroesophageal squamous cell carcinoma, gastric cancer, and colorectal cancer, which maybe partly due to induction of ROS production by ethanol or its metabolite, acetaldehyde [159-161].

Helicobacter strains expressing the virulence factor cytotoxin-associated gene A (Cag-A) stimulate the expression of spermine oxidase in gastric epithelial cells and promote ROS generation and DNA damage in these cells, thereby increasing gastric cancer risk [83]. SMO expression also contributes to ulcerative colitis, an inflammatory condition that is associated with colon cancer [162]. The bacterium Enterococcus faecalis produces large amounts of superoxide anions and hydrogen peroxide in the colon and this causes DNA damage in luminal cells of the colon [163]. The large amounts of [H.sub.2][O.sub.2] may promote [sup.1][O.sub.2] and [O.sub.3] formation in that environment. In addition, some colon microorganisms convert bile components into metabolites that are carcinogenic, partly by inducing ROS generation [164]. Consumption of foods containing probiotic microorganisms may reduce oxidative stress in various ways including inhibiting the growth of oxidative stress-inducing microorganisms [164, 165].

High fat and high carbohydrate diets are associated with increased postprandial inflammation and oxidative stress [166]. Hence, such diets may promote the generation of singlet oxygen and ozone, besides other ROS. The consumption of foods rich in Maillard oxidation products may also contribute to endogenous singlet oxygen and ozone generation because dietary advanced glycation end products promote oxidative stress and inflammation through interaction with the receptor for advanced glycation products in a variety of cells, resulting in oxidative stress involving superoxide anion and [H.sub.2][O.sub.2] formation [167-169].

Various dietary phenolic substances are recognized as powerful antioxidants mainly by their scavenging of free radicals. On the other hand, these phenolic substances also have prooxidant activity in that they can react with oxygen to generate superoxide anions, hydrogen peroxide, and singlet oxygen [31, 52, 53]. Thus, consumption of coffee or tea, which is rich in these phytochemicals, also means consumption of substantial amounts of hydrogen peroxide and perhaps singlet oxygen [73, 74]. Nevertheless, the consumption of foods rich in such substances, such as fruits and vegetables, and even tea and coffee has mainly been associated with beneficial effects [170-172]. This is because, apart from direct antioxidant or prooxidant activity, these compounds also affect cellular physiology by signaling pathways. For example, they may inhibit redox-sensitive transcription factors and prooxidant enzymes such as xanthine oxidase or nitric oxide synthase [171] and/or induce expression of antioxidant enzymes and phase II detoxification enzymes [170-172]. Phytochemicals in virgin olive oil were found to lower postprandial inflammation by reducing postprandial plasma lipopolysaccharide levels [173].

14. Conclusion

Singlet oxygen may be commonly generated in tissues through a range of enzymatic and nonenzymatic reactions, and, at least based on the in vivo formation of cholesterol secosterol aldehydes, ozone formation also seems to be important. Endogenous overproduction of these two oxidants likely plays important roles in the pathogenesis of physiological disorders such as diabetes, cardiovascular diseases, skin photoaging, and some cancers. Consumption of foods rich in singlet oxygen quenchers and components with anti-inflammatory activities, including probiotics, may help reduce the negative effects of high levels of these oxidants. Phytochemicals that generate low levels of these oxidants might also be useful for cellular adaptation to oxidative stress and prevention of physiological disorders.

Conflict of Interests

The author declares that there is no conflict of interests regarding the publication of this paper.


[1] W. A. Pryor, K. N. Houk, C. S. Foote et al., "Free radical biology and medicine: it's a gas, man!," The American Journal of Physiology--Regulatory Integrative and Comparative Physiology, vol. 291, no. 3, pp. R491-R511, 2006.

[2] J. Terao, Y. Minami, and N. Bando, "Singlet molecular oxygen-quenching activity of carotenoids: relevance to protection of the skin from photoaging," Journal of Clinical Biochemistry and Nutrition, vol. 48, no. 1, pp. 57-62, 2011.

[3] L. L. Smith, "Oxygen, oxysterols, ouabain, and ozone: a cautionary tale," Free Radical Biology and Medicine, vol. 37, no. 3, pp. 318-324, 2004.

[4] J. Balla and E. Tyihak, "Direct measurement of emission of endogenous ozone from plants by GC-MS-SIM," Chromatographia, vol. 71, supplement 1, pp. 87-91, 2010.

[5] R. P. Rastogi, Richa, A. Kumar, M. B. Tyagi, and R. P. Sinha, "Molecular mechanisms of ultraviolet radiation-induced DNA damage and repair," Journal of Nucleic Acids, vol. 2010, Article ID 592980, 32 pages, 2010.

[6] E. Tyihak, A. M. Moricz, and P. G. Ott, "BioArena studies: unique function of endogenous formaldehyde and ozone in the antibiotic effect--a review," Medicinal Chemistry, vol. 8, no. 1, pp. 75-84, 2012.

[7] P. Wentworth Jr., J. E. McDunn, A. D. Wentworth et al., "Evidence for antibody-catalyzed ozone formation in bacterial killing and inflammation," Science, vol. 298, no. 5601, pp. 2195-2199, 2002.

[8] K. Yamashita, T. Miyoshi, T. Arai et al., "Ozone production by amino acids contributes to killing of bacteria," Proceedings of the National Academy of Sciences of the United States of America, vol. 105, no. 44, pp. 16912-16917, 2008.

[9] M. Y. Akhalaya, G. V. Maksimov, A. B. Rubin, J. Lademann, and M. E. Darvin, "Molecular action mechanisms of solar infrared radiation and heat on human skin," Ageing Research Reviews, vol. 16, no. 1, pp. 1-11, 2014.

[10] I. E. Kochevar, M. A. Pathak, and J. A. Parrish, "Photophysics, photochemistry, and phobiology," in Fitzpatrick's Dermatology in General Medicine, I. M. Freedberg, A. Z. Eisen, K. Wolff et al., Eds., pp. 220-229, McGraw-Hill, New York, NY, USA, 1999.

[11] A. Knak, J. Regensburger, T. Maisch, and W. Baumler, "Exposure of vitamins to UVB and UVA radiation generates singlet oxygen," Photochemical and Photobiological Sciences, vol. 13, no. 5, pp. 820-829, 2014.

[12] G. T. Wondrak, M. K. Jacobson, and E. L. Jacobson, "Endogenous UVA-photosensitizers: mediators of skin photodamage and novel targets for skin photoprotection," Photochemical and Photobiological Sciences, vol. 5, no. 2, pp. 215-237, 2006.

[13] W. Baumler, J. Regensburger, A. Knak, A. Felgentrager, and T. Maisch, "UVA and endogenous photosensitizers--the detection of singlet oxygen by its luminescence," Photochemical & Photobiological Sciences, vol. 11, no. 1, pp. 107-117, 2012.

[14] J. Baier, T. Maisch, M. Maier, M. Landthaler, and W. Baumler, "Direct detection of singlet oxygen generated by UVA irradiation in human cells and skin," Journal of Investigative Dermatology, vol. 127, no. 6, pp. 1498-1506, 2007.

[15] M. Sun, S. C. Finnemann, M. Febbraio et al., "Light-induced oxidation of photoreceptor outer segment phospholipids generates ligands for CD36-mediated phagocytosis by retinal pigment epithelium," Journal of Biological Chemistry, vol. 281, no. 7, pp. 4222-4230, 2006.

[16] M. J. Niedre, M. S. Patterson, A. Giles, and B. C. Wilson, "Imaging of photodynamically generated singlet oxygen luminescence in vivo," Photochemistry and Photobiology, vol. 81, no. 4, pp. 941-943, 2005.

[17] M. Bregnhoj, A. Blazquez-Castro, M. Westberg, T. Breitenbach, and P. R. Ogilby, "Direct 765 nm optical excitation of molecular oxygen in solution and in single mammalian cells," The Journal of Physical Chemistry B, vol. 119, no. 17, pp. 5422-5429, 2015.

[18] S. G. Sokolovski, S. A. Zolotovskaya, A. Goltsov, C. Pourreyron, A. P. South, and E. U. Rafailov, "Infrared laser pulse triggers increased singlet oxygen production in tumour cells," Scientific Reports, vol. 3, article 3484, 2013.

[19] A. M. Holzer, M. Athar, and C. A. Elmets, "The other end of the rainbow: infrared and skin," Journal of Investigative Dermatology, vol. 130, no. 6, pp. 1496-1499, 2010.

[20] P. Schroeder, C. Calles, T. Benesova, F. MacAluso, and J. Krutmann, "Photoprotection beyond ultraviolet radiation--effective sun protection has to include protection against infrared a radiation-induced skin damage," Skin Pharmacology and Physiology, vol. 23, no. 1, pp. 15-17, 2010.

[21] P. Schroeder, J. Lademann, M. E. Darvin et al., "Infrared radiation-induced matrix metalloproteinase in human skin: implications for protection," Journal of Investigative Dermatology, vol. 128, no. 10, pp. 2491-2497, 2008.

[22] M. E. Darvin, W. Sterry, J. Lademann, and T. Vergou, "The role of carotenoids in human skin," Molecules, vol. 16, no. 12, pp. 10491-10506, 2011.

[23] T. Rodrigues, L. P. de Franca, C. Kawai et al., "Protective role of mitochondrial unsaturated lipids on the preservation of the apoptotic ability of cytochrome c exposed to singlet oxygen," Thew Journal of Biological Chemistry, vol. 282, no. 35, pp. 25577-25587, 2007.

[24] M. E. Darvin, I. Gersonde, H. Albrecht, L. Zastrow, W. Sterry, and J. Lademann, "In vivo Raman spectroscopic analysis of the influence of IR radiation on the carotenoid antioxidant substances beta-carotene and lycopene in the human skin. Formation of free radicals," Laser Physics Letters, vol. 4, no. 4, pp. 318-321, 2007.

[25] F. M. Prado, M. C. B. Oliveira, S. Miyamoto et al., "Thymine hydroperoxide as a potential source of singlet molecular oxygen in DNA," Free Radical Biology and Medicine, vol. 47, no. 4, pp. 401-409, 2009.

[26] H. Wefers and H. Sies, "Oxidation of glutathione by the superoxide radical to the disulfide and the sulfonate yielding singlet oxygen," European Journal of Biochemistry, vol. 137, no. 1-2, pp. 29-36, 1983.

[27] J. Massari, R. Tokikawa, D. B. Medinas et al., "Generation of singlet oxygen by the glyoxal-peroxynitrite system," Journal of the American Chemical Society, vol. 133, no. 51, pp. 20761-20768, 2011.

[28] G. D. Mendenhall, X. C. Sheng, and T. Wilson, "Yields of excited carbonyl species from alkoxyl and from alkylperoxyl radical dismutations," Journal of the American Chemical Society, vol. 113, no. 23, pp. 8976-8977, 1991.

[29] P. Nagy, A. J. Kettle, and C. C. Winterbourn, "Superoxide-mediated formation of tyrosine hydroperoxides and methionine sulfoxide in peptides through radical addition and intramolecular oxygen transfer," The Journal of Biological Chemistry, vol. 284, no. 22, pp. 14723-14733, 2009.

[30] J. R. Kanofsky, H. Hoogland, R. Wever, and S. J. Weiss, "Singlet oxygen production by human eosinophils," The Journal of Biological Chemistry, vol. 263, no. 20, pp. 9692-9696, 1988.

[31] M. Akagawa, T. Shigemitsu, and K. Suyama, "Production of hydrogen peroxide by polyphenols and polyphenol rich beverages under quasi-physiological conditions," Bioscience, Biotechnology and Biochemistry, vol. 67, no. 12, pp. 2632-2640, 2003.

[32] G. F. Fedorova, A. V. Trofimoz, R. F. Vasilev, and T. L. Veprinstev, "Peroxy-radical-mediated chemiluminescence: mechanistic diversity and fundamentals for antioxidant assay," ARKIVOC, vol. Peroxy-radical-mediated chemiluminescence: mechanistic diversity and fundamentals for antioxidant assay, no. 8, pp. 163-215, 2007.

[33] R. Michalski, J. Zielonka, E. Gapys, A. Marcinek, J. Joseph, and B. Kalyanaraman, "Real-time measurements of amino acid and protein hydroperoxides using coumarin boronic acid," The Journal of Biological Chemistry, vol. 289, no. 32, pp. 22536-22553, 2014.

[34] A. N. Onyango, "Alternatives to the 'water oxidation pathway' of biological ozone formation," Journal of Chemical Biology, vol. 9, no. 1, pp. 1-8, 2016.

[35] M. J. Steinbeck, A. U. Khan, and M. J. Karnovsky, "Intracellular singlet oxygen generation by phagocytosing neutrophils in response to particles coated with a chemical trap," The Journal of Biological Chemistry, vol. 267, no. 19, pp. 13425-13433, 1992.

[36] C. C. Winterbourn and A. J. Kettle, "Redox reactions and microbial killing in the neutrophil phagosome," Antioxidants & Redox Signaling, vol. 18, no. 6, pp. 642-660, 2013.

[37] J. K. Hurst, "What really happens in the neutrophil phagosome?" Free Radical Biology and Medicine, vol. 53, no. 3, pp. 508-520, 2012.

[38] C. S. Foote, F. C. Shook, and R. A. Abakerli, "Chemistry of superoxide ion. 4. Singlet oxygen is not a major product of dismutation," Journal of the American Chemical Society, vol. 102, no. 7, pp. 2503-2504, 1980.

[39] M. J. Steinbeck, A. U. Khan, and M. J. Karnovsky, "Extracellular production of singlet oxygen by stimulated macrophages quantified using 9,10-diphenylanthracene and perylene in a polystyrene film," The Journal of Biological Chemistry, vol. 268, no. 21, pp. 15649-15654,1993.

[40] C. Prolo, M. N. Alvarez, and R. Radi, "Peroxynitrite, a potent macrophage-derived oxidizing cytotoxin to combat invading pathogens," BioFactors, vol. 40, no. 2, pp. 215-225, 2014.

[41] P. Di Mascio, E. J. H. Bechara, M. H. G. Medeiros, K. Briviba, and H. Sies, "Singlet molecular oxygen production in the reaction of peroxynitrite with hydrogen peroxide," FEBS Letters, vol. 355, no. 3, pp. 287-289, 1994.

[42] A. A. Noronha-Dutra, M. M. Epperlein, and N. Woolf, "Reaction of nitric oxide with hydrogen peroxide to produce potentially cytotoxic singlet oxygen as a model for nitric oxide-mediated killing," FEBS Letters, vol. 321, no. 1, pp. 59-62, 1993.

[43] G. A. Russell, "Deuterium-isotope effects in the autoxidation of aralkyl hydrocarbons--mechanism of the interaction of peroxy radicals," Journal of the American Chemical Society, vol. 79, no. 14, pp. 3871-3877, 1957.

[44] S. Miyamoto, G. E. Ronsein, F. M. Prado et al., "Biological hydroperoxides and singlet molecular oxygen generation," IUBMB Life, vol. 59, no. 4-5, pp. 322-331, 2007.

[45] S. Miyamoto, G. R. Martinez, M. H. G. Medeiros, and P. Di Mascio, "Singlet molecular oxygen generated by biological hydroperoxides," Journal of Photochemistry and Photobiology B: Biology, vol. 139, pp. 24-33, 2014.

[46] K. M. Schaich, "Lipid oxidation: theoretical aspects," in Baileys Industrial oil and Fat Products, F. Shahidi, Ed., vol. 1, pp. 269-355, Edible Oil and Fat Products: Chemistry, Properties and Health Effects, 6th edition, 2005.

[47] M. Rac, M. Krupka, S. Binder et al., "Oxidative damage of U937 human leukemic cells caused by hydroxyl radical results in singlet oxygen formation," PLOS ONE, vol. 10, no. 3, Article ID e0116958, 2015.

[48] A. N. Onyango and N. Baba, "New hypotheses on the pathways of formation of malondialdehyde and isofurans," Free Radical Biology and Medicine, vol. 49, no. 10, pp. 1594-1600, 2010.

[49] K. Kaur, R. G. Salomon, J. O'Neil, and H. F. Hoff, "(Carboxyalkyl) pyrroles in human plasma and oxidized low-density lipoproteins," Chemical Research in Toxicology, vol. 10, no. 12, pp. 1387-1396, 1997.

[50] A. N. Onyango and N. Baba, "A non-radical mechanism for the rearrangement of linoleic acid dihydroperoxides," New Journal of Chemistry, vol. 33, no. 8, pp. 1635-1636, 2009.

[51] L. Trazl and J. Pipek, "Formation of excited formaldehyde in model reactions simulating real biological systems," Journal of Molecular Structure: THEOCHEM, vol. 170, pp. 213-223, 1988.

[52] Y. Li, M. A. Trush, and J. D. Yager, "DNA damage caused by reactive oxygen species originating from a copper-dependent oxidation of the 2-hydroxy catechol of estradiol," Carcinogenesis, vol. 15, no. 7, pp. 1421-1427, 1994.

[53] I. Kruk, K. Lichszteld, T. Michalska, J. Wronska, and M. Bounias, "The formation of singlet oxygen during oxidation of catechol amines as detected by infrared chemiluminescence and spectrophotometry method," Zeitschrift fur Naturforschung C, vol. 44, no. 11-12, pp. 895-900, 1989.

[54] S. Ikeuci, Y. Miyamoto, T. Katoh, and K. Nishimura, "Action of ascorbic acid on a myosin molecule derived from carp," Bioscience, Biotechnology and Biochemistry, vol. 71, no. 8, pp. 2091-2094, 2007.

[55] G. E. Ronsein, M. C. B. de Oliveira, M. H. G. de Medeiros, and P. di Mascio, "Mechanism of dioxindolylalanine formation by singlet molecular oxygen-mediated oxidation of tryptophan residues," Photochemical and Photobiological Sciences, vol. 10, no. 11, pp. 1727-1730, 2011.

[56] G. S. Timmins, R. E. dos Santos, A. C. Whitwood et al., "Lipid peroxidation-dependent chemiluminescence from the cyclization of alkylperoxyl radicals to dioxetane radical intermediates," Chemical Research in Toxicology, vol. 10, no. 10, pp. 1090-1096, 1997.

[57] S. H. Lee, T. Oe, and I. A. Blair, "Vitamin C-induced decomposition of lipid hydroperoxides to endogenous genotoxins," Science, vol. 292, no. 5524, pp. 2083-2086, 2001.

[58] C. Schneider, K. A. Tallman, N. A. Porter, and A. R. Brash, "Two distinct pathways of formation of 4-hydroxy-2-nonenal," The Journal of Biological Chemistry, vol. 276, no. 24, pp. 20831-20838, 2001.

[59] R. C. Murphy and K. M. Johnson, "Cholesterol, reactive oxygen species, and the formation of biologically active mediators," The Journal of Biological Chemistry, vol. 283, no. 23, pp. 15521-15525, 2008.

[60] H. Yin, L. Xu, and N. A. Porter, "Free radical lipid peroxidation: mechanisms and analysis," Chemical Reviews, vol. 111, no. 10, pp. 5944-5972, 2011.

[61] A. D. Wentworth, B.-D. Song, J. Nieva, A. Shafton, S. Tripurenani, and P. Wentworth Jr., "The ratio of cholesterol 5,6-secosterols formed from ozone and singlet oxygen offers insight into the oxidation of cholesterol in vivo," Chemical Communications, no. 21, pp. 3098-3100, 2009.

[62] M. Uemi, G. E. Ronsein, F. M. Prado et al., "Cholesterol hydroperoxides generate singlet molecular oxygen [[O.sub.2] ([sup.1][[DELTA].sub.g])]: near-IR emission, [sup.18]O-labeled hydroperoxides, and mass spectrometry," Chemical Research in Toxicology, vol. 24, no. 6, pp. 887-895, 2011.

[63] E. W. Kellogg and I. Fridovich, "Superoxide, hydrogen peroxide, and singlet oxygen in lipid peroxidation by a xanthine oxidase system," The Journal of Biological Chemistry, vol. 250, no. 22, pp. 8812-8817, 1975.

[64] A. U. Khan and M. Kasha, "Singlet molecular oxygen in the Haber-Weiss reaction," Proceedings of the National Academy of Sciences of the United States of America, vol. 91, no. 26, pp. 12365-12367, 1994.

[65] W. H. Koppenol, "The Haber-Weiss cycle--70 years later," Redox Report, vol. 6, no. 4, pp. 229-234, 2001.

[66] S. Miyamoto, I. L. Nantes, P. A. Faria et al., "Cytochrome c-promoted cardiolipin oxidation generates singlet molecular oxygen," Photochemical and Photobiological Sciences, vol. 11, no. 10, pp. 1536-1546, 2012.

[67] E. E. Boh, W. H. Baricos, C. Bernofsky, and R. H. Steele, "Mitochondrial chemiluminescence elicited by acetaldehyde," Journal of Bioenergetics and Biomembranes, vol. 14, no. 2, pp. 115-133, 1982.

[68] L. Trezl, G. Torok, G. Vasvari, J. Pipek, and L. Hullan, "Formation of burst of chemiluminescence, excited aldehydes, and singlet oxygen in model reactions and from carcinogenic compounds in rat liver S9 fractions," Periodica Polytechnica-Chemical Engineering, vol. 36, pp. 236-239, 1992.

[69] E. Tyihak, S. Rozsnyay, E. Sardi, G. Gullner, L. Trezl, and R. Gaborjanyi, "Possibility of formation of excited formaldehyde and singlet oxygen in biotic and abiotic stress situations.," Acta Biologica Hungarica, vol. 45, no. 1, pp. 3-10, 1994.

[70] L. Trazl, L. Hullan, T. Szarvas, A. Csiba, and J. Pipek, "Analogies and differences in the excited reactions of formaldehyde and D-glucose," Acta Biologica Hungarica, vol. 49, no. 2-4, pp. 437-447, 1998.

[71] E. Tyihak, A. M. Moricz, P. G. Ott, G. Katay, and E. Mincsovics, "Biological characterization of ingredients in OPLC-BioArenagreenhouse-system: unique reactions of endogenous HCHO and [O.sub.3] in in vitro and in vivo conditions," Chromatographia, vol. 75, no. 17, pp. 983-990, 2012.

[72] E. Tyihak, A. M. Moricz, P. G. Ott, Z. Kiraly-Veghely, G. Katay, and E. Mincsovics, "BioArena system for knowing and understanding the biological world: a review with new experimental results," Journal of AOAC International, vol. 96, no. 6, pp. 1189-1199, 2013.

[73] T. Kato, K. Hiramoto, and K. Kikugawa, "Possible occurrence of new mutagens with the DNA breaking activity in coffee," Mutation Research/Fundamental and Molecular Mechanisms of Mutagenesis, vol. 306, no. 1, pp. 9-17, 1994.

[74] Y. Fujita, K. Wakabayashi, M. Nagao, and T. Sugimura, "Implication of hydrogen peroxide in the mutagenicity of coffee," Mutation Research Letters, vol. 144, no. 4, pp. 227-230, 1985.

[75] H. Ueno, K. Nakamuro, Y. Sayato, and S. Okada, "Characteristics of mutagenesis by glyoxal in Salmonella typhimurium: contribution of singlet oxygen," Mutation Research/Fundamental and Molecular Mechanisms of Mutagenesis, vol. 251, no. 1, pp. 99-107, 1991.

[76] S.-B. Kim, I.-S. Kim, D.-M. Yeum, and Y.-H. Park, "Mutagenicity of Maillard reaction products from d-glucose-amino acid mixtures and possible roles of active oxygens in the mutagenicity," Mutation Research/DNA Repair, vol. 254, no. 1, pp. 65-69, 1991.

[77] K. Hiramoto, T. Kato, and K. Kikugawa, "Generation of DNA-breaking activity in the Maillard reaction of glucose-amino acid mixtures in a solid system," Mutation Research/Fundamental and Molecular Mechanisms of Mutagenesis, vol. 285, no. 2, pp. 191-198, 1993.

[78] J. Clayden, N. Greeves, and S. Warren, Organic Chemistry, Oxford University Press, Oxford, UK, 2nd edition, 2012.

[79] I. Kruk, Environmental Toxicology and Chemistry of Oxygen Species, vol. 2, Springer, part 1, 1998.

[80] N. Tada, L. Cui, H. Okubo, T. Miura, and A. Itoh, "A facile catalyst-free synthesis of gem-dihydroperoxides with aqueous hydrogen peroxide," Chemical Communications, vol. 46, no. 10, pp. 1772-1774, 2010.

[81] K. S. Renar, S. Pecar, and J. Iskra, "Activation of aqueous hydrogen peroxide for non-catalyzed dihydroperoxidation of ketones by azeotropic removal of water," Organic & Biomolecular Chemistry, vol. 13, no. 36, pp. 9369-9372, 2015.

[82] J. Hang, P. Ghorai, S. A. Finkenstaedt-Quinn et al., "Generation of singlet oxygen from fragmentation of monoactivated 1,1-dihydroperoxides," Journal of Organic Chemistry, vol. 77, no. 3, pp. 1233-1243, 2012.

[83] R. Chaturvedi, T. de Sablet, R. Peek, and K. Wilson, "Spermine oxidase, a polyamine catabolic enzyme that links Helicobacter pylori CagA and gastric cancer risk," Gut Microbes, vol. 3, no. 1, pp. 48-56, 2012.

[84] V. Battaglia, C. DeStefano Shields, T. Murray-Stewart, and R. A. Casero Jr., "Polyamine catabolism in carcinogenesis: potential targets for chemotherapy and chemoprevention," Amino Acids, vol. 46, no. 3, pp. 511-519, 2014.

[85] T. Murray-Stewart, Y. Wang, A. Goodwin, A. Hacker, A. Meeker, and R. A. Casero Jr., "Nuclear localization of human spermine oxidase isoforms-possible implications in drug response and disease etiology," FEBS Journal, vol. 275, no. 11, pp. 2795-2806, 2008.

[86] M. Salimi, K. Abdi, H. M. Kandelous et al., "Antiproliferative effects of copper(II)-polypyridyl complexes in breast cancer cells through inducing apoptosis," BioMetals, vol. 28, no. 2, pp. 267-278, 2015.

[87] M. Cervelli, G. Bellavia, E. Fratini et al., "Spermine oxidase (SMO) activity in breast tumor tissues and biochemical analysis of the anticancer spermine analogues BENSpm and CPEN-Spm," BMC Cancer, vol. 10, article 555, 2010.

[88] S. L. Hazen, A. d'Avignon, M. M. Anderson, F. F. Hsu, and J. W. Heinecke, "Human neutrophils employ the myeloperoxidase-hydrogen peroxide-chloride system to oxidize [alpha]-amino acids to a family of reactive aldehydes. Mechanistic studies identifying labile intermediates along the reaction pathway," Journal of Biological Chemistry, vol. 273, no. 9, pp. 4997-5005, 1998.

[89] Y. Kato, Y. Mori, Y. Makino et al., "Formation of [N.sup.[epsilon]]-(hexanonyl)lysine in protein exposed to lipid hydroperoxide. A plausible marker for lipid hydroperoxide-derived protein modification," The Journal of Biological Chemistry, vol. 274, no. 29, pp. 20406-20414, 1999.

[90] W. Jian, S. H. Lee, J. S. Arora, M. V S. Elipe, and I. A. Blair, "Unexpected formation of etheno-2'-deoxyguanosine adducts from 5(S)-hydroperoxyeicosatetraenoic acid:evidence for a bis-hydroperoxide intermediate," Chemical Research in Toxicology, vol. 18, no. 3, pp. 599-610, 2004.

[91] Q. Wang, E. Durand, R. J. Elias, and R. V. Tikekar, "Generation of reactive oxidative species from thermal treatment of sugar solutions," Food Chemistry, vol. 196, pp. 301-308, 2016.

[92] S. Kawakishi, Y. Okawa, and K. Uchida, "Oxidative damage of protein induced by the Amadori compound-copper ion system," Journal of Agricultural and Food Chemistry, vol. 38, no. 1, pp. 13-17, 1990.

[93] A. Elgawish, M. Glomb, M. Friedlander, and V. M. Monnier, "Involvement of hydrogen peroxide in collagen cross-linking by high glucose in vitro and in vivo," The Journal of Biological Chemistry, vol. 271, no. 22, pp. 12964-12971, 1996.

[94] S. Arena, A. M. Salzano, G. Renzone, C. D'Ambrosio, and A. Scaloni, "Non-enzymatic glycation and glycoxidation protein products in foods and diseases: an interconnected, complex scenario fully open to innovative proteomic studies," Mass Spectrometry Reviews, vol. 33, no. 1, pp. 49-77, 2014.

[95] O. Novotny, K. Cejpek, and J. Velisek, "Formation of carboxylic acids during degradation of monosaccharides," Czech Journal of Food Sciences, vol. 26, no. 2, pp. 117-131, 2008.

[96] M. Rac, M. Sedlarova, and P. Pospisil, "The formation of electronically excited species in the human multiple myeloma cell suspension," Scientific Reports, vol. 5, article 8882, 2015.

[97] X. Zhu, P. Wentworth Jr., A. D. Wentworth, A. Eschenmoser, R. A. Lerner, and I. A. Wilson, "Probing the antibody-catalyzed water-oxidation pathway at atomic resolution," Proceedings of the National Academy of Sciences of the United States of America, vol. 101, no. 8, pp. 2247-2252, 2004.

[98] J. Brinkhorst, S. J. Nara, and D. A. Pratt, "Hock cleavage of cholesterol-5[alpha]-hydroperoxide: an ozone-free pathway to the cholesterol ozonolysis products identified in arterial plague and brain tissue," Journal of the American Chemical Society, vol. 130, no. 37, pp. 12224-12225, 2008.

[99] M. Uemi, G. E. Ronsein, S. Miyamoto, M. H. G. Medeiros, and P. Di Mascio, "Generation of cholesterol carboxyaldehyde by the reaction of singlet molecular oxygen [[O.sub.2] (1[DELTA]g)] as well as ozone with cholesterol," Chemical Research in Toxicology, vol. 22, no. 5, pp. 875-884, 2009.

[100] N. Miyoshi, L. Iuliano, S. Tomono, and H. Ohshima, "Implications of cholesterol autoxidation products in the pathogenesis of inflammatory diseases," Biochemical and Biophysical Research Communications, vol. 446, no. 3, pp. 702-708, 2014.

[101] C. Hamelin, "Production of single- and double-strand breaks in plasmid dna by ozone," International Journal of Radiation Oncology, Biology, Physics, vol. 11, no. 2, pp. 253-257, 1985.

[102] C. Hamelin and Y. S. Chung, "Repair of ozone-induced DNA lesions in Escherichia coli B cells," Mutation Research/ Fundamental and Molecular Mechanisms of Mutagenesis, vol. 214, no. 2, pp. 253-255, 1989.

[103] O. Cantoni, P. Sestili, and F. Cattabeni, "Induction of DNA double strand breaks in cultured mammalian cells exposed to hydrogen peroxide and histidine," Cytotechnology, vol. 5, no. 1, pp. 80-81, 1991.

[104] O. Cantoni, P. Sestili, G. Brandi, and F. Cattabeni, "The l-histidine-mediated enhancement of hydrogen peroxide-induced cytotoxicity is a general response in cultured mammalian cell lines and is always associated with the formation of DNA double strand breaks," FEBS Letters, vol. 353, no. 1, pp. 75-78, 1994.

[105] P. Sestili, O. Cantoni, F. Cattabeni, and D. Murray, "Evidence for separate mechanisms of cytotoxicity in mammalian cells treated with hydrogen peroxide in the absence or presence of L-histidine," Biochimica et Biophysica Acta--Molecular Cell Research, vol. 1268, no. 2, pp. 130-136, 1995.

[106] I. Chomaand W. Jesionek, "TLC-Directbioautography as a high throughput method for detection of antimicrobials in plants," Chromatography, vol. 2, no. 2, pp. 225-238, 2015.

[107] J. Cerkovnik and B. Plesnicar, "Recent advances in the chemistry of hydrogen trioxide (HOOOH)," Chemical Reviews, vol. 113, no. 10, pp. 7930-7951, 2013.

[108] M. Hajimohammadi, N. Safari, H. Mofakham, and A. Shaabani, "A new and efficient aerobic oxidation of aldehydes to carboxylic acids with singlet oxygen in the presence of porphyrin sensitizers and visible light," Tetrahedron Letters, vol. 51, no. 31, pp. 4061-4065, 2010.

[109] D. Harman, "Aging: a theory based on free radical and radiation chemistry," Journal of Gerontology, vol. 11, no. 3, pp. 298-300, 1956.

[110] D. Harman, "The biologic clock: the mitochondria?" Journal of the American Geriatrics Society, vol. 20, no. 4, pp. 145-147, 1972.

[111] I. Shokolenko, N. Venediktova, A. Bochkareva, G. I. Wilson, and M. F. Alexeyev, "Oxidative stress induces degradation of mitochondrial DNA," Nucleic Acids Research, vol. 37, no. 8, pp. 2539-2548, 2009.

[112] A. Boveris, N. Oshino, and B. Chance, "The cellular production of hydrogen peroxide," Biochemical Journal, vol. 128, no. 3, pp. 617-630, 1972.

[113] G. Loschen and A. Azzi, "On the formation of hydrogen peroxide and oxygen radicals in heart mitochondria," Recent Advances in Studies on Cardiac Structure and Metabolism, vol. 7, pp. 3-12, 1975.

[114] V. Valez, A. Cassina, I. Batinic-Haberle, B. Kalyanaraman, G. Ferrer-Sueta, and R. Radi, "Peroxynitrite formation in nitric oxide-exposed submitochondrial particles: detection, oxidative damage and catalytic removal by Mn-porphyrins," Archives of Biochemistry and Biophysics, vol. 529, no. 1, pp. 45-54, 2013.

[115] C. Giulivi, J. J. Poderoso, and A. Boveris, "Production of nitric oxide by mitochondria," The Journal of Biological Chemistry, vol. 273, no. 18, pp. 11038-11043, 1998.

[116] M. Kirca, P. Kleinbongard, D. Soetkamp et al., "Interaction between Connexin 43 and nitric oxide synthase in mice heart mitochondria," Journal of Cellular and Molecular Medicine, vol. 19, no. 4, pp. 815-825, 2015.

[117] G. B. Stefano, K. J. Mantione, L. Capellan et al., "Morphine stimulates nitric oxide release in human mitochondria," Journal of Bioenergetics and Biomembranes, vol. 47, no. 5, pp. 409-417, 2015.

[118] T. Roszer, "Nitric oxide synthesis in the mitochondria of animal cells," in The Biology of Subcellular Nitric Oxide, pp. 169-178, Springer, Amsterdam, The Netherlands, 2012.

[119] M. R. Ramis, S. Esteban, A. Miralles, D. Tan, and R. Reiter, "Protective effects of melatonin and mitochondria-targeted antioxidants against oxidative stress: a review," Current Medicinal Chemistry, vol. 22, no. 22, pp. 2690-2711, 2015.

[120] R. Radi, J. S. Beckman, K. M. Bush, and B. A. Freeman, "Peroxynitrite-induced membrane lipid peroxidation: the cytotoxic potential of superoxide and nitric oxide," Archives of Biochemistry and Biophysics, vol. 288, no. 2, pp. 481-487, 1991.

[121] E. D. Kerver, I. M. C. Vogels, K. S. Bosch, H. Vreeling-Sindelaarovaa, R. J. M. Van Den Munckhof, and W. M. Frederiks, "In situ detection of spontaneous superoxide anion and singlet oxygen production by mitochondria in rat liver and small intestine," The Histochemical Journal, vol. 29, no. 3, pp. 229-237, 1997.

[122] M. Berneburg, S. Grether-Beck, V. Kurten et al., "Singlet oxygen mediates the UVA-induced generation of the photoaging-associated mitochondrial common deletion," The Journal of Biological Chemistry, vol. 274, no. 22, pp. 15345-15349, 1999.

[123] R. De Bont and N. van Larebeke, "Endogenous DNA damage in humans: a review of quantitative data," Mutagenesis, vol. 19, no. 3, pp. 169-185, 2004.

[124] J. Cadet, T. Douki, and J.-L. Ravanat, "Oxidatively generated damage to cellular DNA by UVB and UVA radiation," Photochemistry and Photobiology, vol. 91, no. 1, pp. 140-155, 2015.

[125] A. Kumar, V. Pottiboyina, and M. D. Sevilla, "Hydroxyl radical (Off) reaction with guanine in an aqueous environment: a DFT study," The Journal of Physical Chemistry B, vol. 115, no. 50, pp. 15129-15137, 2011.

[126] D. Dai, Y. Chiao, D. J. Marcinek, H. H. Szeto, and P. S. Rabinovitch, "Mitochondrial oxidative stress in aging and healthspan," Longevity & Healthspan, vol. 3, article 6, 2014.

[127] S. E. Schriner, N. J. Linford, G. M. Martin et al., "Medecine: extension of murine life span by overexpression of catalase targeted to mitochondria," Science, vol. 308, no. 5730, pp. 1909-1911, 2005.

[128] P. C. Tapia, "Sublethal mitochondrial stress with an attendant stoichiometric augmentation of reactive oxygen species may precipitate many of the beneficial alterations in cellular physiology produced by caloric restriction, intermittent fasting, exercise and dietary phytonutrients: 'mitohormesis' for health and vitality," Medical Hypotheses, vol. 66, no. 4, pp. 832-843, 2006.

[129] M. Ristow and K. Schmeisser, "Mitohormesis: promoting health and lifespan by increased levels of reactive oxygen species (ROS)," Dose-Response, vol. 12, no. 2, pp. 288-341, 2014.

[130] K. Sharma, "Mitochondrial hormesis and diabetic complications," Diabetes, vol. 64, no. 3, pp. 663-672, 2015.

[131] I. Wilkins-Peter, L. Delgado-Roche, J. M. Barrios, and G. B. Fabregas-Popoco, "Rectal insufflation of ozone attenuates chronic oxidative stress in elderly patients with cardiovascular diseases," Oxidants and Antioxidants in Medical Science, vol. 4, no. 1, pp. 23-27, 2015.

[132] G. Martinez-Sanchez, S. M. Al-Dalain, S. Menandez et al., "Therapeutic efficacy of ozone in patients with diabetic foot," European Journal of Pharmacology, vol. 523, no. 1-3, pp. 151-161, 2005.

[133] M. Sagai and V. Bocci, "Mechanisms of action involved in ozone therapy: is healing induced via a mild oxidative stress?" Medical Gas Research, vol. 1, article 29, 2011.

[134] R. P. E. Sarkany, "Making sense of the porphyrias," Photodermatology Photoimmunology and Photomedicine, vol. 24, no. 2, pp. 102-108, 2008.

[135] A. Umeno, M. Shichiri, N. Ishida et al., "Singlet oxygen induced products of linoleates, 10- and 12-(Z,E)-hydroxyoctadecadienoic acids (HODE), can be potential biomarkers for early detection of type 2 Diabetes," PLoS ONE, vol. 8, no. 5, Article ID e63542, 2013.

[136] K. Murotomi, A. Umeno, M. Yasunaga et al., "Switching from singlet-oxygen-mediated oxidation to free-radical-mediated oxidation in the pathogenesis of type 2 diabetes in model mouse," Free Radical Research, vol. 49, no. 2, pp. 133-138, 2015.

[137] A. Umeno, K. Yoshino, Y. Hashimoto et al., "Multi-biomarkers for early detection of type 2 diabetes, including 10- and 12-(Z,E)-hydroxyoctadecadienoic acids, insulin, leptin, and adiponectin," PLoS ONE, vol. 10, no. 7, Article ID e0130971, 2015.

[138] A. Umeno, H. Nagai, Y. Hagihara, and Y. Yoshida, "Demand for the early detection of diabetic risk at annual health examinations and a probable solution," Journal of Diabetes and Metabolis, vol. 6, article 589, 2015.

[139] S. M. Grundy, "Pre-diabetes, metabolic syndrome, and cardiovascular risk," Journal of the American College of Cardiology, vol. 59, no. 7, pp. 635-643, 2012.

[140] S. L. Nowotarski, P. M. Woster, and R. A. Casero Jr., "Polyamines and cancer: implications for chemotherapy and chemoprevention," Expert Reviews in Molecular Medicine, vol. 15, article e3, 2013.

[141] P. Wentworth Jr., J. Nieva, C. Takeuchi et al., "Evidence for ozone formation in human atherosclerotic arteries," Science, vol. 302, no. 5647, pp. 1053-1056, 2003.

[142] S. Tomono, N. Miyoshi, H. Shiokawa et al., "Formation of cholesterol ozonolysis products in vitro and in vivo through a myeloperoxidase-dependent pathway," Journal of Lipid Research, vol. 52, no. 1, pp. 87-97, 2011.

[143] F. Luchetti, B. Canonico, E. Cesarini et al., "7-ketocholesterol and 5,6-secosterol induce human endothelial cell dysfunction by differential mechanisms," Steroids, vol. 99, pp. 204-211, 2015.

[144] Q. Zhang, E. T. Powers, J. Nieva et al., "Metabolite-initiated protein misfolding may trigger Alzheimer's disease," Proceedings of the National Academy of Sciences of the United States of America, vol. 101, no. 14, pp. 4752-4757, 2004.

[145] D. A. Bosco, D. M. Fowler, Q. Zhang et al., "Elevated levels of oxidized cholesterol metabolites in Lewy body disease brains accelerate [alpha]-synuclein fibrilization," Nature Chemical Biology, vol. 2, no. 5, pp. 249-253, 2006.

[146] J. Nieva, B.-D. Song, J. K. Rogel et al., "Cholesterol secosterol aldehydes induce amyloidogenesis and dysfunction of wildtype tumor protein p53," Chemistry & Biology, vol. 18, no. 7, pp. 920-927, 2011.

[147] S. Tomono, Y. Yasue, N. Miyoshi, and H. Ohshima, "Cytotoxic effects of secosterols and their derivatives on several cultured cells," Bioscience, Biotechnology and Biochemistry, vol. 77, no. 3, pp. 651-653, 2013.

[148] N. K. Cygan, J. C. Scheinost, T. D. Butters, and P. Wentworth, "Adduction of cholesterol 5,6-secosterol aldehyde to membrane-bound myelin basic protein exposes an immunodominant epitope," Biochemistry, vol. 50, no. 12, pp. 2092-2100, 2011.

[149] Y. Nishinaka, T. Arai, S. Adachi, A. Takaori-Kondo, and K. Yamashita, "Singlet oxygen is essential for neutrophil extracellular trap formation," Biochemical and Biophysical Research Communications, vol. 413, no. 1, pp. 75-79, 2011.

[150] J. Lademann, W. Kocher, R. Yu et al., "Cutaneous carotenoids: the mirror of lifestyle?" Skin Pharmacology and Physiology, vol. 27, no. 4, pp. 201-207, 2014.

[151] I. Sluijs, E. Cadier, J. W. J. Beulens, D. L. van der A, A. M. W. Spijkerman, and Y. T. van der Schouw, "Dietary intake of carotenoids and risk of type 2 diabetes," Nutrition, Metabolism and Cardiovascular Diseases, vol. 25, no. 4, pp. 376-381, 2015.

[152] I. Sluijs, J. W. J. Beulens, D. E. Grobbee, and Y. T. Van Der Schouw, "Dietary carotenoid intake is associated with lower prevalence of metabolic syndrome in middle-aged and elderly men," Journal of Nutrition, vol. 139, no. 5, pp. 987-992, 2009.

[153] M. A. Beydoun, M. R. Shroff, X. Chen, H. A. Beydoun, Y. Wang, and A. B. Zonderman, "Serum antioxidant status is associated with metabolic syndrome among U.S. adults in recent national surveys," The Journal of Nutrition, vol. 141, no. 5, pp. 903-913, 2011.

[154] A. Kaulmann and T. Bohn, "Carotenoids, inflammation, and oxidative stress-implications of cellular signaling pathways and relation to chronic disease prevention," Nutrition Research, vol. 34, no. 11, pp. 907-929, 2014.

[155] G. Valacchi, A. Pecorelli, M. Mencarelli, E. Maioli, and P. A. Davis, "Beta-carotene prevents ozone-induced proinflammatory markers in murine skin," Toxicology and Industrial Health, vol. 25, no. 4-5, pp. 241-247, 2009.

[156] M. E. Darvin, W. Sterry, J. Lademann, and A. Patzelt, "Alcohol consumption decreases the protection efficiency of the antioxidant network and increases the risk of sunburn in human skin," Skin Pharmacology and Physiology, vol. 26, no. 1, pp. 45-51, 2012.

[157] K. Aoki, Y. Ito, R. Sasaki, M. Ohtani, N. Hamajima, and A. Asano, "Smoking, alcohol drinking and serum carotenoids levels," Japanese Journal of Cancer Research, vol. 78, no. 10, pp. 1049-1056, 1987.

[158] S. Balbo, L. Meng, R. L. Bliss, J. A. Jensen, D. K. Hatsukami, and S. S. Hecht, "Time course of DNA adduct formation in peripheral blood granulocytes and lymphocytes after drinking alcohol," Mutagenesis, vol. 27, no. 4, pp. 485-490, 2012.

[159] M. Tamura, H. Matsui, T. Kaneko, and I. Hyodo, "Alcohol is an oxidative stressor for gastric epithelial cells: detection of superoxide in living cells," Journal of Clinical Biochemistry and Nutrition, vol. 53, no. 2, pp. 75-80, 2013.

[160] M. Tamura, H. Ito, H. Matsui, and I. Hyodo, "Acetaldehyde is an oxidative stressor for gastric epithelial cells," Journal of Clinical Biochemistry and Nutrition, vol. 55, no. 1, pp. 26-31, 2014.

[161] Y. Liu, H. Chen, Z. Sun, and X. Chen, "Molecular mechanisms of ethanol-associated oro-esophageal squamous cell carcinoma," Cancer Letters, vol. 361, no. 2, pp. 164-173, 2015.

[162] S.-K. S. Hong, R. Chaturvedi, M. B. Piazuelo et al., "Increased expression and cellular localization of spermine oxidase in ulcerative colitis and relationship to disease activity," Inflammatory Bowel Diseases, vol. 16, no. 9, pp. 1557-1566, 2010.

[163] M. M. Huycke, V. Abrams, and D. R. Moore, "Enterococcus faecalis produces extracellular superoxide and hydrogen peroxide that damages colonic epithelial cell DNA," Carcinogenesis, vol. 23, no. 3, pp. 529-536, 2002.

[164] M. A. Azcarate-Peril, M. Sikes, and J. M. Bruno-Barcena, "The intestinal microbiota, gastrointestinal environment and colorectal cancer: a putative role for probiotics in prevention of colorectal cancer?" The American Journal of Physiology--Gastrointestinal and Liver Physiology, vol. 301, no. 3, pp. G401-G424, 2011.

[165] A. Mohammadi, S. Jazayeri, K. Khosravi-Darani et al., "Effects of probiotics on biomarkers of oxidative stress and inflammatory factors in petrochemical workers: a randomized, double-blind, placebo-controlled trial," International Journal of Preventive Medicine, vol. 6, no. 1, p. 82, 2015.

[166] C. Patel, H. Ghanim, S. Ravishankar et al., "Prolonged reactive oxygen species generation and nuclear factor-[kappa]B activation after a high-fat, high-carbohydrate meal in the obese," The Journal of Clinical Endocrinology & Metabolism, vol. 92, no. 11, pp. 4476-4479, 2007.

[167] M. W. Poulsen, M. J. Bak, J. M. Andersen et al., "Effect of dietary advanced glycation end products on postprandial appetite, inflammation, and endothelial activation in healthy overweight individuals," European Journal of Nutrition, vol. 53, no. 2, pp. 661-672, 2014.

[168] S. I. Yamagishi and T. Matsui, "Pathologic role of dietary advanced glycation end products in cardiometabolic disorders, and therapeutic intervention," Nutrition, vol. 32, no. 2, pp. 157-165, 2015.

[169] G. Daffu, C. H. del Pozo, K. M. O'Shea, R. Ananthakrishnan, R. Ramasamy, and A. M. Schmidt, "Radical roles for RAGE in the pathogenesis of oxidative stress in cardiovascular diseases and beyond," International Journal of Molecular Sciences, vol. 14, no. 10, pp. 19891-19910, 2013.

[170] K. B. Pandey and S. I. Rizvi, "Plant polyphenols as dietary antioxidants in human health and disease," Oxidative Medicine and Cellular Longevity, vol. 2, no. 5, pp. 270-278, 2009.

[171] M. S. Butt, A. Imran, M. K. Sharif et al., "Black tea polyphenols: a mechanistic treatise," Critical Reviews in Food Science and Nutrition, vol. 54, no. 8, pp. 1002-1011, 2014.

[172] V. Calabrese, C. Cornelius, A. Trovato-Salinaro et al., "The hormetic role of dietary antioxidants in free radical-related diseases," Current Pharmaceutical Design, vol. 16, no. 7, pp. 877-883, 2010.

[173] A. Camargo, O. A. Rangel-Zuniga, C. Haro et al., "Olive oil phenolic compounds decrease the postprandial inflammatory response by reducing postprandial plasma lipopolysaccharide levels," Food Chemistry, vol. 162, pp. 161-171, 2014.

Department of Food Science and Technology, Jomo Kenyatta University of Agriculture and Technology, P.O. Box 62000, Nairobi 00200, Kenya

Correspondence should be addressed to Arnold N. Onyango;

Received 27 December 2015; Accepted 8 February 2016

Academic Editor: Sergio Di Meo

Caption: Figure 1: Formation of [sup.1][O.sub.2] through reaction of thymine peroxyl radicals (1) by the Russell mechanism [25].

Caption: Figure 2: Russell-type mechanism for formation of [sup.1][O.sub.2] from the reaction of glutathione (RSH) with superoxide anions ([sup.*-][O.sub.2]) [26].

Caption: Figure 3: Russell-type mechanism for formation of [sup.1][O.sub.2] upon reaction of glyoxal (6) with peroxynitrite (ONO[O.sup.-]) via formyl radical (8) [27] and proposed occurrence of such a reaction via formyl radicals formed during lipid oxidation.

Caption: Figure 4: Formation of [sup.1][O.sub.2] via dismutation of alkoxyl radicals [28]. The asterisk indicates that the carbonyl is in excited state.

Caption: Figure 5: Formation of [sup.1][O.sub.2] during the superoxide-dependent oxidation of tyrosine 11 [29].

Caption: Figure 6: Proposed formation of [sup.1][O.sub.2] from catechol derivative 15 via hydroperoxide 17 formed by superoxide anion addition and [sup.1][O.sub.2] formation via oxidation of semiquinone radical 16 to quinone 18 in the presence of [Cu.sup.2+] ions [30]. Catechol derivative 15 may undergo oxidation to the semiquinone radical 16 without metal catalysis [31].

Caption: Figure 7: Formation of [sup.1][O.sub.2] during the oxidation of tryptophan 19 via dioxetane 24 [32,33] and formation of [O.sub.3] by [sup.1][O.sub.2]-mediated deoxidation of intermediates 23 and 26 [34]. The asterisk indicates that the carbonyl is in excited state.

Caption: Figure 8: Postulated conversion of linoleic acid 28 via dioxetanyl derivative 31 to major products 9-oxononanoic acid 32 and 4-hydroperoxy-2- nonenal 33 [49] or via dioxetanyl radical 38 to hydroperoxyaldehyde 33 and 8-oxooctanoic acid 39 [50]. Decomposition of the dioxetanyl derivatives affords excited carbonyls that transfer energy to [O.sub.2], thus forming [sup.1][O.sub.2]. The asterisk indicates that the carbonyl is in excited state.

Caption: Figure 9: Oxidation pathways of cholesterol 41, leading to the 7-hydroperoxide 44 during autoxidation, the 5-hydroperoxide 46 upon reaction with [sup.1][O.sub.2], and secosterol A (49) upon reaction with [O.sub.3]. Aldolization of 49 produces secosterol B (50). Hock cleavage of 46 predominantly produces secosterol 50 and minor amounts of 49. There is no evidence of formation of dioxetanyl derivatives.

Caption: Figure 10: Mechanism of formation of [sup.1][O.sub.2] and triplet carbonyls during reaction of [H.sub.2][O.sub.2] with carbonyls [51]. The asterisk indicates that the carbonyl is in excited state.

Caption: Figure 11: Proposed mechanisms of lysine- (RN[H.sub.2]-) promoted reaction of [H.sub.2][O.sub.2] with carbonyls to generate [sup.1][O.sub.2] and the formation of carbonylated lysine products (62) under such conditions.

Caption: Figure 12: Proposed mechanism for conversion of acrolein-derived hydroperoxide 63 to formyl lysine 65 and acetaldehyde. The asterisk indicates that the carbonyl is in excited state.

Caption: Figure 13: Spermine oxidase- (SMO-) catalyzed catabolism of spermine 66 to form [H.sub.2][O.sub.2], spermidine 67, and 3-aminopropanal 68, which can participate in further reactions leading to [sup.1][O.sub.2] and [O.sub.3] formation.

Caption: Figure 14: Proposed mechanism for the reaction of the 13-hydroperoxide of linoleic acid 34 with lysine (RN[H.sub.2]) to form [N.sup.[epsilon]]-(hexanoyl) lysine 74 via a dioxetane intermediate 69. The asterisk indicates that the carbonyl is in excited state.

Caption: Figure 15: Proposed pathways of formation of [sup.1][O.sub.2] and excited carbonyls during Maillard and glycoxidation reactions. The asterisk indicates that the carbonyl is in excited state.

Caption: Figure 16: Mechanism of [O.sub.3] formation by [sup.1][O.sub.2]- mediated deoxidation of a peroxyacid [34].
COPYRIGHT 2016 Hindawi Limited
No portion of this article can be reproduced without the express written permission from the copyright holder.
Copyright 2016 Gale, Cengage Learning. All rights reserved.

Article Details
Printer friendly Cite/link Email Feedback
Author:Onyango, Arnold N.
Publication:Oxidative Medicine and Cellular Longevity
Date:Jan 1, 2016
Previous Article:Short-Term Effects of Chlorpromazine on Oxidative Stress in Erythrocyte Functionality: Activation of Metabolism and Membrane Perturbation.
Next Article:Potential Role of Protein Disulfide Isomerase in Metabolic Syndrome-Derived Platelet Hyperactivity.

Terms of use | Privacy policy | Copyright © 2018 Farlex, Inc. | Feedback | For webmasters