Burkhard Poeggeler

A review of the evidence supporting melatonin's role as an antioxidant

Abstract: This survey summarizes the findings, accumulated within the last 2 years, concerning melatonins role in defending against toxic free radicals. Free radicals are chemical constituents that have an unpaired electron in their outer or‐bital and, because of this feature, are highly reactive. Inspired oxygen, which sustains life, also is harmful because up to 5% of the oxygen (O2) taken in is converted to oxygen‐free radicals. The addition of a single electron to O2 produces the superoxide anion radical (O2); C2: is catalytic‐reduced by superoxide dismutase, to hydrogen peroxide (H2O2). Although H2O2 is not itself a free radical, it can be toxic at high concentrations and, more importantly, it can be reduced to the hydroxyl radical (OH). The OH is the most toxic of the oxygen‐based radicals and it wreaks havoc within cells, particularly with macromolecules. In recent in vitro studies, melatonin was shown to be a very efficient neutralizer of the OH; indeed, in the system used to test its free radical scavenging ability it was found to be significantly more effective than the well known antioxidant, glutathione (GSH), in doing so. Likewise, melatonin has been shown to stimulate glutathione peroxidase (GSH‐Px) activity in neural tissue; GSH‐PX metabolizes reduced glutathione to its oxidized form and in doing so it converts H2O2 to H2O, thereby reducing generation of the OH by eliminating its precursor. More recent studies have shown that melatonin is also a more efficient scavenger of the peroxyl radical than is vitamin E. The peroxyl radical is generated during lipid peroxidation and propagates the chain reaction that leads to massive lipid destruction in cell membranes. In vivo studies have demonstrated that melatonin is remarkably potent in protecting against free radical damage induced by a variety of means. Thus, DNA damage resulting from either the exposure of animals to the chemical carcinogen safrole or to ionizing radiation is markedly reduced when melatonin is co‐administered. Likewise, the induction of cataracts, generally accepted as being a consequence of free radical attack on lenticular macromolecules, in newborn rats injected with a GSH‐depleting drug are prevented when the animals are given daily melatonin injections. Also, paraquat‐induced lipid peroxidation in the lungs of rats is overcome when they also receive melatonin during the exposure period. Paraquat is a highly toxic herbicide that inflicts at least part of its damage by generating free radicals. Finally, bacterial endotoxin (lipopolysaccharide or LPS)‐induced free radical damage to a variety of organs is highly significantly reduced when melatonin is also administered; LPS, like paraquat, produces at least part of its damage to cells by inducing the formation of free radicals. Physiological melatonin concentrations have also been shown to inhibit the nitric oxide (NO)‐generting enzyme, nitric oxide synthase. The reduction of NO‐ production would contribute to melatonins antioxidant action since NO‐ can generate the peroxynitrite anion, which can degrade into the OH. Thus, melatonin seems to have multiple ways either to reduce free radical generation or, once produced, to neutralize them. Melatonin accomplishes these actions without membrane receptors, indicating that the indole has important metabolic functions in every cell in the organism, not only those that obviously contain membrane receptors for this molecule.

MELATONIN: NATURE'S MOST VERSATILE BIOLOGICAL SIGNAL

Melatonin is a ubiquitous molecule and widely distributed in nature, with functional activity occurring in unicellular organisms, plants, fungi and animals. In most vertebrates, including humans, melatonin is synthesized primarily in the pineal gland and is regulated by the environmental light/dark cycle via the suprachiasmatic nucleus. Pinealocytes function as ‘neuroendocrine transducers’ to secrete melatonin during the dark phase of the light/dark cycle and, consequently, melatonin is often called the ‘hormone of darkness’. Melatonin is principally secreted at night and is centrally involved in sleep regulation, as well as in a number of other cyclical bodily activities. Melatonin is exclusively involved in signaling the ‘time of day’ and ‘time of year’ (hence considered to help both clock and calendar functions) to all tissues and is thus considered to be the bodys chronological pacemaker or ‘Zeitgeber’. Synthesis of melatonin also occurs in other areas of the body, including the retina, the gastrointestinal tract, skin, bone marrow and in lymphocytes, from which it may influence other physiological functions through paracrine signaling. Melatonin has also been extracted from the seeds and leaves of a number of plants and its concentration in some of this material is several orders of magnitude higher than its night‐time plasma value in humans. Melatonin participates in diverse physiological functions. In addition to its timekeeping functions, melatonin is an effective antioxidant which scavenges free radicals and up‐regulates several antioxidant enzymes. It also has a strong antiapoptotic signaling function, an effect which it exerts even during ischemia. Melatonins cytoprotective properties have practical implications in the treatment of neurodegenerative diseases. Melatonin also has immune‐enhancing and oncostatic properties. Its ‘chronobiotic’ properties have been shown to have value in treating various circadian rhythm sleep disorders, such as jet lag or shift‐work sleep disorder. Melatonin acting as an ‘internal sleep facilitator’ promotes sleep, and melatonins sleep‐facilitating properties have been found to be useful for treating insomnia symptoms in elderly and depressive patients. A recently introduced melatonin analog, agomelatine, is also efficient for the treatment of major depressive disorder and bipolar affective disorder. Melatonins role as a ‘photoperiodic molecule’ in seasonal reproduction has been established in photoperiodic species, although its regulatory influence in humans remains under investigation. Taken together, this evidence implicates melatonin in a broad range of effects with a significant regulatory influence over many of the bodys physiological functions.

Melatonin stimulates brain glutathione peroxidase activity

Exogenously administered melatonin causes a 2-fold rise in glutathione peroxidase activity within 30 min in the brain of the rat. Furthermore, brain glutathione peroxidase activity is higher at night than during the day and is correlated with high night-time tissue melatonin levels. Glutathione peroxidase is thought to be the principal enzyme eliminating peroxides in the brain. This antioxidative enzyme reduces the formation of hydroxyl radicals formed via iron-catalyzed Fenton-type reactions from hydrogen peroxide by reducing this oxidant to water. Since the hydroxyl radical is the most noxious oxygen radical known, induction of brain glutathione peroxidase might be an important mechanism by which melatonin exerts its potent neuroprotective effects.

Melatonin, hydroxyl radical‐mediated oxidative damage, and aging: A hypothesis

Abstract: Melatonin is a very potent and efficient endogenous radical scavenger. The pineal indolamine reacts with the highly toxic hydroxyl radical and provides on‐site protection against oxidative damage to biomolecules within every cellular compartment. Melatonin acts as a primary non‐enzymatic antioxidative defense against the devastating actions of the extremely reactive hydroxyl radical. Melatonin and structurally related tryptophan metabolites are evolutionary conservative molecules principally involved in the prevention of oxidative stress in organisms as different as algae and rats. The rate of aging and the time of onset of age‐related diseases in rodents can be retarded by the administration of melatonin or treatments that preserve the endogenous rhythm of melatonin formation. The release of excitatory amino acids such as glutamate enhances endogenous hydroxyl radical formation. The activation of central excitatory amino acid receptors suppress melatonin synthesis and is therefore accompanied by a reduced detoxification rate of hydroxyl radicals. Aged animals and humans are melatonin‐deficient and more sensitive to oxidative stress. Experiments investigating the effects of endogenous excitatory amino acid antagonists and stimulants of melatonin biosynthesis such as magnesium may finally lead to novel therapeutic approaches for the prevention of degeneration and dysdifferentiation associated with diseases related to premature aging.

The significance of the metabolism of the neurohormone melatonin: antioxidative protection and formation of bioactive substances.

Recent findings suggest that the ability of melatonin to enter all body tissues and to be metabolized, enzymatically or nonenzymatically, in any of them results in a spectrum of effects, which exceed substantially those transduced by membrane receptors. These actions comprise the formation of various bioactive compounds such as N-acetylserotonin, 5-methoxytryptamine, N,N-dimethyl-5-methoxytryptamine, 5-methoxytryptophol, cyclic 2-hydroxymelatonin, pinoline, and 5-methoxylated kynuramines. Apart from enzymatic metabolism, nonenzymatic reactions with free radicals, in particular the superoxide anion and the hydroxyl radical, represent a new and significant aspect of melatonins biological role. Melatonin represents the most potent physiological scavenger of hydroxyl radicals found to date, and recent findings suggest an essential role of this indoleamine for protection from hydroxyl radical-induced carcinogenesis and neurodegeneration.

Melatonin as a free radical scavenger: implications for aging and age-related diseases.

Melatonin, ~-acetyl-5-methoxytryptamine, is phylogenetically a very old molecule. Melatonin is known to exist in the dinoflagellate Gonyaulax polyedra, and it is perhaps produced by most if not all organisms in the animal kingdom. The conservation of this molecule during evolution may relate to its free radical scavenging ability.2 This recently discovered function of melatonin establishes a role for this indole in every organism, and indeed in every cell, from the most primitive members of the animal kingdom up to and including the was shown to be a hormone produced in and secreted from the mammalian pineal gland. In vertebrates melatonins production in the pineal exhibits a circadian rhythm with highest blood levels of the hormone being present during the night.6 The circadian rhythm in melatonin production provides important time-of-day and time-of-year information and, as a result, this hormonal cycle drives other 24-hour rhythms8 as well as seasonal cycles of reproduction, at least in photoperiodic mammal^.^ Although for years melatonin was thought to be exclusively produced in the pineal gland and to function only as a hormone which acted via membrane receptors located at a few discrete sites in mammals,O~ it was subsequently learned that in perhaps all vertebrates melatonin is found in a number of other cells and organs. l 2 , l 3 Its likely production outside the pineal gland was strongly reinforced by the observation that melatonin is even produced in unicellular organisms such as the dinoflagellate; since they obviously lack a pineal gland, or for that matter any other organ, it is clear that individual pineal-unrelated cells can synthesize melatonin. The fact that melatonin is highly lipophilic made some investigators question Melatonin, when discovered slightly over 30 years

Evaluation of the antioxidant activity of melatonin in vitro

Melatonin is being increasingly promoted as a treatment for jet lag and insomnia and has been suggested to act as an antioxidant in vivo. The antioxidant and potential pro-oxidant activities of melatonin were investigated in vitro. Melatonin was able to scavenge hypochlorous acid (HOCl) at a rate sufficient to protect catalase against inactivation by this molecule. Melatonin could also prevent the oxidation of 5-thio-2-nitrobenzoic acid by HOCl. Melatonin decreased the peroxidation of ox-brain phospholipids with a calculated IC50 of (210 +/- 2.3) microM. In contrast, serotonin which also scavenged HOCl, was much more effective in decreasing phospholipid peroxidation (IC50 15 +/- 5 microM). Both compounds reacted with trichloromethylperoxyl radical (CCl3O2) with rate constants of (2.7 +/- 0.2) x 10(8) and (1.2 +/- 0.1) x 10(8)M-1 s- respectively. Melatonin did not scavenge superoxide radical and weakly protected DNA against damage by the ferric bleomycin system. By contrast serotonin was weakly pro-oxidant in the ferric-bleomycin system and strongly pro-oxidant in the Fe(3+)-EDTA/H2O-deoxyribose system. Solubility restrictions precluded examination of melatonin in this system. Our data show that melatonin exerts only limited direct antioxidant activities.

Melatonin—A Highly Potent Endogenous Radical Scavenger and Electron Donor: New Aspects of the Oxidation Chemistry of this Indole Accessed in vitro

Endogenous indolamines derived from the essential aromatic amino acid tryptophan can act as substrates and mediators of electron transfer mechanisms and radical reactions. The indoleamine melatonin is the most powerful and effective hydroxyl radical scavenger detected to date, which, due to its lipophilic nature, provides on-site protection against oxidative damage to biomolecules within every cell compartment.,*

The pineal hormone melatonin inhibits DNA-adduct formation induced by the chemical carcinogen safrole in vivo

Melatonin inhibits DNA-adduct formation induced by the chemical carcinogen safrole in a dose-dependent manner. Total DNA-adduct formation after in vivo administration of 300 mg/kg safrole measured by 32P-postlabeling analysis of carcinogen-modified DNA in rat liver was 36,751 +/- 2290 counts/min/10 micrograms DNA. Coadministration of 300 mg/kg safrole with either 0.2 mg/kg (low dose) or 0.4 mg/kg (high dose) melatonin reduced DNA-adduct formation induced by safrole to 22,182 +/- 987 counts/min/10 micrograms DNA and 462 +/- 283 counts/min/10 micrograms DNA, respectively. Circulating melatonin concentrations at the termination of the study in safrole, low melatonin and high melatonin groups were 50 +/- 8, 3140 +/- 430 and 10,040 +/- 2610 pg/ml serum, respectively. The results suggest that melatonin protects against safrole associated DNA damage.

Non-vertebrate melatonin.

Abstract: Melatonin has been detected in bacteria, eukaryotic unicells, macroalgae, plants, fungi and various taxa of invertebrates. Although precise determinations are missing in many of these organisms and the roles of melatonin are still unknown, investigations in some species allow more detailed conclusions. Non‐vertebrate melatonin is not necessarily circadian, and if so, not always peaking at night, although nocturnal maxima are frequently found. In the cases under study, the major biosynthetic pathway is identical with that of vertebrates. Mimicking of photoperiodic responses and concentration changes upon temperature decreases have been studied in more detail only in dinoflagellates. In plants, an involvement in photoperiodism seems conceivable but requires further support. No stimulation of flowering has been demonstrated to date. A participation in antioxidative protection might be possible in many aerobic non‐vertebrates, although evidence for a contribution at physiological levels is mostly missing. Protection from stress by oxidotoxins or/and extensions of lifespan have been shown in very different organisms, such as the dinoflagellate Lingulodinium, the ciliate Paramecium, the rotifer Philodina and Drosophila. Melatonin can be taken up from the food, findings with possible implications in ecophysiology as well as for human nutrition and, with regard to high levels in medicinal plants, also in pharmacology.