Genaro Gabriel Ortiz

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-induced increased activity of the respiratory chain complexes I and IV can prevent mitochondrial damage induced by ruthenium red in vivo

Melatonin displays antioxidant and free radical scavenger properties. Due to its ability with which it enters cells, these protective effects are manifested in all subcellular compartments. Recent studies suggest a role for melatonin in mitochondrial metabolism. To study the effects of melatonin on this organelle we used ruthenium red to induce mitochondrial damage and oxidative stress. The results show that melatonin (10 mg/kg i.p.) can increase the activity of the mitochondrial respiratory complexes I and IV after its administration in vivo in a time‐dependent manner; these changes correlate well with the half‐life of the indole in plasma. Melatonin administration also prevented the decrease in the activity of complexes I and IV due to ruthenium red (60 μg/kg i.p.) administration. At this dose, ruthenium red did not induce lipid peroxidation but it significantly reduced the activity of the antioxidative enzyme glutathione peroxidase, an effect also counteracted by melatonin. These results suggest that melatonin modulates mitochondrial respiratory activity, an effect that may account for some of the protective properties of the indoleamine. The mitochondria‐modulating role of melatonin may be of physiological significance since it seems that the indoleamine is concentrated into normal mitochondria. The data also support a pharmacological use of melatonin in drug‐induced mitochondrial damage in vivo.

Rhythms of glutathione peroxidase and glutathione reductase in brain of chick and their inhibition by light

Melatonin was recently shown to be a component of the antioxidative defense system of organisms due to its free radical scavenging and antioxidant activities. Pharmacologically, melatonin stimulates the activity of the peroxide detoxifying enzyme glutathione peroxidase in rat brain and in several tissues of chicks. In this report, we studied the endogenous rhythm of two antioxidant enzymes, glutathione peroxidase and glutathione reductase, in five regions (hippocampus, hypothalamus, striatum, cortex and cerebellum) of chick brain and correlated them with physiological blood melatonin concentrations. Glutathione peroxidase exhibited a marked 24 h rhythm with peak activity in each brain region which had acrophases about 8 h after lights off and about 4 h after the serum melatonin peak was detected. Glutathione reductase activity exhibited similar robust rhythms with the peaks occurring roughly 2 h after those of glutathione peroxidase. We suggest that neural glutathione peroxidase increases due to the rise of nocturnal melatonin levels while glutathione reductase activity rises slightly later possibly due to an increase of its substrate, oxidized glutathione. The exposure of chicks to constant light for 6 days eliminated the melatonin rhythm as well as the peaks in both glutathione peroxidase and glutathione reductase activities. These findings suggest that the melatonin rhythm may be related to the nighttime increases in the enzyme activities, although other explanations cannot be excluded.

Melatonin is protective against MPTP-induced striatal and hippocampal lesions

The in vivo effect of melatonin on MPTP-induced neurotoxicity in mouse brain was studied. Melatonin (10 mg/kg) or saline was administered intraperitoneally (i.p.) to mice 30 min prior to a s.c. injection of MPTP (20 mg/kg). After MPTP treatment, the animals received melatonin or saline injections every hour for three hours. Mice were killed 4 hours after the MPTP injection. Regionally-specific increases in lipid peroxidation were observed in corpus striatum and hippocampus (71% and 58%, respectively), but not in cerebral cortex, cerebellum or midbrain. Treatment with melatonin completely reversed the rises in lipid peroxidation products. MPTP-treated mice showed a significant decrease in the striatal tyrosine hydroxylase immunoreactive nerve terminals, an effect that was also prevented by melatonin. These data show that melatonin is neuroprotective in this MPTP model of Parkinsons disease and suggest that melatonin, an endogenous antioxidant and nontoxic compound, may have potential beneficial effects for this neurodegenerative disorder.

Lipopolysaccharide-induced hepatotoxicity is inhibited by the antioxidant melatonin

Oxidative damage to the liver of lipopolysaccharide-treated rats was evaluated using four parameters: level of lipid peroxidation, changes in total GSH and GSSG concentrations and hepatic morphology. Bacterial lipopolysaccharide (10 mg/kg b.w.) was injected i.p. either at 6, 16 or 24 h before animals were killed. Lipopolysaccharide increased lipid peroxidation most dramatically when it is injected 6 h before killing. Hepatic total GSH increased after lipopolysaccharide in a time-dependent manner. The highest level of GSSG and largest GSSG/total GSH ratio were also observed in the group of animals injected with lipopolysaccharide 6 h before tissue collection. In a second study, lipopolysaccharide was injected 6 h before the animals were killed, with or without 1 mg/kg b.w. melatonin. Melatonin totally abolished lipopolysaccharide-induced increase in lipid peroxidation, exaggerated the rise in total GSH and reversed the increase in GSSG concentration. The liver showed obvious histological degenerative changes after lipopolysaccharide, effects that were counteracted by melatonin administration. The protection conferred by melatonin is presumably due to its antioxidant activity.

Role of pinoline and melatonin in stabilizing hepatic microsomal membranes against oxidative stress.

We investigated the influence of pinoline (0.01–1.5 mM) on microsomal membrane fluiditybefore and after rigidity was induced by oxidative stress. In addition, we tested the effect ofpinoline in the presence of 1 mM melatonin. The fluidity in rat hepatic microsomes wasmonitored using fluorescence spectroscopy and it was compared to the inhibition ofmalonaldehyde (MDA) plus 4-hydroxyalkenals (4-HDA) production as a reflection of lipid peroxidation.Below 0.6 mM, pinoline inhibited membrane rigidity in a manner parallel to its inhibitoryeffect on MDA + 4−HDA formation. At concentrations between 1–1.5 mM, pinoline wasless effective in stabilizing microsomal membranes than was predicted from its inhibition oflipid peroxidation. The addition of 1 mM melatonin enhanced the membrane-stabilizing activityof pinoline (0.01–0.6 mM). This cooperative effect was not observed for concentrations ofpinoline between 1–1.5 mM. When pinoline was tested without induced oxidative damage,1–1.5 mM pinoline maintained membrane fluidity at the same level as that recorded afterinduced lipid peroxidation. The results suggest that pinoline may be another pineal moleculethat prevents membrane rigidity mediated by lipid peroxidation and this ability is enhancedby melatonin.

Melatonin prevents increases in neural nitric oxide and cyclic GMP production after transient brain ischemia and reperfusion in the Mongolian gerbil (Meriones Unguiculatus)

ABSTRACT: While nitric oxide (NO) has been implicated as a mediator of glutamate excitotoxicity after cerebral ischemia/reperfusion, melatonin has been reported to inhibit brain NO production by suppressing nitric oxide synthase. The purpose of the present studies was to determine the effect of exogenous melatonin administration on NO‐induced changes during brain ischemia/reperfusion. Indicators of cerebral cortical and cerebellar NO production [nitrite/nitrate levels and cyclic guanosine monophosphate(cGMP)] were used to estimate neural changes after transient bilateral carotid artery ligation followed by reperfusion in adult Mongolian gerbils (Meriones unguiculatus). Results show for the first time that melatonin prevents the increases in NO and cGMP production after transient ischemia/reperfusion in frontal cerebral cortex and cerebellum of Mongolian gerbils. The inhibitory effect of melatonin on NO production and its ability to scavenge free radicals and the peroxynitrite anion may be responsible for the protective effect of melatonin on neuronal structures during transient ischemia followed by reperfusion.

Orally administered melatonin reduces oxidative stress and proinflammatory cytokines induced by amyloid‐β peptide in rat brain: a comparative, in vivo study versus vitamin C and E

Abstract: To determine the efficacy of antioxidants in reducing amyloid‐β‐induced oxidative stress, and the neuroinflammatory response in the central nervous system (CNS) in vivo, three injections of fibrillar amyloid‐β (fAβ) or artificial cerebrospinal fluid (aCSF) into the CA1 region of the hippocampus of the rat were made. Concomitantly, one of the three free radical scavengers, i.e. melatonin, vitamin C, or vitamin E was also administered. Besides being a free radical scavenger, melatonin also has immunomodulatory functions. Antioxidant treatment reduced significantly oxidative stress and pro‐inflammatory cytokines. There were no marked differences between melatonin, vitamin C, and vitamin E regarding their capacity to reduce nitrites and lipoperoxides. However, melatonin exhibited a superior capacity to reduce the pro‐inflammatory response induced by fAβ.

Melatonin and vitamin E limit nitric oxide-induced lipid peroxidation in rat brain homogenates.

We have investigated the level of lipid peroxidation (LPO) in rat brain homogenates in the presence of nitric oxide (NO) which was released by the addition of sodium nitroprusside (SNP) and compared it with that induced by H2O2. We also examined the effect of melatonin and vitamin E on the NO-induced LPO. The concentration of malonaldehyde (MDA) plus 4-hydroxyalkenals (4-HDA) was used as an index of LPO. While both H2O2 and SNP increased MDA + 4-HDA production in brain homogenates in a concentration-dependent manner, SNP was more potent than H2O2 at all concentrations tested. Both melatonin or vitamin E reduced NO-induced LPO in a dose-dependent manner in concentrations ranging from 10 microM to 10 mM. Under the in vitro conditions of this experiment, vitamin E was more efficient than melatonin in limiting NO-induced LPO in rat brain homogenates.

Melatonin reduces H2O2-induced lipid peroxidation in homogenates of different rat brain regions.

Abstract: The ability of melatonin to modify H2O2‐induced lipid peroxidation in brain homogenates was determined. The concentrations of brain malonaldehyde (MDA) and 4‐hydroxyalkenals (4‐HDA) were assayed as an index of induced membrane oxidative damage. Homogenates from five different regions of the brain (cerebral cortex, cerebellum, hippocampus, hypothalamus, and corpus striatum) derived from two different strains of rats, Sprague‐Dawley and Wistar, were incubated with either H2O2 (5 mM) alone or H2O2 together with melatonin at increasing concentrations ranging from 0.1 to 4 mM. The basal level of lipid peroxidation was strain‐dependent and about 100% higher in homogenates from the brain of Wistar rats than those measured in Sprague‐Dawley rats. MDA + 4‐HDA levels increased after H2O2 treatment in homogenates obtained from each region of the brain in both rat strains but the sensitivity of the homogenates from Sprague‐Dawley rats was greater than that for the homogenates from Wistar rats (increases after H2O2from 45 to 165% compared 20 to 40% for Sprague‐Dawley and Wistar rats, respectively). Melatonin co‐treatment reduced H202‐induced lipid peroxidation in brain homogenates in a concentration‐dependent manner; the degree of protection against lipid peroxidation was similar in all brain regions.