Delio Tolivia

Neurohormone melatonin prevents cell damage: effect on gene expression for antioxidant enzymes.

It is well known that porphyrins cause a toxic light‐mediated effect due to their capability to generate free radicals. Several reports have proved that melatonin is a potent free radical scavenger. The aim of this work has been to study the ability of melatonin to prevent the cell damage caused by porphyrins in the Harderian gland of female Syrian hamsters. Cell injury was evaluated estimating the percentage of damaged cells found in the gland and analyzing the degree of this damage at ultrastructural level. To explain the mechanism by which this hormone could prevent the cell damage caused by porphyrins, its capability to both decrease porphyrin synthesis and increase the mRNA levels for antioxidant enzymes was evaluated. Our results demonstrate that melatonin administration decreases the percentage of damaged cells, porphyrin synthesis, and aminolevulinate synthase (ALA‐S) mRNA levels and increases the mRNA levels for manganese superoxide‐dismutase and copper‐zinc superoxide dismutase. When observed under an electron microscope, the lesions in the clear cells of the treated females were much less severe than in the corresponding cells of the control animals. Melatonin exerts a cytoprotective effect by inhibiting the ALA‐S gene expression (and so porphyrin synthesis) and by raising the mRNA levels for several antioxidant enzymes.—Antolín, I., Rodríguez, C., Sáinz, R. M., Mayo, J. C., Uría, H., Kotler, M. L., Rodríguez‐Col‐ unga, M. J., Tolivia, D., Menéndez‐Peláez, A. Neurohormone melatonin prevents cell damage: effect on gene expression for antioxidant enzymes. FASEB J. 10, 882‐890 (1996)

Favorable effects of a prolonged treatment with melatonin on the level of oxidative damage and neurodegeneration in senescence-accelerated mice

Abstract:  Senescence‐accelerated mice (SAMP8) and senescence‐accelerated resistant mice (SAMR1) were studied at 5 and 10 months of age, respectively. In the animals, neurodegenerative processes and how they were influenced by melatonin were examined. Melatonin (10 mg/kg) or vehicle (ethanol at 0.066%) treatments were administrated from the age of 1 to 9 months in the drinking water. Differences in the neurodegenerative markers examined were found between the two strains with a more damaged protein, phosphorylated Tau at Ser392, increased neurofibrillary tangles (NT) and higher α‐synuclein expression in SAMP8 versus SAMR1 mice overall, when the mice were 10 months of age. Changes in density of receptors and oxidative stress‐related signaling with age were found in the brains of SAM strains at 10 months as shown by a marked decrease in the level of MT‐1 melatonin receptor and retinoic acid receptor‐related orphan receptor (ROR)‐α1. This diminution was earlier and more pronounced in SAMP8 mice. Likewise, the levels of nuclear factor‐kappa B (NF‐kB) transcriptional factor were higher in SAMP8 mice compared with SAMR1 mice regardless of age confirming the direct role of oxidative stress in the aging process. Treatment with melatonin in SAMP8 and SAMR1 mice reduced the neurodegenerative changes with an increase of ROR‐α1 levels without an apparent influence in the levels of MT‐1 receptor. However, different melatonin effects on NF‐kB signaling were observed suggesting that NF‐kB could trigger inflammatory processes in a different way, being SAM strain‐dependent and associated with age‐related oxidative stress levels. The effectiveness of melatonin in improving age‐related neural impairments is corroborated.

Coexpression of MT1 and RORα1 melatonin receptors in the Syrian hamster Harderian gland

Abstract:  Melatonin acts through several specific receptors, including membrane receptors (MT1 and MT2) and members of the RZR/ROR nuclear receptors family, which have been identified in a large variety of mammalian and nonmammalian cells types. Both membrane and nuclear melatonin receptors have been partially characterized in Harderian gland of the Syrian hamster. Nevertheless, the identities of these receptors were unknown until this study, where the coexistence of MT1 and RORα1 in this gland was determined by nested RT‐PCR followed by amplicon sequencing and Western‐blot. Furthermore, the cellular localization of both receptors was determined by immunohistochemistry. Thus, MT1 receptor was localized exclusively at the basal side of the cell acini, supporting the hypothesis that this receptor is activated by the pineal‐synthesized melatonin. On the contrary, although a RORα1‐immunoreactivity was observed in nuclei of epithelial cells of both sexes, an extranuclear specific staining, which was more frequently among those cells of males, was also seen. The implication of this possible nuclear exclusion of RORα1 on the role of this indoleamine against oxidative stress is discussed.

Melatonin alters cell death processes in response to age‐related oxidative stress in the brain of senescence‐accelerated mice

Abstract:  We studied the effect of age and melatonin on cell death processes in brain aging. Senescence‐accelerated prone mice 8 (SAMP8) and senescence‐accelerated resistant mice (SAMR1) at 5 and 10 months of age were used as models of the study. Melatonin (10 mg/kg) or its vehicle (ethanol at 0.066%) was administered in the drinking water from 1 to 9 months of age. Neurodegeneration, previously shown in the aged brain of SAMP8 and SAMR1 at 10 months of age, may be due to a drop in age‐related proteolytic activities (cathepsin D, calpains, and caspase‐3). Likewise, lack of apoptotic and macroautophagic processes were found, without apparent modification by melatonin. However, the caspase‐independent cell death, owing to high p53 and apoptosis‐inducing factor (AIF) levels, might be an alternative pathway of cell death in the aged brain. The main effects of melatonin treatment were observed in the aged SAMR1 mice; in this strain we observed a marked increase in antioxidant activity (catalase and superoxide dismutase). Likewise, a key antioxidant role of apoptosis‐related proteins, Bcl‐2 and AIF, was suggested in the aged brain of SAM mice, which was clearly influenced by melatonin. Moreover, the age‐related increase of lysosomal activity of cathepsin B and a lysosomal membrane‐associated protein 2 supports the possibility of the maintenance of lysosomal viability in addition to age‐related impairments of the proteolytic or macroautophagic activities. The effectiveness of melatonin against the oxidative stress‐related impairments and apoptosis during the aging process is, once more, corroborated in this article.

Physiological oxidative stress model: Syrian hamster Harderian gland—sex differences in antioxidant enzymes

The Syrian hamster Harderian gland, a juxtaorbital organ exhibiting marked gender-associated differences in contents of porphyrins and melatonin, was used as a model system for comparing strong (in females) and moderate (in males) physiological oxidative stress. Histological differences showing much higher cell damage in females were studied in conjunction with lipid peroxidation and activities of superoxide dismutase, catalase, glutathione peroxidase, and glutathione reductase. Lipid peroxidation and enzyme activities were measured throughout the circadian cycle, revealing the importance of dynamical processes in oxidative stress. Especially in lipid peroxidation and in catalase, short-lasting rises exhibited strongest gender differences. Peaks of lipid peroxidation were about three times higher in females, compared to males. Catalase peaks of females exceeded those in males by several hundred-fold. Average levels of superoxide dismutase and glutathione peroxidase were about three or two times higher in females, respectively. A clear-cut diurnally peaking rhythm was found in glutathione peroxidase of females, which was not apparent in males. Glutathione reductase showed differences in time patterns, but less in average activities. The time courses of lipid peroxidation and of protective enzymes are not explained by circulating melatonin, whereas melatonin formed in the Harderian gland should contribute to differences in average levels. Neither damage nor antioxidative defense simply reflect the illumination cycle and are, therefore, not only a consequence of photoreactions.

Melatonin neutralizes neurotoxicity induced by quinolinic acid in brain tissue culture.

Abstract:  Quinolinic acid is a well‐known excitotoxin that induces oxidative stress and damage. In the present study, oxidative damage to biomolecules was followed by measuring lipid peroxidation and protein carbonyl formation in rat brain tissue culture over a period of 24 hr of exposure to this prooxidant agent at a concentration of 0.5 mm. Quinolinic acid enhanced lipid peroxidation in an early stage of tissue culture, and protein carbonyl at a later stage. These data confirm and extend previous studies demonstrating that quinolinic acid can induce significant oxidative damage. Melatonin, an antioxidant and neuroprotective agent with multiple actions as a radical scavenger and signaling molecule, completely prevented these prooxidant actions of quinolinic acid at a concentration of 1 mm. Morphological lesions and neurotoxicity induced by quinolinic acid were evaluated by light microscopy. Quinolinic acid produced extensive apoptosis/necrosis which was significantly attenuated by melatonin. Cotreatment with melatonin exerted a profound protective effect antagonizing the neurotoxicity induced by quinolinic acid. Glutathione reductase and catalase activities were increased by quinolinic acid and these effects were antagonized by melatonin. Furthermore, melatonin induced superoxide dismutase activity. Quinolinic acid and melatonin acted independently and by different mechanisms in modulating antioxidant enzyme activities. Our findings using quinolinic acid and melatonin clearly demonstrate that such changes should always be seen in the context of oxidative neurotoxicity and antioxidant neuroprotection.

Effects of δ-aminolevulinic acid and melatonin in the harderian gland of female syrian hamsters

Abstract Effects of δ-aminolevulinic acid (ALA) and melatonin were investigated in the female Syrian hamster Harderian gland. This is an organ physiologically exposed to strong oxidative stress due to the highest porphyrinogenic rates known in nature. Enzyme activities of porphyrin biosynthesis and of antioxidative protection, oxidative protein modification, and histological integrity were studied. In the porphyrin biosynthetic pathway, ALA and melatonin acted synergistically by downregulating ALA synthase (ALA-S) and stimulating product formation from ALA; the combination of ALA and melatonin suppressed ALA-S activity, down to about 1% of that in controls. While ALA effects on porphyrinogenesis can be interpreted in terms of homeostasis, melatonin’s actions may be seen in relation to seasonality and/or reduction of oxidative stress. Among antioxidant enzymes, superoxide dismutase (SOD) and glutathione reductase (GR) activities were diminished by ALA, presumably due to the vulnerability of their active centers to free radicals, whereas melatonin moderately increased SOD. Both ALA and melatonin strongly stimulated catalase (CAT), thereby counteracting the oxidative stress induced by ALA and its metabolites. Nevertheless, exogenous ALA caused a strong net rise in protein carbonyl and considerable damage of tissue. When given together with ALA, melatonin antagonized these effects and largely protected the integrity of glandular structures.

Effects of continuous light exposure on antioxidant enzymes, porphyric enzymes and cellular damage in the Harderian gland of the Syrian hamster

Abstract: The Syrian hamster Harderian gland (HG), an organ present in the male two secretory cell types (type‐I and type‐II cells), is physiologically exposed to high oxidative stress because of high concentrations of porphyrins and their precursor, 5‐aminolevulinic acid. Because of its juxtaorbital location, the HG is accessible to light, and subject to phototoxic effects of these substances. After having previously demonstrated circadian rhythms in antioxidant enzymes, porphyric enzymes and oxidative damage of proteins and lipids, as well as influences of melatonin on these parameters, we have now studied the effects of continuous light (LL), which suppresses melatonin secretion by the pineal gland. Measurements were performed in two different circadian phases, in order to detect the presence or absence of day/night differences. In LL, no differences between circadian phases of subjective day and subjective night were demonstrable for 5‐aminolevulinate synthase, 5‐aminolevulinate dehydratase, porphobilinogen deaminase, or superoxide dismutase; temporal differences in glutathione reductase and catalase were markedly diminished, whereas all these parameters showed marked day/night differences in the rats exposed to a light/dark cycle of 14:10. In LL, oxidative damage to lipids was minimally effected, while protein damage was enhanced. LL also caused a reduction in the percentage of type‐II cells. Therefore, cell differentiation in the HG does not seem to be controlled only by the androgen, but, unexpectedly, also by melatonin.

Polychromatic staining of epoxy semithin sections: a new and simple method.

A simple, rapid method is described for the polychromatic coloration of semithin sections, which is applicable to material routinely processed for transmission electron microscopy. Material fixed with a glutaraldehyde-paraformaldehyde mixture and postfixed in osmium tetroxide with or without potassium ferrocyanide and embedded in different types of resin (Durkupan-ACM, Spurr resin, Taab resin) can be used. Constant and homogenous results are obtained with this technique, the staining procedure being achieved at room temperature in no more than 10 min. Sections of 0.5–1 μm in thickness are oxidised and bleached. After washing, sections are stained in two steps with carbol methylene blue/carbol gentian violet solution and pararosaniline solution. Using the method described in this paper, a polychromatic coloration of the different cells and tissues was obtained (epithelial cells in various shades of blue-violet, connective tissue and elastic laminae of blood vessels in pink or red, etc.). This procedure provides greater contrast between cytoplasm and nuclei, and among the different types of cells and tissues than is seen with toluidine blue, which is very useful for observation and photography of semithin sections. Polychromatic methods found in the literature are normally complex and require a lengthy staining time or cannot be applied on material routinely processed for transmission electron microscopy. Our method is simple, rapid and can be used on any type of material routinely processed for transmission electron microscopy and embedded in epoxy resins.

Melatonin protects against δ-aminolevulinic acid-induced oxidative damage in male Syrian hamster Harderian glands

Effects of the prooxidant delta-aminolevulinic acid (ALA) and the antioxidant melatonin (MEL) were investigated in the male Syrian hamster Harderian gland (HG). Rodent Harderian glands are highly porphyrogenic organs, which may be used as model systems for studying damage by delta-aminolevulinic acid and its metabolites, as occurring in porphyrias. Chronic administration of delta-aminolevulinic acid (2 weeks) markedly decreased activities of the porphyrogenic enzymes delta-aminolevulinate synthase (ALA-S) and delta-aminolevulinate dehydratase (ALA-D) and of the antioxidant enzymes superoxide dismutase (SOD), glutathione reductase (GR) and catalase (CAT), whereas porphobilinogen deaminase (PBG-D) remained unaffected. This treatment led to increased lipid peroxidation (LPO) and oxidatively modified protein (protein carbonyl) as well as to morphologically apparent tissue damage. Melatonin also caused decreases in delta-aminolevulinate synthase, delta-aminolevulinate dehydratase, superoxide dismutase, glutathione reductase and catalase. Despite lower activities of antioxidant enzymes, lipid peroxidation and protein carbonyl were markedly diminished. The combination of delta-aminolevulinic acid and melatonin led to approximately normal levels of delta-aminolevulinate dehydratase, glutathione reductase, catalase and protein carbonyl, and to rises in superoxide dismutase and porphobilinogen deaminase activities; lipid peroxidation remained even lower than in controls and the appearance of the tissue revealed a protective influence of melatonin. These results suggest that melatonin may have profound effects on the oxidant status of the Harderian gland.