Ana I. Esquifino

Role of melatonin in neurodegenerative diseases

The pineal product melatonin has remarkable antioxidant properties. It scavenges hydroxyl, carbonate and various organic radicals, peroxynitrite and other reactive nitrogen species. Melatonyl radicals formed by scavenging combine with and, thereby, detoxify superoxide anions in processes terminating the radical reaction chains. Melatonin also enhances the antioxidant potential of the cell by stimulating the synthesis of antioxidant enzymes like superoxide dismutase, glutathione peroxidase and glutathione reductase, and by augmenting glutathione levels. The decline in melatonin production in aged individuals has been suggested as one of the primary contributing factors for the development of age-associated neurodegenerative diseases,e.g., Alzheimer’s disease. Melatonin has been shown to be effective in arresting neurodegenerative phenomena seen in experimental models of Alzheimer’s disease, Parkinsonism and ischemic stroke. Melatonin preserves mitochondrial homeostasis, reduces free radical generation, e.g., by enhancing mitochondrial glutathione levels, and safeguards proton potential and ATP synthesis by stimulating complex I and IV activities. Therapeutic trials with melatonin have been effective in slowing the progression of Alzheimer’s disease but not of Parkinson’s disease. Melatonin’s efficacy in combating free radical damage in the brain suggests that it may be a valuable therapeutic agent in the treatment of cerebral edema after traumatic brain injury.

The role of melatonin in immuno-enhancement : potential application in cancer

Melatonin, a neurohormone produced mainly by the pineal gland, is a modulator of haemopoiesis and of immune cell production and function, both in vivo and in vitro. Physiologically, melatonin is associated with T‐helper 1 (Th1) cytokines, and its administration favours Th1 priming. In both normal and leukaemic mice, melatonin administration results in quantitative and functional enhancement of natural killer (NK) cells, whose role is to mediate defenses against virus‐infected and cancer cells. Melatonin appears to regulate cell dynamics, including the proliferative and maturational stages of virtually all haemopoietic and immune cells lineages involved in host defense – not only NK cells but also T and B lymphocytes, granulocytes and monocytes – in both bone marrow and tissues. In particular, melatonin is a powerful antiapoptotic signal promoting the survival of normal granulocytes and B lymphocytes. In mice bearing mid‐stage leukaemia, daily administration of melatonin results in a survival index of 30–40% vs. 0% in untreated mice. Thus, melatonin seems to have a fundamental role as a system regulator in haemopoiesis and immuno‐enhancement, appears to be closely involved in several fundamental aspects of host defense and has the potential to be useful as an adjuvant tumour immunotherapeutic agent.

Melatonin effect on plasma adiponectin, leptin, insulin, glucose, triglycerides and cholesterol in normal and high-fat fed rats.

Abstract:  Melatonin effect on body weight progression, mean levels and 24‐hr pattern of circulating adiponectin, leptin, insulin, glucose, triglycerides and cholesterol were examined in rats fed a normal or a high‐fat diet. In experiment 1, rats fed a normal diet were divided into two groups: receiving melatonin (25 μg/mL drinking water) or vehicle for 9 wk. In experiment 2, animals were divided into three groups: two fed with a high‐fat diet (35% fat) and melatonin (25 μg/mL) or vehicle in drinking water for 11 wk, while a third group was given a normal diet (4% fat). At the end of experiments, groups of eight rats were killed at six different time intervals throughout a 24‐ hr period. Melatonin administration for 9 wk decreased body weight gain from the 3rd wk on without affecting food intake. A significant reduction in circulating insulin, glucose and triglyceride mean levels and disrupted daily patterns of plasma adiponectin, leptin and insulin were observed after melatonin. In high fat–fed rats, melatonin attenuated body weight increase, hyperglycemia and hyperinsulinemia, as well as the increase in mean plasma adiponectin, leptin, triglycerides and cholesterol levels. The high‐fat diet disrupted normal 24‐ hr patterns of circulating adiponectin, insulin and cholesterol, the effects on insulin and cholesterol being counteracted by melatonin. Nocturnal plasma melatonin concentration in control and obese rats receiving melatonin for 11 wk attained values 21–24‐fold greater than controls. The results indicate that melatonin counteracts some of the disrupting effects of diet‐induced obesity in rats.

Effect of a high-fat diet on 24-h pattern of circulating levels of prolactin, luteinizing hormone, testosterone, corticosterone, thyroid-stimulating hormone and glucose, and pineal melatonin content, in rats

Circadian rhythmicity is affected in obese subjects. This article analyzes the effect of a high-fat diet (35% fat) on 24-h changes circulating prolactin, luteinizing hormone (LH), testosterone, corticosterone, thyroid-stimulating hormone (TSH) and glucose, and pineal melatonin content, in rats. When body weight of rats reached the values of morbid obesity, the animals were sacrificed at six different time intervals throughout a 24-h cycle, together with age-matched controls fed a normal diet (4% fat). Plasma hormone levels were measured by specific radioimmunoassays and glucose concentration by an automated glucose oxidase method. In rats under a high-fat diet, a significant disruption of the 24-h pattern of plasma TSH, LH, and testosterone and a slight disruption of prolactin rhythm were found. Additionally, high-fat fed rats showed significantly lower total values of plasma TSH and testosterone and absence of correlation between testosterone and circulating LH levels. Plasma corticosterone levels increased significantly in high-fat fed rats and their 24-h variation became blunted. In obese animals, a significant hyperglycemia developed, individual plasma glucose values correlating with circulating corticosterone in high-fat fed rats only. The amplitude of the nocturnal pineal melatonin peak decreased significantly in high-fat fed rats. The results underlie the significant effects that obesity has on circadian organization of hormone secretion.

Melatonin and the Immune System in Aging

Aging is associated with a decline in immune function (immunosenescence), a condition known to correlate with increased incidence of cancer as well as infectious and degenerative diseases. Innate, cellular and humoral immunity all exhibit increased deterioration with age. Circulating melatonin decreases with age, and in recent years much interest has been focused on its immunomodulatory effect. Melatonin stimulates the production of progenitor cells for granulocytes and macrophages. It also stimulates the production of natural killer cells and CD4+ cells and inhibits CD8+ cells. The production and release of various cytokines from natural killer cells and T helper lymphocytes are enhanced by melatonin. Melatonin has the potential therapeutic value to enhance immune function in aged individuals.

Twenty-Four-Hour Rhythms in Immune Responses in Rat Submaxillary Lymph Nodes and Spleen: Effect of Cyclosporine

Twenty-four-hour variations in cellularity, lipopolysaccharide (LPS)- and concanavalin A (Con A)-induced cell proliferation, and natural killer (NK) activity were examined in submaxillary lymph nodes and spleen of rats injected with Freunds complete adjuvant or its vehicle and kept under light from 08:00 to 20:00 h daily. A significant daily variation in cellularity was detected, exhibiting maxima at 09:00 h in submaxillary lymph nodes (nonimmunized and immunized rats) and at 13:00 h in spleen (immunized rats only). Submaxillary lymph node LPS- and Con A-mitogenic effect displayed maximal activity during daytime (peak at 13:00-17:00 h). In spleen, the maxima for 24-h rhythm in LPS-induced cell proliferation and NK activity occurred at midnight and at early morning (09:00 h), respectively. Con A-induced spleen cell proliferation peaked at midday in nonimmunized rats only. Injection of the immunosuppressive drug cyclosporine decreased Freunds adjuvant-induced augmentation of LPS and Con A mitogenic effect in both tissues and diminished spleen cell number. Cyclosporine blunted circadian rhythms in submaxillary lymph node Con A response and cell number, while it shifted the maximum in LPS effect to peak at 01:00 h. Cyclosporine also suppressed the circadian changes in LPS- and Con A-induced spleen cell proliferation, but not those found in NK activity. The results indicate the existence of 24-h rhythms in immune responses of rat submaxillary lymph nodes and spleen with maxima at different times of the day and that were significantly affected by cyclosporine injection.

Cadmium effects on hypothalamic activity and pituitary hormone secretion in the male

Cadmium specifically modify amine metabolism at the central nervous system and pituitary hormone secretions. Thus, the physiological functions controlled by these hormones can be modulated by cadmium. This xenobiotic is associated with deleterious effects on the gonadal function and with changes in the secretory pattern of other pituitary hormones like prolactin, ACTH, GH or TSH. The observed changes in pituitary hormone secretion do not correlate with the modifications of central nervous system metabolism of the neurotransmitters involved in their regulation. The accumulative data indicates the existence of a disruption in the regulatory mechanisms of the hypothalamic-pituitary axis. The physiological significance of these effects remains to be elucidated.

Effect of a high-fat diet on 24-hour pattern of circulating adipocytokines in rats.

We have shown a significant disruption of 24‐h pattern of plasma pituitary, adrenal, and gonadal hormones in high‐fat‐fed rats. Our objective was to assess the effect of a high‐fat diet (35% fat) on mean levels and 24‐h pattern of several adipocytokines in rats. A normal diet–fed rats (4% fat) were used as controls. When body weight of high‐fat‐fed rats attained values about 25% higher than controls (after 66 days of treatment), the animals were killed at six different time intervals throughout a 24‐h cycle. Plasma concentrations of insulin, adiponectin, interleukin (IL)‐1, leptin, ghrelin, plasminogen activator inhibitor‐1 (PAI‐1), and monocyte chemoattractant protein‐1 (MCP‐1) were measured in a multianalyte profiling by using the Luminex‐100 system. Tumor necrosis factor α (TNFα) and IL‐6 were measured by enzyme‐linked immunosorbent assay. A significant hyperglycemia developed in high‐fat‐fed rats, together with a significant increase in plasma insulin. Mean levels of plasma adiponectin, IL‐1, IL‐6, TNFα, and leptin augmented, and ghrelin decreased, in high‐fat‐fed rats. The normal daily pattern of plasma insulin, adiponectin, IL‐1, IL‐6, TNFα, leptin, ghrelin, and MCP‐1 became disrupted in high‐fat‐fed rats. The results indicate that a high‐fat diet may bring about signs of insulin resistance and mild inflammation in rats, together with the disruption in daily variations of circulating insulin and ghrelin, and of several adipocytokines including leptin, adiponectin, IL‐1, IL‐6, TNFα, and MCP‐1.

Melatonin site and mechanism of action: Single or multiple?

ABSTRACT: By affecting the entrainment pathways of the biologic clock, melatonin has a major influence on the circadian and seasonal organization of vertebrates. In addition, a number of versatile functions that far transcend melatonin actions on photoperiodic time measurement and circadian entrainment have emerged. Melatonin is a free radical scavenger and antioxidant and it has a significant immunomodulatory activity, being presumably a major factor in an organisms defense toxic agents and invading organisms. Besides affecting specific receptors in cell membranes to exert its effects, the interaction of melatonin with nuclear receptor sites and with intracellular proteins, like calmodulin or tubulin‐associated proteins, as well as the direct antioxidant effects of melatonin, may explain many general functions of the pineal hormone.

24‐Hour Changes in ACTH, Corticosterone, Growth Hormone, and Leptin Levels in Young Male Rats Subjected to Calorie Restriction

Calorie restriction of young male rats increases plasma prolactin, decreases luteinizing hormone (LH) and testosterone, and disrupts their 24 h secretory pattern. To study whether this could be the consequence of stress, we examined the 24 h variations of plasma adrenocorticotropic hormone (ACTH) corticosterone, growth hormone (GH), leptin, and adrenal corticosterone. Rats were submitted to a calorie restriction equivalent to a 66% of usual intake for 4 weeks, starting on day 35 of life. Controls were kept in individual cages and allowed to eat a normal calorie regimen. Significantly lower ACTH levels were detected in calorie‐restricted rats. Plasma corticosterone levels during the light phase of the daily cycle were significantly higher in calorie‐restricted rats. Time‐of‐day variation in plasma ACTH and corticosterone levels attained significance in calorie‐restricted rats only, with a maximum toward the end of the resting phase. The daily pattern of adrenal gland corticosterone mirrored that of circulating corticosterone; however, calorie restriction reduced its levels. Plasma ACTH and corticosterone correlated significantly in controls only. Calorie restriction decreased plasma GH and leptin, and it distorted 24 h rhythmicity. In a second study, plasma ACTH and corticosterone levels were measured in group‐caged rats, isolated control rats, and calorie‐restricted rats during the light phase of the daily cycle. Plasma ACTH of calorie‐restricted rats was lower, and plasma corticosterone was higher, compared with isolated or group‐caged controls. The changes in the secretory pattern of hormones hereby reported may be part of the neuroendocrine and metabolic mechanisms evolved to maximize survival during periods of food shortage.