Melatonin Research https://melaonin-research.com/index.php/MR <p><span style="color: rgb(0, 0, 0);"></span>This is an open access journal. This journal is published by the ST-Bio-Life LLC as its publisher. The Journal is non-profit but only for the academic information sharing.&nbsp;</p> ST Bio-Life. LLC en-US Melatonin Research 2641-0281 <p>For all articles published in Melatonin Res., copyright is retained by the authors. Articles are licensed under an open access Creative Commons CC BY 4.0 license, meaning that anyone may download and read the paper for free. In addition, the article may be reused and quoted provided that the original published version is cited. These conditions allow for maximum use and exposure of the work, while ensuring that the authors receive proper credit.</p><p>In exceptional circumstances articles may be licensed differently. If you have specific condition (such as one linked to funding) that does not allow this license, please mention this to the editorial office of the journal at submission. Exceptions will be granted at the discretion of the publisher.</p> Differential effects of melatonin on adipose tissues under normoestrogenic and estrogen-deficient conditions in rats https://melaonin-research.com/index.php/MR/article/view/257 <p style=";text-align:justify;text-justify: inter-ideograph;line-height:normal"><span style="font-size:16px;font-family: &#39;Times New Roman&#39;,serif">In post-menopause, oxidative stress due to the decline of natural antioxidants increases the susceptibility to metabolic syndromes (MetS). Estrogen and melatonin (MEL) share antioxidant properties; however, few studies have reported the impact of estrogen deficiency and MEL treatment on morphology, redox status, and antioxidant defense capacity of diverse adipose tissue (AT) subtypes. To investigate this issue, MEL was administered to ovariectomized (OVX) rats and sham-operated rats for 16 weeks (10 mg/kg). The adipocyte morphology, oxidative stress parameters and antioxidant enzyme activity were evaluated in the visceral retroperitoneal adipose tissue (rVAT), subcutaneous inguinal adipose tissue (iSAT) and brown adipose tissue (BAT). In OVX rats, MEL treatment suppressed rVAT hypertrophy and increased the prevalence of small adipocytes in iSAT, suggesting a better lipid distribution among ATs. MEL treatment increased glutathione reductase and </span><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif">glucose-6-phosphate dehydrogenase</span><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif"> activity in iSAT; therefore, restored the glutathione level. In rVAT, MEL increased glutathione peroxidase and glutathione reductase activity. MEL minimized the risks for the development of metabolic abnormalities due to estrogen deficiency. However, under normoestrogenic condition, MEL decreased plasma estradiol levels and uterine mass, raising the concerning of its effect on reproductive functions.</span></p><p><br/></p> Danielle Aparecida Munhos Hermoso Lenilson da Fonseca Roza Aparecida Pinto Munhos Hermoso Eduardo Makiwama Klosowski Franciele Neves Moreno Maria Raquel Marçal Natali Tatiana Carlesso Santos Jorgete Constantin Rodrigo Polimeni Constantin Eduardo Hideo Gilglione Emy Luiza Ishii Iwamoto ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2024-08-31 2024-08-31 7 2 187 212 10.32794/mr112500175 Onset in late adolescence of schizophrenia: Could melatonin modulate this debut? https://melaonin-research.com/index.php/MR/article/view/264 <p style="text-align:justify;line-height:normal"><span style="font-size:16px;line-height:107%;font-family:&#39;Times New Roman&#39;,serif">Schizophrenia, one of the most serious and widespread mental disorders in the world, makes its debut often in late adolescence and early adulthood, which allows us to focus our attention on those brain areas that still retain plasticity during this period. Parvalbumin interneurons, GABAergic and inhibitory, in both cortical and hippocampal areas, maintain their plasticity and are particularly vulnerable to oxidative stress due to their high energy requirements. Evidence has shown that their damage favors the triggering of schizophrenia by altering the neurobehavioral development of individuals. These neurons have melatonin receptors of MT1 and MT2, and the cytoprotective role of melatonin has been reported on these neurons. However, the role of this indolamine played in adolescence in protecting parvalbumin interneurons, reducing their oxidative stress and/or preventing their disappearance, which could prevent the onset of schizophrenia, is not yet known. The importance of this activity and its implications on patient therapy require the urgent studies</span></p><p><br/></p> Cristina Cachán-Vega Jose Antonio Boga Yaiza Potes Ana Maria Cotomontes ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2024-08-30 2024-08-30 7 2 181 186 10.32794/mr112500174 Multiple actions of melatonin in reducing viral pathophysiologies https://melaonin-research.com/index.php/MR/article/view/259 <p style="margin-bottom:16px;text-align:justify;text-justify: inter-ideograph;text-autospace: none"><span style="font-family: &quot;Times New Roman&quot;, serif;">Viral infections lead to significant morbidity and mortality while the effective therapeutic approaches are lacking. Melatonin (MEL) (N-acetyl-5-methoxytryptamine) is a pleiotropic molecule that has a variety of functions, including the antiviral properties. It is a potent antioxidant, anti-inflammatory agent, a stimulator of immune functions, and regulator of apoptosis. These effects support the use of MEL in viral infections, which are often associated with excessive inflammatory responses and elevated oxidative stress. The virus- and cytokine- storm-driven control of the pineal and mitochondrial melatonergic pathway regulates immune responses and increases gut dysbiosis, suppressing levels of the short-chain fatty acid, butyrate</span><span style="font-family: &quot;Times New Roman&quot;, serif;">,</span><span style="font-family: &quot;Times New Roman&quot;, serif;"> and increasing circulating lipopolysaccharides, stimulating viral replication and host symptoms severity. MEL has a contrasting role in controlling the pathophysiological effects of various viruses due to its chronobiotic, antioxidant and anti-inflammatory actions. Several recent preclinical and clinical studies have</span><span style="font-family: &quot;Times New Roman&quot;, serif; color: rgb(29, 29, 29);"> documented a robust protective effect of MEL against viral infections, including COVID-19 and it</span><span style="font-family: &quot;Times New Roman&quot;, serif;"> has emerged as an excellent candidate for protection against an array of different viruses. This review summarizes available data on the beneficial effects of MEL on viral pathophysiological actions, and also discusses and highlights likely evidence-based therapeutic applications.</span><br/></p><p style="margin-bottom:16px;text-align:justify;text-justify: inter-ideograph;text-autospace: none"><span style="font-family:&#39;Times New Roman&#39;;color:black"></span><br/></p><p style="margin-bottom:16px;text-align:justify;text-justify: inter-ideograph;text-autospace: none"><span style="font-family:&#39;Times New Roman&#39;;color:black">&nbsp;</span></p><p><br/></p><p><br/></p> Leonor Chacin-Bonilla Ernesto Bonilla ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2024-08-01 2024-08-01 7 2 153 180 10.32794/mr112500173 Transgenerational effects of maternal circadian melatonin deficiency and melatonin replacement in rats during pregnancy and lactation on the energy metabolism and thermoregulation in the offspring subjected to a high-fat diet https://melaonin-research.com/index.php/MR/article/view/265 <p style="text-align:justify;text-justify:inter-ideograph"><span style="font-family:&#39;Times New Roman&#39;,serif">Pineal melatonin participates in the control of numerous biological functions through its immediate effects, which result from its high presence in the systemic circulation during the dark phase of the circadian cycle or, through its prolonged effects, when its level is extremely low during the light phase. At pregnancy, maternal melatonin signals the external photoperiod to the fetus, highlighting its importance not only in synchronizing rhythms, but also in preparing the fetus to adapt the external environments. The fetus and newborns are exclusively dependent on maternal melatonin since their pineal melatonin production only occurs weeks after birth. Thus, maternal hypomelatoninemia stands out as an important factor capable of modulating the physiological systems of their descendants, demonstrating its transgenerational capacity. The present study evaluated the transgenerational influence of maternal melatonin deficiency and replacement during pregnancy on morphometric parameters, thermoregulation and energy metabolism of the offspring submitted to the normal and high-fat diets, respectively. For this, nulliparous Wistar rats at an age of 8 weeks were used and randomized into three groups: CTL (pregnant rats), PINX (pinealectomized pregnant rats), PINX + MEL (pinealectomized pregnant rats submitted to melatonin replacement). After birth, the pups were divided into three groups: (C) pups from control mothers, (P) pups from PINX mothers and (PM) pups from PINX + MEL mothers. One week after weaning, part of the animals was fed a high-fat diet (DH) and rest of them were fed a normal diet (ND) for 12 weeks. Subsequently, the animals were euthanized at ZTs 6 and 18. The results showed that maternal melatonin deficiency disrupted the energy metabolism of the offspring and melatonin replacement normalized the energy metabolism in the offspring submitted to the high-fat diet, enabling them to make functional adaptations such as reduced food consumption and greater thermoregulatory capacity, resulting in reduction in body weight gain white adipose tissue mass.</span></p><p><br/></p> Luciana Tocci Belpiede Patricia Rodrigues Lourenço Gomes Guilherme Gomes Caroline Mendes Fernanda Marques Cunha Felipe Macedo Livia Clemente Motta Teixeira Sinésio Silva Júnior Fernanda Gaspar Amaral José Cipolla-Neto ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2024-07-31 2024-07-31 7 2 134 152 10.32794/mr112500172 Cell polarization, migration and tissue repair: A promising field for future melatonin research https://melaonin-research.com/index.php/MR/article/view/261 <p style=";text-align:justify;line-height: normal"><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif">Melatonin has been shown to support the repair of various tissue injuries. Wound healing is a complicated process that comprises several different cellular activities and regulation mechanisms, such as activation and programming of stem cells, interaction of different cell types, polarization of cells, especially concerning the alternative of pro- vs. anti-inflammatory behavior, migration of cells to the site of replacement, with guidance by other cells and modified extracellular matrix, as observed in the formation of biobridges. In most of these processes, melatonin acts as a decisive modulator, but details depend on tissue and cell types and have not been completely identified. Many aspects will require a considerable amount of work for understanding, in this context, the role of melatonin on a comprehensive basis. Moreover, the modulation of important cell properties has remained partially unknown or has only poorly considered in recent work. For instance, pro- or anti-inflammatory polarization of cells has been described in various cell types, not only in macrophages, in which melatonin is a major regulator, but also in microglia, in astrocytes and in neutrophils. Even in fibroblasts, polarization has been observed and concerns the alternative of inflammatory or fibrotic behavior. Notably, polarized cells that support healing in normal tissue seem to also protect tumors, whereas inflammatory phenotypes show antitumor activities. With regard to antitumor properties of melatonin, it seems necessary to clarify whether melatonin polarizes cells differently in the tumor microenvironment, compared to normal tissue, in which it promotes healing.</span></p><p><br/></p> Ruediger Hardeland ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2024-07-18 2024-07-18 7 2 120 133 10.32794/mr112500171 Melatonin and the intervertebral disc: a potential intervention for lower back pain? https://melaonin-research.com/index.php/MR/article/view/255 <p style=";text-align:justify;line-height: normal"><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif">Lower back pain is a common disability associated with aging that continues to carry a huge economic and health burden globally. Importantly, lower back pain is strongly associated with diseases involving intervertebral discs (IVDs), and many of the treatment options for the repair and maintenance of the IVDs are insufficient. Being a well-tolerated and endogenously produced molecule, melatonin is a suitable candidate for the treatment and prevention of a wide variety of skeletal conditions. In this review, we have evaluated current updates regarding melatonin’s activities in IVD degenerative disease and discuss multiple mechanisms related to its effects on inflammation, oxidative stress, autophagy and senescence that contribute towards its support of the IVDs as well as its benefits in the treatment of IVD disease.</span></p><p><br/></p> Christopher File Ramaswamy Sharma ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2024-04-30 2024-04-30 7 2 84 102 10.32794/mr112500169 The effects of endogenous melatonin on brain tissue oxidative stress induced by photoperiodic alterations and iron overloading in rats https://melaonin-research.com/index.php/MR/article/view/262 <p style=";text-align:justify;text-indent: 19px;line-height:normal"><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif">Melatonin is a potent endogenously occurring antioxidant with the pleiotropic activities to neurodegenerative diseases associated with brain oxidative damage. In this study, we examined the prolonged photoperiodic alterations and iron (Fe) overload on melatonin production and brain oxidative stress in rats. The result showed that the 15 days of constant light (CL) exposure did not low the melatonin production but the 15 days of constant darkness (CD) significantly increased serum melatonin level in rats. The Fe treatment in both CL and CD conditions significantly reduced endogenous melatonin levels and increased brain tissue lipid peroxidation. Fe as a toxic transition metal can induce Fenton reaction to generated hydroxyl radical which can damage the neuronal cell membrane and impair the brain antioxidant system. In the current study, we observed the imbalanced antioxidant defense alterations upon Fe treatment in rat brain including the increased levels of alpha-tocopherol (α-T) and total thiols and the reduced melatonin level and catalase (CAT) activity. We speculated that the reduced melatonin level caused by Fe was due to its consumption since melatonin served as a metal chelator and antioxidant. Understanding these aspects enhances knowledge of brain Fe metabolism and its role in neurodegenerative disorders as well as the potential protective effects of melatonin on this metal.</span></p><p><br/></p> Marcelo P Hernando Joaquín Cogo Pagella Claudio Osvaldo Cervino ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2024-04-30 2024-04-30 7 2 103 119 10.32794/mr112500170 Melatonin as a promising agent alleviating endocrine deregulation and concurrent cardiovascular dysfunction: a review and future prospect https://melaonin-research.com/index.php/MR/article/view/244 <p style="margin-left:28px;text-align:justify;text-justify: inter-ideograph;line-height:150%"><span style="font-size:16px;line-height: 150%;font-family:&#39;Times New Roman&#39;,&#39;serif&#39;">Endocrine modulation of various growth and survival mechanisms is at the helm of cellular homeostasis and impaired endocrine balance may potentially galvanize cardiovascular health to go haywire. Melatonin, an effective antioxidant and multipotent hormone has preponderant influence on the activities of several endocrine factors including growth hormones, thyroid hormones, gastro-intestinal hormones, and those controlling reproductive and metabolic functions. Many of these hormones tightly regulate cardiovascular functions while the mammalian heart has its own endocrine machinery. Endocrine disruptions severely affect cardiovascular integrity and hormonal therapies may instigate adverse cardiac events. Therefore, this review focuses on the cardioprotective potential of melatonin concerning endocrine instability-mediated cardiovascular dysfunction. Melatonin has been reported to effectively counteract sympathetic overstimulation and also reduce the cardiotoxic attributes of catecholamines and their derivatives. Melatonin suppresses the pernicious cardiovascular manifestation of thyrotoxicosis and autoimmune thyroiditis, which is possibly attributed to its antioxidant property and regulation of iodothyronine-deiodinase activity. Interestingly, being a circadian synchronizer melatonin potentially preserves the diurnal pattern of insulin secretion and thereby improves glucose tolerance and cardiac GLUT-4 expression. Besides, melatonin modulates insulin signaling pathway by enhancing the activation of insulin receptor-associated tyrosine kinase, thus protecting the heart against diabetogenic outcomes. Further, melatonin has demonstrated its beneficial action against non-dipper hypertension by regulating the RAAS function. However, there is a plethora of unresolved research question that necessitates additional investigation into the potential therapeutic effect of melatonin in endocrine dysfunctions that emanates during various physiological and pathological states and may have potentially harmful cardiovascular implications.</span></p><p><br/></p> Swaimanti Sarkar Aindrila Chattopadhyay Debasish Bandyopadhyay ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2024-04-20 2024-04-20 7 2 1 19 10.32794/mr112500166 Melatonin and viral infections: A review focusing on therapeutic effects and SARS-CoV-2 https://melaonin-research.com/index.php/MR/article/view/256 <p><br/></p><p style="margin-bottom:16px;text-align:justify;text-justify: inter-ideograph;text-autospace: none">&nbsp;&nbsp;&nbsp; <span style="font-family: &#39;Times New Roman&#39;;color:black">&nbsp;&nbsp;<span style="font-size: 16px;font-family: &#39;Times New Roman&#39;, serif">Viral infections can cause serious diseases which lead to significant morbidity and mortality of patients. In most cases, effective therapeutic approaches are lacking. Melatonin (MEL), a multifunctional molecule produced in the pineal gland and many other organs, is known as a potent anti-inflammatory and antioxidant, a positive regulator of immune functions and a suppressor of apoptosis, with therapeutic effects in diverse diseases. These actions suggest the potential of MEL to treat viral infections. A variety of studies have shown that MEL supplementation is effective against a number of viral infections. Many of these reports have strongly suggested its use as an adjuvant or therapeutic agent. Notably, the efficacy of this molecule as a prophylactic or therapeutic weapon against COVID-19 has been demonstrated both in experimental conditions and in clinical trials, and it can reduce the severity and mortality of the patients. </span><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif">This review summarizes actions of MEL on viral infections and focuses on its therapeutic effects against COVID-19 and generally highlights MEL as an attractive therapy in other viral infections.&nbsp;</span></span></p><p><br/></p><p><br/></p> Leonor Chacin-Bonilla Ernesto Bonilla ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2024-04-19 2024-04-19 7 2 47 83 10.32794/mr112500168 Physiological processes underpinning the ubiquitous benefits and interactions of melatonin, butyrate and green tea in neurodegenerative conditions https://melaonin-research.com/index.php/MR/article/view/254 <p style=";text-align:justify;text-justify: inter-ideograph;line-height:normal"><span style="font-size:16px;font-family: &#39;Times New Roman&#39;,serif">There is a growing dissatisfaction at the lack of progress in treating neurodegenerative conditions, such as Alzheimer’s disease, Parkinson’s disease and amyotrophic lateral sclerosis. No current pharmaceuticals have any significant impact on the pathophysiological changes occurring in such neurodegenerative conditions. More promising has been the utilization of nutraceuticals, a number of which show preventative and treatment benefits. This article reviews the beneficial effects of melatonin, sodium butyrate and epigallocatechin gallate (EGCG) in the management of the pathophysiological changes underpinning neurodegenerative conditions. It is proposed that all three nutr</span><span style="font-size:16px;font-family: &#39;Times New Roman&#39;,serif">a</span><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif">ceuticals upregulate the tryptophan-melatonin pathway, which may be particularly important in astrocytes given astrocyte regulation of neuronal energy supply and antioxidants, including released melatonin. Alterations in the tryptophan-melatonin pathway are intimately intertwined with changes in the kynurenine pathway and its neuroregulatory products, including kynurenic acid and quinolinic acid. This article places these changes in the tryptophan-melatonin pathways within a novel circadian-systemic interaction, involving the regulation of the night-time rise in cortisol culminating in the morning cortisol awakening response that mediates effects via glucocorticoid receptor (GR) activation. The night-time and morning GR activation is suppressed by melatonin, gut microbiome derived butyrate and bcl2-associated athanogene (BAG)-1. As melatonin, butyrate and BAG-1 decrease over age, there is a heightened level of GR nuclear translocation with age at night and early morning. This is exemplified by the 10-fold decrease in pineal melatonin in people in their 9<sup>th</sup>, versus 2<sup>nd</sup>, decade of life. The ‘battle’ of melatonin/butyrate/EGCG versus cortisol/GR for influence on cellular function, microenvironment homeostasis and systemic system (immune) regulation at night and early morning shapes how the body and brain are prepared for the coming day and drives the emergence of aging associated neurodegenerative conditions. It is upon such processes that melatonin, butyrate and EGCG have their impacts.&nbsp;&nbsp; </span></p><p style=";text-align:justify;text-justify: inter-ideograph;line-height:normal"><strong><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif">&nbsp;</span></strong></p><p><br/></p> George Anderson ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2024-04-18 2024-04-18 7 2 20 46 10.32794/mr112500167 Melatonin and cancer: Exploring gene networks and functional categories https://melaonin-research.com/index.php/MR/article/view/240 <p style="text-align:justify;text-justify:inter-ideograph">&nbsp; &nbsp; &nbsp;While melatonin is known for its multifaceted properties and its potential to combat cancer, there has been limited exploration of the cancer-melatonin interaction at the gene network level. One of the ways to better understand the molecular mechanisms of melatonin’s anti-cancer effects is to use text-mining strategies to extract relevant information that creates knowledge networks of entities and their associations. In this study, we mined gene-publication associations to search for genes most relevant to the terms of “melatonin” and “cancer”. A total of 152 genes were identified and ranked, among which 15 were kinase-related and three G-protein coupled receptor genes. The hub genes (<em>STAT3</em>, <em>JUN</em>, <em>TP53</em>, <em>MAPK3</em>, <em>EP300</em>, <em>SRC</em>, <em>HSP90AA1</em>, <em>AKT1</em>, <em>ESR1</em>, and <em>IL6</em>) were involved with several pathways in cancer. After examining the melatonin-treated cancers, we mapped 25 upregulated and 51 downregulated genes; these were strongly associated with cancer hallmarks such as resisting cell death, sustaining proliferative signaling, and inducing invasion and metastasis. Upregulated genes showed molecular functions including apoptotic protease activator, caspase activator, enzyme regulator, and protein binding, whereas the downregulated genes affected protein kinase activities, transcription factor binding, protein, enzyme, DNA, and promoter bindings. By connecting gene subsets, we detected a closer relationship among breast, hepatocellular, prostate, and oral cancers, in addition to neuroblastoma and osteosarcoma in terms of changes in melatonin-related signaling pathways. TCGA data were analyzed to understand the impact of gene signatures on survival of patients, and melatonin-downregulated genes were associated with longer survival of patients with glioblastoma, bladder, breast, colon, stomach, liver, lung, and ovarian carcinomas. These results provide a global view of gene interaction networks in melatonin-treated cancers and their functional value, opening new opportunities to consider melatonin for cancer therapy.</p><p><br/></p> Luiz Chuffa Robson Francisco Carvalho Victória Larissa Schimidt Camargo Sarah Santiloni Cury Raquel Fantin Domeniconi Debora Aparecida Pires de Campos Zuccari Fábio Rodrigues Ferreira Seiva ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2023-12-31 2023-12-31 7 2 431 451 10.32794/mr112500161 The therapeutic potential of melatonin against hepatotoxicity caused by obesity and NSAIDs: A comprehensive review https://melaonin-research.com/index.php/MR/article/view/232 <p style="text-align:justify;text-justify:inter-ideograph"><span style="font-family:&#39;Times New Roman&#39;,serif;color:black">The obesity and increased free fatty acid level are considered the etiology of hepatotoxicity leading to steatohepatitis and hepatic fibrosis. Obesity promotes inflammatory response and oxidative stress. Adipocytes secrete various proinflammatory cytokines including TNF-α, IL-1β, IL-6 and leptin to initiate a vicious cycle and cause further fat acc</span><span style="font-family:&#39;Times New Roman&#39;,serif;color:black">u</span><span style="font-family:&#39;Times New Roman&#39;,serif;color:black">mulation and weight gain. Specifically, to liver, the fat accumulation will cause non-alcoholic fatty liver disease (NAFLD), the most prevailing chronic liver ailment, if it is not properly treated</span><span style="font-family:&#39;Times New Roman&#39;,serif;color:black">,</span> <span style="font-family:&#39;Times New Roman&#39;,serif;color:black">then</span> <span style="font-family:&#39;Times New Roman&#39;,serif;color:black">it </span><span style="font-family:&#39;Times New Roman&#39;,serif;color:black">will cause severe outcomes including fatality. In addition, obesity also cause other inflammatory disorders including osteoarthritis of the knee, joint pain, etc.&nbsp; Non-steroidal anti-inflammatory drugs (NSAIDs) are most often used medicines for treatment of inflammation but their serious side effects are concerning. These include gastric mucosal damage, liver injury with elevated aminotransferase (AST/ALT) levels, hepatitis, jaundice and more fatal liver diseases. Melatonin</span><span style="font-family:&#39;Times New Roman&#39;,serif;color:black">,</span><span style="font-family:&#39;Times New Roman&#39;,serif;color:black"> a</span><span style="font-family:&#39;Times New Roman&#39;,serif;color:black">n</span><span style="font-family:&#39;Times New Roman&#39;,serif;color:black"> antioxidant and anti-inflammatory molecule can be used to treat diverse kind of inflammatory diseases. It remarkably reduces the mRNA levels of pro</span><span style="font-family:&#39;Times New Roman&#39;,serif;color:black">-</span><span style="font-family:&#39;Times New Roman&#39;,serif;color:black">inflammatory cytokines of TNF-α, IL-6, IL-1β, etc. Melatonin and its metabolites retain the properties as an effective free radical scavenger and regulate various antioxidative and pro-oxidative enzymes. This molecule can potentially abate the ill effects of hepatotoxicity induced by both NSAIDs and obesity. Therefore, this review briefly summarizes the recent available knowledge on the protective effects of melatonin against various disorders involving weight gain and hepatotoxicity.</span></p><p><br/></p> Anupama Nath Songita Ghosh Tiyasa Dey Aindrila Chattopadhyay Debasish Bandyopadhyay ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2023-12-31 2023-12-31 7 2 452 473 10.32794/mr112500162 Melatonin and Covid-19: An opened Pandora's box and the hope for the time being https://melaonin-research.com/index.php/MR/article/view/241 <p>&nbsp;&nbsp;&nbsp; The SARS-CoV-2 pandemic is a global health concern still ongoing. No single therapeutic intervention with high efficacy exists and virus mutations continue to improve immune evasion decreasing vaccine efficacy. Therefore, a therapy which instead targets severe symptoms of COVID-19 should be contemplated. Hyperinflammation, cytokine storm and oxidation are relevant in the evolution of COVID-19. Considering the anti-inflammatory, anti-oxidative and cytoprotective effects of melatonin (MEL) on viral infections, its potential links with COVID-19 should be researched. In addition, evidence suggests a viricidal action of MEL and an increase in the efficacy of SARS-CoV-2 vaccines. One of the neglected and excellent options for therapy is MEL. We strongly support and encourage the use of MEL as a therapy for COVID-19.</p><p><br/></p> Leonor Chacin-Bonilla Ernesto Bonilla ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2023-12-31 2023-12-31 7 2 474 484 10.32794/mr112500163 Olfactory neuronal precursors as a model to analyze the effects of melatonin in Alzheimer's disease. https://melaonin-research.com/index.php/MR/article/view/249 <p>&nbsp; &nbsp; &nbsp;<span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif">Alzheimer&#39;s disease (AD) is a multifactorial disorder of great importance affecting millions globally and its prevalence will triple in the following decades. Therefore, analysis and identification of substances which can effectively reduce the pathological process of this disease in different study models are crucial. Melatonin works as a multitasking substance and some of its activities could be used to target the neurodegenerative process of AD. These include, but not limited to, its potent antioxidant activity, regulation of sleep-wake rhythms (important for the consolidation of memory and cognition) and its action as a neurotrophic growth factor that promotes differentiation and neuronal proliferation. To evaluate the effects of melatonin at cellular level in AD, it is essential to have a study model that reflects the pathological process occurring in the CNS. In this, review we summarize the potential use of olfactory neuronal precursors derived from olfactory neuroepithelium directly obtained from patients for such purposes.</span></p> Valeria Santillan Morales Gloria Acacia Benitez King ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2023-12-31 2023-12-31 7 2 485 502 10.32794/mr112500164 Nanocarriers for melatonin delivery https://melaonin-research.com/index.php/MR/article/view/242 <p style=";text-align:justify;text-justify: inter-ideograph;line-height:normal;direction:ltr;unicode-bidi:embed"><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif">More attention has been drawn to the drug delivery systems to achieve more precise and efficient treatment for patients with less doses of medicines. The use of nanoparticles for drug delivery system has emerged for this purpose. It can enhance the treatment efficiency by use of the drugs more selectively and precisely to deliver them to the targeted organs or tissues. Drug delivery systems can also help to reduce the side effects, especially for the chemotherapeutic agents that have severe toxicity. Melatonin (N-acetyl-5-methoxytriptamine) is a small indolamine molecule that is produced by most cells and can influence on circadian manner. Melatonin also has antiapoptotic and antioxidant actions depending on the microenvironment; these actions are enhanced when it is incorporated into nanocarriers. Although the therapeutic effects of melatonin are promising, to achieve its optimal results is required. Therefore, the use of nanocarriers of melatonin is of clinical interest. Different melatonin loaded nanocarriers such as lipid-based nanocarriers, hybrid nanocarriers, synthetic ones, etc. can be used to deliver melatonin more efficiently for prevention or treatment of various diseases. In this review, we summarize the treatment efficiency of melatonin when it is incorporated into different nanocarriers.</span></p><p><br/></p> Amirreza Ahmadi Jazi Fatemeh Mohammadzadeh Saeed Amirkhanlou Zahra Arab Bafarani Seyed Mostafa Mir ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2023-12-31 2023-12-31 7 2 503 519 10.32794/mr112500165 CREB1 spatio-temporal dynamics within the rat pineal gland https://melaonin-research.com/index.php/MR/article/view/227 <p style="line-height: normal; text-align: justify;"><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif">In the rat pineal gland (PG), cyclic AMP responsive element-binding protein 1 (CREB1) participates in the nocturnal melatonin synthesis that rhythmically modulates physiology and behavior. Phosphorylation of CREB1 is one of the key regulatory steps that drives pineal transcription. The spatio-temporal dynamics of CREB1 itself in the different PG cell types have not yet been documented. <a>In this study we analyzed total CREB1 in the rat PG via Western blot and fluorescence immunohistochemistry followed by confocal laser-scanning microscopy and quantitative analysis. </a>Total CREB1 levels remained constant in the PG throughout the light:dark cycle. The distribution pattern of nuclear CREB1 did vary among PG cell types. Pinealocytes emerged &nbsp;to &nbsp;have &nbsp;discrete CREB1 domains within their nucleoplasm that were especially distinct. The number, size, and location of CREB1 foci fluctuated among pinealocytes, within the same PG and among <em>Zeitgeber</em> times (ZTs). A significantly larger dispersion of CREB1-immunoreactive nuclear sites was found at night than during the day. However, the overall transcription activity was mostly conserved between the light and dark phases, as shown by the expression of a particular phosphorylated form of the RNA polymerase II (RNAPII-pSer<sup>5</sup>CTD). Suppression of the nocturnal norepinephrine pulse by chronic bilateral superior cervical ganglionectomy increased CREB1 dispersion in pinealocyte nuclei at early night, as compared to sham-derived cells. In addition, differences in CREB1 distribution were found between sham-operated and non-operated rats at ZT14. Together, these data suggest that in mature pinealocytes, nuclear CREB1 is subjected to a dynamic spatio-temporal distribution. Further studies are necessary to elucidate the underlying mechanisms and to understand the impact of CREB1 reorganization in the pineal transcriptome.</span></p><p style="text-align: justify;"><br/></p> Luz E . Farias Altamirano Elena Vásquez Carlos L. Freites Jorge E. Ibañez Mario E . Guido Estela M . Muñoz ##submission.copyrightStatement## 2023-09-30 2023-09-30 7 2 234 255 10.32794/mr112500153 Melatonin modulates the in vitro angiogenesis of granulosa cells collected from women with marital infertility for IVF https://melaonin-research.com/index.php/MR/article/view/219 <p style="text-align: justify;"><span style="font-size: 12pt; line-height: 107%; font-family: &quot;Times New Roman&quot;, serif;">Melatonin concentration is several folds higher in the follicular fluid than that in blood suggesting an important role of this molecule on follicular physiology. However, the actions of melatonin on angiogenesis in granulosa cells are currently unknown. In this study, we have specifically investigated the potential effects of melatonin on the angiogenesis in granulosa cells from female individuals with marital infertility. Sixty patients who were submitted to the <em>in vitro</em>fertilization were included. The granulosa-luteal cells of these females were collected for cell culture. The cells were divided into four groups: a) vehicle (control); b) 0.1 µM melatonin; c) 1 µM melatonin; d) 10 µM melatonin treated groups, respectively. After a period of 10 days of culture, expression of genes involved in the angiogenesis signaling pathway were analyzed by Real-Time PCR and Western Blot assays. The results showed that the expressions of <em>FGF1</em>(fibroblast growth factor 1), <em>IL1B</em> (interleukin 1-beta), <em>VEGFR-2</em>(type 2 vascular-endothelial growth factor receptor), and <em>TGFB1</em> (tumor growth factor 1- beta) were significantly upregulated in melatonin treated groups compared to the control. In contrast, the expressions of <em>HIF-1A</em>(hypoxia-inducing factor 1-alpha), <em>FGF2</em> (fibroblastic growth factor 2), <em>IGF-1</em>(insulin-like growth factor 1), and <em>VEGFA</em> (vascular endothelial growth factor alpha) were significantly downregulated by melatonin compared to the control. The results suggest that melatonin modulates angiogenesis of granulosa cells from women with marital infertility. The underlining mechanism may relate to melatonin maintaining the homeostasis of VEGF, especially at a low dose of melatonin.&nbsp;</span></p> Carla C Maganhin Maria Candida P Baracat Camilla M Luquetti Daniella Buonfiglio Manoel João Girão José Cipolla-Neto Manuel J Simoes Ricardo S Simoes Edson Lo Turco Pedro Montelione Edmund C Baracat José Maria Soares-Jr ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2023-09-30 2023-09-30 7 2 296 312 10.32794/mr112500156 Why are aging and stress associated with dementia, cancer, and other diverse medical conditions? Role of pineal melatonin interactions with the HPA axis in mitochondrial regulation via BAG-1 https://melaonin-research.com/index.php/MR/article/view/239 <p>Pineal melatonin and the cortisol awakening response (CAR) are integral aspects of the circadian rhythm. Pineal melatonin release during sleep is proposed to optimize mitochondrial function and dampen any residual oxidant and inflammatory activity. Little is known about CAR, which is generally thought to prepare the body for the coming day, primarily through the activation of the glucocorticoid receptor (GR). Melatonin, like the gut microbiome-derived butyrate, suppresses GR nuclear translocation, indicating that pineal melatonin and night-time butyrate may interact to modulate CAR effects via the GR, including CAR priming of immune and glia cells that underpin the pathogenesis of most medical conditions. Cutting edge research shows that the GR can be chaperoned by bcl2-associated athanogene (BAG)-1 to mitochondria, where GR can have significant and diverse impacts on mitochondrial function. A number of lines of evidence indicate that melatonin indirectly increases BAG-1, including via epigenetic mechanisms, such as derepressing miR-138 inhibition of BAG-1. The dramatic decrease in pineal melatonin production over aging will therefore have significant impacts on GR nuclear translocation, but also possibly the levels of BAG-1 mediated mitochondrial translocation of the GR. This may have dramatic consequences for how CAR ‘prepares the body for the coming day’, via the differential consequence of GR location in the cytoplasm, nucleus or mitochondria, with differential effects in different cell types. The interactions of melatonin/butyrate/BAG-1/GR are especially important in the hypothalamus, where a maintained heightened melatonin concentration occurs over the night due to the direct release of pineal melatonin, via the pineal recess, into the third ventricle. The interaction of melatonin/butyrate/BAG-1/GR will have differential effects in different cell types, thereby altering the intercellular homeostatic interactions in a given microenvironment that will contribute to the pathogenesis of many aging-associated conditions, including neurodegenerative conditions and cancer. This reframes the nature of the circadian rhythm as well as how stress-associated hypothalamus-pituitary-adrenal (HPA) axis may modulate both the pathogenesis and course of diverse medical presentations. This has a number of research and treatment implications across a host of current medical conditions. &nbsp;</p><p><br/></p> George Anderson ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2023-09-30 2023-09-30 7 2 345 371 10.32794/mr112500158 The preventive and protective role of melatonin in SARS-CoV-2 infection: a retrospective study https://melaonin-research.com/index.php/MR/article/view/236 <p style="line-height: normal; text-align: justify;"><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif">This study has investigated the protective role of melatonin against SARS-CoV-2 infection. For this purpose, 62 adults were recruited who were in &nbsp;daily relatively high doses of melatonin intaking, with the particularity that they started taking it before the beginning of the COVID-19 pandemic and&nbsp; continued to present. A continuous validation process has been carried out with a series of questionnaires to identify the risk factors, whether they were contacts, were infected, if yes, the level of disease severity, need for treatment, hospitalization, etc. According to the dose of melatonin the individuals took/are taking, they were divided into two groups: a) those taking 20 mg (n = 27) and, b) those taking ≥ 40 mg (n = 32). For statistical analysis, the shi2 test and Fisher&#39;s exact test were used. The number of infected subjects with positive PCR was 7 (11.9%). Only one required medication, the rest had a very favorable clinical evolution, mild in three cases and asymptomatic in three others. While in their environment this percentage is 22.05% (chi2 = 2.928; p &lt; 0.087). Melatonin offers a good safety profile, is well tolerated and can play an important role in the different levels of COVID-19 prevention.</span></p><p><br/></p> Antonio Molina-Carballo Antonio Emilio Jerez-Calero Luisa Fernández-López María del Carmen Augustin-Morales Antonio Muñoz-Hoyos Ahmad Agil ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2023-09-30 2023-09-30 7 2 372 396 10.32794/mr112500159 The cardioprotective potential of melatonin on cardiac hypertrophy: A mechanistic overview https://melaonin-research.com/index.php/MR/article/view/230 <p style=";text-align:justify;text-justify: inter-ideograph;line-height:normal"><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif">Cardiac hypertrophy (CH) is an increment of muscle mass to maintain the heart regular operations. A physiological cardiac hypertrophy due to exercise or other normal physiological process is characterized by normal contractile function and structural framework of heart tissue. In contrast, pathological hypertrophy occurs in response to increased pressure or volume overload from several cardiovascular diseases including hypertension, valvular diseases, cardiac infarction and heart failure. It is of major concern as it is one of the leading causes of death worldwide. Despite much progress in this field there is a scope for understanding of the molecular mechanisms of this condition. In this review, various types of cardiac hypertrophy and their intricate physio-pathological mechanisms have been discussed. In addition, the genetic mutations in sarcomere genes and oxidative stress are also closely linked to hypertrophic cardiomyopathy. Although several drugs against cardiac hypertrophy have been used, it appears that melatonin, due to its high bioavailability and low side effects, is a better candidate than the conventional medicine for treatment of hypertrophic cardiomyopathy. Melatonin, a hormone and a potent antioxidant, is secreted mainly from the pineal gland, but it is also synthesized from different peripheral tissues including the heart. This molecule can regulate a myriad of cellular functions.&nbsp; It can protect against cardiac hypertrophy via reducing oxidative stress, elevating Cu-Mn SOD via controlling several cell signalling pathways of Akt/mTOR, ROR-α and NLRP3 cascades. Melatonin also mitigates cardiac hypertrophy by suppressing pro-inflammatory cytokines including TNF-α and TGF-β and cardiac hypertrophy markers like β-MHC, ANP, BNP, LDH. This review focuses on the molecular mechanisms of cardiac hypertrophy and the defensive role of melatonin on it. We propose melatoninas a propitious adjunct for the treatment of cardiac hypertrophy.</span></p><p><br/></p> Razia Khatoon Swaimanti Sarkar Aindrila Chattopadhyay Debasish Bandyopadhyay ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2023-09-30 2023-09-30 7 2 313 344 10.32794/mr112500157 An insight into the importance of B vitamins and melatonin in the prevention of diabetes through modulation of the brain energy metabolism- a comprehensive review https://melaonin-research.com/index.php/MR/article/view/229 <p><span style="font-size:16px;line-height: 107%;font-family:&#39;Times New Roman&#39;,serif">Energy metabolism is the biochemical pathway of converting macronutrients (carbohydrates, protein, and fat) to cellular energy for the maintenance of cell homeostasis. The brain is an organ that consumes unproportional energy compared to its size. Glucose (glycogen, in storage form of glucose) is the principal source of brain energy. Impairment in brain energy metabolism results in neuronal loss and subsequent neurodegenerative diseases including AD, PD, amyotrophic lateral sclerosis, Huntington’s disease, etc. However, metabolic disorders such as chronic hyperglycemia, and insulin resistance are also linked with neuronal activity. Dysregulation in neuronal transmission is associated with oxidative stress and brain insulin resistance. Diabetes <em>mellitus </em>jeopardizes<em> </em>brain function through various mechanisms including glucose toxicity, BBB damage, neuroinflammation, and gliosis. B vitamins as antioxidants and neuroprotective agents, can improve brain glucose metabolism. Melatonin is a potent free radical scavenger and it can also modulate cellular cytokine levels and prevent insulin resistance. The neuroprotective and antihyperglycemic effects of melatonin improve the brain&#39;s antioxidant defense system, decrease brain NOS activity, and prevent glucose toxicity. Hence this review suggests a therapeutic use of a combination of melatonin and&nbsp; B vitamins to improve brain functioning disrupted by diabetes.&nbsp;</span></p> Manisha Mukhopadhyay Priyanka Ghosh Aindrila Chattopadhyay Debasish Bandyopadhyay ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2023-09-30 2023-09-30 7 2 397 430 10.32794/mr112500160 Effects of melatonin on the circadian functions of sleep-wake cycle, metabolism, hormonal regulation and immune activity: A recent review https://melaonin-research.com/index.php/MR/article/view/223 <p style=";text-align:justify;text-justify: inter-ideograph;line-height:normal"><span style="font-size:16px;font-family: &#39;Times New Roman&#39;,serif">Rhythms following a period of approximately 24 hours are called circadian (from Latin circa diem, approximately one day) rhythms. These rhythms are observed in the activities of various vital body functions. Melatonin is considered as an important molecule participating in the formation of circadian rhythms of virtually all organisms. As a molecular regulator of the circadian clock, melatonin has various regulatory functions in both physiological and pathological conditions. Sleep-wake cycle depends on CSF melatonin levels, and melatonin also has a protective effect on the disrupted sleep-wake cycle in various pathological conditions. Melatonin ensures the proper function of vital metabolic pathways; therefore, it improves metabolism-related systems and protects them from damage. A bidirectional relationship between hormonal activity and melatonin ensures it having a healing effect on various reproductive disorders. Finally, melatonin can target inflammation pathways and various elements of immune system by changing their behavior and structure. In summary, melatonin has important effects on vital body functions mediated by its receptors, signaling pathways and clock genes, and has the capacity to protect and improve these functions under pathological conditions.</span></p><p><br/></p> Bugra Sarisozen Feyza Sule Aslan Enes Akyuz ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2023-08-31 2023-08-31 7 2 256 276 10.32794/mr112500154 Tryptophan decarboxylase (TDC) in sweet pepper (Capsicum annuum L.): Gene expression analysis during fruit ripening and after nitric oxide exposure https://melaonin-research.com/index.php/MR/article/view/238 <p style=";text-align:justify;text-justify:inter-ideograph"><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif;color:windowtext;font-weight:normal">Tryptophan decarboxylase (TDC) catalyzes the conversion of L-tryptophan (Trp) to tryptamine, a first step in the biosynthesis of serotonin and melatonin in plants. Pepper (<em>Capsicum annuum</em> L.) fruit, a globally popular horticultural product has great nutritional and economic values. In addition to that pepper fruit undergoes phenotypical changes during ripening, many other alterations also occur at the transcriptomic, proteomic, biochemical, and metabolic levels. However, little information is known on how many genes encoding for TDC in pepper plants and their expression levels during the ripening of sweet pepper fruit. In the current study, based on a data-mining approach on the pepper genome and transcriptome (RNA-seq), five putative <em>CaTDC</em> genes were identified. They are designated as 1 to 5 based on their localizations in chromosomes and also their previous biochemical data. Among them, <em>CaTDC3</em> and <em>CaTDC4</em> encode proteins with tryptophan decarboxylase activity; however, <em>CaTDC1</em>, <em>CaTDC2</em> and <em>CaTDC5</em> encode either tyrosine decarboxylase (TYDC) or aromatic aldehyde synthase (AAS), although CaTDC5 shares some degree TDC homology. Therefore, they are considered as the putative CaTDCs until their activity is corroborated. The <em>CaTDC4</em> and putative <em>CaTDC5</em> are expressed in pepper fruit. The time-course analysis of these genes during fruit ripening (green immature, breaking point, and red ripe) showed that they were differentially expressed, i.e., <em>CaTDC4</em> was upregulated, and putative<em> CaTDC5</em> was downregulated. <em>CaTDC4</em> was positively modulated by two light-responsive elements, Box4 and TCT-motif, while <em>CaTDC5</em> was influenced by GT1-motif and G-Box. The protein sequence analysis also allowed identifying the Trp-substrate-binding pocket which is a characteristic of the TDC proteins. Exogenous NO (a signaling molecule) treatment triggered the downregulation of <em>CaTDC4</em> but not putative<em> CaTDC5</em>. These data provide a novel insight on the potential functions involved in the secondary metabolism of TDCs in fleshy fruits. In the identified three new <em>CaTDC</em> genes, two (<em>CaTDC4 </em>and<em> CaTDC5</em>) expressed in pepper fruits are modulated by exogenous NO treatment during ripening.</span></p><p>&nbsp;</p><p><br/></p> Jorge Taboada Salvador González-Gordo José M Palma Francisco J Corpas ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2023-08-31 2023-08-31 7 2 277 295 10.32794/mr112500155 Inflammation, oxidative stress, DNA damage response and epigenetic modifications interact behind the beneficial actions of melatonin on H. pylori-mediated gastric disorders https://melaonin-research.com/index.php/MR/article/view/218 <p style=";text-align:justify;text-justify: inter-ideograph;line-height:normal"><em><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif">Helicobacter pylori </span></em><span style="font-size:16px;font-family:&#39;Times New Roman&#39;,serif">(<em>H. pylori</em>) infection<em> </em>is associated with several disorders of the gastrointestinal tract, including gastric cancer. Studies of ours and others suggest that <em>H. pylori</em> infection may affect melatonin synthesis in the gastric epithelial cells. On the other hand, melatonin ameliorates gastric disorders as shown in clinical trials and experimental studies. Moreover, melatonin not only suppresses the DNA-damaging reaction of diet-related mutagens that can initiate carcinogenesis in gastric mucosa, but also the oxidative DNA damage evoked by reactive oxygen and nitrogen species produced during <em>H. pylori-</em>related<em> </em>gastric inflammation. <em>H. pylori</em> infection is associated with several functional and organic gastric disorders, including gastritis, peptic ulcer disease and gastric cancer, but the precise mechanism behind this association is not known and many pathways can be involved. Some of beneficial effects of melatonin in the gastrointestinal tract are underlined by mechanisms that likely play a role in detrimental effects of <em>H. pylori</em> in the stomach. Therefore, melatonin may modulate these mechanisms resulting in ameliorating <em>H. pylori-</em>related symptoms. In this narrative review the role of inflammation, oxidative stress, DNA damage response and epigenetic modifications in <em>H. pylori­-</em>associated gastric disorders will be discussed with an emphasis on gastric cancer. We also suggest that melatonin may have potential to inhibit <em>H. pylori-</em>mediated pathologies through its interaction with essential pathways as described herein. Overlapping mechanisms of <em>H. pylori-</em>associated pathogenesis and beneficial effects of melatonin justify further studies on the action of melatonin on gastric disorders associated with <em>H. pylori </em>infection, including clinical trials. <em>&nbsp;</em></span></p><p style=";text-align:justify;text-justify: inter-ideograph;line-height:normal"><span style="font-size:16px;font-family: &#39;Times New Roman&#39;,serif">&nbsp;</span></p><p><br/></p> Janusz Blasiak Jan Chojnacki Cezary Chojnacki ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2023-06-30 2023-06-30 7 2 135 147 10.32794/mr112500145 Effect of iron on rat serum melatonin levels under different light/dark cycle patterns https://melaonin-research.com/index.php/MR/article/view/221 <p style=";text-align:justify;text-justify:inter-ideograph;background:#F7F7F8"><span style="color:black">Exposure to constant light or darkness for long periods has diverse effects on circadian physiology. Iron (Fe) overloading promotes oxidative stress and causes alterations in cellular structure and function in animals and humans. The aim of this study is to evaluate the interactions among serum melatonin (ML), photoperiod manipulation, and Fe overloading in rats. The results showed that constant darkness exposure for 15 days significantly increased serum ML levels (up to 22%) while the constant light exposure failed to reduce the serum ML level compared to the normal light/dark cycle treated rats. The lost serum ML level usually from the pineal gland under the long term of constant light exposure may be compensated by ML generated by other organs which adapted to the situation. Also, Fe overloading decreased ML production due to this molecule being consumed to scavenge the free radicals induced by the Fe overloading. In addition, we observed interactions among constant light or darkness exposure, Fe overloading and serum ML level. Overall, our results support the hypothesis of ML as scavenging molecule; it may be an effective therapeutic tool in iron-induced oxidative stress.</span></p><p><br/></p> Joaquín Xavier Cogo Pagella Marcelo P Hernando Claudio Osvaldo Cervino ##submission.copyrightStatement## http://creativecommons.org/licenses/by/4.0 2023-06-30 2023-06-30 7 2 148 160 10.32794/mr112500146