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Melatonin: Roles in influenza, Covid-19, and other viral infections.
Anderson, G, Reiter, RJ
Reviews in medical virology. 2020;30(3):e2109
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Viruses like influenza and coronaviruses change quickly, making it challenging to develop effective treatments and vaccines in a short time frame. Consequently, the use of generic substances that limit viral effects are of high interest. In this paper, the authors summarize a range of mechanisms in which melatonin can alter the impact of virus infections and infection-associated inflammatory overdrive aka cytokine storm. Melatonin, the sleep hormone, is well known for its potent antioxidant and anti-inflammatory action. It seems highly likely that melatonin can modulate the cellular function of all cells, mostly via mitochondrial function. This is particularly relevant in immune cells. For example, the daytime variance in immune function seems to be closely linked with mitochondrial activity and energy production. Other relevant mechanisms described are the antiviral role of melatonin-induced sirtuins - proteins that regulate cellular health-, the impact of viruses on cell coordinating microRNA, the role of the gut microbiome and gut permeability, as well as sympathetic nervous system activation and the protective effects of parasympathetic activation. Also considered are pre-existing health conditions and conditions that are linked with a decline in melatonin along with ageing, all being groups in which severity of viral infections is felt. This paper may be of interest to those who like to explore in more depth the mechanisms behind melatonin and its ability to influence viral disease progression.
Abstract
There is a growing appreciation that the regulation of the melatonergic pathways, both pineal and systemic, may be an important aspect in how viruses drive the cellular changes that underpin their control of cellular function. We review the melatonergic pathway role in viral infections, emphasizing influenza and covid-19 infections. Viral, or preexistent, suppression of pineal melatonin disinhibits neutrophil attraction, thereby contributing to an initial "cytokine storm", as well as the regulation of other immune cells. Melatonin induces the circadian gene, Bmal1, which disinhibits the pyruvate dehydrogenase complex (PDC), countering viral inhibition of Bmal1/PDC. PDC drives mitochondrial conversion of pyruvate to acetyl-coenzyme A (acetyl-CoA), thereby increasing the tricarboxylic acid cycle, oxidative phosphorylation, and ATP production. Pineal melatonin suppression attenuates this, preventing the circadian "resetting" of mitochondrial metabolism. This is especially relevant in immune cells, where shifting metabolism from glycolytic to oxidative phosphorylation, switches cells from reactive to quiescent phenotypes. Acetyl-CoA is a necessary cosubstrate for arylalkylamine N-acetyltransferase, providing an acetyl group to serotonin, and thereby initiating the melatonergic pathway. Consequently, pineal melatonin regulates mitochondrial melatonin and immune cell phenotype. Virus- and cytokine-storm-driven control of the pineal and mitochondrial melatonergic pathway therefore regulates immune responses. Virus-and cytokine storm-driven changes also increase gut permeability and dysbiosis, thereby suppressing levels of the short-chain fatty acid, butyrate, and increasing circulating lipopolysaccharide (LPS). The alterations in butyrate and LPS can promote viral replication and host symptom severity via impacts on the melatonergic pathway. Focussing on immune regulators has treatment implications for covid-19 and other viral infections.
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The Functional Medicine Approach to COVID-19: Nutrition and Lifestyle Practices for Strengthening Host Defense.
Minich, DM, Hanaway, PJ
Integrative medicine (Encinitas, Calif.). 2020;19(Suppl 1):54-62
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Lifestyle interventions can be an effective means to help patients regain their locus of control during times of uncertainty like those experienced in a pandemic. The study is a review about emerging research focusing on nutrition and lifestyle practices for strengthening host defense. Research indicates that there are three mechanisms that may be involved in the ability of food-derived compounds to reduce viral infection and severity: a. balancing inflammatory pathways, b. reducing oxidative stress and increasing antioxidant levels, and c. harmonizing the gut microbiome. Clinical recommendations focus mainly on nutrition, stress reduction/management, sleep quality and quantity, physical activity programme and social factors/connections. Authors conclude by emphasising that the findings of this study are only intended to identify lifestyle practices that may boost the immune system as they have not been proven effective against COVID-19.
Abstract
The developing symptoms of COVID-19, as well as the progression of illness and fatality, are a clearly a function of the overall health status of the individual. Complex, chronic diseases such as obesity, hypertension, and diabetes are directly correlated with risk of disease severity and mortality. We explore lifestyle interventions that have specifically been demonstrated to strengthen host defense, reduce the probability and mitigate the severity of viral infection. Lifestyle interventions, from a Functional Medicine perspective, include nutrition, sleep, exercise, stress reduction, and connection. These factors, when in balance, provide a foundation for optimal health and immune function.
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The Sleep-Immune Crosstalk in Health and Disease.
Besedovsky, L, Lange, T, Haack, M
Physiological reviews. 2019;99(3):1325-1380
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The interaction between sleep and immunity is an established phenomena. This thorough review article summarises sleep changes in response to both infectious and non-infectious immune system challenges and describes the role of sleep in supporting the immune system. Details are provided of how sleep affects the innate immune system (first line, rapid defence against infection) as well as the adaptive immune system (second line, delayed defence against infection), using a feedback system which promotes host defence. Sleep is associated with reduced infection risk and can improve infection outcome and vaccination responses. Sleep deprivation is also associated with chronic, low-grade inflammation. Nutrition Practitioners wishing to support immunity can focus on sleep as a simple lifestyle measure to enhance resilience.
Abstract
Sleep and immunity are bidirectionally linked. Immune system activation alters sleep, and sleep in turn affects the innate and adaptive arm of our body's defense system. Stimulation of the immune system by microbial challenges triggers an inflammatory response, which, depending on its magnitude and time course, can induce an increase in sleep duration and intensity, but also a disruption of sleep. Enhancement of sleep during an infection is assumed to feedback to the immune system to promote host defense. Indeed, sleep affects various immune parameters, is associated with a reduced infection risk, and can improve infection outcome and vaccination responses. The induction of a hormonal constellation that supports immune functions is one likely mechanism underlying the immune-supporting effects of sleep. In the absence of an infectious challenge, sleep appears to promote inflammatory homeostasis through effects on several inflammatory mediators, such as cytokines. This notion is supported by findings that prolonged sleep deficiency (e.g., short sleep duration, sleep disturbance) can lead to chronic, systemic low-grade inflammation and is associated with various diseases that have an inflammatory component, like diabetes, atherosclerosis, and neurodegeneration. Here, we review available data on this regulatory sleep-immune crosstalk, point out methodological challenges, and suggest questions open for future research.
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Shared Dysregulation of Homeostatic Brain-Body Pathways in Depression and Type 2 Diabetes.
Hoogendoorn, CJ, Roy, JF, Gonzalez, JS
Current diabetes reports. 2017;17(10):90
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Depression and type 2 diabetes (T2D) appear to have a bidirectional relationship, with the two diseases possibly being linked through emotional and biological changes. This review paper aimed to discuss this bidirectional relationship and in particular the biological changes that may be involved. The authors started by stating that two biological systems may be influenced in depression and T2D, the hypothalamic-pituitary-adrenal axis (HPA), which is responsible for many systems in the body involved in the stress response and emotional and physical health. The second is the brain-gut-microbiome axis (BGM), which is related to the microorganisms in the gut and how they communicate with the brain. The immune system, sleep and blood sugar balance may be influenced by the HPA and BGM and are all dysregulated in both depression and T2D indicating a link between the two diseases. However causal relationships need further research. Dietary and lifestyle changes may be of benefit in these individuals. It was concluded that the disruption of shared biological systems in T2D and depression may be an important target for treatments, however further research is warranted. This study could be used by healthcare practitioners to understand the relationship between T2D and depression and the potential therapeutic areas to target. However, although research is optimistic, it is still in its infancy.
Abstract
PURPOSE OF REVIEW The purpose of this review is to provide an overview of shared dysregulation of the hypothalamic-pituitary-adrenal (HPA) and brain-gut-microbiome (BGM) axes associated with depression and type 2 diabetes (T2D). Clinical implications and future research are also discussed. RECENT FINDINGS Both depression and T2D are associated with dysregulation of the HPA and BGM axes. These pathways regulate immune function, glucose metabolism, and sleep, which are altered in both illnesses. Dysregulation of homeostatic brain-body pathways may be positively influenced through different therapeutic actions, including psychotherapy, healthy eating, physical activity, sleep promotion, and certain anti-inflammatory or antidepressant medications. While the causal nature of the relationship between depression and T2D remains unclear, these conditions share dysregulation of homeostatic brain-body pathways that are central to mental and physical health. Better understanding of this dysregulation may provide opportunities for interventions that could benefit both conditions. Future research should examine the additive burden of depression and T2D on HPA and BGM dysregulation and better differentiate depression from emotional distress.
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The microbiome: A key regulator of stress and neuroinflammation.
Rea, K, Dinan, TG, Cryan, JF
Neurobiology of stress. 2016;4:23-33
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This study discusses the concept of intestinal microbiota as the key regulator involved in energy regulation, gut barrier function, protection from pathogens, and immune system function amongst others. The gut microbiota is the complex community of microorganisms that lives in the digestive tracts of humans. The main aim of this study is to summarise the role of gastrointestinal microbiota in fundamental physiological and pathophysiological processes and thereafter to understand and treat a range of stress and immune-related disorders. This review outlines the numerous complex relationships between gastrointestinal microbiota, stress and immune responses at the three critical stages of life The authors concluded that the evidence from this study suggests that resilience to stress and immune-related disorders and dysfunction of stress and immune systems may be dependent on the diversity and complexity of gastrointestinal microbiota. However, gut microbiota mediated relationship to stress and neuro-inflammation is still unconfirmed as previous studies mostly, have largely been, preclinical and further studies are warranted.
Abstract
There is a growing emphasis on the relationship between the complexity and diversity of the microorganisms that inhabit our gut (human gastrointestinal microbiota) and health/disease, including brain health and disorders of the central nervous system. The microbiota-gut-brain axis is a dynamic matrix of tissues and organs including the brain, glands, gut, immune cells and gastrointestinal microbiota that communicate in a complex multidirectional manner to maintain homeostasis. Changes in this environment can lead to a broad spectrum of physiological and behavioural effects including hypothalamic-pituitary-adrenal (HPA) axis activation, and altered activity of neurotransmitter systems and immune function. While an appropriate, co-ordinated physiological response, such as an immune or stress response are necessary for survival, a dysfunctional response can be detrimental to the host contributing to the development of a number of CNS disorders. In this review, the involvement of the gastrointestinal microbiota in stress-mediated and immune-mediated modulation of neuroendocrine, immune and neurotransmitter systems and the consequential behaviour is considered. We also focus on the mechanisms by which commensal gut microbiota can regulate neuroinflammation and further aim to exploit our understanding of their role in stress-related disorders as a consequence of neuroinflammatory processes.