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Serotonin Reuptake Inhibitors and the Gut Microbiome: Significance of the Gut Microbiome in Relation to Mechanism of Action, Treatment Response, Side Effects, and Tachyphylaxis.
Sjöstedt, P, Enander, J, Isung, J
Frontiers in psychiatry. 2021;12:682868
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In preceding centuries common thought was that psychiatric disorders originated from the gut. In later years this concept was replaced by the idea of it being a disorder of the brain and that an imbalance of neurotransmitters is the cause of depression and other psychiatric conditions (monoamine hypothesis). This theory has been dominating psychiatric research for the past decades, and selective serotonin reuptake inhibitors (SSRIs) have become a widespread treatment option for psychological disorders. Despite their benefits, their use also presents clinical challenges such as treatment resistance, side effects or loss of effect. Consequently, the monoamine hypothesis has become disputed with other pathophysiological mechanisms having been proposed in recent years. With an appreciation of the pathophysiological complexities, this opinion-based article sought to present alternate views and to suggest areas for future research regarding psychiatric disorders, SSRIs and the gut-brain axis. The gut-brain axis has complex communication and signalling pathways in essence, the gut microbiome can exert significant effects on emotions, behaviours, metabolic risks, and the metabolism of drugs. Nerve cells of the gut also generate substantial amounts of serotonin for use within the gut. Equally, the gut microbiome produces and uses serotonin. It appears that some of the side effects associated with SSRIs, such as weight gain, are mediated via the gut microbiome. Further evidence suggests that SSRIs and several other psychotropic drugs exert antimicrobial action, which can alter the balance and integrity of the gut microbiome. Therefore, it would be valuable to further investigate the impact of long-term SSRI use on the microbial constellation in the gut and whether certain microbiome patterns could help predict treatment responsiveness or side effects, that may be manageable via microbiome manipulation. The authors believe that an advanced understanding of the dynamics of the gut microbiome could provide better and personalized treatment options for mental health conditions. This article provides a brief insight into current thoughts and theories of psychiatric disorders, SSRIs and the gut.
Abstract
The monoamine hypothesis of psychopharmacology has been dominating the biological psychiatric research field for decades. Currently psychiatric research has increasingly appreciated psychiatric disorders and suicidal behavior as being highly complex and multi-etiological. In this pathway the gut microbiome and its interrelationship with the brain is gaining traction. The usage of selective serotonin reuptake inhibitors (SSRIs) is increasing in the general population. This is due to their effect on a broad range of psychiatric disorders, and their favorable side effect profile. Still, there are enigmatic aspects about SSRIs, such as the difficulty to predict effect in individual patients, inter-individual differences in side effect, tachyphylaxis (a sudden loss of response to a certain drug), and to date, uncertainties on how they exert their clinical effect. A majority of the serotonin in the human body is produced within the gut, and SSRIs affect enteric neurons. They also exhibit antimicrobial properties that comes with the potential of disrupting microbial hemostasis. We propose that the role of the gut-brain axis and the gut microbiome in relation to psychopharmacology should be more highlighted. With this article, together with similar articles, we would like to provide a hypothetical framework for future studies within this field. We believe that this would have the potential to provide a paradigm shift within the field of psychopharmacology, and result in findings that potentially could contribute to the development of a more personalized and tailored treatment.
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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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Gut dysbiosis: a potential link between increased cancer risk in ageing and inflammaging.
Biragyn, A, Ferrucci, L
The Lancet. Oncology. 2018;19(6):e295-e304
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This study looks at the important role our gut bacterial and commensal microbes play in supporting immunity and potentially reducing the risk of cancer from aging. Cancer risk increases as we age and is one of the main causes of reduced life expectancy. Our gut microbiome changes continually in response to diet, lifestyle, infection, and activation of immune responses. Gut dysbiosis is characterised by a shift towards proinflammatory commensals and a reduction of beneficial microbes, which can cause impairment and leakiness of the intestinal barrier. This is thought to trigger inflammaging or rather aging in a state of continual inflammation, where the immune system is in a heightened state of activation, and the body essentially creates an environment conducive to cancer. The gut is populated by trillions of species of bacteria which work together with our immune cells. As we age the diversity and density of these beneficial bacteria reduce. Therapies which support the balance of our commensal bacteria may prove effective at reducing rates of cancer in the elderly.
Abstract
Cancer incidence substantially increases with ageing in both men and women, although the reason for this increase is unknown. In this Series paper, we propose that age-associated changes in gut commensal microbes, otherwise known as the microbiota, facilitate cancer development and growth by compromising immune fitness. Ageing is associated with a reduction in the beneficial commensal microbes, which control the expansion of pathogenic commensals and maintain the integrity of the intestinal barrier through the production of mucus and lipid metabolites, such as short-chain fatty acids. Expansion of gut dysbiosis and leakage of microbial products contributes to the chronic proinflammatory state (inflammaging), which negatively affects the immune system and impairs the removal of mutant and senescent cells, thereby enabling tumour outgrowth. Studies in animal models and the importance of commensals in cancer immunotherapy suggest that this status can be reversible. Thus, interventions that alter the composition of the gut microbiota might reduce inflammaging and rejuvenate immune functions to provide anticancer benefits in frail elderly people.