Chronic stress and corticosterone exacerbate alcohol-induced tissue injury in the gut-liver-brain axis (original) (raw)
Related papers
Alcohol, inflammation, and gut-liver-brain interactions in tissue damage and disease development
World Journal of Gastroenterology, 2010
Chronic inflammation is often associated with alcoholrelated medical conditions. The key inducer of such inflammation, and also the best understood, is gut microflora-derived lipopolysaccharide (LPS). Alcohol can significantly increase the translocation of LPS from the gut. In healthy individuals, the adverse effects of LPS are kept in check by the actions and interactions of multiple organs. The liver plays a central role in detoxifying LPS and producing a balanced cytokine milieu. The central nervous system contributes to anti-inflammatory regulation through neuroimmunoendocrine actions. Chronic alcohol use impairs not only gut and liver functions, but also multi-organ interactions, leading to persistent systemic inflammation and ultimately, to organ damage. The study of these interactions may provide potential new targets for therapeutic intervention.
Alcoholism: Clinical and Experimental Research, 2001
Background: Endotoxin has been proposed to play a primary role in ALD, by initiating an inflammatory cascade within the liver. Although the source of these cytokines has been presumed to be circulating monocytes or tissue macrophages, ethanol-induced, nonhepatic sources of soluble mediators recently have been identified. One potential, but not clearly defined, extrahepatic source of cytokines in ALD is the intestine. In the current study, we hypothesized that alcohol would alter cytokine expression within the small intestine of mice exposed to ethanol and that LPS would alter levels of cytokine expression even more dramatically. Methods: Mice were fed a modified Lieber-DeCarli liquid ethanol or control diet for up to 14 days prior to injecting either saline or LPS. Plasma alanine aminotransferase (ALT) and cytokine levels, histology, and RT-PCR of pro-and anti-inflammatory cytokine gene expression were determined from distal ileum and liver samples. Translocation of intestinal bacterial flora also was assessed. Results: Ethanol exposure upregulated basal gene expression of IL-1, TNF-␣, IL-6, and iNOS in the distal ileum, but similar effects of ethanol on the liver were not observed. In contrast, LPS challenge of ethanol-exposed mice increased intestinal gene expression of some cytokines, but decreased expression of others. These effects were not associated with bacterial translocation. Also, ethanol alone induced a modest increase in both ICAM-1 and TLR4 mRNA expression in the intestine, but expression of both molecules was inhibited in mice that received both ethanol and LPS. Finally, whereas basal levels of hepatic IL-11 mRNA were not elevated by exposure to ethanol, intestinal IL-11 mRNA levels were increased more than100-fold. Conclusions: These studies are the first to show that ethanol affects cytokine gene expression in the ileum and identifies the ileum as a potential target for ethanol effects. In addition, our results suggest that IL-11 expression may be enhanced in the intestine to help repair or protect this organ from alcohol-induced damage. Collectively, these studies suggest that both pro-and anti-inflammatory soluble mediators in the intestine maintain and exacerbate the local hepatic response to ethanol.
Alcohol and Gut-Derived Inflammation
Alcohol research : current reviews, 2017
In large amounts, alcohol and its metabolites can overwhelm the gastrointestinal tract (GI) and liver and lead to damage both within the GI and in other organs. Specifically, alcohol and its metabolites promote intestinal inflammation through multiple pathways. That inflammatory response, in turn, exacerbates alcohol-induced organ damage, creating a vicious cycle and leading to additional deleterious effects of alcohol both locally and systemically. This review summarizes the mechanisms by which chronic alcohol intake leads to intestinal inflammation, including altering intestinal microbiota composition and function, increasing the permeability of the intestinal lining, and affecting the intestinal immune homeostasis. Understanding the mechanisms of alcohol-induced intestinal inflammation can aid in the discovery of therapeutic approaches to mitigate alcohol-induced organ dysfunctions.
International Immunopharmacology, 2011
Background: Acute ethanol administration just prior to a stimulus, such as the viral mimic poly I:C, results in decreased proinflammatory cytokine production. Studies have indicated that this suppression is not primarily mediated by glucocorticoids (corticosterone in mice) released in the ethanol-induced stress response. Fewer studies have been done on the effects of acute ethanol administration 12 or more hours prior to a stimulus. The purpose of this study was to determine the role of corticosterone on these effects. Also, since gender differences occur in immune responses, separate experiments were performed using male and female mice. Methods: Mice were treated with ethanol 15 min or 12 h before stimulation by poly I:C to demonstrate immunosuppressive effects of ethanol on cytokine production. A glucocorticoid synthesis inhibitor was used to manipulate corticosterone levels. Results: Short-term and persistent effects of acute ethanol exposure on corticosterone and cytokine levels were nearly identical in males and females. Blocking glucocorticoid synthesis altered the inhibition of some cytokines, particularly IL-6, in females, but not in males. Conclusion: These results indicate that the short-term effects of acute ethanol on poly I:C-induced cytokine production are not primarily mediated by corticosterone in male or female mice. In female mice, however, corticosterone does appear to mediate the persistent effects of acute ethanol administration on poly I:C-induced IL-6 levels. Since many IL-6 related disorders are gender associated, further research into the bidirectional effects of the HPG and HPA axes on alterations in cytokine production mediated by ethanol is warranted.
Neuroimmune consequences of chronic alcohol exposure: relationship to stress
Alcoholism is characterized by tolerance to alcohol, withdrawal signs or symptoms, and continued use despite detrimental physical or psychological consequences. Studies have illustrated the deleterious effects of prolonged and excessive alcohol use extend to many organs including the liver, lungs, stomach, and brain. While the brain represents the most important organ in the development and maintenance of alcoholism, the neurobiological mechanisms underlying its role are not sufficiently understood to permit effective and timely intervention. Recent work has demonstrated that alcohol-associated changes in neuroimmune function may contribute to the progression of alcoholism. To better understand the role of alcohol in neuroimmune system dysregulation, changes in cytokine expression were determined after alcohol exposure in rats. While acute alcohol administration did not increase proinflammatory cytokines measured in the cerebral cortex, chronic alcohol administration produced a robu...
Brain, behavior, and immunity, 2012
Mood and cognition alterations play a role in the motivation for alcohol-drinking. Lipopolysaccharides are known to stimulate inflammation that was shown to induce mood and cognitive changes in rodents and humans. Enhanced intestinal permeability and elevated blood LPS characterize alcohol-dependent mice. However, no data have been published in non-cirrhotic humans. Our first goal was to test whether intestinal permeability, blood LPS and cytokines are increased in non-cirrhotic alcohol-dependent subjects before withdrawal and if they recover after withdrawal. Our second goal was to test correlations between these biochemical and the behavioral variables to explore the possibility of a role for a gut-brain interaction in the development of alcohol-dependence. Forty alcohol-dependent-subjects hospitalized for a 3-week detoxification program were tested at onset (T1) and end (T2) of withdrawal and compared for biological and behavioral markers with 16 healthy subjects. Participants we...
The Journal of Nutritional Biochemistry, 2016
Previous in vitro studies showed that glutamine (Gln) prevents acetaldehyde-induced disruption of tight junctions and adherens junctions in Caco-2 cell monolayers and human colonic mucosa. In the present study, we evaluated the effect of Gln supplementation on ethanol-induced gut barrier dysfunction and liver injury in mice in vivo. Ethanol feeding caused a significant increase in inulin permeability in distal colon. Elevated permeability was associated with a redistribution of tight junction and adherens junction proteins and depletion of detergent-insoluble fractions of these proteins, suggesting that ethanol disrupts apical junctional complexes in colonic epithelium and increases paracellular permeability. Ethanol-induced increase in colonic mucosal permeability and disruption of junctional complexes were most severe in mice fed Gln-free diet. Gln supplementation attenuated ethanol-induced mucosal permeability and disruption of tight junctions and adherens junctions in a dose-dependent manner, indicating the potential role of glutamine in nutritional intervention to alcoholic tissue injury. Gln supplementation dosedependently elevated reduced-protein thiols in colon without affecting the level of oxidizedprotein thiols. Ethanol feeding depleted reduced protein thiols and elevated oxidized protein thiols. Ethanol-induced protein thiol oxidation was most severe in mice fed Gln-free diet and absent in mice fed Gln-supplemented diet, suggesting that antioxidant effect is one of the likely mechanisms involved in Gln-mediated amelioration of ethanol-induced gut barrier dysfunction. Ethanol feeding elevated plasma transaminase and liver triglyceride, which was accompanied by histopathologic lesions in the liver; ethanol-induced liver damage was attenuated by Gln supplementation. These results indicate that Gln supplementation ameliorates alcohol-induced gut and liver injury.
Immunity & Ageing
Background There are currently > 600 million people over the age of 65 globally and this number is expected to double by the year 2050. Alcohol use among this population is on the rise, which is concerning as aging is associated with increased risk for a number of chronic illnesses. As most studies investigating the effects of alcohol have focused on young/middle-aged populations, there is a dearth of information regarding the consequences of alcohol use in older consumers. In addition, most murine ethanol models have concentrated on exposure to very high levels of ethanol, while the vast majority of elderly drinkers do not consume alcohol in excess; instead, they drink on average 2 alcoholic beverages a day, 3–4 days a week. Methods We designed a murine model of aging and moderate ethanol consumption to determine if the deleterious effects of alcohol on the gut-liver axis are exacerbated in aged, relative to younger, animals. Aged and young mice were exposed to a multi-day moder...
Alcoholism: Clinical and Experimental Research, 2009
Background-Alcoholic liver disease (ALD) requires endotoxemia and is commonly associated with intestinal barrier leakiness. Using monolayers of intestinal epithelial cells as an in vitro barrier model, we showed that ethanol-induced intestinal barrier disruption is mediated by iNOS (inducible nitric-oxide synthase) upregulation, NO (nitric oxide) overproduction, and oxidation/ nitration of cytoskeletal proteins. We hypothesized that iNOS inhibitors (L-NAME, L-NIL) in vivo will inhibit the above cascade and liver injury in an animal model of alcoholic steatohepatitis (ASH).