Advanced age is associated with chronic low-grade inflammation, which is usually referred to as inflammaging. Elderly are also known to have an altered gut microbiota composition. However, whether inflammaging is a cause or consequence of an altered gut microbiota composition is not clear. In this study, gut microbiota from young or old conventional mice was transferred to young germ-free (GF) mice. Four weeks after gut microbiota transfer immune cell populations in spleen, Peyer’s patches, and mesenteric lymph nodes from conventionalized GF mice were analyzed by flow cytometry. In addition, whole-genome gene expression in the ileum was analyzed by microarray. Gut microbiota composition of donor and recipient mice was analyzed with 16S rDNA sequencing. Here, we show by transferring aged microbiota to young GF mice that certain bacterial species within the aged microbiota promote inflammaging. This effect was associated with lower levels of Akkermansia and higher levels of TM7 bacteria and Proteobacteria in the aged microbiota after transfer. The aged microbiota promoted inflammation in the small intestine in the GF mice and enhanced leakage of inflammatory bacterial components into the circulation was observed. Moreover, the aged microbiota promoted increased T cell activation in the systemic compartment. In conclusion, these data indicate that the gut microbiota from old mice contributes to inflammaging after transfer to young GF mice.
Males and females are known to have gender-specific differences in their immune system and gut microbiota composition. Whether these differences in gut microbiota composition are a cause or consequence of differences in the immune system is not known. To investigate this issue, gut microbiota from conventional males or females was transferred to germ-free (GF) animals of the same or opposing gender. We demonstrate that microbiota-independent gender differences in immunity are already present in GF mice. In particular, type I interferon signaling was enhanced in the intestine of GF females. Presumably, due to these immune differences bacterial groups, such as Alistipes, Rikenella, and Porphyromonadaceae, known to expand in the absence of innate immune defense mechanism were overrepresented in the male microbiota. The presence of these bacterial groups was associated with induction of weight loss, inflammation, and DNA damage upon transfer of the male microbiota to female GF recipients. In summary, our data suggest that microbiota-independent gender differences in the immune system select a gender-specific gut microbiota composition, which in turn further contributes to gender differences in the immune system.
The gastrointestinal microbiota is emerging as a unique and inexhaustible source for metabolites with potential to modulate G-protein coupled receptors (GPCRs). The ghrelin receptor [growth hormone secretagogue receptor (GHSR)-1a] is a GPCR expressed throughout both the gut and the brain and plays a crucial role in maintaining energy balance, metabolism, and the central modulation of food intake, motivation, reward, and mood. To date, few studies have investigated the potential of the gastrointestinal microbiota and its metabolites to modulate GPCR signaling. Here we investigate the ability of short-chain fatty acids (SCFAs), lactate, and different bacterial strains, including Bifidobacterium and Lactobacillus genera, to modulate GHSR-1a signaling. We identify, for what is to our knowledge the first time, a potent effect of microbiota-derived metabolites on GHSR-1a signaling with potential significant consequences for host metabolism and physiology. We show that SCFAs, lactate, and bacterial supernatants are able to attenuate ghrelin-mediated signaling through the GHSR-1a. We suggest a novel route of communication between the gut microbiota and the host via modulation of GHSR-1a receptor signaling. Together, this highlights the emerging therapeutic potential in the exploration of the microbiota metabolome in the specific targeting of key GPCRs, with pleiotropic actions that span both the CNS and periphery.
The review summarizes the existent literature on this emerging research field and provides a comprehensive overview of the multifaceted links between the microbiota, diet, and depression. Several pathways linking early life trauma, pharmacological treatment effects, and nutrition to the microbiome in depression are described aiming to foster the psychotherapeutic treatment of depressed patients by interventions targeting the microbiota.
Highlights d C-section leads to changes in Bifidobacterium spp. abundance in early life d Mice born by C-section have behavioral deficits throughout their lifespan d Co-housing C-section-born mice with vaginally born mice corrects social deficits d B. breve or a dietary prebiotic mixture improves behavior in C-section mice
The neurotransmitter serotonin (5-HT) plays a vital regulatory role in both the brain and gut. 5-HT is crucial for regulating mood in the brain as well as gastrointestinal motility and secretion peripherally. Alterations in 5-HT transmission have been linked to pathological symptoms in both intestinal and psychiatric disorders and selective 5-HT transporter (5-HTT) inhibitors, affecting the 5-HT system by blocking the 5-HT transporter (5-HTT) have been successfully used to treat CNS- and intestinal disorders. Humans that carry the short allele of the 5-HTT-linked polymorphic region (5-HTTLPR) are more vulnerable to adverse environmental stressors, in particular early life stress. Although, early life stress has been shown to alter the composition of the gut microbiota, it is not known whether a lower 5-HTT expression is also associated with an altered microbiome composition. To investigate this, male and female wild type (5-HTT+/+), heterozygous (5-HTT+/-), and knockout (5-HTT-/-) 5-HT transporter rats were maternally separated for 6 h a day from postnatal day 2 till 15. On postnatal day 21, fecal samples were collected and the impact of 5-HTT genotype and maternal separation (MS) on the microbiome was analyzed using high-throughput sequencing of the bacterial 16S rRNA gene. MS showed a shift in the ratio between the two main bacterial phyla characterized by a decrease in Bacteroidetes and an increase in Firmicutes. Interestingly, the 5-HTT genotype caused a greater microbal dysbiosis (microbial imbalance) compared with MS. A significant difference in microbiota composition was found segregating 5-HTT-/- apart from 5-HTT+/- and 5-HTT+/+ rats. Moreover, exposure of rats with 5-HTT diminished expression to MS swayed the balance of their microbiota away from homeostasis to ‘inflammatory’ type microbiota characterized by higher abundance of members of the gut microbiome including Desulfovibrio, Mucispirillum, and Fusobacterium, all of which are previously reported to be associated with a state of intestinal inflammation, including inflammation associated with MS and brain disorders like multiple depressive disorders. Overall, our data show for the first time that altered expression of 5-HTT induces disruptions in male and female rat gut microbes and these 5-HTT genotype-related disruptions are augmented when combined with early life stress.
Background and AimsA ‘leaky’ gut barrier has been implicated in the initiation and progression of a multitude of diseases, e.g., inflammatory bowel disease, irritable bowel syndrome, celiac disease, and colorectal cancers. Here we asked how Chromogranin A (CgA), a major hormone produced by the enteroendocrine cells, and Catestatin (CST), the most abundant CgA-derived proteolytic peptide, affect the gut barrier.Methods and ResultsUltrastructural studies on the colons from Catestatin (CST: hCgA352-372) knockout (CST-KO) mice revealed (i) altered morphology of tight (TJ) and adherens (AJ) junctions and desmosomes, indicative of junctional stress and (ii) an increased infiltration of immune cells compared to controls. Flow cytometry studies confirmed these cells to be macrophages and CD4+ T cells. Gene expression studies confirmed that multiple TJ-markers were reduced, with concomitant compensatory elevation of AJ and desmosome markers. Consistently, the levels of plasma FITC-dextran were elevated in the CST-KO mice, confirming leakiness’ of the gut. Leaky gut in CST-KO mice correlated with inflammation and a higher ratio of Firmicutes to Bacteroidetes, a dysbiotic pattern commonly encountered in a multitude of diseases. Supplementation of CST-KO mice with recombinant CST reversed this leakiness and key phenotypes. Supplementation of CgA-KO mice with either CST alone, or with the pro-inflammatory proteolytic CgA fragment pancreastatin (PST: CgA250-301) showed that gut permeability is regulated by the antagonistic roles of these two peptide hormones: CST reduces and PST increases leakiness.ConclusionWe conclude that the enteroendocrine cell-derived hormone, CgA regulates gut permeability. CST is both necessary and sufficient to reduce the leakiness. CST acts primarily via antagonizing the effects of PST.What you need to knowBackground and ContextThe intestinal barrier is disrupted in many intestinal diseases such as Crohn’s disease. Chromogranin A (CgA) is produced by enteroendocrine cells in the gut. CgA is proteolytically cleaved into bioactive peptides including catestatin (CST) and pancreastatin (PST). The role of CgA in the gut is unknown.New findingsCgA is efficiently processed to CST in the gut and this processing might be decreased during active Crohn’s disease. CST promotes epithelial barrier function and reduces inflammation by counteracting PST.LimitationsThe complete mechanism of intestinal barrier regulation by CST likely involves a complex interplay between the enteroendocrine system, metabolism, the epithelium, the immune system and the gut microbiota.ImpactOur findings indicate that CST is a key modulator of the intestinal barrier and immune functions that correlates with disease severity of Crohn’s disease. CST could be a target for therapeutic interventions in Crohn’s disease.
Aim A “leaky” gut barrier has been implicated in the initiation and progression of a multitude of diseases, for example, inflammatory bowel disease (IBD), irritable bowel syndrome and celiac disease. Here we show how pro‐hormone Chromogranin A (CgA), produced by the enteroendocrine cells, and Catestatin (CST: hCgA352‐372), the most abundant CgA‐derived proteolytic peptide, affect the gut barrier. Methods Colon tissues from region‐specific CST‐knockout (CST‐KO) mice, CgA‐knockout (CgA‐KO) and WT mice were analysed by immunohistochemistry, western blot, ultrastructural and flowcytometry studies. FITC‐dextran assays were used to measure intestinal barrier function. Mice were supplemented with CST or CgA fragment pancreastatin (PST: CgA250‐301). The microbial composition of cecum was determined. CgA and CST levels were measured in blood of IBD patients. Results Plasma levels of CST were elevated in IBD patients. CST‐KO mice displayed (a) elongated tight, adherens junctions and desmosomes similar to IBD patients, (b) elevated expression of Claudin 2, and (c) gut inflammation. Plasma FITC‐dextran measurements showed increased intestinal paracellular permeability in the CST‐KO mice. This correlated with a higher ratio of Firmicutes to Bacteroidetes, a dysbiotic pattern commonly encountered in various diseases. Supplementation of CST‐KO mice with recombinant CST restored paracellular permeability and reversed inflammation, whereas CgA‐KO mice supplementation with CST and/or PST in CgA‐KO mice showed that intestinal paracellular permeability is regulated by the antagonistic roles of these two peptides: CST reduces and PST increases permeability. Conclusion The pro‐hormone CgA regulates the intestinal paracellular permeability. CST is both necessary and sufficient to reduce permeability and primarily acts by antagonizing PST.
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