Project description:Transplant recipients require lifelong, multimodal immunosuppression to prevent rejection by reducing alloreactive immunity. Rapamycin, a mechanistic target of rapamycin (mTOR) inhibitor, is known to modulate adaptive and innate immunity, while the full spectrum of its immunosuppressive mechanisms remains incompletely understood. Given the broad expression of mTOR, we investigated the understudied effects of rapamycin on lymph node (LN) architecture, leukocyte trafficking, and the gut microbiome and metabolism after 3, 7, and 30 days of rapamycin treatment, to characterize the early, intermediate, and late changes. Rapamycin significantly reduced CD4+ T cells, CD8+ T cells, and regulatory T (Treg) cells in peripheral LNs, mesenteric LNs, and the spleen over time. Rapamycin induced early pro-inflammation transition to pro-tolerogenic status, by modulating the LN laminin α4:α5 expression ratios (La4:La5) through LN stromal cells laminin α5 expression and by adjusting Treg numbers and distribution. Additionally, rapamycin significantly altered gut microbiota composition and metabolic functions, shifting the Bacteroides to Firmicutes ratio and increasing amino acid bioavailability in the gut lumen. These effects were evident by 7 days and became most pronounced by 30 days in naïve mice, with notable changes as early as 3 days in allogeneic splenocyte-stimulated mice. These findings reveal a novel mechanism of rapamycin action through time-dependent modulation of LN architecture and gut microbiome, which orchestrates changes in immune cell trafficking, providing a new framework for understanding and optimizing immunosuppressive therapies.

Project description:In our model the newborns of asthmatic mother mice or of mothers exposed to air pollutant particles are born with a predisposition to asthma. Gut microbiome of these pups is altered, and the transplant of the pups’ microbiome (GMT) has conferred the asthma predisposition to naïve recipients. We hypothesized that bacteria alter metabolomic profile in the gut, which polarizes the dendritic cells (DC) in the recipient by affecting epigenetic regulation in these key decision-maker cells. Here we examined DNA methylation profiles in the recipient host’s DCs to test the prediction that GMT confers alterations in DNA methylation (not seen with sterilized GMT).

Project description:Mycophenolate mofetil (MMF) has been widely prescribed for neuromyelitis optica spectrum disorders (NMOSD) although some patients experience severe gastrointestinal (GI) side effects following MMF administration. Our study investigated the potential mechanisms of this toxicity in NMOSD patients. We constructed MMF-induced colitis mouse model and produced a multi-omic dataset in which microbiome and metabolome analysis from the mouse GI tract to decipher the mechanisms of MMF GI toxicity. Further, 17 female NMOSD patients treated with MMF were prospectively enrolled and grouped according to the diarrhea symptom as non-diarrhea NMOSD group (NM) and diarrhea NMOSD group (DNM) as well as healthy controls (HC, 12 female). The gut microbiota was analyzed using 16S rRNA sequencing of stool samples. In the mouse model, we found that vancomycin administration drastically altered the colon content metabolomes and microbiomes and prevented MMF-induced body weight loss, cecal and colon tissue injury. Bacteroidetes and Firmicutes converted phenyl-beta-D-glucuronide (MPAG) to mycophenolic acid (MPA) that could result in damaged intestinal tissue. We also demonstrated that the alpha diversity in the DNM group was increased and this was accompanied by increased Firmicutes and Proteobacteria abundance. Collectively, these results reveal that alterations of the gut microbiome and metabolome contribute to MMF-induced colitis. Modifying of the gut microbiome and metabolome may alleviate MMF-induced GI toxicity in NMOSD patients.

Project description:Aging is associated with declining immunity and inflammation as well as alterations in the gut microbiome with a decrease of beneficial microbes and increase in pathogenic ones. The aim of this study was to investigate aging associated gut microbiome in relation to immunologic and metabolic profile in a non-human primate (NHP) model. 12 old (age>18 years) and 4 young (age 3-6 years) Rhesus macaques were included in this study. Immune cell subsets were characterized in PBMC by flow cytometry and plasma cytokines levels were determined by bead based multiplex cytokine analysis. Stool samples were collected by ileal loop and investigated for microbiome analysis by shotgun metagenomics. Serum, gut microbial lysate and microbe-free fecal extract were subjected to metabolomic analysis by mass-spectrometry. Our results showed that the old animals exhibited higher inflammatory biomarkers in plasma and lower CD4 T cells with altered distribution of naïve and memory T cell maturation subsets. The gut microbiome in old animals had higher abundance of Archaeal and Proteobacterial species and lower Firmicutes than the young. Significant enrichment of metabolites that contribute to inflammatory and cytotoxic pathways was observed in serum and feces of old animals compared to the young. We conclude that aging NHP undergo immunosenescence and age associated alterations in the gut microbiome that has a distinct metabolic profile.

Project description:TransplantLines is designed as a single-center, prospective cohort study and biobank including all different types of solid organ transplant recipients as well as living organ donors. In the TransplantLines gut microbiome study the gut microbiome of solid organ transplant recipients is characterized and linked to clinical phenotypes. This batch contains the cross-sectional data from renal transplant recipients is.

Project description:TransplantLines is designed as a single-center, prospective cohort study and biobank including all different types of solid organ transplant recipients as well as living organ donors. In the TransplantLines gut microbiome study the gut microbiome of solid organ transplant recipients is characterized and linked to clinical phenotypes. This batch contains the cross-sectional data from liver transplant recipients and longitudinal data from renal and liver transplant recipients.

Project description:We explore whether a low-energy diet intervention for Metabolic dysfunction-associated steatohepatitis (MASH) improves liver disease by means of modulating the gut microbiome. 16 individuals were given a low-energy diet (880 kcal, consisting of bars, soups, and shakes) for 12 weeks, followed by a stepped re-introduction to whole for an additional 12 weeks. Stool samples were obtained at 0, 12, and 24 weeks for microbiome analysis. Fecal microbiome were measured using 16S rRNA gene sequencing. Positive control (Zymo DNA standard D6305) and negative control (PBS extraction) were included in the sequencing. We found that low-energy diet improved MASH disease without lasting alterations to the gut microbiome.

Project description:Purpose: The intestine's main function is to digest and absorb dietary nutrients, with help from the absorptive epithelium and underlying vasculature and lymphatic system, as well as the microbiome. The intestine also houses the largest immune cell population in the body, tasked with providing resistance to toxins and invading pathogens while maintaining tolerance to dietary and microbial antigens, either by local action or lymphatic trafficking to the gut-draining lymph nodes (gLNs) to mount adaptive responses. While previous studies revealed the drainage map to various gLNs along the murine gut, and described immunological differences between gLNs, the underlying cellular components and the functional consequences of gut segment-specific drainage have not been systematically addressed. We sought to understand how compartmentalized lymphatic drainage of the intestinal milieu contributes to immune responses towards luminal antigens. Results: Here we report that gLNs are immunologically unique according to the functional gut segment they drain. Stromal and dendritic cell gene signatures, as well as adaptive T cell polarization against the same luminal antigen, differed between gLNs along the intestine, the proximal small intestine–draining gLNs preferentially giving rise to tolerogenic and the distal gLNs to pro-inflammatory T cell responses. This compartmentalized dichotomy could be perturbed by duodenal infection, surgical removal of select distal gLNs, dysbiosis, or ectopic antigen delivery, impacting both lymphoid organ and tissue immune responses. Conclusions: Our findings reveal that the conflict between tolerogenic and inflammatory adaptive responses is in part resolved by discrete gLN drainage, and encourage gut segment-specific antigen targeting for therapeutic immune modulation.

Project description:The gut microbiome can impact brain health and is altered in Parkinson’s disease (PD) patients. The vermiform appendix is a lymphoid tissue implicated in the storage and regulation of the gut microbiome. Here, we investigate changes in the functional microbiome in the appendix of PD patients relative to controls by metatranscriptomic analysis. In the PD appendix, we find microbial dysbiosis affecting lipid metabolism, particularly an upregulation of bacteria responsible for secondary bile acid synthesis. Likewise, proteomic and transcript analysis in the PD gut corroborates a disruption in cholesterol homeostasis and lipid catabolism. Bile acid analysis in the PD appendix reveals an increase in the microbially-derived, toxic secondary bile acids deoxycholic acid (DCA) and lithocholic acid (LCA). Synucleinopathy in mice induces similar microbiome alterations to those of PD patients and heightens microbial changes to gut inflammation. As observed in PD, the mouse model of synucleinopathy has elevated DCA and LCA. Raised levels of DCA and LCA can lead to liver injury, and an analysis of blood markers of liver dysfunction shows evidence of biliary abnormalities in PD patients, including elevated alkaline phosphatase and bilirubin. Increased bilirubin levels are also evident before PD diagnosis, in individuals at-risk of developing PD. In sum, microbially-derived toxic bile acids are heightened in PD and biliary changes may even precede the onset of overt motor symptoms.

Project description:In this study the characteristics and alterations of the gut microbiome during chemotherapy for metastasized or irresectable CRC are studied, as well as the relation between the gut microbiome and the effects of chemotherapy.