Project description:Aging is the predominant cause of morbidity and mortality in industrialized countries. The specific molecular mechanisms that drive aging are poorly understood, especially the contribution of the microbiota in these processes. Here, we combined multi-omics with metabolic modeling in mice to comprehensively characterize host–microbiome interactions and how they are affected by aging. Our findings reveal a complex dependency of host metabolism on microbial functions, including previously known as well as novel interactions. We observed a pronounced reduction in metabolic activity within the aging microbiome, which we attribute to reduced beneficial interactions in the microbial community and a reduction in the metabolic output of the microbiome. These microbial changes coincided with a corresponding downregulation of key host pathways predicted by our model that are crucial for maintaining intestinal barrier function, cellular replication, and homeostasis. Our results elucidate potential microbiome–host interactions that may influence host aging processes, focusing on microbial nucleotide metabolism as a pivotal factor in aging dynamics.

Project description:Metabolic modeling reveals the aging-associated decline of host-microbiome metabolic interactions in mice

Project description:Metabolic modeling reveals the aging-associated decline of host–microbiome metabolic interactions in mice

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:Genome scale metabolic model of Drosophila gut microbe Acetobacter fabarum Abstract - An important goal for many nutrition-based microbiome studies is to identify the metabolic function of microbes in complex microbial communities and their impact on host physiology. This research can be confounded by poorly understood effects of community composition and host diet on the metabolic traits of individual taxa. Here, we investigated these multiway interactions by constructing and analyzing metabolic models comprising every combination of five bacterial members of the Drosophila gut microbiome (from single taxa to the five-member community of Acetobacter and Lactobacillus species) under three nutrient regimes. We show that the metabolic function of Drosophila gut bacteria is dynamic, influenced by community composition, and responsive to dietary modulation. Furthermore, we show that ecological interactions such as competition and mutualism identified from the growth patterns of gut bacteria are underlain by a diversity of metabolic interactions, and show that the bacteria tend to compete for amino acids and B vitamins more frequently than for carbon sources. Our results reveal that, in addition to fermentation products such as acetate, intermediates of the tricarboxylic acid (TCA) cycle, including 2-oxoglutarate and succinate, are produced at high flux and cross-fed between bacterial taxa, suggesting important roles for TCA cycle intermediates in modulating Drosophila gut microbe interactions and the potential to influence host traits. These metabolic models provide specific predictions of the patterns of ecological and metabolic interactions among gut bacteria under different nutrient regimes, with potentially important consequences for overall community metabolic function and nutritional interactions with the host.IMPORTANCE Drosophila is an important model for microbiome research partly because of the low complexity of its mostly culturable gut microbiota. Our current understanding of how Drosophila interacts with its gut microbes and how these interactions influence host traits derives almost entirely from empirical studies that focus on individual microbial taxa or classes of metabolites. These studies have failed to capture fully the complexity of metabolic interactions that occur between host and microbe. To overcome this limitation, we reconstructed and analyzed 31 metabolic models for every combination of the five principal bacterial taxa in the gut microbiome of Drosophila This revealed that metabolic interactions between Drosophila gut bacterial taxa are highly dynamic and influenced by cooccurring bacteria and nutrient availability. Our results generate testable hypotheses about among-microbe ecological interactions in the Drosophila gut and the diversity of metabolites available to influence host traits.

Project description:Aging is the result of an accumulation of molecular damages, driven by multiple factors like metabolic and oxidative stress, (epi)genetic alterations, and microbiome dysbiosis. In addition, aging is characterized by a chronic, low-grade inflammation known as inflammaging that represents a high significant risk factor for most, if not all, age-related diseases. Dietary restriction (DR) is the best-known non-invasive method to ameliorate the aging phenotype in many organisms. While it has been shown that DR reduces the inflammation in some tissues, the molecular mechanisms in old individuals are still largely unknown. Here we identify a multi-tissue gene network which regulates the inflammaging and that is ameliorated by DR. Using transcriptional profiling (RNA-seq), we found that aging upregulates the innate immune system receptor together with the activation of a systemic interferon (IFN) signaling through the Interferon Regulatory Factors (Irf), inflammatory cytokines and finally Stat1 transcription factor. Our results suggest that DR is able to ameliorate inflammaging by downregulating the expression and the activity of almost all the components of this gene network. In addition, chromatin accessibility genome-wide analysis showed that the binding site of Irf and Stat1 in the promoter of their target genes are more open in aging and become closer upon DR treatment indicating a transcriptional control of the inflammaging phenotype involving epigenetic modifications. Our results provide a comprehensive understanding of the molecular network regulating the inflammation in aging and DR and present novel anti-inflammaging therapeutic targets.

Project description:Aging is the result of an accumulation of molecular damages, driven by multiple factors like metabolic and oxidative stress, (epi)genetic alterations, and microbiome dysbiosis. In addition, aging is characterized by a chronic, low-grade inflammation known as inflammaging that represents a high significant risk factor for most, if not all, age-related diseases. Dietary restriction (DR) is the best-known non-invasive method to ameliorate the aging phenotype in many organisms. While it has been shown that DR reduces the inflammation in some tissues, the molecular mechanisms in old individuals are still largely unknown. Here we identify a multi-tissue gene network which regulates the inflammaging and that is ameliorated by DR. Using transcriptional profiling (RNA-seq), we found that aging upregulates the innate immune system receptor together with the activation of a systemic interferon (IFN) signaling through the Interferon Regulatory Factors (Irf), inflammatory cytokines and finally Stat1 transcription factor. Our results suggest that DR is able to ameliorate inflammaging by downregulating the expression and the activity of almost all the components of this gene network. In addition, chromatin accessibility genome-wide analysis showed that the binding site of Irf and Stat1 in the promoter of their target genes are more open in aging and become closer upon DR treatment indicating a transcriptional control of the inflammaging phenotype involving epigenetic modifications. Our results provide a comprehensive understanding of the molecular network regulating the inflammation in aging and DR and present novel anti-inflammaging therapeutic targets.

Project description:Marine sponges are essential for coral reefs to thrive and harbour a diverse microbiome that is thought to contribute to host health. Although the overall function of sponge symbionts has been increasingly described, in-depth characterisation of each taxa remains challenging, with many sponge species hosting up to 3,000 distinct microbial species. Recently, the sponge Ianthella basta has emerged as a model organism for symbiosis research, hosting only three dominant symbionts: a Thaumarchaeotum, a Gammaproteobacterium, and an Alphaproteobacterium and a range of other minor taxa. Here, we retrieved metagenome assembled genomes (MAGs) for >90% of I. basta’s microbial community which allowed us to make a complete metabolic reconstruction of the sponge’s microbiome, identifying metabolic complementarity between microbes, as well as the importance of symbionts present in low abundance. We also mined the metagenomes for putative viral sequences, highlighting the contribution of viruses to the overall metabolism of the sponge, and complement this data with metaproteomic sequencing to identify active metabolic pathways in both prokaryotes and viruses. This data now allows us to use I. basta as a model organism for studying host-microbe interactions and provides a basis for future (genomic) manipulative experiments.

Project description:Characteization host-microbiome interactions in patients with allergic (model: atopic dermatitis) and autoimmune (model: psoriasis) diseases by integration of microarray transcriptome data with 16S microbial profiling. 6mm punch biopsies were collected from the skin of atopic dermatitis and psoriasis patients alongside healthy volunteers, and subjected to analysis using Affymetrix Human Gene ST 2.1 arrays.

Project description:Metabolic modeling reveals the aging-associated decline of host-microbiome metabolic interactions in mice