Project description:Interventions: Case series:N/A Primary outcome(s): Serum immune cytokines;Blood immune cells;SCFAs of bacterial metabolites;Gut microbial genomics;Metabolic function of intestinal microorganism Study Design: Sequential

Project description:Mucosa-associated invariant T (MAIT) cells recognize microbial-derived riboflavin metabolites presented by the evolutionarily conserved MR1 molecule. Their persistent loss in chronic HIV-1 infection is a significant insult to antimicrobial immune defenses. Here we explore MAIT cell dynamics in the critical acute stages of HIV-1 infection for the first time

Project description:Dried Blood Spots samples are a rich source of proteins and have therefore great potential for proteomics biomarker discovery studies. Only a few articles have used DBS samples for non-targeted bottom-up protein analysis, probably due to the complexity of the DBS samples. Gas-phase separation by ion mobility spectrometry such as Field Asymmetric Waveform Ion Mobility (FAIMS) could be useful in analysis of DBS samples as FAIMS has previously shown to be advantageous for bottom-up protein analysis of complex samples. The aim of this project was therefore to evaluate FAIMS in non-targeted analysis of Dried Blood Spots.

Project description:Sensing of microbial tryptophan catabolites by the aryl hydrocarbon receptor (AhR) plays a pivotal role in host-microbiome homeostasis by modulating the host immune response. Thereby the involved cellular processes triggered by the metabolites are largely unknown. We analyzed proteomic changes in macrophages trough 24h after treatment with the tryptophan metabolites indole-3-acetic acid (I3AA) or indole-3-aldehyde (IAld), as well as the prototypic AhR-ligand Benzo(a)pyrene (BaP) in the absence and presence of LPS to identify affected processes and pathways.

Project description:Background: More than 100 million Americans are living with metabolic syndrome, increasing their propensity to develop heart disease– the leading cause of death worldwide. A major contributing factor to this epidemic is caloric excess, often a result of consuming low cost, high calorie fast food. Several recent seminal studies have demonstrated the pivotal role of gut microbes contributing to cardiovascular disease in a diet-dependent manner. Given the central contributions of diet and gut microbiota to cardiometabolic disease, we hypothesized that novel microbial metabolites originating postprandially after fast food consumption may contribute to cardiometabolic disease progression. Methods: To test this hypothesis, we gave conventionally raised or antibiotic-treated mice a single oral gavage of a fast food slurry or a control rodent chow diet slurry and sacrificed the mice four hours later. Here, we coupled untargeted metabolomics in portal and peripheral blood, 16S rRNA gene sequencing, targeted liver metabolomics, and host liver RNA sequencing to identify novel fast food-derived microbial metabolites. Results: We successfully identified several metabolites that were enriched in portal blood, increased by fast food feeding, and essentially absent in antibiotic-treated mice. Strikingly, just four hours post-gavage, we found that fast food consumption resulted in rapid reorganization of the gut microbial community structure and drastically altered hepatic gene expression. Importantly, diet-driven reshaping of the microbiome and liver transcriptome was dependent on a non-antibiotic ablated gut microbial community. Conclusions: Collectively, these data suggest that single fast food meal is sufficient to reshape the gut microbial community yielding a unique signature of food-derived microbial metabolites. Future studies are warranted to determine if these metabolites are causally linked to cardiometabolic disease.

Project description:The characterization of fish blood proteomes is important for the comparative studies of seminal and blood proteins as well as for the analysis of fish immune mechanisms and pathways. In this study LC-MS/MS and 2D DIGE was applied to compare seminal and blood plasma trout proteomes. The 54 differentially abundant proteins identified in seminal plasma are involved in a variety of signaling pathways, including protein ubiqutination, liver X receptor/retinoid X receptor (LXR/RXR) and farnesoid X (FXR)/RXR activation, cell cycle and acute phase signaling. These finding may indicate the prevalence of acute phase signaling pathways in trout seminal plasma, and its essential role in protecting spermatozoa and reproductive tissues. Furthermore our study provides the first in-depth analysis of the rainbow trout blood plasma proteome, with a total of 119 identified proteins. The major proteins of rainbow trout blood plasma were recognized as acute phase proteins. The Ingenuity Pathway Analysis of trout BP plasma proteins indicated that acute phase response signaling, complement system, LXR, FXR-RXR activation and coagulation system are the top canonical pathways associated with trout blood proteins. In conclusion this study enhances the knowledge of the blood origin of trout seminal plasma proteins and the understanding of fish reproductive biology. Additionally our results provide new insight into blood proteins specifically important for fish physiology and innate immunity.

Project description:Ionizing radiation exposure from a potential nuclear energy plant leak or detonation of a nuclear weapon can cause massive casualties to both warfighters and civilians. Biomarkers in biological specimens like blood and tissue, such as RNA, proteins, and metabolites, have shown potential to determine radiation dose levels. However, these biomarkers in blood and urine are short-lived, typically detectable only within hours or a few days. To address the need for stable, long-term radiation exposure biomarkers, we developed two LC-MS-based methods using non-invasive hair samples to identify radiation-induced biomarkers

Project description:Most individuals exposed to hepatitis C virus (HCV) become persistently infected while a minority spontaneously eliminate the virus. Although early immune events influence infection outcome, the cellular composition, molecular effectors, and timeframe of the host response active shortly after viral exposure remain incompletely understood. Employing specimens collected from people who inject drugs (PWID) with high risk of HCV exposure, we utilized RNA-Seq to characterize immune function in peripheral blood before, during, and after acute HCV infection resulting in spontaneous resolution. Our results provide a detailed description of innate immune programs active in peripheral blood during acute HCV infection, which include prominent type I interferon and inflammatory signatures. Innate immune gene expression rapidly returns to pre-infection levels upon viral clearance. This innate response coincides with a decrease in B cell transcriptional signatures. These results represent the first longitudinal transcriptomic characterization of human immune function in acute HCV infection and identify several dynamically regulated features of the complex response to natural HCV exposure.

Project description:Analysis of peripheral blood specimens from patients with acute myocardial infarction (AMI). Results provide insight into molecular mechanisms associated with AMI.

Project description:Background: Dengue virus (DENV) infection often leads to acute illness lasting 2-7 days with severity ranging from dengue fever (DF) to hemorrhagic fever (DHF) and fatal dengue shock syndrome (DSS). The dynamic changes of host responses on the gene transcription level that accompany DENV infection and differences between DF and DHF cases have been poorly understood, particularly for South American population. Methodology/Principal Findings: Supported by a longitudinal active surveillance program for dengue transmission in Maracay, Venezuela, we conducted a prospective study to investigate host responses in dengue patients. Blood specimens and clinical information were collected on a daily basis from febrile cases confirmed with DENV infection from their first day of enrollment to early defervescence together with one convalescent sample. A total of 49 and 13 study participants were defined as DF and DHF cases respectively based on their clinical and hematological information. Using convalescent specimens as baseline, day-to-day gene expression was evaluated ex vivo in peripheral blood mononuclear cells of the study participants. Two waves of gene expression were detected: the first wave peaked at day 1 from the onset of fever (day 0) then declined at days 3-4; the second wave emerged from day 4 and peaked around day 5-6. Genes associated with innate immune process, including type I interferon signaling, cytokine-mediated signaling, chemotaxis, and antiviral responses, dominated the first wave; whereas genes involved in cell cycle processes, including cell division, mitosis, DNA replication, chromosome, and spindle organization dominated the second wave. Measureable genomic markers predicted early acute, late acute and convalescent phases with 91% accuracy. Gene signatures expressed in early acute phase predicted disease severity (DF vs DHF) with 96% accuracy. Conclusions/Significance: Our study established a dynamic pattern of detailed host immune responses to DENV infection and revealed genomic signatures valuable for diagnostics purposes.