Project description:Venous thromboembolism is common in individuals with chronic inflammatory diseases, but the pathogenic basis for this increased thrombotic risk remains poorly understood. Myeloid cell ‘trained immunity’ describes persistent innate immune cell memory arising from prior exposure to an inflammatory stimulus, leading to an enhanced immune response to subsequent unrelated stimuli. We identify enhanced myeloid cell prothrombotic activity as a novel maladaptive consequence of trained immunity. LPS stimulation of murine bone marrow-derived macrophages trained previously with either β-glucan or free haem exhibited significantly enhanced procoagulant and antifibrinolytic gene expression and activity compared to macrophages stimulated with LPS alone. The β-glucan training-mediated increase in activated myeloid cell procoagulant activity was mediated by enhanced acid sphingomyelinase-mediated tissue factor (TF) functional decryption. Furthermore, pre-treatment with methyltransferase and acetyltransferase inhibitors to erase epigenetic marks associated with innate immune memory diminished trained macrophage TF gene expression in β-glucan-trained macrophages. Functional analysis of splenic monocytes isolated from β-glucan-trained mice revealed enhanced procoagulant activity up to 4 weeks after β-glucan administration compared to monocytes from control mice over the same time period. Remarkably, monocyte procoagulant activity increased proportionately with time since β-glucan administration, before plateauing at 4 weeks. Furthermore, haematopoietic progenitor cells and bone marrow interstitial fluid isolated from β-glucan-trained mice possessed enhanced procoagulant activity compared to control mice. Trained immunity and associated metabolic perturbations may therefore represent novel therapeutic vulnerabilities in immunothrombotic disease development, opening new avenues for targeted intervention.

Project description:Cells of the innate immune system retain memory of prior exposures through a process known as innate immune training. b-glucan, a Dectin-1 ligand purified from the Candida albicans cell wall, has been one of the most widely utilized and well-characterized ligands for inducing innate immune memory. However, many Dectin-1 agonists exist, and it is not known whether all Dectin-1 ligands produce the same phenotype. Using a well-established in vitro model of trained immunity, we compared two commercially available Dectin-1 agonists with the gold standard b-glucan represented in the literature. We found that depleted zymosan, a b-glucan purified from the Saccharomyces cerevisiae cell wall through alkali treatment, produced near identical training effects as C. albicans b-glucan. However, untreated zymosan produced a distinct training effect from b-glucans at both the transcript and cytokine level. Training with zymosan diminished, rather than potentiated, induction of key cytokines such as TNF, IL-12, and IL-6. Zymosan activated NFkB and AP-1 transcription factors more strongly than b-glucans. The addition of the toll-like receptor (TLR) ligand Pam3CSK4 was sufficient to convert the training effect of b-glucans to a phenotype resembling training with zymosan. We conclude that differential activation of TLR signaling pathways determines the phenotype of innate immune training induced by Dectin-1. These findings bring clarity to the specific question of which Dectin-1 agonists produce prototypical training effects and provides broader insight into how signaling networks regulate innate immune training at large.

Project description:Trained immunity is classically characterized by long-term epigenetic reprogramming of innate immune cells to combat infectious diseases. Infection-induced organ injury is a common clinical severity phenotype of sepsis. However, whether the induction of trained immunity plays a role in protecting septic-organ injury remains largely unknown. Here, through establishing an in vivo β-glucan training and secondary LPS challenge-induced organ injury model in zebrafish larvae, we observe that induction of trained immunity could inhibit the pyroptosis of hepatocytes to alleviate septic-liver injury, with an elevated epigenetic modification of trimethylation at histone 3 lysine 4 (H3K4me3) that targets mitophagy activation. Moreover, we identify a novel C-type lectin domain receptor in zebrafish, named DrDectin-1, which is revealed as the orchestrator in gating H3K4me3 rewiring-mediated mitophagy activation and alleviating the pyroptosis-engaged septic-liver injury in vivo. Taken together, our results uncover a tissue-resident trained immunity in maintaining tissue homeostasis at a whole animal level, and offer a facile in vivo model to efficiently integrate trained immunity for immunotherapies.

Project description:Infectious enteritis is often accompanied with immuno-disorder of intestinal immune cells caused by microbials infection. Trained immunity is classically characterized by long-term functional reprogramming of innate immune cells to combat infectious diseases. However, whether the induction of trained immunity plays a role in protecting infectious enteritis remains largely unknown. Here, through establishing an in vivo β-glucan training and E. piscicida infection model in zebrafish, we observe that induction of trained immunity could alleviate bacterial infection-caused enteritis. Moreover, we identify intestinal complement C3 as a crucial target of trained immunity and could be amplified in response to bacterial infection. Furthermore, we reveal that trained immunity could reverse the reduction of intestinal Th17 cells in C3-dependent manner to alleviate infectious enteritis. Taken together, our results uncover the role of complement C3-mediated trained immunity in maintaining Th17 cells and intestine homeostasis, and provide a theoretical strategy for immunotherapies of infectious enteritis.

Project description:Non-specific protective effects against reinfection have been described following infection with Candida albicans. Here we show that mice defective in functional T and B lymphocytes were protected against reinfection with C. albicans in a monocyte-dependent manner. C. albicans and beta glucans induced functional programming of monocytes, leading to enhanced cytokine production in vivo and in vitro. The training required the beta glucan receptor dectin 1 and the non-canonical Raf 1 pathway. Monocyte training by beta-glucans was mediated by epigenetic mechanisms through genome-wide changes in histone trimethylation at H3K4. Pathway analysis showed specific induction of epigenetic changes in genes of innate immunity. The functional programming of monocytes, reminiscent of similar properties of NK cells, has been termed M-bM-^@M-^\trained immunityM-bM-^@M-^] and may be employed for the design of improved vaccination strategies. Chromatin-IP at day7 followed by highthroughput sequencing to look at the differences in H3K4me3 and H3K27me3 binding in Monocytes either cultured in RPMI only versus those trained for 24hrs with beta glucan. Additionally expression analysis was performed by doing strandspecific RNAseq also for both unstimulated and beta glucan trained monocytes for correlating the histone modification changes with the expression changes. Biological replicates were generated from independent samples for H3K4me3 and RNAseq. Additional H3K4me3 ChIP-seq assays were performed for day0 untreated, 24hrs control and beta glucan trained monocytes. H3K4me3 ChIP-seq was also performed for Mouse macrophages both saline(control) and low dose Candida treated.

Project description:Trained immunity is a form of innate immune memory characterized by epigenetic and metabolic reprogramming in response to specific stimuli. This rewiring can result in increased cytokine and effector responses to pathogenic challenge, providing non-specific protection against disease. It may also improve immune responses to established immunotherapeutics and vaccines. Despite the promise of training for next-generation therapeutic design, most current understanding and experimentation is conducted with complex and heterogeneous biologically derived molecules, such as β-glucan or the BCG vaccine. This limited collection of training compounds also limits study of the genes most involved in training responses as each molecule has both training and non-training effects. Small molecules with tunable pharmacokinetics and delivery modalities would both assist in the study of trained immunity and its future application for therapeutics. To identify novel small molecule inducers of trained immunity, we screened a library of 2000 drugs and drug-like compounds. Identification of well-defined compounds can improve our understanding of innate immune memory and broaden the scope of its clinical applications. We identified over 2 dozen small molecules in several chemical classes, including the traditionally immunosuppressive glucocorticoids, that induce a training phenotype in the absence of initial immune activation – a current limitation of reported inducers of training. We chose 7 of these top candidates to characterize and establish training activity in vivo. In this work, we expand the number of compounds known to induce trained immunity, creating new avenues for the study and application of innate immune training.

Project description:We generated BMDMs from aged C57BL/6J mice. BMDMs were treated with C.ablican derived β-glucan, which is known to induce trained immunity. mRNA was isolated form immune trained and control BMDMs using the Rneasy Kit from Qiagen. Library preparation and sequencing performed by Novogene. We found that trained immunity induced transcriptional changes in BMDMs from aged mice

Project description:Trained immunity is a long-term memory of innate immune cells, generating an improved response upon re-infection. Shigella is an important human pathogen and inflammatory paradigm for which there is no effective vaccine. Using zebrafish larvae we demonstrate that after Shigella priming neutrophils are more efficient at bacterial clearance. We observe that Shigella-induced protection is non-specific and long-lasting, and is unlike training by BCG and β-glucan. Analysis of histone ChIP-seq on primed neutrophils revealed that Shigella training deposits the active H3K4me3 mark on promoter regions of 1612 genes, significantly changing the epigenetic landscape of neutrophils towards enhanced microbial recognition and mitochondrial ROS production. Finally, we demonstrate that mitochondrial ROS plays a key role in enhanced antimicrobial activity of trained neutrophils. It is envisioned that signals and mechanisms we discover here can be used in other vertebrates, including humans, to suggest new therapeutic strategies involving neutrophils to control bacterial infection.

Project description:We establish a trained immunity activation model in turbot (Scophthalmus maximus) by training with β-glucan in vivo. Through single cell RNA-sequencing analysis, we annotate 16 clusters of immune cells and blood cells from head kidney and spleen, and successfully characterize that neutrophils exhibit distinguished feature of trained immunity.

Project description:Monocyte differentiation into macrophages represents one of the cornerstone processes in innate host defense. In addition, immunological imprinting of either tolerance or trained immunity after an initial infection determines the functional fate of innate immune cells and the susceptibility of the host to secondary infections. Here we comprehensively characterize the epigenetic profiles of these functional states relative to healthy adult naM-CM-/ve monocytes. Inflammatory and metabolic pathways are strongly modulated in the derived macrophages, including decreased activation of inflammasome components. The cAMP-dependent signaling pathway is remodeled and adrenergic signaling was functionally implicated in trained innate immunity induction in vivo. Interestingly, M-oM-^AM-"-Glucan trains innate immune cells through extensive remodeling of distal regulatory region-bound histone acetylation, resulting in a sizeable exclusive epigenomic signature. Accordingly, genome-wide transcription factor footprint analysis reveals a specific transcription factor repertoire at trained cell-specific enhancers when recouped with epigenetic data, forming a rich hypothesis generator to manipulate innate immunity. Monocytes were pre-incubated either with cell culture medium (RPMI), M-NM-2-glucan (5M-BM-5g/mL) or with LPS (100ng/mL), for 24 hours in a total volume of 10 mL. After a wash-out, cells were cultured in RPMI supplemented with 10% human pool serum. Monocytes were collected at different time points (0 h and 6 d after treatment) and counted before further treatment for chromatin immunoprecipitation, RNA or DNaseI treatment. Different donor Buffycoats (BC) were used as independent replicates. Replicates were generated for all the profiles including ChIPseq,RNAseq and DNaseIseq.