Project description:We performed gene expression microarray experiments to compare the global transcriptional response induced by b-glucans and LPS with their secretomes. We identified 1683, 767 and 1447 genes with over two-fold increase or decrease in LPS-, curdlan- or GBY-stimulated macrophages, respectively. We show that both LPS and b-glucan induces significant gene expression changes in macrophages, but only b-glucans activate a robust protein secretion. The gene expression of human primary macrophage cells was measured at 6 hours after exposure the cells to 1 M-BM-5g LPS or 10 M-BM-5g Curdlan or 100 M-BM-5g GBY (glucan from bakerM-BM-4s yeast), also 0-group was included. Three independent experiments were performed using three different donors for each experiment.

Project description:We demonstrate that a natural compund B-Glucan (WGP) can induce training of macrophages by upregulating the Sphingolipid biosynthesis pathway and more specifically, the accumulation of S1P, resulting in mitochondrial fission in macrophages. These trained macrophages upon re-stimulation with tumor cells or tumor-derived factors showed increased responsiveness by increased pro-inflammatory cytokine production, increased phagocytosis and cytotoxicity. In vivo training of mice with WGP resulted in the training of Lung Interstitial macrophages and controlled the metastasis to the lungs.

Project description:We performed gene expression microarray experiments to compare the global transcriptional response induced by b-glucans and LPS with their secretomes. We identified 1683, 767 and 1447 genes with over two-fold increase or decrease in LPS-, curdlan- or GBY-stimulated macrophages, respectively. We show that both LPS and b-glucan induces significant gene expression changes in macrophages, but only b-glucans activate a robust protein secretion.

Project description:Analysis of transcriptional profiles in mDC sorted from apheresed PBMC and stimulated for 6 hours with cyclic glucan or LPS. The hypothesis tested is that cyclic glucan induces maturation and T cell-activation transcripts in human mDC. Total RNA extracted from mDC sorted from apheresed PBMC and activated for 6 hours with cyclic glucan or LPS.

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:We found that beta-glucan treatment induces early induction of transcripts associated with inflammation and metabolism. Several days after beta-glucan treatment, genes associated with differentation and housekeeping remain upregulated. LPS treatment induces a strong inflammatory response. Beta-glucan did not significantly alter the macrophage response to LPS.

Project description:Objective: Transcriptional profiling of murine HSPC in response to β-glucan-induced innate immune training

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:Macrophages (MΘs) play a critical role in tumor growth, immunosuppression and inhibition of adaptive immune responses in cancer. Hence, targeting signaling pathways in MΘs that promote tumor immunosuppression will provide therapeutic benefit. PI3Kγ has been recently established by our group and others as a novel immuno-oncology target. Herein, we report that macrophage Syk drives polarization of immunosuppressive macrophages which establish an immunosuppressive tumor microenvironment in in vivo syngeneic tumor models. Genetic or pharmacological blockade of Syk in MΘs promotes a pro-inflammatory MΘ phenotype, restores CD8+ T cell activity, destabilizes HIF under hypoxia, and stimulates antitumor immune response. Moreover, we have developed in silico the “first in class” dual Syk/PI3K inhibitor, SRX3207, for the combinatorial inhibition of Syk and PI3K in one small molecule to activate anti-tumor immunity in vivo. This chemotype shows great efficacy in various tumor models and represents a new therapeutic approach to treat devastating cancers. Significance: Our data indicate a central role of Syk in macrophage transcriptional programming leading to inhibition of adaptive immune responses. Furthermore, SRX3207 blocks macrophage expression of immunosuppressive factors and activates anti-tumor immune responses, validating the concept of combined Syk and PI3K inhibition as an effective approach to treat macrophage driven cancers.

Project description:Exposure to pathogen-associated molecular patterns (PAMPs) induces an augmented, broad-spectrum antimicrobial response to subsequent infection, a phenomenon termed innate immune memory. This study examined the effects of treatment with β-glucan, a fungus-derived Dectin-1 ligand, and monophosphoryl lipid A (MPLA), a bacteria-derived TNS4 ligand, on innate immune memory with a focus on identifying common cellular and molecular pathways. Treatment with either PAMP prepared the innate immune system to respond more robustly to Pseudomonas aeruginosa infection in vivo by facilitating mobilization of innate leukocytes into blood, their recruitment to the site of infection, augmentation of microbial clearance and attenuation of cytokine production. Examination of macrophages ex vivo showed that metabolism, phagocytosis and respiratory burst were amplified by treatment with either agent, although MPLA more robustly augmented these activities and more effectively facilitated killing of bacteria. Both agents activated gene expression pathways in macrophages that control inflammation, antimicrobial functions and protein synthesis and suppressed pathways regulating cell division with MPLA more potently inducing global gene transcription. β-glucan treatment minimally modified macrophage differential gene expression in response to LPS challenge compared to control whereas MPLA attenuated the magnitude of the LPS-induced transcriptional response. These results show that b-glucan and MPLA similarly augment the innate response to infection in vivo. Yet, MPLA more potently induces alterations in macrophage metabolism, antimicrobial functions, gene transcription and the response to LPS.