Project description:Single-Cell Epitope-Transcriptomics Reveal Lung Stromal and Immune Cell Response Kinetics to Nanoparticle-delivered RIG-I and TLR4 Agonists

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.

Project description:Using microarray analysis, we explored the differences in gene expression profiles between individual and combined stimulation of Toll-like receptor 4 (TLR4) and Nucleotide oligomerization domain (NOD)-like receptor (NOD2) in THP-1 cells. Analysis was performed 3 hours post addition of TLR4 agonist MPLA and the NOD2 agonist MDP to THP-1 cells. The results provide the detailed molecular profile of the the genetic response to individual and combined stimulation of TLR4 and NOD2 receptors THP-1 cells (Invivogen) were seeded in 3-cm culture dishes at 1x10^6 cells per dish in RPMI medium. Next day, cells were treated with MDP (20μg/ml) and MPLA (1μg/ml) individually or in combination or left untreated.

Project description:Treatment with the toll-like receptor (TLR) 4 agonist monophosphoryl lipid A (MPLA) conditions innate immunocytes to respond robustly to subsequent infection, a phenotype termed innate immune memory. Our published studies show that metabolic reprogramming of macrophages is a prominent feature of the memory phenotype. We undertook studies to define the functional contributions of tricarboxylic acid (TCA) reprogramming to innate immune memory. We observed that MPLA potently induced expression of immunoresponsive gene 1 (Irg1) and accumulation of its byproduct, the TCA cycle metabolite itaconate, in macrophages. Treatment with MPLA enhanced microbial clearance in wild type (WT), but not Irg1-deficient, mice, demonstrating that itaconate contributes to the antimicrobial phenotype in vivo. Treatment with MPLA equally augmented innate leukocyte recruitment, phagocytosis, respiratory burst and cytokine responses in WT and Irg1-deficient innate leukocytes after infection. However, the ability of Irg1-deficient macrophages to kill Pseudomonas aeruginosa was impaired. We further observed that itaconate is directly antimicrobial against P. aeruginosa at pH 5, which is characteristic of the phagolysosome, and is facilitated by reactive oxygen species. RNA sequencing revealed suppressed transcription of genes associated with phagolysosome function in Irg1 deficient macrophages. This study identifies a contribution of itaconate to MPLA-induced augmentation of innate antimicrobial immunity via facilitation of microbial killing.

Project description:Here we implemented a simple dendritic cell (DC)-mediated immunization approach to study the effects of commonly used adjuvants, Toll like receptor (TLR) ligands, on effector CD8 T cell differentiation and memory T cell development. To our surprise, we found that the TLR4 ligand LPS was far more superior to other TLR ligands in generating memory CD8 T cells upon immunization. LPS boosted clonal expansion similar to the other adjuvants, but fewer of the activated CD8 T cells died during contraction, generating a larger pool of memory cells. Intriguingly, monophosphoryl lipid A (MPLA), another TLR4 ligand, enhanced clonal expansion of effector CD8 T cells, but also promoted their terminal differentiation and contraction; thus, fewer memory CD8 T cells formed and MPLA-primed animals were less protected against secondary infection compared to those primed with LPS. Furthermore, gene expression profiling revealed that LPS-primed effector cells displayed a stronger pro-memory gene expression signature, whereas the gene expression profile of MPLA-primed effector cells had aligned closer with terminal effector CD8 T cells. Mice that contain small number of P14 CD8 T cells were immunized with DC-33 either alone or in combination with LPS or MPLA. KLRG1loIL-7Rhi MPECs were purified by FACS sort, and mRNA isolated from MPECs was subjected to whole-genome expression profiling using Illumina MouseWG-6 v2.0 Expression BeadChip.

Project description:Natural and synthetic circular RNAs effectively impair miRNA function. MiR-21-5p is a potent oncomiR presenting ~33% of all miRNAs across cancers, ~41% in lung adenocarcinoma (LUAD), and ~68% in LUAD-derived cells. We validate and identify five main tumor suppressors targeted by miR-21-5p by deletion of the MIR21 locus in LUAD cells. Synthetic, liposome-delivered circular miR-21-5p decoys enhance expression of these tumor suppressors and severely impair tumor cell vitality at low doses. Decoy efficacy is not increased by bulging of miR-21-5p targeting sites, but associated with substantial cellular decoy stability, indicated by a half-life of ~20h. The intraperitoneal application of nanoparticle-delivered miR-21-5p decoys significantly impairs tumor growth in mouse LUAD tumor models. Decoys are well tolerated and were enriched in lung tissue. However, despite low decoy abundance, tumor suppressor expression was only increased in subcutaneous tumors. These findings suggest nanoparticle-delivered circular miRNA decoys as potent therapeutics in cancer treatment.

Project description:Natural and synthetic circular RNAs effectively impair miRNA function. MiR-21-5p is a potent oncomiR presenting ~33% of all miRNAs across cancers, ~41% in lung adenocarcinoma (LUAD), and ~68% in LUAD-derived cells. We validate and identify five main tumor suppressors targeted by miR-21-5p by deletion of the MIR21 locus in LUAD cells. Synthetic, liposome-delivered circular miR-21-5p decoys enhance expression of these tumor suppressors and severely impair tumor cell vitality at low doses. Decoy efficacy is not increased by bulging of miR-21-5p targeting sites, but associated with substantial cellular decoy stability, indicated by a half-life of ~20h. The intraperitoneal application of nanoparticle-delivered miR-21-5p decoys significantly impairs tumor growth in mouse LUAD tumor models. Decoys are well tolerated and were enriched in lung tissue. However, despite low decoy abundance, tumor suppressor expression was only increased in subcutaneous tumors. These findings suggest nanoparticle-delivered circular miRNA decoys as potent therapeutics in cancer treatment.

Project description:Natural and synthetic circular RNAs effectively impair miRNA function. MiR-21-5p is a potent oncomiR presenting ~33% of all miRNAs across cancers, ~41% in lung adenocarcinoma (LUAD), and ~68% in LUAD-derived cells. We validate and identify five main tumor suppressors targeted by miR-21-5p by deletion of the MIR21 locus in LUAD cells. Synthetic, liposome-delivered circular miR-21-5p decoys enhance expression of these tumor suppressors and severely impair tumor cell vitality at low doses. Decoy efficacy is not increased by bulging of miR-21-5p targeting sites, but associated with substantial cellular decoy stability, indicated by a half-life of ~20h. The intraperitoneal application of nanoparticle-delivered miR-21-5p decoys significantly impairs tumor growth in mouse LUAD tumor models. Decoys are well tolerated and were enriched in lung tissue. However, despite low decoy abundance, tumor suppressor expression was only increased in subcutaneous tumors. These findings suggest nanoparticle-delivered circular miRNA decoys as potent therapeutics in cancer treatment.

Project description:Using microarray analysis, we explored the differences in gene expression profiles between individual and combined stimulation of Toll-like receptor 4 (TLR4) and Nucleotide oligomerization domain (NOD)-like receptor (NOD2) in THP-1 cells. Analysis was performed 3 hours post addition of TLR4 agonist MPLA and the NOD2 agonist MDP to THP-1 cells. The results provide the detailed molecular profile of the the genetic response to individual and combined stimulation of TLR4 and NOD2 receptors

Project description:Many cancers recruit monocytes/macrophages and polarize them into tumor-associated macrophages (TAMs). TAMs promote tumor growth and metastasis and inhibit cytotoxic T cells, preventing immune control of the cancer. However, macrophages polarized by lipopolysaccharide (a bacteria-derived toll-like receptor 4 [TLR4] agonist) and interferon gamma (IFNγ) instead kill cancer cells. They do so via nitric oxide (NO), generated by inducible NO synthase (iNOS). Altering the polarization of macrophages might therefore be a strategy for controlling tumors. Here, we show that monophosphoryl lipid A (MPLA, a TLR4 agonist used as a vaccine adjuvant)- and IFNγ-activated human macrophages from metastatic breast cancers to kill the same patients’ cancer cells in vitro. Excitingly, intratumoral injection of MPLA with IFNγ not only controlled local tumor growth but also led to reduced metastasis in mouse models of metastatic luminal and triple negative breast cancers. Furthermore, intraperitoneal administration of MPLA and IFNγ reprogrammed peritoneal macrophages and suppressed metastasis in ID8-p53-/- ovarian tumor-bearing mice. We found that the combination of MPLA and IFNγ reprogrammed the immunosuppressive microenvironment to be immunostimulatory by recruiting leukocytes, stimulating type I interferon signaling, reprogramming tumor-associated (CD206+) macrophages to tumoricidal (iNOS+) macrophages, and activating cytotoxic T cells through macrophage-secreted IL12 and TNFα. Both macrophages and T cells, including memory T cells (CD44+CD62L-), were critical for the anti-metastatic effects of MPLA and IFNγ. MPLA and IFNγ are used individually in humans, so our strategy to engage the anti-tumor immune response, which requires no knowledge of unique tumor antigens, may be ready for near-future clinical testing.