Project description:Bacterial outer membrane vesicles (OMVs) are promising as antitumor agents, but their clinical application is limited by toxicity concerns and unclear mechanisms. We engineered OMVs with CDH17 tumor-targeting nanobodies, enhancing tumor selectivity and efficacy while reducing adverse effects. These engineered OMVs function as natural stimulator of interferon genes (STING) agonists, activating the cyclic GMP-AMP synthase (cGAS)-STING pathway in cancer cells and tumor-associated macrophages (TAMs). Loading engineered OMVs with photoimmunotherapy photosensitizers further enhanced tumor inhibition and STING activation in TAMs. Combining nanobody-engineered OMV-mediated photoimmunotherapy with CD47 blockade effectively suppressed primary and metastatic tumors, establishing sustained antitumor immune memory. This study demonstrates the potential of nanobody-engineered OMVs as STING agonists and provides insights into novel OMV-based immunotherapeutic strategies harnessing the innate immune system against cancer. Our findings open new avenues for OMV applications in tumor immunotherapy, offering a promising approach to overcome current limitations in cancer treatment.

Project description:This study is the first to show transfer of regulatory bacterial sRNAs from bacterial OMVs to host cells. Demonstration of transfer of bacterial sRNA from Pseudomonas aeruginosa OMVs to host cells in two cell types. RNA isolated from PA14 OMV exposed primary human bronchial epithelial cells or CFBE41o- bronchial epithelial cells as well as unexposed control cells was analyzed by small RNA-Seq. Primary cell exposures were performed on two donors and exposures of CFBE41o- cells were done in triplicate.

Project description:Only regulation of tumor-associated macrophages (TAMs) in tumor microenvironment (TME) is always insufficient to achieve satisfactory clinical outcome, and training of central progenitor cells of TAMs in bone marrow is a potential approach. To achieve the whole-course taming of TAMs from central to peripheral, we developed nanohybrids containing bacterial outer membrane vesicle (OMV), GM-CSF and SIRPα-Fc fusion protein, which were coated with calcium phosphate (CaP) shell. The surface CaP coating endowed nanohybrids with safe circulation, allowing them to reach both bone marrow and TME. In bone marrow, OMV and GM-CSF together induced trained immunity of central progenitor cells, indicating by transcriptional alterations and epigenetic remodeling, which was inherited to peripheral TAMs. In peripheral TME, OMV and SIRPα-Fc triggered M1-like TAM phagocytosis with subsequent CD8+ T cell activation.

Project description:Only regulation of tumor-associated macrophages (TAMs) in tumor microenvironment (TME) is always insufficient to achieve satisfactory clinical outcome, and training of central progenitor cells of TAMs in bone marrow is a potential approach. To achieve the whole-course taming of TAMs from central to peripheral, we developed nanohybrids containing bacterial outer membrane vesicle (OMV), GM-CSF and SIRPα-Fc fusion protein, which were coated with calcium phosphate (CaP) shell. The surface CaP coating endowed nanohybrids with safe circulation, allowing them to reach both bone marrow and TME. In bone marrow, OMV and GM-CSF together induced trained immunity of central progenitor cells, indicating by transcriptional alterations and epigenetic remodeling, which was inherited to peripheral TAMs. In peripheral TME, OMV and SIRPα-Fc triggered M1-like TAM phagocytosis with subsequent CD8+ T cell activation.

Project description:Outer membrane vesicles (OMVs) produced by Gram-negative bacteria are mediators of cell survival and pathogenesis by facilitating nutrient transport, virulence factor dissemination, and resistance to antimicrobials. Studies of OMV properties often focus on hypervesiculating Escherichia coli mutants that have increased OMV production when compared to their corresponding wild-type (WT) strains. Currently, two conventional techniques, ultracentrifugation (UC) and ultradiafiltration (UF), are used interchangeably to isolate OMVs, however, there is concern that each technique may inadvertently alter the properties of isolated OMVs during study. To address this concern, we compared two OMV isolation methods, UC and UF, with respect to final OMV quantities, size distributions, and morphologies using a hypervesiculating Escherichia coli K-12 ∆tolA mutant. Cryo-transmission electron microscopy (cryo-TEM) visualization of isolated OMVs revealed distinct morphological differences between wild-type and ∆tolA OMVs, where ∆tolA OMVs isolated by either UC or UF method possessed a greater proportion of OMVs with two or more membranes (39.6-42.4%). Proteomic OMV analysis of WT and ∆tolA OMVs confirmed that ∆tolA enhances inner plasma membrane carryover in multi-lamellar OMVs. This study demonstrates that UC and UF are useful techniques for OMV isolation, where UF may be preferable due to faster isolation, higher OMV yields and enrichment of smaller sized vesicles.

Project description:Microbial molecules have evolved to promote transient and/or permanent associations with mammals. Although numerous examples of secretion systems employed by pathogens have been described, mechanisms by which commensal bacteria export molecules during symbiosis remain unknown. The human gut mutualist Bacteroides fragilis produces a capsular polysaccharide (PSA) that directs host immune development. We reveal herein that outer membrane vesicles (OMVs) deliver PSA to dendritic cells (DCs), promoting regulatory T cells and inducing anti-inflammatory cytokines during protection from intestinal disease. In addition, we found that TLR2 signaling by DCs is required for OMV sensing. Following internalization into DCs and engagement of TLR2, OMVs initiate a gene expression program that results in IL-10 production by DCs. Although it is known that the outcome of PSA sensing by the immune system is Treg induction, nothing is known about the intracellular signaling pathway(s) activated by PSA within DCs. We analyzed the gene expression profile of DCs treated with OMVs to uncover factors that are expressed in a PSA-dependent, TLR2-dependent manner. Our findings demonstrate DC-induced protection from disease via OMV-delivery of a beneficial microbial molecule, uncovering a novel paradigm for inter-kingdom communication between the microbiota and mammals. RNA samples (1ug total RNA) from BMDCs were labeled with fluorescent dyes using the Quick Amp Labeling Kit (Agilent). Microarray (AgilentWhole Mouse Genome chip) hybridizations (65M-BM-0C for 16 hours) and washes were performed with Agilent reagents following standard protocols. Microarrays were analyzed using an Agilent DNA Microarray Scanner G2565CA, and data were acquired using Agilent's Feature Extraction Software version 10.1.1.1. Significant genes were selected based on p< 0.01 and fold change >2.0.

Project description:Outer membrane vesicles (OMV) are spherical structures derived from the outer membrane (OM) of Gram-negative bacteria. OMVs from the predominant gut microbiota members, Bacteroides, are proposed to play key roles in gut homeostasis. OMV biogenesis in Bacteroides is a poorly understood process. Here, we revisited the protein composition of B. theta OMVs by mass spectrometry. We confirmed that OMVs produced by this organism contain large quantities of glycosidases and proteases, with most of them being lipoproteins. We found that many of these OMV-enriched lipoproteins are encoded by polysaccharide utilization loci (PULs), such as the sus operon. We examined the subcellular localization of the components of the sus operon and found that the alpha-amylase SusG is highly enriched in OMVs while the oligosaccharide importer SusC remains mostly in the OM. We show that all OMV-enriched lipoproteins possess a lipoprotein export sequence (LES) that mediates translocation of SusG from the periplasmic face of the OM towards the extracellular milieu and is required for SusG to localize preferentially to OMVs. We also show that surface-exposed SusG in OMVs is active and can rescue growth of bacterial cells incapable of growing on starch as only carbon source. Our results support the role of OMVs as "public goods" that can be utilized by other organisms with different metabolic capabilities.

Project description:Infections caused by carbapenem-resistant Acinetobacter baumannii (CRAb) are associated with high patient morbidity and mortality. The serious threat for human health imposed by CRAb was recently underscored by identification of close-to-untouchable carbapenem- and tetracycline-resistant isolates. Since outer membrane vesicles (OMVs) of Gram-negative bacteria may contribute to antimicrobial resistance, our present study was aimed at investigating OMVs produced by the first two carbapenem- and tetracycline-resistant CRAb isolates in Europe. These isolates, denoted CRAb1 and CRAb2 contain large, nearly identical plasmids that specify multiple resistances. Both isolates produce OMVs that were analyzed by differential light scattering, transmission electron microscopy and proteomics. By comparison with OMVs from the plasmid-free non-carbapenem-resistant A. baumannii isolate Ab1, which is an isogenic ancestor of the CRAb1 isolate, we show that plasmid carriage by the CRAb1 and CRAb2 isolates leads to an increased OMV size that is accompanied by increased diversity of the OMV proteome. Our analyses show that OMVs from CRAb1 and CRAb2 are major reservoirs of proteins involved in antimicrobial resistance, including the plasmid-encoded carbapenemases BlaNDM-1, and BlaOXA-97. We also show that these OMV-borne carbapenemases hydrolyze imipenem and protect otherwise carbapenem-sensitive A. baumannii and Escherichia coli isolates against this antibiotic. Altogether, our observations show that OMVs from highly drug-resistant CRAb confer tolerance against last-resort antibiotics to non-resistant bacterial pathogens.

Project description:Microbial molecules have evolved to promote transient and/or permanent associations with mammals. Although numerous examples of secretion systems employed by pathogens have been described, mechanisms by which commensal bacteria export molecules during symbiosis remain unknown. The human gut mutualist Bacteroides fragilis produces a capsular polysaccharide (PSA) that directs host immune development. We reveal herein that outer membrane vesicles (OMVs) deliver PSA to dendritic cells (DCs), promoting regulatory T cells and inducing anti-inflammatory cytokines during protection from intestinal disease. In addition, we found that TLR2 signaling by DCs is required for OMV sensing. Following internalization into DCs and engagement of TLR2, OMVs initiate a gene expression program that results in IL-10 production by DCs. Although it is known that the outcome of PSA sensing by the immune system is Treg induction, nothing is known about the intracellular signaling pathway(s) activated by PSA within DCs. We analyzed the gene expression profile of DCs treated with OMVs to uncover factors that are expressed in a PSA-dependent, TLR2-dependent manner. Our findings demonstrate DC-induced protection from disease via OMV-delivery of a beneficial microbial molecule, uncovering a novel paradigm for inter-kingdom communication between the microbiota and mammals.

Project description:Sensing of microbes activates the immune system, depending on functional mitochondria. However, pathogenic bacteria inhibit mitochondria activity by delivering toxins via outer membrane vesicles (OMVs). How innate immune cells respond to pathogenic microbes that target mitochondria remains unclear. Here, we show that macrophages induce mitochondrial apoptosis and the NLRP3 inflammasome in response OMVs. Macrophages treated with OMVs and toxins that cause mitochondria dysfunction cease host protein translation which depletes pro-survival BCL-2 family member, MCL-1, and induces BAK-dependent mitochondrial apoptosis. Mitochondrial apoptosis and potassium ion efflux activate the NLRP3 inflammasome after OMV exposure. Importantly, mitochondrial apoptosis modulates IL-1 serum levels in response to OMVs. Our data highlight how innate immune cells sense infections by monitoring mitochondrial health.