Project description:The dogma that adaptive immunity is the only arm of the immune response with memory capacity has been recently challenged by several studies demonstrating evidence for memory-like innate immune training. However, the underlying mechanisms and location for generating such innate memory responses in vivo remains unknown. Here we show that access of Bacillus Calmette­Guérin (BCG) to the bone marrow (BM) following intravenous immunization induced local hematopoietic stem cell (HSC) expansion and enhanced myelopoiesis at the expense of lymphopoiesis. Importantly, HSC reprogramming led to the generation of epigenetically­modified macrophages that provided significantly better protection against virulent M. tuberculosis infection than naïve macrophages. By using parabiotic and chimeric mice as well as adoptive transfer approaches, we demonstrate that training of the monocyte/macrophage lineage via BCG­induced HSC reprogramming is sustainable in vivo. Our results indicate that targeting the HSC compartment provides a novel approach for vaccine development.

Project description:The dogma that adaptive immunity is the only arm of the immune response with memory capacity has been recently challenged by several studies demonstrating evidence for memory-like innate immune training. However, the underlying mechanisms and location for generating such innate memory responses in vivo remains unknown. Here we show that access of Bacillus Calmette­Guérin (BCG) to the bone marrow (BM) following intravenous immunization induced local hematopoietic stem cell (HSC) expansion and enhanced myelopoiesis at the expense of lymphopoiesis. Importantly, HSC reprogramming led to the generation of epigenetically­modified macrophages that provided significantly better protection against virulent M. tuberculosis infection than naïve macrophages. By using parabiotic and chimeric mice as well as adoptive transfer approaches, we demonstrate that training of the monocyte/macrophage lineage via BCG­induced HSC reprogramming is sustainable in vivo. Our results indicate that targeting the HSC compartment provides a novel approach for vaccine development.

Project description:The dogma that adaptive immunity is the only arm of the immune response with memory capacity has been recently challenged by several studies demonstrating evidence for memory-like innate immune training. However, the underlying mechanisms and location for generating such innate memory responses in vivo remains unknown. Here we show that access of Bacillus Calmette-Guérin (BCG) to the bone marrow (BM) changes the transcriptional landscape of hematopoietic stem cells (HSC) and multipotent progenitors (MPP) leading to local cell expansion and enhanced myelopoiesis at the expense of lymphopoiesis. Importantly, BCG-educated HSCs generate epigenetically-modified macrophages that provide significantly better protection against virulent M. tuberculosis infection than naïve macrophages. By using parabiotic and chimeric mice as well as adoptive transfer approaches, we demonstrate that training of the monocyte/macrophage lineage via BCG-induced HSC reprogramming is sustainable in vivo. Our results indicate that targeting the HSC compartment provides a novel approach for vaccine development.

Project description:Innate immune memory is a vital mechanism of myeloid cell plasticity that occurs in response to environmental stimuli and alters subsequent immune responses. Two types of immunological imprinting can be distinguished—training and tolerance. These are epigenetically mediated and enhance or suppress subsequent inflammation, respectively. Whether immune memory occurs in tissue-resident macrophages in vivo and how it may affect pathology remains largely unknown. Here we demonstrate that peripherally applied inflammatory stimuli induce acute immune training and tolerance in the brain and lead to differential epigenetic reprogramming of brain-resident macrophages (microglia) that persists for at least six months. Strikingly, in a mouse model of Alzheimer’s pathology, immune training exacerbates cerebral beta-amyloidosis and immune tolerance alleviates it; similarly, peripheral immune stimulation modifies pathological features after stroke. Our results identify immune memory in the brain as an important modifier of neuropathology.

Project description:Innate immune memory is a vital mechanism of myeloid cell plasticity that occurs in response to environmental stimuli and alters subsequent immune responses. Two types of immunological imprinting can be distinguished—training and tolerance. These are epigenetically mediated and enhance or suppress subsequent inflammation, respectively. Whether immune memory occurs in tissue-resident macrophages in vivo and how it may affect pathology remains largely unknown. Here we demonstrate that peripherally applied inflammatory stimuli induce acute immune training and tolerance in the brain and lead to differential epigenetic reprogramming of brain-resident macrophages (microglia) that persists for at least six months. Strikingly, in a mouse model of Alzheimer’s pathology, immune training exacerbates cerebral beta-amyloidosis and immune tolerance alleviates it; similarly, peripheral immune stimulation modifies pathological features after stroke. Our results identify immune memory in the brain as an important modifier of neuropathology.

Project description:Besides centrally induced innate immune memory/trained immunity in the bone marrow/peripheral blood by parenteral vaccination or infection, recently emerging evidence suggests that the barrier mucosal tissue-resident innate immune memory may develop via a local inflammatory pathway following mucosal immunologic exposure. However, it remains unclear whether the mucosal-resident innate immune memory may result from integrating distally generated immunological signals following parenteral vaccination/infection.  We show here that subcutaneous Bacillus Calmette-Guérin (BCG) vaccination is able to induce memory alveolar macrophages (AM) and trained immunity at the respiratory barrier mucosa. Although parenteral BCG vaccine can centrally train bone marrow progenitors and circulating monocytes, induction of memory AM is entirely independent of circulating monocytes. Rather, parenteral BCG vaccination, via distal mycobacterial dissemination, causes a time-dependent alteration in gut microbiome, barrier function and microbial metabolites including short-chain fatty acids, and subsequently the changes in circulating and lung tissue metabolites, leading to induction of tissue-resident memory macrophages and trained innate immunity in the lung. Our study thus reveals a novel gut microbiota-mediated pathway for innate immune memory development at distal barrier mucosal tissues. Our findings have far-reaching implications in developing next-generation parenteral vaccine strategies against respiratory pathogens such as M.tb.

Project description:Besides centrally induced innate immune memory/trained immunity in the bone marrow/peripheral blood by parenteral vaccination or infection, recently emerging evidence suggests that the barrier mucosal tissue-resident innate immune memory may develop via a local inflammatory pathway following mucosal immunologic exposure. However, it remains unclear whether the mucosal-resident innate immune memory may result from integrating distally generated immunological signals following parenteral vaccination/infection.  We show here that subcutaneous Bacillus Calmette-Guérin (BCG) vaccination is able to induce memory alveolar macrophages (AM) and trained immunity at the respiratory barrier mucosa. Although parenteral BCG vaccine can centrally train bone marrow progenitors and circulating monocytes, induction of memory AM is entirely independent of circulating monocytes. Rather, parenteral BCG vaccination, via distal mycobacterial dissemination, causes a time-dependent alteration in gut microbiome, barrier function and microbial metabolites including short-chain fatty acids, and subsequently the changes in circulating and lung tissue metabolites, leading to induction of tissue-resident memory macrophages and trained innate immunity in the lung. Our study thus reveals a novel gut microbiota-mediated pathway for innate immune memory development at distal barrier mucosal tissues. Our findings have far-reaching implications in developing next-generation parenteral vaccine strategies against respiratory pathogens such as M.tb.

Project description:Trained immunity is the phenomenon whereby innate immune cells such as monocytes or macrophages undergo functional reprogramming after exposure to certain microbial components, altering their responses to future exposures. This study profiled the transcriptomes of human monocytes responding to two different BCG vaccine strains.

Project description:BCG reprogramming of hematopoietic stem cells generates protective innate immunity against tuberculosis

Project description:Trained immunity is a phenomenon whereby innate immune cells such as monocytes or macrophages undergo functional reprogramming after exposure to certain microbial components, altering their responses to future exposures. This study profiled the transcriptomes of human monocytes responding to two different BCG vaccine strains.