Project description:Probiotic administration effect on microbiome composition, emotional memory and decision-making

Project description:Cellular decisions leading to a sustained cellular migration constitute a critical parameter during wound healing and metastasis. Cellular decision processes for migration involve signaling pathways as well as gene expression regulation that have been not yet studied in an integrated way. Here, heterologous cocultures combining primary human keratinocytes and genetically defined murine fibroblasts served as a model for wound healing of human skin to gain a systemic view of the underlying principles of cellular decision making towards migration. By inverse modeling of time series of gene expression data followed by experimental validation we show that (I) pulse-like activation of the proto-oncogene receptor Met by its ligand HGF triggers a responsive system state, (II) permanent, time sequential activation of the EGF-receptor is required to initiate and sustain migration, and (III), context information for enhancing, delaying or stopping migration is provided via the activity of the PKA-signaling pathway. Our study reveals a complex orchestration of events controlling cell migration.

Project description:Cellular decisions leading to a sustained cellular migration constitute a critical parameter during wound healing and metastasis. Cellular decision processes for migration involve signaling pathways as well as gene expression regulation that have been not yet studied in an integrated way. Here, heterologous cocultures combining primary human keratinocytes and genetically defined murine fibroblasts served as a model for wound healing of human skin to gain a systemic view of the underlying principles of cellular decision making towards migration. By inverse modeling of time series of gene expression data followed by experimental validation we show that (I) pulse-like activation of the proto-oncogene receptor Met by its ligand HGF triggers a responsive system state, (II) permanent, time sequential activation of the EGF-receptor is required to initiate and sustain migration, and (III), context information for enhancing, delaying or stopping migration is provided via the activity of the PKA-signaling pathway. Our study reveals a complex orchestration of events controlling cell migration.

Project description:Somatic cells acclimate to changes in the environment by temporary reprogramming. Much has been learned about transcription factors that induce these cell-state switches in both plants and animals, but how cells rapidly modulate their proteome remains elusive. Here, we show rapid induction of autophagy during temporary reprogramming in plants triggered by phytohormones, immune and danger signals. Quantitative proteomics following sequential reprogramming revealed that autophagy is required for timely decay of previous cellular states and for tweaking the proteome to acclimate to the new conditions. Signatures of previous cellular programs thus persist in autophagy deficient cells, affecting cellular decision-making. Concordantly, autophagy deficient cells fail to acclimatize to dynamic climate changes. Similarly, they have defects in dedifferentiating into pluripotent stem cells, and redifferentiation during organogenesis. These observations indicate that autophagy mediates cell state switches that underlie somatic cell reprogramming in plants and possibly other organisms, and thereby promotes phenotypic plasticity.

Project description:Granulomas are immune cell aggregates formed in response to persistent inflammatory stimuli. Granuloma macrophage subsets are diverse and carry varying copy numbers of their genomic information. The molecular programs that control the differentiation of such macrophage populations in response to a chronic stimulus, though critical for disease outcome, have not been defined. In this study, we performed scRNA-Seq experiments to gain insights into the transcriptional regulation of polyploid macrophage differentiation in response to chronically persistent inflammatory stimuli.

Project description:Inflammation is a physiopathological process triggered by infection or tissue damage. Immune system initiates coordinated sequential steps in response to these danger signals. Once the threat has been contained inflammation has to be subsequently shut down. Inflammation resolution is initiated by the reprogramming of pro-inflammatory macrophages toward a pro-resolving profile. This reprogramming is induced in particular by the non-phlogistic engulfment of apoptotic cells, mostly apoptotic neutrophils, a process called efferocytosis. As a matter of fact, macrophages are an essential linchpin regulating both inflammation triggering and sustaining and inflammation resolution. This duality can be achieved through the tremendous plasticity of these innate immune cells. Indeed, depending on microenvironmental signals (cytokines, efferocytosis, growth factors…) macrophages can adopt numerous diverse and sometimes antagonistic phenotypes. The mechanisms governing these transitions remain relatively scattered especially in human. With this project we propose to explore the mechanisms involved in human macrophage reprogramming toward a pro-resolving profile after efferocytosis. The stakes are high due to the estimated prevalence of chronic inflammatory diseases in Western society is 5 to 7%. Chronic inflammation is a burden to patient due to life-long debilitating illness and increased mortality and is also a burden to society due to high costs for therapy and care. Finding new therapies to limit chronic inflammation establishment and persistence is thus a highly valuable goal.

Project description:During a viral infection, CD8 T cells encounter a myriad of antigenic and inflammatory signals of variable strength, which sets off each individual T cell on a unique differentiation trajectory. However, the developmental path for each of these cells will ultimately lead to one of only two potential outcomes after clearance of the infection—death or survival and development into memory CD8 T cells. How this cell fate decision is made remains incompletely understood. In this study, we explore the dynamic transcriptional changes during effector and memory CD8 T cell differentiation at the single cell level.

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:The diversity of human immune responses to P. falciparum is unknown and yet immune decision-making likely dictates outcome of infection We infected 15 malaria-naïve human volunteers with P. falciparum and used longitudinal whole blood transcriptional profiling to independently analyse the immune response in every volunteer