Project description:Trained immunity is defined by increased inflammatory cytokine production by macrophages that are sequentially activated by two stimuli, separated by a resting period. The models used to study trained immunity should reflect the definition of this process, which includes five different steps. Here, we developed an in vitro methodology to study trained immunity using murine bone marrow-derived macrophages (BMDM), following sequential stimulation with β-glucan and lipopolysaccharide (LPS). Kinetic analysis of cytokine production demonstrated, for the first time, that trained BMDM secrete high levels of tumor necrosis factor (TNF) and interleukin 6 (IL6) following stimulation with β-glucan (stimulus 1), compared to unstimulated BMDM (step 1). After a resting period, trained BMDM do not secrete significant levels of these cytokines (step 2), but rapidly produce enhanced levels of TNF and IL6 after secondary stimulation with LPS (stimulus 2), compared to BMDM stimulated with either β-glucan (step 3) or LPS (step 4) alone. In addition, the sum of cytokine levels produced by both BMDM stimulated with either β-glucan (stimulus 1) or LPS (stimulus 2) individually, was significantly lower than the cytokine levels produced by trained BMDM stimulated with both β-glucan and LPS (stimulus 1+2) (step 5). Our findings also demonstrate that trained BMDM produce higher levels of serum amyloid A3 (SAA3) protein due to metabolic and epigenetic reprogramming. Functionally, trained BMDM upregulate the expression of stimulatory molecules such as MHC-II, CD80, CD86, OX40L and PDL1; downregulate the inhibitory molecules ICOSL and CD206; and induce CD4+ and CD8+ T cell proliferation in vitro through a cell contact-dependent mechanism. Our results also revealed strain-specific differences in the training response among mice, the negative impact of cell cryopreservation on trained immunity, and the potential use of genetically modified mice in elucidating mechanistic pathways through which different training stimuli may induce long-lived memory macrophages. These results also highlight the applicability of mouse in vitro methods as an additional tool to study trained immunity, as the use of inbred mice reduce the genetic variability present in humans and minimize variables that affect trained immunity such as infections, vaccinations and lifestyle-related stimuli. The standardization of trained immunity protocols using murine BMDM will facilitate the development of therapeutic strategies that target the innate immune memory response for the treatment of multiple immune-based diseases.

Project description:Trained immunity is defined by increased inflammatory cytokine production by macrophages that are sequentially activated by two stimuli, separated by a resting period. The models used to study trained immunity should reflect the definition of this process, which includes five different steps. Here, we developed an in vitro methodology to study trained immunity using murine bone marrow-derived macrophages (BMDM), following sequential stimulation with β-glucan and lipopolysaccharide (LPS). Kinetic analysis of cytokine production demonstrated, for the first time, that trained BMDM secrete high levels of tumor necrosis factor (TNF) and interleukin 6 (IL6) following stimulation with β-glucan (stimulus 1), compared to unstimulated BMDM (step 1). After a resting period, trained BMDM do not secrete significant levels of these cytokines (step 2), but rapidly produce enhanced levels of TNF and IL6 after secondary stimulation with LPS (stimulus 2), compared to BMDM stimulated with either β-glucan (step 3) or LPS (step 4) alone. In addition, the sum of cytokine levels produced by both BMDM stimulated with either β-glucan (stimulus 1) or LPS (stimulus 2) individually, was significantly lower than the cytokine levels produced by trained BMDM stimulated with both β-glucan and LPS (stimulus 1+2) (step 5). Our findings also demonstrate that trained BMDM produce higher levels of serum amyloid A3 (SAA3) protein due to metabolic and epigenetic reprogramming. Functionally, trained BMDM upregulate the expression of stimulatory molecules such as MHC-II, CD80, CD86, OX40L and PDL1; downregulate the inhibitory molecules ICOSL and CD206; and induce CD4+ and CD8+ T cell proliferation in vitro through a cell contact-dependent mechanism. Our results also revealed strain-specific differences in the training response among mice, the negative impact of cell cryopreservation on trained immunity, and the potential use of genetically modified mice in elucidating mechanistic pathways through which different training stimuli may induce long-lived memory macrophages. These results also highlight the applicability of mouse in vitro methods as an additional tool to study trained immunity, as the use of inbred mice reduce the genetic variability present in humans and minimize variables that affect trained immunity such as infections, vaccinations and lifestyle-related stimuli. The standardization of trained immunity protocols using murine BMDM will facilitate the development of therapeutic strategies that target the innate immune memory response for the treatment of multiple immune-based diseases.

Project description:The capacity of innate immune cells to build immunological memory after a first encounter with certain pathogens or vaccines that allow them to respond stronger to reinfection is referred to as “trained immunity”. Despite few studies highlighting an important role for trained immunity in protection during COVID-19 infection or vaccination, no study so far has shown whether SARS-CoV-2 can train innate immune cells to respond stronger to a second stimuli. The aim of this study was to investigate whether this virus can induce trained immunity in human monocytes. To this purpose we used monocytes from healthy donors and exposed them to inactivated (i) SARS -CoV-2 for 24 hours followed by a resting period of several days in medium only and restimulation on day 6. On day 6, to evaluate the effects of iSARS-CoV-2 training on monocyte gene expression, transcriptomic analysis of human monocytes, before or 3h after LPS stimulation, was done. Our data provide the transcriptional profile of untrained and trained monocytes with iSARS-CoV-2.

Project description:Trained innate immunity has been shown for human macrophages, i.e. a primary stimulation with specific compounds such as Beta-glucans, BCG vaccine or oxidized LDL generates an innate memory capacity that leads to an amplified pro-inflammatory reaction to various microbial components when restimulated days later. In this study, phorbol ester differentiated THP-1 cells were used as a model for human macrophages. The aim of this experiment was to map the biological processes involved in DCATH-2 peptide trained THP-1 cells versus control cells without restimulation and after restimulation with lipopolysaccharides.

Project description:Anterior interpositus nucleus (AIN) is a proposed site of memory formation of eyeblink conditioning. A large part of the underlying molecular events, however, remains unknown. To elucidate molecular mechanisms, we examined transcriptional changes in the AIN of mice trained with delayed-type eyeblink conditioning Experiment Overall Design: 7-d paired training group: Mice received a surgery for implanting four Teflon-coated stainless-steel wires in their left eyelid and a headstage on their head. After 3daysâ?? recovery, they were trained with paired paradigm of conditioned stimulus (CS) and unconditioned stimulus (US) for 7 days: A 352-ms tone CS (1kHz, 83~85dB) was delivered first and a 100ms periorbital shock US (100kHz square pluses) were delivered with 252ms after the onset of CS, and they co-terminated. In case of 7-d unpaired training group, A CS and a US were delivered in an explicitly unpaired, pseudorandomized manner for 7 days. After the last trial was given, anterior interpositus was immediately sampled in 10 to 30 min from the sacrifice.

Project description:We used a custom-designed microarray to characterize the transcriptional response that accompanies longt-term sensitization training in the marine mollusk Aplysia californica. We characterized transcription for a new memory (1 day after training), a forgotten memory (8 days after training) and for a long-term savings memory (8 days after training but 1 day after a reminder that re-instates the sensitization memory). All animals received a 1-day unilateral LTS training protocol (4 rounds of noxious shock at 30 min intervals, each shock 10s of 1/2s off 1/2on 90mA 60-hz biphasic square-wave shock). This produced robust sensitization in all animals (measured as an increase in T-SWR response from baseline to 24h after training). In the forgetting condition, animals received training on day 1, and post-tests on days 7 and 8 showed little-to-no evidence of recall (T-SWR responses on the trained side returned to close to baseline). In the savings condition, animals received training on day 1 that produced strong sensitization, showed forgetting on day 7, and then received a weak bilateral shock as a reminder (day 7), producing a long-term savings memory on day 8 (a re-instatement of the behavioral expression of sensitization on the previously trained side). In the new memory condition, animals received sham training on day 1, then real training on day 7, producing robust sensitization measured on day 8. Pleural ganglia were harvested on day 8. Samples from a left-trained and right-trained animal were combined to smooth out lateralized gene expression. The pleural ganglia contains the VC nociceptors, which are thought to play a primary role in expressing LTS memory.

Project description:Trained immunity is a form of innate immune memory characterized by epigenetic and metabolic reprogramming in response to specific stimuli. This rewiring can result in increased cytokine and effector responses to pathogenic challenge, providing non-specific protection against disease. It may also improve immune responses to established immunotherapeutics and vaccines. Despite the promise of training for next-generation therapeutic design, most current understanding and experimentation is conducted with complex and heterogeneous biologically derived molecules, such as β-glucan or the BCG vaccine. This limited collection of training compounds also limits study of the genes most involved in training responses as each molecule has both training and non-training effects. Small molecules with tunable pharmacokinetics and delivery modalities would both assist in the study of trained immunity and its future application for therapeutics. To identify novel small molecule inducers of trained immunity, we screened a library of 2000 drugs and drug-like compounds. Identification of well-defined compounds can improve our understanding of innate immune memory and broaden the scope of its clinical applications. We identified over 2 dozen small molecules in several chemical classes, including the traditionally immunosuppressive glucocorticoids, that induce a training phenotype in the absence of initial immune activation – a current limitation of reported inducers of training. We chose 7 of these top candidates to characterize and establish training activity in vivo. In this work, we expand the number of compounds known to induce trained immunity, creating new avenues for the study and application of innate immune training.

Project description:Environmental microbial triggers shape the development and functionality of the immune system. Alveolar macrophages (AMs), tissue-resident macrophages of the lungs, are in constant and direct contact with inhaled particles and microbes. Such exposures likely impact AM reactivity to subsequent challenges by immunological imprinting mechanisms referred to as trained immunity. Here, we investigated whether a ubiquitous microbial compound has the potential to induce AM training in vivo. We showed that intranasal exposure to ambient amounts of lipopolysaccharide (LPS) protected mice from bacterial pneumonia six days later and discovered a pronounced AM memory response, characterized by enhanced reactivity upon pneumococcal challenge. Exploring the mechanistic basis of AM training, we identified a critical role of type 1 interferon signaling and found that trained AMs displayed a substantially modulated metabolite and lipid composition. Inhibition of fatty acid oxidation and glutaminolysis significantly attenuated the training effect, suggesting a key function of metabolic rewiring in LPS-induced AM memory. Collectively, our findings demonstrate the profound impact of ambient microbial exposure on pulmonary immune memory and highlight tissue-specific features of trained immunity.

Project description:Environmental microbial triggers shape the development and functionality of the immune system. Alveolar macrophages (AMs), tissue-resident macrophages of the lungs, are in constant and direct contact with inhaled particles and microbes. Such exposures likely impact AM reactivity to subsequent challenges by immunological imprinting mechanisms referred to as trained immunity. Here, we investigated whether a ubiquitous microbial compound has the potential to induce AM training in vivo. We showed that intranasal exposure to ambient amounts of lipopolysaccharide (LPS) protected mice from bacterial pneumonia six days later and discovered a pronounced AM memory response, characterized by enhanced reactivity upon pneumococcal challenge. Exploring the mechanistic basis of AM training, we identified a critical role of type 1 interferon signaling and found that trained AMs displayed a substantially modulated metabolite and lipid composition. Inhibition of fatty acid oxidation and glutaminolysis significantly attenuated the training effect, suggesting a key function of metabolic rewiring in LPS-induced AM memory. Collectively, our findings demonstrate the profound impact of ambient microbial exposure on pulmonary immune memory and highlight tissue-specific features of trained immunity.

Project description:Plant memory is a tool for plants that they can use to increase their fitness and cope with adverse environmental stresses. In this study, mRNA-seq., WGBS and RT-qPCR methods were applied for evaluating formation and maintenance of somatic transcriptional memory after treatment with ultrasound and drought stimuli in tomatoes. In addition, effects of repeated stimuli, as well as association-forming ability of plants were studied when they were trained previously with combined stimuli. 48 h after exposure to the two stimuli applied alone or in combination, significantly altered gene transcription and DNA methylation were revealed but there was no correlation between these changes. Using four selected target genes, we have proven that plants memorized stimuli for 5 to 10 days, in a gene-, and stimulus-dependent way. The repeated application of the stimuli caused altered behavior, such as habituation, sustained induction or modified re-induction, depending on the genes and physiological ages of plants. Plants were able to use one conditioned stimulus as a predictor of the other, unconditioned one, after conditioning in the case of 3 out of 4 target genes, and use their transcriptional memory associatively.