Project description:Understanding the molecular defense mechanism of macrophages and identifying their effector molecules against malarial parasites may provide important clues for the discovery of new therapies. To analyze the immunological responses of malarial parasite-induced macrophages, we used DNA microarray technology to examine the gene profile of differentiated macrophages phagocytizing Plasmodium falciparum-parasitized erythrocytes (iRBCs). The transcriptional gene profile of macrophages in response to iRBCs represented 168 down-regulated genes, which were mainly involved in the cellular immune response, and 216 upregulated genes, which were involved in cellular proteolysis, growth, and adhesion. Importantly, the specific upregulation of β-defensin 130 (DEFB130) in these macrophages suggested a possible role for DEFB130 in malarial parasite elimination. Strikingly, differentiated macrophages phagocytizing iRBCs exhibited an increase in intracellular DEFB130 levels and DEFB130 appeared to accumulate at the site of iRBC engulfment. Furthermore, DEFB130 synthetic peptide exhibited a modest toxic effect on P. falciparum in vitro and P. yoelii in vivo, unlike scrambled DEFB130 peptide, which showed no antiplasmodial activity. Our data broaden our knowledge of the immunological response of macrophages to iRBCs and shed light on a new target for therapeutic intervention.

Project description:Erythrocyte binding-like (EBL) proteins are known to play an important role in malaria parasite invasion; however, any roles in regulating host immune responses remain unknown. Here we show that an amino acid substitution (C741Y) in the protein trafficking domain of Plasmodium yoelii EBL (PyEBL) changes host immune response and disease severity, but not invasion of red blood cells (RBCs) as suggested previously. The C741Y substitution alters protein processing and trafficking in merozoites and in the cytoplasm of iRBCs, reduces its binding to Band 3, increases phosphatidylserine (PS) surface exposure, and elevates osmotic fragility of iRBCs. The modified iRBC surface triggers PS-CD36 mediated phagocytosis of iRBCs, host type I interferon (IFN-I) signaling, and T cell differentiation, leading to improved host survival. This study reveals a previously unknown role of PyEBL in regulating the innate immune response and host-pathogen interaction, which may be explored for developing disease control strategies.

Project description:Circadian biology regulates inflammatory responses in mice via the clock protein REVERBα, resulting in altered mortality and morbidity. The influence of this immune-modulation pathway in humans is unclear, but may affect outcomes after transplant. We sought to determine whether the circadian clock affects primary graft dysfunction after lung transplantation, and the role of the clock protein REVERBα. In this study we investigated the action of a synthetic REVERB ligand, (GSK4112) in human monocyte-derived macrophages.

Project description:In the immune system various parameters and immune functions are controlled by the circadian system. To investigate molecular mechanisms that link the circadian clock and the immune system we analyzed the transcriptom of peritoneal macrophages from mice collected in a time course for two consecutive days. We found that more than 8% of expressed genes are under circadian control including many important regulators in pathogen recognition, signal transduction and cytokine secretion. Peritoneal macrophages from mice kept in constant conditions were isolated in 4 h intervalls over a period of 48 h. RNA of CD11b sorted cells was extracted, pooled from 3 mice per time point and used for microarray analysis.

Project description:Introduction Malaria remains a significant global health problem, particularly due to the human malaria parasite Plasmodium falciparum, which is responsible for most fatal infections. Infected red blood cells (iRBCs) evade spleen clearance by adhering to endothelial cells (ECs), triggering capillary blockage, inflammatory cytokine release, endothelial dysfunction, and altered vascular permeability, prompting an endothelial transcriptional response. Methods The iRBCIT4var04/HBEC-5i model, where iRBCs present IT4var04 (VAR2CSA) on their surface was employed to analyse the effects of iRBC binding on ECs. We used this model to investigate how cytoadhesion of iRBCs to ECs influences their expression profile depending on the temperature (37°C vs 40°C). Results Binding of non-infected RBCs (niRBCs) and fever alone significantly changes expression of hundreds of genes in ECs. Comparing the expression profile of HBEC-5i cultured either in the presence of iRBCs or in the presence of niRBCs, genes encoding proteins assigned to the GO terms immune response, nucleosome assembly, NF-kappa B signaling, angiogenesis, and antiviral immune response/interferon-alpha/beta signaling pathway were significantly up-regulated. If the cultivation temperature is increased from 37°C to 40°C, which simulates fever, a further significant increase in expression can be observed for most regulated genes, especially for genes coding for cytokines and proteins involved in angiogenesis. Conclusion The presence of iRBCs leads to the stimulation of ECs, activating several immunological signaling pathways and affecting antiviral (-parasitic) mechanisms and angiogenesis. Furthermore, to our knowledge, the induction of the interferon-alpha/beta signaling pathway in ECs in response to iRBCs has been described for the first time.

Project description:In the immune system various parameters and immune functions are controlled by the circadian system. To investigate molecular mechanisms that link the circadian clock and the immune system we analyzed the transcriptom of peritoneal macrophages from mice collected in a time course for two consecutive days. We found that more than 8% of expressed genes are under circadian control including many important regulators in pathogen recognition, signal transduction and cytokine secretion.

Project description:A variant of the TNFSF13B gene (BAFF-var) increases the production of the cytokine BAFF, up-regulating humoral immunity and increasing the risk for certain autoimmune diseases. BAFF-var was evolutionarily advantageous, most likely by increasing resistance to malaria infection. We assessed experimentally the role of BAFF-var in response to malaria antigens. Lysates of erythrocytes infected with Plasmodium falciparum (iRBCs) or left uninfected (uRBCs, control) were used to treat PBMCs with distinct BAFF genotypes. PBMCs purified from BAFF-var donors and treated with iRBCs showed different levels of specific cells, immunoglobulins and cytokines as compared with BAFF-WT. In particularly a relevant differential effect on mucosal immunity B subpopulations have been observed. RNA sequencing of total B cells, purified from PBMC treated with iRBCs or uRBCs, identified several transcripts differentially expressed including some that encoded proteins critical for the response to malaria infection. These findings point to specific immune cells and molecules through which the evolutionary selected BAFF-var may have improved fitness during P. falciparum infection.

Project description:As a circadian organ, liver executes diverse functions in different phase of the circadian clock. This process is believed to be driven by a transcription program. Here, we present a TF DNA-binding activity centered multi-dimensional proteomics landscape, including DNA-binding activity of TFs, the phosphorylation pattern, ubiquitylation pattern, the nuclear sub-proteome, the whole proteome as well as the transcriptome, to portrait the hierarchical circadian clock network of mouse liver. The TF DNA-binding activity indicates diurnal oscillation in four major pathways, immune response, glucose metabolism, fatty acid metabolism, and the cell cycle. We also isolated the mouse liver Kupffer cells and measured their proteomes in the circadian clock to reveal cell type resolved circadian clock. These are the most comprehensive datasets for circadian clock in the mouse liver and provided the richest data resource for the understanding of mouse liver physiology around the circadian clock.

Project description:As a circadian organ, liver executes diverse functions in different phase of the circadian clock. This process is believed to be driven by a transcription program. Here, we present a TF DNA-binding activity centered multi-dimensional proteomics landscape, including DNA-binding activity of TFs, the phosphorylation pattern, ubiquitylation pattern, the nuclear sub-proteome, the whole proteome as well as the transcriptome, to portrait the hierarchical circadian clock network of mouse liver. The TF DNA-binding activity indicates diurnal oscillation in four major pathways, immune response, glucose metabolism, fatty acid metabolism, and the cell cycle. We also isolated the mouse liver Kupffer cells and measured their proteomes in the circadian clock to reveal cell type resolved circadian clock. These are the most comprehensive datasets for circadian clock in the mouse liver and provided the richest data resource for the understanding of mouse liver physiology around the circadian clock.

Project description:Though it is well established that immunological functions of CD4+ T cells are time of day-dependent, the underlying molecular mechanisms remain largely obscure. To address the question whether T cells themselves harbor a functional clock driving circadian rhythms of immune function, we analyzed clock gene expression and immune responses of CD4+ T cells purified from blood of healthy subjects at different time points throughout the day. Circadian clock function as well as immune function was further analyzed in cultivated T cells and circadian clock reporter systems. We found robust rhythms of clock gene expression as well as, after stimulation, of IFN-g production and CD40L expression in both freshly isolated and in cultured CD4+ T cells. Moreover, circadian luciferase reporter activities in CD4+ T cells and in thymic sections from PER2::LUCIFERASE reporter mice suggest that endogenous T cell clock rhythms are self-sustained under constant culture conditions. Microarray analysis of stimulated CD4+ T cell cultures revealed a rhythmic regulation of the NF-kB pathway as a candidate mechanism regulating circadian immune responses. Collectively, these data demonstrate for the first time that CD4+ T cell responses are regulated by an intrinsic cellular circadian oscillator capable of driving rhythmic adaptive immune responses in vitro and in vivo. The study is designed with 3 biological replicates from three different time points.