Cooperative Stimulation of Dendritic Cells by Cryptococcus neoformans Mannoproteins and CpG Oligodeoxynucleotides

While mannosylation targets antigens to mannose receptors on dendritic cells (DC), the resultant immune response is suboptimal. We hypothesized that the addition of toll-like receptor (TLR) ligands would enhance the DC response to mannosylated antigens. Cryptococcus neoformans mannoproteins (MP) synergized with CpG-containing oligodeoxynucleotides to stimulate enhanced production of proinflammatory cytokines and chemokines from murine conventional and plasmacytoid DC. Synergistic stimulation required the interaction of mannose residues on MP with the macrophage mannose receptor (MR), CD206. Moreover, synergy with MP was observed with other TLR ligands, including tripalmitoylated lipopeptide (Pam3CSK4), polyinosine-polycytidylic acid (pI:C), and imiquimod. Finally, CpG enhanced MP-specific MHC II-restricted CD4+ T-cell responses by a mechanism dependent upon DC expression of CD206 and TLR9. These data suggest a rationale for vaccination strategies that combine mannosylated antigens with TLR ligands and imply that immune responses to naturally mannosylated antigens on pathogens may be greatly augmented if TLR and MR are cooperatively stimulated.National Institutes of Health (RO1 AI25780, RO1 AI37532, K08 AI 53542

Driving chronicity in rheumatoid arthritis: perpetuating role of myeloid cells

Acute inflammation is a complex and tightly regulated homeostatic process that includes leukocyte migration from the vasculature into tissues to eliminate the pathogen/injury, followed by a pro-resolving response promoting tissue repair. However, if inflammation is uncontrolled as in chronic diseases such as Rheumatoid Arthritis (RA) it leads to tissue damage and disability. Synovial tissue inflammation in RA patients is maintained by sustained activation of multiple inflammatory positive-feedback regulatory pathways in a variety of cells including myeloid cells. In this review, we will highlight recent evidence uncovering biological mechanisms contributing to the aberrant activation of myeloid cells that contributes to perpetuation of inflammation in RA, and discuss emerging data on anti-inflammatory mediators contributing to sustained remission that may inform a novel category of therapeutic targets

Examining the role of insulin in the regulation of cardiovascular health

A substantial body of evidence has reported that insulin has direct actions on the cardiovascular system independent of its systemic effects on plasma glucose or lipids. In particular, insulin regulates endothelial synthesis of the vasoactive mediators nitric oxide and endothelin-1, yet the importance of this in the maintenance of cardiovascular health remains poorly understood. Recent studies using animals with targeted downregulation of insulin signaling in vascular tissues are improving our understanding of the role of insulin in vascular health. This article focuses on the direct actions of insulin in cardiovascular tissues, with particular emphasis on the molecular mechanisms of insulin action on endothelial function. The potential contribution of impaired vascular insulin action to the cardiovascular complications of diabetes will also be discussed

Histone deacetylase 2-mediated deacetylation of the Ribonuclease 1 promoter in inflamed human endothelial cells

Endothelial cells (ECs) function as protective barrier to separate the blood from the surrounding tissue by conducting crucial roles in regulation and maintenance of vascular homeostasis, such as control of vessel permeability or coagulation. Therefore, dysfunction of the EC barrier due to inflammation, infection or injury can cause a variety of vascular pathologies, such as thrombosis or atherosclerosis. In this context, the circulating extracellular endonuclease Ribonuclease 1 (RNase1) was identified as a vessel- and tissue-protective enzyme and a potent regulator of vascular homeostasis. Upon acute inflammation, RNase1 functions as a natural counterpart to extracellular RNA (eRNA), a damage-associated molecular pattern, via degradation to protect the EC cell layer from excessive inflammation. However, long-term inflammation disrupts the RNase1-eRNA system. Thereby, eRNA accumulates in the extracellular space to induce massive proinflammatory cytokine release from circulating inflammatory cells, such as tumor necrosis factor alpha (TNF-α) or interleukin 1 beta (IL-1β). These cytokines negatively affect the EC layer by downregulation of RNase1 presumably through activation of histone deacetylases (HDACs). In this regard, this study investigated whether inflammation-mediated deacetylase function of HDACs suppresses RNase1 expression in human ECs through modulation of chromatin modifications. Proinflammatory stimulation with TNF-α or IL-1β of human umbilical vein endothelial cells significantly reduced RNase1 expression. Thus, identification of the RNASE1 promoter region and analysis of its chromatin state revealed the association of RNASE1 repression with deacetylation of histone 3 at lysine 27 and histone 4. The important role of HDACs in this process was further confirmed by administration of the specific class I HDAC1-3 inhibitor MS275 that successfully restored RNASE1 promoter acetylation and mRNA abundance upon TNF-α or IL-1β treatment. These results indicate an essential impact of HDAC1-3 in RNase1 regulation. Additionally, identification of specific HDACs involved in RNase1 regulation was obtained by chromatin immunoprecipitation kinetics confirming significant accumulation of HDAC2 at the RNASE1 promoter upon TNF-α stimulation. These findings were further validated by siRNA double knockdown of HDAC2 and its redundant enzyme HDAC1, which also recovered RNase1 mRNA abundance upon proinflammatory stimulation. In conclusion, our data identified HDAC2 as a crucial factor in RNase1 regulation in human ECs. HDAC2 is recruited to the RNASE1 promoter site to attenuate histone acetylation and suppress subsequent gene repression. This effect can be blocked by the specific HDAC inhibitor MS275 implicating the potential of HDAC inhibitors as novel therapeutic strategy to promote vascular integrity by preventing RNase1 downregulation in EC inflammation

Regulation of neutrophil senescence by microRNAs

Neutrophils are rapidly recruited to sites of tissue injury or infection, where they protect against invading pathogens. Neutrophil functions are limited by a process of neutrophil senescence, which renders the cells unable to respond to chemoattractants, carry out respiratory burst, or degranulate. In parallel, aged neutrophils also undergo spontaneous apoptosis, which can be delayed by factors such as GMCSF. This is then followed by their subsequent removal by phagocytic cells such as macrophages, thereby preventing unwanted inflammation and tissue damage. Neutrophils translate mRNA to make new proteins that are important in maintaining functional longevity. We therefore hypothesised that neutrophil functions and lifespan might be regulated by microRNAs expressed within human neutrophils. Total RNA from highly purified neutrophils was prepared and subjected to microarray analysis using the Agilent human miRNA microarray V3. We found human neutrophils expressed a selected repertoire of 148 microRNAs and that 6 of these were significantly upregulated after a period of 4 hours in culture, at a time when the contribution of apoptosis is negligible. A list of predicted targets for these 6 microRNAs was generated from http://mirecords.biolead.org and compared to mRNA species downregulated over time, revealing 83 genes targeted by at least 2 out of the 6 regulated microRNAs. Pathway analysis of genes containing binding sites for these microRNAs identified the following pathways: chemokine and cytokine signalling, Ras pathway, and regulation of the actin cytoskeleton. Our data suggest that microRNAs may play a role in the regulation of neutrophil senescence and further suggest that manipulation of microRNAs might represent an area of future therapeutic interest for the treatment of inflammatory disease

A PPAR-gamma, egy lipidek által aktivált transzkripciós faktor aktivitásának szabályozása a makrofágok különböző állapotaiban = Regulation of the activity of a lipid-activated transcription factor, PPAR-gamma in macrophages

A Peroxisome Proliferator-activated Receptor y (PPARy) egy lipidek által aktivált transzkripciós faktor, mely a lipidanyagcsere és a gyulladás szabályozásával olyan folyamatokban vesz részt, mint az érelmeszesedés és diabétesz. A PPARy aktivátorai több szinten képesek a gyulladás gátlására. Jelen pályázat célja az volt, hogy tanulmányozzuk a gyulladásos folyamatok PPARy aktivitására kifejtett hatását, megvizsgáljuk, hogy a gyulladásos mediátorok hogyan kommunikálnak a PPARy-val és megfejtsük ezeknek folyamatoknak a molekuláris mechanizmusát. Azt találtuk, hogy a gyulladásos molekulák befolyásolják a PPARy működését. Proinflammatórikus molekulák gátolják, míg az interleukin-4 (IL-4) fokozza a receptor működését makrofágokban és dendritikus sejtekben. Az IL-4 szignálútvonal bekapcsolása egy újonnan feltárt mechanizmussal, a Signal Transducer and Activators of Transcription 6 (STAT6) és a PPARg interakciója révén erősíti a receptor válaszait a célgének promóterén. Ennek eredményeképpen az IL-4 emeli a PPARg által szabályozott gének számát és fokozza az egyes gének esetében azok transzkripcióját. Ily módon a PPARg egy pozitív transzkripciós faktorként működhet a makrofágokban is. Eredményeink szerint létezik egy új mechanizmus, ahogy az immunrendszer sejtspecifikusan képes szabályozni egy magreceptor működését. Mindez felhívja a figyelmet a sejtek gyulladásos állapota és a lipidanyagcsere kapcsolatára olyan folyamatokban, mint pl. az érelmeszesedés. | Peroxisome Proliferator-activated Receptor y(PPARy) is a lipid-activated transcription factor that regulates lipid metabolism and inflammation, key processes in atherosclerosis and diabetes. PPARy agonists are known to regulate inflammation on multiple levels. The goal of this grant was to study how the inflammatory milieu regulates the activity of PPARy, analyze the crosstalk between inflammatory reactions and PPARy and to find the molecular mechanism how mediators of the immune system influence the receptor activity. We demonstrated that inflammatory molecules interfere with PPARg signaling. Proinflammatory molecules inhibit, while interleukin-4 (IL-4) stimulate PPARy in macrophages and dendritic cells (DCs). Activation of IL-4 signaling augments PPARg activity through a novel interaction between PPARg and Signal Transducer and Activators of Transcription 6 on the promoter of PPAR? target genes, like FABP4. As a consequence, IL-4 strongly enhances PPARy response and acts as a licensing factor by increasing the number of genes regulated and also the magnitude of the responses. Through target gene induction PPARy can be designated a positive regulator of macrophage gene expression. These findings introduce a new mechanism how inflammatory molecules modulate the activity of a nuclear receptor via cell-type specific factors and highlight the importance of the inflammatory status of cells in lipid metabolism and atherosclerosis

Inflammatory responses in primary muscle cell cultures in Atlantic salmon (Salmo salar)

Peer reviewedPublisher PD

Reformulating Pro-Oxidant Microglia in Neurodegeneration

In neurodegenerative diseases, microglia-mediated neuroinflammation and oxidative stress are central events. Recent genome-wide transcriptomic analyses of microglial cells under different disease conditions have uncovered a new subpopulation named disease-associated microglia (DAM). These studies have challenged the classical view of the microglia polarization state's proinflammatory M1 (classical activation) and immunosuppressive M2 (alternative activation). Molecular signatures of DAM and proinflammatory microglia (highly pro-oxidant) have shown clear differences, yet a partial overlapping gene profile is evident between both phenotypes. The switch activation of homeostatic microglia into reactive microglia relies on the selective activation of key surface receptors involved in the maintenance of brain homeostasis (a.k.a. pattern recognition receptors, PRRs). Two relevant PRRs are toll-like receptors (TLRs) and triggering receptors expressed on myeloid cells-2 (TREM2), whose selective activation is believed to generate either a proinflammatory or a DAM phenotype, respectively. However, the recent identification of endogenous disease-related ligands, which bind to and activate both TLRs and TREM2, anticipates the existence of rather complex microglia responses. Examples of potential endogenous dual ligands include amyloid β, galectin-3, and apolipoprotein E. These pleiotropic ligands induce a microglia polarization that is more complicated than initially expected, suggesting the possibility that different microglia subtypes may coexist. This review highlights the main microglia polarization states under disease conditions and their leading role orchestrating oxidative stress