Visceral leishmaniasis in children from Mato Grosso do Sul state, Brazil: a contribution to diagnosis and treatment

The innate immune response to viral pathogens is critical in order to mobilize protective immunity. Cells of the innate immune system detect viral infection largely through germline-encoded pattern recognition receptors (PRRs) present either on the cell surface or within distinct intracellular compartments. These include the Toll-like receptors (TLRs), the retinoic acid-inducble gene I-like receptors (RLRs), the nucleotide oligomerization domain-like receptors (NLRs, also called NACHT, LRR and PYD domain proteins) and cytosolic DNA sensors. While in certain cases viral proteins are the trigger of these receptors, the predominant viral activators are nucleic acids. The presence of viral sensing PRRs in multiple cellular compartments allows innate cells to recognize and quickly respond to a broad range of viruses, which replicate in different cellular compartments. Here, we review the role of PRRs and associated signaling pathways in detecting viral pathogens in order to evoke production of interferons and cytokines. By highlighting recent progress in these areas, we hope to convey a greater understanding of how viruses activate PRR signaling and how this interaction shapes the anti-viral immune response.

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Endothelial Cilia Are Fluid Shear Sensors That Regulate Calcium Signaling and Nitric Oxide Production Through Polycystin-1

Nauli

et al. 2008

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Background-When challenged with extracellular fluid shear stress, vascular endothelial cells are known to release nitric oxide, an important vasodilator. Here, we show that the ability of cultured endothelial cells to sense a low range of fluid shear depends on apical membrane organelles, called cilia, and that cilia are compartments required for proper localization and function of the mechanosensitive polycystin-1 molecule. Methods and Results-Cells with the Pkd1null/null or Tg737 orpk/orpk mutation encoded for polycystin-1 or polaris, respectively, are unable to transmit extracellular shear stress into intracellular calcium signaling and biochemical nitric oxide synthesis. Cytosolic calcium and nitric oxide recordings further show that fluid shear sensing is a cilia-specific mechanism because other mechanical or pharmacological stimulation does not abolish calcium and nitric oxide signaling in polycystin-1 and polaris mutant endothelial cells. Polycystin-1 localized in the basal body of Tg737

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Synthetic Oligodeoxynucleotides Containing Suppressive TTAGGG Motifs Inhibit AIM2 Inflammasome Activation

Kaminski

Schattgen

Tzeng

et al. 2013

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Synthetic oligodeoxynucleotides comprised of the immunosuppressive motif TTAGGG block TLR9 signaling, prevent STAT1 and STAT4 phosphorylation and attenuate a variety of inflammatory responses in vivo. Here, we demonstrate that such suppressive oligodeoxynucleotides (sup ODN) abrogate activation of cytosolic nucleic acid sensing pathways. Pretreatment of dendritic cells and macrophages with the suppressive ODN-A151 abrogated type I IFN, TNFα and ISG induction in response to cytosolic dsDNA. In addition, A151 abrogated caspase-1-dependent IL-1β and IL-18 maturation in dendritic cells stimulated with dsDNA and murine cytomegalovirus (MCMV). Inhibition was dependent on A151’s phosphorothioate backbone while substitution of the guanosine residues for adenosine negatively affected potency. A151 mediates these effects by binding to AIM2 in a manner that is competitive with immune-stimulatory DNA and as a consequence prevents AIM2 inflammasome complex formation. Collectively, these findings reveal a new route by which suppressive ODNs modulate the immune system and unveil novel applications for suppressive ODNs in the treatment of infectious and autoimmune diseases.

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Endothelial cilia are mechanosensory organelles

et al. 2008

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BACKGROUNDWhen challenged with extracellular fluid‐shear stress, vascular endothelial cells are known to release nitric oxide (NO), an important vasodilator. We here show that this mechanosensing signal transduction depends on apical membrane organelles, termed cilia.METHODS AND RESULTSCells with Pkd1null/null or Tg737orpk/orpk mutation encoded for polycystin‐1 or polaris, respectively, are unable to transmit extracellular shear stress into intracellular calcium signaling and biochemical NO synthesis. Cytosolic calcium and NO recordings further show that fluid‐shear sensing is a cilia‐specific mechanism, as other mechanical or pharmacological stimulation does not abolish calcium and NO signaling in polycystin‐1 and polaris mutant endothelial cells. Polycystin‐1 localized in the basal body of Tg737orpk/orpk endothelial cells is insufficient for a fluid‐shear stress response.CONCLUSIONWe demonstrate for the first time that the ability of endothelial cells to sense a low range of fluid shear depends on cilia and that cilia are compartments required for proper localization and function of the mechanosensitive polycystin‐1 molecule.

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John J. Kaminski

Pattern Recognition Receptors and the Innate Immune Response to Viral Infection

Endothelial Cilia Are Fluid Shear Sensors That Regulate Calcium Signaling and Nitric Oxide Production Through Polycystin-1

Synthetic Oligodeoxynucleotides Containing Suppressive TTAGGG Motifs Inhibit AIM2 Inflammasome Activation

Endothelial cilia are mechanosensory organelles

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