It has long been known that the ITIM-bearing IgG Fc receptor (FcγRIIb, RIIb) is expressed on liver sinusoidal endothelial cells (LSEC) and that the liver is the major site of small immune complex (SIC) clearance. Thus, we proposed that RIIb of LSEC eliminates blood-borne small immune complexes (SIC), thereby controlling IC-mediated autoimmune disease. Testing this hypothesis we found most RIIb of the mouse, fully three-quarters, to be expressed in liver. Moreover, most (90%) liver RIIb was expressed in LSEC, the remainder in Kupffer cells (KC). An absent FcRγ in LSEC implied that RIIb is the sole FcγR expressed. Testing the capacity of liver RIIb to clear blood-borne SIC we infused mice intravenously with radioiodinated SIC made of ovalbumin and rabbit IgG anti-ovalbumin. Tracking decay of SIC from the blood, we found the RII KO strain to be severely deficient in eliminating SIC compared with the WT strain, terminal half-lives being, respectively, 6 and 1.5 hours. RIIb on LSEC, a major scavenger, keeps SIC blood concentrations low and minimizes pathologic deposition of inflammatory IC.
The liver removes quickly the great bulk of virus circulating in blood, leaving only a small fraction to infect the host, in a manner characteristic of each virus. The scavenger cells of the liver sinusoids are implicated, but the mechanism is entirely unknown. Here we show, borrowing a mouse model of adenovirus clearance, that nearly all infused adenovirus is cleared by the liver sinusoidal endothelial cell (LSEC). Using refined immunofluorescence microscopy techniques for distinguishing macrophages and endothelial cells in fixed liver, and identifying virus by two distinct physicochemical methods, we localized adenovirus 1 minute after infusion mainly to the LSEC (∼90%), finding ∼10% with Kupffer cells (KC) and none with hepatocytes. Electron microscopy confirmed our results. In contrast with much prior work claiming the main scavenger to be the KC, our results locate the clearance mechanism to the LSEC and identify this cell as a key site of antiviral activity.
The Gram-negative bacterium Francisella novicida infects primarily monocytes/macrophages and is highly virulent in mice. Macrophages respond by producing inflammatory cytokines that confer immunity against the infection. However, the molecular details of host cell response to Francisella infection are poorly understood. In this study, we demonstrate that F. novicida infection of murine macrophages induces the activation of Akt. Inhibition of Akt significantly decreases proinflammatory cytokine production in infected macrophages, whereas production of the anti-inflammatory cytokine IL-10 is enhanced. Analysis of the mechanism of Akt influence on cytokine response demonstrated that Akt promotes NF-κB activation. We have extended these findings to show that Akt activation may be regulated by bacterial genes associated with phagosomal escape. Infection with mglA mutants of F. novicida elicited sustained activation of Akt in comparison to cells infected with wild-type F. novicida. Concomitantly, there was significantly higher proinflammatory cytokine production and lower IL-10 production in cells infected with the mglA mutant. Finally, transgenic animals expressing constitutively active Akt displayed a survival advantage over their wild-type littermates when challenged with lethal doses of F. novicida. Together, these observations indicate that Akt promotes proinflammatory cytokine production by F. novicida-infected macrophages through its influence on NF-κB, thereby contributing to immunity against F. novicida infection.
LPS stimulates monocytes/macrophages through TLR4, resulting in the activation of a series of signaling events that potentiate the production of inflammatory mediators. Recent reports indicated that the inflammatory response to LPS is diminished by PI3K, through the activation of the serine/threonine kinase Akt. SHIP is an inositol phosphatase that can reverse the activation events initiated by PI3K, including the activation of Akt. However, it is not known whether SHIP is involved in TLR4 signaling. In this study, we demonstrate that LPS stimulation of Raw 264.7 mouse macrophage cells induces the association of SHIP with lipid rafts, along with IL-1R-associated kinase. In addition, SHIP is tyrosine phosphorylated upon LPS stimulation. Transient transfection experiments analyzing the function of SHIP indicated that overexpression of a wild-type SHIP, but not the SHIP Src homology 2 domain-lacking catalytic activity, up-regulates NF-κB-dependent gene transcription in response to LPS stimulation. These results suggest that SHIP positively regulates LPS-induced activation of Raw 264.7 cells. To test the validity of these observations in primary macrophages, LPS-induced events were compared in bone marrow macrophages derived from SHIP+/+ and SHIP−/− mice. Results indicated that LPS-induced MAPK phosphorylation is enhanced in SHIP+/+ cells, whereas Akt phosphorylation is enhanced in SHIP−/− cells compared with SHIP+/+ cells. Finally, LPS-induced TNF-α and IL-6 production was significantly lower in SHIP−/− bone marrow-derived macrophages. These results are the first to demonstrate a role for SHIP in TLR4 signaling, and propose that SHIP is a positive regulator of LPS-induced inflammation.
Prions are novel kinds of hereditary units, relying solely on proteins, that are infectious and inherited in a non-Mendelian fashion. To date, they are either based on autocatalytic modification of a 3D conformation or on autocatalytic cleavage. Here, we provide further evidence that in the filamentous fungus Podospora anserina, a MAP kinase cascade is probably able to self-activate and generate C, a hereditary unit that bears many similarities to prions and triggers cell degeneration. We show that in addition to the MAPKKK gene, both the MAPKK and MAPK genes are necessary for the propagation of C, and that overexpression of MAPK as that of MAPKKK facilitates the appearance of C. We also show that a correlation exists between the presence of C and localization of the MAPK inside nuclei. These data emphasize the resemblance between prions and a self-positively regulated cascade in terms of their transmission. This thus further expands the concept of protein-base inheritance to regulatory networks that have the ability to self-activate.epigenetic ͉ prion ͉ Podospora anserina
Francisella tularensis, a Gram-negative facultative intracellular pathogen infecting principally macrophages and monocytes, is the etiological agent of tularemia. Macrophage responses to F. tularensis infection include the production of pro-inflammatory cytokines such as interleukin (IL)-12, which is critical for immunity against infection. Molecular mechanisms regulating production of these inflammatory mediators are poorly understood. Herein we report that the SH2 domain-containing inositol phosphatase (SHIP) is phosphorylated upon infection of primary murine macrophages with the genetically related F. novicida, and negatively regulates F. novicida–induced cytokine production. Analyses of the molecular details revealed that in addition to activating the MAP kinases, F. novicida infection also activated the phosphatidylinositol 3-kinase (PI3K)/Akt pathway in these cells. Interestingly, SHIP-deficient macrophages displayed enhanced Akt activation upon F. novicida infection, suggesting elevated PI3K-dependent activation pathways in absence of SHIP. Inhibition of PI3K/Akt resulted in suppression of F. novicida–induced cytokine production through the inhibition of NFκB. Consistently, macrophages lacking SHIP displayed enhanced NFκB-driven gene transcription, whereas overexpression of SHIP led to decreased NFκB activation. Thus, we propose that SHIP negatively regulates F. novicida–induced inflammatory cytokine response by antagonizing the PI3K/Akt pathway and suppressing NFκB-mediated gene transcription. A detailed analysis of phosphoinositide signaling may provide valuable clues for better understanding the pathogenesis of tularemia.
During Gram-negative bacterial infections, excessive lipopolysaccharide (LPS) induces inflammation and sepsis via action on immune cells. However, the bulk of LPS can be cleared from circulation by the liver. Liver clearance is thought to be a slow process mediated exclusively by phagocytic resident macrophages, Kupffer cells (KC). However, we discovered that LPS disappears rapidly from the circulation, with a half-life of 2–4 minutes in mice and liver eliminates about three quarters of LPS from blood circulation. Using microscopic techniques, we found that ~75% of fluor-tagged LPS in liver became associated with liver sinusoidal endothelial cells (LSEC) and only ~25% with KC. Notably, the ratio of LSEC-KC associated LPS remained unchanged 45 min after infusion, indicating that LSEC independently processes the LPS. Most interestingly, results of kinetic analysis of LPS bioactivity, using modified limulus amebocyte lysate assay, suggest that recombinant factor-C, an LPS binding protein, competitively inhibits HDL-mediated LPS association with LSEC early in the process. Supporting the previous notion 3 min post-infusion, 75% of infused fluorescently-tagged LPS-HDL complex associates with LSEC, suggesting that HDL facilitates LPS clearance. These results lead us to propose a new paradigm of LSEC and HDL in clearing LPS with a potential to avoid inflammation during sepsis.
In adults, the nonclassical MHC class I molecule, FcRn, binds both IgG and albumin and rescues both from a degradative fate, endowing both proteins with high plasma concentrations. FcRn also transports IgG from mother to young during gestation. Anticipating that a detailed understanding of gestational IgG transport in the mouse may give us a useful model to understand FcRn function in the human placenta, we have studied FcRn in the mouse yolk sac placenta in detail. Analyzing day 19–20 fetuses of the three FcRn genotypes resulting from matings of FcRn+/− parents, we found that FcRn−/− fetuses showed negligible IgG concentrations (1.5 μg/ml), whereas IgG concentrations in FcRn+/− fetuses were about a half (176 μg/ml) that of FcRn+/+ fetuses (336 μg/ml), indicating that FcRn is responsible for virtually all IgG transport from mother to fetus. Immunofluorescence and immunoblotting studies indicated that FcRn is expressed in the endoderm of the yolk sac placenta but not in other cells of the yolk sac placenta or in the chorioallantoic placenta. IgG was found in the endoderm of both FcRn+/+ and FcRn−/− yolk sac placentas and in the mesenchyme of FcRn+/+ but was missing from the mesenchyme of FcRn−/− yolk sac placentas, indicating that IgG enters the endoderm constitutively but is moved out of the endoderm by FcRn. The similarities of these results to human placental FcRn expression and function are striking.
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