The many faces of FcγRI: implications for therapeutic antibody function.

Fcγ receptor I (FcγRI or CD64) is the sole human Fc receptor with high affinity for monovalent IgG. While it contains an immunoreceptor tyrosine-based activation motif in its cytoplasmic domain, binding of FcγRI can result in a complex array of activating and inhibitory outcomes. For instance, binding of monomeric IgG provides a low-intensity tonic signal through FcγRI that is necessary for full interferon γ receptor signaling in the same cell. Interaction of FcγRI with larger high-avidity complexes can result in phagocytosis, the generation of reactive oxygen species, as well as the synthesis and release of inflammatory cytokines. However, numerous reports also document potent anti-inflammatory effects brought about by FcγRI engagement with immune complexes such as the inhibition of IFNγ and TLR4 signaling, and secretion of interleukin-10. This has led to conflicting hypotheses regarding the function of FcγRI, especially with regard to its role in the efficacy of several therapeutic monoclonal antibodies. While many of these issues are still unclear, continued characterization of the regulation and context dependence of FcγRI function, as well as the molecular mechanisms responsible for these various outcomes, will improve our understanding of FcγRI biology as well as the therapeutic strategies designed to harness or constrain its actions.

Immune complexes suppress IFN-γ-induced responses in monocytes by activating discrete members of the SRC kinase family.

The regulation of the innate and the adaptive immune responses are extensively intertwined and tightly regulated. Ag-driven immune responses that are modulated by immune complexes (ICs) are known to inhibit IFN-γ-dependent MHC class II expression. We have previously demonstrated that ICs dramatically inhibit IFN-γ-induced activation of human monocytes through the activation of the FcγRI signaling pathway. In the present study we further explore the mechanisms by which ICs regulate IFN-γ activation of human monocytes. We demonstrate that members of the SRC kinase family (SKF) are key mediators of IFN-γ pathway suppression: inhibitors of the SKF reverse the ability of ICs to suppress IFN-γ signaling. Small interfering RNA was used to target specific members of the SKF. The data indicate that SRC and LYN are both required for ICs to elicit their immunosuppressive activity, whereas FYN does not appear to contribute to this function. Similarly, the kinase SYK, though not a member of the SKF, is also demonstrated to be involved in this IC-mediated immunosuppression. Our data suggest a mechanism whereby ICs directly inhibit inflammatory signals by crosslinking FcγRI, resulting in the activation of the specific phosphotyrosine kinases SRC, LYN, and SYK and the concomitant suppression of the IFN-γ signaling pathway.

IgG4 can induce an M2-like phenotype in human monocyte-derived macrophages through FcγRI.

Antibodies evoke cellular responses through the binding of their Fc region to Fc receptors, most of which contain immunoreceptor tyrosine-based activation motif domains and are thus considered "activating." However, there is a growing appreciation of these receptors for their ability to deliver an inhibitory signal as well. We previously described one such phenomenon whereby interferon (IFN)γ signaling is inhibited by immune complex signaling through FcγRI. To understand the implications of this in the context of therapeutic antibodies, we assessed individual IgG subclasses to determine their ability to deliver this anti-inflammatory signal in monocyte-derived macrophages. Like IgG1, we found that IgG4 is fully capable of inhibiting IFNγ-mediated events. In addition, F(ab')2 fragments that interfere with FcγRI signaling reversed this effect. For mAbs developed with either an IgG1 or an IgG4 constant region for indications where inflammation is undesirable, further examination of a potential Fc-dependent contribution to their mechanism of action is warranted.

Annexin A2 tetramer activates human and murine macrophages through TLR4.

Annexins are a large family of intracellular phospholipid-binding proteins, yet several extracellular roles have been identified. Specifically, annexin A2, found in a heterotetrameric complex with S100A10, not only serves as a key extracellular binding partner for pathogens and host proteins alike, but also can be shed or secreted. We reported previously that soluble annexin A2 tetramer (A2t) activates human monocyte-derived macrophages (MDM), resulting in secretion of inflammatory mediators and enhanced phagocytosis. Although a receptor for A2t has been cloned from bone marrow stromal cells, data contained in this study demonstrate that it is dispensable for A2t-dependent activation of MDM. Furthermore, A2t activates wild-type murine bone marrow-derived macrophages, whereas macrophages from myeloid differentiation factor 88-deficient mice display a blunted response, suggesting a role for Toll-like receptor (TLR) signaling. Small interfering RNA knockdown of TLR4 in human MDM reduced the response to A2t, blocking antibodies against TLR4 (but not TLR2) blocked activation altogether, and bone marrow-derived macrophages from TLR4(-/-) mice were refractory to A2t. These data demonstrate that the modulation of macrophage function by A2t is mediated through TLR4, suggesting a previously unknown, but important role for this stress-sensitive protein in the detection of danger to the host, whether from injury or invasion.

Annexin A2 is a soluble mediator of macrophage activation.

On the surface of the macrophage, annexin A2 tetramer (A2t) serves as a docking protein or recognition element for bacterial and viral pathogens. Plasma levels of free A2t have been reported to increase following infection, although the mechanistic significance of this observation is unclear. Although annexin A2 had generally been thought to play an anti-inflammatory role, soluble A2t stimulates MAP kinase activity in bone marrow stromal cells downstream of a recently cloned receptor. This raises the question of whether A2t activates human macrophages via MAP kinases and whether it might be capable of acting as an inflammatory mediator. To this end, human monocyte-derived macrophages were treated with soluble A2t and MAP kinase phosphorylation, p65 NF-kappaB activation, and inflammatory mRNA and protein levels were measured. It was found that A2t caused rapid phosphorylation of several MAP kinases, as well as translocation of p65 NF-kappaB to the nucleus. A2t stimulated the production of TNF-alpha, IL-1beta, and IL-6, as well as several members of the chemokine family within 24 h, which are capable of recruitment and/or activation of a broad range of leukocyte classes. Furthermore, A2t-activated macrophages demonstrated enhanced phagocytic ability for the ingestion of GFP-expressing Escherichia coli. These data are the first to suggest the participation of an annexin in microbial clearance, as well as the establishment of inflammation and the immune response, including the recruitment and activation of immune cells to the site of infection.

Analysis of putative RNase sensitivity and protease insensitivity of demethylation activity in extracts from rat myoblasts.

The mechanism for demethylation of DNA in rat myoblasts has recently been studied using a new in vitro system that monitors demethylation in whole cell extracts. Previous investigations using this system had indicated that demethylation is resistant to conditions that are normally assumed to denature or digest proteins. Remarkably, it was reported that the activity appeared to be sensitive to the action of ribonuclease, suggesting a role for RNA in the demethylation of DNA. This manuscript reports that, upon further purification of the extract, demethylation activity has properties that are different. When subjected to more rigorous procedures for digestion of proteins, the demethylase activity disappears. Furthermore, RNase sensitivity of the extract disappears when a quantity of unmethylated competitor DNA is added to the reaction mix or when extracts treated with RNase are subsequently treated with protease. Although a role for RNA cannot be completely discounted, it is unlikely that this demethyl-ation reaction involves RNA cofactors or ribozyme components. These results have important implications for the mechanism of DNA demethylation and they exemplify the potential pitfalls of experiments in which new biological roles for RNA are evaluated using RNase sensitivity experiments.