Abstract
Microglial cell phagocytic receptors may play important roles in the pathogenesis and treatment of several neurological diseases. We studied microglial Fc receptor (FcR) activation with respect to the specific FcgammaR types involved and the downstream signaling events by using monoclonal antibody (MAb)-coated Cryptococcus neoformans immune complexes as the stimuli and macrophage inflammatory protein 1alpha (MIP-1alpha) production as the final outcome. C. neoformans complexed with murine immunoglobulin G (IgG) of gamma1, gamma2a, and gamma3, but not gamma2b isotype, was effective in inducing MIP-1alpha in human microglia. Since murine gamma2b binds to human FcgammaRII (but not FcgammaRI or FcgammaRIII), these results indicate that FcgammaRI and/or FcgammaRIII is involved in MIP-1alpha production. Consistent with this, an antibody that blocks FcgammaRII (IV.3) failed to inhibit MIP-1alpha production, while an antibody that blocks FcgammaRIII (3G8) did. An anti-C. neoformans MAb, 18B7 (IgG1), but not its F(ab')(2), induced extracellular signal-regulated kinase (ERK) mitogen-activated protein kinase kinase phosphorylation, and MIP-1alpha release was suppressed by the ERK inhibitor U0126. C. neoformans plus 18B7 also induced degradation of I-kappaBalpha, and MIP-1alpha release was suppressed by the antioxidant NF-kappaB inhibitor pyrrolidine dithiocarbamate. To confirm the role of FcR more directly, we isolated microglia from wild-type and various FcR-deficient mice and then challenged them with C. neoformans plus 18B7. While FcgammaRII-deficient microglia showed little difference from the wild-type microglia, both FcgammaRI alpha-chain- and FcgammaRIII alpha-chain-deficient microglia produced less MIP-1alpha, and the common Fc gamma-chain-deficient microglia showed no MIP-1alpha release. Taken together, our results demonstrate a definitive role for FcgammaRI and FcgammaRIII in microglial chemokine induction and implicate ERK and NF-kappaB as the signaling components leading to MIP-1alpha expression. Our results delineate a new mechanism for microglial activation and may have implications for central nervous system inflammatory diseases.