Granulocyte-macrophage colony-stimulating factor (GM-CSF)-induced STAT5 activation and target-gene expression during human monocyte/macrophage differentiation

GM-CSF signals through JAK2 and STAT5 and stimulates the expression of STAT5 target genes, such as pim-1 and CIS. Analyzed by EMSA, GM-CSF stimulation led to much stronger STAT5 DNA-binding to pim-1 or CIS GAS elements in primary human monocytes compared with mature macrophages. Similarly, GM-CSF-induced expression of pim-1 and CIS mRNAs was much stronger in monocytes. These differencies were not a result of downregulation of the GM-CSF receptor system or STAT5 expression, because monocytes and macrophages readily expressed GM-CSF receptor, JAK2, STAT5A, and STAT5B mRNAs and proteins. Monocytes expressed significant amounts of truncated STAT5 forms that took part in STAT5-DNA complex formation in GM-CSF-stimulated monocytes. This resulted in faster moving STAT5 complexes compared with macrophages in EMSA. Our results demonstrate that STAT5 isoform expression, GM-CSF-induced STAT5 activation, and STAT5 target-gene expression are altered significantly during monocyte/macrophage differentiation.     

Immune complexes suppress IFN-gamma signaling by activation of the FcgammaRI pathway

Antigen-driven immune responses are modulated by immune complexes (ICs), in part through their ability to inhibit IFN-gamma-dependent MHC Class II expression. We have demonstrated previously that ICs dramatically inhibit IFN-gamma-induced activation of human monocytes through the suppression of the JAK/STAT signaling pathway. In the current study, we further explore the mechanisms by which ICs regulate IFN-gamma activation of human monocytes. Consistent with previous studies in monocytes pretreated with ICs, there was a reduction in steady-state levels of RNA by real-time RT-PCR of the IFN-inducible protein 10 gene as well as the FcgammaRI gene. Pull-down assays confirm that IC pretreatment inhibits IFN-gamma-induced STAT1 phosphorylation without affecting the ability of STAT1 to bind to the STAT1-binding domain of the IFN-gamma receptor. In addition, the inhibitory function of ICs was reduced when cells from the FcR common gamma-chain knockout mice were used, supporting the role of the FcgammaRI in this inhibitory pathway. It is unexpected that ICs also require the phosphatase Src homology-2-containing tyrosine phosphatase 1 (SHP-1) to inhibit IFN-gamma induction, as demonstrated by studies with cells from the SHP-1 knockout (motheaten) mice. These data suggest a mechanism of IC-mediated inhibition of IFN-gamma signaling, which requires the ITAM-containing FcgammaRI, as well as the ITIM-dependent phosphatase SHP-1, ultimately resulting in the suppression of STAT1 phosphorylation.     

DC-SIGN ligation greatly affects dendritic cell differentiation from monocytes compromising their normal function

DC-SIGN is a C-type lectin selectively expressed by certain types of DCs, including monocyte-derived DCs. Many reports have described the impact of DC-SIGN engagement with concomitant TLR signaling in tailoring of the DC maturation process, but so far, none has addressed the importance of DC-SIGN engagement during their differentiation from blood progenitors. We therefore examined the role of DC-SIGN engagement limited to the stage of IL-4-guided differentiation of DCs from human peripheral blood monocytes but not during maturation. We used two different anti-DC-SIGN antibodies with reported DC-SIGN-engaging activities. In cultures with DC-SIGN ligands, the resulting iDCs displayed abrogated expression of differentiation markers CD1a and DC-SIGN. Without further DC-SIGN activation, such DCs matured with low CD80/CD86 and high ILT3 expression, along with the appearance of macrophage marker CD14. Additionally, treated DCs indicated a tolerogenic potential by possessing a low, allostimulatory capacity and inducing na?ve, allogeneic CD4(+) T cells to produce low levels of IFN-γ. Upon activation, IL-10 production was greatly increased by such DCs; however, the use of IL-10-blocking antibodies could not completely reverse alternative DC activation. This suggests an alternative activation response that is a result of a different elementary state of DCs generated with concomitant ligation of DC-SIGN. During differentiation, IL-4-induced pSTAT6 was reduced by DC-SIGN ligands. Furthermore, during LPS-induced maturation, treated DCs displayed lowered activation levels of p38 MAPK, STAT1, as well as STAT6, compared with controls. Collectively, evidence is presented confirming a crucial role for DC-SIGN signaling in DC generation from monocytes.     

Signal transduction activator of transcription 5 (STAT5) dysfunction in autoimmune monocytes and macrophages

Autocrine granulocyte macrophage-colony stimulating factor (GM-CSF) sequentially activates intracellular components in monocyte/macrophage production of the pro-inflammatory and immunoregulatory prostanoid, prostaglandin E2 (PGE2). GM-CSF first induces STAT5 signaling protein phosphorylation, then prostaglandin synthase 2 (COX2/PGS2) gene expression, and finally IL-10 production, to downregulate the cascade. Without activation, monocytes of at-risk, type 1 diabetic (T1D), and autoimmune thyroid disease (AITD) humans, and macrophages of nonobese diabetic (NOD) mice have aberrantly high GM-CSF, PGS2, and PGE2 expression, but normal levels of IL-10. After GM-CSF stimulation, repressor STAT5A and B isoforms (80-77kDa) in autoimmune human and NOD monocytes and activator STAT5A (96-94kDa) and B (94-92kDa) isoforms in NOD macrophages stay persistently tyrosine phosphorylated. This STAT5 phosphorylation persisted despite treatment in vitro with IL-10, anti-GM-CSF antibody, or the JAK2/3 inhibitor, AG490. Phosphorylated STAT5 repressor isoforms in autoimmune monocytes had diminished DNA binding capacity on GAS sequences found in the PGS2 gene enhancer. In contrast, STAT5 activator isoforms in NOD macrophages retained their DNA binding capacity on these sites much longer than in healthy control strain macrophages. These findings suggest that STAT5 dysfunction may contribute to dysregulation of GM-CSF signaling and gene activation, including PGS2, in autoimmune monocytes and macrophages.