Decreased expression of the glucocorticoid receptor-GILZ pathway in Kupffer cells promotes liver inflammation in obese mice.

BACKGROUND & AIMS: Kupffer cells (KC) play a key role in the onset of inflammation in non-alcoholic steatohepatitis (NASH). The glucocorticoid receptor (GR) induces glucocorticoid-induced leucine zipper (GILZ) expression in monocytes/macrophages and is involved in several inflammatory processes. We hypothesized that the GR-GILZ axis in KC may contribute to the pathophysiology of obesity-induced liver inflammation. METHODS: By using a combination of primary cell culture, pharmacological experiments, mice deficient for the Gr specifically in macrophages and transgenic mice overexpressing Gilz in macrophages, we explored the involvement of the Gr-Gilz axis in KC in the pathophysiology of obesity-induced liver inflammation. RESULTS: Obesity was associated with a downregulation of the Gr and Gilz, and an impairment of Gilz induction by lipopolysaccharide (LPS) and dexamethasone (DEX) in KC. Inhibition of Gilz expression in isolated KC transfected with Gilz siRNA demonstrated that Gilz downregulation was sufficient to sensitize KC to LPS. Conversely, liver inflammation was decreased in obese transgenic mice specifically overexpressing Gilz in macrophages. Pharmacological inhibition of the Gr showed that impairment of Gilz induction in KC by LPS and DEX in obesity was driven by a downregulation of the Gr. In mice specifically deficient for Gr in macrophages, Gilz expression was low, leading to an exacerbation of obesity-induced liver inflammation. CONCLUSIONS: Obesity is associated with a downregulation of the Gr-Gilz axis in KC, which promotes liver inflammation. The Gr-Gilz axis in KC is an important target for the regulation of liver inflammation in obesity.

Glucocorticoid-induced leucine zipper enhanced expression in dendritic cells is sufficient to drive regulatory T cells expansion in vivo.

Tolerance induction by dendritic cells (DCs) is, in part, mediated by the activation of regulatory T cells (Tregs). We have previously shown in vitro that human DCs treated with glucocorticoids (GCs), IL-10, or TGF-ß upregulate the GC-Induced Leucine Zipper protein (GILZ). GILZ overexpression promotes DC differentiation into regulatory cells that generate IL-10-producing Ag-specific Tregs. To investigate whether these observations extend in vivo, we have generated CD11c-GILZ(hi) transgenic mice. DCs from these mice constitutively overexpress GILZ to levels observed in GC-treated wild-type DCs. In this article, we establish that GILZ(hi) DCs display an accumulation of Foxp3(+) Tregs in the spleens of young CD11c-GILZ(hi) mice. In addition, we show that GILZ(hi) DCs strongly increase the Treg pool in central and peripheral lymphoid organs of aged animals. Upon adoptive transfer to wild-type recipient mice, OVA-loaded GILZ(hi) bone marrow-derived DCs induce a reduced activation and proliferation of OVA-specific T cells as compared with control bone marrow-derived DCs, associated with an expansion of thymus-derived CD25(+)Foxp3(+) CD4 T cells. Transferred OVA-loaded GILZ(hi) DCs produce significantly higher levels of IL-10 and express reduced levels of MHC class II molecules as compared with OVA-loaded control DCs, emphasizing the regulatory phenotype of GILZ(hi) DCs in vivo. Thus, our work demonstrates in vivo that the GILZ overexpression alone is sufficient to promote a tolerogenic mode of function in DCs.

H4 histamine receptor mediates optimal migration of mast cell precursors to CXCL12.

BACKGROUND: CXCL12, a constitutive chemokine (ligand of CXCR4 and CXCR7), is expressed in the skin and airway epithelium and plays a significant role in allergic airway diseases. The pleiotropic effects of CXCL12 are enhanced by cofactors specific to the target cell. OBJECTIVE: We hypothesized that histamine, a major mediator of allergic reactions, could interact with CXCL12 to promote human mast cell (MC) migration. METHODS: The chemotactic effects of CXCL12 alone or in combination with histamine were evaluated on human precursor and mature MCs by using in vitro migration assays. RESULTS: CXCL12 exerts a chemotactic activity on both precursor and fully mature MCs. Histamine and supernatants from IgE-activated MCs enhanced CXCL12 chemotactic activity on the precursor MC population. The synergy between histamine and CXCL12 was not observed with mature MCs, CD4(+) T cells, and monocytes. Inhibition of histamine receptors pharmacologically or with specific small interfering RNA (siRNA) indicated that synergy between histamine and CXCL12 required the H(4) receptor. CONCLUSION: Histamine released by allergen-activated mature MCs might promote MC-rich allergic inflammation by enhancing recruitment of their precursors in tissues constitutively expressing CXCL12, including skin and airways. CLINICAL IMPLICATIONS: This work highlights a novel role of the H(4) receptor in the perpetuation of allergic responses and provides evidence for the utility of H(4) receptor antagonists in the treatment of allergic diseases.

GILZ expression in human dendritic cells redirects their maturation and prevents antigen-specific T lymphocyte response.

Interleukin (IL)-10 and glucocorticoids (GCs) inhibit the ability of antigen-presenting dendritic cells (DCs) to stimulate T lymphocytes. We show that induction of GILZ (GC-induced leucine zipper) is involved in this phenomenon. IL-10, dexamethasone (DEX), and transforming growth factor (TGF)beta stimulate GILZ production in human immature DCs derived from monocytes and from CD34+ cells. GILZ is necessary and sufficient for DEX, IL-10, and TGFbeta modulation of CD80, CD83, CD86, immunoglobulin-like transcript (ILT)-3, and B7-H1 expression by DCs, and alteration of DC functions. GILZ stimulates the production of IL-10 by immature DCs and prevents the production of inflammatory chemokines by CD40L-activated DCs. In contrast, GILZ does not prevent CD40 ligand-mediated inhibition of phagocytosis, indicating that it affects some but not all aspects of DC maturation. GILZ prevents DCs from activating antigen-specific T lymphocyte responses. Administration of GCs to patients stimulates GILZ expression in their circulating antigen-presenting cells, and this contributes to the weak lymphocyte responses of GC-treated patients. Thus, regulation of GILZ expression is an important factor determining the decision of DCs whether or not to stimulate T lymphocytes, and IL-10, GCs, and TGFbeta share this mechanism for influencing DC functions and the balance between immune response and tolerance.

Aluminum hydroxide adjuvant induces macrophage differentiation towards a specialized antigen-presenting cell type.

Aluminum hydroxide (AlOOH) has been used for many years as a vaccine adjuvant, but little is known about its mechanism of action. We investigated in this study the in vitro effect of aluminum hydroxide adjuvant on isolated macrophages. We showed that AlOOH-stimulated macrophages contain large and persistent intracellular crystalline inclusions, a characteristic property of muscle infiltrated macrophages described in animal models of vaccine injection, as well as in the recently described macrophagic myofasciitis (MMF) histological reaction in humans. AlOOH-loaded macrophages exhibited phenotypical and functional modifications, as they expressed the classical markers of myeloid dendritic cells (HLA-DR(high)/CD86(high)/CD83(+)/CD1a(-)/CD14(-)) and displayed potent ability to induce MHC-II-restricted antigen specific memory responses, but kept a macrophage morphology. This suggests a key role of macrophages, in the reaction to AlOOH-adjuvanted vaccines and these mature antigen-presenting macrophages may therefore be of particular importance in the establishment of memory responses and in vaccination mechanisms leading to long-lasting protection.

The CX3C chemokine fractalkine in allergic asthma and rhinitis.

BACKGROUND: Unlike other chemokines, fractalkine is expressed as a membrane-bound form, mainly on endothelial and epithelial cells, and can be shed as a soluble chemotactic form. Fractalkine can capture leukocytes expressing its receptor (CX(3)CR(1)), including T lymphocytes, rapidly and firmly in an integrin-independent manner. Because of its dual activity, fractalkine plays a major role in the transendothelial and transepithelial migration of leukocytes during inflammation. OBJECTIVE: We sought to study the fractalkine-CX(3)CR(1) axis in patients with allergic airways diseases. METHODS: Plasma fractalkine levels were measured by means of ELISA in 19 control subjects and 55 patients with symptomatic allergic rhinitis, asthma, or both, and CX(3)CR(1) function was studied by using triple-color flow cytometry in circulating T-lymphocyte subpopulations. Segmental allergen challenge was performed in 16 allergic asthmatic patients to analyze fractalkine expression and inflammatory cell recruitment in bronchoalveolar lavage fluid and bronchial biopsy specimens. RESULTS: Compared with control subjects, patients with symptomatic allergic rhinitis and asthmatic patients had increased circulating fractalkine levels, and CX(3)CR(1) function was upregulated in circulating CD4(+) T lymphocytes. Twenty-four hours after segmental allergen challenge, bronchoalveolar lavage fluid soluble fractalkine concentrations increased and correlated with the total number of recruited cells. Bronchial epithelial and endothelial cells expressed high levels of the membrane-bound form of fractalkine before and after challenge. CONCLUSION: Allergic asthma and rhinitis are associated with systemic and bronchial upregulation of the chemotactic axis fractalkine-CX(3)CR(1). This might contribute to the rapid recruitment of circulating CD4(+) T lymphocytes in the airways after allergen stimulation.

CX(3)C chemokine fractalkine in pulmonary arterial hypertension.

Perivascular infiltrates composed of macrophages and lymphocytes have been described in lung biopsies of patients displaying pulmonary arterial hypertension (PAH), suggesting that circulating inflammatory cells can be recruited in affected vessels. CX(3)C chemokine fractalkine is produced by endothelial cells and promotes leukocyte recruitment, but unlike other chemokines, it can capture leukocytes rapidly and firmly in an integrin-independent manner under high blood flow. We therefore hypothesized that fractalkine may contribute to pulmonary inflammatory cell recruitment in PAH. Expression and function of the fractalkine receptor (CX(3)CR1) were studied by use of triple-color flow cytometry on circulating T-lymphocyte subpopulations in freshly isolated peripheral blood mononuclear cells from control subjects and patients with PAH. Plasma-soluble fractalkine concentrations were measured by enzyme-linked immunosorbent assay. Finally, fractalkine mRNA and protein expression were analyzed in lung samples by reverse transcriptase-polymerase chain reaction or in situ hybridization and immunohistochemistry, respectively. In patients with PAH, CX(3)CR1 expression and function are upregulated in circulating T-lymphocytes, mostly of the CD4+ subset, and plasma soluble fractalkine concentrations are elevated, as compared with control subjects. Fractalkine mRNA and protein product are expressed in pulmonary artery endothelial cells. We conclude that inflammatory mechanisms involving chemokine fractalkine and its receptor CX(3)CR1 may have a role in the natural history of PAH.

Protein kinase and NO-stimulated ADP-ribosyltransferase activities associated with glyceraldehyde-3-phosphate dehydrogenase isolated from human liver.

Background/aims: GAPD has been exhaustively investigated as a key cytosolic enzyme in glycolysis. In recent years GAPD has also been implicated in many cellular activities unrelated to glycolysis. However, although various functions have been ascribed to GAPD from rabbit muscle, human blood and rat tissues, no information is available on human liver GAPD. We have recently demonstrated that, as a cellular kinase, GAPD might interfere in the life-cycle of hepatitis B virus. We therefore investigated the enzymatic activities and subcellular localization of GAPD in normal human liver. Methods: GAPD and hepatocyte membranes were isolated from human liver homogenates to study the subcellular localization and enzymatic activities of GADP (kinase and ADP-ribosyltransferase). Results: (i) GAPD was recovered from the plasma-membrane-enriched fraction, in internal membranes, and in the cytosol; (ii) GAPD could be phosphorylated, a phenomenon inhibited by both GAP and NADH; and (iii) GAPD exhibits ADP-ribosyltransferase activity, which is stimulated by nitric oxide in a concentration-dependent manner. Conclusions: Human liver GAPD may play significant biological roles in addition to glycolysis, especially in signal transduction and in intracellular processes possibly involved in HBV infection.