Walter Luini

Role of IL-6 and its soluble receptor in induction of chemokines and leukocyte recruitment.

IL-6-/- mice showed impaired leukocyte accumulation in subcutaneous air pouches. Defective leukocyte accumulation was not due to a reduced migratory capacity of IL-6-/- leukocytes and was associated with a reduced in situ production of chemokines. These observations led to a reexamination of the interaction of IL-6 with endothelial cells (EC). EC express only the gp130 signal transducing chain and not the subunit-specific IL-6R and are therefore unresponsive to IL-6. However, EC are responsive to a combination of IL-6 and soluble IL-6R as measured by the activation of STAT3, chemokine expression, and augmentation of ICAM-1. Activation by IL-6-IL-6R complexes was inhibited by an IL-6 receptor antagonist and potentiated by a superagonist. Hence, in vivo and in vitro evidence supports the concept that the IL-6 system plays an unexpected positive role in local inflammatory reactions by amplifying leukocyte recruitment.

Role of ChemR23 in directing the migration of myeloid and plasmacytoid dendritic cells to lymphoid organs and inflamed skin

Chemerin is a chemotactic agent that was recently identified as the ligand of ChemR23, a serpentine receptor expressed by activated macrophages and monocyte-derived dendritic cells (DCs). This paper shows that blood plasmacytoid and myeloid DCs express functional ChemR23. Recombinant chemerin induced the transmigration of plasmacytoid and myeloid DCs across an endothelial cell monolayer. In secondary lymphoid organs (lymph nodes and tonsils), ChemR23 is expressed by CD123+ plasmacytoid DCs and by CD1a+ DC-SIGN+ DCs in the interfollicular T cell area. ChemR23+ DCs were also observed in dermis from normal skin, whereas Langerhans cells were negative. Chemerin expression was selectively detected on the luminal side of high endothelial venules in secondary lymphoid organs and in dermal endothelial vessels of lupus erythematosus skin lesions. Chemerin+ endothelial cells were surrounded by ChemR23+ plasmacytoid DCs. Thus, ChemR23 is expressed and functional in plasmacytoid DCs, a property shared only by CXCR4 among chemotactic receptors. This finding, together with the selective expression of the cognate ligand on the luminal side of high endothelial venules and inflamed endothelium, suggests a key role of the ChemR23/chemerin axis in directing plasmacytoid DC trafficking.

Expression of monocyte chemotactic protein-1 by monocytes and endothelial cells exposed to thrombin.

Thrombin, in addition to being a key enzyme in hemostasis, affects a series of endothelial and leukocyte functions and thus may be involved in the regulation of inflammatory reactions. Because leukocyte recruitment and activation are important events in inflammatory and thrombotic processes, in this study we have examined the possibility that thrombin induces the production of a cytokine chemotactic for mononuclear phagocytes. Human peripheral blood mononuclear cells (PBMC) exposed in vitro to thrombin expressed transcripts of monocyte chemotactic protein-1 (MCP-1; alternative acronyms: JE, monocyte chemotactic and activating factor, tumor-derived chemotactic factor). Thrombin was two- to threefold less effective than endotoxin in inducing MCP-1 transcripts in PBMC. Among circulating mononuclear cells, monocytes were identified as the cells expressing MCP-1 in response to thrombin. Monocytes expressed thrombin receptor transcripts. Boiling, hirudin, antithrombin III, and mutation of the catalytic site serine 205 into alanine) blocked the capacity of thrombin to induce MCP-1 expression. The thrombin receptor-activating peptide mimicked the effect of thrombin in inducing MCP-1 expression. Induction of MCP-1 transcript by thrombin was not reduced by blocking interleukin-1 and tumor necrosis factor, suggesting that these mediators are not involved in thrombin-induced expression of MCP-1. In addition to monocytes, endothelial cells (EC) also expressed MCP-1 in response to thrombin, although at lower levels compared with monocytes. Actinomycin D experiments indicated that induction of MCP-1 by thrombin in PBMC and EC was gene transcription dependent. The inhibition of protein synthesis blocked thrombin-induced MCP-1 expression in PBMC, whereas it superinduced both constitutive and thrombin-inducible expression of MCP-1 in EC, indicating different mechanisms of regulation of this gene in mononuclear phagocytes versus endothelial cells. Thrombin stimulated mononuclear cells and EC to release chemotactic activity for monocytes that could be inhibited by absorption with anti-MCP-1 antibodies. Induction of a chemotactic cytokine for monocytes by thrombin points to the importance of this enzyme in regulating inflammatory processes and further indicates that hemostasis, inflammation, and immunity are strictly interconnected processes.

Differential responsiveness to constitutive vs. inducible chemokines of immature and mature mouse dendritic cells

Upon exposure to immune or inflammatory stimuli, dendritic cells (DC) migrate from peripheral tissues to lymphoid organs, where they present antigen. The molecular basis for the peculiar trafficking properties of DC is largely unknown. In this study, mouse DC were generated from CD34+ bone marrow precursors and cultured with granulocyte‐macrophage‐CSF and Flt3 ligand for 9 days. Chemokines active on immature DC include MIP1α, RANTES, MIP1β, MCP‐1, MCP‐3, and the constitutively expressed SDF1, MDC, and ELC. TNF‐α‐induced DC maturation caused reduction of migration to inducible chemokines (MIPIα, RANTES, MIP1β, MCP‐1, and MCP‐3) and increased migration to SDF1, MDC, and ELC. Similar results were obtained by CD40 ligation or culture in the presence of bacterial lipopolysaccharide. TNF‐α down‐regulated CC chemokine receptor (CCR)1, CCR2, and CCR5 and up‐regulated CCR7 mRNA levels, in agreement with functional data. This study shows that selective responsiveness of mature and immature DC to inducible vs. constitutively produced chemokines can contribute to the regulated trafficking of DC. J. Leukoc. Biol. 66: 489–494; 1999.

Defective dendritic cell migration and activation of adaptive immunity in PI3Kγ‐deficient mice

Gene‐targeted mice were used to evaluate the role of the gamma isoform of phosphoinositide 3‐kinase (PI3Kγ) in dendritic cell (DC) migration and induction of specific T‐cell‐mediated immune responses. DC obtained from PI3Kγ−/− mice showed a reduced ability to respond to chemokines in vitro and ex vivo and to travel to draining lymph nodes under inflammatory conditions. PI3Kγ−/− mice had a selective defect in the number of skin Langerhans cells and in lymph node CD8α− DC. Furthermore, PI3Kγ−/− mice showed a defective capacity to mount contact hypersensitivity and delayed‐type hypersensitivity reactions. This defect was directly related to the reduced ability of antigen‐loaded DC to migrate from the periphery to draining lymph nodes. Thus, PI3Kγ plays a nonredundant role in DC trafficking and in the activation of specific immunity. Therefore, PI3Kγ may be considered a new target to control exaggerated immune reactions.

Unique Regulation of CCL18 Production by Maturing Dendritic Cells

Dendritic cells (DC) orchestrate the trafficking of lymphocytes by secreting chemokines with different specificity and function. Chemokines are produced at higher levels by mature DC. This study shows that CCL18 is one of the most abundant chemokines produced by immature DC. In contrast to all other chemokines investigated to date, CCL18 was selectively down-regulated during the maturation process induced by LPS, TNF, CD40 ligand, Staphylococcus aureus Cowan I, Candida albicans, and influenza virus. IL-10 and vitamin D3, two known inhibitors of DC differentiation and function, strongly promoted CCL18 secretion, whereas IFN-γ, a costimulator of DC function, inhibited its production. IL-10 also induced CCL18 secretion in blood myeloid DC. No CCL18 secretion was observed in blood plasmacytoid DC. The opposite pattern of regulation was observed for CCL20, a prototypic inflammatory chemokine. CCL18 was found to be a chemotactic factor for immature DC. Therefore, CCL18 may act as a chemotactic signal that promotes the colocalization of immature DC with naive T lymphocytes in an IL-10-dominated environment with the consequent generation of T regulatory cells. These characteristics suggest that CCL18 may be part of an inhibitory pathway devoted to limiting the generation of specific immune responses at peripheral sites.

Identification of the CC chemokines TARC and macrophage inflammatory protein-1β as novel functional ligands for the CCR8 receptor

Chemokines are key molecules in directing leukocyte migration toward sites of inflammation. We have previously cloned a putative CC chemokine receptor gene, TER1, whose expression is restricted to lymphoid tissues and cell lines. Recently, this receptor has been shown to signal in response to the human CC chemokine I‐309 and thus it has been renamed CCR8 according to the current nomenclature. In the present study, we report the identification of the CC chemokines thymus and activation‐regulated cytokine (TARC) and macrophage inflammatory protein‐1β (MIP‐1β) as CCR8 ligands, as they induce chemotaxis in CCR8 Jurkat stable transfectants. Furthermore, we have generated a polyclonal antiserum that is able to recognize the CCR8 molecule in transfectant lysates. The pattern of CCR8 mRNA expression and the functional effects exerted by its ligand suggest that the triggering of this receptor may regulate multiple functions including activation, migration and proliferation of lymphoid cells.

Induction of Functional IL-8 Receptors by IL-4 and IL-13 in Human Monocytes

IL-8 and related Glu-Leu-Arg (ELR+) CXC chemokines are potent chemoattractants for neutrophils but not for monocytes. IL-13 and IL-4 strongly increased CXCR1 and CXCR2 chemokine receptor expression in human monocytes, macrophages, and dendritic cells. The effect was receptor- and cell type-selective, in that CCRs were not increased and no augmentation was seen in neutrophils. The effect was rapid, starting at 4 h, and concentration dependent (EC50 = 6.2 and 8.3 ng/ml for CXCR1 and CXCR2, respectively) and caused by new transcriptional activity. IL-13/IL-4-treated monocytes showed increased CXCR1 and CXCR2 membrane expression. IL-8 and related ELR+ chemokines were potent and effective chemotactic agents for IL-13/IL-4-treated monocytes, but not for untreated mononuclear phagocytes, with activity comparable to that of reference monocyte attractants, such as MCP-1. In the same cells, IL-8 also caused superoxide release. Macrophages and dendritic cells present in biopsies from Omenn’s syndrome and atopic dermatitis patients, two Th2 skewed pathologies, expressed IL-8 receptors by immunohistochemistry. These results show that IL-13 and IL-4 convert IL-8 and related ELR+ chemokines, prototypic neutrophil attractants, into monocyte chemotactic agonists, by up-regulating receptor expression. Therefore, IL-8 and related chemokines may contribute to the accumulation and positioning of mononuclear phagocytes in Th2-dominated responses.

Phosphatidic Acid and Lysophosphatidic Acid Induce Haptotactic Migration of Human Monocytes

The present study was aimed at defining the chemotactic activity of phosphatidic acid, which is rapidly produced by phagocytes in response to chemotactic agonists. Exogenously added phosphatidic acid induced human monocyte directional migration across polycarbonate filters with an efficacy (number of cell migrated) comparable to that of “classical” chemotactic factors. In lipid specificity studies, activity of phosphatidic acid decreased with increasing acyl chain length but was restored by introducing unsaturation in the acyl chain with the most active form being the natural occurring 18:0,20:4-phosphatidic acid. Lysophosphatidic acid was also active in inducing monocyte migration. No other phospholipid and lysophospholipid tested was effective in this response. Monocyte migration was regulated by a gradient of phosphatidic acid and lysophosphatidic acid bound to the polycarbonate filter, in the absence of detectable soluble chemoattractant. Migration was also observed if phospholipids were bound to fibronectin-coated polycarbonate filters. Thus, phosphatidic acid and lysophosphatidic acid, similarly to other physiological chemoattractants (e.g. C5a and interleukin-8), induce cell migration by an haptotactic mechanism. Phosphatidic acid caused a rapid increase of filamentous actin and, at higher concentrations, induced a rise of intracellular calcium concentration. Monocyte migration to phosphatidic acid and lysophosphatidic acid, but not to diacylglycerol, was inhibited in a concentration-dependent manner by Bordetella pertussis toxin, while cholera toxin was ineffective. In the chemotactic assay, phosphatidic acid and lysophosphatidic acid induced a complete homologous desensitization and only partially cross-desensitized one with each other, or with diacylglycerol and monocyte chemotactic protein-1. Suramine inhibited monocyte chemotaxis with a different efficiency: phosphatidic acid > lysophosphatidic acid diacylglycerol. On the contrary, monocyte chemotactic protein-1-induced chemotaxis was not affected by the drug. Collectively, these data show that phosphatidic acid induces haptotactic migration of monocytes that is at least in part receptor-mediated. These results support a role for phosphatidic acid and lysophosphatidic acid in the regulation of leukocyte accumulation into tissues.

Human monocyte-derived and CD34+ cell-derived dendritic cells express functional receptors for platelet activating factor.

Dendritic cells (DC) are a heterogeneous population of specialized antigen presenting cells that exhibit complex trafficking properties. DC differentiated in vitro from both peripheral monocytes and CD34+ cells expressed mRNA for platelet activating factor (PAF) receptor. Expression of PAF receptor was increased by TNFα, a prototypic inflammatory cytokine that induces differentiation and in vivo mobilization of DC. PAF induced in vitro directional migration of DC obtained from both precursor cells through its specific receptor. Since DC are highly motile cells, protein chemoattractants as well as bioactive phospholipids are likely to contribute to tissue localization of DC, in vivo.