Hironori Matsushima

TLR3-, TLR7-, and TLR9-mediated production of proinflammatory cytokines and chemokines from murine connective tissue type skin-derived mast cells but not from bone marrow-derived mast cells.

Recent studies have revealed that murine bone marrow-derived cultured mast cells (BMMC), which are phenotypically immature mast cells, express functional TLR2 and TLR4 that recognize distinct pathogen-associated molecules. However, it remains relatively uncertain whether mast cells express other TLR. We recently established a method to obtain large numbers of murine fetal skin-derived cultured mast cells (FSMC); these cells exhibit important features of connective tissue type mast cells. Working with FSMC and BMMC, the TLR mRNA expression profiles were compared between both cell types. Although TLR2 and TLR4 mRNA were detected in both cells at comparable levels, TLR3, TLR7, and TLR9 mRNA were expressed by FSMC at higher levels than by BMMC, suggesting distinct TLR expression profiles among different mast cell populations. With respect to their functional aspects, FSMC, but not BMMC, dose dependently produced proinflammatory cytokines (TNF-α and IL-6) and chemokines (RANTES, MIP-1α, and MIP-2) in response to poly(I:C), R-848, and CpG oligodeoxynucleotide, which are TLR3, TLR7, and TLR9 activators, respectively. Interestingly, these TLR activators failed to induce degranulation and IL-13 production by both mast cells, although peptidoglycan and LPS (TLR2 and TLR4 activators, respectively) induced IL-13 production by both cells. Mast cells, thus, may have potential to recruit other immune cells to the infected sites by responding to various bacterial and viral components through TLR signaling pathways, presumably being involved in initiating innate immunity and subsequently linking innate and acquired immune responses.

Neutrophil-derived IL-1β Is Sufficient for Abscess Formation in Immunity against Staphylococcus aureus in Mice

Neutrophil abscess formation is critical in innate immunity against many pathogens. Here, the mechanism of neutrophil abscess formation was investigated using a mouse model of Staphylococcus aureus cutaneous infection. Gene expression analysis and in vivo multispectral noninvasive imaging during the S. aureus infection revealed a strong functional and temporal association between neutrophil recruitment and IL-1β/IL-1R activation. Unexpectedly, neutrophils but not monocytes/macrophages or other MHCII-expressing antigen presenting cells were the predominant source of IL-1β at the site of infection. Furthermore, neutrophil-derived IL-1β was essential for host defense since adoptive transfer of IL-1β-expressing neutrophils was sufficient to restore the impaired neutrophil abscess formation in S. aureus-infected IL-1β-deficient mice. S. aureus-induced IL-1β production by neutrophils required TLR2, NOD2, FPR1 and the ASC/NLRP3 inflammasome in an α-toxin-dependent mechanism. Taken together, IL-1β and neutrophil abscess formation during an infection are functionally, temporally and spatially linked as a consequence of direct IL-1β production by neutrophils.

Osteopontin is produced by mast cells and affects IgE-mediated degranulation and migration of mast cells.

Osteopontin (OPN), originally discovered in bone as an extracellular matrix protein, was identified in many cell types in the immune system, presumably being involved in many aspects of pathogenesis of inflammatory and immune diseases. Mast cells are also involved in such pathological aspects by secreting multiple mediators. However, it has not been determined whether mast cells produce OPN and whether it affects their function. To test this, we used murine fetal skin‐derived cultured mast cells (FSMC) and bone marrow‐derived cultured mast cells. We found that OPN was spontaneously produced by FSMC and inducible by ionomycin and FcϵRI aggregation in bone marrow‐derived cultured mast cells. In the presence of mast cell growth factors, FSMC were similarly generated from both OPN‐deficient (OPN–/–) and ‐sufficient (OPN+/+) mice without significant differences in yield, purity, granularity, and viability. Using OPN–/– FSMC, we found that recombinant OPN augmented IgE‐mediated degranulation and induced FSMC chemotaxis. Both effects were mediated by OPN receptors (i.e. CD44 and integrin αv). IgE‐mediated passive cutaneous anaphylaxis was significantly reduced in OPN–/– mice compared with OPN+/+ mice, indicating physiological relevance of OPN. These results indicate that OPN is a mast cell mediator, enhances mast cell responses to antigen, and thus may influence mast cell‐related pathological conditions.

The effects of endothelin-1 on degranulation, cytokine, and growth factor production by skin- derived mast cells

Endothelin‐1 (ET‐1), originally described as a vasoconstrictor, is now known to be involved in pathogenesis of various disorders including vascular, inflammatory, and fibrotic diseases. Recentstudies suggest that mast cells are also involved in the same pathological conditions. In this study, we tested a hypothesis that ET‐1 would affect mast cell functions and contribute to such disease conditions, using fetal skin‐derived cultured mast cells (FSMC) and bone marrow‐derived cultured mast cells (BMMC). FSMC expressed ET receptors (ETA and ETB) at mRNA and protein levels, whereas BMMC expressed lower levels of ETA, and little, if any, ETB. ET‐1 induced degranulation by FSMC, but not by BMMC through ETA‐mediated pathways. ET‐1 at different concentrations exerted the reciprocal effects on degranulation by IgE‐bound FSMC. Furthermore, ET‐1 induced TNF‐α and IL‐6 production by FSMC, but not by BMMC, and significantly enhanced VEGF production and TGF‐β1 mRNA expression by FSMC. Finally, ET‐1 was produced by FSMC, but not by BMMC in response to Toll‐like receptor ligands. These results indicate contrasting impacts of ET‐1 on distinct mast cell populations. We propose that ET‐1 may participate in pathological conditions of various disorders via its multi‐functional effects on mast cells under certain conditions.

IL-33 promotes DC development in BM culture by triggering GM-CSF production.

Short‐term DC cultures generated with GM‐CSF and other cytokines have markedly improved our ability to study the immunobiology of DC. Here, we tested 65 cytokines individually for their potential to promote the generation of CD11c+ cells in a murine BM culture system. In addition to several cytokines known to promote DC survival and/or growth, IL‐33 was found to augment DC development time‐ and dose‐dependently. Although the resulting CD11c+ cells generated in the presence of IL‐33 exhibited a typical dendritic morphology, they expressed MHC class II molecules only at modest levels, showed negligible responses to TLR ligands, produced no detectable IL‐12 p70, displayed PD‐L1 and PD‐L2 on the surface, and failed to activate immunologically naïve T cells efficiently. IL‐33‐induced expansion of CD11c+ cells was completely blocked by anti‐GM‐CSF mAb, and GM‐CSF mRNA and protein expression in BM culture was markedly elevated by added IL‐33, indicating that IL‐33 promotes in vitro DC generation indirectly by a GM‐CSF‐dependent manner. With regard to the cellular source, IL‐33‐dependent GM‐CSF production was observed exclusively within the CD45+/FcεRI+ BM population. Not only do our results reinforce the notion that GM‐CSF serves as a primary DC growth factor, but they also reveal a previously unrecognized mechanism supporting DC development.

Emergence, origin, and function of neutrophil–dendritic cell hybrids in experimentally induced inflammatory lesions in mice

Although unusual neutrophils expressing major histocompatibility complex class II (MHC II) and costimulatory molecules have been detected at inflammatory sites in mice and humans, their identity, origin, and function remain unclear. We have demonstrated that, when cultured with granulocyte macrophage-colony-stimulating factor, neutrophils can give rise to a unique hybrid population exhibiting dual phenotypic and functionality of neutrophils and dendritic cells (DCs). Here we report that hybrid cells expressing surface markers of neutrophils (Ly6G, L-selectin, CXC chemokines receptor 2, and 7/4) and DCs (CD11c, MHC II, CD80, and CD86) become detectable in the peritoneal cavity, skin, lung, and lymph nodes under inflammatory conditions. Importantly, 20% to 30% of the adoptively transferred neutrophils acquired CD11c and MHC II expression when recovered from inflammatory lesions, demonstrating neutrophil → hybrid conversion in living animals. Using Escherichia coli strains expressing green fluorescent protein and ovalbumin, we further show hybrids play dual protective roles by rapidly clearing bacteria and presenting bacterial antigens to CD4 T cells. These results indicate that some of the neutrophils recruited to inflammatory lesions can differentiate into neutrophil-DC hybrids, thus challenging the classic view of neutrophils as terminally differentiated leukocytes destined to die or to participate primarily in host innate immunity.

Intravital Imaging of IL-1β Production in Skin

IL-1 is a prototypic inflammatory cytokine that has pathogenic roles in various skin disorders. Although Langerhans cells (LCs) have been reported to express IL-1beta mRNA upon application of contact sensitizers, it remains unclear whether other cell types produce IL-1beta in skin. Thus, we sought to directly identify IL-1beta-producing cells in living animals by construction of transgenic mice expressing DsRed fluorescence protein gene under the control of IL-1beta promoter. Little DsRed fluorescence signal was detected in skin under steady-state conditions. Striking increases in DsRed signal were observed after topical application of a contact sensitizer, oxazolone, which also induced markedly elevated IL-1beta mRNA and protein expression. DsRed signal was expressed primarily by CD45(+)/CD11b(+) myeloid leukocytes in both epidermal and dermal compartments and was detected only in small fractions of epidermal LCs. Interestingly, DsRed(+) cells emerged preferentially as clusters around hair follicles. Intravital confocal imaging experiments revealed highly motile potentials of DsRed(+) cells-they constantly crawled around hair follicles via amoeba-like movements with a mean velocity of 1.0+/-0.4 microm min(-1) (epidermis) or 2.7+/-1.4 microm min(-1) (dermis). The newly developed in vivo imaging system represents a useful tool for studying spatial regulation of IL-1beta production in skin.

Neutrophil priming occurs in a sequential manner and can be visualized in living animals by monitoring IL-1β promoter activation.

Rapid enhancement of phagocyte functionality is a hallmark of neutrophil priming. GeneChip analyses unveiled elevated CD54, dectin-2, and IL-1β mRNA expression by neutrophils isolated from inflammatory sites. In fact, CD54 and dectin-2 protein expression was detected on neutrophils recovered from skin, peritoneal, and lung inflammation lesions but not on those in bone marrow or peripheral blood. Neutrophils increased CD54 and dectin-2 mRNA during migration in Boyden chambers and acquired CD54 and dectin-2 surface expression after subsequent exposure to GM-CSF. Neutrophils purified from IL-1β promoter-driven DsRed-transgenic mice acquired DsRed signals during cell migration or exposure to GM-CSF. CD54 and dectin-2 were expressed by DsRed+ (but not DsRed−) neutrophils in GM-CSF–supplemented cultures, and neutrophils recovered from inflammatory sites exhibited strong DsRed signals. The dynamic process of neutrophil priming was studied in chemically induced inflammatory skin lesions by monitoring DsRed expression using confocal microscopy. A majority (>80%) of Ly6G+ neutrophils expressed DsRed, and those DsRed+/Ly6G+ cells exhibited crawling motion with a higher velocity compared with their DsRed−/Ly6G+ counterparts. This report unveils motile behaviors of primed neutrophils in living animals. We propose that neutrophil priming occurs in a sequential manner with rapid enhancement of phagocyte functionality, followed by CD54 and dectin-2 mRNA and protein expression, IL-1β promoter activation, and accelerated motility. Not only do these findings provide a new conceptual framework for our understanding of the process of neutrophil priming, they also unveil new insights into the pathophysiology of many inflammatory disorders that are characterized by neutrophil infiltration.

Reciprocal Regulation of Development of Neutrophil-Dendritic Cell Hybrids in Mice by IL-4 and Interferon-Gamma

Neutrophils contribute to innate host immunity by functioning as professional phagocytes, whereas dendritic cells (DCs) are prototypic antigen presenting cells (APCs) responsible for the induction of adaptive immune responses. We have demonstrated recently that neutrophils trans-differentiate into a unique population, termed “neutrophil-DC hybrids,” expressing surface markers of both neutrophils and DCs and exhibiting dual functionality of both phagocytes and APCs. Although the hybrid cells emerged in significant numbers in murine bone marrow (BM) culture in the presence of GM-CSF, mechanisms regulating their development remained mostly unknown. In this study, we tested a total of 61 cytokines for their potentials to regulate neutrophil-DC hybrid formation using a newly developed BM micro-culture system combined with semi-automated FACS analysis. Several cytokines including GM-CSF were found to promote the generation of neutrophil-DC hybrids defined by the phenotype of CD11c+/MHC II+/Ly6G+. When tested in the presence of GM-CSF, hybrid cell development was enhanced by IL-4 and suppressed by interferon-γ (IFNγ) in dose-dependent fashions. We next determined in vivo impacts of IL-4 and IFNγ on the development of neutrophil-DC hybrids in thioglycollate-induced peritonitis lesions. Intraperitoneal administrations of IL-4/anti-IL-4 antibody complex (IL-4C) significantly increased the number of hybrids recovered from the lesions. By contract, recovery of hybrids was reduced by recombinant IFNγ. With regard to function, those hybrid cells recovered from IL-4C-treated mice and IFNγ-treated mice showed potent abilities to capture E.coli. These observations imply that emergence of neutrophil-DC hybrids in inflammatory sites is tightly regulated by local cytokine milieus.

Bidirectional homing of Tregs between the skin and lymph nodes

Although several homing receptors are known to be differentially expressed by Tregs in lymphoid tissues compared with those found in peripheral tissues, it remains unclear whether these cells traffic between the two locations. In this issue of the JCI, Tomura et al. report steady-state Treg migration from the skin to draining LNs in mice. Furthermore, they report that not only does skin inflammation exacerbate LN-directed Treg homing, it also triggers reverse circulation of Tregs from LNs to skin, whereby these cells contribute to regulation of the immune response. These results now form a new framework for our understanding of Treg homing.