ADAM10 and Notch1 on murine dendritic cells control the development of type 2 immunity and IgE production.

BACKGROUND: Allergy and allergic asthma are significant health burdens in developed countries and are increasing in prevalence. Dendritic cells (DCs) initiate immune responses to common aeroallergens, and ADAM10 has been demonstrated to be important for the development of adaptive responses. This study's objective was to understand the role of ADAM10 on DCs in the development of allergic and anaphylactic responses. METHODS: In this study, we used mouse models of allergic airway inflammation (house dust mice and Alternaria alternata) and OVA-induced models of active anaphylaxis to determine the DC-specific function of ADAM10 and Notch signaling. To examine TH 1 and TH 17 immunity infection with Anaplasma phagocytophilum and Citrobacter rodentium respectively, were used. RESULTS: Mice, which have ADAM10 deleted from DCs, have dramatic reductions in IgE production and do not develop significant TH 2 immune responses. Further, ADAM10DC-/- mice are resistant to IgE-mediated anaphylaxis. This response is selective for TH 2 immunity as TH 1 and TH 17 immunity is largely unaffected. Notch1, a known ADAM10 substrate, when knocked out of DCs (Notch1DC-/- ) demonstrated a similar reduction in anaphylaxis and IgE. Without ADAM10 and Notch1 signaling, DCs were unable to make cytokines that stimulate TH 2 cells and cytokines. Anaphylaxis and allergic lung inflammation were restored in ADAM10DC-/- with the overexpression of the Notch1-intracellular domain, confirming the role of Notch signaling. CONCLUSIONS: Targeting ADAM10 and Notch1 on DCs represent a novel strategy for modulating TH 2 immune responses and IgE production.

A potential new target for asthma therapy: a disintegrin and metalloprotease 10 (ADAM10) involvement in murine experimental asthma.

BACKGROUND: Elevated levels of CD23, a natural regulator of IgE production, have been shown to decrease the signs of lung inflammation in mice. The aim of this study was to study the involvement of ADAM10, the primary CD23 sheddase, in experimental asthma. METHODS: ADAM10 was blocked either by using mice with a B-cell-specific deletion of the protease or pharmacologically by intranasal administration of selective ADAM10 inhibitors. Airway hypersensitivity (AHR) and bronchoaveolar lavage fluid (BALF) eosinophilia and select BALF cytokine/chemokine levels were then determined. RESULTS: Using an IgE and mast cell-dependent mouse model, B-cell-specific ADAM10(-/-) mice (C57B/6 background) exhibited decreased eosinophilia and AHR when compared with littermate (LM) controls. Treatment of C57B/6 mice with selective inhibitors of ADAM10 resulted in an even further decrease in BALF eosinophilia, as compared with the ADAM10(-/-) animals. Even in the Th2 selective strain, Balb/c, BALF eosinophilia was reduced from 60% to 23% respectively. In contrast, when an IgE/mast cell-independent model of lung inflammation was used, the B-cell ADAM10(-/-) animals and ADAM10 inhibitor treated animals had lung inflammation levels that were similar to the controls. CONCLUSIONS: These results thus show that ADAM10 is important in the progression of IgE-dependent lung inflammation. The use of the inhibitor further suggested that ADAM10 was important for maintaining Th2 levels in the lung. These results thus suggest that decreasing ADAM10 activity could be beneficial in controlling asthma and possibly other IgE-dependent diseases.

Interaction of beta1H globulin with cell-bound C3b: quantitative analysis of binding and influence of alternative pathway components on binding.

Purified beta1H globulin (beta1H) was shown to bind to C3b coated cells by both immunofluorescent and radioactive tracer techniques. With EAC43, the amount of beta1H bound was directly proportional to the amount of C3 used to prepare the cells; EA, EAC14 and EAC14oxy2 bound very small amounts of beta1H. The C3b binding site on beta1H was labile in that not all of the purified 125I-beta1H was capable of binding to C3b, even when an excess of cell-bound C3b was present. Scatchard analysis of binding of beta1H to C3b-coated cells indicated an equilibrium constant of 10(9) L/M. Deviations from linearity were regularly found on Scatchard analyses. This was consistent with the hypothesis that the beta1H binding sites exhibit negative cooperativity in that as more sites become occupied, it becomes more difficult to fill the remaining sites. The stoichiometry of the reaction between C3b and beta1H was examined using EAC14oxy23 prepared with 131I-C3 and beta1H labeled with 125I. Between 0.5--0.8 beta1H molecules were bound per C3b molecule. Other alternative pathway components influenced the binding of 125I-beta1H to cell bound C3b. Both C3b and native C3 inhibited binding of labeled beta1H at an efficiency approximately 1/1,000 that of unlabeled beta1H. Factor B inhibited binding with 1/280 the efficiency of unlabeled beta1H. Properdin caused a dose-dependent increase in the binding of beta1H; this enhancement was abrogated if B was also present in the reaction mixture. Scatchard analysis indicated that the enhancement of beta1H binding by P resulted in an increased number of available binding sites rather than an increase in the affinity of binding.

The murine lymphocyte receptor for IgE. II. Characterization of the multivalent nature of the B lymphocyte receptor for IgE.

The murine B lymphocyte Fc epsilon R is functionally multivalent. Radiolabeled rat IgE, when bound to the B cell Fc epsilon R will co-isolate with the Fc epsilon R on a rat IgE affinity column; examination of the affinity column eluate by SDS-PAGE reveals the component previously identified as the Fc epsilon R as well as E and L chains from IgE. At low levels of Fc epsilon R saturation, up to 30% of the Fc epsilon R bound IgE becomes bound to IgE-Affi-Gel. By using a biotin-avidin system, the coprecipitation of non-haptenated IgE with haptenated IgE was examined and the results suggest (but do not prove) a divalent receptor.

Infection with Nippostrongylus brasiliensis or injection of anti-IgD antibodies markedly enhances Fc-receptor-mediated interleukin 4 production by non-B, non-T cells.

Non-B, non-T cells from spleen and bone marrow of naive mice produce IL-4 upon stimulation by plate-bound IgE or IgG2a in the presence of IL-3. Infection of mice with Nippostrongylus brasiliensis (Nb) or injection of anti-IgD antibodies, treatments known to cause striking polyclonal IgE responses, increase the number of splenic non-B, non-T cells and cause 10-30-fold increase in IL-4 production by a standard number of these cells. In Nb-infected mice, IL-4 producing non-B, non-T cells can be found in the lungs, a site through which Nb larvae migrate. Non-B, non-T cells from anti-IgD-injected mice produce IL-4 in response to anti-IgE antibodies, indicating that these cells have been sensitized in vivo with IgE and that crosslinkage of such IgE can lead to stimulation of lymphokine production. Similarly, non-B, non-T cells from Nb-infected mice produce IL-4 upon stimulation with Nb-antigen, indicating that antigen can also crosslink receptors on in vivo sensitized non-B, non-T cells and stimulate lymphokine production. The striking increases in the IL-4-producing capacity of the splenic non-B, non-T cell population in anti-IgD-injected and Nb-infected mice and the in vivo sensitization of these cells strongly suggests that they may have an important role in lymphokine production in helminthic infections and other situations marked by striking elevations of serum IgE levels.

Enhanced intestinal transepithelial antigen transport in allergic rats is mediated by IgE and CD23 (FcepsilonRII).

We previously reported that active sensitization of rats resulted in the appearance of a unique system for rapid and specific antigen uptake across intestinal epithelial cells. The current studies used rats sensitized to horseradish peroxidase (HRP) to define the essential components of this antigen transport system. Sensitization of rats to HRP stimulated increased HRP uptake into enterocytes (significantly larger area of HRP-containing endosomes) and more rapid transcellular transport compared with rats sensitized to an irrelevant protein or naive control rats. Whole serum but not IgE-depleted serum from sensitized rats was able to transfer the enhanced antigen transport phenomenon. Immunohistochemistry demonstrated that sensitization induced expression of CD23, the low-affinity IgE receptor (FcepsilonRII), on epithelial cells. The number of immunogold-labeled CD23 receptors on the enterocyte microvillous membrane was significantly increased in sensitized rats and was subsequently reduced after antigen challenge when CD23 and HRP were localized within the same endosomes. Finally, pretreatment of tissues with luminally added anti-CD23 antibody significantly inhibited both antigen transport and the hypersensitivity reaction. Our results provide evidence that IgE antibodies bound to low-affinity receptors on epithelial cells are responsible for the specific and rapid nature of this novel antigen transport system.

Fc epsilon receptors.

Advances in our understanding of the molecular structure of Fc receptors have been made at a rapid pace. Details of how Fc receptors are involved in cell triggering, e.g. allergic mediator release from mast cells, and IgE synthesis are also continuing to be elucidated, although much work is still required. Recent highlights of investigations of mast-cell and lymphocyte IgE Fc receptors will be outlined.

Vitamin A in liposomes. Inhibition of complement binding and alteration of membrane structure.

Incorporation of vitamin A aldehyde (retinal) into liposomes had an inhibitory effect on the amount of human complement protein bound in the presence of specific antiserum. The total membrane-bound protein was directly measured on liposomes which were washed after incubation in antiserum and fresh human serum (complement). At every concentration of complement, decreased protein binding was found with liposomes which contained retinal. Binding of the third component of complement (C3) was also measured directly on washed liposomes and was found to be decreased in the presence of retinal. The diminution in protein binding due to retinal was not caused by differences in the amount of antibody bound and this was shown by two experiments. First, specific antibody protein binding to liposomes was directly measured and was essentially unaffected by retinal. Second, liposomes were prepared from lipid extracts of sheep erythrocytes. These liposomes were used as as immunoadsorbants to remove antisheep erythrocyte antibodies. The immunoadsorbant capacity was the same in both the presence and the absence of retinal. A further conclusion from these experiments was that retinal did not change the number of liposomal glycolipid antigen molecules available for antibody binding and thus presumably did not change the total number of lipid molecules present on the outer surface of the liposomes. Retinal did have an effect on the geometric structure of the liposomes. Size distribution measurements were performed in the diameter range of 1-6.35 mum by using an electronic particle size analyzer (Coulter Counter). Liposomes containing retinal were shifted toward smaller sizes and had less total surface area and volume. It was suggested that retinal-containing liposomes may have had a tighter packing of the molecules in the phospholipid bilayer. This effect of retinal on liposomal structure may have been responsible for the observed decreased binding of C3 and total complement protein.

The cross-reactivity of rat IgE and IgG with solubilized receptors of rat basophilic leukemia cells.

Normal rat IgG-Sepharose binds the same two receptors from solubilized rat basophilic leukemia (RBL) cells as are bound by rat IgE-Sepharose. These receptors have previously been designated R and H, and have apparent mol. wts of 45,000 and 55,000, respectively. Inhibition studies indicate that, although soluble deaggregated IgG is capable of interacting with both receptors, its affinity is higher for H than for R. Conversely, soluble IgE preferentially interacts with R, but its affinity for H is somewhat higher than that of rat IgG. Control studies show that IgG receptor interaction to be specific in that it is significantly stronger than that obtained with F(ab')2 fragments or a variety of proteins having pIs approximating that of IgG.

Characterization of new rat anti-mouse IgE monoclonals and their use along with chimeric IgE to further define the site that interacts with Fc epsilon RII and Fc epsilon RI.

Three rat monoclonal antibodies specific for mouse IgE (C12B9, 23G3, and B1E3) were established by using monoclonal anti-DNP mouse IgE (mIgE) as immunogen. These antibodies, as well as a fourth, (R1E4) were characterized. It was found that one antibody (C12B9) recognizes an allotypic determinant (Igh-7a) found on the C epsilon chain of mIgE. Antibody cross-blocking studies and epitope mapping studies using recombinant mIgE indicated that 3 antibodies (C12B9, R1E4 and 23G3) were directed against the C epsilon 3 domain while one (B1E3) was directed against the C epsilon 4 domain. A highly specific sandwich RIA for mIgE was developed using these antibodies. Use of these monoclonal anti-mIgE antibodies in conjunction with recombinant chimeric mIgE-human IgG1 molecules, demonstrated that the C epsilon 3 domain is important in the binding of mIgE to the murine B cell Fc epsilon RII as well as to the murine mast cell F epsilon RI. The presence of the C epsilon 4 domain influenced the binding of the recombinant IgE to the Fc epsilon RII; in contrast to the C epsilon 4 domain had no effect on binding to the Fc epsilon RI.

Chromosomal location and isoform analysis of mouse Fc epsilon RII/CD23.

The gene for the mouse low affinity receptor for IgE (Fc epsilon RII, also known as CD23) was mapped on Chromosome (Chr) 8 proximal to Plat. This gene, symbolized Fcer2 (formerly Fce2) resides in a region of Chr 8 with linkage homology with human chromosomes 8 and 19. The mouse Fc epsilon RII was examined for the presence of alternate N-terminal forms such as seen in humans. An antisense RNA probe was prepared from the 5' end of the cDNA through the first 660 bp of the cDNA and was used to analyze message from Fc epsilon RII+ B cells and B cell hybridomas both before and after treatment with interleukin 4 (IL-4). Using RNase protection analysis, a major 640 bp band corresponding to the full length probe was seen, even after activation of the cells with LPS in the presence of IL-4, which is known to give high expression levels of the Fc epsilon RII. This result suggests that the mouse does not produce significant levels of an alternate IL-4 inducible Fc epsilon RII, as seen in man, and this may explain the more restricted cell lineage expression of the Fc epsilon RII in the mouse.

Molecular mechanisms of murine Fc epsilon RII/CD23 regulation.

The low affinity receptor for IgE (Fc epsilon RII or CD23), expressed primarily on mouse B cells, is known to be upregulated by interleukin-4 (IL-4) at both the mRNA and protein levels. Fc epsilon RII expression is superinduced when the IL-4 is combined with cell activation. In order to explore the molecular regulation of Fc epsilon RII expression, mouse B cell lines were screened to develop a cell line model. The B cell lymphoma A20.1, was found to behave in a manner similar to mouse B cells in that Fc epsilon RII levels are very low on cells cultured in media alone (< 10(3)/cell), increased by culture in the presence of IL-4, and superinduced by LPS and IL-4 (> 10(5)/cell). The steady state mRNA levels for Fc epsilon RII corresponded to the level of cell surface expression. Transcription assays indicated that the Fc epsilon RII level increases could be explained entirely by increased transcription rates. The A20.1 cell line was subsequently used to analyse the Fc epsilon RII promoter. Nested deletion analysis of the 1.3 kB 5' of the mouse Fc epsilon RII transcription start site, using CAT reporter plasmids transfected into A20.1 cells, identified major elements activating the Fc epsilon RII promoter within 250 bp of the transcription start site. Constructs containing greater than 250 bp of 5' sequence showed significantly reduced CAT activity suggesting negative regulatory regions. Coincident with the restricted tissue expression of murine Fc epsilon RII, the promoter was B cell specific in that little CAT expression was seen in fibroblast, mast cells or T cell lines. Expression was seen, however, in both mouse and human B cell lines. Finally, the promoter was analysed for response to IL-4. Stimulation with IL-4 plus LPS resulted in only a modest increase in CAT activity (approximately 2-fold), in contrast to transcription assays, where increases approximated that seen at the cell surface. Thus, the IL-4 response must also require sequences distal to the regions examined.

Inhibition of CD23-mediated IgE transcytosis suppresses the initiation and development of allergic airway inflammation.

The epithelial lining of the airway tract and allergen-specific IgE are considered essential controllers of inflammatory responses to allergens. The human low affinity IgE receptor, CD23 (FcɛRII), is capable of transporting IgE or IgE-allergen complexes across the polarized human airway epithelial cell (AEC) monolayer in vitro. However, it remains unknown whether the CD23-dependent IgE transfer pathway in AECs initiates and facilitates allergic inflammation in vivo, and whether inhibition of this pathway attenuates allergic inflammation. To this end, we show that in wild-type (WT) mice, epithelial CD23 transcytosed both IgE and ovalbumin (OVA)-IgE complexes across the airway epithelial barrier, whereas neither type of transcytosis was observed in CD23 knockout (KO) mice. In chimeric mice, OVA sensitization and aerosol challenge of WT/WT (bone-marrow transfer from the WT to WT) or CD23KO/WT (CD23KO to WT) chimeric mice, which express CD23 on radioresistant airway structural cells (mainly epithelial cells) resulted in airway eosinophilia, including collagen deposition and a significant increase in goblet cells, and increased airway hyperreactivity. In contrast, the absence of CD23 expression on airway structural or epithelial cells, but not on hematopoietic cells, in WT/CD23KO (the WT to CD23KO) chimeric mice significantly reduced OVA-driven allergic airway inflammation. In addition, inhalation of the CD23-blocking B3B4 antibody in sensitized WT mice before or during airway challenge suppressed the salient features of asthma, including bronchial hyperreactivity. Taken together, these results identify a previously unproven mechanism in which epithelial CD23 plays a central role in the development of allergic inflammation. Further, our study suggests that functional inhibition of CD23 in the airway is a potential therapeutic approach to inhibit the development of asthma.

Use of monoclonal anti-rat IgE in a radioimmunoassay for antigen specific rat IgE.

A monoclonal mouse anti-rat IgE, ELIVB5 (B5) was used in a solid-phase radioimmunoassay (RIA) to detect antigen specific IgE in antisera from rats infected with a larval nematode. Binding of 125I-labeled B5 was specific for rat IgE and did not crossreact with human IgE. The RIA was used to demonstrate crossreactivity between antigens of closely related larval nematodes.

Antisera with anti-pan C3 receptor reactivity which block complement C3b, C3bi and C3d receptors.

Antisera directed at human C3 receptors were prepared by 2 different methods. In method I rabbits were immunized with EAC coated with C3 receptors of tonsil cells (AC3RS type I). In method II rabbits were immunized with insoluble aggregates of tonsil membrane constituents containing significant amounts of C3 receptors. After appropriate absorptions both types of AC3RS showed a selective reactivity with those cells known to express C3 receptors. With the EAC rosette inhibition test it is demonstrated that both types of AC3RS contain antibodies against the binding sites of C3b, C3bi and C3d receptors. The antibody titer was consistently higher in AC3RS of type II.

Androstenetriol and androstenediol. Protection against lethal radiation and restoration of immunity after radiation injury.

Androstenetriol (AET) and Androstenediol (AED) upregulate host immunity, leading to increased resistance against infections. AET augments IL-2, IL-3, IFN gamma levels, and counteracts hydrocortisone immune suppression. AET and AED at a dose of 0.75 mg/- and 8.0 mg/25-g mouse, protected 60 and 70%, respectively, of C57/BL/6J mice irradiated with a lethal dose. These hormones also protected mice irradiated with 6 Gy and infected with a coxsackievirus B4 LD50. AET significantly increased spleen lymphocyte numbers at 7, 14, and 21 days after a 6-Gy exposure. Fluorescent activated cell-sorter analysis of irradiated mice, spleen, and bone marrow showed that AET significantly augmented the myeloid precursor markers, CD11b/Mac-1, and B220 (pan B), as well as the absolute numbers of CD4+/CD8+ cells over the 21 days of testing. Overall, the data are consistent with AET/AED inducing a more rapid recovery of all hematopoietic precursors from the small number of surviving stem cells.

Effects of 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) on interleukin-4-mediated mechanisms of immunity.

Because of similarities in the independent actions of the pleiotropic cytokine, interleukin-4 (IL-4), and the environmental contaminant, 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD), on murine B-lymphocytes suggested in earlier studies, we have investigated whether the immunosuppression mediated by direct exposure to TCDD in vitro is due to an IL-4-like biological activity. In particular, the ability of TCDD to mimic hallmark responses of B-cells to IL-4, such as upregulation of major histocompatibility complex (MHC) antigens of the class II type, increases in cell surface expression of the low affinity form of the Fc receptor for IgE (CD23) and induction of immunoglobulin class switching, was tested. At concentrations that readily suppress B-cell proliferative and antibody-forming cell responses, TCDD failed to demonstrate any of the activities of IL-4 observed in parallel cultures. Further, in experiments in which TCDD was preincubated with B-cells before addition of IL-4, no evidence of increased IL-4 activity was observed. Rather, TCDD preincubation resulted in decreased secretion of IgG1 and IgE in B-cell cultures stimulated to undergo immunoglobulin class switching by incubation with bacterial lipopolysaccharide (LPS) and IL-4. Because TCDD produced comparable suppression of IgM secretion induced by LPS alone (i.e., no IL-4), it appears that TCDD inhibits the formation of fully differentiated B-cells capable of secreting antibody and has no effects on class switching events per se. Coupled with previous reports from this and other laboratories, these observations indicate that TCDD is able to suppress secretion of several classes of immunoglobulin.