Human lung macrophage-derived histamine-releasing activity is due to IgE-dependent factors

Human lung macrophages obtained from surgical specimens spontaneously secreted a factor(s) (which we term macrophage factor) during 24-hr culture that induced calcium-dependent histamine release from human basophils and lung mast cells. Macrophage factor induced noncytotoxic histamine release from purified (85%) basophils. The kinetics of release were relatively slow and similar to that of anti-IgE. We performed a series of experiments to test the IgE dependence of macrophage factor-induced release. Preincubation of basophils with anti-IgE in calcium-free medium resulted in complete desensitization to macrophage factor-induced histamine release (i.e., when calcium and macrophage factor were added to the basophils, no histamine release occurred), and preincubation with macrophage factor in calcium-free medium resulted in partial desensitization to anti-IgE-induced histamine release. Pretreatment of basophils with pH 3.9 lactic acid buffer, which dissociates basophil IgE from its receptors, markedly reduced the capacity of basophils to release histamine in response to macrophage factor. Basophils that were incubated with IgE myeloma (but not with IgG) after lactic acid treatment partially or completely regained their capacity to release histamine in response to macrophage factor. Fluid-phase IgE myeloma (15 micrograms/ml) (but not IgG) inhibited basophil histamine release induced by two macrophage-derived supernatants, whereas IgE myeloma (200 micrograms/ml) did not inhibit release due to other supernatants. IgE-affinity columns removed the histamine-releasing activity of five macrophage-derived supernatants, and IgG-affinity columns had similar effects. However, neither affinity column removed the histamine-releasing activity of three other macrophage-derived supernatants. On Sephadex G-75 chromatography, nearly all of the histamine-releasing activity migrated as single peak with an apparent m.w. of 18,000. These results suggest that, although macrophage factor are heterogeneous, they are related, as they are a IgE-dependent factors that induce histamine release by interacting with cell surface IgE. These macrophage factors may be responsible for stimulation of basophil/mast cell mediator release in chronic allergic reactions.     

Studies of IgE-dependent histamine releasing factors: heterogeneity of IgE

Nasal lavage fluids from unstimulated individuals contain a histamine-releasing factor (HRF) similar to those which we have previously described from macrophages, platelets, and from blister fluids obtained during the late cutaneous reaction. The nasal HRF was partially purified by ion-exchange chromatography and gel filtration. Although some m.w. heterogeneity was observed, the majority of the HRF eluted at an apparent m.w. range of 15,000 to 30,000. This partially purified HRF induced histamine release from basophils of certain individuals. Histamine release occurred via a mechanism which is IgE-dependent in that: basophils desensitized by exposure to anti-IgE in the absence of calcium no longer respond to HRF, and desensitization with HRF reduces responsiveness to anti-IgE; and removal of IgE from the basophil surface by using lactic acid renders cells unresponsive to HRF. We have further defined this IgE dependence and have shown that the reason that only selected basophil donors respond to HRF is due to a previously unrecognized, functional heterogeneity of IgE. Thus, passive sensitization using sera from responders restored the responsiveness of acid-stripped basophils and conferred responsiveness to basophils of a nonresponder with naturally unoccupied IgE receptors. Sera from nonresponders failed to do this even though similar numbers of IgE molecules were put onto the basophil surface in each case. This property of responder sera was due to IgE because both heating sera at 56 degrees C for 2 hr and passage of sera over anti-IgE-Sepharose (which removes greater than 90% of the IgE) markedly reduced the ability of sera to induce responsiveness, and because an excess of either purified IgE myeloma or purified penicillin-specific IgE antibody from a nonresponder competitively inhibited the ability of IgE from responder sera to induce responsiveness to HRF. We conclude that nasal lavage fluids contain an HRF which induces basophil histamine release in a specific, IgE-dependent fashion but only from individuals with the appropriate type of IgE. Because we have shown that basophils are recruited into the nose during the late-phase reaction, we suggest that nasal HRF may induce these cells to release histamine and other mediators which could contribute to the symptomatology of the late-phase reaction.     

Neutrophils and mast cells. I. Human neutrophil-derived histamine-releasing activity

Histamine release occurs during the late phase allergic reaction concomitantly with neutrophil (PMN) infiltration. To determine whether PMN might release a factor capable of causing histamine release, supernatants generated by incubating human PMN in the presence or absence of specific activators were added to rat basophilic leukemia cells (RBL) and histamine release was measured. PMN supernatants from 17 of 21 donors induced noncytotoxic histamine release. Neutrophil-derived histamine-releasing activity, termed HRA-N, was dose-dependent and supernatants from greater than or equal to 10(7) PMN/ml caused 6 to 27% net histamine release from RBL. PMN supernatants induced histamine release as effectively as did intact PMN cocultured with RBL. The capacity of various donors to generate HRA-N was not related to atopic status or gender but was inversely related to the proportion of eosinophils (EOS) contaminating the PMN isolate (the larger the proportion of EOS, the lower the histamine release). Addition of EOS to PMN during the generation of HRA-N completely inhibited histamine-releasing activity. HRA-N was not released from mononuclear cells or platelets contaminating the PMN preparation. HRA-N release was not increased by the presence of either serum-treated zymosan or phorbol myristate acetate, agents that caused dose-related release of PMN granule enzymes. Indeed, HRA-N was released from unstimulated PMN in the complete absence of granule enzyme release. HRA-N release was detectable by 15 min and the majority of release occurred between 45 and 60 min of incubation. Thus, the data indicate that HRA-N is released spontaneously from human PMN and that HRA-N release is independent of primary or secondary PMN granule release. It is attractive to suggest that release of HRA-N by PMN might act to recruit mast cells or basophils into participating in acute inflammatory reactions.     

Human monocytes generate basophil histamine-releasing activities

Human peripheral blood monocytes generated activities during 24-h culture that were capable of triggering histamine release from 17 of 18 human basophil donors. Monocytes and their in vitro transformed macrophages continued to elaborate these basophil histamine-releasing activities for at least 3 wk in culture. In the 18 basophil donors tested, maximum histamine release induced by monocyte supernatants was 33.8 +/- 5.9% (mean +/- SEM) of total basophil histamine content; optimum anti-IgE-induced release was 38.8 +/- 6.2%. Basophil histamine release in response to monocyte activities was optimal at 37 degrees C and at calcium concentrations of 2 to 5 mM. Release was greater than 90% complete 1 min after challenge and was inhibited by anti-allergic drugs. The mechanism of release appeared to be independent of IgE binding. Gel filtration of supernatants derived from both day 1 (monocyte stage) and day 14 (macrophage stage) cultures demonstrated activity peaks with approximate m.w. of 12,000 and 30,000. In contrast to the marked responsiveness of basophils, only 2 of 10 human lung mast cell preparations responded; release in those preparations was low: 3% and 13% histamine release, respectively. Thus, monocytes produce potent histamine-releasing activities with differential actions on basophils and mast cells.     

IL-8 inhibits histamine release from human basophils induced by histamine-releasing factors, connective tissue activating peptide III, and IL-3.

We have previously purified and partially characterized histamine releasing factors (HRF), which were derived from a mixture of human mononuclear cells and platelets. We now report the effect of IL-8 upon HRF-, connective tissue activating peptide III (CTAP III)-, and IL-3-induced histamine release from human basophils. We determined that IL-8 itself, at concentrations between 10(-7) to 10(-11) M, does not release histamine from basophils, although positive results are observed in two of 26 subjects at 10(-7) M. Unfractionated (crude) HRF released histamine in 25 of 26 donors, in the range of 6.7% to 100% of total basophil histamine stores. When basophils were preincubated with IL-8 (10(-7) to 10(-11) M) for 5 min, followed by a 40-min incubation with HRF, histamine release was significantly inhibited in 20 of 25 donors. Inhibition was observed at as little as 10(-11) M IL-8, with maximal inhibition being attained at 10(-9) M. HRF-containing supernatants contain a mixture of different histamine-releasing moieties. To better define which factor(s) may be inhibited by IL-8, fractionated supernatants, purified CTAP III, and IL-3 were studied. Histamine release produced by two different HRF-containing chromatographic fractions (HRFvoid and HRFpeak 2) and purified CTAP-III (5 micrograms/ml) was inhibited by IL-8 in 10 of 12 donors, three of three donors, and seven of 10 donors, respectively. IL-3 (5000 U/ml)-dependent histamine release was inhibited by IL-8 in all subjects tested. In contrast, histamine release by anti-IgE and FMLP was not affected by IL-8. Thus, IL-8 appears to be an inhibitor of cytokine-like molecules that induce histamine release and may represent the previously described 8-kDa histamine release inhibitory factor present in mononuclear cell supernatants.     

Comparative effect of recombinant IL-1, -2, -3, -4, and -6, IFN-gamma, granulocyte-macrophage-colony-stimulating factor, tumor necrosis factor-alpha, and histamine-releasing factors on the secretion of histamine from basophils

Most cytokines possess multiple biologic activities. This study was undertaken to investigate the effect of rIL-1 beta, -2, -3, -4 and -6, IFN-gamma, TNF-alpha, and granulocyte-macrophage (GM)-CSF on basophils from 16 donors and the amount of histamine released was compared with that by partially purified mononuclear cell-derived histamine-releasing factor (HRF) and anti-IgE. We found that only IL-3 and GM-CSF at relatively high doses (50 to 500 ng/ml) released small amounts of histamine (3 to 14%) from two allergic donors. In contrast, both HRF and anti-IgE released significant amounts of histamine from all donors. Other cytokines did not release any measurable quantity of histamine. Simultaneous addition of several cytokines to the basophils also failed to release histamine. IL-3, GM-CSF, and IL-1 can also release histamine at lower concentrations (less than 5 ng/ml) when incubated with basophils in the presence of D2O. Basophils from 6 out of 13 allergic donors released histamine in response to IL-3, whereas three donors responded to IL-1 beta and two responded to GM-CSF. The results of this study demonstrated that although IL-3 and GM-CSF release small amounts of histamine only from a select group of allergic patients, mononuclear cell-derived HRF is more potent in their action and release histamine from normals as well as allergic patients.     

A histamine-releasing factor from activated human mononuclear cells

Human mononuclear cells activated by streptokinase-streptodornase have been shown to elaborate a factor capable of releasing histamine from human basophils. We have developed reproducible methods for its production in large quantities by using cells obtained from leukapheresis packs, by detection utilizing donor basophils known to release well with anti IgE, and by quantitation of histamine by the radioenzyme method. Human histamine-releasing factor (HRF) gave a single peak upon gel filtration with an estimated m.w. of 32,000; SDS gel electrophoresis revealed a single major band as seen at m.w. 30,000. HRF can be resolved into at least two forms separable by ion-exchange chromatography on QAE Sephadex, and two peaks of activity were obtained by chromatofocusing or isoelectric focusing in gels at pH 6.9 and between 7.4 and 8.3. This factor represents an important potential link between cellular immunity and immediate hypersensitivity.     

Production and properties of histamine-releasing factor of guinea pigs

The production of histamine-releasing factor (HRF) by human mononuclear cells has previously been reported. In this paper we describe the production of HRF by guinea pig spleen cells, thymocytes, and PBMC. Guinea pig lymphoid cells were cultured either alone or in the presence of mitogens (PHA and Con A) or specific Ag(OVA and keyhole limpet hemocyanin) and the dialyzed cell-free supernatant was tested for histamine-releasing activity on guinea pig lung mast cells and blood basophils. Lung mast cells were isolated by enzymatic digestion and partially purified by countercurrent elutriation and discontinuous Percoll gradient centrifugation. Guinea pig spleen cells, thymocytes, and PBMC spontaneously produced significant amounts of HRF. The production was enhanced upon stimulation with PHA or specific Ag in animals immunized with Ag in CFA. Two distinct species of HRF were identified with m.w. of 50,000 to 70,000 and 5000 to 8000 by gel chromatography. HRF is a trypsin- and chymotrypsin-sensitive heat-stable protein. It does not bind to Con A-Sepharose and its production is not inhibited by tunicamycin. HRF-induced histamine release from lung mast cells is a temperature-dependent process and is complete in 10 min at 37 degrees C. Intradermal injection of HRF caused an immediate ear-swelling reaction in guinea pigs. The most severe ear-swelling reactions did not resolve within 1 h, but instead evolved over a period of 12 to 24 h.     

IgE-dependent regulation of human basophil adherence to vascular endothelium

Mechanisms favoring the recruitment of circulating human basophils to extravascular sites of allergic inflammation are unknown. The basophil secretagogues anti-IgE, and pollen allergens rye grass I and ragweed Ag E (Lol p I and Amb a I) were tested for their ability to promote basophil adherence to umbilical vein endothelial cells. Co-incubation of endothelial cells and basophils with anti-IgE resulted in time and dose-dependent increases in basophil adhesion. These effects were due to activation of the basophil, required both magnesium and calcium, occurred before or in the absence of histamine release, and were seen at concentrations of stimulus below the usual range of secretagogue activity. In contrast, anti-IgE or Ag stimulation of neutrophils, or basophils from donors non-responsive to anti-IgE or Ag with respect to histamine release, had no effect on cell adherence. mAb 60.3, recognizing the CD18 leukocyte adhesion molecule, inhibited anti-IgE-induced enhancement of basophil-endothelial cell binding. Exposure of basophils to low concentrations of Ag in vivo may selectively initiate basophil infiltration into tissue sites of allergic inflammation by enhancing their adherence to endothelium.     

Protein L. A bacterial Ig-binding protein that activates human basophils and mast cells.

Peptostreptococcus magnus strain 312 (10(6) to 10(8)/ml), which synthesizes a protein capable of binding to kappa L chains of human Ig (protein L), stimulated the release of histamine from human basophils in vitro. P. magnus strain 644, which does not synthesize protein L, did not induce histamine secretion. Soluble protein L (3 x 10(-2) to 3 micrograms/ml) induced histamine release from human basophils. The characteristics of the release reaction were similar to those of rabbit IgG anti-Fc fragment of human IgE (anti-IgE): it was Ca2(+)- and temperature-dependent, optimal release occurring at 37 degrees C in the presence of 1.0 mM extracellular Ca2+. There was an excellent correlation (r = 0.82; p less than 0.001) between the maximal percent histamine release induced by protein L and that induced by anti-IgE, as well as between protein L and protein A from Staphylococcus aureus (r = 0.52; p less than 0.01). Preincubation of basophils with either protein L or anti-IgE resulted in complete cross-desensitization to a subsequent challenge with the heterologous stimulus. IgE purified from myeloma patients PS and PP (lambda-chains) blocked anti-IgE-induced histamine release but failed to block the histamine releasing activity of protein L. In contrast, IgE purified from myeloma patient ADZ (kappa-chains) blocked both anti-IgE- and protein L-induced releases, whereas human polyclonal IgG selectively blocked protein L-induced secretion. Protein L acted as a complete secretagogue, i.e., it activated basophils to release sulfidopeptide leukotriene C4 as well as histamine. Protein L (10(-1) to 3 micrograms/ml) also induced the release of preformed (histamine) and de novo synthesized mediators (leukotriene C4 and/or PGD2) from mast cells isolated from lung parenchyma and skin tissues. Intradermal injections of protein L (0.01 to 10 micrograms/ml) in nonallergic subjects caused a dose-dependent wheal-and-flare reaction. Protein L activates human basophils and mast cells in vitro and in vivo presumably by interacting with kappa L chains of the IgE isotype.     

Measurement of IgE on human basophils: relation to serum IgE and anti-IgE-induced histamine release.

The number of IgE molecules bound to human basophils was calculated from direct measurements of the IgE dissociated after exposing leukocytes to pH 3.7 acetate buffer in the cold. In 18 donors studied, cell-bound IgE ranged from 4000 to 500,000 molecules/basophil and correlated with the serum IgE concentration (r = 0.89, p less than 0.001) which ranged from 5 to 3,000 ng/ml. Sensitivity of these cells to anti-IgE was tested to explore the relationship between cell-bound IgE and the concentration of anti-IgE required for histamine release. Cells from some nonatopic donors (4000 to 100,000 IgE molecules/basophil) were as sensitive as cells from allergic donors (100,00 to 500,000 IgE molecules/basophil). Moreover, cells from donors having approximately the same cell-bound IgE concentration varied widely in their sensitivity to anti-IgE. We conclude that an intrinsic property of human basophils ("releasability") is an important parameter in determing mediator release.     

Recombinant IL-3 induces histamine release from human basophils

Human rIL-3 induces histamine release from some human basophils, with cells from atopics responding to a greater extent than non-atopic donors. The dose response curves were highly variable. IL-3 was active on purified basophils and the release process was slower and required more calcium than anti-IgE. Removal of surface IgE from basophils rendered them unresponsive to IL-3. The response could be restored by passive sensitization of basophils with IgE+, IgE known to bind histamine-releasing factors, and not IgE-, IgE unreactive with histamine-releasing factors. Thus, IL-3 uncovers IgE heterogeneity. IL-3 does not, however, directly interact with IgE+. Rather, passive sensitization with IgE+ or stimulation of basophils with low concentrations of several secretagogues renders the cells sensitive to IL-3. IL-3 may well play a pro-inflammatory role by potentiating the effects of IgE+ or various secretagogues.     

Human basophil releasability. III. Genetic control of human basophil releasability

Basophil releasability implies that, in addition to the surface density of IgE molecules, biochemical events determine the capacity to release chemical mediators in response to activating stimuli. We studied the IgE (anti-IgE)-mediated and non-IgE-mediated (f-met peptide and the Ca2+ ionophore A23187) releasability of human basophils obtained from 14 monozygotic (MZ) (ages 25.7 +/- 13.3 yr; mean +/- SDM) and 13 dizygotic (DZ) twin pairs (ages 20.4 +/- 9.9 yr). A significant intrapair correlation coefficient of the maximal percent of anti-IgE-induced histamine release was found in the MZ, whereas no significant correlation was found in the DZ. The mean intrapair variance of anti-IgE-induced histamine release in MZ (VMZ) and in DZ (VDZ) gave an F value equal to 3.84 (p less than 0.01) and a heritability (H) index of 0.74. Similar findings were obtained with respect to the sensitivity to a standard concentration (10(-1) micrograms/ml) of anti-IgE. No correlation between serum IgE level and anti-IgE-induced histamine release was found in either MZ or DZ. A significant intrapair correlation coefficient of f-met peptide-induced histamine release was found in both the MZ and the DZ. The difference between MZ and DZ was not significant. The VMZ and the VDZ of the f-met peptide-induced histamine release gave an F value of 1.52 (NS) and an H value of 0.34. The intrapair correlation coefficient of A23187-induced release was significant in MZ and not significant in DZ. The mean intrapair variance of A23187-induced histamine release gave an F value of 2.33 (NS) and an H index of 0.57. Similar findings were obtained by using suboptimal (3 X 10(-1) micrograms/ml) concentrations of A23187. There was no correlation between the sensitivity of basophils to release in response to anti-IgE and their response to f-met peptide or A23187, in either the MZ or the DZ. We conclude that the ability of basophils to respond to anti-IgE and A23187 is influenced by genetic factors.     

Immunoglobulin superantigen protein L induces IL-4 and IL-13 secretion from human Fc epsilon RI+ cells through interaction with the kappa light chains of IgE

Peptostreptococcus magnus protein L is a multidomain bacterial surface protein that correlates with virulence. It consists of up to five homologous Ig-binding domains (B1-B5) that interact with the variable domain of Ig kappa L chains. Intact protein L stimulates the synthesis and the release of IL-4 and IL-13 from human basophils in vitro. A protein L fragment covering the Ig-binding domains B1-B4 also induced IL-4 and IL-13 release from basophils. There was an excellent correlation (r(s) = 0.82; p < 0.001) between the maximal percent IL-4 release induced by protein L and that induced by anti-IgE and between intact protein L and the B1-B4 fragment (r(s) = 0.90; p < 0.01). Removal of IgE bound to basophils markedly reduced the IL-4 release induced by anti-IgE, protein L, and B1-B4. Preincubation of basophils with protein L or anti-IgE caused complete cross-desensitization to subsequent challenge with the heterologous stimulus. IgE purified from myeloma patients PS and PP (lambda chains) blocked anti-IgE-induced IL-4 release, but not the releasing activity of protein L. In contrast, IgE purified from myeloma patient ADZ (kappa chains) blocked both anti-IgE- and protein L-induced secretion. Cyclosporin A, but not cyclosporin H, inhibited protein L-induced release of IL-4 and IL-13 from basophils. Thus, protein L acts as a bacterial Ig superantigen to induce the synthesis and release of IL-4 and IL-13 from basophils by interacting with kappa L chains of the IgE isotype.     

Identification of histamine releasing factor(s) in the late phase of cutaneous IgE-mediated reactions

We have shown that fluids collected from antigen-challenged skin blisters during the late phase reaction cause the release of substantial amounts of histamine (means = 42%, n = 14) from human basophils in vitro. Control fluids collected either during the immediate phase or from an unchallenged blister released less than or equal to 10% histamine from both basophils and lung mast cells. Late phase blister fluids induced low levels of histamine release from human lung cells (means = 11%, n = 4) that were slightly but not significantly greater than levels induced by control blister fluids. The characteristics of basophil release were similar to IgE-mediated stimuli in dose dependence, calcium and temperature requirements, and kinetics. The IgE dependence of the late phase blister fluid was demonstrated by desensitization of the basophils to anti-IgE, which obviated the response to anti-IgE and blister fluid but did not affect a non-IgE-mediated stimulus. Removal of the cell surface IgE with lactic acid also abolished the response to both anti-IgE and late phase blister fluid. Incubation of the "stripped" cells with serum containing IgE myeloma restored the response to anti-IgE but failed to affect response to late phase blister fluid. The characteristics of release obtained with this factor closely resemble those of an IgE-dependent histamine releasing factor from cultured macrophages previously described by our group.     

Cellular origin of histamine-releasing factor produced by peripheral blood mononuclear cells

Histamine releasing factors (HRF) are a group of cytokines that release histamine and other mediators from mast cells and basophils. It has been speculated that HRF might play a major role in the pathogenesis of allergic diseases. Most investigators have studied PBMC as a source of HRF. This study was undertaken to investigate the cellular origin of HRF. Peripheral blood was processed to isolate and purify monocytes, T cells, CD4- T cells, CD8- T cells and B cells by using plastic adherence, 2-aminoethylisothiomonium-treated SRBC rosetting and negative selection with the use of mAb OKM1, OKT11, OKT8, OKT4, and OKB7 plus C. Highly purified subpopulations of PBMC were cultured alone or in the presence of Con A for 24 h. Supernatants were harvested, dialyzed, and assayed for HRF activity in the basophil histamine release test. We found that all subpopulations of PBMC including T cells, CD4- T cells, CD8- T cells, B cells, and monocytes produce variable quantities of HRF. The spontaneous production is very high in B cells but only barely measurable in T cells and monocytes. The synthesis of HRF by B cells was confirmed by abolishing the release of the activity after treatment of B cells with OKB7 mAb and C. Stimulation of cell populations by Con A significantly enhances HRF production by PBMC and T cells but not by B cells and monocytes. In mixing experiments, unstimulated monocytes + B cells showed synergism, but other combinations demonstrated an additive effect. This is the first demonstration of HRF production by human peripheral blood B cells. The results of this study also suggest that histamine releasing cytokines are of multiple cellular origin. This perhaps contributes to their molecular heterogeneity.     

Characteristics of human basophil sulfidopeptide leukotriene release: releasability defined as the ability of the basophil to respond to dimeric cross-links

Human basophils release approximately 90 pmol of LTC4/micrograms histamine when challenged with anti-IgE antibody, but donor to donor variation produces a 1000-fold range of response. There is little conversion to LTC4 to LTE4 in purified preparations of basophils, but conversion to LTE4 does occur if cell densities are high during incubation. Like histamine release, leukotriene release is calcium and temperature dependent and is complete in 20 min, with a t1/2 of approximately 8 min. The process of desensitization also ablates leukotriene release, but there is a distinct two phase process where leukotriene release is enhanced after 5 min of desensitization, whereas histamine release is inhibited and total ablation of leukotriene release occurs only after 45 min of desensitization. Human basophils respond well to stimulation with covalently cross-linked trimeric IgE myeloma but respond poorly to dimeric IgE. This differential sensitivity to the two forms of cross-linked IgE is most exaggerated in the context of leukotriene release, where dimer is 30-fold less efficacious and 100- to 1000-fold less potent than trimer on some donors' basophils. This dichotomy of response is also observed in antigen-challenged cells, where the bivalent hapten, BPO2, also poorly induces leukotriene release in accord with the fact that it predominantly induces dimeric cross-links of penicillin-specific IgE. Anti-IgE dose-response curves reveal a region of dimeric cross-link dominance that may explain the peculiar differences observed in pharmacologic studies of basophil release induced with antigen vs anti-IgE. In addition, there is a continuum of "releasability," where some donors' basophils display no response (histamine or leukotriene release) to dimeric IgE, and others' basophils are essentially equally responsive to both dimeric and trimeric IgE. This releasability difference manifests itself by conferring increased sensitivity to antigenic challenge in those donors' basophils capable of responding to dimeric cross-links such that these donors' basophils are capable of releasing histamine upon antigen challenge while possessing only 50 molecules of cell surface antigen-specific IgE; other dimer-insensitive donors' basophils require 6 to 10-fold greater IgE densities for equal histamine release.     

Stimulation of human bronchial epithelial cells by IgE-dependent histamine-releasing factor

An IgE-dependent histamine-releasing factor (HRF p23; also known as translationally controlled tumor protein or p23) stimulates the release of histamine, IL-4, and IL-13 from a subpopulation of highly allergic donor basophils. It has also been shown to act as a chemoattractant for eosinophils. To elucidate novel functions of HRF p23 in airway inflammation, we examined the effects of human recombinant HRF p23 (hrHRF) on bronchial epithelium and found that hrHRF stimulated the secretions of IL-8 and granulocyte/macrophage colony-stimulating factor by both primary cultures of human bronchial epithelial cells and BEAS-2B cells. In response to hrHRF, these cells induced IL-8 mRNA expression within 4 h. H2O2, but not IL-1 beta or tumor necrosis factor-alpha, stimulated secretion of HRF p23 by BEAS-2B cells, suggesting that oxidative stress may trigger the release of HRF p23 from bronchial epithelial cells. Bronchoalveolar lavage (BAL) from healthy volunteers contained only trivial or undetectable amounts of HRF p23. Significantly higher amounts of HRF p23 were recovered from BAL fluid taken from asthmatic patients, and the amounts of HRF p23 were further elevated in patients with idiopathic eosinophilic pneumonia. Our results demonstrate for the first time that HRF p23 can stimulate nonimmune epithelium. HRF p23 derived from bronchial epithelial cells may regulate complex cytokine networks in eosinophil-dependent inflammation of the human airway.     

Anti-human IgG causes basophil histamine release by acting on IgG-IgE complexes bound to IgE receptors.

We have reexamined the ability of anti-human IgG antibodies to induce histamine release from human basophils. A panel of purified murine mAbs with International Union of Immunological Societies-documented specificity for each of the four subclasses of human IgG was used. Of the 24 allergic subjects studied, the basophils of 75% (18/24) released greater than 10% histamine to one or more anti-IgG1-4 mAb, whereas none of the 13 nonatopic donor's basophils released histamine after stimulation with optimal amounts of anti-IgG mAb. The basophils of 85% (11/13) of the nonatopic donors did respond to anti-IgE challenge, as did 92% (22/24) of the atopic donor cells. Histamine release was induced most frequently by anti-IgG3, and 10/18 anti-IgG responder cells released histamine with mAb specific for two or more different subclass specificities. The rank order for induction of histamine release was anti-IgG3 greater than anti-IgG2 greater than IgG1 greater than anti-IgG4. As in our previous study using polyclonal anti-IgG, 100- to 300-micrograms/ml quantities of the anti-IgG mAb were required for maximal histamine release, about 1000-fold higher than those for comparable release with anti-human IgE. Specificity studies using both immunoassays and inhibition studies with IgE myeloma protein indicated that anti-IgG induced histamine release was not caused by cross-reactivity with IgE. Ig receptors were opened by lactic acid treatment so that the cells could be passively sensitized. Neither IgE myeloma nor IgG myeloma (up to 15 mg/ml) proteins could restore the response to anti-IgG mAb. However, sera from individuals with leukocytes that released histamine upon challenge with anti-IgG mAb could passively sensitize acid-treated leukocytes from both anti-IgG responder and nonresponder donors for an anti-IgG response. The only anti-IgG mAb that induced release from these passively sensitized cells were those to which the serum donor was responsive. Sera from non-IgG responders could not restore an anti-IgG response. These data led to the hypothesis that the IgG specific mAb were binding to IgG-IgE complexes that were attached to the basophil through IgE bound to the IgE receptor. This was shown to be correct because passive sensitization to anti-IgG could be blocked by previous exposure of the basophils to IgE. We conclude that anti-IgG-induced release occurs as a result of binding to IgG anti-IgE antibodies and cross-linking of the IgE receptors on basophils.