IgG1 antibody-dependent mediator release after passive systemic sensitization of basophils arriving at cutaneous basophil hypersensitivity reactions

When antigen is injected into a 24-hr cutaneous basophil hypersensitivity (CBH) reaction of an actively sensitized guinea pig, local basophils degranulate and release histamine. This reaction is called cutaneous basophil anaphylaxis and may be antibody mediated. We now report passive sensitization of basophils at CBH sites by systemic transfer of anti-picryl immune serum. Keyhole limpet hemocyanin- (KLH) immunized animals were skin tested with KLH to elicit 24-hr CBH reactions at day 7. Anti-picryl serum was injected i.v. at various times. On day 7, blue dye was injected i.v., and then 24-hr CBH sites vs nearby normal skin were challenged with 0.1 microgram picryl-human serum albumin (Pic-HSA). An immediate increase in vascular permeability (blueing) was noted at normal skin sites due to systemic passive cutaneous anaphylaxis (PCA), and augmented blueing occurred at CBH sites compared with normal skin. Systemic passive sensitization of CBH sites occurred when antiserum was administered as little as 1 hr before challenge of CBH site. However, local administration of anti-picryl serum (as in a local PCA reaction) was not able to sensitize tissue basophils, whether antigen was administered locally or systemically. The serum factor that mediated cutaneous basophil anaphylaxis was heat-stable (56 degrees C X 4 hr) 7S IgG1 antibody. Electron microscopy of Pic-HSA-challenged CBH sites in animals that received IgG1 antibody showed that local basophils undergo anaphylactic degranulation by exocytosis. These studies suggest that basophils arriving at CBH reactions are sensitized for anaphylactic function by antibody that can be acquired in the circulation, but possibly not at the local site.     

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.     

Histamine release due to bivalent penicilloyl haptens: control by the basophil plasma membrane.

We describe the characteristics of in vitro histamine release from human basophils passively sensitized with serum from a penicillin-allergic individual. The histamine release is induced by a synthetic bivalent hapten, bis benzylpenicilloyl 1,6 diaminohexane (BPO)2. We present data on the effect of a monovalent hapten, benzylpenicilloyl formyl-L-lysine (BPO)1, on the histamine release. We also examine how histamine release depends on the concentration of serum used for passive sensitization, the source of cells used for passive sensitization, and the time allowed for histamine release. We interpret these experiments in terms of a theory of equilibrium binding of bivalent haptens to cell surface antibody that is presented in the previous paper. The results are consistent with the idea that the amount of histamine release is controlled by the number of cross-linked IgE molecules on the cell surface. In particular, the histamine dose-response curve rises because cross-links rise, has a maximum because the cross-links are a maximum, and falls because the cross-links fall.     

A newly described activity of guinea pig IgG1 antibodies: transfer of cutaneous basophil reactions.

Hapten-specific delayed time course skin reactions containing predominant accumulations of basophils and eosinophils were elicited in newborn guinea pigs after i.v. transfer of small amounts of oxazolone immune serum. The immune serum was fractionated by column chromatography procedures, and the fractions were examined for their ability in transferring this form of cutaneous basophil hypersensitivity (CBH). Only the 7S IgG-containing peak from Sephadex G-200 columns, and only the IgG1-containing fractions from DEAE columns, transferred CBH. An affinity column of bound oxazolone removed the activity from immune serum, and it could be recovered from the column by eluting with soluble oxazolone. About 35 microgram of purified IgG1 anti-oxazolone antibody could systemically transfer CBH reactivity. An immunoadsorbant column of anti-IgG1 removed this activity, but a column of anti-IgG2 did not. None of the procedures were able to separate activity in transferring CBH from passive cutaneous anaphylactic (PCA) activity classically associated with guinea pig IgG1 antibody. IgG1 from 8-day immune and 31-day hyperimmune donors were both effective. The average association constant of 8-day antibody was 8 X 10(-4) M-1. Transfer of cutaneous basophil reactions can be mediated by low affinity serum 7S IgG1 antibody.     

IgE antibody-mediated cutaneous basophil hypersensitivity reactions in guinea pigs

Cutaneous basophil hypersensitivity (CBH) reactions are a heterogeneous group of delayed time course basophil-rich immune responses that can be mediated in the guinea pig by T cells, B cells, or IgG1 antibody. This study examined whether guinea pig IgE antibody could also mediate CBH reactions. IgE antibody to picryl or oxazolone determinants was induced by immunizing Hartley strain guinea pigs pretreated with cyclophosphamide. Hyperimmune serum from these animals was passed through a heavy chain-specific anti-IgG1 affinity column. The presence of IgE anti-hapten antibody in the filtrate fraction was verified by passive cutaneous anaphylaxis (PCA) testing with a 7-day period of local passive sensitization and by the heat lability (56 degrees C, 4 hr) of PCA activity. This IgE-rich fraction and the IgG1 fraction eluted from the column with base (0.2 M Na2CO3, pH 11.3) were transferred i.v. to separate groups of normal guinea pigs. Both fractions mediated delayed time course reactions that contained basophils. Macroscopic and microscopic reactions mediated by the IgE-rich fraction were abolished with heat (56 degrees C, 4 hr). Thus, two antigen-specific factors in guinea pig serum can mediate delayed time course basophil-containing reactions: IgG1 and IgE antibodies. IgE-mediated CBH reactions are similar to the late-phase reaction that follows IgE-dependent wheal-and-flare reactions in humans. The finding that guinea pig IgE can mediate a late reaction that contains basophils makes this a possible model for the human late-phase response, and suggests that some forms of CBH may play a role in human allergic disease.     

Rejection of ticks from guinea pigs by anti-hapten-antibody-mediated degranulation of basophils at cutaneous basophil hypersensitivity sites: role of mediators other than histamine

Previous studies have established that recruitment of basophils to sites of tick feeding in guinea pigs is required to effect immune resistance. In the current study, actively sensitized guinea pigs treated three times daily with H-1 (mepyramine) and H-2 (cimetidine) histamine receptor antagonists, during the challenge tick infestation period, expressed normal resistance to Amblyomma americanum larvae. Similarly, naive guinea pigs treated with anti-histamines four times daily, beginning 7 days before transfer of immune serum and tick challenge and continuing through the tick infestation period, also expressed normal antibody-mediated resistance to A. americanum. These results indicated that histamine was not an important basophil mediator of the resistance response. Ticks allowed to feed on tissue rich in basophils that were induced by sensitization and subsequent local challenge with non-tick protein antigen, keyhole limpet hemocyanin (KLH), expressed normal yield. Ticks that fed on similar tissue rich in basophils induced by sensitization and challenge with KLH, in which the basophils expressed anti-picryl specificity due to systemic passive transfer of anti-picryl antibodies, were rejected when basophils were induced to degranulate by i.v. challenge with picryl antigen at 6 hr (29% rejection), 12 hr (18% rejection), 24 hr (22% rejection), and 48 hr (37% rejection) post-tick attachment. However, basophil degranulation at 18, 72 and 96 hr post-tick attachment had no adverse effect on tick feeding. These hosts were protected from systemic anaphylaxis by treatment with the anti-histamine mepyramine. Release of histamine occurred at tick feeding sites, but vasoactive effects were blocked by mepyramine treatment as evidenced by a lack of increased vascular permeability (bluing) at these sites compared with non-tick-infested tissues, or to cutaneous basophil hypersensitivity (CBH) sites of animals not protected with mepyramine. These results indicate that local recruitment and subsequent degranulation of basophils via immune mechanisms dependent on non-tick antigens can lead to tick rejection, and that basophil-derived mediators other than histamine are involved in this immune resistance response to A. americanum ticks. The identity of the crucial basophil mediator(s) is not known. The significant susceptibility of ticks to basophil-mediator release at 6 to 12 hr and 24 to 48 hr post-attachment coincides with the tick attaching and fast-feeding phases, respectively, suggesting that these phases of tick parasitism are particularly susceptible to the effect of basophil mediators other than histamine.     

Cutaneous basophil hypersensitivity uncovered in the cell transfer of classical tuberculin hypersensitivity.

Cellular transfer of cutaneous basophil hypersensitivity (CBH) was studied. Guinea pigs immunized for CBH with incomplete Freund's adjuvant (IFA) provided cells which could transfer delayed and basophil-rich reactions in skin tests of recipients. Guinea pigs immunized with complete classical tuberculin-type delayed hypersensitivity reactions (DH), which are characteristically devoid of basophils. However, recipients of cells from donors with DH, surprisingly, were found to have delayed skin reactions containing large basophil infiltrates which were lacking in the donors. Thus, recipients of classical cell transfers of tuberculin-type DH had delayed reactions which resembled CBH. Control experiments verified that the cell transfer of CBH from donors with DH was due to passive transfer with live cells and not transfer of contaminating humoral factors or active sensitization of recipients. It was concluded that cutaneous basophil responses were suppressed in CFA-immunized donors and expressed in cell transfer recipients. Cells from donors immunized with CFA were enriched for nonadherent and nonimmunoglobulin-bearing lymphocytes by passage through nylon wool columns, and these cells transferred conjugate specific CBH reactions. It was concluded that cells mediating these transfers were probably T cells. The finding of basophils in cell transfers of DH and a variety of other findings suggesting complex regulation of basophil numbers in tissue lead to the conclusion that the term CBH be used to simply describe a basophil-containing skin reaction.     

Involvement of host Fc receptors in antibody-mediated cutaneous basophil hypersensitivity reactions.

Cutaneous basophil hypersensitivity (CBH) reactions are heterogeneous delayed time course basophil-rich responses that can be mediated by either T cells, B cells, or serum antibodies. The current study examined the mechanism by which antibodies mediate CBH in guinea pigs. Fc competition experiments were constructed by passively transferring mixtures of anti-KLH serum and normal heterologous gamma-globulins. It was found that rabbit IgG and its isolated and purified Fc fragment [but not the (Fab')2 fragment] inhibited the ability of guinea pig immune serum to transfer CBH. Concurrent inhibition of transferred KLH-specific CBH and systemic passive cutaneous anaphylaxis (PCA) reactions by rabbit IgG or its Fc fragment, and not by sheep or bovine gamma-globulins, indicated that Fc receptors on cutaneous mast cells were probably involved in both CBH and PCA. It was also found that the basophil aspect of delayed cutaneous responses elicited by PHA was inhibited by Fc competition maneuvers. This could mean that some forms of apparently T cell-mediated CBH may be T cell dependent, but via secretion of molecules that bind to Fc receptors, as seems required in antibody-mediated CBH.     

The inhibition of cutaneous basophil hypersensitivity reactions by a heterologous anti-guinea pig T cell serum.

Systemic treatment with a heterologous anti-T cell serum of guinea pigs immunized with EA in IFA markedly suppressed CBH reactivity to specific antigen and T cell mitogens, as judged by gross reactivity, histology, and skin histamine. The antiserum produced a marked drop in circulating lymphocytes, mainly at the expense of T cells, as indicated by the ability of surviving lymphocytes to rosette with rabbit RBC. It was postulated that the suppression of CBH reactivity is due to the depletion of T cells, which would have released a factor chemotactic for basophils. The data therefore provide further evidence that cutaneous reactions rich in basophils are primarily dependent on a population of T cells.     

Naturally abundant basophils in the snapping turtle, Chelydra serpentina, possess cytophilic surface antibody with reaginic function

Basophils constitute 50 to 63% of the blood leukocytes in Chelydra serpentina, the snapping turtle. Immunoglobulin (Ig) on the surface of the turtle basophil was detected by indirect immunofluorescence by using an IgG fraction from rabbit anti-turtle Ig serum (RATIg) and a fluoresceinated goat anti-rabbit antibody incubated at 4 degrees C. However, when the cells were incubated with RATIg at 22 degrees C, the basophil number, as determined by Wright's stain and neutral red counts, decreased dramatically. This morphologic evidence of degranulation was directly proportional to the antiserum concentration. Degranulation also correlated with cell histamine release (r = 0.73). In other experiments, turtle basophils were found to express antigen-specific surface Ig after immunization with sheep red blood cells (SRBC). Washed basophils from immunized turtles formed basophil-SRBC rosettes in vitro. Basophils from control turtles did not. Basophil-SRBC rosettes could also be induced by in vitro passive sensitization by preincubation of normal turtle basophils in the SRBC immune turtle sera. This study shows clearly that the turtle basophil has an immune capacity analogous to the mammalian basophil/mast cell. This study also contains the first direct evidence for the existence of reaginic antibody (or antibodies) in an ectothermic vertebrate. Finally, C. serpentina is proposed as a unique animal model for the study of basophil function.     

IgE-mediated release of histamine from human cutaneous mast cells

We investigated the ability of antigen-IgE interactions to stimulate histamine release from human infant cutaneous mast cells. Skin obtained at circumcision contained numerous perivascular mast cells, as assessed by light and electron microscopy. The histamine content of this tissue averaged 17.7 ng (+/- 1.5 SEM)/mg wet weight. Challenge of 200-microns thick sections of unsensitized skin with varying concentrations of monoclonal murine antibodies to human IgE caused no net release of histamine. After skin sections were incubated in the presence of 5 micrograms/ml of human myeloma IgE (S) for 120 min at 37 degrees C, monoclonal anti-IgE challenge resulted in 40.1% (+/- 6.0 SEM) histamine release. Similar passive sensitization with 1/20 dilutions of serum from humans expressing IgE to purified Juniperus sabinoides (JS) antigen rendered the tissue responsive to specific antigen challenge. Dose-related histamine release occurred over 30 min with optimal release of 12.6% (+/- 2.4 SEM) after stimulation with 100 ng/ml of JS antigen. This reaction required sensitization with serum containing IgE to JS and was antigen-specific. Optimal reactions to antigen occurred at 3 mM added Ca++, 34 degrees C to 37 degrees C, pH 7.2. Antigen-induced release was markedly influenced by the added Ca++ concentration; no release occurred in the absence of Ca++, 54% of the optimal response was observed at 2 mM Ca++, and 28% of the optimal response occurred at 4 mM Ca++. The addition of Mg++ did not influence antigen-induced release. The results of this study provide functional evidence that 1) human infant cutaneous mast cells express Fc-epsilon receptors; 2) these receptors are largely unoccupied in vivo; and 3) stimulation of passively sensitized infant mast cells with anti-IgE or specific antigen leads to immediate histamine release. This new system should permit detailed in vitro studies of immediate hypersensitivity reactions in human skin.     

Biologic significance of disulfide bonds in human IgE molecules.

E myeloma protein, PS, was reduced in different concentrations of dithiothreitol (DTT) for 1 hr followed by alkylation with 14C-iodoacetamide. The affinity of the reduced-alkylated molecules for target cells was evaluated by their ability 1) to sensitize primate skin in a reversed P-K reaction, 2) to sensitize human basophils in a reversed-type histamine release and 3) to block passive sensitization with reaginic antibody. Antibody-epsilon0 antibody was employed for reversed type reactions to avoid participation of cell-bound normal IgE in the reactions. The sensitizing activity of IgE did not change following reduction in 1 mM DTT, which split inter-heavy-light chain disulfide bond. The activity of IgE significantly diminished after reduction in 2 mM DTT followed by alkylation. This treatment resulted in the cleavage of two intra-epsilon-chain disulfide bonds, which are present between the hinge and the Fd portion of the molecules. The reduced-alkylated protein was capable of sensitizing primate skin and human basophils, however, a much higher concentration of the reduced-alkylated protein than the native protein was required for passive sensitization. The optimal sensitization period for the reversed P-K reaction was 3 hr with the reduced-alkylated protein. The protein had the ability to block passive sensitization with reaginic antibody. The reduced-alkylated protein and the native protein were labeled with 125I, and binding of these proteins with human basophils was examined by autoradiography. The results showed that affinity of the reduced-alkylated protein for basophils was less than that of native protein. Since the disulfide bonds split by 2 mM DTT were not included in the Fc portion of the molecules, the Fc fragment was obtained from the reduced-alkylated protein and was tested for affinity for basophils. It was found that the Fc fragment had higher affinity than the reduced-alkylated protein. Recovery of the affinity by papain digestion strongly suggested that cleavage of disulfide bonds in the Fab portion of the molecules induced conformational changes in the Fc portion which is involved in binding to the target cells. Reduction of IgE with 10 mM DTT followed by alkylation resulted in cleavage of 5 disulfide bonds, which is accompanied by a loss of both sensitizing and blocking activities. The fifth disulfide bond which was cleaved by 10 mM DTT, but not by 2 mM DTT, appears to be an inter-heavy chain disulfide bond in the Fc portion of the epsilon-chains. Neither epsilon1 nor epsilon2 determinants in the Fc portion of epsilon-chains were degraded by this treatment.     

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.     

Systemic expression of cutaneous basophil hypersensitivity.

Guinea pigs primed for cutaneous basophil hypersensitivity (CBH) with several soluble proteins or with sheep erythrocytes developed a systemic, delayed-onset, maculopapular rash when challenged parenterally with specific antigen. The rash was most readily induced 5 to 7 days after immunization, at a time when local CBH skin test reactivity was also optimal. Miscroscopically, the rash resembled local CBH skin test reactions, being comprised of a papillary dermal infiltrate of basophils and lymphocytes and a striking dilatation and compaction of superficial venules. In addition to the systemic rash, animals expressing systemic CBH (SCBH) exhibited a striking eosinophilia at 24 hr which gave way to basophilia at 48 hr. Focal collections of eosinophils, and of smaller numbers of basophils, were found in the lungs and spleen; both eosinophils and basophils infiltrated the medulla of the thymus. Thus, basophil-rich infiltrations are favored in the skin even after systemic challenge with antigen and occur only to a much smaller extent in other organs where eosinophils may predominate. These differences in the response of various organs to challenge with parenteral antigen suggest that as yet unidentified local factors play a determinative role in regulating the inflammatory response. The pathogenesis of SCBH is not yet established, but it shares many of the properties of local CBH: histology, carrier specificity, development early after sensitization in the absence of detectable antibodies. Passive transfer has not been accomplished with serum alone but has been achieved irregularly with cells plus serum. SCBH may serve as a useful model for several disease states in man characterized by a systemic rash and eosinophilia, including certain types of drug reaction.     

Basophil-sensitizing antibody response to herpes simplex viruses in rabbits.

Antibodies to herpes simplex virus type 1 and type 2 were detected in the sera of rabbits by release of histamine from basophils sensitized in vitro with the sera. The time course of the appearance of the antibodies, the dose-response curve of the release of histamine in relation to antigen concentration, the sedimentation characteristics of the antibodies in sucrose gradients, and the ability to destroy the sensitizing capacity of the sera with heat suggest that the antibodies being assessed were of the IgE class. These antibodies were induced in animals injected intradermally, intramuscularly, and i.p. with live virus. The antibodies were detected 1 week after primary injection and a similar time course of antibody appearance was observed after a second or third injection. The same cross-reactivity between type 1 and type 2 virus observed with IgG antibody was also observed with IgE antibody.     

Potentiation of histamine release by sodium cromoglycate.

Human lung slices passively sensitized with allergic serum released histamine when incubated with specific antigen and anti-IgE but anti-IgG had no effect. Sodium cromoglycate (SCG) inhibited antigen induced histamine release but the dose-response curve was bell-shaped. Inhibition of anti-IgE induced release was linearly related to dose, whereas that induced by anti-IgG was potentiated by increasing doses of SCG. After sensitization with allergic serum in which IgE had been inactivated by heating, specific antigen released little or no histamine but this was potentiated by SCG. It is concluded that SCG inhibits IgE mediated but potentiates IgG mediated allregic reactions thus explaining its characteristic dose-response curve $\text{in vitro}$.     

Demonstration of Fcgamma receptors on human basophil granulocytes.

Fcgamma receptors were detected on human basophil granulocytes. The mononuclear cell fraction of human peripheral blood was incubated with heat-aggregated human IgG (HGG) followed by 125I-anti-HGG. Autoradiography of the cells showed that the majority of basophil granulocytes gave a significant number of grains. Basophils were not labeled by preincubation of the same cells with monomeric HGG followed by 125I-anti-HGG. However, the binding of aggregated HGG to basophils was inhibited by the presence of a high concentration of monomeric HGG or its Fc fragment but not by the Fab fragment. Evidence was obtained that Fcgamma receptors are distinct from IgE receptors on the same cells: i) Saturation of basophils with IgE did not affect the binding of aggregated HGG to the cells. ii) Preincubation with and the presence of aggregated HGG failed to affect the binding of 125I-IgE to basophils, or to block passive sensitization of the cells with IgE antibodies. iii) The Fcgamma receptors did not co-cap with IgE receptors. Aggregated HGG failed to induce histamine release from basophils even in the presence of D2O. It was also found that the presence of aggregated HGG on basophils did not modulate IgE-mediated histamine release from the cells.     

Neutrophils and mast cells. Comparison of neutrophil-derived histamine-releasing activity with other histamine-releasing factors

Human neutrophil-derived histamine-releasing activity (HRA-N) was partially purified and found to contain a heat-stable 1400 to 2300-Da fraction which caused human basophils and rat basophil leukemia cells (RBL) to degranulate. The capacity of HRA-N to activate basophils was not related to the gender or atopic status of the basophil donor, but was related to anti-IgE responsiveness. Several lines of evidence suggest that HRA-N and anti-IgE induce histamine release through distinctly different mechanisms: 1) the time course of HRA-N- and anti-IgE-induced RBL histamine release are different; 2) HRA-N causes histamine release from RBL with and without surface-bound IgE; 3) lactic acid stripping of IgE from human basophils reduces anti-IgE-induced histamine release, but has no consistent effect on HRA-N-induced histamine release; and 4) passive sensitization of lactic acid-stripped basophils with IgE restores anti-IgE-induced histamine release but not HRA-N-induced histamine release. Several histamine-releasing factors (HRF) were compared with HRA-N. Human nasal HRF (HRF-NW, crude and partially purified fractions of 15 to 30, 3.5 to 9, and less than 3.5 kDa), like HRA-N, caused equal histamine release from both native and IgE-sensitized RBL. However, only the 15- to 30-kDa fraction caused histamine release from human basophils in the doses tested. Mononuclear cell HRF (HRF-M, crude and a partially purified 25 kDa Mr fraction) and platelet HRF (HRF-P, crude preparation) failed to cause histamine release from either native or IgE-sensitized RBL but caused 30 +/- 5.5% and 20 +/- 10% net histamine release from human basophils, respectively. HRA-N and HRF-NW were both stable to boiling. These data, taken together, suggest that the capacity of HRA-N to induce RBL and human basophil histamine release and of HRF-NW to stimulate RBL histamine release is independent of IgE. The data further suggest that HRA-N and HRF-NW can be distinguished by size, and that they both differ from mononuclear cell HRF and platelet HRF. Thus, it appears that inflammatory cells generate a family of distinct HRF.     

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.     

Dissociation of IgE from receptors on human basophils. I. Enhanced passive sensitization for histamine release

Leukocytes of only one of 11 nonatopic donors could be passively sensitized for histamine release elicited by ragweed extract. A short incubation in an unbuffered isotonic saline at pH 3.9 or in an 0.01 M lactic acid/lactate-buffered isotonic saline at pH 3.9 dissociated from 4 X 10(5) to less than 3 X 10(4) IgE molecules per basophil from washed leukocytes of several in a series of six atopic and 11 nonatopic donors. After such treatment, leukocytes of only one of the 11 nonatopic donors could not be sensitized for histamine release. Basophils of the four ragweed-sensitive donors lost their sensitivity to ragweed after the treatment, but all could be passively resensitized; for three of these donors the level of release approximated their original reactivity. Leukocytes of the two mold-sensitive donors could be passively sensitized to ragweed allergens after but not before treatment. Four plasma samples from histamine release-positive volunteers were used for sensitization of treated leukocytes of each cell donor; three were consistently effective and one was consistently ineffective. The positive plasmas had concentrations of antigen E-specific IgE of over 100 ng/ml, which accounted for 17 to 23% of the total IgE; the inactive one had less than 5 ng/ml of specific IgE. For each cell donor, all three samples of active plasma mediated quite similar histamine release, but there was a spectrum of donor cell reactivity ranging from 23 to 70% release. These results suggest that basophils from each donor, atopic or nonatopic, had a maximal potential for in vitro sensitization, which was only attained if the plasma contained appropriate, but yet to be fully defined, concentrations of specific and total IgE. Several unexpected results were obtained. Treated leukocytes from some individuals were sensitized for mediator release to a greater extent by sixfold diluted than undiluted plasma. In addition, a 4-hr incubation with plasma at 37 degrees C, but not at 25 degrees C or 0 degrees C, was less effective than were shorter incubation periods. Treated leukocytes should be useful in studying kinetic and equilibrium parameters of IgE binding to specific receptors on human basophils. Analogous treatments should also be useful in sensitization and measurement of IgE-receptor interactions of mast cell populations.