Complement-mediated release of histamine from human leukocytes.

Activation of either the alternative or classical pathway of complement generated a factor which induced release of histamine from both non-allergic and allergic human basophils. This factor probably is derived from the complement system since 1) its formation was associated with loss of C3 activity in human serum, 2) chemotactic factor, probably also a complement product, was generated simultaneously, 3) heat inactivation blocked its formation, 4) anti-C3 and anti-C5 blocked formation of the factor, and finally 5) anti-C5 inhibited the activity of the factor once it had been formed. It appears that both complement-mediated and allergen-mediated release of histamine from basophils are secretory, non-cytolytic pathways since both were maximal at 37 degrees C, required the presence of divalent cations, and were inhibited by theophylline. One consistent difference between these two mechanisms was noted: complement-initiated release of histamine occurred more quickly.     

Modulation of human basophil histamine release by hemopoietic growth factors

To determine what kinds of CSF modulate human basophil function, recombinant or purified hemopoietic growth factors were tested for the effect on histamine release from basophils. Both granulocyte (G)-macrophage (M) CSF and IL-3 markedly enhanced histamine release upon stimulation with anti-IgE in a dose-dependent manner (maximal enhancement 25.5% by GM-CSF and 30.8% by IL-3 as expressed as percent increase against total cellular histamine content), whereas G-CSF, M-CSF, and IL-4 had no effect. Enhancing action of these factors was still observed in the highly enriched basophil population, suggesting that this action was not via contaminating cells. Enhancement of histamine release by both factors was not necessarily IgE mediated, because they also amplified histamine release upon stimulation with FMLP and ionophore A23187. The enhancement by both factors was temperature dependent, and took place rapidly and reached plateau levels in 15 min. GM-CSF and IL-3 achieved the similar plateau level of augmentation and no additive effects were observed between them. This finding suggests that they enhance histamine release by sharing the same pathway in the release reaction.     

The diisopropylfluorophosphate inhibitable step in antigen-induced histamine release from human leukocytes.

DFP inhibits early events in antigen-induced histamine release from human leukocytes. If added to cells 5 min or more after antigen it is ineffective. If added with antigen it can be removed at 5 min but release will still be inhibited. In contrast, ethylenediaminetetraacetate (EDTA) and 2 deoxyglucose (2DG) still inhibit the reactions when added 5 min after antigen. During incubation of leukocytes for 90 to 120 min at 0 degrees C they react with specific antigen since they subsequently release significant quantities of histamine after washing and reincubation at 37 degrees C without addition of antigen. Such priming at 0 degrees C is at least equivalent to priming for 2 to 4 min at 37 degrees C. During antigen priming at 0 degrees C the cells are not activated beyond the step in the release sequence which is inhibited by diisopropylfluorophosphate (DFP). This is apparent from the undiminished inhibitory activity of DFP on these cells. Furthermore, cells primed with antigen at 0 degrees C in the presence of DFP release as much histamine after washing and incubation at 37 degrees D as control cells primed in the absence of DFP. Incubation of leukocytes with specific antigen at 37 degrees C for 3 min resulted in significant but not quite complete priming for subsequent histamine release in the absence of antigen. Most of these primed cells were not activated beyond the step inhibitable by DFP. However, some had completed the entire sequence including the release of histamine while others had not released their histamine but were not inhibited by DFP from subsequent release. After 5 min incubation with antigen at 37 degrees C almost all leukocytes had progressed beyond the stage which is inhibited by DFP. Incubation of leukocytes at 37 degrees C with DFP but without antigen for up to 15 min followed by washing did not impair subsequent antigen-induced histamine release by these cells. Thus, DFP was inhibitory under these conditions only after antigen activation of leukocytes.     

Induction of histamine release and desensitization in human leukocytes. Effect of anaphylatoxin.

Hog anaphylatoxin (AT) in concentrations from 0.5 to 5 mug/ml gives a dose-dependent histamine release from human leukocytes. Concentration of 100 mug/ml AT give the same high histamine release as 5 mug/ml. This is in contrast to the histamine release obtained with anti-IgE or allergen, which give low histamine release with high doses. The histamine release obtained with AT is completed in 20 sec and the reaction is temperature- and calcium-dependent. Treatment of cells with AT in the presence or absence of calcium makes them insensitive to another challenge with AT. Such treated cells are fully responsive, however, to challenge with anti-IgE if the pretreatment has been performed in the absence of calcium. This, together with the calcium- and temperature-dependence indicates that the AT-induced histamine release is nontoxic. Treatment of cells with AT in the presence of calcium induces, besides histamine release, decrease in sensitivity to anti-IgE, indicating that both AT and anti-IgE release histamine from the same cells. We discuss to what extent AT and cell-bound Ig share intracellular mechanisms for induction of histamine release.     

Characterization of the beta receptor responsible for enhanced histamine release from bovine leukocytes

The present study was undertaken to determine the beta-receptor subtype responsible for the enhanced anaphylactic histamine release from bovine leukocytes produced by isoprenaline. The selective beta 1 antagonist practolol competitively inhibited the enhancement of histamine release produced by isoprenaline. The selective beta 2 agonists salbutamol and terbutaline produce no significant effect on antigen-induced histamine release. This indicates that the receptor responsible for enhancement of histamine release from bovine granulocytes is of the beta 1 subtype. The question is raised as to whether this is a normal physiological response or an abnormal condition produced by the sensitization procedure.     

A role for intracellular calcium and calmodulin in the release of triiodothyronine from human thyroid-cell monolayer cultures

Human thyroid cells in monolayer responded to acute stimulation by TSH with an increase in the secretion of T₃. This process appeared to be dependent on a rise in the cytosolic calcium concentration since the antagonist of intraceliular calcium mobilization, TMB-8, was found to inhibit the release of T₃ in response to TSH. The importance of intracellular calcium was further shown using the agent veratridine which increases the free calcium level within cells; veratridine potentiated the stimulation of T₃ secretion by TSH and itself stimulated the release of T₃ to a level higher than that seen in the presence of TSH alone. The calcium ionophore A23197 produced a biphasic effect on T₃ secretion from human thyroid monolayers; at low concentrations, A23187 caused a decrease in both unstimulated and TSH-stimulated T₃ secretion but above a concentration of 1 M, T₃ secretion was increased. The calmodulin antagonist W7 was found to inhibit T₃ release in response to TSH, indicating a role for calmodulin in mediating the effects of intracellular calcium on T₃ secretion.     

Complement-induced histamine release from human basophils. II. Mechanism of the histamine release reaction.

The activation of human serum complement by incubation with zymosan generates C5a which releases histamine from autologous basophils. The characteristics of the C5a-induced histamine release were investigated. It is similar to IgE-mediated reactions in requiring Ca++ and in being inhibited by EDTA. However, it has marked differences from IgE-mediated reactions. C5a, at all concentrations, released histamine completely in less than 2 min. The C5a reaction has a narrow pH optimum that antigen-induced release and occurs well at 17 degrees to 37 degreesC but not at 0 degreesC. The optimal reaction temperature is 25 degrees to 30 degrees C. Unlike the antigen-induced release, no two-stage activation with C5a for the release of histamine could be demonstrated. There was additive release between C5a- IgE-mediated reactions. Leukocytes could be desensitized to the C5a-mediated reaction by 1) incubating the cells at 37 degrees C for 45 min, 2) pretreating the leukocytes with activated serum in the presence of EDTA, and 3) adding the activated serum to the leukocytes at 0 degrees C before transferring to the optimal reaction temperatures. Cells desensitized to the complement-induced release have normal reactions to IgE-mediated histamine release. In parallel experiments, cells from allergic donors desensitized for IgE-mediated reactions by incubation with antigen under sub-optimal conditions release histamine normally upon the addition of C5a. The results indicate that histamine release by C5a involves a mechanism of basophil activation that is different from the pathway involved in the IgE-induced reaction.     

The effect of calmodulin on histamine release in the rat peritoneal mast cell

To investigate the role of the Ca2+-binding protein calmodulin on histamine release in the rat peritoneal mast cell, we exposed cells to exogenous calmodulin in the presence of a variety of histamine secretagogues. Histamine release stimulated by compound 48/80, polymyxin B and ionophore A23187 was inhibited while concanavalin A-stimulated release was not affected. Calmodulin in the presence of the secretagogues did not affect cell viability and calmodulin alone had no effect on histamine release. No direct interaction between calmodulin and the secretagogues was observed. Exogenous calmodulin does not appear to be incorporated into the cell. The inhibition of histamine release by calmodulin can be explained as a labile interaction between the protein and the cell that requires externally-bound Ca2+. These experiments demonstrate the use of exogenous calmodulin as a probe in the study of the mechanism of histamine release.     

The effect of calmodulin on histamine release in the rat peritoneal mast cell

To investigate the role of the Ca²⁺-binding protein calmodulin on histamine release in the rat peritoneal mast cell, we exposed cells to exogenous calmodulin in the presence of a variety of histamine secretagogues. Histamine release stimulated by compound , polymyxin B and ionophore A23187 was inhibited while concanavalin A-stimulated release was not affected. Calmodulin in the presence of the secretagogues did not affect cell viability and calmodulin alone had no effect on histamine release. No direct interaction between calmodulin and the secretagogues was observed. Exogenous calmodulin does not appear to be incorporated into the cell. The inhibition of histamine release by calmodulin can be explained as a labile interaction between the protein and the cell that requires externally-bound Ca²⁺. These experiments demonstrate the use of exogenous calmodulin as a probe in the study of the mechanism of histamine release.