Neutrophil functional responses depend on immune complex valency.

Ligand-induced cross-linking of Fc gamma receptors (Fc gamma R) on neutrophils plays a significant role in their stimulation, shown here by contrasting the responses induced by low valency immune complexes (LICs) and high valency immune complexes (HICs) and by cross-linking LICs in situ (L/Ab) after their addition to the cells. Multiparameter flow cytometry was used to measure immune complex (IC)-elicited changes in cytoplasmic Ca2+ concentration and initiation of the oxidative burst simultaneously in the same cell and to correlate these with Fc gamma R occupancy. We have previously shown that subpopulations of neutrophils respond maximally to subsaturating concentrations of HIC; saturating dosages stimulate the entire population. This discrepancy was not due to differences in receptor occupancy. The magnitude of the transient Ca2+ increase was independent of the dose of HIC but depended on the dose when an LIC was used. As shown here, L/Ab cross-linking elicited Ca2+ responses similar to those observed in HIC-stimulated cells. In contrast, LIC elicited only minimal intracellular delta pH and no oxidative burst or membrane potential changes at all unless Fc gamma R was cross-linked, accomplished by HIC or by L/Ab. However, azurophilic degranulation, as determined by elastase release, was not observed in cells stimulated by the in situ cross-linking method, whereas the HIC preparation triggered azurophilic degranulation. Thus, some Fc gamma R-mediated neutrophil effector functions such as azurophilic degranulation and oxidative burst initiation have an absolute requirement for Fc gamma R cross-linking, whereas signaling functions such as changes in membrane potential, intracellular pH, and intracellular Ca2+ concentration can occur, albeit more slowly and to a lesser extent, if single Fc gamma R are occupied.

Role of the Fc gamma R subclasses Fc gamma RII and Fc gamma RIII in the activation of human neutrophils by low and high valency immune complexes.

Two Fc gamma receptor (Fc gamma R) subclasses on human neutrophils, Fc gamma RII and Fc gamma RIII, activate different cellular functions. To examine the involvement of each receptor subtype in polymorphonuclear leukocyte activation, Fab and F(ab')2 fragments of subclass-specific monoclonal antibodies ([mAbs] mAb IV.3 against Fc gamma RII and mAb 3G8 against Fc gamma RIII, respectively) were used to block the binding of low valency immune complexes (LICs) and high valency immune complexes (HICs). Flow cytometry then permitted the simultaneous quantitation of antibody and ligand binding, the elicited intracellular Ca2+ concentration (delta[Ca2+]int), initiation of the oxidative burst, and/or the phospholipase A activation in the same cell. We have previously demonstrated that subsaturating dosages of HIC bind uniformly to all the cells but elicit an "all-or-none" (i.e., dose independent) maximal delta[Ca2+]int in a dose-dependent subpopulation of the cells. In contrast, both the proportion of cells responding and the magnitude of the delta[Ca2+]int transient depend on the subsaturating dose of LIC, even though it too binds uniformly to all the cells, nonresponding as well as responding. These earlier findings have here been extended by single cell flow cytometric analysis to demonstrate that F(ab')2 Fc gamma RIII is the major Fc gamma R involved in HIC binding (and [Ca2+]int mobilization), as well as in oxidative burst and phospholipase A activation. In contrast, both receptor subclasses must be available for LIC-elicited delta[Ca2+]int, as blockage by either of the mAb Fab or F(ab')2 fragments abrogates this response, even though LIC binding to the receptors is not decreased. Furthermore, LIC elicited little oxidative burst activity and failed to activate phospholipase A but cross-linking to achieve multivalency, previously shown to induce [Ca2+]int and oxidative burst responses, elicited phospholipase A activity via Fc gamma RIII. Fc gamma RII's role appears to be modulation of the small, late Ca2+ influx observed at > 1 min, whereas Fc gamma RIII modulates all the earlier larger events. Thus, simultaneous observation of receptor identity, receptor occupancy, and consequent activation parameters in the same cell by flow cytometry permits use to demonstrate that Fc gamma RII is necessary for the small signal transduction elicited by LIC; it plays a relatively small role in polymorphonuclear leukocyte stimulation by HIC. Fc gamma RIII is the main receptor responsible for immune complex-elicited polymorphonuclear leukocyte responses; its efficacy is greatly enhanced when the receptors are cross-linked, either by preequilibrated multivalent complexes or by in situ cross-linking of bound LIC with excess antibody.

Differential roles of Fc gamma RII and Fc gamma RIII in immune complex stimulation of human neutrophils.

Insoluble immune complexes (IIC) stimulate human neutrophils through Fc gamma receptors. Freshly isolated human neutrophils express two FcR subclasses, FcRII and FcRIII. We explored the role of FcRII and FcRIII in this activation process by selectively binding each FcR subclass with the Fab fragments of the respective anti-FcR monoclonal antibodies (MFab) before exposure to IIC. Correlation among liganded FcR subclass, IIC binding, and ensuant IIC stimulation was achieved with multiparameter flow cytometry. We utilized rhodamine-labeled anti-FcRIII and fluorescein-labeled IIC to study binding and observed the change in [Ca2+]i in the same cell with a Ca2+ indicator, Indo-1. Treatment with either anti-FcRII (IV.3) or anti-FcRIII (3G8) MFab decreased both the fraction of cells exhibiting a Ca2+ transient and the magnitude of that transient, although only anti-FcRIII but not anti-FcRII significantly inhibited the subsequent IIC binding. In addition, cells treated with anti-FcRII and then stimulated with IIC exhibited a decrease in both the intracellular Ca2+ transient and the later Ca2+ influx, whereas anti-FcRIII totally abolished the mobilization of intracellular Ca2+ without affecting the Ca2+ influx. Treatment with either anti-FcR MFab decreased the IIC-stimulated transmembrane potential change, oxidative burst, and elastase release. These studies indicate that freshly isolated neutrophils' Fc receptor subclasses have unique roles in the IIC-initiated stimulation and that full activation can only be achieved when both FcR subclasses are available.

Propionate induces polymorphonuclear leukocyte activation and inhibits formylmethionyl-leucyl-phenylalanine-stimulated activation.

Short-chain carboxylic acids (SCCA) are metabolic by-products of bacterial pathogens which can alter cytoplasmic pH and inhibit a variety of polymorphonuclear leukocyte (PMN) motile functions. Since cytoskeletal F-actin alterations are central to PMN mobility, in this study we examined the effects of SCCA on cytoskeletal F-actin. Initially, we tested nine SCCA (formate, acetate, propionate, butyrate, valerate, caproate, lactate, succinate, and isobutyrate). We document here that while eight altered cytoplasmic pH, only six altered cytoskeletal F-actin. We then selected one SCCA that altered both F-actin and cytoplasmic pH (propionate) and one SCCA that altered only cytoplasmic pH (lactate) for further study. Propionate, but not lactate, caused an irregular cell shape and F-actin distribution. Furthermore, propionate, but not lactate, inhibited formylmethionyl-leucyl-phenylalanine (fMLP)-stimulated PMN polarization, F-actin localization, and cytoplasmic pH oscillation. Propionate-induced changes in cytoskeletal F-actin and cytoplasmic acidification were not affected by the fMLP receptor antagonist N-t-BOC-1-methionyl-1-leucyl-1-phenylalanine; however, alkalinization was affected. Pertussis toxin treatment completely inhibited propionate-induced changes in F-actin but had no effect on propionate-induced cytoplasmic pH oscillation. These results indicate that propionate (i) bypasses the fMLP receptor and G protein(s) to induce cytoplasmic pH oscillation, (ii) operates through G protein(s) to induce actin oscillation, cell shape changes (to irregular), and F-actin localization, and (iii) inhibits fMLP-stimulated cytoplasmic pH and actin oscillation, PMN polarization, and F-actin localization.

Calcium changes in immune complex-stimulated human neutrophils. Simultaneous measurement of receptor occupancy and activation reveals full population stimulus binding but subpopulation activation.

Immune complexes (ICs) induce an initial transient increase in cytosolic intracellular calcium [( Ca2+]in) levels in human neutrophils (PMN). Changes in PMN [Ca2+]in were measured with the fluorescent calcium indicator Indo-1 ( [1-[2-amino-5-(6-carboxylindol-2-yl]-phenoxyl]-2-(2'-amino-5 '- methylphenoxy]ethane-N,N,N'N'-tetraacetic acid), at the level of individual cells by flow cytometry. Two kinds of immune complexes (ICs) were used in this study: an insoluble (IIC) and a more soluble less valent immune complex (SIC) with fewer available Fc receptor binding ends per molecule of SIC than IIC. Simultaneous binding and activation studies performed on the flow cytometer with fluoresceinated IIC or SIC demonstrated that a majority of the cells bound each stimulus uniformly. However, only an IC dose-dependent proportion of those IC-bound cells responded with an increase in [Ca2+]in. Analysis of Indo-1 fluorescence signals from neutrophils exposed to IIC, corrected for the contribution of the nonresponding population, indicated that every dose of IIC elicited a similar maximum [Ca+2]in within the responding population. In contrast, the magnitude of the increase in [Ca2+]in elicited by low doses of SIC did become dependent on dose. Cells treated with pertussis toxin and exposed to IIC exhibited a normal [Ca2+]in response both in magnitude and expression. Therefore, [Ca2+]in responses induced by immune complexes are expressed by subpopulations of PMN, in a response which is dependent on the valency of the stimulus. In addition, pertussis toxin sensitive G protein(s) appear not to have a major role in IIC-induced [Ca2+]in changes, membrane potential changes, production of superoxide anions, and elastase release.