HTPS flow cytometry: a novel platform for automated high throughput drug discovery and characterization.

The flow cytometer is unique among biomedical analysis instruments because it makes simultaneous and multiple optical measurements on individual cells or particles at high rates. High throughput flow cytometry represents a potentially important multifactorial approach for screening large combinatorial libraries of compounds. Limiting this approach has been the availability of instrumentation and methods in flow cytometry for automated sample handling on the scale required for drug discovery applications. Here, we describe an automated system in which a novel patented fluidics-based pharmacology platform, the HTPS (High Throughput Pharmacological System), is coupled to a flow cytometer using a recently described plug flow-coupling valve technology. Individual samples are aspirated sequentially from microplate wells and delivered to a flow cytometer for rapid multiparametric analysis. For primary screening to detect and quantify cell fluorescence in endpoint assays, a high-speed no-wash protocol enabled processing of 9-10 cell samples/min from 96-well microplates. In an alternate primary screening format, soluble receptor ligands were sampled from microplate wells at rates of 3-4 samples/minute and successfully assessed for the ability to elicit intracellular calcium responses. Experiments with fluorescent beads validated the accurate automated production by the HTPS of exponential and linear gradients of soluble compounds. This feature enabled rapid (2- to 3-min) characterization of the intracellular calcium dose response of myeloid cells to formyl peptide as well as the quantitative relationship between formyl peptide receptor occupancy and cell response. HTPS flow cytometry thus represents a powerful high throughput multifactorial approach to increase the efficiency with which novel bioresponse-modifying drugs may be identified and characterized.

Detection of epitope-tagged proteins in flow cytometry: fluorescence resonance energy transfer-based assays on beads with femtomole resolution.

Epitope tagging of expressed proteins is a versatile tool for the detection and purification of the proteins. This approach has been used in protein-protein interaction studies, protein localization, and immunoprecipitation. Among the most popular tag systems is the FLAG epitope tag, which is recognized by three monoclonal antibodies M1, M2, and M5. We describe novel approaches to the detection of epitope-tagged proteins via fluorescence resonance energy transfer on beads. We have synthesized and characterized biotinylated and fluorescein-labeled FLAG peptides and examined the binding of FLAG peptides to commercial streptavidin beads using flow cytometric analysis. A requirement of assay development is the elucidation of parameters that characterize the binding interactions between component systems. We have thus compiled a set of Kd values determined from a series of equilibrium binding experiments with beads, peptides, and antibodies. We have defined conditions for binding biotinylated and fluoresceinated FLAG peptides to beads. Site occupancies of the peptides were determined to be on the order of several million sites per bead and Kd values in the 0.3-2.0 nM range. The affinity for antibody attachment to peptides was determined to be in the low nanomolar range (less than 10 nM) for measurements on beads and solution. We demonstrate the applicability of this methodology to assay development, by detecting femtomole amounts of N-terminal FLAG-bacteria alkaline phosphatase fusion protein. These characterizations form the basis of generalizable and high throughput assays for proteins with known epitopes, for research, proteomic, or clinical applications.

Real time analysis of the affinity regulation of alpha 4-integrin. The physiologically activated receptor is intermediate in affinity between resting and Mn(2+) or antibody activation.

This work examines the affinity of alpha(4)beta(1)-integrin and whether affinity regulation by G protein-coupled receptor (GPCR) and chemokines receptors is compatible with cell adhesion mediated between alpha(4)-integrin and vascular cell adhesion molecule-1. We used flow cytometry to examine the binding of a fluorescent derivative of an LDV peptide (Chen, L. L., Whitty, A., Lobb, R. R., Adams, S. P., and Pepinsky, R. B. (1999) J. Biol. Chem. 274, 13167-13175) to several cell lines and leukocytes with alpha(4)-integrin ranging from about 2,000 to 100,000 sites/cell. The results support the idea that alpha(4)-integrins exhibit multiple affinities and that affinity changes are regulated by the dissociation rate and conformation. The affinity varies by 3 orders of magnitude with the affinity induced by binding mAb TS2/16 plus Mn(2+) > Mn(2+) ' TS2/16 > activation because of occupancy of GPCR or chemokines receptor > resting receptors. A significant fraction of the receptors respond to the activating process. The change in alpha(4)-integrin affinity and the corresponding change in off rates mediated by GPCR receptor activation are rapid and transient, and their duration depends on GPCR desensitization. The affinity changes mediated by IgE receptor or interleukin-5 receptor persist longer. It appears that the physiologically active state of the alpha(4)-integrin, determined by inside-out signaling, has similar affinity in several cell types.

Analysis of free intracellular calcium by flow cytometry: multiparameter and pharmacologic applications.

Flow cytometry offers numerous advantages over traditional techniques for measuring intracellular Ca(2+) in lymphoid and nonlymphoid cells. In particular, the heterogeneity of cell responses can be defined by flow cytometry, and multiparameter analyses permit the determination of intracellular Ca(2+) in surface-marker-defined target cells as well as correlation of changes in Ca(2+) with other biochemical markers, including ligand binding. This article presents several established methods for measuring intracellular Ca(2+) by flow cytometry in lymphoid and nonlymphoid cells. Examples are provided for determination of Ca(2+) in human peripheral blood leukocytes and two human epithelial cell lines grown in monolayer. In addition, applications are reviewed or presented for correlating changes in intracellular Ca(2+) with other cell parameters, including cell cycle analysis, changes in cell membrane integrity, and the induction of apoptosis markers. Finally, a number of novel sample handling capabilities useful for performing kinetic analyses of Ca(2+) changes by flow cytometry are now available and one application is presented which is finding utility in pharmacologic studies.

Peptides, antibodies, and FRET on beads in flow cytometry: A model system using fluoresceinated and biotinylated beta-endorphin.

BACKGROUND: Particulate surfaces such as beads are routinely used as platforms for molecular assembly for fundamental and practical applications in flow cytometry. Molecular assembly is transduced as the direct analysis of fluorescence, or as a result of fluorescence resonance energy transfer. Binding of fluorescent ligands to beads sometimes alters their emission yield relative to the unbound ligands. Characterizing the physical basis of factors that regulate the fluorescence yield of bound fluorophores (on beads) is a necessary step toward their rational use as mediators of numerous fluorescence based applications. METHODS: We have examined the binding between two biotinylated and fluoresceinated beta-endorphin peptides and commercial streptavidin beads using flow cytometric analysis. We have analyzed the assembly between a specific monoclonal antibody and an endorphin peptide in solution using resonance energy transfer and compared the results on beads in flow cytometry using steady-state and time-resolved fluorescence. RESULTS: We have defined conditions for binding biotinylated and fluoresceinated endorphin peptides to beads. These measurements suggest that the peptide structure can influence both the intensity of fluorescence and the mode of peptide binding on the bead surface. We have defined conditions for binding antibody to the bead using biotinylated protein A. We compared and contrasted the interactions between the fluoresceinated endorphin peptide and the rhodamine- labeled antibody. In solution we measure a K(d) of <38 nM by resonance energy transfer and on beads 22 nM. DISCUSSION: Some issues important to the modular assembly of a fluorescence resonance energy transfer (FRET) based sensing scheme have been resolved. The affinity of peptides used herein is a function of their solubility in water, and the emission intensity of the bound species depends on the separation distance between the fluorescein and the biotin moiety. This is due to the quasi-specific quenching interaction between the fluorescein and a proximal binding pocket of streptavidin. Detection of antibodies in solution and on beads either by FRET or capture of fluorescent ligands by dark antibodies subsequently enables the determination of K(d) values, which indicate agreement between solution and flow cytometric determinations.

Beta2-integrins mediate stable adhesion in collisional interactions between neutrophils and ICAM-1-expressing cells.

The aggregation of human neutrophils in suspension has features that are analogous to their attachment to activated endothelium in that both involve selectin and beta2-integrin adhesion receptors. For the collisional interaction that forms neutrophil aggregates in suspension, there is a tethering step in which L-selectin on neutrophils binds PSGL-1. At relatively low shear rates (100-200 s(-1)) firm adhesion is mediated in equal measure by LFA-1 binding to ICAM-3, and Mac-1 binding to an as yet undefined ligand. In this report we used a mouse melanoma cell line expressing an estimated 700,000 ICAM-1 (CD54) to examine the relative roles of LFA-1 and Mac-1 over the kinetics of heterotypic cell adhesion in shear mixed suspensions. Neither heterotypic nor homotypic neutrophil aggregates formed with application of shear alone. However, the rate of aggregation peaked within seconds of chemotactic stimulation. In contrast to homotypic aggregation, neither L-selectin nor its O-glycoprotein ligands on neutrophils contributed to heterotypic adhesion. Adhesion was inhibited in a dose-dependent manner as ICAM-1 was titrated with blocking mAb. A direct interaction between LFA-1 and ICAM-1 was preferred over the first minute of stimulation, whereas at later times adhesion was supported equally by Mac-1. Activation with MnCl2 also favored participation of the constitutively expressed LFA-1. Application of defined shear in a cone and plate viscometer showed that adhesion to the ICAM-1 cells decreased from a maximum level to baseline as shear rate increased up to 400 s(-1) in a manner typical of integrin adhesion alone. In contrast, homotypic aggregation supported by the transition from selectin to integrin binding exhibited an increase in efficiency up to 800 s(-1). The pathophysiological significance of receptor site density and duration of contact in collisional interactions relevant to leukocyte recruitment compared to leukocyte-endothelial cell interactions on surfaces is discussed.

The emergence of flow cytometry for sensitive, real-time measurements of molecular interactions.

The analysis of macromolecular interactions is an essential element of biomedical research. Flow cytometry is uniquely capable of making sensitive and quantitative measurements of molecular interactions. These measurements can be made in real time with subsecond kinetic resolution using purified biomolecules or living cells. Combined with automated sample handling, these features make flow cytometry a versatile and robust technology for the analysis of molecular interactions.

Retinoic acid induces aggregation of the acute promyelocytic leukemia cell line NB-4 by utilization of LFA-1 and ICAM-2.

All-trans retinoic acid (tRA) is a potent differentiation agent that is effective therapy for acute promyelocytic leukemia (APL). However, 5% to 25% of patients develop retinoic acid syndrome, a potentially life-threatening complication in which the pathogenesis relates to adhesive alterations of APL cells. Therefore, we investigated the relationship between tRA-induced differentiation and the adhesive properties of APL cells. After confirming differentiation-related morphological changes of NB-4 cells in response to tRA, we showed that homotypic aggregation of NB-4 cells grown in tRA for 72 hours is dose-dependent with a median effective dose of approximately 50 nmol/L. Maximal aggregation occurred at mean and peak therapeutic serum concentrations (100 and 1,000 nmol/L, respectively). Aggregation also increased with the length of tRA exposure over 168 hours. Aggregation was inhibited by neutralizing antibodies against LFA-1 and ICAM-2. Notably, antibodies directed against VLA-4, other beta2 integrins (Mac-1 and p150), or other potential LFA-1 counterstructures that were expressed on the cell surface (ICAM-1 and ICAM-3) did not block aggregation. Aggregation occurred with similar kinetics regardless of the presence of phorbol ester or the "activating" monoclonal antibody (MoAb) KIM 185, suggesting that the avidity of LFA-1 is not modulated on NB-4 cells in a manner similar to other leukocytes. Consistent with the prompt clinical effectiveness of methyl prednisolone sodium succinate (MPSS) in retinoic acid syndrome, MPSS rapidly inhibited homotypic aggregation in a dose-dependent manner. Thus, tRA alters the adhesive properties of APL cells by inducing the expression of high-avidity beta2 integrins, aggregation is inhibited by LFA-1 and ICAM-2 MoAb, and tRA effects are rapidly reversible by MPSS. Taken together, our findings provide a clinically relevant system for study of LFA-1/ICAM-2 interaction and suggest a mechanism in part for retinoic acid syndrome and the effectiveness of MPSS in ameliorating retinoic acid syndrome.

Relationship of ligand-receptor dynamics to actin polymerization in RBL-2H3 cells transfected with the human formyl peptide receptor.

The human formyl peptide receptor (FPR) expressed in RBL-2H3 transfectants (RBL[FPR]) behaves qualitatively like the FPR expressed by neutrophils except that it causes sustained F-actin accumulation and cell shape change responses on formyl peptide stimulation. These sustained responses were not accounted for by changes in the transfected receptor's ability to interact with ligand or by receptor density. Signal transduction pathways of transfected and neutrophil FPRs are apparently similar. In transfected cells, dissociation of ligand is sensitive to guanine nucleotide, the G protein is pertussis toxin-sensitive, FPR and G protein appear to be precoupled, the F-actin response is stimulated with the same dose-response profile as in neutrophils, and the F-actin accumulation response is directly regulated by the FPR, even long after initial stimulation. Potentially significant differences between neutrophil and transfected FPR were found when receptor processing was measured. In neutrophils, practically 100% of the FPR is converted to forms that dissociate slowly from ligand and are inactive in signal transduction within 2 min of ligand stimulation. By contrast, 20% or more of transfected FPR remains rapidly dissociating even 5 min after stimulation. Although 80% of neutrophil FPR is internalized by 5 min after stimulation, transfected FPR appears to plateau at 50-60% internalized. Because actin responses in neutrophils are regulated by a small number of active receptors, the inefficiency of receptor inactivation in RBL(FPR) transfectants may account for the prolonged F-actin accumulation response.

Cooperation between the Fc epsilonR1 and formyl peptide receptor signaling pathways in RBL(FPR) cells: the contribution of receptor-specific Ca2+ mobilization responses.

RBL(FPR) mast cells express the tyrosine kinase-coupled IgE receptor, Fc epsilonR1, and the G-protein-coupled formyl peptide receptor, FPR. Fc epsilonR1 crosslinking causes Ca2+ stores release, Ca2+ influx, Ins(1,4,5)P3 production and secretion. FPR ligation also mobilizes Ca2+, but without measurable Ins(1,4,5)P3 production or secretion. Co-stimulating the FPR and Fc epsilonR1 induces more Ins(1,4,5)P3 production and secretion than Fc epsilonR1 cross-linking alone. Costimulation also produces more rapid and sustained Ca2+ responses than are generated by Fc epsilonR1 activation alone. We identified multiple differences between the FPR- and Fc epsilonR1-coupled Ca2+ responses, including a more rapid Ca2+ spike response to FPR ligation; intracellular Ca2+ stores that are empty following Fc epsilonR1 crosslinking but partially full following FPR activation; a more sustained Ca2+ influx response to Fc epsilonR1 crosslinking; and the immediate inhibition of stimulated Ca2+ influx by FPR antagonists but not by monovalent ligand that terminates Fc epsilonR1 crosslinking. We hypothesize that the interaction of receptor-specific Ca2+ mobilization pathways contributes to the FPR-mediated potentiation of Fc epsilonR1-coupled secretion.

Interactions of lipopolysaccharide with neutrophils in blood via CD14.

The functional characteristics of neutrophils are exceedingly sensitive to physiological conditions as well as the details of isolation. Exposure to lipopolysaccharide (LPS) or even contamination of the isolating media with traces of LPS is known to play an important role in regulating cell function and expression of receptors. Because of the suspected role of CD14 as a receptor for LPS, we used anti-CD14 monoclonal antibodies both to identify CD14 in the cell surface of polymorphonuclear leukocytes and to inhibit functional changes elicited by LPS. Cytometric techniques were used to investigate the regulation of CD14 and CR3 on the neutrophil cell surface in whole blood to minimize any effects of isolation. In whole blood neutrophil express low levels of formyl peptide receptor, CD14, and CR3, which increase substantially in response to formyl peptide and LPS. The increases in CR3 and CD14 occurred in parallel and were independent of protein synthesis and tumor necrosis factor (TNF) production. The increase in CR3 was inhibited by antibodies MY4, 3C10, and 28C5 against CD14. These findings are consistent with the notion that in blood the observed receptor up-regulation is in direct response to the action of LPS on neutrophils through CD14 and does not require products from macrophages such as TNF or the production of C5a from the plasma.

Reversal of inhibitory pathways in neutrophils by protein kinase antagonists: a rational approach to the restoration of depressed cell function?

Neutrophil functions are sensitive to both stimulatory and inhibitory pathways. For example, the endogenous hormones histamine, prostaglandin E1, adenosine, and catecholamine were found to inhibit the oxidant responses of human neutrophils by formyl peptide to 6.2, 16.8, 11.4, and 15.4%, respectively, of the initial response. The inhibition of cell function is mimicked by dibutyryl cAMP and forskolin, consistent with a pathway involving cAMP and an A kinase. Because of likely roles of kinases in both stimulatory and inhibitory pathways, we evaluated the potential for regulating either pathway by kinase inhibitors. Preincubation of intact neutrophils with membrane-permeable but nonspecific protein kinase antagonists blocked the isoproterenol-mediated inhibition of superoxide generation. The isoquinoline sulfonamides H-7, H-8, and H-9 at 100 microM reversed inhibition to 60.1, 66.6, and 70.9%, respectively, of the response of control cells. H-9 also antagonized the inhibition of superoxide production induced by other agents that regulate intracellular cAMP (prostaglandin E1, histamine, adenosine, forskolin, and dibutyryl cAMP). A synthetic peptide used as a specific but impermeable protein kinase A antagonist restored superoxide production inhibited by isoproterenol and cAMP up to 70% in electroporated cells. A small number of proteins are targets of cAMP-dependent phosphorylation in electroporated cells, and phosphorylation is inhibited in the presence of the peptide inhibitor. Taken together, these data show that a peptide inhibitor and isoquinoline sulfonamides reverse the inhibition of the respiratory burst in neutrophils evoked by the inhibitory pathways. Drugs that reverse the effect of endogenous inhibitors of neutrophil activation (by restoring cell function) have important therapeutic implications in restoring cell functions in patients whose cell functions are depressed under physiological conditions.

Heparin enhances the interaction of infective Leishmania donovani promastigotes with mouse peritoneal macrophages. A fluorescence flow cytometric analysis.

Human visceral leishmaniasis results from the infection of macrophages by the protozoan parasite Leishmania donovani. Both forms of the parasite, the extracellular promastigote and the obligate intracellular amastigote, require cell surface molecules to ensure their recognition and uptake by the host cell, the macrophage. We have proposed previously that the heparin-binding protein on the surface of promastigotes is an adhesion molecule. The present report provides experimental evidence to support this hypothesis. Fluorescence flow cytometry using FITC-heparin was employed to study the heparin-binding protein of L. donovani promastigotes and amastigotes. We demonstrate the presence of the heparin-binding protein on the surface of amastigotes and document the heparin specificity of the binding protein for both forms of the parasite. Two-color fluorescence analysis was performed to compare R-PNA reactivity and FITC-heparin binding during the parasite's 7-day growth curve. Using this strategy we show that the expression of heparin binding activity coincides with the differentiation of the noninfective promastigote into the infective metacyclic from of the parasite. Macrophages that were challenged for 30 min with heparin-treated, FITC-labeled parasites became 2.82-fold more fluorescent than their counterparts which were exposed to non-heparin-treated FITC-labeled promastigotes. Finally, using Kolmogorov-Smirnov analysis we show that the adhesion of promastigotes to mouse peritoneal macrophages is significantly enhanced in the presence of 3.3 microM heparin. The experiments described in the present report provide evidence for the hypothesis that L. donovani's heparin-binding protein is a virulence factor that functions as an adhesion molecule in the parasite-macrophage interaction.

Rap1A is a substrate for cyclic AMP-dependent protein kinase in human neutrophils.

The Ras-related protein, Rap1B, has previously been shown to serve as a PKA substrate in vitro and to be phosphorylated by cAMP elevating agents in human platelets. We have purified a Rap1 protein that serves as a PKA substrate from human neutrophils, and we now identify this protein as Rap1A. A 23-kDa protein that co-migrated with recombinant Rap1A was phosphorylated in electroporated human neutrophils upon stimulation by cAMP in the presence of [gamma-32P]ATP. This protein could be immunoprecipitated by the Rap1A/B-specific antibody, R61. The 23-kDa phosphoprotein was monitored during the purification of Rap1 from neutrophil membrane extracts and was shown to copurify with Rap1 during the DEAE Sephacel, heptylamine Sepharose, and MonoQ chromatography steps utilized. The purified protein was phosphorylated to an extent of 1 mol phosphate/mol GTP gamma S bound. This protein was identified as Rap1A by: 1) amino acid sequence analysis; and 2) immunoblotting with a Rap1A-specific antibody. The amino acid phosphorylated on Rap1A by PKA was a serine residue. The site of phosphorylation was indicated by carboxypeptidase digestion and confirmed using a mutant recombinant Rap1A lacking the relevant serine (serine-180). Rap1A, not Rap1B, appears to be the major 23-kDa PKA substrate in human neutrophils. It is possible that Rap1A plays a role in human neutrophils in mediating the inhibitory effects of cAMP-elevating agents upon chemoattractant-stimulated cell activation.

Differential amplification of antagonistic receptor pathways in neutrophils.

In human neutrophils approximately 500 ligand-occupied beta-adrenergic receptors almost completely inhibit the superoxide production generated by at least 50,000 formyl peptide receptors, suggesting a massive amplification of the inhibitory receptor signals. We estimated two stages of amplification. In the first stage, we quantitated the ligand-dependent GTPase activities. For the formyl peptide receptor, the number of phosphates released from GTP in the presence of the saturating ligand is relatively modest, i.e. approximately 1/min/receptor, even though there are approximately 200 Gn (Gi type II) proteins/formyl peptide receptor in neutrophil membranes. In contrast, the number of GTPs cleaved in the presence of a beta-adrenergic agonist is approximately 100/min/beta-adrenergic receptor, and there are about 700 Gs/beta-adrenergic receptor in membranes. Thus the signal of the beta-adrenergic receptor is already massively amplified at the G protein, whereas the signal of the formyl peptide receptor is likely to be amplified at subsequent steps. New kinetic evidence from intact cells and biochemical evidence from permeabilized cells is provided that the second messenger of the inhibitory pathway is cAMP. To estimate the amplification of this step, we determined the cAMP concentration necessary to maximally inhibit superoxide anion production of formyl peptide-stimulated electropermeabilized cells, and we compare these concentrations to previously determined values of cAMP production in neutrophils. We conclude that each receptor may generate up to 10,000 molecules of cAMP.

Mastoparan interacts with the carboxyl terminus of the alpha subunit of Gi.

Mastoparan, a peptide toxin from wasp venom, stimulates guanine nucleotide binding and hydrolysis by G proteins. To elucidate the site of mastoparan-G protein interaction, we utilized a polyclonal antibody (R16,17) directed against the carboxyl terminus of the Gi alpha subunit to develop a competitive enzyme-linked immunosorbent assay. We investigated the ability of mastoparan to influence R16,17 antibody binding to G protein alpha subunits in a purified preparation of brain Gi and in neutrophil membrane extracts. Mastoparan antagonized the ability of R16,17 to detect G protein alpha subunits with an IC50 of 15 microM in the purified preparation and with an IC50 of 1 microM for the predominant G protein population in membrane extracts. This reduction was not seen when an unrelated peptide or a peptide of similar charge composition to mastoparan was used in place of mastoparan in the assay. Additionally, antibody R16,17 blocked up to 85% of mastoparan-stimulated GTPase activity. Taken together, these data indicate that the interaction of mastoparan with G protein depends in part on the carboxyl terminus of Gi alpha. Pertussis toxin-catalyzed ADP-ribosylation of Gi alpha markedly inhibited mastoparan-stimulated GTPase activity but only slightly attenuated the ability of mastoparan to recognize G protein. These data suggest that ribosylation inhibits mastoparan-induced G protein activation by a mechanism distinct from the ability of mastoparan to physically interact with G protein. Since mastoparan is thought to mimic hormone-liganded receptors, these findings may be applicable to the mechanism of receptor-Gi protein uncoupling that results from ADP-ribosylation of the G protein.

An HPLC procedure for separating polyphosphoinositides on hydroxylapatite.

We describe a method for separation of several phosphoinositides by high performance liquid chromatography (HPLC) for the purposes of identification, analysis, and possible purification of cell phospholipid extracts. The phosphoinositides were separated on an hydroxylapatite column using a solvent system consisting of tetrahydrofuran-ethanol-water with a gradient of triethylamine phosphate ranging from 1 to 100 mM. Increasing triethylamine phosphate concentrations over a series of isocratic steps resulted in the resolution of [3H]phosphoinositide standards (phosphatidylinositol, phosphatidylinositol-4-phosphate, phosphatidylinositol-4,5-bisphosphate) and their lyso-derivatives. The eluted peaks were collected and quantitated using scintillation counting, and the samples of the eluates were subjected to further analysis by thin-layer chromatography to verify their integrity and identity.

Transient increase in phosphatidylinositol 3,4-bisphosphate and phosphatidylinositol trisphosphate during activation of human neutrophils.

We recently showed that phosphatidylinositol trisphosphate (PIP3) was present in a unique lipid fraction generated in neutrophils during activation. Here, we demonstrate that the band containing this fraction isolated from thin layer chromatography consists primarily of PIP3 and that only small amounts of radiolabeled PIP3 exist prior to activation. In addition, high performance liquid chromatography of deacylated phospholipids from stimulated cells reveals an increase in a fraction eluting ahead of glycerophosphoinositol 4,5-P2. After removal of the glycerol we found that it coeluted with inositol 1,3,4-P3 when resubjected to high performance liquid chromatography. Thus, we have detected a second, novel form of phosphatidylinositol bisphosphate in activated neutrophils, PI-(3,4)P2. The elevation of PIP3 through the formyl peptide receptor is blocked by pretreatment with pertussis toxin, implicating mediation of the increase in PIP3 by a guanosine triphosphate-binding (G) protein. The rise in PIP3 is not secondary to calcium elevation. Buffering the rise in intracellular calcium did not diminish the increase in PIP3. The elevation of PIP3 appears to occur during activation with physiological agonists, its level varying with the degree of activation. Leukotriene B4, which elicits many of the same responses as stimulation of the formyl peptide receptor but with minimal oxidant production, stimulates a much attenuated rise in PIP3. Isoproterenol, which inhibits oxidant production also reduces the rise in PIP3. Hence formation of PI(3,4)P2 and PIP3 (presumed to be PI(3,4,5)P3) correlates closely with the early events of neutrophil activation.

Coupling of antagonistic signalling pathways in modulation of neutrophil function.

Modulation of neutrophil activation by catecholamines reflects a fine-tuning by coupling inhibitory and stimulatory receptor pathways. The catecholamine isoproterenol (ISO) binds to beta-adrenergic cell surface receptors and thereby inhibits cell responses such as O2- production stimulated by formyl peptides. However, ISO did not inhibit O2- generation activated by 1 microM ionophore A23187, the protein kinase C activators phorbol ester (PMA, 100 ng/ml) and oleoylacetylglycerol (OAG, 50 microM), and the G-protein activator NaF (40 mM). Furthermore, the overall kinetics of oxidant production in the presence of ISO were unchanged when cells were stimulated with PMA, OAG, A23187, and NaF. These results would imply that neither intracellular calcium, the activation of protein kinase C, nor the activation of G-protein are the primary target of the inhibitory pathway. Accordingly, pertussis toxin did not block PMA or NaF-stimulated superoxide generation. In contrast, formyl peptide-dependent GTPase activity is inhibited by ISO in sonicated cell preparations. Since ISO increases the cAMP concentration in the cell, the possibility is raised that a cAMP-dependent kinase inhibits signal transduction in part by blocking the interaction of this receptor with its G-protein.

Three states for the formyl peptide receptor on intact cells.

Three distinct states of the formyl peptide receptor have been described. These are: 1) the ternary complex of ligand, receptor, and G protein (LRG); 2) the rapidly dissociating occupied receptor (ligand-receptor complex (LR]; and 3) a desensitized slowly dissociating guanine nucleotide-insensitive receptor (desensitized ligand-receptor complex ("LRX"]. During cell activation there is a rapid interconversion among receptor states from a rapidly dissociating form (t 1/2 approximately 10 s) to a slowly dissociating form (t 1/2 greater than or equal to 2 min). Neither the dynamics of the states nor their interconversion is influenced by ribosylation of G protein in the presence of pertussis toxin. In contrast to ribosylation, treatment of cells with either 2-deoxyglucose or fluoride ion, both of which lead to a loss of adenine and guanine nucleotides, causes a time-dependent change in ligand dissociability. After short periods of treatment (5-15 min) rapid dissociation is observed; after longer times (30-60 min), slow dissociation is once again detected. When intact cells are first ribosylated and then energy-depleted, only a rapidly dissociating receptor is detected. These results are discussed in terms of a model with the following elements: 1) intact cell dynamics during cell activation are dominated by an energy-dependent interconversion from LR to LRX; 2) under activation conditions, LRG appears and disappears too rapidly to be detected; 3) in cells depleted of energy and guanine nucleotide, LRG is stabilized; 4) in cells both ribosylated and depleted of energy, LR is stabilized.