Remodeling of granulocyte membrane fatty acids during phagocytosis.

During phagocytosis, new phospholipid is synthesized from triglyceride fatty acid and may be utilized to form the membranes of phagocytic vesicles. In addition, hydrogen peroxide, which can peroxidize unsaturated fatty acids, is generated. Since both of these processes could change membrane fatty acid composition during the conversion of cytoplasmic granules and plasma membranes to phagosomes, the lipid compositions of these structures were examined. Phagocytic vesicles were prepared by density gradient centrifugation of polystyrene latex particles after phagocytosis. Granule and plasma membrane fractions were isolated by density gradient and differential centrifugation. Phospholipids and fatty acids were analyzed by thin-layer chromatography and gas-liquid chromatography. While whole cells, granules, plasma membranes, and phagosomes were all similar in phospholipid composition, phagosome fatty acids were significantly more saturated than those of the other fractions. This was primarily due to reduced oleic and arachidonic acids and increased palmitic acid in the phagocytic vesicle lipids. Plasma membrane was also more saturated in comparison to whole cells and granules. However, this difference was not sufficient to explain the marked comparative saturation of the phagosomes. The observed increase in fatty acid saturation in these lipids may have been induced by a combination of either peroxidative destruction of polyunsaturated fatty acids or phospholipase activity, coupled with reacylation mechanisms favoring saturated fatty acids.

Increased levels of cyclic adenosine-3',5'-monophosphate in human polymorphonuclear leukocytes after surface stimulation.

Levels of cyclic AMP (cAMP) (but not cyclic GMP) in suspensions of human polymorphonuclear leukocytes (PMN) increased promptly after exposure of the cells to stimuli such as the chemotactic peptide N-formyl methionyl leucyl phenylalanine, the immune complex bovine serum albumin/anti-bovine serum albumin and calcium ionophore A23187. cAMP increased rapidly, reaching a maximum of twice the basal level 10--45 s after stimulation; after 2--5 min the amount of cAMP had subsided to basal levels. Elevations in cAMP levels were concurrent with, or followed, membrane hyperpolarization (measured by uptake of the lipophilic cation triphenylmethyl phosphonium) and always preceded lysosomal enzyme release and superoxide anion (O2) production. Elevated cAMP levels could be uncoupled from these later events by removal of extracellular divalent cations, replacement of extracellular Na+ with K+ or choline+, and by use of low concentrations of stimulus; each of these conditions virtually abolished lysosomal enzyme release and O2 generation, while leaving the stimulated elevation of cAMP levels unimpaired. Calcium ionophore A23187 did not provoke membrane hyperpolarization, thus uncoupling changes in membrane potential from changes in cAMP levels. These data suggested that cAMP is not a critical component in the earliest steps of stimulus-secretion coupling. Surface stimulation of cells pretreated with prostaglandins E1 or I2 yielded very high levels of cAMP; these high levels may be an important part of the mechanism by which stable prostaglandins inhibit lysosomal enzyme release and O2 generation.

Role of phorbol diesters in in vitro murine megakaryocyte colony formation.

In vitro megakaryocyte differentiation is regulated by two activities: a megakaryocyte colony-stimulating activity (Mk-CSA), which is required for proliferation, and an auxiliary factor, megakaryocyte potentiating activity, which plays a role in later differentiation events. Tumor-promoting phorbol esters alter many cellular differentiation-related events. Thus, it was hypothesized that phorbol esters may bring about megakaryocyte differentiation in vitro. 4 beta-Phorbol 12-myristate 13-acetate (PMA), when co-cultured with a source of Mk-CSA, stimulated a threefold increase in colony numbers. Co-culture of PMA and megakaryocyte potentiator activity did not stimulate colony formation, thus eliminating any action of PMA as an Mk-CSA. The direct effect of PMA on the formation of megakaryocyte colonies was established by (a) the function of PMA as a megakaryocyte potentiator in serum-free experiments, (b) the ability of PMA to stimulate megakaryocyte colony formation using bone marrow cells depleted of populations known to produce potentiating activity, (c) the inability of bone marrow adherent cells previously treated with phorbol, 12,13-dibutyrate (PDBu) to augment megakaryocyte colony formation, and (d) the ability of PMA to induce the growth of immature megakaryocytes into large single megakaryocytes. Structure:activity experiments resulted in equivalent activities for PMA and PDBu, whereas the nontumor promoter phorbol 12,13-diacetate and phorbol itself lacked activity. The observations in this study indicate that phorbol esters can bring about megakaryocyte differentiation, and during colony formation, can induce effects identical to those brought about by biological sources of megakaryocyte potentiator activity.

Human neutrophil annexin I promotes granule aggregation and modulates Ca(2+)-dependent membrane fusion.

The mechanism and cofactor requirements of exocytotic membrane fusion in neutrophils are unknown. Cytosolic proteins have been implicated in membrane fusion events. We assessed neutrophil cytosol for the presence of fusogenic proteins using a liposome fusion assay (lipid mixing). A fusogenic 36-kD protein containing amino acid sequence homology with human annexin I was purified from the cytosol of human neutrophils. This protein also shared functional characteristics with annexin I: it associated with and promoted lipid mixing of liposomes in a Ca(2+)-dependent manner at micromolar Ca2+ concentrations. The 36-kD protein required diacylglycerol to promote true fusion (contents mixing) at the same Ca2+ concentrations used for lipid mixing. The 36-kD protein exhibited a biphasic dose-response curve, by both promoting and inhibiting Ca(2+)-dependent lipid-mixing between liposomes and a plasma membrane fraction. The 36-kD protein also promoted Ca(2+)-dependent increases in aggregation of a specific granule fraction, as measured by a turbidity increase. Antiannexin I antibodies depleted the 36-kD protein from the cytosol by greater than 70% and diminished its ability to promote lipid mixing. Antiannexin I antibodies also decreased by greater than 75% the ability of neutrophil cytosol to promote Ca(2+)-dependent aggregation of the specific granules. These data suggest that annexin I may be involved in aggregation and fusion events in neutrophils.

Guanine nucleotides reduce the free calcium requirement for secretion of granule constituents from permeabilized human neutrophils.

Human neutrophils can be permeabilized with the cholesterol complexing agent digitonin and then induced to secrete lysosomal constituents by increases in free Ca2+ alone. In order of increasing requirements for Ca2+, vitamin B-12 binding protein, lysozyme and beta-glucuronidase were released. A variety of guanine nucleotides were examined with respect to their abilities to modulate this response. GTP, along with its analogues 5'-guanylylimidodiphosphate (Gpp[NH]p) and guanosine-5'-O-[3-thio]-triphosphate (GTP[gamma S]) decreased the Ca2+ requirements for secretion of all three granule constituents by one third to one order of magnitude. This synergy was dependent upon the concentration of guanine nucleotides employed. The effects of Gpp[NH]p could be blocked with the inactive derivative GDP[beta-S]. The active guanine nucleotides, particularly GTP, served as stimuli in their own right. At high concentrations of Ca2+ and GTP, degranulation was strikingly inhibited; inhibition was also achieved with high concentrations of guanylyl[beta, gamma-methylene]diphosphate (Gpp[CH2]p). Both GDP and GMP were without any effect. When neutrophils were pretreated with pertussis toxin, granule discharge induced by fMet-Leu-Phe was almost completely blocked, as reported by others. If the neutrophils pretreated with pertussis toxin were then permeabilized with digitonin, the synergy between Ca2+ and the stimulatory guanine nucleotides was maintained. These data suggest the involvement of G-proteins in secretion induced by Ca2+; however, this response either uses a different G-protein or a different pool of G-proteins from those responses triggered by fMet-Leu-Phe.

Ca2(+)-induced secretion by electropermeabilized human neutrophils. The roles of Ca2+, nucleotides and protein kinase C.

Studies of stimulus-response coupling have benefitted from the availability of permeabilization techniques, whereby putative second messengers and intracellular modulators can be introduced into the cell interior. Electropermeabilization, which uses high-intensity electric fields to breach the plasma membrane, creates small pores, permitting access of solutes with molecular masses below 700 KDa. Neutrophils permeabilized by this technique, but not intact cells, discharged lysosomal constituents when exposed to micromolar levels of Ca2+. Secretion by electroporated neutrophils was significantly enhanced by the presence of Mg-ATP (0.3-1.0 mM). Contrary to expectations, it was determined that ATP was not the only nucleotide which enhanced Ca2(+)-induced secretion in the presence of Mg2+. Not only could GTP, XTP, ITP, UTP or ADP partially or completely replace ATP, but even non-hydrolyzable nucleotides such as ADP beta S ATP gamma S, and App[NH]p were effective. GTP gamma S and GDP beta S were inhibitory, while Gpp[NH]p was inactive. None of these nucleotides induced secretion on its own. In contrast, neutrophils which were permeabilized and then washed, were only slightly activated by Mg-ATP and other nucleotides; even the response to Ca2+ alone was less. This hyporesponsiveness of washed cells proved to be due to a time-dependent deactivation of the permeabilized neutrophils taking place at 4 degrees C. In an effort to assess the role for protein kinase C (PKC) in secretion in this system, we examined the effects of phorbol myristate acetate (PMA), a PKC agonist. PMA enhanced degranulation induced by Ca2+ by lowering the requirement for this divalent cation; enhancement by PMA was not dependent upon exogenous ATP. Three inhibitors of PKC with varying specificity, namely H-7, K-252a, and staurosporine, all abrogated PMA-enhanced secretion. These agents also inhibited secretion stimulated by Ca2+ plus ATP in parallel with that induced by Ca2+ plus PMA, strongly suggesting a role for PKC in modulation of degranulation by ATP. Our results show that electropermeabilized neutrophils provide a convenient, useful model for stimulus-secretion coupling. These data also suggest that the 'requirement' for Mg-ATP, which has been observed in other permeabilized cell systems, is not simply for metabolic energy or as a substrate for kinases. It is possible that these nucleotides all interact with a recently described neutrophil receptor for adenine nucleotides or with a recently postulated exocytosis-linked G-protein.

The effects of heavy metal cations and sulfhydryl reagents on degranulation from digitonin-permeabilized neutrophils.

Digitonin-permeabilized neutrophils were exposed to micromolar levels of a variety of heavy metal cations and sulfhydryl oxidants to gain insight into the potential biochemical mechanisms underlying neutrophil degranulation. The results from this study suggest that the oxidation of intracellular sulfhydryl groups may play a role in neutrophil signal transduction. Evidence to support this conclusion is based on the observation that cupric phenanthroline and Cu2+/cysteine, agents reported to induce disulfide bond formation, evoke significant granule enzyme release when presented to permeabilized neutrophils. The stimulatory actions of these compounds occur in the absence of Ca2+ and are blocked by the sulfhydryl reducing agent, dithiothreitol. In addition, we observed marked potentiation of Ca2+-induced secretion by potentially physiological levels of Ni2+. Although we are unaware of any Ni2+-requiring enzymes in eukaryotic cells that are likely to be pertinent to degranulation, the ability of this divalent metal cation to lower the Ca2+ requirements for granule secretion suggests that it may play an important regulatory role in Ca2+-dependent processes. Finally, we observed significant granule release when permeabilized neutrophils were exposed to the heavy metal cations, Hg2+ and Ag+. The apparent stimulatory actions of these metals were the result of lysis rather than degranulation. Thus, the ability of these metals to lyse intracellular organelles such as lysosomal granules may contribute to their toxicological properties.

The effect of various stimuli and calcium antagonists on the fluorescence response of chlorotetracycline-loaded human neutrophils.

Chlorotetracycline has been used in neutrophils and other cells as probe of the state of membrane-bound calcium. We report here that human neutrophils treated with chlorotetracycline response to soluble secretagogues by a prompt decrease in chlorotetracycline fluorescence. This response was observed within 2-5 s, making it one of the most immediate reactions in neutrophils to stimulation, and was obtained with three secretagogues studied: a chemotactic peptide N-formyl-methionyl-leucyl-phenylalanine, a tumor promotor (phorbol myristate acetate) and a lectin (concanavalin A). The responses of neutrophils to the three stimuli differed both quantitatively and qualitatively. The calcium EGTA, did not effect the onset of the decrease in chlorotetracycline fluorescence, suggesting that the probe was measuring changes in intracellular calcium pools. The intracellular calcium antagonists, TMb-8, W-7 and trifluoperazine, did not block, but actually augmented, the fluorescence response. All four of these calcium antagonists blocked the recovery of chlorotetracycline fluorescence which was usually observed several minutes after stimulation with N-formyl-methionyl-leucyl-phenylalanine. This suggests that recovery was dependent upon both extracellular calcium and active calmodulin. The results are consistent with the hypothesis that changes in chlorotetracycline fluorescence reflect changes in a pool of membrane-bound 'trigger calcium', the release of which is an essential first step in stimulus-response coupling in human neutrophils.

Stimuli which provoke secretion of azurophil enzymes from human neutrophils induce increments in adenosine cyclic 3'-5'-monophosphate.

1. Stimuli for human neutrophils were divided into two classes on the basis of their ability to induce degranulation: complete secretagogues provoked release of both azurophil and specific granules, while incomplete secretagogues only induced release of specific granules. 2. Complete secretagogues, which possessed the ability to induce secretion of azurophil granules, also induced transient increments in total cellular cyclic AMP levels: incomplete secretagogues did not. 3. Complete secretagogues, unlike the incomplete variety, also induced further increments of cyclic AMP in prostaglandin E1-pretreated neutrophils. 4. Inhibition of lysosomal enzyme release by prostaglandin E1 was closely correlated with elevated levels of cyclic AMP induced by the prostaglandin alone, than with the much higher transient increment in cyclic AMP produced by stimulation of prostaglandin E1-treated cells. 5. Our results describe the first biochemical difference between neutrophil responses associated with secretion of azurophil granules, as opposed to specific granules: transient increments in cyclic AMP.

Mg2+-ATPase as a membrane ecto-enzyme of human granulocytes. Inhibitors, activators and response to phagocytosis.

(1) The Mg2+-ATPase of purified human granulocytes is located at the plasma membrane. Thus, no additional enzyme activity was detected when the cells were disrupted. Moreover, the Mg2+-ATPase activity of intact cells was inhibited by such poorly permeant reagents as diazotized sulfanilic acid and suramin. Finally, the enzyme activity of cell homogenates was recovered in particulate fractions. (2)The surface Mg2+-ATPase of human granulocytes had an apparent Km of 50 microns for ATP and displayed substrate inhibition. (3) The enzyme was not affected by ouabain, but was inhibited by N-ethyl malemide, sodium meta-periodate, suramin and diazotized sulfanilic acid. The enzyme was activated by cytochalasins B and D and by UDP. Activation by UDP was characterized by changes in the enzyme's apparent Km and V and by belief of substrate inhibition. (4)Internalization of surface membranes subsequent to phagocytosis of suitable particles did not result in depletion of Mg2+-ATPase from the cell surface. The enzyme activity did not decrease after exposure to several varieties of paraffin oil emulsion particles, even if the challenged cells had been pretreated with colchicine of cytochalasin B. (5) Since suramin, which inhibited Mg2+-ATPase, had no effect upon other granulocyte functions such as chemotaxis, superoxide anion generation, or phagocytosis, it is unlikely that the enzyme plays a major role in these functions.

The fluorescence response of chlorotetracycline-loaded human neutrophils. Correlations with lysosomal enzyme release and evidence for a 'trigger pool' of calcium.

Neutrophils labelled with chlorotetracycline (commonly employed as a probe for membrane-bound calcium), underwent rapid decreases in fluorescence upon exposure to N-formylmethionylleucylphenylalanine (more than 1 nM). This decrease was maximal at 1 min and was followed by partial recovery by 3 min. When neutrophils were stimulated with N-formylmethionylleucylphenylalanine and then re-exposed to the same stimulus 3 min later, an additional decrease in chlorotetracycline fluorescence was observed. The magnitude of this second response was inversely related to the concentration of the initial stimulus. Similarly, neutrophils exposed to N-formylmethionylleucylphenylalanine and then restimulated by N-formylmethionylleucylphenylalanine in the presence of cytochalasin B secreted the azurophil granule enzyme beta-glucuronidase; release of the enzyme was also inversely related to the initial concentration of N-formylmethionylleucylphenylalanine. These responses were also time-dependent. Both the second decrement in chlorotetracycline fluorescence and beta-glucuronidase release increased with time allowed between the two administrations of N-formylmethionylleucylphenylalanine. In contrast, decreases in chlorotetracycline fluorescence induced by phorbol myristate acetate showed no comparable recovery phase. When neutrophils, stimulated with phorbol myristate acetate, were then exposed to N-formylmethionylleucylphenylalanine, the second decrement in chlorotetracycline fluorescence diminished as the time allowed between the two stimuli was increased. Secretion of beta-glucuronidase in response to N-formylmethionylleucylphenylalanine was also diminished by increasing the time of exposure to the initial stimulus of phorbol myristate acetate. When N-formylmethionylleucylphenylalanine was used as the initial stimulus, the chlorotetracycline fluorescence response characteristic of phorbol myristate acetate could not be observed for at least 1 min. These results are consistent with the hypothesis that chlorotetracycline serves as a probe of mobilizable membrane-bound 'trigger calcium', a replete pool of which is an obligate requirement for lysosomal enzyme release.

Human neutrophils permeabilized with digitonin respond with lysosomal enzyme release when exposed to micromolar levels of free calcium.

We have recently reported that human neutrophils can be permeabilized with the cholesterol complexing agent saponin and that these cells can be induced to secrete the granule enzyme lysozyme in response to micromolar levels of free calcium. We now report that digitonin can be used in place of saponin and that it has several advantages. Permeabilization of human neutrophils was accomplished with 10 micrograms/ml digitonin in a high potassium medium. Normally impermeant solutes such as [14C]sucrose and inulin [14C]carboxylic acid gained access to one half of the intracellular water space marked with [3H]H2O. Between 30 and 100% of the cytoplasmic enzyme, lactate dehydrogenase, leaked from the intracellular space. The permeabilization process and calcium-triggered granule secretion were critically dependent upon temperature, time and digitonin concentration. Permeabilized neutrophils secreted beta-glucuronidase, lysozyme and vitamin B-12 binding-protein, constituents of both azurophil and specific granules, when exposed to micromolar levels of free calcium. Release of specific granule constituents appeared to be more sensitive to free calcium than release from azurophil granules. Although the amount of permeabilization varied considerably with each batch of cells, release of these granule markers was a consistent finding. Release of granule markers was accompanied by resealing of the cells to high-molecular-weight (Mr greater than 5000) solutes. Electron microscopic evidence also suggested that granule and plasma membranes were intact following digitonin treatment and that fusion of these membranes occurred in response to calcium. These results suggest that elevation of intracellular free-calcium levels is a sufficient condition for lysosomal enzyme release.

Calcium-dependent fusion of the plasma membrane fraction from human neutrophils with liposomes.

A cell-free assay monitoring lipid mixing was used to investigate the role of Ca2+ in neutrophil membrane-liposome fusion. Micromolar concentrations of Ca2+ were found to directly stimulate fusion of inside-out neutrophil plasma membrane enriched fractions (from neutrophils subjected to nitrogen cavitation) with liposomes (phosphatidylethanolamine:phosphatidic acid, 4:1 molar ratio). In contrast, right-side-out plasma membranes and granule membranes did not fuse with liposomes in the presence of Ca2+. Similar results were obtained with two different lipid mixing assays. Fusion of the neutrophil plasma membrane-enriched fraction with liposomes was dependent upon the concentration of Ca2+, with threshold and 50% maximal rate of fusion occurring at 2 microM and 50 microM, respectively. Furthermore, the fusion was highly specific for Ca2+; other divalent cations such as Ba2+, Mg2+ and Sr2+ promoted fusion only at millimolar concentrations. Red blood cell (RBC) membranes were used in control studies. Ca2(+)-dependent fusion did not occur between right-side-out or inside-out RBC-vesicles and liposomes. However, if the RBC-vesicles were exposed to conditions which depleted spectrin (i.e., low salt), then Ca2(+)-dependent fusion was detected. Other quantitative differences between neutrophil and RBC membranes were found; fusion of liposomes with RBC membranes was most readily achieved with La3+ while neutrophil membrane-liposome fusion was most readily obtained with Ca2+. Furthermore, GTP gamma S was found to enhance Ca2(+)-dependent fusion between liposomes and neutrophil plasma membranes, but not RBC membranes. These studies show that plasma membranes (enriched fractions) from neutrophils are readily capable of fusing with artificial lipid membranes in the presence of micromolar concentrations of Ca2+.

Changes in phosphatidylinositol and phosphatidic acid in stimulated human neutrophils. Relationship to calcium mobilization, aggregation and superoxide radical generation.

Human neutrophils aggregate and release mediators of inflammation, such as active oxygen species and lysosomal enzymes, when exposed to the chemoattractant, fMet-Leu-Phe, or the tumor promotor, phorbol myristate acetate. In order to 'stage' events which may lead to such neutrophil responses, we determined the temporal relationship between stimulus-induced changes in the endogenous phospholipids phosphatidylinositol (PI) and phosphatidic acid, the mobilization of calcium, and the onset of aggregation and generation of superoxide anion during the initial 2 min of cell activation. Within 5 s after addition of fMet-Leu-Phe (10(-7) M) neutrophils accumulated phosphatidic acid and the levels of PI decreased, as determined by two-dimensional thin-layer chromatography and phosphorus determinations. By 5 s, phosphatidic acid levels rose approximately 3.5-fold and at 15 s the loss of PI exceeded the quantity of phosphatidic acid generated. In response to phorbol myristate acetate (1 microgram/ml), however, changes in PI or phosphatidic acid were not observed until after 60 s. Accumulation of phosphatidic acid in fMet-Leu-Phe-stimulated cells was not inhibited by chelation of extracellular calcium. Neutrophils exposed to either fMet-Leu-Phe or phorbol myristate acetate also showed rapid decrements in fluorescence of cell-associated chlorotetracycline (used as an indirect probe of mobilization of intracellular membrane-associated calcium) and took up 45Ca2+ from the extracellular medium (under 60 s). The results indicate that changes in calcium mobilization, together with the alterations in phospholipid metabolism (under 5 s) anteceded aggregation and the generation of O2-. (10-15 s) induced by fMet-Leu-Phe. In contrast, when neutrophils were exposed to phorbol myristate acetate, changes in PI and phosphatidic acid (over 60 s) were observed after the mobilization of calcium (under 5 s) and the onset of O2-. generation and aggregation (30-35 s).

Protein kinase C is not involved in secretion by permeabilized human neutrophils.

The generally accepted sequence of intracellular signal transduction involves: (1) cell surface receptor-ligand interactions; (2) activation of G-proteins; (3) activation of phospholipase C, leading to inositol phosphate (IP3), and diacylglycerol production; (4) parallel mobilization of intracellular Ca2+ by IP3, and; (5) activation of protein kinase C (PKC) by diacylglycerol and Ca2+, leading to; (6) cellular responses. Human neutrophils appear to utilize this cascade, at least in general, and some, but not all, elements of the intracellular signal cascade known to be operating in intact cells also function in permeabilized cell systems. We have previously shown that permeabilized neutrophils can be induced to secrete lysosomal enzymes in response to elevated levels of Ca2+ alone and this secretion can be synergistically enhanced by the presence of guanine nucleotides. We now show that Ca2+, in the presence and absence of guanine nucleotides, can stimulate the production of soluble inositol phosphates. Furthermore, neomycin, a putative inhibitor of phospholipase C, can block Ca2(+)-induced secretion. These data thus suggest a role for phospholipase C activity or its products in the transduction process. The next enzymatic activity 'downstream' is PKC. Consequently, we looked at the role Mg-ATP, one of the substrates of PKC, plays in degranulation by permeabilized neutrophils, We found no obligatory role for this nucleotide in the secretory process. We then looked at the activity of oleoyl-acetyl-glycerol (OAG), a synthetic diacylglycerol and PKC agonist, on degranulation. We found that OAG was largely additive with Ca2+. Another PKC agonist, phorbol myristate acetate (PMA), also did not display notable synergy. Finally, inhibitors of PKC activity were not capable of blocking secretion, either in the presence or absence of guanine nucleotides. Thus, while circumstantial evidence seems to point towards a requirement for phospholipase C activation and diacylglycerol production in secretion, we were unable to demonstrate the next putative step in signal transduction, namely activation of PKC.

Cyclic AMP inhibits secretion from electroporated human neutrophils.

It has long been known that intracellular cAMP inhibits and cGMP enhances intact neutrophil function. However, these effects are modest and require relatively high concentrations of the cyclic nucleotides. We decided to re-examine the effects of cyclic nucleotides on Ca2(+)-induced secretion by electroporated cells. This system allowed us to bypass normal cell surface receptor-ligand interactions as well as to directly expose the intracellular space to native cyclic nucleotides. We found that concentrations of cAMP as low as 3 microM inhibited Ca2(+)-induced secretion; 30-300 microM cAMP was maximally inhibitory. cAMP was actually slightly more potent than dibutyryl cAMP, a membrane-permeant derivative. In contrast, cGMP was only slightly stimulatory at 3 microM and modestly inhibitory at 300 microM; dibutyryl cGMP was ineffective. A more detailed investigation of the effects of cAMP showed that inhibition was only obtained in the presence of Mg2+. Half-maximal inhibition by cAMP occurred at 10-30 microM. Inhibition by cAMP was achieved by shifting the Ca2+ dose-response curve for secretion to the right; this was observed for the release of both specific granules (vitamin B12 binding protein) and azurophil granules (B-glucuronidase). We previously showed that ATP could enhance Ca2(+)-induced secretion in the presence of Mg2+, apparently by interacting with a cell surface purine receptor. However, increasing concentrations of ATP could not overcome inhibition by cAMP; this suggested that cAMP acted at some site other than the purine receptor. Inhibition by cAMP was also less apparent in the presence of the protein kinase C agonist phorbol myristate acetate (PMA), suggesting that the cyclic nucleotide did not produce systemic desensitization of the neutrophils. In summary, these results demonstrate that low, physiologically relevant concentrations of cAMP can modulate neutrophil responsiveness.

The kinetics of secretion from permeabilized human neutrophils: release of elastase and correlations with other granule constituents and right angle light scatter.

We have previously reported that human neutrophils can be permeabilized with the cholesterol-complexing agent digitonin. These permeabilized cells can be induced to secrete lysosomal constituents when exposed to micromolar levels of free Ca2+, a process that is enhanced by certain guanine nucleotides. We examined the kinetics in this system by employing both direct and indirect measures of secretion. A continuous, fluorescent assay of elastase permits real-time monitoring of secretion from azurophil granules. The kinetics of elastase release proved to be rapid, beginning within 3-10 sec and reaching a maximum at 1-2 min. Changes in the Ca2+ concentration did not affect the "lag period" for release. A comparison of the Ca2+ dose-response curves for release of the various granule constituents indicated that elastase was being secreted along with other contents of the azurophil granules. Changes in right angle light scatter (RLS), which have been shown to correlate closely with secretion, also commenced rapidly after the addition of Ca2+; when measured simultaneously, both the Ca2+ dose-response characteristics for changes in RLS and elastase release were very similar. Changes in RLS could be halted within 5 sec by excess EGTA and restarted promptly by repletion with secretory concentrations of Ca2+. In addition, neomycin, a phospholipase C inhibitor, profoundly diminished degranulation as monitored by RLS and end-point techniques. A continuous assay employing 9-aminoacridine self-quenching as a measure of secretion proved far less satisfactory, but, nonetheless, produced similar kinetics and dose-response characteristics.(ABSTRACT TRUNCATED AT 250 WORDS)

PLA2 promotes fusion between PMN-specific granules and complex liposomes.

Neutrophil stimulation results in the activation of a variety of phospholipases, including phospholipase A2 (PLA2), which releases arachidonic acid from the 2 position of membrane phospholipids, leaving a lysophospholipid. Because arachidonic acid is known to be a potent fusogen in vitro, we examined the effect of metabolism by PLA2 on the fusion of complex liposomes (liposomes prepared with a phospholipid composition similar to that found in neutrophil plasma membrane). We observed that PLA2 augmented the fusion of complex liposomes with each other as well as with specific granules isolated from human neutrophils, lowering the Ca2+ requirement for fusion by three orders of magnitude. Furthermore, although lysophospholipids inhibited fusion, the incorporation of arachidonic acid into liposome membranes overcame the inhibitory effects of the lysophospholipids. Thus with PLA2 and annexins we were able to obtain fusion of complex liposomes at concentrations of Ca2+ that are close to physiological. Our data suggest that the activation of PLA2 and the generation of arachidonic acid may be the major fusion-promoting event mediating neutrophil degranulation.

Identification of glyceraldehyde-3-phosphate dehydrogenase as a Ca2+-dependent fusogen in human neutrophil cytosol.

The membrane fusion events observed during neutrophil degranulation are important aspects of the immunoregulatory system. In an attempt to understand the regulation of granule-plasma membrane fusion, we have begun characterizing human neutrophil cytosol for fusion activity, finding that 50% of the fusogenic activity could be attributed to members of the annexin family of proteins. The major non-annexin fusion activity (25% of the total cytosolic activity) was enriched by ion exchange chromatography after depletion of annexins by Ca2+-dependent phospholipid affinity chromatography. The fusion activity co-purified with a 10,14-kDa dimer identified as leukocyte L1 (which was non-fusogenic), along with an approximately 36-kDa protein. This protein was identified as glyceraldehyde-3-phosphate dehydrogenase (GAPDH) by amino-terminal sequencing, and the fusion activity was verified using commercially available GAPDH. GAPDH may play an important role in degranulation because it is as potent as annexin I on a mass basis and may constitute up to 25% of the total cytosolic fusion activity of the neutrophil.

Polymorphonuclear leukocytes as secretory organs of inflammation.

Polymorphonuclear (PMN) leukocytes mediate that phase of inflammation at which vascular responses become translated into tissue injury. After phagocytosis, the PMN leukocyte generates derivatives of molecular oxygen (O2-.,OH., and H2O2) that stimulate a metabolic burst and assist in the killing of microorganisms. They also release oxidation products of membrane fatty acids (e.g., arachidonate), which are detected as thromboxanes and protaglandins. After interaction of phagocytic ligands (immune complexes and C3b-opsonized particles), the PMN leukocyte secretes lysosomal enzymes from open phagocytic vacuoles, and, especially when phagocytosis is blocked by cytochalasin B, secretes them directly into the cell's surrounding fluids. Secretion is enhanced by agents that elevate intracellular levels of cyclic GMP, and inhibited by agents that raise cyclic AMP. These reciprocal changes are associated with assembly and disassembly (respectively) of cytoplasmic microtubules. These cytoskeletal structures, together with contractile elements, regulate in part the secretory events of inflammation in which lysosomal constituents (e.g., elastase, collagenase, and cathepsin G) are diverted from their intracellular depots to an inappropriate assault on the tissues of the host.