Auranofin affects early events in human polymorphonuclear neutrophil activation by receptor-mediated stimuli

Auranofin, a new oral antirheumatic gold compound, in concentrations achieved therapeutically, inhibits neutrophil phagocytosis, chemotaxis, chemiluminescence, reduction of cytochrome c, and release of lysosomal enzymes. To further characterize the mechanism by which auranofin affects neutrophils, we studied the effects of auranofin on unstimulated properties and functions of neutrophils as well as on rapidly stimulated functions. When examined by electron microscopy, 4 micrograms/ml of auranofin significantly decreased the number of visualized centriole-associated microtubules in resting cells. Furthermore, auranofin inhibited neutrophil spreading on glass and caused a decrease in negative surface charge (electrophoretic mobility). In addition, auranofin inhibited several fmet-leu-phe-stimulated responses such as shape change, increases in centriole-associated microtubules, decreases in surface charge, and elicited membrane potential changes (di-O-C5(3) dye response). Auranofin (1 micrograms/ml) inhibited fmet-leu-phe-stimulated superoxide and hydrogen peroxide production by 80% (p less than 0.05), and also increased the affinity of receptors for fmet-leu-phe (from Ka 0.035 to Ka 0.48, p less than 0.001). Auranofin also affected neutrophil responses to phorbol myristic acetate (PMA). The total amount of PMA-stimulated superoxide production was suppressed by as little as 0.4 micrograms/ml of auranofin, but the lag time for activation was shortened by low concentrations of auranofin (0.5 to 1 microgram/ml). Four micrograms per milliliter of auranofin suppressed the decrease in surface charge induced by PMA. However, auranofin did not influence superoxide production elicited by the ionophore A23187. The results indicate that auranofin affects the earliest detected responses in neutrophil activation by certain receptor-mediated stimuli.     

Calcium modulation and chemotactic response: divergent stimulation of neutrophil chemotaxis and cytosolic calcium response by the chemotactic peptide receptor

Stimulation of neutrophils by chemoattractants is followed by a rapid, transient rise in cytosolic calcium concentration. The role of calcium in activation of cell movement and related responses was examined by selectively chelating extracellular or both extra- and intracellular calcium. Removal of calcium from the extracellular medium did not alter the cytosolic calcium concentration (Quin 2 fluorescence, 110 to 120 nM) of unstimulated neutrophils and did not dramatically affect the rise induced by formyl peptide. Despite the intact Quin 2 response, depletion of extracellular calcium partially inhibited chemotaxis, adherence to substrate, and polarization (increased forward light scatter) in response to formyl peptide. Loading neutrophils with Quin 2 in the absence of calcium depressed cytosolic Ca2+ to 10 to 20 nM and abrogated a detectable rise with formyl peptide stimulation. Depletion of intracellular calcium further inhibited chemotaxis and polarization, although neutrophils still demonstrated significant directed migration and shape change to formyl peptide (30 to 40% of control) without an increase in Quin 2 fluorescence. Other neutrophil responses related to chemotaxis (decreased right-angle light scatter, actin polymerization) were minimally affected by depletion of calcium from either site. The data indicate that neutrophil chemotaxis and related responses to formyl peptide may be activated by intracellular signals not detectable with Quin 2.     

The involvement of calcium and protein kinase C in modulating agonist-stimulated chemotaxis of human neutrophils

Chemotaxis of human neutrophils in response to a gradient of the chemotactic peptide, fmet-leu-phe (FMLP), was measured by the under-agarose technique. The dose-response curve for FMLP was biphasic; low concentrations were stimulatory, and the response was reduced at higher concentrations. The response to FMLP was partially inhibited (about 50%) in the absence of extracellular Ca2 (EGTA added). NiCl2 dose-dependently inhibited FMLP-stimulated chemotaxis in the presence of extracellular Ca2+; the maximum inhibition obtainable with NiCl2 was similar to that with the absence of extracellular Ca2+. These results suggest that FMLP-stimulated chemotaxis is, at least partially, dependent on stimulation of Ca2+ influx. The phorbol ester, PMA, dose-dependently inhibited chemotaxis; the response was almost completely inhibited by 10 nM PMA. This result indicates that activation of protein kinase C inhibits chemotaxis. These results are discussed in relation to the physiological responses of neutrophils.     

IgE receptor-mediated hydrolysis of phosphoinositides by cytoplasts from rat basophilic leukemia cells

Cytoplasts (plasma membrane sacs containing cytoplasm, endoplasmic reticulum, and few organelles) were prepared from rat basophilic leukemia cells by treatment with cytochalasin B and centrifugation at 33 degrees C through stepwise gradients of Ficoll. To compare the relative ability of cytoplasts and cells to generate second-messengers (inositol phosphates, Ca2+) in response to stimulation of the high affinity receptor for IgE, we normalized our results per recovered receptor by using the tightly bound IgE as a marker. This marker correlated well with other estimates of plasma membrane recovery. Furthermore, data normalized on this basis correlated well with data expressed as percentage of phosphoinositides hydrolyzed. The purest fraction of cytoplasts (containing about 6% of the receptors) was satisfactorily devoid of organelles and, at early times, generated about 50% as much inositol phosphates per receptor as did the intact, untreated cells. This response of the cytoplasts, like that of the cells, was totally dependent upon aggregation of the receptors. The response by the cytoplasts (in the 5-min time frame which we examined), unlike that of the cells, was not enhanced by the presence of extracellular Ca2+. Furthermore, unlike the cells, the cytoplasts failed to raise their intracellular free Ca2+ levels after addition of polyvalent Ag. This result suggests that aggregation of the receptors may be insufficient, by itself, to open the normal Ca2+ channels.     

Neutrophil chemotaxis and superoxide production are induced by cross-linking FcgammaRII receptors

Neutrophils express two types of receptor for the Fc region of IgG, FcgammaRII and FcgammaRIIIB. Via these receptors, neutrophils bind IgG complexes that contain more than one IgG molecule. This binding activates functional processes, such as the respiratory burst and chemotaxis. Neutrophils were treated with biotinylated anti-Fc receptor monoclonal antibodies and chemotaxis toward streptavidin, a cross-linking agent, was determined. Cross-linking FcgammaRII and not FcgammaRIIIB induced neutrophil chemotaxis. Superoxide production in response to immobilized anti-Fc receptor antibodies was also examined. Anti-FcgammaRII Fab bound to ELISA plates induced superoxide production, while anti-FcgammaRIIIB Fab did not. Pretreatment of neutrophils with anti-FcgammaRII Fab reduced superoxide generated by immobilized anti-FcgammaRII antibody. The data demonstrate that FcgammaRII and not FcgammaRIIIB are responsible for neutrophil chemotaxis and superoxide production upon Fc receptor activation.     

Temporal adaptation of human neutrophil metabolic responsiveness to the peptide formylmethionyl-leucyl phenylalanine: a comparison between human neutrophils and granule-depleted neutrophil cytoplasts

When polymorphonuclear leukocytes (neutrophils) and soluble or particulate matter interact, the cells produce superoxide anions (O2-) and hydrogen peroxide (H2O2). The chemotactic peptide formylmethionyl-leucyl-phenylalanine (FMLP) induced a very weak response in normal neutrophils. The cellular response was changed, however, as a result of in vitro aging of the cells, i.e. the magnitude of the response was increased following storage of the cells at 22 degrees C for up to 120 min, in the absence of any stimulus, and before the addition of the peptide. When phorbol myristate acetate was used as a stimulus, there was a pronounced production of O2- and H2O2, but no change in magnitude as a result of in vitro aging. When neutrophil cytoplasts (granule-free vesicles of cytoplasm enclosed by plasmalemma) were exposed to the peptide FMLP of PMA, the vesicles produced both O2- and H2O2. There was, however, no increase in oxidative metabolite production in cytoplasts as a result of in vitro aging when either FMLP or PMA was used as a stimulus. The results thus indicate that mere incubation at room temperature primed the cells to increase their production of oxidative metabolites as a result of spontaneous exposure of hidden receptors. The fact that no such effects were observed with cytoplasts indicates that spontaneous receptor recruitment is a granule-dependent process.     

Evidence for distinct intracellular pools of receptors for C3b and C3bi in human neutrophils

In this report, the modulation and localization of complement receptors CR1 and CR3 in neutrophils were examined with the use of monoclonal antibodies (mab) directed against these membrane proteins. We first studied complement receptor modulation in a patient with neutrophil-specific granule deficiency. With flow cytometric analysis, we determined that, while N-formyl-methionyl-leucyl-phenylalanine (f-met-leu-phe) (10(-6) M) caused an increase in the binding of both anti-CR1 and anti-CR3 mab to normal neutrophils, the fmet-leu-phe-stimulated neutrophils from our patient increased anti-CR1 binding but decreased anti-CR3 binding. This suggested that CR3, but not CR1, might be associated with specific granules. We next studied receptor modulation in organelle-depleted neutrophil cytoplasts obtained from normal donors. Unlike the specific granule-deficient neutrophils, the normal cytoplasts failed to augment expression of either receptor after stimulation. Immunofluorescence studies of permeabilized polymorphonuclear leukocytes (PMN) revealed considerable internal binding of both anti-CR1 and anti-CR3. In additional studies, phorbol myristate acetate (PMA) was used as a stimulus for receptor modulation in normal neutrophils. Unlike fmet-leu-phe and C5a, PMA elicited a biphasic dose-response curve. High doses of PMA (greater than 0.5 ng/ml) caused a reduction in the magnitude of membrane expression of both CR1 and CR3. In studies designed to localize the internal pool of receptors, we evaluated the binding of 125I-anti-receptor mab to plasma membrane-, specific granule, and azurophilic granule-enriched fractions obtained from sucrose gradient fractionation of disrupted neutrophils. 125I-anti-CR1 mab bound to the membrane-enriched fraction but bound little to either granule-enriched fraction. In contrast, 125I-anti-CR3 mab bound more to the specific granule-enriched fraction than to the plasma membrane-enriched fraction. Azurophilic granules showed no increased anti-CR3 binding. Immunoprecipitation of radiolabeled solubilized subcellular fractions with anti-receptor mab confirmed these findings. CR3 was present in the plasma membrane-, and specific granule-enriched fraction but not in the azurophilic granule-enriched fraction. CR1, however, was present only in the plasma membrane-enriched fraction. These data indicate that there are intracellular pools for both the CR1 and CR3, but the intracellular locations for these pools are distinct. The pool for CR3 co-sediments with specific granules, while the pool for CR1 does not. Nonetheless, a variety of stimulatory agents increase and decrease the membrane expression of both receptors in parallel.     

Dynamics of a chemoattractant receptor in living neutrophils during chemotaxis

Persistent directional movement of neutrophils in shallow chemotactic gradients raises the possibility that cells can increase their sensitivity to the chemotactic signal at the front, relative to the back. Redistribution of chemoattractant receptors to the anterior pole of a polarized neutrophil could impose asymmetric sensitivity by increasing the relative strength of detected signals at the cell's leading edge. Previous experiments have produced contradictory observations with respect to receptor location in moving neutrophils. To visualize a chemoattractant receptor directly during chemotaxis, we expressed a green fluorescent protein (GFP)-tagged receptor for a complement component, C5a, in a leukemia cell line, PLB-985. Differentiated PLB-985 cells, like neutrophils, adhere, spread, and polarize in response to a uniform concentration of chemoattractant, and orient and crawl toward a micropipette containing chemoattractant. Recorded in living cells, fluorescence of the tagged receptor, C5aR-GFP, shows no apparent increase anywhere on the plasma membrane of polarized and moving cells, even at the leading edge. During chemotaxis, however, some cells do exhibit increased amounts of highly folded plasma membrane at the leading edge, as detected by a fluorescent probe for membrane lipids; this is accompanied by an apparent increase of C5aR-GFP fluorescence, which is directly proportional to the accumulation of plasma membrane. Thus neutrophils do not actively concentrate chemoattractant receptors at the leading edge during chemotaxis, although asymmetrical distribution of membrane may enrich receptor number, relative to adjacent cytoplasmic volume, at the anterior pole of some polarized cells. This enrichment could help to maintain persistent migration in a shallow gradient of chemoattractant.     

A phospholipase A2-activating protein (PLAP) stimulates human neutrophil aggregation and release of lysosomal enzymes, superoxide, and eicosanoids

We have recently isolated a human phospholipase A2-activating protein (PLAP) that shares antigenic and biochemical similarities with melittin, a well characterized bee venom phospholipase-stimulatory peptide. To explore the potential mechanisms of action of PLAP that extend beyond its effects on eicosanoid synthesis, we examined its effects on the release of human neutrophil lysosomal enzymes and superoxide, and on RBC hemolysis. These results were compared to the effects of melittin, which has been reported to induce enzyme release and hemolysis. We also examined the effects of PLAP on neutrophil aggregation and chemotaxis. PLAP induced neutrophils to release beta-glucuronidase and metalloproteinase enzyme activities as well as produce superoxide ion in both a dose- and time-dependent manner. Eicosanoid synthesis inhibitors did not abrogate these responses. PLAP induced release of arachidonic acid metabolites, but this response could be abrogated by eicosanoid synthesis inhibitors. PLAP also induced neutrophil aggregation and chemokinesis, but not chemotaxis. Concentrations of PLAP that induced these responses did not induce cellular toxicity as determined by light and electron microscopy, lactic dehydrogenase release, trypan blue dye exclusion, and RBC hemolysis. In contrast, prolonged incubation with higher concentrations of PLAP induced cell death that was similar to that observed with melittin. These findings suggest that the mechanisms of action of PLAP extend beyond the eicosanoid synthetic pathway, and that disordered regulation of PLAP may be responsible, at least in part, for chronic immune and inflammatory states.     

Human recombinant interleukin 1 beta has no effect on intracellular calcium or on functional responses of human neutrophils

The effect of human recombinant interleukin 1 beta (rIL 1 beta) on human neutrophils was examined. rIL 1 beta, even at concentrations of 100 ng/ml (100 half-maximal T cell stimulating U/ml) did not change significantly the intracellular free calcium concentration, [Ca++]i, whereas the control stimulus, fmet-leu-phe, significantly elevated [Ca++]i. rIL 1 beta also failed to stimulate production of superoxide, degranulation of lysosomal enzymes, phagocytosis of bacterial particles, chemotaxis, or chemokinesis of human neutrophils. This is substantial evidence that superphysiologic concentrations of interleukin 1 have no direct effect on [Ca++]i, as well as on functional responses of neutrophils.     

Human neutrophil Fc gamma RIIIB and formyl peptide receptors are functionally linked during formyl-methionyl-leucyl-phenylalanine-induced chemotaxis.

The formyl peptide receptor (FPR) and the glycosyl-phosphatidylinositol-linked type III receptor for the Fc portion of IgG (Fc gamma RIIIB; CD16) play important roles in various inflammatory responses in human neutrophils. The mechanisms of signaling by the glycosyl phosphatidylinositol-anchored Fc gamma RIIIB are not known. Therefore, we investigated the possibility that Fc gamma RIIIB and FPR may act in concert to mediate neutrophil functions. We observed that pretreatment of normal human neutrophils with Fab fragments of a mAb to the Fc gamma RIII (3G8) specifically inhibited their chemotaxis into micropore filters in response to the formylated peptides FMLP or formyl-norleucyl-leucyl-phenylalanine. Pretreatment of neutrophils with a saturating concentration of 3G8 Fab (100 nM or 5 micrograms/ml) followed by exposure to FMLP (0.5 to 500 nM) indicated that significant inhibition of chemotaxis was observed at peptide concentrations greater than 5 nM. However, 3G8 Fab had no effect on the neutrophil response to a wide range (0.05 to 500 nM) of other chemotactic factors, including C5a, leukotriene B4, IL-8 (neutrophil-activating peptide-1), and platelet-activating factor. Moreover, pretreatment of neutrophils with mAb to other cell surface molecules (decay-accelerating factor, Fc gamma RII, and HLA class I) did not affect chemotaxis to FMLP. Inhibition of movement was not due to degradation of FMLP by the cell surface endopeptidase 24.11 (CD10), because neutrophils pretreated with the CD10 inhibitor phosphoramidone and 3G8 Fab displayed the same altered response to FMLP as cells pretreated with 3G8 Fab alone. Ligation of the Fc binding site of Fc gamma RIIIB appears to be essential for altering the FMLP-induced response, since soluble aggregated IgG and other anti-Fc gamma RIII antibodies, all of which recognize the ligand binding site, mimic the inhibitory effect of the 3G8 Fab on FMLP-induced chemotaxis. In contrast, a mAb (214.1) that does not recognize the Fc binding site of Fc gamma RIIIB had no effect on FMLP-induced chemotaxis. Not only did anti-Fc gamma RIII inhibit neutrophil chemotaxis to FMLP in a filter-based migration assay, but 3G8 Fab also inhibited FMLP-induced neutrophil transendothelial migration. Scatchard plot analysis of radioligand binding experiments indicated that 3G8 Fab did not significantly alter the number of FMLP binding sites on neutrophils but significantly increased the affinity of the FPR for [3H]FMLP. Removal of greater than 80% of cell surface Fc gamma RIIIB by phospholipase C abolished the neutrophil chemotactic response to FMLP but did not affect movement toward C5a, IL-8, or leukotriene B4.(ABSTRACT TRUNCATED AT 400 WORDS)     

Universal Response-Adaptation Relation in Bacterial Chemotaxis

The bacterial strategy of chemotaxis relies on temporal comparisons of chemical concentrations, where the probability of maintaining the current direction of swimming is modulated by changes in stimulation experienced during the recent past. A short-term memory required for such comparisons is provided by the adaptation system, which operates through the activity-dependent methylation of chemotaxis receptors. Previous theoretical studies have suggested that efficient navigation in gradients requires a well-defined adaptation rate, because the memory time scale needs to match the duration of straight runs made by bacteria. Here we demonstrate that the chemotaxis pathway of Escherichia coli does indeed exhibit a universal relation between the response magnitude and adaptation time which does not depend on the type of chemical ligand. Our results suggest that this alignment of adaptation rates for different ligands is achieved through cooperative interactions among chemoreceptors rather than through fine-tuning of methylation rates for individual receptors. This observation illustrates a yet-unrecognized function of receptor clustering in bacterial chemotaxis.     

Cellular cytotoxicity mediated by granule-depleted neutrophil cytoplasts

Neutrophil-derived nucleus-and granule-free cytoplasts, consisting of cytosol enclosed by an intact plasma membrane, were able to destroy 51Cr-labelled ox red blood cells (ORBC) in the presence of phorbol myristate acetate (PMA). The slope of the target cell lysis vs the log of the cytoplast number was similar to that observed with neutrophils as effector cells. Nevertheless, a number of cytoplasts 60-80 times higher than that of neutrophils was required to obtain a common level of cytotoxicity. The ability of cytoplasts and neutrophils to lyse ORBC was completely abolished by catalase and unaffected by superoxide dismutase and mannitol, suggesting the involvement of hydrogen peroxide in the target cell damage. Addition of myeloperoxidase (MPO) to cytoplasts increased lysis. The MPO lysis by cytoplasts, except when experiments were carried out in the presence of MPO. The results indicate that neutrophil cytosol and plasma membrane represent the basic requirement for the PMA-dependent cytolytic process, whereas MPO behaves as a device to amplify lysis.     

Chemotactic response of human neutrophils to N-acetyl chitohexaose in vitro

N-Acetyl chitohexaose (NACOS-6) was able to display chemotactic response of human neutrophils in vitro. In order to analyze the mechanism, a series of chemotaxis studies by means of neutrophils treated with inhibitors of phospholipase A2, cyclooxygenase, or lipoxygenase to NACOS-6 was conducted. The treatment of neutrophils with inhibitors of phospholipase A2 or cyclooxygenase resulted in decrease of number of migrated cells. However, the lipoxygenase inhibitors did not exhibit the same effect. On the other hand, the treatment of neutrophils with inhibitors of phospholipase A2 or lipoxygenase resulted in decrease of chemotactic response to Formyl-Met-Leu-Phe (FMLP), although the cyclooxygenase inhibitors did not inhibit chemotaxis of neutrophils. Neutrophils added to exogenous prostaglandin E2 (PGE2) caused an enhanced chemotactic response to NACOS-6. These results indicate that the mechanism of chemotactic response to NACOS-6 was different from that of FMLP, and that the response was enhanced by PGE2 released from the neutrophils with stimulation of NACOS-6.     

N-formylpeptide-receptor dynamics, cytoskeletal activation, and intracellular calcium response in human neutrophil cytoplasts

Cytoplasts (enucleated neutrophils which are depleted of dense granules) were prepared from human neutrophils with a modified procedure which employed dihydrocytochalasin B instead of cytochalasin B. These cytoplasts retained an activatable cytoskeletal network similar to cells in that filamentous actin polymerization in response to an N-formylpeptide (fluoresceinated N-formyl-nle-leu-phe-nle-tyr-lys, FLPEP) occurred with similar dose-response characteristics and was inhibitable by cytochalasin B and dihydrocytochalasin B. Cytoplasts had the same number of receptors per surface area as cells and binding constants and dissociation kinetics were the same for cells and cytoplasts. The conversion of receptors from a rapidly dissociating form to a slowly dissociating form was comparable in cells and cytoplasts. This conversion was not inhibited by cytochalasins and thus did not require actin polymerization. Cytoplasts were capable of internalizing 30% of bound FLPEP after 3 min of binding. Cytochalasins did not block this internalization which thus did not appear to require actin polymerization. After 5 min of binding, [3H]-N-formyl-met-leu-phe cosedimented with the Golgi marker enzymes when cytoplasts were fractionated on sucrose density gradients after N2 cavitation. These results indicate that the internalization mechanism is functional in cytoplasts. The Indo-1-detectable calcium response in cytoplasts had a ED50 similar to cells, though the maximum increase in Ca2+ concentration was about one-half that of cells. The response recovered with time after stimulation and the calcium detected was primarily from intracellular stores. The decay of responses after addition of formylpeptide antagonists was parallel for cells and cytoplasts, and leukotriene B4-induced responses in both cells and cytoplasts. Thus the regulation of the responses in cells and cytoplasts was analogous.     

Helicobacter felis does not stimulate human neutrophil oxidative burst in contrast to 'Gastrospirillum hominis' and Helicobacter pylori

Helicobacter pylori is a human pathogen, whereas the natural hosts for 'Gastrospirillum hominis' and Helicobacter felis are animals. 'G. hominis' is occasionally found to cause infection in humans, whereas H. felis only rarely infects humans. The pathogenesis of H. pylori infection is not completely understood and in order to reveal differences in immune response to the three Helicobacter species, the upregulation of adherence molecule CD11b/CD18, chemotactic activity and oxidative burst response of neutrophils after stimulation with H. pylori, 'G. hominis' and H. felis sonicates, were compared. Like H. pylori, 'G. hominis' and H. felis induced upregulation of CD11b/CD18 and chemotaxis of neutrophils. 'G. hominis' demonstrated a more pronounced upregulation of CD11b/CD18, whereas H. felis was the strongest stimulant of neutrophil chemotaxis. H. felis was unable to stimulate neutrophils to oxidative burst response, whereas 'G. hominis' activated neutrophils in a dose-dependent way similar to H. pylori. 'G. hominis' and H. felis were both able to prime neutrophils for oxidative burst response similar to H. pylori. In conclusion, we observed clear differences in neutrophil responses to different Helicobacter species, which indicates that bacterial virulence factors may be important for the diversity in the pathogenetic outcome of Helicobacter infections.     

Chemotaxis and calcium responses of phagocytes to formyl peptide receptor ligands is differentially regulated by cyclic ADP ribose

Cyclic ADP ribose (cADPR) is a calcium-mobilizing metabolite that regulates intracellular calcium release and extracellular calcium influx. Although the role of cADPR in modulating calcium mobilization has been extensively examined, its potential role in regulating immunologic responses is less well understood. We previously reported that cADPR, produced by the ADP-ribosyl cyclase, CD38, controls calcium influx and chemotaxis of murine neutrophils responding to fMLF, a peptide agonist for two chemoattractant receptor subtypes, formyl peptide receptor and formyl peptide receptor-like 1. In this study, we examine whether cADPR is required for chemotaxis of human monocytes and neutrophils to a diverse array of chemoattractants. We found that a cADPR antagonist and a CD38 substrate analogue inhibited the chemotaxis of human phagocytic cells to a number of formyl peptide receptor-like 1-specific ligands but had no effect on the chemotactic response of these cells to ligands selective for formyl peptide receptor. In addition, we show that the cADPR antagonist blocks the chemotaxis of human monocytes to CXCR4, CCR1, and CCR5 ligands. In all cases, we found that cADPR modulates intracellular free calcium levels in cells activated by chemokines that induce extracellular calcium influx in the apparent absence of significant intracellular calcium release. Thus, cADPR regulates calcium signaling of a discrete subset of chemoattractant receptors expressed by human leukocytes. Since many of the chemoattractant receptors regulated by cADPR bind to ligands that are associated with clinical pathology, cADPR and CD38 represent novel drug targets with potential application in chronic inflammatory and neurodegenerative disease.     

Neutrophil activation detected by monoclonal antibodies

Monoclonal antibodies have been produced against three neutrophil-associated membrane proteins (p 90, p 170, and p 70) expressed at different maturation stages of the cells. The reactivity of the antibodies against p 90 (B13.9) and p 170 (CLB-gran 10), as measured by quantitative flow cytofluorometry, increased after stimulation of the neutrophils by the calcium ionophore A23187, by phorbol myristate acetate, or by the chemoattractant formylmethionyl-leucyl-phenylalanine in combination with cytochalasin B. This increase is regulated independently of the simultaneously increased expression of the C3bi receptor, because neutrophils of a patient deficient for the C3bi receptor showed a normal increase in membrane expression of p 90 and p 170. Neutrophil cytoplasts were not inducible to increased membrane expression, suggesting that the cytoplasts lack the internal pool of these proteins. The reactivity of the antibody against p 70 (CLB-gram 5) was not affected by activation. The antibodies B13.9 and CLB-gran 10 may be useful to detect neutrophil activation.     

The receptor for urokinase regulates TLR2 mediated inflammatory responses in neutrophils

The urokinase-type plasminogen activator receptor (uPAR), a glycosylphosphatidylinositol (GPI) anchored membrane protein, regulates urokinase (uPA) protease activity, chemotaxis, cell-cell interactions, and phagocytosis of apoptotic cells. uPAR expression is increased in cytokine or bacteria activated cell populations, including macrophages and monocytes. However, it is unclear if uPAR has direct involvement in the response of inflammatory cells, such as neutrophils and macrophages, to Toll like receptor (TLR) stimulation. In this study, we found that uPAR is required for optimal neutrophil activation after TLR2, but not TLR4 stimulation. We found that the expression of TNF-α and IL-6 induced by TLR2 engagement in uPAR-/- neutrophils was less than that in uPAR+/+ (WT) neutrophils. Pretreatment of neutrophils with PI-PLC, which cleaves GPI moieties, significantly decreased TLR2 induced expression of TNF-α in WT neutrophils, but demonstrated only marginal effects on TNF-α expression in PAM treated uPAR-/- neutrophils. IκB-α degradation and NF-κB activation were not different in uPAR-/- or WT neutrophils after TLR2 stimulation. However, uPAR is required for optimal p38 MAPK activation after TLR2 engagement. Consistent with the in vitro findings that uPAR modulates TLR2 engagement induced neutrophil activation, we found that pulmonary and systemic inflammation induced by TLR2, but not TLR4 stimulation is reduced in uPAR-/- mice compared to WT counterparts. Therefore, our data suggest that neutrophil associated uPAR could be a potential target for treating acute inflammation, sepsis, and organ injury related to severe bacterial and other microbial infections in which TLR2 engagement plays a major role.     

The anti-infective peptide, innate defense-regulator peptide, stimulates neutrophil chemotaxis via a formyl peptide receptor

The anti-infective peptide, innate defense-regulator peptide (IDR-1), has been selectively reported to modulate the innate immune response. We found that IDR-1 stimulates the chemotactic migration in human neutrophils. Moreover, IDR-1-induced neutrophil chemotaxis was completely blocked by pertussis toxin, suggesting the importance of the G_i protein in this process. The mechanism governing the IDR-1-induced neutrophil chemotaxis was found to be completely inhibited by the formyl peptide receptor (FPR) antagonist; cyclosporin H. IDR-1 was also found to induce chemotactic migration in FPR but not in vector-expressing HCT116 cells. Meanwhile, IDR-1 failed to stimulate superoxide anion generation and intracellular calcium increase in human neutrophils. Furthermore, IDR-1 was found to inhibit fMLF (an FPR agonist)-induced superoxide generation and calcium signaling in human neutrophils and FPR-expressing HCT116 cells. Taken together, the results demonstrate that IDR-1 is a partial agonist for FPR and further, stimulates neutrophil chemotaxis without inducing calcium signaling and superoxide generation.