Regulation of the oxidative response of human granulocytes to chemoattractants. No evidence for stimulated traffic of redox enzymes between endo and plasma membranes

Experiments were performed to probe the role of exocytotic and endocytotic processes in the regulation of the human granulocyte O-2-generating system. Analytical subcellular fractionation studies indicated that 25-30% of the total cellular b-cytochrome and 8-10% of the flavin co-sedimented with plasma membrane markers, irrespective of stimulation of the cells by the chemoattractants N-formyl-Met-Leu-Phe (FMLP) or C5a. Phorbol myristate acetate stimulation resulted in significant translocation of b-cytochrome but not flavin from the specific granule/Golgi to the plasma membrane-enriched fractions. These results indicated that approximately 3.1 X 10(5) flavin and 0.8-1 X 10(6) b-cytochrome molecules are present in the plasma membrane of an isolated unstimulated human granulocyte and that these levels are invariant upon stimulation with chemoattractants. Maximal instantaneous rates of O-2 generation by cells in these preparations, however, were equivalent for all the stimuli. Since stimulation of granulocytes by phorbol myristate acetate, FMLP, or C5a results in exocytosis and/or endocytosis, then the role of these processes in regulating stimulated O-2 production by controlling the content of plasma membrane redox enzymes is questionable. This conclusion was supported by observations made with cytoplasts, which do not have an intracellular reserve of granules. Cytoplasts prepared from granulocytes produced O-2 at equivalent rates as their parent cells on a per unit surface area basis. These results suggest: 1) that stimulation of granulocytes with chemotactic peptides leads to full generation of O-2 at the cell surface without exocytotic recruitment of additional b-cytochrome and flavoprotein from the cytoplasmic compartment; 2) that these redox enzymes are not internalized along with chemoattractant receptors; and 3) that traffic of these redox enzymes between endo- and plasma membranes is not involved in the regulation of O-2 production in suspensions of human granulocytes stimulated by chemoattractants.     

Association of rap1 and rap2 proteins with the specific granules of human neutrophils. Translocation to the plasma membrane during cell activation.

Activation of human neutrophils involves the degranulation of specific and azurophil granules. This process is GTP-dependent and the presence of small GTP-binding proteins (SGBPs) has been detected in the two granule populations. At present, none of these SGBPs has been definitely identified. In order to characterize some of these proteins and obtain further insights as to their potential role in degranulation processes, we have used specific antibodies directed against the ras-related rap1 and rap2 proteins. By immunoblot analysis, we observed that rap2p is predominantly located in specific granules, whereas rap1p is detected both in specific granules and a fraction enriched in plasma membranes. Neither rap1p nor rap2p was found in the cytosol or in azurophil granules. Similarly, by indirect immunofluorescence, we observed that cytoplasmic granules were stained with anti-rap1p antibodies and anti-rap2p antibodies, and the plasma membrane was labeled with both antibodies but more distinctly with anti-rap1p than with anti-rap2p antibodies. rap1p and rap2p are tightly bound to the membrane of specific granules since they cannot be extracted by high salt or alkaline buffers. In addition, treatment of intact specific granules with pronase induced the degradation of rap proteins suggesting that they are exposed to the cytoplasmic face of the granules. Degranulation of neutrophils consists of the translocation and subsequent fusion of granules with the plasma membrane. Activation of this process induced the accumulation of rap proteins in the plasma membrane as observed by subcellular fractionation and indirect immunofluorescence experiments; this was not associated with the appearance of a soluble form of these proteins, showing that they remain membrane-bound during this process. The identification and subcellular localization of rap1p and rap2p at the surface of specific granules and the observation that they translocate to the plasma membrane upon cell stimulation without appearance of soluble forms constitute an important step toward the understanding of their physiological functions in human neutrophils.     

Studies of cytochrome b-245 translocation in the PMA stimulation of the human neutrophil NADPH-oxidase

The human neutrophil respiratory burst, activated by phorbol 12-myristate 13-acetate (PMA), results from specific receptor-ligand binding and activation of the NADPH-oxidase in the plasma membrane. The role of granule membrane constituents has been elucidated with neutrophils disrupted by nitrogen cavitation and then fractionated in Percoll gradients to resolve four postnuclear fractions: cytoplasm, light membranes or gamma fraction (site of the NADPH-oxidase), a light granule (beta) fraction containing putative constituents of the NADPH-oxidase (cytochrome b-245 and an associated flavoprotein), and a fraction of heavy granules. Cytochrome b-245 is localized to two pools of specific granules within the beta fraction as assessed by differing sedimentation in narrow Percoll gradients and translocates upon PMA-stimulation from one of these specific granule sub-pools to the plasma membrane where it exhibits no change in its midpoint redox potential. Translocation of cytochrome b-245 parallels O2-production initiated by PMA stimulation as assessed in the time course of each activity. The finding of increased amounts of the b cytochrome in cytoplast membranes relative to plasma membranes of unstimulated cells suggests that the cytoplasts, devoid of granules yet capable of O2-generation upon PMA-stimulation, are useful in assessing post-translocation events in the activation pathway of the NADPH-oxidase. These data support the hypothesis that translocation of NADPH-oxidase components from an intracellular granular pool contributes to respiratory burst expression.     

Characterization of the formyl peptide chemotactic receptor appearing at the phagocytic cell surface after exposure to phorbol myristate acetate

We examined the biochemistry and subcellular source of new formyl peptide chemotactic receptor appearing at the human neutrophil and differentiated HL-60 (d-HL-60) cell surface after stimulation with phorbol myristate acetate (PMA). Formyl peptide receptor was analyzed by affinity labeling with formyl-norleu-leu-phe-norleu-[125I]iodotyr-lys and ethylene glycol bis(succinimidyl succinate) followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and densitometric analysis of autoradiographs. PMA, a specific granule secretagogue, increases affinity labeling of formyl peptide receptors on the neutrophil surface by 100%, and on d-HL-60, which lack specific granule markers, by 20%. Papain treatment markedly reduces surface labeling of formyl peptide receptor in both neutrophils and d-HL-60, and results in the appearance of a lower m.w. membrane-bound receptor fragment. PMA stimulation of papain-treated cells increases uncleaved surface receptor on neutrophils by 400%, and on d-HL-60 by only 45%. This newly appearing receptor is the same apparent m.w. (55,000 to 75,000 for neutrophils; 62,000 to 80,000 for d-HL-60) and yields the same papain cleavage product (Mr, 31,000 for neutrophils; Mr, 29,000 for d-HL-60) as receptor on the surface of unstimulated cells. Formyl peptide receptor detected by affinity labeling in neutrophil specific granule-enriched subcellular fractions is identical to receptor found on the surface of unstimulated cells appearing as equal amounts of two isoelectric forms (isoelectric points, 5.8 and 6.2) at Mr 55,000 to 70,000. There is twice as much receptor present in the specific granule-enriched fraction per cell equivalent compared with plasma membrane. Azurophil granules contain trace amounts of receptor. Similar analysis of neutrophils treated with papain before subcellular fractionation shows that papain cleaved receptor fragment is detectable almost exclusively in the plasma membrane-enriched fraction. Most of the affinity-labeled formyl peptide receptor present in specific granule enriched fraction is present in membranes other than plasma membrane or Golgi membrane, because specific granule-enriched fraction contains only a small amount of plasma membrane marker and an amount of Golgi membrane marker equal to that found in plasma membrane-enriched fraction.(ABSTRACT TRUNCATED AT 400 WORDS)     

Beta2 integrins target Rap GTPases to the plasma membrane by means of degranulation

We report the novel observation that engagement of β2 integrins on human neutrophils is accompanied by increased levels of the small GTPases Rap1 and Rap2 in a membrane-enriched fraction and a concomitant decrease of these proteins in a granule-enriched fraction. In parallel, we observed a similar time-dependent decrease of gelatinase B (a marker of specific and gelatinase B-containing granules) but not myeloperoxidase (a marker of azurophil granules) in the granule fraction, and release of lactoferrin (a marker of specific granules) in the extracellular medium. Furthermore, inhibition of Src tyrosine kinases, or phosphoinositide 3-kinase with PP1 or LY294002, respectively, blocked β2 integrin-induced degranulation and the redistribution of Rap1 and Rap2 to a membrane-enriched fraction. Consequently, the β2 integrin-dependent exocytosis of specific and gelatinase B-containing granules occurs via a Src tyrosine kinase/phosphoinositide 3-kinase signaling pathway and is responsible for the translocation of Rap1 and Rap2 to the plasma membrane in human neutrophils.     

Cytochrome b translocation to human neutrophil plasma membranes and superoxide release. Differential effects of N-formylmethionylleucylphenylalanine, phorbol myristate acetate, and A23187

The role of specific granules and cytochrome b in superoxide (O(2)) release was studied by comparing the effects of three different stimuli on normal human neutrophils, neutrophils congenitally deficient in specific granules, and granule-free normal neutrophil cytoplasts. Phorbol myristate acetate (PMA) stimulated normal neutrophils to release more O(2) than did N-formylmethionylleucylphenylalanine (fMet-Leu-Phe), which stimulated greater release than the calcium ionophore A23187. Neutrophils lacking specific granules produced variable amounts of O(2) in response to all stimuli. Stimulation with PMA, fMet-Leu-Phe, and A23187 produced maximal rates of O(2) release that were 32, 55, and 21% of that by normal cells. Likewise, granule-free neutrophil cytoplasts released 24, 20, and 0% of the O(2) released by intact cells. These data suggest that the stimuli require different mechanisms for activation. Three subcellular fractions (azurophil granule rich, specific granule rich, and plasma membrane rich) were separated by Percoll gradients from normal resting and stimulated neutrophils. In resting neutrophils, the cytochrome b content in the plasma membrane was 31% of the total, with the rest in the specific granule-rich fraction. Ten minutes after stimulation, PMA, fMet-Leu-Phe, and A23187 induced translocation of 27, 8, and 49%, respectively, of the cytochrome b from the specific granule-rich fraction to the plasma membrane. Although our data support a role for specific granule factors in A23187-induced O(2) release, there is no correlation between the amount of cytochrome b incorporated into the plasma membrane and the extent of O(2) production activated by the different stimuli.     

Arachidonic acid release from diacylglycerol in human neutrophils. Translocation of diacylglycerol-deacylating enzyme activities from an intracellular pool to plasma membrane upon cell activation

We have studied the capacity of human neutrophils to release arachidonic acid from diacylglycerol, employing 1-stearoyl-2-[1-14C]arachidonoyl-sn-glycerol and 1-[1-14C]stearoyl-2-arachidonoyl-sn-glycerol as exogenous substrates. We have found that arachidonic acid is removed from diacylglycerol by the sequential action of two enzymes. First, the sn-1 position is split by 1-diacylglycerol lipase activity, and then, arachidonic acid is released from the resulting 2-monoacylglycerol by a 2-monoacylglycerol lipase. The specific activity of the 2-monoacylglycerol lipase, using 2-[1-14C]arachidonoyl-sn-glycerol as exogenous substrate, was at least 9-fold higher than that of 1-diacylglycerol lipase, indicating that the action of the 1-diacylglycerol lipase is the rate-limiting step in arachidonic acid release from diacylglycerol. Postnuclear supernatants from A23187-treated cells showed a 2.5-fold increase in both lipase activities. The arachidonic acid-releasing diacylglycerol lipase system showed an optimum pH of 4.5 and was not inhibited by EGTA or stimulated by Ca2+, Mg2+, Mn2+, Zn2+, or Co2+. However, arachidonic acid release was inhibited by Hg2+, suggesting the involvement of sulfhydryl groups in catalytic activity. The subcellular distribution of both 1-diacylglycerol lipase and 2-monoacylglycerol lipase activities was examined in resting and A23187-treated human neutrophils by fractionation of postnuclear supernatants on continuous sucrose gradients. Both lipases were localized mainly in the membrane of gelatinase-containing granules, which were resolved from cytosol, plasma membrane, phosphasomes, and specific and azurophilic granules. When neutrophils were stimulated by the calcium ionophore A23187, a drastic shift of the 1-diacylglycerol lipase and 2-monoacylglycerol lipase toward the plasma membrane was detected. This shift was due to fusion of gelatinase-containing granules with the plasma membrane upon neutrophil stimulation. As a result of the membrane fusion process, the capacity to release arachidonic acid from diacylglycerol was increased. This translocation from the membrane of gelatinase-containing granules to the plasma membrane may play an important role in regulating the diacylglycerol level in stimulated human neutrophils.     

Changes in the subcellular distribution of the cytochrome b-245 on stimulation of human neutrophils.

Cytochrome b-245 of neutrophils has a bimodal distribution in sucrose density gradients. The lighter component (d = 1.14) is shown to be associated with the plasma membrane by the similarity between its density and that of markers of this organelle, as well as a parallel increase in the density of the cytochrome and plasma membrane after treatment with digitonin or dimethyl suberimidate. The cytochrome b-245 of monocytes and cytoplasts, the latter produced by the removal of nuclei and granules from neutrophils, was located only in the plasma membrane. The denser peak of cytochrome (d = 1.19), which contained approximately half of the cytochrome b of neutrophils, had a similar density-distribution profile to the specific granules. After hypo-osmotic disruption of this denser material, the cytochrome distributed with the density of membranes, suggesting an original location within the membrane of the intracellular structure. Redistribution of the cytochrome from the granules to the membranes was observed after stimulation of respiratory activity with soluble agents or opsonized particles. This translocation is not responsible for activation of the oxidase system. There was poor agreement between the kinetics of the transfer of cytochromes from the dense component to the membranes, and degranulation of specific-granule contents, suggesting that the cytochrome may be located in another intracellular structure or that its localization becomes further modified after granule fusion.     

Role of vesicle-associated membrane protein-2, through Q-soluble N-ethylmaleimide-sensitive factor attachment protein receptor/R-soluble N-ethylmaleimide-sensitive factor attachment protein receptor interaction,in the exocytosis of specific and tertiary granules of human neutrophils

We have examined the role of the R-soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) synaptobrevin-2/vesicle-associated membrane protein (VAMP)-2 in neutrophil exocytosis. VAMP-2, localized in the membranes of specific and gelatinase-containing tertiary granules in resting human neutrophils, resulted translocated to the cell surface following neutrophil activation under experimental conditions that induced exocytosis of specific and tertiary granules. VAMP-2 was also found on the external membrane region of granules docking to the plasma membrane in activated neutrophils. Specific Abs against VAMP-2 inhibited Ca(2+) and GTP-gamma-S-induced exocytosis of CD66b-enriched specific and tertiary granules, but did not affect exocytosis of CD63-enriched azurophilic granules, in electropermeabilized neutrophils. Tetanus toxin disrupted VAMP-2 and inhibited exocytosis of tertiary and specific granules. Activation of neutrophils led to the interaction of VAMP-2 with the plasma membrane Q-SNARE syntaxin 4, and anti-syntaxin 4 Abs inhibited exocytosis of specific and tertiary granules in electropermeabilized neutrophils. Immunoelectron microscopy showed syntaxin 4 on the plasma membrane contacting with docked granules in activated neutrophils. These data indicate that VAMP-2 mediates exocytosis of specific and tertiary granules, and that Q-SNARE/R-SNARE complexes containing VAMP-2 and syntaxin 4 are involved in neutrophil exocytosis.     

Myeloid-related protein-14 is a p38 MAPK substrate in human neutrophils

The targets of the p38 MAPK pathway that mediate neutrophil functional responses are largely unknown. To identify p38 MAPK targets, a proteomic approach was applied in which recombinant active p38 MAPK and [(32)P]ATP were added to lysates from unstimulated human neutrophils. Proteins were separated by two-dimensional gel electrophoresis, and phosphoproteins were visualized by autoradiography and identified by MALDI-TOF. Myeloid-related protein-14 (MRP-14) was identified as a candidate p38 MAPK substrate. MRP-14 phosphorylation by p38 MAPK was confirmed by an in vitro kinase reaction using purified MRP-14/MRP-8 complexes. The site of MRP-14 phosphorylation by p38 MAPK was identified by tandem mass spectrometry and site-directed mutagenesis to be Thr(113). MRP-14 phosphorylation by p38 MAPK in intact neutrophils was confirmed by [(32)P]orthophosphate loading, followed by fMLP stimulation in the presence and absence of a p38 MAPK inhibitor, SB203580. Confocal microscopy of Triton X-100 permeabilized neutrophils showed that a small amount of MRP-14 was associated with cortical F-actin in unstimulated cells. fMLP stimulation resulted in a p38 MAPK-dependent increase in MRP-14 staining at the base of lamellipodia. By immunoblot analysis, MRP-14 was present in plasma membrane/secretory vesicle fractions and gelatinase and specific granules, but not in azurophil granules. The amount of MRP-14 associated with plasma membrane/secretory vesicle and gelatinase granule fractions increased after fMLP stimulation in a p38 MAPK-dependent manner. Direct phosphorylation of the MRP-14/MRP-8 complex by p38 MAPK increased actin binding in vitro by 2-fold. These results indicate that MRP-14 is a potential mediator of p38 MAPK-dependent functional responses in human neutrophils.     

Activation of the oxygen-radical-generating system in granules of intact human neutrophils by a calcium ionophore (ionomycin).

Subcellular fractionation studies were performed on human neutrophils stimulated with ionomycin (a Ca(2+)-specific ionophore). The results of these studies revealed NADPH-oxidase activity, without any additive, both in the plasma membrane and in the specific granule fractions. After comparing these results with the NADPH oxidase activity induced by the ionophore in intact neutrophils, in differentiated HL-60 cells and in neutrophil cytoplasts, we conclude that ionomycin preferentially activates the NADPH oxidase pool located in the membrane of specific granules. Furthermore, we suggest that incorporation of granule membrane into the plasma membrane makes the associated NADPH oxidase less sensitive to activation induced by a rise in [Ca(2+)]i.     

The neutrophil glycoprotein Mo1 is an integral membrane protein of plasma membranes and specific granules

The glycoprotein Mo1 has previously been demonstrated to be on the cell surface and in the specific granule fraction of neutrophils and to be translocated to the cell surface during degranulation. It is not known, however, whether Mo1 is an integral membrane protein or a soluble, intragranular constituent loosely associated with the specific granule membrane. Purified neutrophils were disrupted by nitrogen cavitation and separated on Percoll density gradients into four fractions enriched for azurophilic granules, specific granules, plasma membrane, and cytosol, respectively. The glycoproteins in these fractions were labeled with 3H-borohydride reduction, extracted with Triton X-114, and immunoprecipitated with 60.3, an anti-Mo1 monoclonal antibody Mo1 was detected only in the specific granule and plasma membrane fractions and partitioned exclusively into the detergent-rich fraction consistent with Mo1 being an integral membrane protein. In addition, treatment of specific granule membranes with a high salt, high urea buffer to remove absorbed or peripheral proteins failed to dissociate Mo1. These data support the hypothesis that Mo1 is an integral membrane protein of plasma and specific granule membranes in human neutrophils.     

Subcellular localization and dynamics of components of the respiratory burst oxidase

Membrane and cytosolic factors cooperate to generate NADPH-oxidase. The study of the syndrome of NADPH-oxidase deficiencies, chronic granulomatous disease, has enabled the identification of two membrane factors: a flavin adenine dinucleotide flavoprotein and ab cytochrome. The nature of the cytosolic components is still unknown, but a 47-kD protein, whose phosphorylation occurs in parallel with the generation of a respiratory burst in intact cells, seems to be one of the cytosolic factors. The subcellular localization of the membrane-bound NADPH-oxidase components has been studied in neutrophils: In unstimulated cells, only a minute fraction of the NADPH-oxidase components is localized in the plasma membrane, whereas 80% is localized in the membrane of the specific granules and the majority of the rest is in a newly described membrane-bound compartment, the secretory granules, identified by latent alkaline phosphatase. During stimulation, these NADPH-oxidase components are translocated to the plasma membrane as a result of fusion of granule membrane with plasma membrane. Only the NADPH-oxidase components present in the plasma membrane are incorporated in the respiratory burst oxidase generated in intact cells.     

Morphological evidence for the association of plasma membrane glycoprotein IIb/IIIa with the membrane skeleton in human platelets

We examined the association between glycoprotein (GP) IIb/IIIa, a receptor for fibrinogen, and membrane skeletons in both unstimulated and thrombin-activated human platelets. After a treatment with dithiobis succinimidyl propionate (DTSP), a cross-linker, unstimulated and activated platelets were simultaneously extracted and fixed with a fixing solution containing Triton X-100. Also, the localization of GPIIb/IIIa on the plasma membrane was observed by a preembedding staining method of unextracted platelets. In unstimulated platelets, 20-40% of the whole plasma membrane remained in the detergent-extracted samples. Amorphous structures with 10-70 nm in diameters are distributed at 20 to 100-nm intervals on the surface of plasma membrane. Similar structures also were identified in the intact platelets by the immunocytochemical method. By careful inspection, we found that most of the amorphous structures that contained gold particles were connected to the submembrane zone just beneath the plasma membrane. The submembrane zone was identified as the membrane skeleton because actin was detected in the zone. After activation, detergent-insoluble granules were surrounded by dense networks of microfilaments in the central part of platelets. The filaments were identified as actin and became associated with myosin. These results demonstrate that GPIIb/IIIa on the plasma membrane is connected to the membrane skeleton and suggest that, during activation, actin filaments which extend into the cytoplasm from the membrane skeleton increase and form dense networks around Triton-insoluble granules.     

Dynamic reorganization of the alkaline phosphatase-containing compartment during chemotactic peptide stimulation of human neutrophils imaged by backscattered electrons

Scanning electron microscopy (EM) and cytochemical techniques were used to examine the alkaline phosphatase-containing compartment in human neutrophils after stimulation with nanomolar concentrations of N-formylmethionyl-leucyl-phenylalanine (10^–8M fMLP). Alkaline phosphatase (AlkPase) activity was demonstrated with a lead-based metal capture cytochemical method. The reaction product was visualized with the backscattered electron imaging mode of scanning EM, and analyzed by electron probe X-ray microanalysis. Alkaline phosphatase activity was detected only in fMLP-stimulated neutrophils; unstimulated neutrophils displayed no activity. Stimulation of human neutrophils with 10^–8 M fMLP induced a time-dependent intracellular redistribution of irregular round or tubular granules containing alkaline phosphatase activity, as seen by backscattering. The intracellular redistribution of alkaline phosphatase activity was accompanied by increased cytochemical activity on the cell surface. The reaction product was localized preferentially on ridges and folds of polar neutrophils. Reorganization of the AlkPase-containing compartment correlated with changes induced by fMLP in cell shape, ie, membrane ruffling and front-tail polarity, as observed with the secondary electron image mode of scanning EM. These findings demonstrate the intracellular reorganization, increase, and asymmetric distribution of alkaline phosphatase activity on the plasma membrane of human neutrophils after stimulation by chemotactic peptides.     

Subcellular distribution and characterization of GTP-binding proteins in human neutrophils

The subcellular distribution of GTP binding proteins in human neutrophils and their functional coupling to the N-formylmethionylleucylphenylalanine (FMLP) receptor was characterized to provide insight into mechanisms of cellular activation. Human neutrophils were nitrogen cavitated and fractionated on discontinuous Percoll gradients. Four subcellular fractions were obtained: cytosol, light membranes enriched for plasma membranes, specific granules and azurophilic granules. ADP-ribosylation catalyzed by pertussis toxin (PT) revealed a major substrate of 40 kDa only in plasma membrane and cytosol, and antiserum specific for Gi alpha confirmed the presence of neutrophil Gi alpha in plasma membrane and cytosol and its absence from specific granules. The cytosolic PT substrate was shown to be mostly in monomeric form by molecular sieve chromatography. The rate of the ribosyltransferase reaction was several-fold lower in cytosol compared to plasma membranes, and the extent of ADP-ribosylation was greatly augmented by supplementation with beta gamma subunits in cytosol. ADP-ribosylation catalyzed by cholera toxin (CT) revealed substrates of 52, 43 and 40 kDa in plasma membrane alone. FMLP receptors in plasma membrane were shown to be coupled to the 40 kDa substrate for CT by ligand-modulation of ADP-ribosylation, while FMLP added to specific granules did not induce ribosylation of this substrate even though FMLP receptors were found in high density in this compartment. Both 24 and 26 kDa [32P]GTP binding proteins were found to codistribute with FMLP receptors in specific granules and plasma membranes. Functional evidence for the coupling of GTP binding proteins to the FMLP receptor in specific granules was obtained by modulating [3H]FMLP binding with GTP gamma S, and by accelerating [35S]GTP gamma S binding with FMLP.     

Subcellular distribution and membrane association of human neutrophil substrates for ADP-ribosylation by pertussis toxin and cholera toxin

Neutrophil guanine nucleotide-binding proteins are important components of receptor-mediated cellular responses such as degranulation, chemotaxis, and superoxide production. Because the cytoplasmic granules of neutrophils serve as an intracellular store of receptors and NADPH oxidase components, we investigated the subcellular distribution of substrates for ADP-ribosylation by both pertussis and cholera toxins. Cholera toxin substrates of Mr 43 and 52 kDa were present only in the plasma membrane fraction. A 39-kDa pertussis toxin substrate was present in the plasma membrane, cytosol, and a specific granule-enriched fraction. There were no substrates for either toxin in the primary granules. Quantitative GTP-gamma-5 binding was localized predominantly to the plasma membrane fraction (47%), but significant portions were found in the specific granule-enriched fractions (13%) and cytosol (34%) as well. Two-dimensional gel electrophoresis and chymotryptic digests of the pertussis toxin substrate from these three subcellular fractions suggested that they are highly homologous. Triton X-114 phase partitioning was used to investigate the hydrophobicity of the toxin substrates. The pertussis toxin substrates in the plasma membrane and granule fractions behaved like integral membrane proteins, whereas the cytosolic substrate partitioned into both lipophilic and aqueous fractions. ADP-ribosylation converted the substrates to a somewhat less lipophilic form. These data suggest that the specific granules or an organelle of similar density serve as an intracellular store of a G protein with a 39-kDa alpha-subunit and that the cytosolic fraction of neutrophils contains free alpha-subunits of the same size.     

Effect of botulinum D toxin on human neutrophilic leukocytes and localization of its substrates

Botulinum D toxin has been shown to ADP-ribosylate 22-kD proteins in neutrophilic leukocytes, but the function of these GTP-binding proteins remains unknown. In analogy to small GTP-binding proteins like SEC4 to YPT1, it has been suggested that botulinum D toxin substrates might be involved in secretory process of myeloid cells. Three main findings lead to the opposite conclusion. First of all, in human neutrophils, botulinum D toxin does not modify the release of azurophilic and specific granules induced by a chemoattractant (a formylpeptide) or a phorbol ester. Second, botulinum D toxin ADP-ribosylates 24 to 26-kD proteins that are only present in plasma membranes of human neutrophils. The membrane location of these substrates differs largely from that of the GTP-binding proteins involved in exocytosis and located in granules. Finally, since the same quantity of the toxin substrates is present in neutrophils as in their precursors, HL60 cells (which are devoid of specific granules and characterized by immature azurophilic granules and NADPH oxidase), it is unlikely that endogenous botulinum D toxin substrates are directly involved in the secretory responses of neutrophils.     

Low molecular weight GTP-binding proteins in human neutrophil granule membranes

Degranulation of neutrophils involves the differential regulation of the exocytosis of at least two populations of granules. Low molecular weight GTP-binding proteins (LMW-GBPs) have been implicated in the regulation of vesicular traffic in the secretory pathways of several types of cells. In the present study we identify distinct subsets of LMW-GBPs associated with the membranes of neutrophil-specific and azurophilic granules. Ninety-four percent of total [35S]guanosine 5'-(3-O-thio)triphosphate (GTP gamma S) binding activity was equally distributed between the plasma membrane and cytosol with the remaining 6% localized in the granules. In contrast, the cytosol contained only 10% of the total GTPase activity while the specific granules accounted for 13%. [alpha-32P]GTP binding to proteins transferred to nitrocellulose revealed LMW-GBPs in all fractions except the azurophilic granules. The specific granules contained three out of four bands which were found in the plasma membrane; these ranged from 20 to 23 kDa and all were resistant to alkaline extraction. Photoaffinity labeling with [alpha-32P]8-azido-GTP in the presence of micromolar Al3+ identified proteins of 25 and 26 kDa unique to azurophilic granules; these could not be labeled with [alpha-32P]8-azido-ATP and could be extracted by acidic but not alkaline pH. Botulinum C3-mediated [32P]ADP-ribosylation identified proteins of 16, 20, and 24 kDa both in plasma membranes and those of specific granules. An anti-ras monoclonal antibody, 142-24E5, recognized a 20-kDa protein localized to the plasma and specific granule membranes which could not be extracted by alkaline pH, was not a substrate for botulinum C3 ADP-ribosyltransferase, and was translocated from specific granules to plasma membrane after exposure of neutrophils to phorbol myristate acetate. We conclude that neutrophil-specific and azurophilic granules contain distinct subsets of LMW-GBPs which are uniquely situated to regulate the differential exocytosis of these two compartments.     

Subcellular localization of cytochrome b and ubiquinone in a tertiary granule of resting human neutrophils and evidence for a proton pump ATPase

The subcellular distribution of cytochrome b and ubiquinone in resting human neutrophils was investigated by rate zonal sedimentation of postnuclear supernatants on continuous sucrose gradients. Both cytochrome b and ubiquinone were mainly localized in small organelles, tertiary granules, that were resolved from the specific and azurophilic granules as well as from the cell membrane fraction. This cytochrome b- and ubiquinone-rich granule was shown to contain dicyclohexylcarbodiimide (DCCD)-sensitive, Mg2+-dependent ATPase as well as low amounts, less than a third, of the acid hydrolases beta-glucuronidase and N-acetyl-beta-glucosaminidase. Cytochrome b was also found in smaller proportions in plasma membranes and specific granules. A significant proportion of the ubiquinone was located in the region of the gradients where specific granules and mitochondria sedimented. However, quantitative measurements of oligomycin-sensitive ATPase indicated that this second localization of ubiquinone could not be entirely attributed to mitochondrial contamination. Plasma membrane contained small amounts of ubiquinone. In addition, the existence and location of a putative proton pump ATPase were also investigated. The ATPase was mainly located in the plasma membrane and in the upper half of the gradients (tertiary and specific granules), with the highest specific activity occurring in the tertiary granules. This activity was inhibited by 100 microM DCCD. Furthermore, ATP-dependent uptake of [14C]methylamine by tertiary and specific granules was observed. These results suggest that the DCCD-sensitive ATPase may function as a proton pump. DCCD inhibited the release of enzymes from specific granules that occurred when human neutrophils were activated by phorbol myristate acetate. However, higher concentrations of DCCD were required to achieve the same degree of inhibition of O2 uptake (I50 of 0.4 mM for secretion versus 1 mM for O2 uptake). These results suggest that specific granules do not play a crucial role in oxygen metabolism.