Initial characterization of human platelet mepacrine-labelled granules isolated using a short metrizamide gradient

Granule-mediated release of sphingosine-1-phosphate by activated platelets

Sphingosine-1-phosphate (S1P) is an intracellularly generated bioactive lipid essential for development, vascular integrity, and immunity. These functions are mediated by S1P-selective cell surface G-protein coupled receptors. S1P signaling therefore requires extracellular release of this lipid. Several cell types release S1P and evidence for both plasma membrane transporter-mediated and vesicle-dependent secretion has been presented. Platelets are an important source of S1P and can release it in response to agonists generated at sites of vascular injury. S1P release from agonist-stimulated platelets was measured in the presence of a carrier molecule (albumin) using HPLC-MS/MS. The kinetics and agonist-dependence of S1P release were similar to that of other granule cargo e.g. platelet factor IV (PF4). Agonist-stimulated S1P release was defective in platelets from Unc13d(Jinx) (Munc13-4 null) mice demonstrating a critical role for regulated membrane fusion in this process. Consistent with this observation, platelets efficiently converted fluorescent NBD-sphingosine to its phosphorylated derivative which accumulated in granules. Fractionation of platelet organelles revealed the presence of S1P in both the plasma membrane and in α-granules. Resting platelets contained a second pool of constitutively releasable S1P that was more rapidly labeled by exogenously added sphingosine. Our studies indicate that platelets contain two pools of S1P that are released extracellularly: a readily-exchangeable, metabolically active pool of S1P, perhaps in the plasma membrane, and a granular pool that requires platelet activation and regulated exocytosis for release.

Isolation of platelet granules

Functional analysis of platelet intracellular structures requires isolation and purification of these cellular compartments. With regard to the function of platelets, both, dense (delta) and alpha granules are relevant target structures. However, the availability of sufficient purification protocols for these structures is rather limited. This unit describes two protocols for isolation and purification of platelet granule structures. The Basic Protocol describes a new technique based on immunolabeling with target-specific antibodies followed by magnetic sorting, whereas the Alternate Protocol describes the more traditional procedure based on differential centrifugation and density-based sedimentation. For both methods, the degree of granule purification can be most easily determined by immunoblotting using various antibodies that recognize structure-specific proteins. The immunomagnetic sorting method is especially good for studies requiring highly purified material (e.g., for the identification of specific transporters and receptors).

Human platelet dense granules contain polyphosphate and are similar to acidocalcisomes of bacteria and unicellular eukaryotes

Inorganic polyphosphate (polyP) has been identified and measured in human platelets. Millimolar levels (in terms of Pi residues) of short chain polyP were found. The presence of polyP of approximately 70-75 phosphate units was identified by 31P NMR and by urea-polyacrylamide gel electrophoresis of platelet extracts. An analysis of human platelet dense granules, purified using metrizamide gradient centrifugation, indicated that polyP was preferentially located in these organelles. This was confirmed by visualization of polyP in the dense granules using 4',6-diamidino-2-phenylindole and by its release together with pyrophosphate and serotonin upon thrombin stimulation of intact platelets. Dense granules were also shown to contain large amounts of calcium and potassium and both bafilomycin A1-sensitive ATPase and pyrophosphatase activities. In agreement with these results, when human platelets were loaded with the fluorescent calcium indicator Fura-2 acetoxymethyl ester to measure their intracellular Ca2+ concentration ([Ca2+]i), they were shown to possess a significant amount of Ca2+ stored in an acidic compartment. This was indicated by the following: 1) the increase in [Ca2+]i induced by nigericin, monensin, or the weak base, NH4Cl, in the nominal absence of extracellular Ca2 and 2) the effect of ionomycin, which could not take Ca2+ out of acidic organelles and was more effective after alkalinization of this compartment by the previous addition of nigericin, monensin, or NH4Cl. All of these characteristics of the platelet dense granules, together with their known acidity and high density (both by weight and by electron microscopy), are similar to those of acidocalcisomes (volutin granules, polyP bodies) of bacteria and unicellular eukaryotes. The results suggest that acidocalcisomes have been conserved during evolution from bacteria to humans.

The nucleotide transporter MRP4 (ABCC4) is highly expressed in human platelets and present in dense granules, indicating a role in mediator storage

Platelet aggregation is initiated by the release of mediators as adenosine diphosphate (ADP) stored in platelet granules. Possible candidates for transport proteins mediating accumulation of these mediators in granules include multidrug resistance protein 4 (MRP4, ABCC4), a transport pump for cyclic nucleotides and nucleotide analogs. We investigated the expression of MRP4 in human platelets by immunoblotting, detecting a strong signal at 170 kDa. Immunofluorescence microscopy using 2 MRP4-specific antibodies revealed staining mainly in intracellular structures, which largely colocalized with the accumulation of mepacrine as marker for delta-granules and to a lower extent at the plasma membrane. Furthermore, an altered distribution of MRP4 was observed in platelets from a patient with Hermansky-Pudlak syndrome with defective delta-granules. Adenosine triphosphate (ATP)-dependent cyclic guanosine monophosphate (cGMP) transport codistributed with MRP4 detection in subcellular fractions, with highest activities in the dense granule and plasma membrane fractions. This transport was inhibited by dipyramidole, indomethacin, and MK571 with median inhibitory concentration (IC(50)) values of 12, 22, and 43 microM, and by ibuprofen. Transport studies with [(3)H]ADP indicated the presence of an orthovanadate-sensitive ADP transporting system, inhibited by dipyramidole, MK571, and cyclic nucleotides. The results indicate a function of MRP4 in platelet mediator storage and inhibition of MRP4 may represent a novel mechanism for inhibition of platelet function by some anti-inflammatory drugs.

Calcium-dependent stabilization of type I plasminogen activator inhibitor within platelet alpha-granules

Type 1 plasminogen activator inhibitor (PAI-1) is known to be synthesized in an active conformation but it is rapidly converted into an inactive conformation (t1/2 1 h) upon incubation at 37 degrees C. This study was initiated to investigate the mechanism that account for the presence of active PAI-1 in anucleated platelets that have a mean life span of 9-12 days in the circulation. Stabilization experiments with a functional immunoassay indicated that the activity of PAI-1 in both platelets and in isolated alpha-granules was prolonged in comparison to the rapid inactivation of this molecule in their lysates (t1/2 1 h). Although combined ligand blot/immunoblot analysis revealed that vitronectin was the major PAI-1 binding protein in platelets, vitronectin/PAI-1 complexes were not detected in alpha-granules using a two-site immunoassay. Co-incubation of alpha-granules with a number of agents that disrupt pH gradients (e.g. ionophores) had no effect on the stability of PAI-1 activity, whereas incubation of alpha-granules with the calcium ionophore A23187 reduced the half-life of PAI-1 to the levels observed for PAI-1 in solution. Addition of calcium ions to intact alpha-granules was an effective means of neutralizing the ionophore's effect on PAI-1 activity. Fractionation of alpha-granule proteins on molecular sieving columns using conditions known to be present within storage granules (e.g. a high calcium concentration) revealed the presence of PAI-1 in fractions with a molecular mass of > 10(6) daltons. Immunoabsorption of PAI-1 from these column fractions followed by negative staining revealed 25-nm diameter complexes of alpha-granule proteins under the electron microscope. PAI-1 activity associated with these complexes was prolonged in the presence of calcium ions and these high Mr complexes were shown to be composed of a defined set of proteins that can be dissociated from PAI-1 by chelation of calcium ions. These data indicate that PAI-1 is stabilized by its packaging with other alpha-granule proteins in a calcium-dependent manner.

Identification of small GTP-binding rab proteins in human platelets: thrombin-induced phosphorylation of rab3B, rab6, and rab8 proteins

The activation of platelets by specific agonists is a tightly regulated mechanism that leads to the secretion of the dense- and alpha-granule contents. Platelets have been shown to possess small GTP-binding proteins thought to be involved in central biological processes; however, no rab proteins, which may regulate the exocytic process at different stages, have been reported. This study has shown that rab1, rab3B, rab4, rab6, and rab8 proteins, but not rab3A protein, were present in platelets and in endothelial cells. To probe their functional significance in platelets, rab3B, rab6, and rab8 proteins were further characterized with regard to their intracellular localization and their phosphorylation properties. Whereas rab3B protein was found to be mainly cytosolic, rab6 and rab8 proteins were preferentially targeted to the plasma membrane and to the alpha granules. The activation of platelets by thrombin, a potent inducer of secretion, resulted in the phosphorylation of rab3B, rab6, and rab8 proteins, whereas no phosphorylation was observed in the presence of prostaglandin E1, which stimulates cAMP-dependent protein kinase and inhibits the secretion process. These findings provide evidence that members of the subfamily of rab proteins, rab6 and rab8, are localized in platelets to one type of specific secretory vesicle, the alpha granule, and would suggest their possible implication in the secretion process through phosphorylation mechanisms.

The protein CD63 is in platelet dense granules, is deficient in a patient with Hermansky-Pudlak syndrome, and appears identical to granulophysin

The levels and expression of the proteins CD63 and granulophysin in platelets from control and from a Hermansky-Pudlak syndrome subject (a condition characterized by dense granule and lysosomal deficiencies and the accumulation of ceroid-like material in reticuloendothelial cells) were examined. Immunofluorescence studies indicated that anti-CD63 and anti-granulophysin antibodies recognized similar numbers of granules; coapplication of antibodies did not identify more granules than the individual antibodies. Significantly fewer granules were recognized in Hermansky-Pudlak syndrome platelets than in control using either antibody. Immunoblotting studies demonstrated that anti-CD63 and anti-granulophysin antibodies apparently recognize the same protein, which was deficient in Hermansky-Pudlak platelets. Analysis by fluorescence-activated cell sorter (FACS) showed biphasic expression of CD63 and granulophysin after thrombin stimulation of control but not Hermansky-Pudlak platelets. Anti-CD63 effectively blocked detection of the protein by anti-granulophysin using immunofluorescence, ELISA, immunoblotting, and FACS analysis. Amino-terminal sequencing over the first 37 amino acids revealed that granulophysin was homologous to CD63, melanoma antigen ME491, and pltgp40. These results suggest that granulophysin and CD63 are possibly identical proteins. This is the first report of a protein present in platelet dense granules, lysosomes, and melanocytes, but deficient in a patient with Hermansky-Pudlak syndrome.

Interaction of wheat germ agglutinin with human platelets: a model for studying platelet response

Binding of wheat germ agglutinin (WGA) to human platelets and their activation were studied. The binding of fluoresceinyl-substituted WGA (F-WGA) was saturable, specific, reversible and cooperative. The apparent association constant (Ka) was 2.4 X 10(6) M-1. Activation of platelets was measured by change in light transmission (LT) (aggregation) and by assays of 14C-serotonin and beta-thromboglobulin (secretion). The maximum platelet activation was obtained with 15 micrograms/ml WGA. At this concentration only 17% of all available binding sites were occupied. Increasing the WGA concentration diminished the change in LT and the secretion from alpha granules but not from dense bodies. The addition of EDTA partially reduced the platelet aggregation without any effect on the secretion. Remaining LT change was insensitive to all metabolic inhibitors tested (CP/CPK, arginine, indomethacin, PGE1, chlorpromazine, colchicine and cytochalasin B). The secretion measured in the presence of EDTA was only reduced by preincubation with PGE1 and CPZ. Succinyl-WGA which only binds glucoconjugates containing GlcNAc did not induce any platelet activation, whereas limulin, which binds to glucoconjugates containing NeuAc did induce platelet agglutination and secretion. These results indicate that: (1) the platelet aggregation and secretion induced by WGA occur with only partial occupancy of the membrane binding sites by the lectin; (2) the platelet LT change is due in part to the agglutinating properties of the lectin bound to the platelet surface, and in another part to the aggregation reaction mediated by a platelet constituent secreted from the storage sites in response to the binding of the lectin.

Simultaneous isolation of two platelet membrane fractions: biochemical, immunological and functional characterization

Simultaneous isolation of two platelet membrane subfractions was achieved by centrifugation on 40% sucrose from a 100.000 g crude membrane fraction. Characterization of both types of membranes was carried out by different biochemical and immunological markers. Using a surface label, 3H Concanavalin A (3HCon A), a marker enzyme, phosphodiesterase, and lipid analysis, one of the fraction has been identified as external or plasma membranes, the other consists of intracellular membranes. Further two specific antibodies directed against external membrane antigens (LeKa and IgG L) react almost exclusively with the external membranes. Finally both kinds of membranes were able to uptake calcium but the affinity for this cation was higher for the internal than for the external membranes. This suggests that both membranes are implicated in the regulation of the cytoplasmic calcium concentration and that the internal membranes (dense tubular system) play the major part in this regulation.

Characterization of calcium liberation from a human platelet membrane fraction

Calcium efflux and EGTA-induced calcium release from an internal platelet membrane fraction have been studied after the oxalate-supported calcium uptake had reached steady state. Increasing external calcium concentrations stimulate the calcium efflux velocity, with an apparent half-maximal stimulation at about 5 microM outside calcium concentration and a maximal velocity of calcium efflux of 4.66 +/- 2.32 nmol X min-1 X mg-1. Moreover, the ratio of the liberated calcium on the loaded calcium seems to be independent of the increasing external calcium concentration. Increasing the calculated internal calcium concentration by varying the oxalate potassium concentration from 10 mM to 1 mM results in an increase of the liberated calcium from the membrane vesicles from 7.4% to 63%, respectively, without changing the calcium efflux velocity. Similar conclusions can be drawn from the observation of results from the calcium efflux and EGTA-induced calcium release methods. Moreover, calcium pump reversal does not seem to be responsible for the calcium efflux or calcium release. All these different points added to the previously described regulation of calcium efflux by the catalytic subunit of cAMP protein kinase suggest us that the mechanism of calcium liberation by the platelet membranes is different from the calcium uptake.