Electropermeabilized platelets: a preparation to study exocytosis

Phosphorylation of SNAP-23 in activated human platelets

Phosphorylation of SNARE proteins may provide a critical link between cell activation and secretory processes. Platelets contain all three members of the SNAP-23/25/29 gene family, but by comparison to brain tissue, SNAP-23 is the most highly enriched of these proteins in platelets. SNAP-23 function is required for exocytosis from platelet alpha, dense, and lysosomal granules. SNAP-23 was phosphorylated largely on serine residues in platelets activated with thrombin. Phosphorylation kinetics paralleled or preceded granule secretion. Inhibition studies suggested that SNAP-23 phosphorylation proceeds largely through a protein kinase C (PKC) mechanism and purified PKC directly phosphorylated recombinant (r-) SNAP-23 (up to 0.3 mol of phosphate/mol of protein). Five major tryptic phosphopeptides were identified in cellular SNAP-23 isolated from activated platelets; three phosphopeptides co-migrated with those identified in PKC-phosphorylated r-SNAP-23. In contrast, only one major phosphopeptide was identified when SNAP-23, engaged in a ternary SNARE complex, was phosphorylated by PKC. Ion trap mass spectrometry revealed that platelet SNAP-23 was phosphorylated at Ser23/Thr24 and Ser161, after cell activation by thrombin; these sites were also identified in PKC-phosphorylated r-SNAP-23. SNAP-23 mutants that mimic phosphorylation at Ser23/Thr24 inhibited syntaxin 4 interactions, whereas a phosphorylation mutant of Ser161 had only minor effects. Taken together these studies show that SNAP-23 is phosphorylated in platelets during cell activation through a PKC-related mechanism at two or more sites with kinetics that parallel or precede granule secretion. Because mutants that mimic SNAP-23 phosphorylation affect syntaxin 4 interactions, we hypothesize that SNAP-23 phosphorylation may be important for modulating SNARE-complex interactions during membrane trafficking and fusion.

Munc18-syntaxin complexes and exocytosis in human platelets

The Sec1-Munc18 (SM) proteins are required for cellular exocytosis, but their mechanistic function remains poorly understood. We examined SM-syntaxin complexes in human platelets, which are terminally differentiated, anuclear cells that secrete the contents of their intracellular granules through syntaxin 2- and syntaxin 4-dependent mechanisms. Munc18a, Munc18b, and Munc18c were detected in human platelets by immunoblotting and/or PCR. The SM proteins and syntaxin 2 were found in the membrane and cytosolic fractions of cells, whereas syntaxin 4 was detected only in the membrane. Platelet membranes contain Munc18c-syntaxin 4 complexes, but minimal if any Munc18c-syntaxin 2 complexes were found. No significant amounts of Munc18a or Munc18b complexes were seen with either syntaxin. Munc18c-syntaxin 4 complexes were dissociated when cells were activated to secrete. Two potential inhibitors of Munc18c-syntaxin 4 complexes were generated to examine whether complex dissociation may lead to exocytosis. Peptides that mimic the projected intermolecular contact sites of Munc18c with syntaxin enhanced Ca2+-triggered dense granule exocytosis in permeabilized cells. Similarly, an anti-Munc18c monoclonal antibody that inhibited the Munc18c-syntaxin complex potently amplified Ca2+-induced platelet granule secretion. In summary, Munc18 proteins bind to specific syntaxin isoforms in platelets despite the presence of other potential binding partners. Acute inhibition of the SM-syntaxin complex promotes Ca2+-induced exocytosis, suggesting that complex formation per se has a regulatory effect on triggered secretion.

Vesicle-associated membrane protein 3 (VAMP-3) and VAMP-8 are present in human platelets and are required for granule secretion

Secretion of platelet granules is necessary for normal hemostasis. Platelet secretion requires soluble N-ethylmaleimide-sensitive factor attachment protein (SNAP) receptor (SNARE) complex formation between different members of the syntaxin, SNAP-25, and vesicle-associated membrane protein (VAMP) gene families. Using microcapillary reverse-phase high-performance liquid chromatography-nano-electrospray tandem mass spectrometry, we identified VAMP-3 and VAMP-8 as VAMP isoforms coimmunoprecipitated from platelets with syntaxin 4. Immunoblotting experiments confirmed the presence of VAMP-3 and VAMP-8 but not VAMP-1 or VAMP-2 in platelets. To examine the effect of VAMP proteins on platelet secretion, soluble recombinant (r) VAMP-2, rVAMP-3, and rVAMP-8 were incubated with streptolysin O-permeabilized platelets. Secretion of alpha granules (monitored by flow cytometric measurement of P-selectin) was blocked, and dense-granule secretion (assessed by release of carbon 14-serotonin) was almost completely inhibited by rVAMP-3, whereas rVAMP-8 inhibited secretion of dense granules but not alpha granules. In contrast, rVAMP-2, which formed SNARE complexes in vitro, had no effect on platelet exocytosis. We conclude that VAMP-3 and VAMP-8 form SNARE complexes with platelet syntaxin 4 and are required for platelet granule secretion.

A Critical Role for N-ethylmaleimide–Sensitive Fusion Protein (NSF) in Platelet Granule Secretion

The molecular mechanisms that regulate membrane targeting/fusion during platelet granule secretion are not yet understood.N-ethylmaleimide-sensitive fusion protein (NSF), soluble NSF attachment proteins (SNAPs), and SNAREs (SNAP receptors) are elements of a conserved molecular machinery for membrane targeting/fusion that have been detected in platelets. We examined whether NSF, an ATPase that has been shown to play a critical role in membrane targeting/fusion in many cell types, is necessary for platelet granule secretion. Peptides that mimic NSF sequence motifs inhibited both -granule and dense-granule secretion in permeabilized human platelets. This inhibitory effect was sequence-specific, because neither proteinase K-digested peptides nor peptides containing similar amino acids in a scrambled sequence inhibited platelet secretion. The peptides that inhibited platelet granule secretion also inhibited the human recombinant -SNAP–stimulated ATPase activity of recombinant NSF. It was also found that anti-NSF antibodies, which inhibited recombinant -SNAP–stimulated ATPase activity of NSF, inhibited platelet granule secretion in permeabilized cells. The inhibition by anti-NSF antibodies was abolished by the addition of recombinant NSF. These data provide the first functional evidence that NSF plays an important role in platelet granule secretion.

A Critical Role for N-ethylmaleimide–Sensitive Fusion Protein (NSF) in Platelet Granule Secretion

The molecular mechanisms that regulate membrane targeting/fusion during platelet granule secretion are not yet understood.N-ethylmaleimide-sensitive fusion protein (NSF), soluble NSF attachment proteins (SNAPs), and SNAREs (SNAP receptors) are elements of a conserved molecular machinery for membrane targeting/fusion that have been detected in platelets. We examined whether NSF, an ATPase that has been shown to play a critical role in membrane targeting/fusion in many cell types, is necessary for platelet granule secretion. Peptides that mimic NSF sequence motifs inhibited both -granule and dense-granule secretion in permeabilized human platelets. This inhibitory effect was sequence-specific, because neither proteinase K-digested peptides nor peptides containing similar amino acids in a scrambled sequence inhibited platelet secretion. The peptides that inhibited platelet granule secretion also inhibited the human recombinant -SNAP–stimulated ATPase activity of recombinant NSF. It was also found that anti-NSF antibodies, which inhibited recombinant -SNAP–stimulated ATPase activity of NSF, inhibited platelet granule secretion in permeabilized cells. The inhibition by anti-NSF antibodies was abolished by the addition of recombinant NSF. These data provide the first functional evidence that NSF plays an important role in platelet granule secretion.

Pepsinogen secretion: coupling of exocytosis visualized by video microscopy and [Ca2+]i in single cells

Conventional in vitro studies of pepsinogen secretion have measured secretion into the bulk medium and have demonstrated the critical role of Ca2+ in the process. The present study was undertaken to obtain further details of the process of secretion and its relation to Ca2+ changes over very short time periods. The relation between Ca2+ mobilization and exocytosis in an isolated individual peptic cell of the bullfrog was investigated by a method to measure both intracellular Ca2+ ([Ca2+]i), using a fluorescent Ca2+ indicator, fura 2, and exocytosis from single cells using a video microscope analyzing system. Bombesin (3.2 x 10(-7) M) and bethanechol (3.2 x 10(-4) M) caused a rapid increase in [Ca2+]i (initial peak) and a corresponding high frequency of initial exocytosis. After the initial peak, [Ca2+]i was maintained at a somewhat elevated level over the baseline (sustained phase), with a corresponding low frequency of exocytosis. Both the sustained phase of elevated [Ca2+]i and the related exocytosis were eliminated by the depletion of extracellular Ca2+. Low concentrations of bombesin (3.2 x 10(-10) M) and bethanechol (3.2 x 10(-7) M) caused sustained low-amplitude Ca2+ oscillations with correspondingly low frequencies but also caused sustained exocytosis. These data show that 1) cellular response differs between high and low concentrations of stimulus, 2) there is a close relation between [Ca2+]i and exocytosis, 3) exocytosis follows elevation of [Ca2+]i by 14-45 s (n = 6), and 4) there is a significant positive correlation between the peak [Ca2+]i and the number of exocytoses.