Trifaró Jm scite author profile

In response to vessel injury or exposure to different substances, platelets undergo activation which consists of shape changes, formation of cellular pseudopodia, aggregation, and secretion. These dramatic changes are accompanied by cycles of actin depolymerization and polymerization. Previous work has shown the presence in platelets of gelsolin and scinderin, two Ca(2+)-dependent F-actin severing proteins. Recent published evidence suggests that scinderin is a component of the exocytotic machinery in chromaffin cells. The present work describes the preparation of recombinant scinderin and peptides Sc-ABP1 and Sc-ABP2 with sequences corresponding to two actin-binding sites of scinderin. Recombinant scinderin and peptides Sc-ABP1 and Sc-ABP2 were tested for their effects on Ca(2+)-induced serotonin release from digitonin permeabilized platelets. The results indicated that recombinant scinderin potentiates Ca(2+)-evoked serotonin release, an effect blocked in the presence of Sc-ABP1, Sc-ABP2, exogenous gamma-actin, or the addition of phosphatidylinositol 4,5-bisphosphate (PIP2). In the presence of a mismatched peptide (MMP) the potentiating effect of recombinant scinderin was not affected. Moreover, Sc-ABP1, Sc-ABP2, and gamma-actin inhibited Ca(2+)-induced release of serotonin in the absence of recombinant scinderin, suggesting an inhibition of platelet endogenous scinderin. MMP was ineffective under these conditions. The results suggest that F-actin disassembly, perhaps at a specific site, is required for platelet secretion and that scinderin might be an important component of the exocytotic machinery in platelets.

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Human Platelets Contain Scinderin, a Ca2+-Dependent Actin Filament-Severing Protein

Tchakarov

et al. 1992

Thromb Haemost

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SummaryA large body of biochemical and morphological evidence suggests that actin polymerizes in response to various stimuli which activate platelets. Previous work has shown the presence in platelets of gelsolin, a Ca2+-dependent regulator of actin filament length. This present work demonstrates that human platelets contain scinderin, another Ca2+-dependent actin filament-severing protein recently discovered in our laboratory. Extracts prepared from platelets were subjected to DNase-I-Sepharose 4B affinity chromatography. EGTA eluates from the affinity columns contained scinderin as demonstrated by mono and two-dimensional polyacrylamide gel electrophoresis and immunoblotting with scinderin antibodies. The concentration of scinderin in platelets was 75 fmol/mg total protein. This might represent 11% of the total actin filament-severing activity if both proteins are equally potent, on a molar basis, in severing actin filaments. Double staining immunocytochemical studies with antibodies against scinderin and rhodamine phalloidin, a probe for F-actin, also demonstrated the presence of scinderin in platelets. These findings suggest that scinderin may participate in the regulation of platelet actin networks.

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Change of quantal size and parameters of release with stimulation in bovine chromaffin cells

2001

Pflügers Arch - Eur J Physiol

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Changes in quantal size and in the parameters of release were examined in chromaffin cells using amperometric recordings during and following various stimuli that induce secretion. As a general rule, a greater quantal content was associated with a greater quantal size. Following a short depolarizing pulse (0.5-2 s; 100 mV from a holding potential of -80 mV), the mean value of quantal size increased by 54% over several seconds before gradually (over tens of seconds) returning toward the control value, whilst its variability rose by 62%. The changes observed following 30-s applications of high extracellular K+ (50 mM) were more modest. A rapid application of short depolarizing pulses (2 s every 10-20 s; 100 mV from a holding potential of -80 mV) also led, at least initially, to greater quantal content and quantal size. Mean quantal size rose initially by 68%, but decreased subsequently to 31% below pre-stimulation levels. In whole-clamped cells, the frequency of quantal release can rise abruptly, probably owing to a mechanical disturbance that makes the membrane leaky to Ca2+. In such cases, a marked rise in quantal content (>ten-fold) was paralleled by an almost as dramatic (up to ten-fold) rise in quantal size and an important, although less pronounced and slower, rise in its variability (up to four-fold). The return toward control values of mean quantal size occurred over several minutes, whilst its variability decayed more slowly. The release parameters were evaluated directly from the number of events to avoid a large and time-dependent contribution of the amplitude variability of spontaneous amperometric current spikes (minis). In general, the greater probability of release contributed more than the greater size of the immediately available store to the increase in quantal output. In conclusion, quantal size was found to be highly labile. Its change can alter strongly the facilitation and depression of evoked quantal output and probably occurs due to a preferential release of large vesicles that are more efficient barriers to Ca2+ diffusion when Ca2+ rises rapidly following a synchronous opening of several Ca2+ channels. When intracellular Ca2+ levels rise slowly to threshold levels for secretion, as during an asynchronous and generally spontaneous release, vesicles are less effective diffusion barriers and quantal size changes less.

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Scinderin and cortical F-actin are components of the secretory machinery

1999

Rev. can. physiol. pharmacol.

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Secretory vesicle exocytosis is the mechanism of release of neurotransmitters and neuropeptides. Secretory vesicles are localized in at least two morphologically and functionally distinct compartments: the reserve pool and the release-ready pool. Filamentous actin networks play an important role in this compartmentalization and in the trafficking of vesicles between these compartments. The cortical F-actin network constitutes a barrier (negative clamp) to the movement of secretory vesicles to release sites, and it must be locally disassembled to allow translocation of secretory vesicles in preparation for exocytosis. The disassembly of the cortical F-actin network is controlled by scinderin (a Ca(2+)-dependent F-actin severing protein) upon activation by Ca2+ entering the cells during stimulation. There are several factors that regulate scinderin activation (i.e., Ca2+ levels, phosphatidylinositol 4,5-bisphosphate (PIP2), etc.). The results suggest that scinderin and the cortical F-actin network are components of the secretory machinery.

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Trifaró Jm

Cytoskeleton dynamics during neurotransmitter release

Recombinant scinderin, an F-actin severing protein, increases calcium- induced release of serotonin from permeabilized platelets, an effect blocked by two scinderin-derived actin-binding peptides and phosphatidylinositol 4,5-bisphosphate

Human Platelets Contain Scinderin, a Ca2+-Dependent Actin Filament-Severing Protein

Change of quantal size and parameters of release with stimulation in bovine chromaffin cells

Scinderin and cortical F-actin are components of the secretory machinery

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