Role of Platelet Size Revisited-Function and Protein Composition of Large and Small Platelets.

Epidemiological studies found an association between increased platelet size and the risk for thrombotic complications, but functional differences of large and small platelets remain poorly understood due to a lack of standardized protocols separating platelets with different size. We designed a protocol to separate large and small platelets from 15 mL whole blood. Separated large and small platelet fractions differed in mean platelet volume: 12.1 fl (10.3-13.8 fl) versus 7.7 fl (6.8-9.5 fl, p < 0.01), and forward scatter mean fluorescence intensity: 24.75 (19.9-30.9) versus 16.85 (11.3-20.6; p < 0.01). Similar fold differences were observed in cell diameter and plateletcrit. Large platelets express 30 to 50% more glycoprotein (GP) Ia, GPIb, GPIIIa, GPVI and P2Y12 on their membranes compared with small ones. Single large platelets covered a 50% larger area on a collagen surface. Adhesion to collagen was faster in large platelets compared with small ones indicating enhanced outside-in signal transduction in large platelets via collagen receptors. In contrast, integrin activation was more pronounced in small platelets after ADP stimulation. Proteome analysis revealed that 80 of the 894 proteins quantified differed in abundance: ADP-ribosylation factor 1/3, guanosine triphosphate-binding protein SAR1a, Voltage-dependent anion-selective channel protein 3 and guanylate cyclase soluble sub-unit α-3 were higher abundant in large, whereas immunoglobulins, haptoglobin, hemopexin, α-1-antitrypsin, serotransferrin and vitronectin were more abundant in small platelets. We conclude that some functions and the protein composition of large and small platelets differ, which cannot only be explained by the size difference. Our data suggest different functional roles of large and small platelets.

The effects of salt stress cause a diversion of basal metabolism in barley roots: possible different roles for glucose-6-phosphate dehydrogenase isoforms.

In this study the effects of salt stress and nitrogen assimilation have been investigated in roots of hydroponically-grown barley plants exposed to 150 mM NaCl, in presence or absence of ammonium as the sole nitrogen source. Salt stress determines a diversion of root metabolism towards the synthesis of osmolytes, such as glycine betaine and proline, and increased levels of reduced glutathione. The metabolic changes triggered by salt stress result in a decrease in both activities and protein abundance of key enzymes, namely GOGAT and PEP carboxylase, and in a slight increase in HSP70. These variations would enhance the requirement for reductants supplied by the OPPP, consistently with the observed increase in total G6PDH activity. The involvement and occurrence of the different G6PDH isoforms have been investigated, and the kinetic properties of partially purified cytosolic and plastidial G6PDHs determined. Bioinformatic analyses examining co-expression profiles of G6PDHs in Arabidopsis and barley corroborate the data presented. Moreover, the gene coding for the root P2-G6PDH isoform was fully sequenced; the biochemical properties of the corresponding protein were examined experimentally. The results are discussed in the light of the possible distinct roles and regulation of the different G6PDH isoforms during salt stress in barley roots.

Purification and biochemical characterisation of a glucose-6-phosphate dehydrogenase from the psychrophilic green alga Koliella antarctica.

Psychrophilic organisms have evolved a number of modifications of cellular structures to survive in the cold environment; among them it is worth noting an increased efficiency of enzymes at lower temperatures. Glucose-6-phosphate dehydrogenase (G6PDH; EC 1.1.1.49) was purified and characterised from the psychrophilic green alga Koliella antarctica (Trebouxiophyceae, Chlorophyta) from the Ross Sea (Antarctica). It was possible to isolate a single G6PDH using biochemical strategies; its maximum activity was measured at 35 °C, and the enzyme showed an E (a) of 39.6 kJ mol(-1). This protein reacted with antibodies raised against higher plants plastidic isoforms. KaG6PDH showed peculiar kinetic properties, with a K (iNADPH) value lower than [Formula: see text]. Notably, catalytic activity was inactivated in vitro by DTT and chloroplastic thioredoxin f. These biochemical properties of G6PDH are discussed with respect to higher plant G6PDHs and the adaptation of K. antarctica to polar low-temperature environment.