Adenine nucleotide metabolism of blood platelets. VIII. Transport of adenine into human platelets

Adenine uptake into human blood platelets is a carrier-mediated process with a K_m of 159±21 nM and a V of 100±10 pmoles/min per 10⁹ platelets (in citrated platelet-rich plasma). The Q₁₀ was 2.53±0.22. A pH optimum was found at 7.5. Washing of the platelets increased the K_m to 453±33 nM and V to 397±38 pmoles/min per 10⁹ platelets. The change in shape induced in platelets by ADP was accompanied by an increase in V (2 times) and K_m (1.5 times).Guanine (K_i 50 μM), hypoxanthine (K_i 390 μM), adenine-N′-oxide (K_i 40 μM), adenosine (K_i 100 μM), RA 233 (K_i 75 μM) and papaverine (K_i 15 μM) acted as competitive inhibitors. Adenosine at low concentrations, and prostaglandin E₁ gave inhibition at only high adenine levels. A similar inhibition was obtained with 2-deoxy-d-glucose. Sulfhydryl-group inhibitors, pyrimidines and ouabain had no effect.     

On the degradation of heparin by human blood platelets.

Human blood platelets are able to degrade heparin from different tissues and species. The main degradation product is an oligosaccharide. Low molecular weight components such as inorganic sulfate or monosaccharides, i.e. products released by exoenzymes are not detected. The in vitro degradation of heparin by the crude enzyme is observed at pHs below 6.5 with an optimum temperature around 37 degrees C. The presence of sulfate in the substrate structure is shown to be essential for the enzyme activity. Since the oligosaccharides formed have only 10 per cent of the anticoagulant activity of the heparins tested, it is conceivable that the platelet enzyme may play an important role in the inactivation of some of the biological properties of heparin.     

Structure-function relationships in the interaction of alpha-thrombin with blood platelets.

Highly purified alpha-thrombin has been chemically modified in an attempt to determine which features of the molecule are important for normal platelet-thrombin interactions. Modifying agents included diisopropylphosphorofluoridate and 1-chloro-3-tosylamido-7-amino-L-2-heptanone, which modify serine and histidine, respectively, at the catalytic site, as well as N-bromosuccinimide and 2-hydroxy-5-nitrobenzyl bromide, which modify a single tryptophan at or near the fibrinogen-binding site. Active site-directed modification did not appreciably affect the binding characteristics, but prevented platelet activation. In contrast, modification of tryptophan at the macromolecular substrate-binding site resulted in the loss of high affinity binding of thrombin to platelets, while low affinity binding was apparently unaffected. This modification altered but did not abolish the ability of thrombin to effect platelet aggregation and release of [14C]serotonin. These results suggest that residues at the catalytic site are not involved in binding and that the macromolecular substrate-binding site of alpha-thrombin participates in high affinity binding to platelets. These data are also consistent with the existence of at least two types of binding sites for thrombin on the platelet surface as well as more than one platelet-binding region on the thrombin molecule.     

Adenosine and blood platelets

Adenosine is an important regulatory metabolite and an inhibitor of platelet activation. Adenosine released from different cells or generated through the activity of cell-surface ectoenzymes exerts its effects through the binding of four different G-protein-coupled adenosine receptors. In platelets, binding of A₂ subtypes (A_2A or A_2B) leads to consequent elevation of intracellular cyclic adenosine monophosphate, an inhibitor of platelet activation. The significance of this ligand and its receptors for platelet activation is addressed in this review, including how adenosine metabolism and its A₂ subtype receptors impact the expression and activity of adenosine diphosphate receptors. The expression of A₂ adenosine receptors is induced by conditions such as oxidative stress, a hallmark of aging. The effect of adenosine receptors on platelet activation during aging is also discussed, as well as potential therapeutic applications.     

Isolation of palmitoyl-CoA hydrolases from human blood platelets.

The palmitoyl-CoA hydrolase activity, which in human blood platelets is mainly localized in the cytosol fraction [Berge, Vollset & Farstad (1980) Scand. J. Clin. Lab. Invest. 40, 271--279], was found to be extremely labile. Inclusion of glycerol or palmitoyl-CoA stabilized the activity during preparation. Gel-filtration studies revealed multiple forms of the enzyme with molecular weights corresponding to about 70 000, 40 000 and 24 000. The relative recovery of the mol.wt.-70 000 form was increased by the presence of 20% (v/v) glycerol or 10 microM-palmitoyl-CoA. The three enzyme forms are probably unrelated, since they were not interconvertible. The three different species of palmitoyl-CoA hydrolase were purified by DEAE-cellulose and hydroxyapatite chromatography, isoelectric focusing and high-pressure liquid chromatography (h.p.l.c.) to apparent homogeneity. The three enzymes had isoelectric points (pI) of 7.0, 6.1 and 4.9. The corresponding molecular weights were 27 000--33 000, 66 000--72 000 and 45 000--49 000, calculated from h.p.l.c. and Ultrogel AcA-44 chromatography. The apparently purified enzymes were unstable, as most of the activity was lost during purification. The enzyme with an apparent molecular weight of 45 000--49 000 was split into fractions with molecular weights of less than 10 000 by re-chromatography on h.p.l.c. concomitantly with a loss of activity. The stimulation of the activity by the presence of serum albumin seems to depend on the availability of palmitoyl-CoA, as has been reported for other palmitoyl-CoA hydrolases. [Berge & Farstad (1979) Eur. J. Biochem. 96, 393--401].     

Activation time of blood platelets

Summary Blood platelets react rapidly in their hemostatic function. Determination of the reaction or activation time of individual platelets is difficult because it requires that physical and/or chemical effectors of activation are nonlimiting. Analysis of experimental conditions shows that the best estimate of mean activation time comes fromin vivo measurements. Thus, the constancy of height-to-length ratio of a growing thrombus, and its change with flow rate, provide additional evidence for the activation time hypothesis.Dedicated with admiration and affection to the memory of Walther Wilbrandt, a very dear friend.     

Adaptor proteins of blood platelets

Adaptor proteins play a pivotal role in the regulation of signal transduction events elicited after the engagement of cell surface receptors. Platelets exhibit a number of integral membrane receptors capable of initiating a cellular response. These include collagen receptors, von Willebrand factor receptors, the fibrinogen receptor, and a number of G-protein coupled receptors, such as those for thrombin and ADP. The primary function of platelet receptors is the translation of externally applied signals into appropriate responses leading to platelet activation being a prerequisite for normal hemostasis. Multitude of signalling pathways described in platelets is based on the interaction of compounds of many different categories, such as transmembrane receptors, protein kinases, protein phoshatases, G-proteins, transmembrane and cytosolic adaptor proteins, phosphoinositides, cyclic AMP or GMP. Adaptor proteins lack intrinsic effector function, but contain distinct molecular domains, which mediate protein-protein and protein-lipid interactions. These molecules thus serve as a scaffolding, around which effectors and their substrates are assembled into three-dimensional signaling complexes. Adaptor proteins integrate receptor-mediated signals at intracellular levels and couple signaling receptors to cytosolic signaling pathways. While the function of adaptor proteins is well established in immune cells, the knowledge about their role in platelet activation is still at the onset Over the last decade numerous adaptor proteins have been identified in platelets and shown to be involved in accurate assembly of intracellular signaling complexes. Collagen-induced platelet intracellular signaling through GPVI resembles the functional response of B- and T-cell antigen receptors and is the best described in the literature. This review focuses on the structure and functional role of the most extensively studied adaptor proteins during platelet activation induced by physiological agonists.