Gerald Soslau

A possible dual physiological role of extracellular ATP in the modulation of platelet aggregation

ATP and ADP are simultaneously released from activated platelets in equimolar concentrations. Micromolar concentrations of ATP inhibit platelet aggregation by both competitive and non-competitive mechanisms. The current studies addressed the question of how platelets respond to agonists in the presence of nanomolar and micromolar concentrations of ATP and ADP alone or in combination. This is a significant issue since the concentration of ATP +/- ADP may vary widely within a microenvironment depending upon the source and cause for the release of the nucleotides. ATP (1-10 nM) was found to significantly enhance the thromboxane A2 analog, U44619-, collagen- and thrombin-induced platelet aggregations. Conversely, ATP at 1-100 microM inhibited these same reactions. ADP, in general, behaved exactly opposite to ATP. When equal amounts of ATP and ADP were added together the ADP response appeared to predominate. The observed ATP-induced response was not due to a hydrolytic product as evidenced by an unaltered response to ATP in the presence of adenosine deaminase or the ATP generating system, creatine phosphate plus creatine phosphokinase. Adenosine (1-10 nM), like ADP, inhibited agonist-induced platelet aggregation. The stimulation of agonist-induced platelet aggregation by 1-10 nM extracellular ATP appears to depend upon the phosphorylation of platelet membrane ecto proteins. The ATP analog, beta gamma-methylene ATP, that is incapable of serving as a phosphate donor for protein kinases, inhibited rather than stimulated agonist-induced platelet aggregation. The dual response of platelets to low and high concentrations of extracellular ATP +/- ADP may play a physiological role in hemostasis and thrombosis under normal and pathological conditions.

The loss of sialic acid and its prevention in stored human platelets

The loss of sialic acid was determined in human platelets stored during a seven day period in their homologous plasma. Approximately 30% of the sialic acid was lost during the first three days of incubation at room temperature and a total of 73% was lost after seven days. The rapid in vitro loss of sialic acid may mimic a slower in vivo loss. It was found that platelets with a greater density had a higher sialic acid content than the less dense platelets. The loss of sialic acid from stored platelets could be completely inhibited by the addition of silyl compounds to the incubation plasma. The trisaccharide, N-acetylneuramin-lactose, gave a greater degree of protection than fetuin at comparable concentrations.

Extracellular ATP inhibits agonist-induced mobilization of internal calcium in human platelets

Our previous studies have demonstrated that platelets possess ATP purinergic receptors in addition to the ADP, P2T, receptor. Occupancy of the P2 receptor by ATP inhibited agonist-induced platelet aggregation. This study demonstrated that the mechanism of inhibition may involve ATP inhibition of agonist-induced mobilization of internal calcium. Within the cardiovascular system, the ATP inhibition of calcium mobilization is unique to platelets. All other cell types in the cardiovascular system, where calcium mobilization is affected by extracellular ATP, responded with an increased mobilization as opposed to inhibition. The platelet inhibitory response to ATP was enhanced by the addition of an ATP generating system, creatine phosphate/phosphocreatine kinase. ATP and ATP analogues were found to inhibit calcium mobilization with a rank order of alpha beta-methylene ATP, beta gamma-methylene ATP approximately ATP > benzoyl ATP > 2 methylthio ATP which is a characteristic of P2x-like receptors. The inhibitory effect of ATP could be abrogated by prolonged treatment of platelets with the P2x desensitizing agent, alpha beta-methylene ATP. Also, UTP and CTP were approximately as effective inhibitors as ATP while GTP was not. ATP competition with ADP for the P2T receptor was excluded in studies with platelets derived from an aspirin-treated individual which were essentially insensitive to ADP. The agonist-induced calcium mobilization and inhibition by ATP occurred with the thromboxane A2 mimetic, U46619, collagen and thrombin; however, the kinetics of mobilization varied somewhat with the different agonists. The responses to extracellular ATP were independent of extracellular Ca2+, where 1 mM calcium or 0.3 mM EGTA was added to the reaction mixture. The inhibition of calcium mobilization coupled to inhibition of platelet aggregation by extracellular ATP may serve an important physiologic role. ATP, released from activated platelets at localized sites of vascular injury, may help to limit the size of the platelet plug-clot that, if left unregulated, could occlude the injured blood vessel.

Cerastes cerastes (Egyptian sand viper) venom induced platelet aggregation as compared to other agonists

The Egyptian Sand Viper (Cerastes cerastes) crude venom and subfractions were, for the first time, shown to induce platelet aggregation with agonist activities present in two subfractions. The combined activities of the crude venom components behaved in a unique fashion as compared to the platelet agonists, ADP, collagen and thrombin. The action of the venom was inhibited by conditions that increased cAMP, partially required the formation of thromboxane A2 and was inhibited by the serine protease inhibitor PMSF while being only partially sensitive to leupeptin or soybean trypsin inhibitor. One of the fractionated venom agonists strongly induced serotonin release while the other venom agonist essentially did not. Further characterization of the Cerastes cerastes venom components should broaden our knowledge of the pathology of snake venoms, platelet aggregation and their potential therapeutic value.

Differential activation and inhibition of human platelet thrombin receptors by structurally distinct α-, β- and γ-thrombin

The development of drugs to neutralize the action of thrombin has to date focused on the α form of the protease. It is generally agreed that inactive prothrombin is proteolytically converted to active α-thrombin which may be further hydrolyzed to β- and γ-thrombin. While all three forms of the enzyme retain catalytic activities, only α-thrombin is presumed to be physiologically important. The β- and γ-thrombin are presumed to be degradation products of no physiological significance. Our demonstration that β- and γ-thrombin selectively activate PAR-4 in this and a previous report (J. Biol. Chem. 276, 21173–21183, 2001) necessitates a reevaluation of how we view their physiological roles and how we approach the pharmacological regulation of their actions. β-Thrombin, like γ-thrombin, at nM levels selectively activates PAR-4. This was demonstrated by full retention of aggregatory activity with platelets whose PAR-1 and GP Ib receptors were inactivated. Furthermore, the β-thrombin response was abrogated by desensitizing platelets with suboptimal levels of the thrombin receptor activating peptide for PAR-4 (TRAP-4). For β-thrombin and γ-thrombin to have a physiological role, it is necessary to show they can be generated under physiological conditions. We demonstrate, for the first time, that α-thrombin is hydrolyzed in less than 1 min by activated factor X at physiological pH, in vitro. This implies that α-thrombin may be rapidly converted to β-thrombin and/or γ-thrombin in vivo in the proper microenvironment. The differential activation of the three platelet thrombin receptors by α-, β- and γ-thrombin implies selective structural variations between these thrombin species. Structural differences are likely to account for the marked differential responses observed with the antithrombotic, hirudin, which inhibits α-thrombin, is a slightly weaker inhibitor of β- thrombin and a very weak inhibitor of γ-thrombin-induced platelet aggregations. The converse order of inhibition is observed with the physiological protease inhibitor, α1-antitrypsin. Finally, a non-traditional inhibitor, histone-1, selectively inhibits only β- and γ-thrombin, primarily at the receptor level of PAR-4 rather than on the thrombin molecule. Trypsin, like β- and γ-thrombin, activates PAR-4 and is also inactive with TRAP-4 desensitized platelets. Therefore, it was reasoned that trypsin would be more structurally similar to γ-thrombin than to α-thrombin. The analysis of the crystalline structures of α-, γ-thrombin and trypsin from the databases confirm that this is the case. These findings should help to elucidate structure-function relationships of the different thrombins and may aid in the development of new anti-thrombotic drugs.

Mitochondrial DNA topoisomerase I from human platelets

An anucleated cell system has been used for the first time to study mitochondrial topoisomerase activity. Mitochondrial extracts from human blood platelets contained type I topoisomerase. The type I classification was based on ATP-independent activity, inhibition by ATP or camptothecin, and the lack of inhibition by novobiocin. Platelet mitochondrial topoisomerase I relaxation activity was inhibited linearly by increasing concentrations of EGTA. Topoisomerase activity greater than 90% inhibited by 175 microM EGTA was partially restored to 16 and 50% of the initial level of activity by the subsequent addition of 50 and 100 microM Ca2+, respectively. Additionally, results from studies of partially purified platelet mitochondrial topoisomerase I were consistent with the crude extract data. This work supports the hypothesis that platelet mitochondria contain a type I topoisomerase that is biochemically distinct from that previously isolated and characterized from cell nuclei.

Characterization of a potent platelet aggregation inducer from Cerastes cerastes (Egyptian sand viper) venom

A potent, proteinaceous inducer of platelet aggregation designated as IVa, has been purified to homogeneity from Cerastes cerastes venom by molecular sieve and ion exchange chromatography. It is composed of 2 subunits with total M(r) of 62,000 as shown by native gel chromatography and chemical cross-linking with disuccinimidyl suberate. It is not clear at the present time whether both subunits are identical gene products, however, both have identical N-terminal sequences for the first 15 amino acids. The protein has a pI above 9.6. IVa (0.1 micrograms/ml) could aggregate platelets up to 80% and was inhibited by p-APMSF, leupeptin, iodoacetamide, protein kinase C inhibitor, phosphatase inhibitor, ATP and PGE1, while it was insensitive to acetylsalicylic acid, ADP scavenger system, protein kinase A inhibitor and hirudin. Protein IVa is a serine proteinase with thrombin-like activity as it hydrolysed thrombin chromogenic substrate CBS 34.47, its aggregatory activity was partially inhibited by monoclonal antibodies against GPIb and the thrombin receptor, as was the thrombin, and its ability to induce intracellular Ca2+ release was blocked by pretreating platelets with thrombin. Unlike thrombin, the IVa protein showed very weak coagulant activity as indicated by plasma recalcification time and fibrinogen clotting time although it could hydrolyse fibrinogen alpha-chains.

Immunological idenTIFication of human platelet mitochondrial DNA topoisomerase I

A nuclear human blood platelets have been used to study mitochondrial topoisomerase activity in the absence of nuclear contamination. Previous work utilizing this novel system demonstrated that platelet mitochondria contain type-I topoisomerase (Kosovsky, M.J. and Soslau, G. (1991) Biochim. Biophys. Acta 1078, 56-62). The present work has demonstrated that mitochondrial topoisomerase activity was inhibited by the specific topoisomerase-I inhibitor, topotecan, yet was not affected by a specific topoisomerase-II inhibitor, VM-26. These results confirm that platelet mitochondria contain topoisomerase I, yet do not contain a detectable level of topoisomerase-II activity. It has been demonstrated for the first time that antibodies directed against nuclear topo I cross-react with mitochondria topo I. Furthermore, immunoblot analysis of platelet mitochondrial proteins, in conjunction with renaturation studies, has led to the identification of a catalytically active 60-kDa form of mitochondrial topoisomerase I.

In vitro incorporation of fucose and methionine into human platelet proteins

Abstract Human blood platelets, maintained in vitro , incorporate labelled methionine into a variety of high molecular weight proteins and labelled fucose into a different set of glycoproteins. The incorporation of methionine is completely sensitive to cycloheximide and partially sensitive to chloramphenicol and leucovorin demonstrating de novo synthesis. The incorporation of fucose is insensitive to these inhibitors but inhibited by 6-thioguanine which would indicate that a fucosyl transferase is adding the sugar onto pre-existing glycoproteins. Some of the fucosyl-glycoproteins correspond to surface glycoproteins.

Phosphoproteins altered by antiproliferative doses of human interferon-β in a human bladder carcinoma cell line

Phosphoproteins of control and IFN-beta treated human bladder carcinoma cells (RT4) were labelled in vitro with [32P]-ATP and analyzed by polyacrylamide gel electrophoresis. Cells treated with antiproliferative doses of IFN had reduced levels of phosphorylated 60 Kd and 40 Kd proteins. IFN also induced within 24 hours the modification of a low molecular weight phosphoprotein doublet in the 22-24,000 molecular weight range. The ability to phosphorylate high molecular weight proteins by the in vitro procedures was generally depressed by IFN treatment. There was a dramatic shift in the phosphorylation of alkali stable phosphoamino acids associated with proteins in the 43-50,000 molecular weight range in IFN-treated cells. Preliminary studies indicate that at least some of the IFN-induced modifications of cellular phosphoproteins may result from transcriptional control of specific oncogenes.