Effects of Plasmin on Rabbit Platelets

The effects of plasmin have been examined because platelets may be exposed to plasmin in vivo and treatment of platelets with plasmin shortens platelet survival. Rabbit plasmin was prepared by urokinase activation of plasminogen immobilized on lysine- Sepharose. Plasmin caused rabbit platelets to aggregate and release the contents of their amine storage granules, but aggregation was slower than in response to ADP or thrombin. EDTA, prostaglandin E1, or creatine phosphate/creatine phosphokinase were inhibitory, but indomethacin was not. Deaggregation did not occur when platelets had been aggregated by a concentration of plasmin that caused extensive release of granule contents. EDTA or prostaglandin E1 caused deaggregation. Low concentrations of ADP and plasmin acted synergistically in causing platelet aggregation. Plasmin decreased the amounts of platelet membrane glycoproteins that stained with periodic acid-Schiff reagent; glycoprotein I was more susceptible than glycoproteins II and III. Concentrations of plasmin that induced the release of amine storage granule contents also released PAS- staining granule gylcoproteins.

Platelets incubated with plasmin, washed and resuspended, were not aggregated by ADP, but were aggregated strongly by the combination of fibrinogen and ADP, and bound 125I-fibrinogen to a greater extent than untreated platelets. Platelets preincubated with a high concentration of plasmin were unresponsive to thrombin, but were sometimes aggregated by fibrinogen.

Plasmin decreased the buoyant density and increased the median size of platelets. Thus plasmin, as well as ADP and thrombin, may contribute to the density shift observed in platelets from rabbits in which thrombosis and continuous vessel injury have been induced.

Eicosapentaenoic Acid Interferes with U46619-Stimulated Formation of Inositol Phosphates in Washed Rabbit Platelets

Eicosapentaenoic acid (EPA) inhibits platelet responsiveness to aggregating agents. To investigate the reactions that are affected by EPA, we examined the effect of preincubating aspirintreated rabbit platelets with EPA on stimulation of inositol phosphate formation in response to the TXA2 analogue U46619. Stimulation of platelets with U46619 (0.5 μM) caused aggregation and slight release of dense granule contents; aggregation and release were inhibited by preincubation of the platelets with EPA (50 μM) for 1 h followed by washing to remove unincorporated EPA. Incubation with EPA (50 μM) for 1 h did not cause a detectable increase in the amount of EPA in the platelet phospholipids. When platelets were prelabelled with [3H]inositol stimulation with U46619 of control platelets that had not been incubated with EPA significantly increased the labelling of mos1tol phosphates. The increases in inositol phosphate labelling due to U46619 at 10 and 60 s were partially inhibited by premcubat10n of the platelets with 50 μM EPA. Since the activity of cyclo-oxygenase was blocked with aspirin, inhibition of inositol phosphate labelling in response to U46619 indicates either that there may be inhibition of signal transduction without a detectable change in the amount of EPA in platelet phospholipids, that changes in signal transduction require only minute changes in the fatty acid composition of membrane phospholipids, or that after a 1 h incubation with EPA, activation of phospholipase C is affected by a mechanism that is not directly related to incorporation of EPA.

The Effect of Thrombin on Platelet Accumulation on the Vessel Wall - Influence of Heparin and Aspirin

Rabbit aortae were removed from exsanguinated rabbits, washed, everted on probes, treated with thrombin, washed to remove unbound thrombin and used to measure the accumulation of 51Cr-labeled platelets in vitro. Thrombin pretreatment of normal rabbit aortae did not cause platelet accumulation on the endothelium; platelets appeared to accumulate only at sites where the subendothelium had been exposed. The quantitative data obtained with 51Cr-labelled platelets was reinforced by observations by scanning electron microscopy. 125I-labelled thrombin became associated with the endothelium and also with de- endothelialized vessels, and some of it could be displaced by high concentrations of heparin. Exposure of vessels to heparin after thrombin treatment eliminated the enhanced platelet accumulation caused by the thrombin treatment, probably because heparin displaced thrombin from the aortae, as demonstrated in experiments with 125I-thrombin. Inhibition of PGI2 production by aspirin treatment of the vessels did not enhance platelet accumulation on normal or thrombin-treated aortae. Thus, although thrombin treatment of the endothelium does not cause platelets to adhere to it, thrombin does cause increased platelet accumulation on the areas where the subendothelium is exposed or where endothelial cells are damaged.

Factors Influencing the Deaggregation of Human and Rabbit Platelets

The mechanisms involved in platelet deaggregation are unclear. Washed platelets from rabbits or humans aggregated by ADP can be deaggregated by EDTA or PGI2 if the release reaction has not occurred; during deaggregation 125I-fibrinogen dissociates from the platelets. Human platelets suspended in a medium without calcium undergo the release reaction during ADP-induced aggregation; EDTA, PGE, or PGI2 do not deaggregate these platelets although EDTA displaces much of the 125I-fibrinogen that associates with them during aggregation. Rabbit platelets aggregated by low concentrations of releaseinducing stimuli (sodium arachidonate, collagen or thrombin) can be deaggregated by EDTA, PGI2 or PGE1 and 125I-fibrinogen dissociates from them; with high concentrations of collagen or thrombin, deaggregation and dissociation of l25I-fibrinogen is slower. Human platelets that have undergone the release reaction in response to thrombin, collagen or a combination of sodium arachidonate and ADP are not readily deaggregated by EDTA or PGE1. Since aggregation and fibrinogen binding involving the glycoprotein IIb/IIIa complex are readily reversed by EDTA, and since Ca2+ is required for thrombospondin binding to activated platelets, there may be a third type of platelet-platelet adherence that is not disrupted by EDTA; this type of binding plays a greater role with human than with rabbit platelets.

Factors Influencing the Deaggregation of Chymotrypsin-Treated Human Platelets Aggregated by Fibrinogen

Washed human platelets aggregated by ADP can be deaggregated by EDTA or PGE1; provided the release reaction does not occur; when the release reaction occurs platelets deaggregate less readily. Platelets treated with chymotrypsin are aggregated by fibrinogen indicating that fibrinogen receptors may be permanently exposed by this treatment. Fibrinogen-induced aggregation of chymotrypsin-treated platelets provides another method of bringing platelets into close contact with each other. Although EDTA deaggregated chymotrypsin-treated platelets aggregated by fibrinogen in a medium containing a physiological concentration of Ca2+, EDTA did not deaggregate these platelets if they were in a medium without calcium in which the release reaction occurs. In this medium, when ASA was added to prevent the release reaction, EDTA caused deaggregation. More fibrinogen associated with platelets in the medium without calcium than in the calcium-containing medium. In both media, EDTA displaced approximately half of the fibrinogen indicating that deaggregation is not solely dependent on dissociation of fibrinogen from its receptors. Thus when platelets undergo the release reaction, a form of platelet-to-platelet adhesion occurs that is not disrupted by chelation of divalent cations and is therefore not likely to involve only fibrinogen or thrombospondin and fibrinogen since the association of fibrinogen with its receptor requires Ca2+ and the binding of thrombospondin to platelets that have undergone the release reaction is also dependent on Ca2+.

Deaggregation of Human Platelets Aggregated by Thrombin

Human platelets that have undergone the release reaction do not deaggregate readily. We examined conditions under which washed human platelets can be deaggregated after they have undergone an extensive release reaction induced by thrombin (1 or 5 U/ml). To make fibrinogen receptors unavailable, either CP/ CPK (or apyrase) was used to remove released ADP, or PGEi was used to increase cAMP. Chymotrypsin was used to digest proteins that might link platelets, and heparin to interact with released proteins and interfere with their binding to platelets and to each other. Individually, none of these caused deaggregation; heparin did not inhibit the effect of thrombin because no antithrombin III was present. Platelets exposed to thrombin (1 U/ ml) which was neutralized at 90 sec by hirudin, could be deaggregated by combinations of CP/CPK (or apyrase) and chymotrypsin, or PGE1 and chymotrypsin. When a higher concentration of thrombin was used (5 U/ml) these combinations caused platelets to deaggregate only when heparin was added before thrombin induced the release reaction. Thus, when extensive release occurs three mechanisms may come into play to link human platelets: one that requires the fibrinogen receptor; a heparin-sensitive reaction that may involve the binding of released proteins; and a linkage that can be disrupted only by proteolysis, providing the other two mechanisms are also inhibited.

Effect of cAMP Phosphodiesterase Inhibitors on ADP-Induced Shape Change, cAMP and Nucleoside Diphosphokinase Activity of Rabbit Platelets

The effects of cAMP phosphodiesterase inhibitors on ADP-induced shape change and cAMP concentrations have been studied. Caffeine (10 mM), theophylline (8 mM), dipyridamole (0.2 mM), or papaverine (0.05 mM) prevented the shape change of washed rabbit platelets induced by 0.4 μM ADP. At these concentrations, none of these cAMP phosphodiesterase inhibitors increased 14C-cAMP in platelets in which the cytoplasmic adenine nucleotides had been labelled with 14C-adenine. By a protein binding assay, only papaverine by itself increased platelet cAMP above its basal level. These results indicate that two pools of cAMP may exist in platelets. Both methods showed that stimulation of platelet adenylate cyclase with PGE1 (1 μM) resulted in an increase in platelet cAMP and all these cAMP phosphodiesterase inhibitors potentiated this increase caused by PGE1. By themselves, some of these compounds may act through mechanisms that do not involve platelet cAMP. The effects of these cAMP phosphodiesterase inhibitors on platelet nucleoside diphosphokinase (NDK) activity were also investigated. At concentrations that prevented ADP-induced shape change, papaverine and dipyridamole had no effect on the formation of 14C-ATP from 14C-ADP by washed rabbit platelets. The methylxanthines partially inhibited NDK activity of washed rabbit platelets and of isolated platelet membranes, probably due to the structural similarity between the adenine ring of ADP and these substances. However, adenine (8 mM) inhibited ADP-induced shape change and platelet NDK activity but was a less effective inhibitor of ADP-induced platelet aggregation. Thus it seems unlikely that interference with platelet NDK or the ADP receptor is the major mechanism by which the methylxanthines inhibit platelet functions.

Ticlopidine Facilitates the Deaggregation of Human Platelets Aggregated by Thrombin

Normal human platelets aggregated by thrombin undergo the release reaction and are not readily deaggregated by the combination of inhibitors hirudin, prostaglandin E1 (PGE1) and chymotrypsin. Released adenosine diphosphate (ADP) plays an important role in the stabilization of thrombin-induced human platelet aggregates. Since ticlopidine inhibits the platelet responses to ADP, we studied thrombin-induced aggregation and deaggregation of 14C-serotonin-labeled platelets from 12 patients with cardiovascular disease before and 7 days after the oral administration of ticlopidine, 250 mg b.i.d. Before and after ticlopidine, platelets stimulated with 1 U/ml thrombin aggregated, released about 80–90% 14C-serotinin and did not deaggregate spontaneously within 5 min from stimulation. Before ticlopidine, hirudin (5× the activity of thrombin) and PGE1 (10 μmol/1) plus chymotrypsin (10 U/ml) or plasmin (0.06 U/ml), added at the peak of platelet aggregation, caused slight or no platelet deaggregation. After ticlopidine, the extent of platelet deaggregation caused by the same inhibitors was significantly greater than before ticlopidine. The addition of ADP (10 μmol/1) to platelet suspensions 5 s after thrombin did not prevent the deaggregation of ticlopidine-treated platelets. Thus, ticlopidine facilitates the deaggregation of thrombin-induced human platelet aggregates, most probably because it inhibits the effects of ADP on platelets.

Pretreatment of Human Platelets with Plasmin Inhibits Responses toThrombin, but Potentiates Responses to Low Concentrations of Aggregating Agents, Including the Thrombin Receptor Activating Peptide, SFLLRN

Effects of plasmin on platelets, that influence subsequent responses to aggregating agents, are relevant to attempts to prevent rethrombosis following administration of fibrinolytic agents. We describe plasmin-induced inhibition of platelet responses to thrombin, but potentiation of responses to other aggregating agents. Washed human platelets were labeled with 14C-serotonin, treated for 30 min at 37° C with 0, 0.1 or 0.2 CU/ml of plasmin, followed by aprotinin, washed and resuspended in a Tyrode-albumin solution with apyrase. Incubation with 0.2 CU/ml of plasmin almost completely inhibited thrombin-induced (0.1 U/ml) aggregation, release of 14C-serotonin, and increase in cytosolic [Ca2+]. In contrast, with plasmin-pretreated platelets, aggregation and release of 14C-serotonin were strongly potentiated in response to low concentrations of the thrombin receptor-activating peptide SFLLRN, ADP, platelet-activating factor, collagen, arachidonic acid, the thromboxane mimetic U46619, and the calcium ionophores A23187 and ionomycin. Aspirin or RGDS partially inhibited potentiation. Plasmin-pretreated platelets resuspended in plasma anticoagulated with FPRCH2C1 (PPACK) also showed enhanced responses to aggregating agents other than thrombin. The contrasting effects on responses to thrombin and SFLLRN are noteworthy. Plasmin cleaves GPIIb/IIIa so that it becomes a competent fibrinogen receptor, and binding of 125I-fibrinogen during ADP-induced aggregation was greatly potentiated within 10 s. Potentiation of aggregation by other agonists may be due to increased binding of released fibrinogen. Thus, platelets freed from a thrombus may have increased responsiveness to low concentrations of aggregating agents other than thrombin. These results provide further support for the use of inhibitors of platelet reactions in conjunction with administration of fibrinolytic agents.

Probenecid Inhibits Platelet Responses to Aggregating Agents in Vitro and Has a Synergistic Inhibitory Effect with Penicillin G

Probenecid is an anion channel blocker and uricosuric agent, originally developed to slow the rate of excretion of penicillin. It is now also administered with many other drugs to reduce their required dosages. Recently, probenecid (2.5 mM) has been used to prevent leakage of fura-2 or fluo-3 when these indicators of cytosolic Ca2+ levels have been introduced into cells. However, we found that probenecid markedly inhibited the increases in cytosolic Ca2+ caused by ADP, thrombin, the thrombin receptor-activating peptide (SFLLRN, TRAP), ADP, sodium arachidonate, the thromboxane A2 (TXA2) mimetic U46619, and platelet-activating factor (PAF). This finding precluded the use of probenecid with platelets in measurements of cytosolic Ca2+ with indicators such as fura-2. We then investigated the effects of probenecid on aggregation and release of 14C-serotonin from prelabeled platelets. Responses to all the agonists were inhibited by 2.5 mM probenecid, but concentrations as low as 0.25-0.5 mM inhibited responses to agonists that act largely via TXA2 (collagen, sodium arachidonate and U46619). Collagen-induced TXA2 formation was inhibited in a dose-dependent manner. Responses of aspirin-pretreated platelets to thrombin, SFLLRN, U46619 and PAF were also inhibited by probenecid, indicating that prevention of TXA2 formation does not account for all the inhibitory effects. The combination of probenecid with penicillin G produced additive or synergistic inhibition of platelet responses; responses dependent on TXA2 were synergistically inhibited by concentrations of the drugs that are reached in vivo. The synergistic inhibitory effect of probenecid on platelet functions could further impair hemostasis if it has already been partially compromised by the administration of other drugs.

Platelet Accumulation on Fibrin-coated Polyethylene: Role of Platelet Activation and Factor XIII

Platelet accumulation on small- and medium-calibre vascular grafts plays a significant role in graft occlusion. We examined platelet accumulation on the surface of fibrin-coated polyethylene tubing (internal diameter 0.17 cm) during 10 min of flow (l0ml/min) at high wall shear rate (764 s-1). Washed platelets labelled with 51Cr were resuspended in Tyrode solution containing albumin, apyrase and red blood cells (hematocrit 40%). When the thrombin that was used to form the fibrin-coated surface was inactivated with FPRCH2C1 before perfusion of the tubes with the platelet:red blood cell suspension, the accumulation of platelets was 59,840 ± 27,960 platelets per mm2, whereas accumulation on fibrin with residual active thrombin was 316,750 ± 32,560 platelets per mm2 (n = 4). When the fibrin on the surface was cross-linked by including recombinant factor XIII (rFXIII) in the fibrinogen solution used to prepare the fibrin-coated surface, platelet accumulation, after thrombin neutralization, was reduced by the cross-linking from 46,974 ± 9702 to 36,818 ± 7964 platelets per mm2 (n = 12, p <0.01). Platelet accumulation on tubes coated with D-dimer was ten times less than on tubes coated with D-domain; this finding also supports the observation that cross-linking of fibrin with the formation of γ-γ dimers reduces platelet accumulation on the fibrin-coated surface. Thrombin-activated platelets themselves were shown to cross-link fibrin when they had adhered to it during perfusion, or in a static system in which thrombin was used to form clots from FXIII-free fibrinogen in the presence of platelets. Thus, cross-linking of fibrin by FXIII in plasma or from platelets probably decreases the reactivity of the fibrin-containing thrombi to platelets by altering the lysine residue at or near the platelet-binding site of each of the γ-chains of the fibrinogen which was converted into the fibrin of these thrombi.

Degranulation of Human Platelets by the Thrombin Receptor Peptide SFLLRN: Comparison with Degranulation by Thrombin

A new, simplified method of degranulating human platelets using the thrombin receptor peptide SFLLRN (20 |iM) is described; released fibrinogen cannot be converted to fibrin, and the platelets are not exposed to a proteolytic enzyme, as they are when thrombin is used for degranulation. The peptide-degranulated platelets regain their disc shape and are recovered as single platelets which have released approximately 90% of the contents of their dense granules. Their procoagulant activity is greater than that of control platelets, but somewhat less than that of thrombin-degranulated platelets. Without added fibrinogen, the peptide-degranulated platelets aggregate slightly in response to 50 μM SFLLRN, and to collagen, arachidonic acid, the thromboxane A2 mimetic U46619, platelet activating factor, ADP, and the divalent cation ionophore A23187; added fibrinogen enhances aggregation caused by these agonists. Extensive aggregation of peptide-degranulated platelets is caused by thrombin in the absence of added fibrinogen; it may be that the alternative thrombin receptor that is not activated by SFLLRN is responsible for the strong response to thrombin. Aggregation responses to most of the agonists are greater than those observed previously (10) with thrombin-degranulated platelets. By this method, platelets are obtained that have been degranulated in a way that is similar to in vivo degranulation. They are useful for studies of platelet responses without the complicating effects of released granule contents, and for investigation of the characteristics and functions of platelets that have come in contract with release-inducing agents in vivo.

Agglutination of Rabbit Platelets in Plasma by the Thrombin Inhibitor D-phenylalanyl-L-prolyl-L-arginyl Chloromethyl Ketone

The specific thrombin inhibitor D-phenylalanyl-L-prolyl-Larginyl chloromethyl ketone (FPRCH2Cl, PPACK) has been used as an anticoagulant with human blood to permit the preparation of platclct-rich plasma in which the physiological concentration of Ca2+ is maintained. When we attempted to use FPRCH2Cl(40 εM) as an anticoagulant for rabbit blood, clotting was prevented for at least 6 h at room temperature, but nearly all the platelets agglutinated. Thromboxane B2 was not formed and indomethacin and prostaglandin E1 were not inhibitory. The presence of citrate delayed this agglutination, but only EDTA (not EGTA) prevented it, indicating a dependence on Mg2+. Addition of FPRCH2Cl to suspensions of rabbit platelets in Tyrode-albumin solution had no effect on responses to ADP or collagen, but completely blocked all responses to human or rabbit thrombin. Thus plasma is required for the agglutination. Intravenous injection of FPRCH2Cl (5 mg/3 kg rabbit) reduced the platelet count to less than 50% by 15 to 25 min. Thus FPRCH2Cl cannot be used as an anticoagulant for rabbit blood when platelets are to be examined, and has a profound effect on the platelet count in vivo in rabbits. These effects should be considered when FPRCH2Cl is used as an antithrombotic agent for in vivo experiments with rabbits.

Effect of the Concentration of Ca2+ in the Suspending Medium on the Responses of Human and Rabbit Platelets to Aggregating Agents

The effect of the concentration of Ca2+ in the suspending medium of human and rabbit platelets on aggregation, release of 14C-serotonin, and TXB2 formation in response to ADP, thrombin, l-0-alkyl-2-acetyl-sn-glyceryl-3-phosphorylcholine (PAF), collagen and arachidonic acid was studied in either platelet-rich plasma anticoagulated with D-phenylalanyl-prolyl-arginyl chloromethylketone (PPACK) or citrate, or suspensions of washed platelets in modified Tyrode-albumin solutions containing 1 mM Mg2+ and concentrations of added Ca2+ ranging from 0 to 5 mM. In response to ADP, thrombin, or PAF, human platelets were stimulated to form TXA2 by close platelet contact in a low- Ca2+ medium; at physiological concentrations of Ca2+, TXB 2formation was much less and declined progressively as the concentration of Ca2+ was raised. When the formation of TXA 2was blocked with aspirin or indomethacin, aggregation and release by human platelets were strongest at physiological concentrations of Ca2+. Rabbit platelet responses differed markedly from those of human platelets because close contact of rabbit platelets in a low-Ca2+ medium did not promote TXA2 formation. Rabbit platelet responses were more strongly inhibited by the lack of added Ca2+ in the medium than the responses of human platelets, possibly because rabbit platelets do not contain releasable Ca2+.

In all studies of human platelets in media with low concentrations of Ca2+, the additional contribution to platelet responses of TXA2 formed because of close platelet contact should be considered because TXA2 formation is not usually stimulated in this way at physiological concentrations of Ca2+. When TXA2 formation is blocked, aggregation and release responses to all agonists are greatest at physiological concentrations of Ca2+. Thus, the responses of human platelets in media with low concentrations of Ca2+ (citrated platelet-rich plasma or artificial media to which no Ca2+ has been added) are abnormal in at least two ways, and do not correspond to the responses at physiological concentrations of Ca2+.

Persistence of procoagulant surface expression on activated human platelets: involvement of apoptosis and aminophospholipid translocase activity

BACKGROUND

Activated platelets express a procoagulant surface when the asymmetric distribution of membrane phospholipids is scrambled, leading to phosphatidylserine (PS) exposure. PS expression, associated with apoptosis in nucleated cells, would be expected to be reversed by aminophospholipid translocase (APLT) activity.

OBJECTIVE

To determine whether the procoagulant surface of activated platelets persists after it forms; to examine whether PS expression on platelets is associated with loss of mitochondrial inner membrane potential (DeltaPsi(m)), a hallmark of apoptosis; and to investigate the role of APLT in persistence of PS expression.

METHODS

Platelets were stimulated with thrombin, collagen, a combination of both, or the Ca(2+)-ionophore A23187. Up to 4 h after activation, procoagulant surface expression was measured by annexin A5 binding by flow cytometry and by a prothrombinase assay. Flow cytometry was also used to measure PS expression concurrently with DeltaPsi(m) collapse, using CMXRos. APLT activity in annexin A5-negative and -positive platelets was measured flow cytometrically as the percent of 1-palmitoyl-2-[6-[(7-nitro-2-1,3-benzoxadiazol-4-yl)amino]caproyl]-sn-glycero-3-phosphatidylserine (NBD-PS) translocated from the outer to the inner membrane leaflet.

RESULTS AND CONCLUSIONS

Procoagulant surface expression on activated platelets persisted in vitro for at least 4 h; if such persistence occurs in vivo, there are important implications for the propagation of thrombosis. With the physiological stimuli, only 10-20% of the activated platelets expressed PS on their surface, and of these, only a portion exhibited DeltaPsi(m) collapse, indicating that PS expression can be associated with platelet apoptosis, but can also occur independently. APLT activity was very low in the PS-expressing platelet subpopulation for up to 4 h after activation, indicating that the persistence of a procoagulant surface may be attributed, at least in part, to this reduced APLT activity.

Procoagulant surface exposure and apoptosis in rabbit platelets: association with shortened survival and steady-state senescence

BACKGROUND

The signal(s) for removal of senescent platelets from the circulation are not fully understood; phosphatidylserine (PS) expression on platelets and another marker of apoptosis, loss of mitochondrial inner membrane potential (DeltaPsim), have been implicated in platelet clearance.

OBJECTIVE

To investigate whether shortened platelet survival and steady-state platelet senescence are associated with increased surface exposure of PS and DeltaPsim collapse.

METHODS

Survival of in-vitro biotinylated rabbit platelets treated with thrombin or Ca(2+)-ionophore A23187 was tracked by flow cytometry after injection. Steady-state platelet senescence was investigated by infusing biotin to label a platelet cohort. PS expression and DeltaPsim of in-vitro biotinylated platelets and of the aging platelet cohort biotinylated in-vivo were measured by flow cytometry using annexin V-FLUOS and the DeltaPsim-sensitive dye CMXRos, respectively.

RESULTS

Although PS expression, DeltaPsim and survival of thrombin-degranulated platelets were similar to those of control platelets, increasing concentrations of A23187 caused increased surface exposure of PS and progressive shortening of platelet survival; only one-sixth of PS-expressing platelets also exhibited DeltaPsim loss. The cohort of senescent, biotinylated platelets remaining in the circulation at 96 h had increased exposure of PS and collapsed DeltaPsim; of the 17% of PS-expressing platelets, one-third did not exhibit DeltaPsim loss. There was also an increase in platelets with collapsed DeltaPsim but not expressing PS.

CONCLUSIONS

Platelets with shortened survival and senescent platelets have increased surface exposure of PS, that may be involved in their clearance. PS expression can occur independently of DeltaPsim collapse and conversely, in aged platelets, DeltaPsim loss can occur independently of PS expression.

Concurrent measurement of the survival of two populations of rabbit platelets labeled with either two PKH lipophilic dyes or two concentrations of biotin

BACKGROUND

To avoid radioisotopic labeling and permit comparison of the survival of two platelet populations concurrently in one animal, we compared simultaneous recoveries and survival times of homologous rabbit platelets labeled in vitro with the lipophilic dyes PKH26 (red fluorescing) and PKH67 (green fluorescing) and with two levels of biotin (low, 1 microg/ml; high, 10 microg/ml).

METHODS

Blood samples were drawn up to 96 h postinfusion and analyzed by flow cytometry. Biotin-labeled samples were incubated with phycoerythrin-streptavidin before analysis.

RESULTS

Recovery of PKH26-labeled platelets at 1 h was lower (37.5%) than that of PKH67-labeled platelets (47.3%; P < 0.001). Platelet survival times were 62.4 and 61.9 h. Recoveries at 1 h of platelets labeled with two levels of biotin were similar (86.6% and 84.6%) and greater than those of PKH-labeled platelets (P < 0.001). Survival of platelets labeled with biotin did not differ (low, 83.3 h; high, 85.2 h) and was longer than for PKH-labeled platelets (P < 0.01). Labeling methods did not activate platelets (measured by P-selectin expression), nor did they affect platelet responses to adenosine diphosphate (ADP), collagen, or thrombin.

CONCLUSIONS

Labeling with two levels of biotin is superior to labeling with PKH dyes, and is useful for measuring concurrently the survival of two differing platelet populations.

Responses to aggregating agents after cleavage of GPIb of human platelets by the O-sialoglycoprotein endoprotease from Pasteurella haemolytica- potential surrogates for Bernard-Soulier platelets?

Most proteolytic enzymes that cleave glycoprotein lb (GPlb) also cleave other glycoproteins or receptors on the surface of platelets. We have used an O-sialoglycoprotein endoprotease from Pasteurella haemolytica that selectively cleaves the heavily O-glycosylated GPlb, but does not cleave N-linked glycoproteins or unglycosylated proteins. Isolated, [14C]serotonin-labeled platelets in Tyrode-albumin solution were incubated with 10 microg/mL endoprotease for 60 minutes at 37 degrees C. These platelets did not release [14C]serotonin, had no detectable GPIb, and were unresponsive to ristocetin/von Willebrand factor. Compared with control platelets, aggregation and release of [14C]serotonin by the endoprotease-pretreated platelets were inhibited in response to low concentrations of thrombin, SFLLRN (the PAR-1-activating peptide), collagen, and U46619 (a thromboxane A(2) mimetic); aggregates were smaller in size. The presence of fibrinogen overcame the inhibition of responses induced by SFLLRN, collagen, and U46619. With fibrinogen, primary ADP-induced aggregation was scarcely affected by pretreatment with the endoprotease. Thus, the PAR-1 receptor for thrombin, and receptors for collagen, thromboxane A(2), fibrinogen (GPIIb/IIIa), and ADP appear to function normally on the endoprotease-pretreated platelets. Since only GPIb is cleaved by the endoprotease, these platelets seem to provide potential surrogates for Bernard-Soulier syndrome platelets for further studies of platelet functions in this condition.

The fibrinogen gamma chain dodecapeptide inhibits agonist-induced aggregation of rabbit platelets and fibrinogen binding to rabbit glycoprotein IIb-IIIa

The HHLGGAKQAGDV (H12) sequence at the carboxyl termini of the y chains and the RGD sequences in the Aalpha chains of human fibrinogen are potential recognition sites for the binding of soluble fibrinogen to glycoprotein IIb-IIIa (GPIIb-IIIa) on activated human platelets. Thus, addition of either H12 or RGD-containing peptides inhibits aggregation of and fibrinogen binding to human platelets. In contrast, we reported previously that RGDS had relatively little inhibitory effect on these functions of rabbit platelets. In the present study, we found that H12 inhibited ADP- and thrombin-induced aggregation of rabbit platelets in a dose-dependent manner. Specificity was demonstrated by the failure of the variant HHLGGAKQAGEV peptide to inhibit ADP-induced aggregation. Furthermore, flow cytometric analyses demonstrated that H12 inhibited the binding of FITC-fibrinogen to ADP-activated rabbit platelets in a dose-dependent manner. To examine the direct interaction of H12 with rabbit GPIIb-IIIa, we performed affinity chromatography by applying an octylglucoside extract of rabbit platelet proteins onto an affinity matrix containing the fibrinogen gamma chain sequence. Proteins of approximately 135 kDa and approximately 95 kDa were specifically eluted by soluble H12, and the 95 kDa protein band was immunoblotted by anti-LIBS1, a monoclonal antibody against human GPIIIa. In control samples, no detectable protein from rabbit platelet lysates was eluted from an RGD affinity matrix by GRGDSP. Collectively, our results demonstrated that H12 inhibits aggregation of and fibrinogen binding to rabbit platelets by directly interacting with rabbit GPIIb-IIIa. These findings suggest that rabbit platelets would serve as a suitable thrombosis model for testing the efficacy of peptide mimetics derived from H12.

Effects of ethanol on platelet responses associated with adhesion to collagen

Adhesion of platelets to collagen in damaged blood vessels or ruptured atherosclerotic plaques is important in hemostasis and arterial thrombosis. Adhesion to collagen results in secretion of granule contents and formation of thromboxane A2; thromboxane A2 and released ADP synergistically promote aggregation around platelets adherent to collagen. Ethanol inhibits collagen-induced platelet aggregation, secretion, arachidonate mobilization, and thromboxane A2 formation but does not inhibit platelet adhesion to de-endothelialized rabbit aortae. We investigated whether ethanol affects the initial signalling events and responses of platelets adherent to collagen, independent of the actions of secondary agonists. Suspensions of washed human platelets, labelled by incorporation of [3H]oleate into phospholipids, were used to measure platelet adhesion to collagen by a filtration method; studies were done in the presence of an ADP-removing system and blockers of receptors for thromboxane A2, platelet-activating factor, serotonin, and fibrinogen. Ethanol (87 mM) did not affect the rate or extent of platelet adhesion to collagen or secretion of [14C]serotonin from prelabelled platelets adherent to collagen, but ethanol did inhibit thromboxane A2 formation. Previous studies showed that ethanol does not affect platelet stimulation by arachidonate, leading to the suggestion that reduced mobilization of arachidonate, rather than inhibition of its conversion to thromboxane A2, is responsible for inhibition by ethanol of thromboxane A2 formation. Here, we show by a gel mobility shift assay and immunoblotting, that ethanol delays the collagen-induced increase in the phosphorylation of cytosolic phospholipase A2, the enzyme responsible for arachidonate mobilization. However, ethanol has no effect on collagen-induced tyrosine phosphorylation of phospholipase Cgamma2, determined by immunoprecipitation and immunoblotting. Thus, ethanol's effect on signal transduction in collagen-adherent platelets occurs distal to phosphorylation of phospholipase Cgamma2 but proximal to phosphorylation of cytosolic phospholipase A2.

Effects of cathepsin G pretreatment of platelets on their subsequent responses to aggregating agents

Cathepsin G, a proteolytic enzyme from activated leukocytes, can interact with platelets during inflammation and thrombosis. Platelets that have been exposed to cathepsin G in thrombi may recirculate if they are freed during fibrinolysis. To determine whether some of the subsequent functions of such platelets would be impaired, we investigated the responses of cathepsin G-pretreated platelets to agonists that they would encounter in the circulation. Suspensions of washed human platelets were labeled with [14C]serotonin and resuspended in Tyrode-albumin solution (with 2 mM Ca2+ and apyrase). After 15 minute incubation with 400 nM cathepsin G at 37 degrees C, 52+/-3% of [14C]serotonin had been released, and glycoprotein Ib was degraded. The platelets were washed and resuspended in fresh medium to remove cathepsin G and released materials. Ristocetin-induced agglutination was abolished, indicating that the binding site for von Willebrand Factor on glycoprotein Ib had been removed. Aggregation and release of residual [14C]serotonin in response to 0.1-1.0 U/mL thrombin was blocked or greatly reduced by the cathepsin G pretreatment. This inhibition is probably largely due to cleavage by cathepsin G of some of the protease-activated receptors at the C-terminal side of Ser42 so that the tethered ligand is lost. Pretreatment with cathepsin G did not affect responses to ADP or a low concentration of platelet-activating factor in the presence of fibrinogen, indicating that receptors for these agonists were unaffected and that the function of the fibrinogen receptor, GPIIb/IIIa was unchanged. Responses to cathepsin G, the thrombin receptor-activating peptide SFLLRN, collagen, or the thromboxane A2 mimetic U46619 were partially inhibited, even in the presence of added fibrinogen. Platelet adhesion to a collagen-coated surface was 51+/-7% inhibited, which may indicate cleavage of a collagen receptor or receptors; this may partly account for strong inhibition of collagen-induced aggregation and release of granule contents; additionally, as shown by inhibition of responses to U46619, the function of the thromboxane A2 receptor may be compromised. Thus, although cathepsin G activates platelets, if they recirculate after interaction with it, their subsequent adhesion to damaged vessel walls, aggregation, and release of granule contents induced by thrombin and collagen will be diminished.

Ethanol inhibits thrombin-induced secretion of the contents of human platelet dense and alpha-granules and lysosomes

Moderate consumption of alcoholic beverages is associated with a reduction in thromboembolic complications of coronary artery disease, possibly partially attributable to inhibition by ethanol of platelet responses to some aggregating agents. Although ethanol is known to inhibit thrombin-induced secretion of platelet dense granule contents, the effect of ethanol on secretion of alpha-granule and lysosomal contents has not been studied. Using suspensions of washed platelets, and a range of thrombin concentrations (up to 0.1 U/ml), we examined the effect of 87 mM ethanol on secretion of [14C]serotonin from prelabelled platelets as a measure of secretion of dense granule contents. Secretion of alpha-granule and lysosomal contents was examined by flow cytometric measurement of the surface expression of CD62P (P-selectin) and CD63, respectively. Secretion of the lysosomal enzyme, beta-N-acetylglucosaminidase was also quantified. Results were expressed as % of maximum response induced by 1 U/ml thrombin. Ethanol inhibited the thrombin-induced secretion of both dense and alpha-granule contents (P <0.001, 2-way ANOVA), and of lysosomal contents (P <0.005 for CD63 expression and P <0.001 for beta-N-acetylglucosaminidase secretion). When platelets were pretreated with aspirin, thrombin-induced secretion of storage granule and lysosomal contents was slightly inhibited, but secretion was inhibited by ethanol to the same extent as the untreated platelets, indicating that this inhibition was independent of thromboxane A2. Surface expression of CD63 occurred at lower thrombin concentrations than those required for secretion of beta-N-acetylglucosaminidase, possibly due to the presence of some CD63 on granule membranes. Although the role of lysosomal contents in thrombus formation is not established, some constituents of storage granules are known to augment thrombus formation; ethanol's inhibition of their secretion by stimulated platelets may contribute to its beneficial effect on thromboembolism.

Apolipoprotein(a) enhances platelet responses to the thrombin receptor-activating peptide SFLLRN

Elevated levels of lipoprotein(a) [Lp(a)] are correlated with an increased risk of atherosclerotic disease. We examined the effect of recombinant apolipoprotein(a) [r-apo(a)] and Lp(a) on responses of washed human platelets, prelabeled in the dense granules with [14C]serotonin and suspended in Tyrode's solution, to ADP and the thrombin receptor-activating peptide SFLLRN. No effect of the 17 kringle (K), 12K, or 6K r-apo(a) derivatives (at concentrations of 0.35 and 0.7 micromol/L) or Lp(a) (up to 0.1 micromol/L) on primary ADP-induced platelet aggregation was observed. In contrast, weak platelet responses stimulated by 7.5 micromol/L SFLLRN were significantly enhanced by the r-apo(a) derivatives; eg, 0.7 micromol/L 17K r-apo(a) increased aggregation from 15+/-4% to 58+/-6%, release of [14C]serotonin from 9+/-3% to 36+/-6%, and formation of thromboxane A2, measured as its stable metabolite thromboxane B2, from 7+/-1 to 29+/-5 ng/10(9) platelets (n=3; P<0.04 to 0.015). Significant enhancement of aggregation and release of granule contents was observed at a concentration of 17K r-apo(a) as low as 0.175 micromol/L. Purified Lp(a) (0.25 to 0.1 micromol/L) also enhanced SFLLRN-induced aggregation and release in a dose-dependent manner. Although plasminogen (0.7 and 1.5 micromol/L) and low density lipoprotein (0.025 to 0.1 micromol/L) both exhibited potentiating effects on SFLLRN-mediated platelet aggregation, the magnitude of the responses was less than that observed with either the r-apo(a) derivatives or Lp(a). The enhanced responses of platelets via the protease-activated receptor- thrombin receptor in the presence of Lp(a) may contribute to the increased risk of thromboembolic complications of atherosclerosis associated with this lipoprotein.

Differences between platelet phosphoinositide metabolism stimulated by thrombin or SFLLRN are not accounted for by interaction of thrombin with glycoprotein Ib

The formation of inositol phosphates was compared in aspirin-treated, washed human platelets suspended in Tyrode's-albumin solution containing 2 mM calcium and stimulated with SFLLRN (thrombin receptor-activating peptide) or thrombin. SFLLRN (20 microM) and thrombin (1 U/ml) resulted in maximal irreversible aggregation and 80-90% secretion of dense granule contents. SFLLRN (50-100 microM) caused larger increases at 10 sec than 20 microM SFLLRN in the formation of inositol trisphosphate (IP3, measured as [3H]inositol label). These increases were not significantly less than those caused by thrombin (1 unit/ml). However, whereas the labeling of IP3 increased from 10-60 sec with thrombin, with SFLLRN it was much less at 60 sec than that at 10 sec. The decrease was not due to degradation of SFLLRN by ectopeptidases, since it was not prevented by amastatin, an inhibitor of ectopeptidases. Degradation of glycoprotein Ib (GPIb) with an O-sialoglycoprotein endopeptidase did not affect the thrombin-stimulated labeling of inositol phosphates, indicating that binding to GPIb is not involved in the sustained thrombin-induced formation of inositol phosphates. The finding that the thrombin-stimulated formation of IP3 was not dependent on Ca2+ in the medium (EGTA added) indicates that the transient SFLLRN-induced formation of IP3 is not due to failure to cause Ca2+ influx. The finding that formation of IP3 was transient in SFLLRN-stimulated platelets, whereas platelet aggregation and secretion were maximal, indicates that the sustained activation of phospholipase C caused by thrombin may have roles related to later processes in which platelets participate.

Pretreatment of human platelets with plasmin inhibits responses to thrombin, but potentiates responses to low concentrations of aggregating agents, including the thrombin receptor activating peptide, SFLLRN

Effects of plasmin on platelets, that influence subsequent responses to aggregating agents, are relevant to attempts to prevent rethrombosis following administration of fibrinolytic agents. We describe plasmin-induced inhibition of platelet responses to thrombin, but potentiation of responses to other aggregating agents. Washed human platelets were labeled with 14C-serotonin, treated for 30 min at 37 degrees C with 0, 0.1 or 0.2 CU/ml of plasmin, followed by aprotinin, washed and resuspended in a Tyrode-albumin solution with apyrase. Incubation with 0.2 CU/ml of plasmin almost completely inhibited thrombin-induced (0.1 U/ml) aggregation, release of 14C-serotonin, and increase in cytosolic [Ca2+]. In contrast, with plasmin-pretreated platelets, aggregation and release of 14C-serotonin were strongly potentiated in response to low concentrations of the thrombin receptor-activating peptide SFLLRN, ADP, platelet-activating factor, collagen, arachidonic acid, the thromboxane mimetic U46619, and the calcium ionophores A23187 and ionomycin. Aspirin or RGDS partially inhibited potentiation. Plasmin-pretreated platelets resuspended in plasma anticoagulated with FPRCH2Cl (PPACK) also showed enhanced responses to aggregating agents other than thrombin. The contrasting effects on responses to thrombin and SFLLRN are noteworthy. Plasmin cleaves GPIIb/IIIa so that it becomes a competent fibrinogen receptor, and binding of 125I-fibrinogen during ADP-induced aggregation was greatly potentiated within 10 s. Potentiation of aggregation by other agonists may be due to increased binding of released fibrinogen. Thus, platelets freed from a thrombus may have increased responsiveness to low concentrations of aggregating agents other than thrombin. These results provide further support for the use of inhibitors of platelet reactions in conjunction with administration of fibrinolytic agents.

Exogenous diacylglycerols synergize with PAF with human platelets, but inhibit PAF-induced responses of rabbit platelets

To investigate whether diacylglycerol (DAG) has a role in reversible platelet aggregation induced by low concentrations of platelet-activating factor (PAF), we attempted to use the DAG kinase inhibitor, R59022, to prevent rapid conversion of DAG to phosphatidic acid. However, we found that R59022 inhibited the binding of [3H]PAF to human and rabbit platelets and to rabbit platelet membranes. We then investigated whether exogenous, cell-penetrating DAGs (1,2-dihexanoyl-sn-glycerol (DHG) and 1-oleoyl-2-acetyl-sn-glycerol (OAG)) act synergistically with low concentrations of PAF that alone induce only reversible aggregation. Platelets were isolated and labeled with [14C]serotonin. DHG (25-75 microM) caused slow, weak aggregation and some release of [14C]serotonin with human, but not rabbit, platelets. OAG (25-75 microM) did not aggregate either species' platelets. Phosphorylation of pleckstrin by DHG was more transient in rabbit platelets than previously observed with human platelets. Both DHG and OAG synergistically potentiated PAF-induced aggregation of human platelets, but, paradoxically, concurrently inhibited the PAF-induced increase in intracellular Ca2+ ([Ca2+]i): potentiation decreased upon incubation with DAGs before PAF addition. In contrast, DHG strongly inhibited PAF-induced aggregation of rabbit platelets; inhibition decreased upon preincubation. OAG, added with PAF, slightly potentiated aggregation of rabbit platelets: upon preincubation, OAG progressively inhibited. Effects of DHG and OAG on PAF-induced increases in [Ca2+]i in rabbit platelets followed a similar pattern; thus, with rabbit platelets, inhibition of the [Ca2+]i increase may at least partially account for inhibition of PAF-induced aggregation by exogenous DAGs. Results with human platelets are consistent with stimulation of protein kinase C by DAGs, and then metabolism of DAGs and/or negative feedback by DAGs, but results with rabbit platelets indicate both an unexpected species difference and a difference between the effects of DHG and OAG on PAF-induced platelet aggregation.

Probenecid inhibits platelet responses to aggregating agents in vitro and has a synergistic inhibitory effect with penicillin G

Probenecid is an anion channel blocker and uricosuric agent, originally developed to slow the rate of excretion of penicillin. It is now also administered with many other drugs to reduce their required dosages. Recently, probenecid (2.5 mM) has been used to prevent leakage of fura-2 or fluo-3 when these indicators of cytosolic Ca2+ levels have been introduced into cells. However, we found that probenecid markedly inhibited the increases in cytosolic Ca2+ caused by ADP, thrombin, the thrombin receptor-activating peptide (SFLLRN, TRAP), ADP, sodium arachidonate, the thromboxane A2 (TXA2) mimetic U46619, and platelet-activating factor (PAF). This finding precluded the use of probenecid with platelets in measurements of cytosolic Ca2+ with indicators such as fura-2. We then investigated the effects of probenecid on aggregation and release of 14C-serotonin from prelabeled platelets. Responses to all the agonists were inhibited by 2.5 mM probenecid, but concentrations as low as 0.25-0.5 mM inhibited responses to agonists that act largely via TXA2 (collagen, sodium arachidonate and U46619). Collagen-induced TXA2 formation was inhibited in a dose-dependent manner. Responses of aspirin-pretreated platelets to thrombin, SFLLRN, U46619 and PAF were also inhibited by probenecid, indicating that prevention of TXA2 formation does not account for all the inhibitory effects. The combination of probenecid with penicillin G produced additive or synergistic inhibition of platelet responses; responses dependent on TXA2 were synergistically inhibited by concentrations of the drugs that are reached in vivo. The synergistic inhibitory effect of probenecid on platelet functions could further impair hemostasis if it has already been partially compromised by the administration of other drugs.

Conditions influencing release of granule contents from human platelets in citrated plasma induced by ADP or the thrombin receptor activating peptide SFLLRN: direct measurement of percent release of beta-thromboglobulin and assessment by flow cytometry of P-selectin expression

Contrary to a recent report [Rinder et al.: Blood 82:505, 1993], aspirin does inhibit the release of alpha-granule contents as well as inhibiting the release of dense granule contents by human platelets during ADP-induced aggregation in citrated platelet-rich plasma (PRP). Measurements were: percent release of 14C-serotonin from prelabeled platelets, radio-immunoassay of beta-thromboglobulin (beta TG), and expression on the platelet surface of the alpha-granule constituent, P-selectin, by flow cytometry. During the second phase of ADP-induced aggregation, 69.0 +/- 8.3% of beta TG and 54.1 +/- 4.6% of 14C-serotonin were released (mean +/- SEM, n = 13); aspirin treatment reduced these values to 6.0 +/- 1.2 and 1.0 +/- 0.3%, respectively. In contrast, incubation of platelets with ADP without stirring caused only 6.7 +/- 1.7% release of beta TG and 2.1 +/- 0.4% release of 14C-serotonin; these low values were not appreciably affected by aspirin. During ADP-induced primary aggregation in PRP anticoagulated with FPRCH2CI (PPACK), only 4.7 +/- 0.9% release of beta TG and no detectable release of 14C-serotonin occurred; aspirin had no effect. In both stirred and unstirred PRP, the thrombin receptor activating peptide, SFLLRN (50 microM), caused at least 75% release of the contents of both granules, which was partially inhibited by aspirin. Upon incubation of platelets with ADP (2-10 microM), the mean fluorescence intensity due to P-selectin was < 14% of that induced by SFLLRN. In this unstirred system used for flow cytometry, aspirin treatment caused no significant inhibition of P-selectin expression. Thus, under conditions in which ADP does not cause secondary aggregation (physiological Ca2+ concentration or unstirred citrated PRP) release of the contents of both types of granules is less than 7% and aspirin is not inhibitory; the P-selectin expression associated with this low percent release is also unaffected by aspirin. However, aspirin does strongly inhibit the extensive release of both alpha-granule and dense granule contents during ADP-induced secondary aggregation in citrated PRP.

The platelet cytoskeleton stabilizes the interaction between alphaIIbbeta3 and its ligand and induces selective movements of ligand-occupied integrin

Previously, we showed that a subpopulation of the major platelet integrin, alphaIIbbeta3, co-sediments from detergent lysates with talin and other membrane skeleton proteins. Once alphaIIbbeta3 has bound adhesive ligand in a platelet aggregate, the detergent-insoluble alphaIIbbeta3 redistributes (along with the detergent-insoluble membrane skeleton proteins and a variety of signaling molecules) to a fraction that contains cytoplasmic actin filaments. Concomitantly, certain signaling molecules are activated. The present study shows that, in intact platelets, alphaIIbbeta3 forms clusters when occupied by ligand and is selectively moved into the open canalicular system; alphaIIbbeta3 that has not bound ligand remains diffusely distributed at the periphery of the cell. When cytoplasmic actin filaments are depolymerized by cytochalasins, the ability of alphaIIbbeta3 to bind ligand is decreased, and the movement of ligand-occupied alphaIIbbeta3 is prevented. Together with the previous findings, these results suggest that (i) membrane skeleton-associated alphaIIbbeta3 is selectively induced to bind ligand in activated platelets, (ii) ligand-induced transmembrane signaling causes an altered association of membrane skeleton-associated alphaIIbbeta3 with the cytoplasmic component of the cytoskeleton, (iii) ligand-induced cytoskeletal reorganizations stabilize the interaction between ligand and integrin, and (iv) ligand-occupancy triggers cytoskeletal reorganizations that result in selective movements of occupied ligand.

The influence of prostaglandin E1 on platelet adherence and injury in preserved rat liver allografts

We have previously shown that part of the injury sustained by cold-preserved livers on reperfusion is the consequence of platelet adhesion to sinusoidal endothelium. The purpose of the present study was to determine whether prostaglandin E1 (PGE1) can reduce the injury and if so, how to maximize this beneficial effect. Rat livers were cold-preserved in University of Wisconsin solution for 30 hours then subjected to 1-hour warm ischemia after which they were reperfused at 37 degrees C with oxygenated Krebs-Henseleit solution with or without isolated platelets. PGE1 was used to treat the donor liver during harvesting, cold preservation, and reperfusion. In some studies, PGE1 was used to pretreat platelets before exposing them to the liver, and in other studies, both liver and platelets were treated. Pretreatment of platelets with paraformaldehyde, which inactivates them, or ADP, which activates them, was also studied. Treatment of livers with PGE1 significantly decreased preservation injury when livers were reperfused in the absence of platelets. However, when platelets were added to the perfusate, prior treatment of the liver with PGE1 had relatively minor beneficial effects. Pretreatment of platelets alone with PGE1 was also beneficial, but again the effect was small. However, when both liver and platelets were treated with PGE1 there was a highly significant decrease in the extent of liver injury and platelet adhesion. Perfusate transaminase levels were lower, bile flow was improved, and histologically, livers appeared less injured. Pretreatment of platelets with paraformaldehyde produced similar results to pretreatment with PGE1. When platelets were preactivated with adenosine diphosphate, extensive hepatic injury occurred upon reperfusion despite PGE1 treatment of the liver. PGE1 can lessen preservation-reperfusion injury impressively when administered to both liver and platelets but has little effect when platelets have been preactivated.

Platelet accumulation on fibrin-coated polyethylene: role of platelet activation and factor XIII

Platelet accumulation on small- and medium-calibre vascular grafts plays a significant role in graft occlusion. We examined platelet accumulation on the surface of fibrin-coated polyethylene tubing (internal diameter 0.17 cm) during 10 min flow (10 ml/min) at high wall shear rate (764 s-1). Washed platelets labelled with 51Cr were resuspended in Tyrode solution containing albumin, apyrase and red blood cells (hematocrit 40%). When the thrombin that was used to form the fibrin-coated surface was inactivated with FPRCH2Cl before perfusion of the tubes with the platelet: red blood cell suspension, the accumulation of platelets was 59,840 +/- 27,960 platelets per mm2, whereas accumulation on fibrin with residual active thrombin was 316,750 +/- 32,560 platelets per mm2 (n = 4). When the fibrin on the surface was cross-linked by including recombinant factor XIII (rFXIII) in the fibrinogen solution used to prepare the fibrin-coated surface, platelet accumulation, after thrombin neutralization, was reduced by the cross-linking from 46,974 +/- 9702 to 36,818 +/- 7964 platelets per mm2 (n = 12, p < 0.01). Platelet accumulation on tubes coated with D-dimer was ten times less than on tubes coated with D-domain; this finding also supports the observation that cross-linking of fibrin with the formation gamma-gamma dimers reduces platelet accumulation on the fibrin-coated surface. Thrombin-activated platelets themselves were shown to cross-link fibrin when they had adhered to it during perfusion, or in a static system in which thrombin was used to form clots from FXIII-free fibrinogen in the presence of platelets.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of thrombin and the thrombin receptor activating peptide, SFLLRN, on redistribution of platelet alpha-granule contents are similar and independent of the extent of thromboxane formation

Immunocytochemistry with gold-labeled antibodies was used to compare the effects of stimulation of human platelets with thrombin (1 U/ml) and the thrombin receptor activating peptide, SFLLRN (20 microM). After 3 min, redistribution of fibrinogen, von Willebrand factor, and P-selectin (GMP-140, CD62) was examined, the percentages of [14C]serotonin and beta-thromboglobulin released from pre-labeled platelets were measured, and the amount of thromboxane B2 formed was assayed. Upon stimulation with either thrombin or SFLLRN, the platelets had changed from their normal disc shape to spheroidal forms with short pseudopodia. Few alpha-granules remained, the open canalicular system was expanded (more so with SFLLRN) and contained most of the fibrinogen and von Willebrand factor, although small amounts were evident on the platelet surface. Most of the P-selectin was on the surface. Both thrombin and SFLLRN caused complete release of beta-thromboglobulin and 88.3 and 77.5% release of [14C]serotonin, respectively. However, formation of TXB2 caused by thrombin was 10 times greater than that caused by SFLLRN (969 +/- 173 vs 76 +/- 22 ng/10(9) platelets). Thus, the redistribution of platelet alpha-granule contents is similar with thrombin or SFLLRN stimulation and is unaffected by the extent of thromboxane formation.

Contrasting effects of thrombin and the thrombin receptor peptide, SFLLRN, on aggregation and release of 14C-serotonin by human platelets pretreated with chymotrypsin or serratia marcescens protease

Chymotrypsin cleaves glycoprotein Ib (GPIb) on platelets and reduces their responsiveness to thrombin; platelets from patients with the Bernard-Soulier syndrome, which lack GPIb, are also less responsive to thrombin than platelets from normal donors. However, Bernard-Soulier platelets respond normally to the thrombin receptor peptide SFLLRN (13). We compared responses of 14C-serotonin-labeled, chymotrypsin-treated platelets (and control platelets) to thrombin (0.25-2 U/ml) and SFLLRN (5-40 microM). Chymotrypsin treatment strongly inhibited thrombin-induced aggregation and release of 14C-serotonin when concentrations of thrombin of 0.5 U/ml or lower were used, even though these responses of control platelets remained near the maximum. In contrast, there was little difference between the responses of control and chymotrypsin-treated platelets to SFLLRN, even when the responses of control platelets were less than maximal. Thus, chymotrypsin treatment greatly inhibits the response to thrombin of the seven transmembrane domain thrombin receptor cloned by Coughlin's group (1, 2). Since Serratia marcescens protease also hydrolyses GPIb, but has less effect than chymotrypsin on other glycoproteins, we pretreated platelets with several concentrations of S. marcescens protease. Concentrations that abolished aggregation and release of 14C-serotonin in response to thrombin had little effect on these responses to SFLLRN. One interpretation of these findings would be that by cleaving GPIb, both proteases are affecting an interaction that may be important for activation of the cloned receptor by thrombin, but irrelevant to activation of this receptor by SFLLRN.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of chronic administration of ethanol on platelets from rabbits with diet-induced hypercholesterolemia. Unchanged characteristics and responses to ADP but reduction of enhanced thrombin-induced, TxA2-independent platelet responses

To investigate the effect on platelet function of the interaction between dietary cholesterol and moderate, chronic doses of ethanol, hypercholesterolemia was induced in rabbits by 8 weeks of administration of a chow diet with added (0.25% wt/wt) cholesterol; during the eighth week, a moderate amount of ethanol (6% in drinking water) was given. Blood alcohol levels were not detectable in ethanol-treated rabbits at the time of exsanguination. Ethanol did not affect plasma cholesterol levels or the cholesterol to phospholipid molar ratio in platelets. Platelet membrane fluidity, which decreased with cholesterol feeding, was not altered further by administration of ethanol. The overall fatty acid composition of platelet phospholipids was not affected by either cholesterol feeding or chronic ethanol intake. Responses of washed platelets stimulated with either ADP or thrombin were studied to determine whether ethanol administration modified platelet functions in hypercholesterolemia. Primary ADP-induced aggregation was not affected by cholesterol feeding or chronic ethanol intake, but thrombin-induced aggregation and secretion of [14C]serotonin from prelabeled platelets, which were enhanced by cholesterol feeding, were diminished by administration of ethanol to hypercholesterolemic rabbits. This reduction in thrombin-induced responses was also observed with aspirin-treated platelets, which cannot form thromboxane A2. Thus, chronic short-term administration of a moderate amount of ethanol inhibited the enhanced responses of platelets from rabbits with diet-induced hypercholesterolemia, via a thrombin-induced, thromboxane A2-independent pathway.

Enhanced collagen-induced responses of platelets from rabbits with diet-induced hypercholesterolemia are due to increased sensitivity to TxA2. Response inhibition by chronic ethanol administration in hypercholesterolemia is due to reduced TxA2 formation

The effects of dietary cholesterol and chronic administration of moderate amounts of ethanol on collagen-induced platelet responses were investigated. Three groups of rabbits were fed the following diets for 8 weeks: a normal chow diet, a cholesterol-enriched (0.25% wt/wt) chow diet, and a cholesterol-enriched chow diet plus 6% ethanol in the drinking water for the final week of the dietary period. Cholesterol feeding enhanced collagen-induced responses-aggregation, secretion of [14C]serotonin from prelabeled platelets, and thromboxane formation--of suspensions of washed platelets, and chronic ethanol treatment significantly reduced these enhanced responses. These effects are mediated by thromboxane A2 (TxA2) rather than ADP. Experiments with collagen-stimulated platelets in which feedback amplification of TxA2 was blocked with the prostaglandin H2/TxA2 receptor blocker BM 13.177 and experiments with aspirin-treated platelets stimulated with the stable TxA2 mimetic U46619 showed that cholesterol feeding enhanced platelet sensitivity to TxA2 rather than formation of TxA2 by platelets that had interacted with collagen. Without BM 13.177 or aspirin, TxA2 increased the amount of TxA2 formed by feedback amplification. In contrast, decreased responsiveness to collagen by platelets from cholesterol-fed rabbits given ethanol was due to inhibition of TxA2 formation rather than reduced sensitivity to TxA2. Platelets from cholesterol-fed rabbits given ethanol did not develop tolerance to the acute inhibitory effects of ethanol. Our results indicate that administration of moderate amounts of ethanol to cholesterol-fed rabbits inhibits enhanced collagen-induced responses of platelets by a TxA2-dependent pathway that involves reduction of TxA2 formation rather than reduction of platelet responses to TxA2.

Role of platelets in thrombosis and hemostasis

Platelet aggregates, stabilized by fibrin, rapidly form hemostatic plugs when blood vessels are severed or arterial thrombi at sites of vessel injury, such as ruptured atherosclerotic plaques, or regions where blood flow is disturbed, such as at stenoses. These thrombi cause the thromboembolic complications of atherosclerosis: heart attacks, strokes, and peripheral vascular disease. Platelet adhesion to subendothelial components such as collagen activates signalling pathways that lead to thromboxane A2 formation and secretion of platelet granule contents, including ADP. Both these substances cause platelet aggregation, a process in which the integrin, glycoprotein IIb/IIIa, becomes a receptor for fibrinogen, which forms bridges between adjacent platelets. On the surface of stimulated platelets, coagulation is accelerated and thrombin is generated; it is a potent inducer of platelet aggregation and secretion and also causes fibrin to form around the aggregates, stabilizing them. There are receptors on the platelet surface for thrombin, thromboxane A2, collagen, ADP, platelet-activating factor, fibrinogen, von Willebrand factor, and other ligands. Agents that inhibit platelet aggregation and the signalling pathways that are activated by the various aggregating agents are under intensive investigation in many laboratories.

Ticlopidine facilitates the deaggregation of human platelets aggregated by thrombin

Normal human platelets aggregated by thrombin undergo the release reaction and are not readily deaggregated by the combination of inhibitors hirudin, prostaglandin E1 (PGE1) and chymotrypsin. Released adenosine diphosphate (ADP) plays an important role in the stabilization of thrombin-induced human platelet aggregates. Since ticlopidine inhibits the platelet responses to ADP, we studied thrombin-induced aggregation and deaggregation of 14C-serotonin-labeled platelets from 12 patients with cardiovascular disease before and 7 days after the oral administration of ticlopidine, 250 mg b.i.d. Before and after ticlopidine, platelets stimulated with 1 U/ml thrombin aggregated, released about 80-90% 14C-serotonin and did not deaggregate spontaneously within 5 min from stimulation. Before ticlopidine, hirudin (5x the activity of thrombin) and PGE1 (10 mumol/l) plus chymotrypsin (10 U/ml) or plasmin (0.06 U/ml), added at the peak of platelet aggregation, caused slight or no platelet deaggregation. After ticlopidine, the extent of platelet deaggregation caused by the same inhibitors was significantly greater than before ticlopidine. The addition of ADP (10 mumol/l) to platelet suspensions 5 s after thrombin did not prevent the deaggregation of ticlopidine-treated platelets. Thus, ticlopidine facilitates the deaggregation of thrombin-induced human platelet aggregates, most probably because it inhibits the effects of ADP on platelets.

Degranulation of human platelets by the thrombin receptor peptide SFLLRN: comparison with degranulation by thrombin

A new, simplified method of degranulating human platelets using the thrombin receptor peptide SFLLRN (20 microM) is described; released fibrinogen cannot be converted to fibrin, and the platelets are not exposed to a proteolytic enzyme, as they are when thrombin is used for degranulation. The peptide-degranulated platelets regain their disc shape and are recovered as single platelets which have released approximately 90% of the contents of their dense granules. Their procoagulant activity is greater than that of control platelets, but somewhat less than that of thrombin-degranulated platelets. Without added fibrinogen, the peptide-degranulated platelets aggregate slightly in response to 50 microM SFLLRN, and to collagen, arachidonic acid, the thromboxane A2 mimetic U46619, platelet activating factor, ADP, and the divalent cation ionophore A23187; added fibrinogen enhances aggregation caused by these agonists. Extensive aggregation of peptide-degranulated platelets is caused by thrombin in the absence of added fibrinogen; it may be that the alternative thrombin receptor that is not activated by SFLLRN is responsible for the strong response to thrombin. Aggregation responses to most of the agonists are greater than those observed previously with thrombin-degranulated platelets. By this method, platelets are obtained that have been degranulated in a way that is similar to in vivo degranulation. They are useful for studies of platelet responses without the complicating effects of released granule contents, and for investigation of the characteristics and functions of platelets that have come in contact with release-inducing agents in vivo.

Role of platelets in hepatic allograft preservation injury in the rat

Cold preservation of liver allografts injuries hepatic sinusoidal lining cells. This injury is exacerbated on reperfusion, in part because of adhesion of leukocytes. Platelets also adhere to activated endothelial surfaces. In this study we examined the role of platelets in preservation injury. Our specific aim was to determine whether the degree of platelet adhesion on reperfusion of preserved rat livers was related to duration of cold or warm ischemia and whether platelet adhesion resulted in injury to allografts. We also examined the effect of prior activation of platelets on adhesion and injury. Rat livers were preserved at 1 degree C for different time periods in University of Wisconsin solution and then reperfused for 3 hr on the isolated perfused rat liver system with Krebs-Henseleit solution to which unactivated isolated rat platelets were added. Other livers were rewarmed before reperfusion or reperfused with activated platelets. Platelets were lost from the circulation in all studies; the percentage reduction of circulating platelets was dependent on the length of preservation. The initial platelet concentration did not affect the rate of reduction of platelets in the circuit. Rewarming before reperfusion increased platelet adherence, and prior activation also increased adherence. With electron microscopy we determined that platelets adhered in small aggregates to endothelial cells or endothelial cell remnants. Adherent platelets appeared more activated and contained fewer granules than did unperfused platelets. Liver injury as measured by release of transaminases into perfusate was worsened by longer periods of cold preservation and by addition of rewarming to the protocol. The presence of platelets under these circumstances aggravated injury. Prior activation of platelets also increased the extent of injury. These studies show that platelets have an important role in cold preservation-reperfusion injury.

Rabbit and rat platelets do not respond to thrombin receptor peptides that activate human platelets

Human platelets are aggregated and induced to release their granule contents and form thromboxane by peptides as short as 6-amino acid residues (SFLLRN) corresponding to the newly released N-terminus of the thrombin receptor that is cleaved by thrombin. Using washed platelets, we found that these responses to SFLLRN (2 to 6 mumol/L) were enhanced by fibrinogen. However, neither SFLLRN nor SFLLRNPNDKYEPF had any effect on washed rabbit or rat platelets, although they were fully responsive to human thrombin. Concentrations of the peptides as high as 100 mumol/L did not cause the platelets of rabbits or rats to change shape, aggregate, release granule contents, or form thromboxane. SFLLRN did not affect the extent of aggregation induced by adenosine diphosphate (ADP) or a low concentration of thrombin. Pig platelets responded to 50 mumol/L SFLLRN with reversible aggregation, which was enhanced by fibrinogen, but not accompanied by the release of dense granule contents. Guinea pig platelets aggregated and released granule contents in response to 25 or 50 mumol/L of SFLLRN, but responded with only shape change to lower concentrations. Thus, these experiments indicate that rabbit and rat platelets lack a functional response to human thrombin receptor peptides that fully activate the previously described human thrombin receptor, despite a full response of both rabbit and rat platelets to human thrombin, and that pig and guinea pig platelets have incomplete responses to these human thrombin receptor peptides. The results suggest that platelets of rabbits and rats, and perhaps guinea pigs and pigs, respond to thrombin through an alternative receptor that has also been suggested to be present on human platelets.