Pomolic acid, triterpenoid isolated from Licania pittieri, as competitive antagonist of ADP-induced aggregation of human platelets.

Pomolic acid (PA), triterpenoid isolated from Licania pittieri, has previously shown a potent ability to inhibit adenosine diphosphate (ADP)- and epinephrine-induced human platelet aggregation. To investigate whether PA could be an antagonist of ADP-activated receptors of human platelets (P2Y(1) and P2Y(12)), pharmacological studies were conducted to examining its ability to modulate the platelet shape change induced by a selective P2Y(1) receptor agonist MRS2365 and also the nature of its possible interaction with ADP receptors by analyzing the characteristics of log concentration-response curves of ADP constructed in the absence and in the presence of fixed concentrations of PA, using in vitro platelet aggregation assays. PA did not interfere with the activation of P2Y(1) receptor by MRS2365 to induce platelet shape change and displayed a competitive antagonism of ADP-induced platelet aggregation, which most probably involves competition for a single binding site in platelets. The estimated equilibrium dissociate constant (K(b)) of PA as ADP receptor antagonist was 15.4±0.06nM. Together, these findings give indirect evidence for the idea that PA could be a potent competitive antagonist of P2Y(12) receptor, and open the possibility to consider it as new member of the non-nucleotide generation of antiplatelet drugs.

A highly constrained cyclic (S,S)-CDC- peptide is a potent inhibitor of carotid artery thrombosis in rabbits.

Inhibition of platelet aggregation is indispensable for the treatment of acute arterial thrombotic episodes. We have previously reported the synthesis of a highly constrained cyclic peptide, that incorporates the -CDC- sequence, (S,S) PSRCDCR-NH(2), which potently inhibits aggregation and fibrinogen binding to human platelets in vitro. We have tested the safety and efficacy of the peptide on the electrically induced carotid artery thrombosis experimental rabbit model. The peptide's effects on carotid blood flow, thrombus weight, in vitro and ex vivo platelet aggregation, and bleeding and hemostatic parameters were evaluated. The peptide was administered via the femoral vein. Carotid blood flow was continuously monitored for 90 min after electrical thrombus formation. The peptide, at 12 mg/kg, prevented total artery occlusion and significantly preserved carotid artery's patency compared with placebo and eptifibatide. Furthermore, (S,S) PSRCDCR-NH(2) administration at 12 mg/kg reduced thrombus weight, whereas it inhibited ex vivo ADP, arachidonic acid (AA) and collagen-induced platelet aggregation. Moreover (S,S) PSRCDCR-NH(2) at 12 mg/kg presented significantly higher inhibitory effects on AA and collagen-induced ex vivo platelet aggregation compared to eptifibatide. The peptide at any dose did not affect the coagulation cascade, the bleeding times or the hemostatic response of the animals. Thus highly constrained cyclic peptides like (S,S) PSRCDCR-NH(2) that incorporate the -CDC- motif and fulfil certain conformational criteria represent novel compounds that potently inhibit thrombus formation, ex vivo platelet aggregation and carotid artery occlusion superiorly to other non-RGD peptides, such as YMESRADR, without causing hemorrhagic complications in a rabbit model of arterial thrombosis.

Ticagrelor: from discovery to Phase III clinical trial.

Ticagrelor (AZD6140), a cyclopentyl-triazolo-pyrimidine, is the first orally available antagonist of the ADP receptor of the P2Y12 subtype. Ticagrelor inhibits platelets in a reversible manner and does not require hepatic bioactivation. The pharmacology of ticagrelor indicates that it provides more consistent, more rapid and more potent platelet inhibition than clopidogrel. Preclinical and clinical studies with ticagrelor have demonstrated that this drug has excellent oral bioavailability. The Phase III clinical study of Platelet Inhibition and Patient Outcomes (PLATO) has shown that ticagrelor reduced ischemic events and all-cause mortality without an increase in major bleeding complications. Potential advantages of ticagrelor include more flexibility in its use if rapid onset of action is needed before percutaneous coronary interventions or when cessation is required before coronary artery bypass graft surgery. Potential disadvantages include more side effects such as dyspnea, ventricular pauses or an increase in concentrations of uric acid and creatinine. However, ticagrelor did not only reduce death due to vascular causes but also all-cause mortality. Further clinical trials in indications other than acute coronary syndrome are awaited.

Inhibitory activity of ginsenosides isolated from processed ginseng on platelet aggregation.

Seven ginsenosides, namely Rg6 (1), F4 (2), Rk3 (3), Rh4 (4), Rs3 (5), Rs4 (6) and Rs5 (7) isolated from processed ginseng were evaluated for their effects on platelet aggregation induced by adenosine diphosphate (ADP), collagen, arachidonic acid (AA) and U46619 (thromboxane A2 mimetic drug). Ginsenosides Rg6, F4 and Rk3 showed inhibitory activity (IC50 = 76 microM, 114 microM and 128 microM, respectively) on AA-induced platelet aggregation. The corresponding IC50 values were comparable to that of acetylsalicylic acid (ASA) (63 microM). Compared to ASA (IC50 = 468 microM) ginsenosides Rg6, F4, Rk3 and Rh4 were found to be more inhibitive (IC50 = 286 microM, 87 microM, 187 microM and 119 microM, respectively) against U46619-induced aggregation. On the other hand, most of the ginsenosides (Rg6, F4, Rh4, Rs3, Rs5) showed negligible effects on ADP and collagen-induced platelet aggregation. The acetylated ginsenosides (Rs3, Rs4 and Rs5) had only mild effects on aggregation induced by four stimulators.

Inhibition of ADP ribosylation prevents and cures helicobacter-induced gastric preneoplasia.

Gastric adenocarcinoma develops as a consequence of chronic inflammation of the stomach lining that is caused by persistent infection with the bacterium Helicobacter pylori. Gastric carcinogenesis progresses through a sequence of preneoplastic lesions that manifest histologically as atrophic gastritis, intestinal metaplasia, and dysplasia. We show here in several preclinical models of Helicobacter-induced atrophic gastritis, epithelial hyperplasia, and metaplasia that the inhibition of ADP ribosylation by the small-molecule inhibitor PJ34 not only prevents the formation of gastric cancer precursor lesions, but also efficiently reverses preexisting lesions. PJ34 exerts its chemopreventive and therapeutic effects by impairing Helicobacter-specific T-cell priming and T(H)1 polarization in the gut-draining mesenteric lymph nodes. The subsequent infiltration of pathogenic T cells into the gastric mucosa and the ensuing gastric T cell-driven immunopathology are prevented efficiently by PJ34. Our data indicate that PJ34 directly suppresses T-cell effector functions by blocking the IFN-gamma production of mesenteric lymph node T cells ex vivo. Upon exposure to PJ34, purified T cells failed to synthesize ADP-ribose polymers and to activate the transcription of genes encoding IFN-gamma, interleukin 2, and the interleukin 2 receptor alpha chain in response to stimuli such as CD3/CD28 cross-linking or phorbol 12-myristate 13-acetate/ionomycin. The immunosuppressive and chemoprotective effects of PJ34 therefore result from impaired T-cell activation and T(H)1 polarization, and lead to the protection from preneoplastic gastric immunopathology. In conclusion, ADP-ribosylating enzymes constitute novel targets for the treatment of Helicobacter-associated gastric lesions predisposing infected individuals to gastric cancer and may also hold promise for the treatment of other T cell-driven chronic inflammatory conditions and autoimmune pathologies.

Antiplatelet and antithrombotic activities of salvianolic acid A.

INTRODUCTION: Salvianolic acid A (SAA), the water-soluble phenolic acids in Salvia miltiorrhiza, has shown the most potent bioactivities, including protection against cerebral lesion, defense from oxidative damage and improvement of remembrance. In the present study, we studied the antiplatelet and antithrombotic effects of a newly synthesized SAA with different methods both in vitro and in vivo. MATERIALS AND METHODS: We tested the effect of antithrombotic activity of SAA in arterio-venous shunt model. The effects of SAA on adenosine diphosphate (ADP)-, Thrombin-, Arachidonic acid- induced rat platelets aggregation were tested both in vivo and in vitro. The activity of SAA on washed human platelet aggregation was determined by ADP stimulation. We also evaluated its property of modulation of hemorheology, assessed its bleeding side effect by measuring coagulation parameters after intravenous administration for 5 days and investigated the potential mechanisms underlying such activities. RESULTS AND CONCLUSIONS: In vivo, SAA significantly reduced thrombus weight in the model of arterio-venous shunt. Meanwhile, SAA increased plasma cAMP level determined by radioimmunoassay in the same model. Intravenously administrated SAA (2.5-10 mg/kg) inhibited platelet aggregation induced by ADP in a dose-dependent manner. Notably, SAA did not affect coagulation parameters in rats after intravenous administration SAA for successive 5 days. In vitro, pretreatment with SAA on washed rat and human platelets significantly inhibited various agonists stimulated platelet aggregation and caused an increase in cAMP level in platelets activated by ADP. These findings support our hypothesis that SAA possesses antithrombotic activities. The antithrombotic effect might be related to its antiplatelet action and ability to modulate hemorheology without affecting coagulation system. The mechanisms underlying such activities may involve the induction of cAMP.

The reversible oral P2Y12 antagonist AZD6140 inhibits ADP-induced contractions in murine and human vasculature.

OBJECTIVES: The platelet ADP P2Y(12) receptor which is a target for the antithrombotic drug clopidogrel is also distributed on vascular smooth muscle cells and stimulate contraction. This study investigates whether AZD6140, in contrast to clopidogrel, can inhibit ADP-mediated arterial contractions. METHODS: Mice were treated with clopidogrel, 50 mg/kg, 24 and 2 h before experiment. Thoracic aorta ring segments from both clopidogrel-treated (n=5) and untreated (n=4) mice were mounted in myograph baths. Contractions of human left internal mammary arteries (IMA) and small arteries were studied in an identical manner. RESULTS: Clopidogrel treatment per os did not inhibit contractions by the stable ADP analogue 2-MeSADP (10 microM). However, addition of 1 microM AZD6140 in vitro inhibited ADP contraction (% of maximal contraction by 60 mM K(+)) both in the clopidogrel-treated, from 64% to 32% (P=0.002) and in the untreated group, from 59% to 33% (P=0.015). 2-MeSADP contractions in human IMA and small arteries were inhibited by AZD6140. CONCLUSIONS: The antiplatelet drug AZD6140 blocks the contractile effects of ADP in both murine and human vasculature. These effects of AZD6140 could be beneficial in the management of conditions in which vasospasm may play a role.

Update on antiplatelet therapy in acute coronary syndromes: what do new drugs bring into clinical practice?

The incidence of new coronary events in patients receiving dual antiplatelet therapy (e.g. cyclo-oxygenase inhibitors such as aspirin [acetylsalicylic acid; ASA]) and ADP receptor blockers (e.g. clopidogrel) is high. Therefore, it is critical to identify patients who require more intense treatment such as those with poor tolerance to existing drugs, those with genotypes that predict treatment resistance, diabetic patients, and smokers. The new ADP receptor blockers (prasugrel, cangrelor, Ticagrelor) can provide greater efficacy but it should not be associated with increased bleeding. Thrombin receptor antagonists (e.g. SCH530348) are another alternative that is currently being tested in randomized trials.

Clinical management of clopidogrel inefficiency by point of care platelet function testing and individual adjustment of anti-platelet therapy--initial experiences.

Insufficient inhibition of ADP dependent platelet aggregation by clopidogrel is associated with an increased risk for adverse coronary events, such as stent thrombosis, after percutaneous coronary intervention. Here, we describe an approach to the clinical management of patients with insufficient inhibition of ADP dependent platelet aggregation by clopidogrel involving dose adjustment or switching of the thienoyridine. We put special emphasize on a patient who experienced recurrent acute myocardial infarction due to stent thrombosis associated with severe clopidogrel non response following elective coronary drug eluting stent implantation. In this patient, an inadequate clopidogrel effect at maintenance doses was confirmed by repeated platelet function assessment with a multiple electrode impedance point of care platelet function test. Subsequent dose adjustments still did not result in sufficient inhibition of ADP dependent platelet aggregation. Only after switching to the then shortly available new thienopyridine prasugrel could a sufficient platelet inhibition be obtained. However, our data from further patients show that although this may overcome inadequate clopidogrel efficiency in many cases, even under prasugrel suboptimal platelet inhibition may occur.

Mechanism of activation and functional role of protein kinase Ceta in human platelets.

The novel class of protein kinase C (nPKC) isoform eta is expressed in platelets, but not much is known about its activation and function. In this study, we investigated the mechanism of activation and functional implications of nPKCeta using pharmacological and gene knock-out approaches. nPKCeta was phosphorylated (at Thr-512) in a time- and concentration-dependent manner by 2MeSADP. Pretreatment of platelets with MRS-2179, a P2Y1 receptor antagonist, or YM-254890, a G(q) blocker, abolished 2MeSADP-induced phosphorylation of nPKCeta. Similarly, ADP failed to activate nPKCeta in platelets isolated from P2Y1 and G(q) knock-out mice. However, pretreatment of platelets with P2Y12 receptor antagonist, AR-C69331MX did not interfere with ADP-induced nPKCeta phosphorylation. In addition, when platelets were activated with 2MeSADP under stirring conditions, although nPKCeta was phosphorylated within 30 s by ADP receptors, it was also dephosphorylated by activated integrin alpha(IIb)beta3 mediated outside-in signaling. Moreover, in the presence of SC-57101, a alpha(IIb)beta3 receptor antagonist, nPKCeta dephosphorylation was inhibited. Furthermore, in murine platelets lacking PP1cgamma, a catalytic subunit of serine/threonine phosphatase, alpha(IIb)beta3 failed to dephosphorylate nPKCeta. Thus, we conclude that ADP activates nPKCeta via P2Y1 receptor and is subsequently dephosphorylated by PP1gamma phosphatase activated by alpha(IIb)beta3 integrin. In addition, pretreatment of platelets with eta-RACK antagonistic peptides, a specific inhibitor of nPKCeta, inhibited ADP-induced thromboxane generation. However, these peptides had no affect on ADP-induced aggregation when thromboxane generation was blocked. In summary, nPKCeta positively regulates agonist-induced thromboxane generation with no effects on platelet aggregation.

Effect of epsilon subunit on the rotation of thermophilic Bacillus F1-ATPase.

F(1)-ATPase is an ATP-driven motor in which gammaepsilon rotates in the alpha(3)beta(3)-cylinder. It is attenuated by MgADP inhibition and by the epsilon subunit in an inhibitory form. The non-inhibitory form of epsilon subunit of thermophilic Bacillus PS3 F(1)-ATPase is stabilized by ATP-binding with micromolar K(d) at 25 degrees C. Here, we show that at [ATP]>2 microM, epsilon does not affect rotation of PS3 F(1)-ATPase but, at 200 nM ATP, epsilon prolongs the pause of rotation caused by MgADP inhibition while the frequency of the pause is unchanged. It appears that epsilon undergoes reversible transition to the inhibitory form at [ATP] below K(d).

Purification and characterization of a new platelet aggregation inhibitor with dissociative effect on ADP-induced platelet aggregation, from the venom of Protobothrops elegans (Sakishima-habu).

A platelet aggregation inhibitor, named snake venom platelet aggregation dissociator (SV-PAD)-1, with a dissociative reaction of ADP-induced platelet aggregation, was purified from the venom of Protobothrops elegans (Sakishima-habu) by gel-filtration employing Sephadex G-100, and ion-exchange chromatographies using DEAE-Sepharose Fast Flow, CM-Sepharose Fast Flow, and Mono S. By this procedure, about 1.5mg of purified protein was obtained from 1.0g of P. elegans venom. The purified protein showed a single protein band and the molecular weight was about 110kDa on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) under reducing conditions. The pI of purified protein showed four-bands of 7.7, 7.8, 7.95, and 8.15. This protein strongly inhibited ADP-induced platelet aggregation in rabbit platelet-rich plasma (PRP), and its IC(50) was about 58nM. It inhibited ristocetin-induced platelet aggregation in rabbit PRP (IC(50): 100nM), but hardly blocked collagen-induced platelet aggregation. This protein promptly dissociated platelet aggregation in rabbit PRP stimulated by high-concentration ADP.

A cytosolic factor that inhibits KATP channels expressed in Xenopus oocytes by impairing Mg-nucleotide activation by SUR1.

ATP-sensitive K(+) (K(ATP)) channels couple cell metabolism to cell electrical activity. Wild-type (Kir6.2/SUR1) K(ATP) channels heterologously expressed in Xenopus oocytes give rise to very small inward currents in cell-attached patches. A large increase in the current is observed on patch excision into zero ATP solution. This is presumably due to loss of intracellular ATP leading to unblock of K(ATP) channels. In contrast, channels containing Kir6.2 mutations associated with reduced ATP-sensitivity display non-zero cell-attached currents. Unexpectedly, these cell-attached currents are significantly smaller (by approximately 40%) than those observed when excised patches are exposed to physiological ATP concentrations (1-10 mm). Cramming the patch back into the oocyte cytoplasm restores mutant K(ATP) current amplitude to that measured in the cell-attached mode. This implies that the magnitude of the cell-attached current is regulated not only by intracellular ATP but also by another cytoplasmic factor/s. This factor seems to require the nucleotide-binding domains of SUR1 to be effective. Thus a mutant Kir6.2 (Kir6.2DeltaC-I296L) expressed in the absence of SUR1 exhibited currents of similar magnitude in cell-attached patches as in inside-out patches exposed to 10 mm MgATP. Similar results were found when Kir6.2-I296L was coexpressed with an SUR1 mutant that is insensitive to MgADP or MgATP activation. This suggests the oocyte contains a cytoplasmic factor that reduces nucleotide binding/hydrolysis at the NBDs of SUR1. In conclusion, our results reveal a novel regulatory mechanism for the K(ATP) channel. This was not evident for wild-type channels because of their high sensitivity to block by ATP.

Adenosine inhibition of adenosine diphosphate and thrombin-induced monocyte-platelet aggregates in cardiac syndrome X.

INTRODUCTION: We previously showed that platelet reactivity at rest is increased in patients with cardiac syndrome X (CSX), but that exercise reduces platelet reactivity in these patients. Adenosine was suggested to be involved in this phenomenon. In this study we investigated the effect of adenosine on adenosine diphosphate (ADP) and thrombin-induced platelet reactivity in CSX patients. MATERIALS AND METHODS: We studied 15 CSX patients and a control group of 15 healthy subjects. Formation of monocyte-platelet (MONO-PLT) aggregates in vitro was assessed by flow cytometry: 1) at baseline; 2) after ADP (10(-7) M) stimulation alone; 3) after ADP stimulation in presence of adenosine (10(-5) M); 4) after thrombin (10(-11) M) stimulation alone; 5) after thrombin stimulation in presence of adenosine. RESULTS: In non stimulated samples there were no relevant differences between the two groups in cytometry variables. Compared to controls, ADP induced a higher increase in MONO-PLT aggregates in CSX patients (P < 0.01), which was significantly inhibited by adenosine (P < 0.01). Thrombin also induced a greater increase in MONO-PLT aggregates in CSX patients (P < 0.001), which was also significantly blunted by adenosine. Similar trends were observed for platelet CD41 (glycoprotein IIb-IIIa) receptor and for monocyte receptors CD142 ad CD162 in MONO-PLT aggregates. CONCLUSIONS: In CSX patients platelet reactivity is increased at rest, compared to healthy controls. Pre-incubation with adenosine reduces the agonist-induced platelet hyper-reactivity in these patients, suggesting that adenosine may be involved in the reduction of platelet reactivity observed in CSX patients after exercise in our previous study.

Perioperative management of patients on adenosine diphosphate inhibitors in the era of drug-eluting stents: review of the literature and clinical implications.

The current adenosine diphosphate inhibitors, ticlopidine and clopidogrel, are thienopyridine compounds that inhibit adenosine diphosphate mediated platelet aggregation. They interfere with platelet activation by selectively and irreversibly blocking P2Y12 sub-unit of the adenosine diphosphate receptor on the surface of platelets. This provides an antiplatelet effect that is additive to the inhibition of the thromboxane A2 pathway by aspirin. Dual antiplatelet therapy is extensively used in cardiovascular medicine. Randomized controlled trials have substantiated the fact that thrombotic complications after percutaneous coronary intervention procedures can be decreased by using dual antiplatelet therapy. However, there is a concern of bleeding due to enhanced and irreversible platelet inhibition in patients who will require any operation including coronary artery bypass grafting while on adenosine diphosphate inhibitors. This applies to a large population of patients requiring either coronary artery bypass grafting after angiographic definition of their coronary anatomy, or patients requiring semi-elective or urgent operation while under dual antiplatelet therapy. This concern is more present in era of drug-eluting stents, where long-term use of dual antiplatelet therapy is encouraged, and the incidence of late thrombosis after late cessation of adenosine diphosphate inhibitors is increasingly surfacing in the literature. The goal this review is to provide the medical chemistry of most commonly used adenosine diphosphate inhibitors, examine the literature on the effect of adenosine diphosphate inhibitors in hemorrhagic-related complications after surgical intervention, and provide the ramifications and alternatives in modern clinical practice.

Anti-platelet effects of flavonoids and flavonoid-glycosides from Sophora japonica.

A methanol extract of Sophora japonica was subjected to anti-platelet activity guided fractionation affording the isolation of four flavonoids and six flavonoid-glycosides: biochanin A (1), irisolidone (2), genistein (3), sissotrin (4), sophorabioside (5), genistin (6), tectoridin (7), apigenin (8), quercitrin (9), and rutin (10). The structure of each compound was determined by a variety of spectroscopic methods. Among the compounds, 1, 3, and 7 showed approximately 2.5-6.5 fold greater inhibitory effects on arachidonic acid (AA) and U46619 induced platelet aggregation (IC50: 19.9 and 99.8 microM; 20.3 and 53.8 microM; 25.9 and 123.4 microM, respectively) than acetylsalicylic acid (ASA, IC50: 63.0 and 350.0 microM). Compound 2 was an approximately 22-40 fold stronger inhibitor than ASA on AA and U46619 induced aggregation (IC50: 1.6 and 15.6 microM, respectively).

Interaction of salvianolic acids and notoginsengnosides in inhibition of ADP-induced platelet aggregation.

Salvia miltiorrhiza and Panax notoginseng were both considered to be beneficial to cardiovascular diseases in traditional Chinese medicine and often used in combination. To examine the possible interaction between them, the effects of the active fractions of these two herbs, salvianolic acids (SA) and notoginsengnosides (NG), on platelet aggregation were checked respectively or in combination in vitro and in vivo. Both the platelet aggregation of platelet rich plasma (PRP) and washed platelet after ADP induction were checked. In vitro study showed that both SA and NG had an inhibitory effect on platelet aggregation. However, there is no synergistic effect of the combination of SA and NG in vitro. In vivo study showed that i.g. 550 mg/kg/day SA or NG for 5 days could significantly inhibit ADP-induced platelet aggregation of PRP. Moreover, combination of SA and NG at a ratio of 5:1 had a synergistic effect on platelet aggregation of PRP. The mechanism for the synergism of SA and NG in vivo was not clear. High performance liquid chromatography analysis of the plasma of rats received SA, NG or combination of SA and NG showed that co-administration of NG caused change in the plasma distribution profile of SA. The influence of combination on the absorption and/or metabolism of SA may be one of the reasons for the synergism of SA and NG in vivo.

Mechanism of inhibition of human KSP by ispinesib.

KSP, also known as HsEg5, is a kinesin that plays an essential role in the formation of a bipolar mitotic spindle and is required for cell cycle progression through mitosis. Ispinesib is the first potent, highly specific small-molecule inhibitor of KSP tested for the treatment of human disease. This novel anticancer agent causes mitotic arrest and growth inhibition in several human tumor cell lines and is currently being tested in multiple phase II clinical trials. In this study we have used steady-state and pre-steady-state kinetic assays to define the mechanism of KSP inhibition by ispinesib. Our data show that ispinesib alters the ability of KSP to bind to microtubules and inhibits its movement by preventing the release of ADP without preventing the release of the KSP-ADP complex from the microtubule. This type of inhibition is consistent with the physiological effect of ispinesib on cells, which is to prevent KSP-driven mitotic spindle pole separation. A comparison of ispinesib to monastrol, another small-molecule inhibitor of KSP, reveals that both inhibitors share a common mode of inhibition.

Inhibition of the adenine nucleotide translocator by N-acetyl perfluorooctane sulfonamides in vitro.

N-alkyl perfluorooctane sulfonamides have been widely used as surfactants on fabrics and papers, fire retardants, and anti-corrosion agents, among many other commercial applications. The global distribution and environmental persistence of these compounds has generated considerable interest regarding potential toxic effects. We have previously reported that perfluorooctanesulfonamidoacetate (FOSAA) and N-ethylperfluorooctanesulfonamidoacetate (N-EtFOSAA) induce the mitochondrial permeability transition (MPT) in vitro. In this study we tested the hypothesis that FOSAA and N-EtFOSAA interact with the adenine nucleotide translocator (ANT) resulting in a functional inhibition of the translocator and induction of the MPT. Respiration and membrane potential of freshly isolated liver mitochondria from Sprague-Dawley rats were measured using an oxygen electrode and a tetraphenylphosphonium-selective (TPP(+)) electrode, respectively. Mitochondrial swelling was measured spectrophotometrically. The ANT ligands bongkregkic acid (BKA) and carboxyatractyloside (cATR) inhibited uncoupling of mitochondrial respiration caused by 10 microM N-EtFOSAA, 40 microM FOSAA, and the positive control 8 microM oleic acid. ADP-stimulated respiration and depolarization of mitochondrial membrane potential were inhibited by cATR, FOSAA, N-EtFOSAA, and oleic acid, but not by FCCP. BKA inhibited calcium-dependent mitochondrial swelling induced by FOSAA, N-EtFOSAA, and oleic acid. Seventy-five micromolar ADP also inhibited swelling induced by the test compounds, but cATR induced swelling was not inhibited by ADP. Results of this investigation indicate that N-acetyl perfluorooctane sulfonamides interact directly with the ANT to inhibit ADP translocation and induce the MPT, one or both of which may account for the metabolic dysfunction observed in vivo.

Oral administration of polyphenolic compounds from cognac decreases ADP-induced platelet aggregation and reduces chronotropic effect of isoprenaline in rats.

This study sought to evaluate whether consumption of polyphenol extract from Cognac (CPC) modulates platelet activation and cardiovascular reactivity in rats. Male Wistar rats were treated daily for 4 weeks by intra-gastric gavage receiving CPC at 80 mg/kg/day or vehicle (5 % glucose). Platelet adhesion and aggregation in response to different activators were assessed. Cardiac and vascular reactivity in response to various agonists as well as NO measurement by electron paramagnetic resonance technique were investigated in isolated heart and thoracic aorta. Oral administration of CPC decreased platelet aggregation induced by ADP but not by collagen. CPC did not affect adhesion to collagen. The chronotropic but not the inotropic response to isoprenaline was reduced without alteration of NO production in hearts from CPC-treated rats. CPC treatment did not affect ex vivo relaxation to acetylcholine nor NO content of rat aorta. CPC did not significantly alter the response to phenylephrine in aorta despite the participation of endothelial vasoconstrictor products. In summary, chronic treatment with CPC has no impact on ex vivo vascular and cardiac reactivity; however, it reduced heart work and platelet aggregation. These data suggest the existence of compounds in Cognac that may decrease the risk of coronary thrombosis and protect against some cardiac diseases.