Angiotensin II (Ang II) is a critical component of the reninangiotensin system that contributes to hypertension. Although platelets in blood from hypertensive subjects have an abnormal biological profile, it is unclear if circulating Ang II influences platelet aggregation or thrombus formation. One of the abnormalities presented to the platelets during hypertension is an elevated plasma concentration of serotonin (5-HT) caused by reduced 5-HT uptake secondary to loss of the 5-HT transporter (SERT) on the platelet plasma membrane. In the current study, we evaluated in vivo platelet function after 7 days of subcutaneous Ang II infusion to establish hypertension in mice and additionally assessed the biology of isolated platelets exposed to Ang II in vitro. The administration of Ang II elevated systolic blood pressure, but markers of platelet activation including P-selectin and PEJon/A staining were not changed. However, the aggregation response to collagen was reduced in isolated platelets from Ang II-infused mice, which also showed reduced 5-HT uptake by SERT. In vitro exposure of isolated platelets to Ang II also resulted in a loss of surface SERT associated with a reduced aggregation response to collagen. These abnormalities were reversed by increasing concentra tions of the Ang II receptor antagonist, valsartan. Interestingly, SERT KO mice failed to fully develop hypertension in response to Ang II infusion and isolated platelets from these animals were insensitive to the anti-aggregatory influence of Ang II. Thus, Ang II blunts the aggregation responses of platelets and the mechanism underlying this action may involve a loss of SERT on the platelet plasma membrane. The latter event depletes intracellular 5-HT in platelets, an event that is associated with reduced aggregation. The widespread use of antihypertensive drugs that target the renin-angiotensin system suggest the potential clinical utility of our findings and emphasize the importance of understanding the impact of Ang II on platelet function.
Platelets are derived from the cytoplasm of megakaryocytes and enter the circulatory system in an inactive form. An initial activation of platelets stabilizes them in hemostasis. Further platelet activation enlists more platelets at a fibrin-stabilized hemostatic area to form a thrombosis after associating with endothelium or with each other. The resulting thrombus is a leading cause of death for patients with hypertension and cardiovascular disease [
In this regard, an activated renin-angiotensin system and its major biologically active component, angiotensin II (Ang II), contribute to hypertension [
In the present study, we induced hypertension by subcutaneous infusion of Ang II in mice for one week to determine if elevation of circulating Ang II influences platelet aggregation. We reported earlier that the concentration of serotonin (5-HT) in plasma was higher in hypertensive than normotensive human subjects [
The goal of the current study was to determine the role of elevated circulating Ang II on in vivo platelet function using an Ang II-infused mouse model, and then define mechanisms by which Ang II influences platelet phenoltype using in vitro assays. Our findings support the hypothesis that Ang II can attenuate the aggregation response of platelets, an effect that appears to rely on stimulation of the angiotensin type I receptor resulting in loss of 5HT-uptake. Pretreatment with the Ang II recaptor blocker, valsartan, restores 5-HT uptake and platelet aggregation [16,27-29]. Thus Ang II contributes to the adhesive properties of platelets and their aggregability suggesting a potential clinical utility of our findings.
The SERT−/− (SERT KO) was provided by The Jackson Laboratory (Bar Harbor, Maine) which has C57BL6 genetic background [
Adult C57BL/6J wild type or transgenic male mice (10 - 12 weeks old) were anesthetized with isoflurane (2.5% at 1.5 L/min oxygen) for implantation of subcutaneous osmotic mini-pumps (Alzet 2004, Durect Corporation, Cupertino, CA) containing angiotensin II (Ang II, Bachem, Torrance, CA, infusion rate: 2 ng/g/min) [
Procedures involving animals were approved by the Institutional Animal Care and Use Committee and were conducted in accordance with the NIH Guide for the Care and Use of Laboratory Animals.
After 24 hours of continuous infusion with either saline or Ang II, blood was withdrawn into a syringe containing 3.8% sodium citrate solution. Samples of platelet and plasma were prepared from the whole blood [
Systolic blood pressure (SBP) was measured in mice using tail cuff plethysmography using the CODA noninvasive blood pressure system by Kent Scientific Corp (Torrington, CT). Baseline SBP was calculated by averaging a minimum of 6 trials on 2 consecutive days prior to insertion of mini-pumps containing saline or Ang II. The SBP was recorded again by taking a minimum of 6 trials in each mouse after 24 hours of saline or 5-HT infusion and averaging the values daily for one week.
Platelet pellets were quickly washed with phosphatebuffered saline (PBS) containing 0.1 mM CaCl2 and 1 mM MgCl2 (PBSCM), and then resuspended in PBS/CM with 14.6 nM 3H-5-HT at room temperature for 10 min, to include only the initial linear phase of 5-HT transport [16,17]. Platelets were collected by rapid filtration through Whatman GF/B filters and were washed twice with 5 ml of ice-cold PBS. Filters were placed in scintillation vials containing 5 ml scintillation cocktail and immediately counted.
Background accumulation of 3H-5-HT that occurred independently of SERT was measured in the same experiment using platelets incubated with the high-affinity cocaine analog, 0.1 µM 2β-carbomethoxy-3-tropane (β- CIT) (Chemical Synthesis Service, NIMH, Bethesda, MD). The value was subtracted from each experimental value to estimate 5-HT uptake mediated by SERT [
The 5-HT levels in platelet and plasma which were prepared from the blood samples of each animal model were measured by a competitive ELISA technique following the manufacturer’s instructions (IBL ImmunoBiological Laboratories, Hamburg, Germany) [16,17]. Briefly, 5-HT in experimental and control samples were acylated with acetic anhydride in acetone and samples, controls, and standards were applied to 96-well microtitre plates coated with goat anti-rabbit IgG. Biotinylated 5-HT and rabbit antiserum to 5-HT were added to each well and incubated overnight at 4˚C. Para-nitrophenylphosphate in a diethanolamine solution was used as a substrate following the application of alkaline phosphatase conjugated goat anti-biotin antibody (Ab). Samples were read at 405 nm on an ELISA plate reader (Molecular Devices Union City, CA, USA). The amounts of 5-HT were quantified using standards supplied by the manufacturer and analyzed using Origin software (Microcal Software, Northampton, MA).
For aggregation assays, platelets in plasma were prepared and platelet counts were normalized (300,000/µL) using a Hemavet 950 (Drew Scientific, Waterbury, CT). The response to collagen (3 µg/ml) as a platelet agonist was monitored by light transmittance (Chrono-log Corp., Havertown, PA) [
The impact of Ang II on platelet activation was assessed using phycoerythrin (PE) labeled anti-αIIbβ3 (Jon/A) Ab developed to follow integrin activation on mouse platelets [
Nonlinear regression fits of experimental and calculated data were performed using Origin software, which uses the Marquardt-Levenberg non-linear least squares curve fitting algorithm. Each figure shows a representative experiment that was performed at least three times. The statistical analyses given in the Results section is from multiple experiments. Data with error bars are represented as mean ± SEM for triplicate samples. Data were analyzed by ANOVA (analysis of variance) to compare data sets and two-sided t-tests based on the ANOVA mean squared error.
Adult C57BL/6J male mice were randomized to receive osmotic mini-pumps filled with isotonic saline or filled with Ang II. The baseline systolic blood pressure (SBP) was measured on 6 consecutive days prior to insertion of mini-pumps containing saline (control) or Ang II (24 µg Ang II/gram body weight) to achieve an Ang II infusion rate of 2 ng/g/min. Then, the SBP in each mouse was averaged from ≥6 trials each day for one week after saline or Ang II infusion (
Platelets from saline-infused control mice, or from Ang II-infused hypertensive mice, were examined for two markers of platelet activation, P-selectin and integrin.
Next, the rate of aggregation was compared between platelets isolated from control and Ang II-infused mice. Platelets of Ang II-induced hypertensive mice were stimulated with collagen (3 µg/ml) to monitor their behavior in a stirred platelet aggregometer. Isolated plate-
lets from Ang II-infused mice showed a lower aggregation response to collagen than the platelets of saline-infused control mice (
We recently reported an association between loss of the serotonin transporter (SERT) on the platelet surface and the pro-thrombotic influence of elevated plasma 5- HT. To evaluate this event as a potential mechanism for the decreased platelet reactivity in Ang II-infused mice, 5-HT concentrations in platelet and in plasma were determined by ELISA. The platelet 5-HT level was 5.15 ± 0.89 ng/µl for control animals (n = 6) and 4.77 ± 0.14 ng/µl for Ang II-infused animals (n = 5) (
Collectively our data showed that elevation of Ang II in vivo causing hypertension in mice increases the plasma/platelet 5-HT ratio but reduces platelet aggregation. To further understand the involvement of 5-HT and SERT in Ang II-mediated hypertension, we compared blood pressure and platelet profiles between wild type (WT) and SERT knockout (KO) mice. Resting SBP was not significantly different between WT and SERT KO mice. However, infusion of Ang II for one week elevated the SBP of WT mice by 46% compared to a SBP rise of only 17% in SERT KO mice. We next evaluated the aggregation response of platelets from SERT KO mice to collagen stimulation. The aggregation response of platelets isolated from SERT KO or Ang II-infused SERT KO mice to collagen stimulation was not significantly different (
Next, the effect of Ang II on platelet function was examined directly in an in vitro system. Isolated platelets from control (WT) mice were exposed to Ang II (50 or 100 pM) for 10 minutes before aggregation responses
were recorded. The representative aggregation traces shown in
The in vitro effect of Ang II on P-selectin, a marker of platelet activation, also was examined. The results from flow cytometry (
To determine if the effect of Ang II on platelet aggregation was mediated by the AT1 receptor, platelets were incubated for 10 minutes in 100 pM Ang II in the absence or presence of the AT1 receptor blocker, valsartan (5, 10 or 15 µM). Valsartan (15 mM) per se had no effect on the aggregation response of platelets (
Finally we explored if Ang II directly regulates 5-HT uptake or expression of SERT molecules on the platelet surface.
The role of Ang II in modulating platelet function during hypertension is controversial, and both a prothrombotic effect [8-10] and an anti-thrombotic effect have been described [11-15]. The findings in this study help to elucidate the molecular mechanisms by which Ang II may favorably modulate platelet function. Notably, we explored the effects of Ang II on platelet biology using both in vivo and in vitro approaches, since efforts to define the direct actions of Ang II on platelets in vivo may be confounded by its pressor effect, impact on fluid and electrolyte balance, and other actions. For this reason, we also used in vitro assays to more directly assess the effect of Ang II on isolated platelets and thereby also eliminate in vivo influences exerted on platelets by blood pressure, circulating substances, endothelium-derived factors and other modulators of platelet function.
Our first new finding was that isolated platelets from Ang II-infused hypertensive mice failed to show markers of activation. These platelets showed reduced collagen-
induced aggregation responses compared to platelets of saline-infused (control) mice. Thus, despite blood pressure elevation, our data suggest that chronic elevation of Ang II in vivo may exert a protective effect on the function of platelets that can persist even after isolation. Whether this favorable effect of Ang II on platelet aggregation can overpower the purported pro-thrombotic effects of Ang II during hypertension that includes oxidant generation and endothelial damage is unclear [
Our second main finding was that platelets from Ang II-infused hypertensive mice showed blunted 5-HT uptake by SERT resulting in a loss of the primary mechanism for regulating plasma levels of 5-HT and depletion of 5-HT in the platelet cytosol. We were able to recapitulate this response in vitro by exposing isolated platelets directly to Ang II, which caused a decrease in 5-HT uptake. The suppressant effect of Ang II on 5-HT uptake was independent of changes in SERT expression and was reversed by the AT1 receptor antagonist, valsartan, a pharmacological intervention that also reversed the antiaggregation effect of Ang II. Based on these findings and supporting literature [11-15,32,34,36], we propose that AT1 receptor stimulation resulting in a loss of SERT activity and reduces platelet 5-HT signaling represents a newly identified mechanism by which Ang II attenuates aggregation responses. Indeed, findings by earlier investigators using mice with targeted deletion of key genes involved in 5-HT synthesis or signaling suggest loss of intracellular 5-HT can attenuate platelet aggregation. Thus, platelets of SERT KO mice shown to be nearly depleted of 5-HT [30,37] showed attenuated aggregation and Ang II did not further reduce this response. These results also resemble the behavior of platelets in blood samples of 5-HT-infused mice injected with the SSRI, paroxetine, to deplete intracellular 5-HT. Whereas the platelets of 5- HT-infused mice showed an enhanced aggregation response to collagen, lowering the 5-HT uptake rate of these platelets by paroxetine injection restored normal aggregation [16,18,19]. Similarly, isolated platelets of mice lacking the gene for tryptophan hydroxylase (TPH), which is the rate-limiting enzyme in the synthesis of 5-HT in peripheral cells, demonstrated a dual requirement for intracellular 5-HT and Ca2+ for the release of a-granules during activation [
Finally, our finding that SERT KO mice show less blood pressure elevation in response to Ang II infusion than WT mice suggests that a link between Ang II and 5-HT signaling supports this pressor response. Whether SERT deletion in platelets per se or in another cell type accounted for the blunted rise in blood pressure in Ang II-infused SERT KO mice cannot be concluded here. However, the finding which platelets of SERT KO mice depleted of 5HT content show normal surface expression of activation markers but a reduced aggregation response to collagen mirrors the functional profile of platelets exposed to Ang II in vivo or in vitro. Thus, Ang II-induced or a gene-based loss of SERT-mediated 5-HT uptake resulted in an anti-aggregation effect, implying that an unrecognized pathway by which Ang II regulates platelet function may include down-regulation of plasma membrane SERT.
Importantly, clinical studies suggest that elevated plasma 5-HT enhances platelet activation [36-38], and plasma 5-HT may be increased in hypertension [17,39-44]. Our earlier studies also suggest that elevated plasma 5-HT is associated with an enhanced propensity for platelet aggregation [
Additional studies are necessary to elucidate the precise mechanism by which Ang II attenuates 5-HT uptake by SERT, which our findings demonstrate relies on AT1 receptor signaling. It also may be important to evaluate if valsartan and other AT1 receptor antagonists alter in vivo platelet function, since our data suggest that valsartan reversed the anti-aggregation effect of Ang II. Our novel findings provide a basis for future studies by suggesting that Ang II confers an anti-aggregation platelet profile that may rely in part on reduced 5-HT uptake by SERT conferred by AT1 receptor signaling. The potential clinical utility of this finding will require further studies.
We gratefully acknowledge the UAMS Division of Laboratory Animal Medicine and Flow Cytometry Core. This work was supported by the American Heart Association [Grant 0660032Z] and by the NIH National Heart Lung and Blood Institute Grant HL091196-04 to FK.