Regulation of Syk activity in GPVI-mediated platelet activation

Thomas, Dafydd Huw

January 2010

Activation of platelets is essential for hemostasis. Following damage to the vascular endothelium collagen is exposed, to which platelets stably adhere. After adhesion on collagen, a signaling cascade is initiated, mediated by Glycoprotein VI (GPVI), which results in platelet activation. A major signaling protein in GPVI signaling is Spleen tyrosine kinase (Syk). It undergoes phosphorylation and activation following GPVI stimulation. Syk's central role in this physiological process suggests regulation of its activity is required to maintain the platelets response to collagen within physiological limits. The regulation of Syk activation is the focus of this work. Previously published reports implicate the phosphatases SHP-1, SHP-2 and TULA-2 in the negative regulation of Syk. Therefore, we tested these phosphatases possible role in platelets. We show that SHP-1 can dephosphorylate Syk in vitro, but is unable to bind Syk. Also, Syk is hypophosphorylated in GPVI-stimulated SHP-1 deficient platelets and platelet functional responses are minimally affected compared to wild-type platelets. SHP-2 is unable to bind Syk and Syk is not a good substrate for SHP-2 in vitro. TULA-2 dephosphorylated Syk in vitro and associated with Syk in platelets. In TULA-2 deficient platelets, Syk and PLCγ2 were hyperphosphorylated compared to wild-type platelets. Deletion of TULA-2 resulted in enhanced GPVI-dependent platelet functional responses and a prothrombotic phenotype. c-Cbl has been shown to be a negative regulator of GPVI signaling, possibly by regulating Syk phosphorylation. Thus, SHP-1, SHP-2 and TULA-2’s role in c-Cbl regulation of GPVI was also investigated. We show that TULA-2 is able to bind c-Cbl in platelets. SHP-1 and SHP-2 do not. Furthermore, we show a striking similarity between the phenotype of TULA-2 and c-Cbl deficient platelets. However, in vitro binding studies show TULA-2 is able to bind Syk independently of c-Cbl. Thus, the exact role of c-Cbl in regulating Syk dephosphorylation is unclear. In conclusion, we show SHP-1 and SHP-2 are probably not involved in the negative regulation of Syk. However, TULA-2 is the major phosphatase responsible for the negative regulation of Syk in GPVI signaling. This serves to negatively regulate GPVI-mediated platelet function and prevent uncontrolled platelet activation that could lead to thrombosis. / Pharmacology

Health Sciences, Pharmacology

Collagen

Gpvi

Phosphatase

Platelets

Syk

Tula

Mechanisms of platelet inhibition by the selective serotonin reuptake inhibitor citalopram

Roweth, Harvey George

January 2018

Background: Selective serotonin reuptake inhibitor (SSRI) antidepressants prevent serotonin (5-HT) uptake by the serotonin transporter (SERT). Since blood platelets express SERT, SSRIs may modify platelet function and the risk of cardiovascular disease. However, the beneficial or adverse effects of SSRIs on arterial thrombosis are poorly characterised and detailed in vitro experimental data is limited. The SSRI citalopram is a racemate, the (S)-isomer being the more potent SERT inhibitor. Although citalopram has been shown to inhibit platelets in vitro, it is unclear whether this is mediated via SERT blockade. Aim: To determine if citalopram inhibits platelet function via SERT blockade, or through a novel mechanism of action. Findings: 5-HT uptake into platelets was blocked by both citalopram isomers at concentrations that had no apparent effect on platelet function. Despite the (S)-citalopram isomer being the more potent SERT inhibitor, (R)-citalopram was equally potent at inhibiting other platelet functions. These findings strongly suggest that inhibition of platelet function by citalopram in vitro is not mediated by blocking SERT. Subsequent experiments identified two putative mechanisms for citalopram-mediated platelet inhibition: 1) citalopram did not inhibit calcium store release induced by the platelet agonist U46619, despite blocking subsequent Rap1 activation. A credible target for this inhibitory mechanism is the calcium and diacylglycerol guanine nucleotide exchange factor-1 (CalDAG-GEFI): 2) citalopram suppressed early protein phosphorylation within the GPVI pathway, resulting in the inhibition of subsequent platelet responses. Further experiments show that other commonly used antidepressants also inhibit platelets. As with citalopram, inhibition was only observed at concentrations above those required to block SERT, suggesting that alternative inhibitory mechanism(s) are responsible. Conclusions: Data presented in this thesis support two novel putative mechanisms of citalopram-induced platelet inhibition. These findings demonstrate that citalopram and other antidepressants inhibit platelets independently of their ability to block SERT-dependent 5-HT transport. The identification of thesemechanisms provides a pharmacological approach to develop novel antiplatelet agents based on current antidepressants.