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Platelets, small anucleate cell fragments in the blood stream, derive from large precursor cells, so-called megakaryocytes (MK) residing in the bone marrow (BM). In addition to their role in wound healing, platelets have been shown to play a significant role during inflammatory bleeding. Above all, the immunoreceptor tyrosine-based activation motif (ITAM) receptors GPVI as well as CLEC-2 have been identified as main regulators of vascular integrity.
In addition to ITAM-bearing receptors, our group identified GPV as another potent regulator of hemostasis and thrombosis. Surprisingly, concomitant lack of GPV and CLEC-2 deteriorated blood-lymphatic misconnections observed in Clec2-/- mice resulting in severe edema formation and intestinal inflammation. Analysis of lymphatic and vascular development in embryonic mesenteries revealed severely defective blood-lymph-vessel separation, which translated into thrombocytopenia and increased vascular permeability due to reduced tight junction density in mesenteric blood vessels and consequent leakage of blood into the peritoneal cavity.
Recently, platelet granule release has been proposed to ameliorate the progression of retinopathy of prematurity (ROP), a fatal disease in newborns leading to retinal degradation. The mechanisms governing platelet activation in this process remained elusive nonetheless, which prompted us to investigate a possible role of ITAM signaling. In the second part of this thesis, granule release during ROP was shown to be GPVI- and partly CLEC-2-triggered since blockade or loss of these receptors markedly deteriorated ROP progression.
Proplatelet formation from MKs is highly dependent on a functional microtubule and actin cytoskeleton, the latter of which is regulated by several actin-monomer binding proteins including Cofilin1 and Twinfilin1 that have been associated with actin-severing at pointed ends. In the present study, a redundancy between both proteins especially important for the guided release of proplatelets into the bloodstream was identified, since deficiency in both proteins markedly impaired MK functionality mainly due to altered actin-microtubule crosstalk.
Besides ITAM-triggered activation, platelets and MKs are dependent on inhibitory receptors, which prevent overshooting activation. We here identified macrothrombocytopenic mice with a mutation within Mpig6b encoding the ITIM-bearing receptor G6b-B. G6b-B-mutant mice developed a severe myelofibrosis associated with sex-specific bone remodeling defects resulting in osteosclerosis and -porosis in female mice. Moreover, G6b-B was shown to be indispensable for MK maturation as verified by a significant reduction in MK-specific gene expression in G6b-B-mutant MKs due to reduced GATA-1 activity.
Studies on platelet cytoskeletal dynamics and receptor regulation in genetically modified mice
(2009)
Platelets are produced by bone marrow megakaryocytes in a process involving actin dynamics. Actin-depolymerizing factor (ADF) and cofilin are actin-binding proteins that act as key regulators in actin turnover by promoting filament severing and depolymerization. The overall significance of ADF/cofilin function and actin turnover in platelet formation is presently unclear. In the first part of this thesis, platelet formation and function were studied in mice constitutively lacking ADF and/or mice with a conditional deficiency (Cre/loxP) in n-cofilin. To delete cofilin exclusively in megakaryocytes and platelets, cofilinfl/fl mice were crossed with PF4 (platelet factor 4)-Cre mice. While a single-deficiency in ADF or n-cofilin resulted in no or only a minor platelet formation defect, respectively, a double-deficiency in ADF and n-cofilin led to an almost complete loss of platelets. Bone marrow megakaryocytes of ADF/n-cofilin-deficient mice showed defective platelet zone formation. Interestingly, in vitro and ex vivo megakaryocyte differentiation revealed reduced proplatelet formation and absence of platelet-forming swellings. These data establish that ADF and n-cofilin have redundant but essential roles in the terminal step of platelet formation in vitro and in vivo. In the second part of the thesis, mechanisms underlying cellular regulation of the major platelet collagen receptor, glycoprotein VI (GPVI), were studied. GPVI mediates platelet activation on exposed subendothelial collagens at sites of vascular injury, and thereby contributes to normal hemostasis but also to occlusion of diseased vessels in the setting of myocardial infarction or stroke. Thus, GPVI is an attractive target for anti-thrombotic therapy, particularly because previous studies have shown that anti-GPVI antibodies induce irreversible down-regulation of the receptor in circulating platelets by internalization and ectodomain shedding. Metalloproteinases of the ADAM (a disintegrin and metalloproteinase domain) family are suspected to mediate this ectodomain shedding, but in vivo evidence for this is lacking. To study the mechanism of GPVI regulation in vivo, two mouse lines, Gp6 knock-out and Adam10fl/fl, PF4-Cre mice, were generated and in addition low TACE (TNFalpha converting enzyme) mice were analyzed. It was shown that GPVI can be cleaved in vitro by ADAM10 or TACE depending on the shedding-inducing signaling pathway. Moreover, GPVI was down-regulated in vivo upon antibody injection in ADAM10-deficient and low TACE mice suggesting that either both or an additional metalloproteinase is involved in GPVI regulation in vivo.
Platelets have a key physiological role in haemostasis however, inappropriate thrombus formation can lead to cardiovascular diseases such as myocardial infarction or stroke. Although, such diseases are common worldwide there are comparatively few anti-platelet drugs, and these are associated with an increased risk of bleeding. Platelets also have roles in thrombo-inflammation, immuno-thrombosis and cancer, in part via C-type lectin-like receptor 2 (CLEC-2) and its ligand podoplanin. Although CLEC-2 contributes to these diseases in mice, as well as to thrombus stability, it is unclear whether CLEC-2 has similar roles in humans, particularly as human CLEC-2 (hCLEC-2) cannot be investigated experimentally in vivo.
To investigate hCLEC-2 in vivo, we generated a humanised CLEC-2 mouse (hCLEC-2KI) model, as well as a novel monoclonal antibody, HEL1, that binds to a different site than an existing antibody, AYP1. Using these antibodies, we have provided proof of principle for the use of hCLEC-2KI mice to test potential therapeutics targeting hCLEC-2, and shown for the first time that hCLEC-2 can be immunodepleted, with little effect on haemostasis. However, our results have also suggested that there are species differences in the role of CLEC-2 in arterial thrombosis. We further confirmed this using human blood where blocking CLEC-2 ligand binding had no effect on thrombosis, whereas we confirmed a minor role for mouse CLEC-2 in thrombus stability. We also investigated the effect of blocking CLEC-2 signalling using the Bruton’s tyrosine kinase inhibitor PRN473 on CLEC-2 mediated immuno-thrombosis in a Salmonella typhimurium infection model. However, no effect on thrombosis was observed suggesting that CLEC-2 signalling is not involved.
Overall, our results suggest that there may be differences in the role of human and mouse CLEC-2, at least in arterial thrombosis, which could limit the potential of CLEC-2 as an anti-thrombotic target. However, it appears that the interaction between CLEC-2 and podoplanin is conserved and therefore CLEC-2 could still be a therapeutic target in immuno-thrombosis, thrombo-inflammation and cancer. Furthermore, any potential human specific therapeutics could be investigated in vivo using hCLEC-2KI mice.
An increase in cytosolic Ca2+ levels ([Ca2+]i) is a key event that occurs downstream of many signaling cascades in response to an external stimulus and regulates a wide range of cellular processes, including platelet activation. Eukaryotic cells increase their basal [Ca2+]i allowing extracellular Ca2+ influx into the cell, which involves different mechanisms. Store-operated Ca2+ entry (SOCE) is considered the main mechanism of extracellular Ca2+ influx in electrically non-excitable cells and platelets, and comprises an initial Ca2+ depletion from intracellular Ca2+ stores prior to activation of extracellular Ca2+ influx. Although the close relation between Ca2+ release from intracellular stores and extracellular Ca2+ influx was clear, the nature of the signal that linked both events remained elusive until 2005, when Stromal Interaction Molecule 1 (STIM1) was identified as an endoplasmic reticulum (ER) Ca2+ sensor essential for inositol (1,4,5)-trisphosphate (IP3)-mediated SOCE in vitro. However, the function of its homologue STIM2 in Ca2+ homeostasis was in general unknown. Therefore, mice lacking STIM2 (Stim2-/-) were generated in this work to study initially STIM2 function in platelets and in cells of the immune system. Stim2-/- mice developed normally in size and weight to adulthood and were fertile. However, for unknown reasons, they started to die spontaneously at the age of 8 weeks. Unexpectedly, Stim2-/- mice did not show relevant differences in platelets, revealing that STIM2 function is not essential in these cells. However, STIM2 seems to be involved in mammary gland development during pregnancy and is essential for mammary gland function during lactation. CD4+ T cells lacking STIM2 showed decreased SOCE. Our data suggest that STIM2 has a very specific function in the immune system and is involved in Experimental Autoimmune Encephalomyelitis (EAE) at early stages of the disease progression. Stim2-/- neurons were also defective in SOCE. Surprisingly, our results evidenced that STIM2 participates in mechanisms of neuronal damage after ischemic events in brain. This is the first time that the involvement of SOCE in ischemic neuronal damage has been reported. This finding may serve as a basis for the development of novel neuroprotective agents for the treatment of ischemic stroke, and possibly other neurodegenerative disorders in which disturbances in cellular Ca2+ homeostasis are considered a major pathophysiological component.
Divalent cations are important second messengers triggering various signal transduction events in platelets. Whereas calcium channel blockers have an established antithrombotic effect and the regulation of Ca2+ homeostasis has been elucidated in platelets, the molecular regulation of Mg2+ and Zn2+ homeostasis has not been investigated so far.
In the first part of the thesis, the role of -type serine-threonine kinase linked to transient receptor potential cation channel, subfamily M, member 7 (TRPM7) in platelets was investigated. Using Trpm7R/R mice with a point mutation deleting the kinase activity, we showed that the TRPM7 kinase regulates platelet activation via immunoreceptor tyrosine-based activation motif (ITAM), hem(ITAM) and protease-activated receptor (PAR) signaling routes. Furthermore, Trpm7R/R mice were protected from in vivo thrombosis and stroke, thus establishing TRPM7 kinase as a promising anti-thrombotic target.
In the second part of the thesis, the role of TRPM7 channel in a megakaryocyte (MK) and platelet-specific knockout mouse, Trpm7fl/fl-Pf4Cre, was investigated. Here, we observed that depending on the type of stimulation, Trpm7fl/fl-Pf4Cre platelets showed either enhanced or inhibited responses. Although Trpm7fl/fl-Pf4Cre mice were thrombocytopenic, no differences to wildtype mice were observed in models of in vivo thrombosis and stroke. The above two studies highlight that inhibition of TRPM7 kinase but not the channel itself (in MKs and platelets) may be a promising anti-thrombotic strategy.
Besides TRPM7, we investigated the role of magnesium transporter 1 (MAGT1) in platelet Mg2+ homeostasis and found that MAGT1 primarily regulates receptor-operated calcium entry (ROCE) in platelets specifically upon GPVI activation. This physiological crosstalk is triggered by protein kinase C (PKC) isoforms. Platelets from Magt1-/y mice hyper-reacted to GPVI and thromboxane A2 (TXA2) receptor stimulation in vitro. Consequently, Magt1-/y platelets were found to be pro-thrombotic in disease models of thrombosis and stroke.
To compare platelet ITAM-signaling to the immune system, we further investigated the role of MAGT1 in T and B cells. We described the primary role of MAGT1 in mice under pathogen-free conditions. Magt1-/y B cells showed dysregulated Mg2+ and Ca2+ homeostasis upon B-cell receptor activation, thereby altering Syk, LAT, phospholipase C (PLC)2 and PKC phosphorylation. In contrast to human MAGT1-deficient T cells, development and effector functions of mouse Magt1-/y T cells showed no alterations.
Finally, in the last part of the thesis, we described methods to measure intracellular free zinc [Zn2+]i in human and mouse platelets with storage pool disease (SPD). We propose to measure the [Zn2+]i status in SPD platelets as a relatively easy diagnostic to screen platelet granule abnormalities.
Every year, stroke affects over 100 million people worldwide and the number of cases continues to grow. Ischemic stroke is the most prevalent form of stroke and rapid restoration of blood flow is the primary therapeutic aim. However, recanalization might fail or reperfusion itself induces detrimental processes leading to infarct progression. Previous studies identified platelets and immune cells as drivers of this so-called ischemia/reperfusion (I/R) injury, establishing the concept of ischemic stroke as thrombo-inflammatory disease. Reduced cerebral blood flow despite recanalization promoted the hypothesis that thrombus formation within the cerebral microcirculation induces further tissue damage. The results presented in this thesis refute this: using complementary methodologies, it was shown that infarct growth precedes the occurrence of thrombi excluding them as I/R injury-underlying cause. Blood brain barrier disruption is one of the hallmarks of ischemic stroke pathology and was confirmed as early event during reperfusion injury in the second part of this study. Abolished platelet α-granule release protects mice from vascular leakage in the early reperfusion phase resulting in smaller infarcts. Using in vitro assays, platelet α-granule-derived PDGF-AB was identified as one factor contributing to blood-brain barrier disruption.
In vivo visualization of platelet activation would provide important insights in the spatio-temporal context of platelet activation in stroke pathology. As platelet signaling results in elevated intracellular Ca2+ levels, this is an ideal readout. To overcome the limitations of chemical calcium indicators, a mouse line expressing an endogenous calcium reporter specifically in platelets and megakaryocytes was generated. Presence of the reporter did not interfere with platelet function, consequently these mice were characterized in in vivo and ex vivo models.
Upon ischemic stroke, neutrophils are among the first cells that are recruited to the brain. Since for neutrophils both, beneficial and detrimental effects are described, their role was investigated within this thesis. Neither neutrophil depletion nor absence of NADPH-dependent ROS production (Ncf-/- mice) affected stroke outcome. In contrast, abolished NET-formation in Pad4-/- mice resulted in reduced infarct sizes, revealing detrimental effects of NETosis in the context of ischemic stroke, which might become a potential therapeutic target.
Cerebral venous (sinus) thrombosis, CV(S)T is a rare type of stroke with mainly idiopathic onset. Whereas for arterial thrombosis a critical contribution of platelets is known and widely accepted, for venous thrombosis this is less clear but considered more and more. In the last part of this thesis, it was shown that fab-fragments of the anti-CLEC-2 antibody INU1 trigger pathological platelet activation in vivo, resulting in foudroyant CVT accompanied by heavy neurological symptoms. Using this novel animal model for CVT, cooperative signaling of the two platelet receptors CLEC-2 and GPIIb/IIIa was revealed as major trigger of CVT and potential target for treatment.
Platelet activation and aggregation at sites of vascular injury are essential processes to limit blood loss but they also contribute to arterial thrombosis, which can lead to myocardial infarction and stroke. Stable thrombus formation requires a series of events involving platelet receptors which contribute to adhesion, activation and aggregation of platelets. Regulation of receptor expression by (metallo-)proteinases has been described for several platelet receptors, but the molecular mechanisms are ill-defined. The signaling lymphocyte activation molecule (SLAM) family member CD84 is expressed in immune cells and platelets, however its role in platelet physiology was unclear. In this thesis, CD84 deficient mice were generated and analyzed. In well established in vitro and in vivo assays testing platelet function and thrombus formation, CD84 deficient mice displayed phenotypes indistinguishable from wild-type controls. It was concluded that CD84 in platelets does not function as modulator of thrombus formation, but rather has other functions. In line with this, in the second part of this thesis, a novel regulation mechanism for platelet CD84 was discovered and elucidated. Upon platelet activation, the N-terminus of CD84 was found to be cleaved exclusively by the a disintegrin and metalloproteinase 10 (ADAM10), whereas the intracellular part was cleaved by calpain. In addition, regulation of the platelet activating collagen receptor glycoprotein VI (GPVI) was studied and it was shown that GPVI is in contrast to CD84 differentially regulated by ADAM10 and ADAM17. A novel role of CD84 under pathophysiological conditions was revealed as CD84 deficient mice were protected from ischemic stroke in the model of transient middle cerebral artery occlusion and this protection was based on the lack of CD84 in T cells. Ca2+ is an essential second messenger that facilitates activation of platelets and diverse functions in different eukaryotic cell types. Store-operated Ca2+ entry (SOCE) represents the major mechanism leading to rise in intracellular Ca2+ concentration in non-excitable cells. The Ca2+ sensor STIM1 (stromal interaction molecule 1) and the SOC channel subunit protein Orai1 are established mediators of SOCE in platelets. STIM2 is the major STIM isoform in neurons, but the role of the SOC channel subunit protein Orai2 in platelets and neurons has remained elusive. In the third part of this thesis, Orai2 deficient mice were generated and analyzed. Orai2 was dispensable for platelet function, however, Orai2 deficient mice were protected from ischemic neurodegeneration and this phenotype was attributed to defective SOCE in neurons.
The pancreas is the key organ for the maintenance of euglycemia. This is regulated in particular by α-cell-derived glucagon and β-cell-derived insulin, which are released in response to nutrient deficiency and elevated glucose levels, respectively. Although glucose is the main regulator of insulin secretion, it is significantly enhanced by various potentiators.
Platelets are anucleate cell fragments in the bloodstream that are essential for hemostasis to prevent and stop bleeding events. Besides their classical role, platelets were implemented to be crucial for other physiological and pathophysiological processes, such as cancer progression, immune defense, and angiogenesis. Platelets from diabetic patients often present increased reactivity and basal activation. Interestingly, platelets store and release several substances that have been reported to potentiate insulin secretion by β-cells. For these reasons, the impact of platelets on β-cell functioning was investigated in this thesis.
Here it was shown that both glucose and a β-cell-derived substance/s promote platelet activation and binding to collagen. Additionally, platelet adhesion specifically to the microvasculature of pancreatic islets was revealed, supporting the hypothesis of their influence on glucose homeostasis. Genetic or pharmacological ablation of platelet functioning and platelet depletion consistently resulted in reduced insulin secretion and associated glucose intolerance. Further, the platelet-derived lipid fraction was found to enhance glucose-stimulated insulin secretion, with 20-hydroxyeicosatetraenoic acid (20-HETE) and possibly also lyso-precursor of platelet-activating factor (lysoPAF) being identified as crucial factors. However, the acute platelet-stimulated insulin secretion was found to decline with age, as did the levels of platelet-derived 20-HETE. In addition to their direct stimulatory effect on insulin secretion, specific defects in platelet activation have also been shown to affect glucose homeostasis by potentially influencing islet vascular development. Taking together, the results of this thesis suggest a direct and indirect mechanism of platelets in the regulation of insulin secretion that ensures glucose homeostasis, especially in young individuals.
Platelet activation and adhesion results in thrombus formation that is essential for normal hemostasis, but can also cause irreversible vessel occlusion leading to myocardial infarction or stroke. The C-type lectin-like receptor 2 (CLEC-2) was recently identified to be expressed on the platelet surface, however, a role for this receptor in hemostasis and thrombosis had not been demonstrated. In the current study, the involvement of CLEC-2 in platelet function and thrombus formation was investigated using mice as a model system. In the first part of the thesis, it was found that treatment of mice with a newly generated monoclonal antibody against murine CLEC-2 (INU1) led to the complete and highly specific loss of the receptor in circulating platelets (a process termed “immunodepletion”). CLEC-2-deficient platelets were completely unresponsive to the CLEC-2-specific agonist rhodocytin, whereas activation induced by all other tested agonists was unaltered. This selective defect translated into severely decreased platelet aggregate formation under flow ex vivo; and in vivo thrombosis models revealed impaired stabilization of formed thrombi with enhanced embolization. Consequently, CLEC-2 deficiency profoundly protected mice from occlusive arterial thrombus formation. Furthermore, variable bleeding times in INU1-treated mice indicated a moderate hemostatic defect. This reveals for the first time that CLEC-2 significantly contributes to thrombus stability in vitro and in vivo and plays a crucial role in hemostasis and arterial thrombosis. Thus, CLEC-2 represents a potential novel anti-thrombotic target that can be functionally inactivated in vivo. This in vivo down-regulation of platelet surface receptors might be a promising approach for future anti-thrombotic therapy. The second part of the work investigated the effect of double-immunodepletion of the immunoreceptor tyrosine-based activation motif (ITAM)- and hemITAM-coupled receptors, platelet glycoprotein (GP) VI and CLEC-2, on hemostasis and thrombosis using a combination of the GPVI- and CLEC-2-specific antibodies, JAQ1 and INU1, respectively. Isolated targeting of either GPVI or CLEC-2 in vivo did not affect expression or function of the respective other receptor. However, simultaneous treatment with both antibodies resulted in the sustained loss of GPVI and CLEC-2 signaling in platelets, while leaving other activation pathways intact. In contrast to single deficiency of either receptor, GPVI/CLEC-2 double-deficient mice displayed a dramatic hemostatic defect. Furthermore, this treatment resulted in profound impairment of arterial thrombus formation that far exceeded the effects seen in single-depleted animals. Importantly, similar results were obtained in Gp6-/- mice that were depleted of CLEC-2 by INU1-treatment, demonstrating that this severe bleeding phenotype was not caused by secondary effects of combined antibody treatment. These data suggest that GPVI and CLEC-2 can be independently or simultaneously down-regulated in platelets in vivo and reveal an unexpected functional redundancy of the two receptors in hemostasis and thrombosis. Since GPVI and CLEC-2 have intensively been discussed as potential anti-thrombotic targets, these results may have important implications for the development of novel, yet save anti-GPVI or anti-CLEC-2-based therapies.
Platelet activation induces cytoskeletal rearrangements involving a change from discoid to spheric shape, secretion, and eventually adhesion and spreading on immobilized ligands. Small GTPases of the Rho family, such as Rac1 and Cdc42, are known to be involved in these processes by facilitating the formation of lamellipodia and filopodia, respectively. This thesis focuses on the role Rac1 and Cdc42 for platelet function and formation from their precursor cells, the megakaryocytes (MKs), using conditional knock-out mice. In the first part of the work, the involvement of Rac1 in the activation of the enzyme phospholipase (PL) C2 in the signaling pathway of the major platelet collagen receptor glycoprotein (GP) VI was investigated. It was found that Rac1 is essential for PLC2 activation independently of tyrosine phosphorylation of the enzyme, resulting in a specific platelet activation defect downstream of GPVI, whereas signaling of other activating receptors remains unaffected. Since Rac1-deficient mice were protected from arterial thrombosis in two different in vivo models, the GTPase might serve as a potential target for the development of new drugs for the treatment and prophylaxis of cardio- and cerebrovascular diseases. The second part of the thesis deals with the first characterization of MK- and platelet-specific Cdc42 knock-out mice. Cdc42-deficient mice displayed mild thrombo-cytopenia and platelet production from mutant MKs was markedly reduced. Unexpectedly, Cdc42-deficient platelets showed increased granule content and release upon activation, leading to accelerated thrombus formation in vitro and in vivo. Furthermore, Cdc42 was not generally required for filopodia formation upon platelet activation. Thus, these results indicate that Cdc42, unlike Rac1, is involved in multiple signaling pathways essential for proper platelet formation and function. Finally, the outcome of combined deletion of Rac1 and Cdc42 was studied. In contrast to single deficiency of either GTPase, platelet production from double-deficient MKs was virtually abrogated, resulting in dramatic macrothrombocytopenia in the animals. Formed platelets were largely non-functional leading to a severe hemostatic defect and defective thrombus formation in double-deficient mice in vivo. These results demonstrate for the first time a functional redundancy of Rac1 and Cdc42 in the hematopoietic system.