570 Biowissenschaften; Biologie
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Platelets play an important role in haemostasis by mediating blood clotting at sites of blood vessel damage. Platelets, also participate in pathological conditions including thrombosis and inflammation. Upon vessel damage, two glycoprotein receptors, the GPIb-IX-V complex and GPVI, play important roles in platelet capture and activation.
GPIb-IX-V binds to von Willebrand factor and GPVI to collagen. This initiates a signalling cascade resulting in platelet shape change and spreading, which is dependent on the actin cytoskeleton. This thesis aimed to develop and implement different super-resolution microscopy techniques to gain a deeper understanding of the conformation and location of these receptors in the platelet plasma membrane, and to provide insights into their signalling pathways. We suggest direct stochastic optical reconstruction microscopy (dSTORM) and structured illumination microscopy (SIM) as the best candidates for imaging single platelets, whereas expansion microscopy (ExM) is ideal for imaging platelets aggregates.
Furthermore, we highlighted the role of the actin cytoskeleton, through Rac in GPVI signalling pathway. Inhibition of Rac, with EHT1864 in human platelets induced GPVI and GPV, but not GPIbα shedding. Furthermore, EHT1864 treatment did not change GPVI dimerisation or clustering, however, it decreased phospholipase Cγ2 phosphorylation levels, in human, but not murine platelets, highlighting interspecies differences. In summary, this PhD thesis demonstrates that; 1) Rac alters GPVI signalling pathway in human but not mouse platelets; 2) our newly developed ExM protocol can be used to image platelet aggregates labelled with F(ab’) fragments
Kef couples the potassium efflux with proton influx in gram-negative bacteria. The resulting acidification of the cytosol efficiently prevents the killing of the bacteria by reactive electrophilic compounds. While other degradation pathways for electrophiles exist, Kef is a short-term response that is crucial for survival. It requires tight regulation since its activation comes with the burden of disturbed homeostasis. Electrophiles, entering the cell, react spontaneously or catalytically with glutathione, which is present at high concentrations in the cytosol. The resulting glutathione conjugates bind to the cytosolic regulatory domain of Kef and trigger activation while the binding of glutathione keeps the system closed. Furthermore, nucleotides can bind to this domain for stabilization or inhibition. The binding of an additional ancillary subunit, called KefF or KefG, to the cytosolic domain is required for full activation. The regulatory domain is termed K+ transport–nucleotide binding (KTN) or regulator of potassium conductance (RCK) domain, and it is also found in potassium uptake systems or channels in other oligomeric arrangements. Bacterial RosB-like transporters and K+ efflux antiporters (KEA) of plants are homologs of Kef but fulfill different functions. In summary, Kef provides an interesting and well-studied example of a highly regulated bacterial transport system.
Monoglyceride lipase (MGL) hydrolyzes monoacylglycerols (MG) to glycerol and one fatty acid. Among the various MG species, MGL also degrades 2-arachidonoylglycerol, the most abundant endocannabinoid and potent activator of the cannabinoid receptors 1 and 2. We investigated the consequences of MGL deficiency on platelet function using systemic (Mgl\(^{−/−}\)) and platelet-specific Mgl-deficient (platMgl\(^{−/−}\)) mice. Despite comparable platelet morphology, loss of MGL was associated with decreased platelet aggregation and reduced response to collagen activation. This was reflected by reduced thrombus formation in vitro, accompanied by a longer bleeding time and a higher blood volume loss. Occlusion time after FeCl\(_3\)-induced injury was markedly reduced in Mgl\(^{−/−}\) mice, which is consistent with contraction of large aggregates and fewer small aggregates in vitro. The absence of any functional changes in platelets from platMgl\(^{−/−}\) mice is in accordance with lipid degradation products or other molecules in the circulation, rather than platelet-specific effects, being responsible for the observed alterations in Mgl\(^{−/−}\) mice. We conclude that genetic deletion of MGL is associated with altered thrombogenesis.
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.
Clostridioides bacteria are responsible for life threatening infections. Here, we show that in addition to actin, the binary toxins CDT, C2I, and Iota from Clostridioides difficile, botulinum, and perfrigens, respectively, ADP-ribosylate the actin-related protein Arp2 of Arp2/3 complex and its additional components ArpC1, ArpC2, and ArpC4/5. The Arp2/3 complex is composed of seven subunits and stimulates the formation of branched actin filament networks. This activity is inhibited after ADP-ribosylation of Arp2. Translocation of the ADP-ribosyltransferase component of CDT toxin into human colon carcinoma Caco2 cells led to ADP-ribosylation of cellular Arp2 and actin followed by a collapse of the lamellipodial extensions and F-actin network. Exposure of isolated mouse colon pieces to CDT toxin induced the dissolution of the enterocytes leading to luminal aggregation of cellular debris and the collapse of the mucosal organization. Thus, we identify the Arp2/3 complex as hitherto unknown target of clostridial ADP-ribosyltransferases.
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.
The platelet-activating collagen receptor GPVI represents the focus of clinical trials as an antiplatelet target for arterial thrombosis, and soluble GPVI is a plasma biomarker for several human diseases. A disintegrin and metalloproteinase 10 (ADAM10) acts as a ‘molecular scissor’ that cleaves the extracellular region from GPVI and many other substrates. ADAM10 interacts with six regulatory tetraspanin membrane proteins, Tspan5, Tspan10, Tspan14, Tspan15, Tspan17 and Tspan33, which are collectively termed the TspanC8s. These are emerging as regulators of ADAM10 substrate specificity. Human platelets express Tspan14, Tspan15 and Tspan33, but which of these regulates GPVI cleavage remains unknown. To address this, CRISPR/Cas9 knockout human cell lines were generated to show that Tspan15 and Tspan33 enact compensatory roles in GPVI cleavage, with Tspan15 bearing the more important role. To investigate this mechanism, a series of Tspan15 and GPVI mutant expression constructs were designed. The Tspan15 extracellular region was found to be critical in promoting GPVI cleavage, and appeared to achieve this by enabling ADAM10 to access the cleavage site at a particular distance above the membrane. These findings bear implications for the regulation of cleavage of other ADAM10 substrates, and provide new insights into post-translational regulation of the clinically relevant GPVI protein.
Short functional peptidic probes can maximize the potential of high-end microscopy techniques and multiplex imaging assays and provide new insights into normal and aberrant molecular, cellular and tissue function. Particularly, the visualization of inhibitory synapses requires protocol tailoring for different sample types and imaging techniques and relies either on genetic manipulation or on antibodies that underperform in tissue immunofluorescence. Starting from an endogenous activity-related ligand of gephyrin, a universal marker of the inhibitory post-synapse, I developed a short peptidic multivalent binder with exceptional affinity and selectivity to gephyrin. By tailoring fluorophores to the binder, I have obtained Sylite, a probe for the visualization of inhibitory synapses, with an outstanding signal-to-background ratio, that bests the “gold standard” gephyrin antibodies both in selectivity and in tissue immunofluorescence. In tissue Sylite benefits from simplified handling, provides robust synaptic labeling in record-short time and, unlike antibodies, is not affected by staining artefacts. In super-resolution microscopy Sylite precisely localizes the post-synapse and enables accurate pre- to post-synapse measurements. Combined with complimentary tracing techniques Sylite reveals inhibitory connectivity and profiles inhibitory inputs and synapse sizes of excitatory and inhibitory neurons in the periaqueductal gray brain region. Lastly, upon probe optimization for live cell application and with the help of novel thiol-reactive cell penetrating peptide I have visualized inhibitory synapses in living neurons. Taken together, my work provided a versatile probe for conventional and super-resolution microscopy and a workflow for the development and application of similar compact functional synthetic probes.
Ubiquitylation is a protein post translational modification, in which ubiquitin is covalently attached to target protein substrates resulting in diverse cellular outcomes. Besides ubiquitin, various ubiquitin-like proteins including FAT10 exist, which are also conjugated to target proteins. The underlying modification mechanisms are conserved. In the initial step, ubiquitin or a ubiquitin-like protein is thioester-linked to a catalytic cysteine in the E1activating enzyme in an ATP-dependent manner. The respective protein modifier is then transferred to an E2 conjugating enzyme in a transthioesterification reaction. Finally, an E3 ubiquitin ligase E3 catalyzes the covalent attachment of the protein modifier to a substrate. In the case of ubiquitin, multiple ubiquitin molecules can be attached to a substrate in the form of either linear or branched polyubiquitin chains but also as single ubiquitin modifications. Depending on the nature of the ubiquitin chain, the substrates are destined to various cellular processes such as their targeted destruction by the proteasome but also non-degradative outcomes may occur.
As stated above FAT10 is a ubiquitin-like protein modifier which typically targets proteins for proteasomal degradation. It consists of two ubiquitin-like domains and is mainly expressed in cells of the human immune system. The reported involvement of FAT10 modifications in cancers and other diseases has caught the attention of the scientific community as an inhibition of the FAT10ylation process may provide avenues for novel therapeutic approaches. UBA6 is the E1 activating enzyme that resides at the apex of the FAT10 proteasomal degradation pathway. UBA6 not only recognizes FAT10 but can also activate ubiquitin as efficiently as the ubiquitin specific E1 UBA1. The dual specificity of UBA6 may complicate the inhibition FAT10ylation since targeting the active site of UBA6 will also inhibit the UBA6-catalyzed ubiquitin activation. Therefore, it is important to understand the underlying principles for the dual specificity of UBA6 prior to the development of compounds interfering with FAT10ylation.
In this thesis important novel insights into the structure and function of UBA6 were derived by X-ray crystallography and biochemical methods. The first crystal structure of UBA6 reveals the multidomain architecture of this enzyme in atomic detail. The enzyme is composed of a rigid core including its active and inactive adenylation domains as well as a 4 helix bundle. Overall, the molecule adopts a “Y” shape architecture with the core at the base and the first and second catalytic half domains forming one arm of the “Y” and the ubiquitin fold domain constituting the other arm. While UBA6 shares the same domain architecture as UBA1, substantial differences were revealed by the crystal structure. In particular, the first catalytic half domain undergoes a significant shift to a position more distal from the core. This rigid body movement is assumed to generate room to accommodate the second ubiquitin-like domain of FAT10. Differences are also observed in a hydrophobic platform between the core and the first catalytic half domain and the adenylation active site in the core, which together from the binding sites for ubiquitin and FAT10. Site directed mutagenesis of key residues in these areas altered the UBA6-catalyzed activation of ubiquitin and FAT10. UBA6 variants were generated with the goal of trying to block the activation of FAT10 while still maintaining that of ubiquitin activation, in order to fully explain the dual specificity of UBA6. However, none of these mutations could block the activation of FAT10, while some of these UBA6 variants blocked ubiquitin activation. Preliminary inhibition assays with a group of E1 inhibitors belonging to the adenosyl sulfamate family demonstrated potent inhibition of FAT10ylation for two compounds. The dual specificity of UBA6 hence needs to be further examined by biochemical and structural methods. In particular, the structure of a complex between UBA6 and ubiquitin or FAT10 would provide key insights for further biochemical studies, ultimately allowing the targeted inhibition of the FAT10ylation machinery.