Institut für Experimentelle Biomedizin
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In hemostasis and thrombosis, the complex process of thrombus formation involves different molecular pathways of platelet and coagulation activation. These pathways are considered as operating together at the same time, but this has not been investigated. The objective of our study was to elucidate the time-dependency of key pathways of thrombus and clot formation, initiated by collagen and tissue factor surfaces, where coagulation is triggered via the extrinsic route. Therefore, we adapted a microfluidics whole-blood assay with the Maastricht flow chamber to acutely block molecular pathways by pharmacological intervention at desired time points. Application of the technique revealed crucial roles of glycoprotein VI (GPVI)-induced platelet signaling via Syk kinase as well as factor VIIa-induced thrombin generation, which were confined to the first minutes of thrombus buildup. A novel anti-GPVI Fab EMF-1 was used for this purpose. In addition, platelet activation with the protease-activating receptors 1/4 (PAR1/4) and integrin αIIbβ3 appeared to be prolongedly active and extended to later stages of thrombus and clot formation. This work thereby revealed a more persistent contribution of thrombin receptor-induced platelet activation than of collagen receptor-induced platelet activation to the thrombotic process.
Ischemic stroke is among the leading causes of disability and death worldwide. In acute ischemic stroke, successful recanalization of occluded vessels is the primary therapeutic aim, but even if it is achieved, not all patients benefit. Although blockade of platelet aggregation did not prevent infarct progression, cerebral thrombosis as cause of secondary infarct growth has remained a matter of debate. As cerebral thrombi are frequently observed after experimental stroke, a thrombus-induced impairment of the brain microcirculation is considered to contribute to tissue damage. Here, we combine the model of transient middle cerebral artery occlusion (tMCAO) with light sheet fluorescence microscopy and immunohistochemistry of brain slices to investigate the kinetics of thrombus formation and infarct progression. Our data reveal that tissue damage already peaks after 8 h of reperfusion following 60 min MCAO, while cerebral thrombi are only observed at later time points. Thus, cerebral thrombosis is not causative for secondary infarct growth during ischemic stroke.
Background
Effective inhibition of thrombosis without generating bleeding risks is a major challenge in medicine. Accumulating evidence suggests that this can be achieved by inhibition of coagulation factor XII (FXII), as either its knock-out or inhibition in animal models efficiently reduced thrombosis without affecting normal hemostasis. Based on these findings, highly specific inhibitors for human FXII(a) are under development. However, currently, in vivo studies on their efficacy and safety are impeded by the lack of an optimized animal model expressing the specific target, that is, human FXII.
Objective
The primary objective of this study is to develop and functionally characterize a humanized FXII mouse model.
Methods
A humanized FXII mouse model was generated by replacing the murine with the human F12 gene (genetic knock-in) and tested it in in vitro coagulation assays and in in vivo thrombosis models.
Results
These hF12\(^{KI}\) mice were indistinguishable from wild-type mice in all tested assays of coagulation and platelet function in vitro and in vivo, except for reduced expression levels of hFXII compared to human plasma. Targeting FXII by the anti-human FXIIa antibody 3F7 increased activated partial thromboplastin time dose-dependently and protected hF12\(^{KI}\) mice in an arterial thrombosis model without affecting bleeding times.
Conclusion
These data establish the newly generated hF12\(^{KI}\) mouse as a powerful and unique model system for in vivo studies on anti-FXII(a) biologics, supporting the development of efficient and safe human FXII(a) inhibitors.
Background
In acute ischemic stroke, cessation of blood flow causes immediate tissue necrosis within the center of the ischemic brain region accompanied by functional failure in the surrounding brain tissue designated the penumbra. The penumbra can be salvaged by timely thrombolysis/thrombectomy, the only available acute stroke treatment to date, but is progressively destroyed by the expansion of infarction. The underlying mechanisms of progressive infarction are not fully understood.
Methods
To address mechanisms, mice underwent filament occlusion of the middle cerebral artery (MCAO) for up to 4 h. Infarct development was compared between mice treated with antigen-binding fragments (Fab) against the platelet surface molecules GPIb (p0p/B Fab) or rat immunoglobulin G (IgG) Fab as control treatment. Moreover, Rag1\(^{−/−}\) mice lacking T-cells underwent the same procedures. Infarct volumes as well as the local inflammatory response were determined during vessel occlusion.
Results
We show that blocking of the platelet adhesion receptor, glycoprotein (GP) Ibα in mice, delays cerebral infarct progression already during occlusion and thus before recanalization/reperfusion. This therapeutic effect was accompanied by decreased T-cell infiltration, particularly at the infarct border zone, which during occlusion is supplied by collateral blood flow. Accordingly, mice lacking T-cells were likewise protected from infarct progression under occlusion.
Conclusions
Progressive brain infarction can be delayed by blocking detrimental lymphocyte/platelet responses already during occlusion paving the way for ultra-early treatment strategies in hyper-acute stroke before recanalization.
Cell death is an essential aspect of life that plays an important role for successful development and tissue remodeling as well as for diseases. There are several different types of cell death that differ from each other in morphological, functional and biochemical ways. Regulated cell death that occurs in physiological processes is generally equated with programmed cell death (PCD), whereby apoptosis is the most studied form of PCD. Ferroptosis is a form of regulated cell death and unique in its requirements for iron and lipid peroxidation. It is linked to numerous biological processes, such as amino acid metabolism, phospholipid metabolism and sterol synthesis. Cholesterol biosynthesis is a complex pathway with a large number of enzymes and substrates that are potential target points for cellular dysfunctions. Motivated by the results from a CRISPR-based genetic screening in this thesis, we focused on 7-dehydrocholesterol reductase (DHCR7), the enzyme responsible for conversion of 7-dehydrocholesterol (7-DHC) to cholesterol. In this work we focused on the ferroptosis sensitive cell line HT1080 and generated a series of models to address the importance of DHCR7 in ferroptosis. Using CRISPR/Cas9, HT1080 DHCR7_KO and DHCR7/SC5D_KO cell lines were generated and used to validate their sensitivity against ferroptosis inducers and sterol consumption. We could show that 7-DHC is a strong antiferroptotic agent that could prevent cell death in genetic models as well as when supplemented directly to cells. Importantly, all the results obtained were subsequently confirmed in isogenic reconstituted pairs from the HT1080 DHCR7/SC5D_KO. Moreover, we demonstrate that this protective effect is not due to an inherent and unspecific resistance as the sensitivity to non-ferroptotic stimuli was equally effective in killing the HT1080 DHCR7_KO and DHCR7/SC5D_KO cell lines. We could also show that selenium present in the media has a strong impact on the activity of 7-DHC and this is because in its absence the effective concentration is rapidly decreased. Surprisingly we also demonstrate that removing sterol from cell culture triggers ferroptosis in cells unable to synthesize 7-DHC, suggestive that this could be used as a novel mechanism to trigger ferroptosis. Ultimately, in the present work we could show that unlike previously reported, 7-DHC is not only a toxic intermediate of the cholesterol biosynthesis pathway but under specific circumstances it has a strong pro-survival effect.
This work investigates the death and degradation of the second polar body of the nematode C. elegans in order to improve our understanding how pluripotent undifferentiated cells deal with dying cells. With the use of fluorescence microscopy this work demonstrates that both polar bodies loose membrane integrity early. The second polar body has contact to embryonic cells and gets internalized, dependent on the Rac1-ortholog CED-10.
The polar body gets degraded via LC3-associated phagocytosis. While lysosome recruitment depends on RAB-7, LC3 does not improve lysosome recruitment but still accelerates polar body degradation.
This work establishes the second polar body as a genetic model to study cell death and LC3-associated phagocytosis and has revealed further aspects of phagosome maturation and degradation.