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Platelets are the second most abundant blood cells and their main function is maintenance of vascular integrity. In addition, platelets are increasingly recognized as cells with immune functions, as they participate in the recruitment of immune cells and modulate the progression and severity of an immune response. So-called lipid mediators, which are – besides other cells – released by activated platelets, influence the immune response. LTB4 is one of these potent lipid mediators and is able to activate neutrophils and induce their infiltration into injured tissue.
In order to investigate the involvement of platelets in inflammatory processes, a murine model of hepatic ischemia reperfusion injury as well as confocal intravital microscopy of the liver were established. Both methods were used to analyze the influence of platelets on the inflammation that follows sterile liver inflammation. We found platelet function to be unaltered after three hours of reperfusion and platelet aggregation to be irrelevant for the outcome of hepatic ischemia reperfusion injury. However, a strong impact of the GPIb-vWF axis could be observed, as antibody mediated blockade of GPIb as well as vWF-deficiency significantly reduced liver damage markers and decreased neutrophil infiltration. GPIb-IL-4R mice were used to exclude the possibility that the protective effects of the anti-GPIbα antibody treatment (p0p/B) results from something else than blocking GPIbα. Furthermore, the slope of neutrophil infiltration was decreased in p0p/B-treated mice, leading to overall decreased neutrophil numbers in the liver after three hours of reperfusion. Blockade of the integrin αIIbβ3, however, showed no reduction in neutrophil infiltration into the post-ischemic liver, in line with unaltered liver damage.
To study the role of leukotriene B4, conditional and constitutive knockout mice for the LTA4 hydrolase, which catalyzes the last step in LTB4 synthesis, were generated. Lta4h deficiency did not affect general platelet functionality in hemostasis and thrombosis. Interestingly,
Lta4h-/- mice were not protected from cellular damage following hepatic ischemia, despite lower neutrophil numbers in the post-ischemic liver.
Intravital microscopy of the pancreas was established and revealed increased CD4+ T cell numbers in GPVI-deficient animals compared to WT controls in line with the pre-diabetic phenotype of Gp6-/- mice that was revealed in Grzegorz Sumara’s group. Furthermore, platelet ‘behavior’ in pancreatic islets was observed following glucose injection. We found a high number of platelets adherent to islet sinusoids under basal conditions and no rolling/decelerating of platelets following glucose injection. This was accompanied by temporary sinusoidal constriction and stop of the blood flow. This phenomenon was not observed in control settings (injection of PBS, insulin or L-glucose).
In a side project, which was carried out jointly with Tobias Heib, a side by side comparison of the classical syringe-based flushing and the centrifugation-based spinning method to isolate murine bone marrow was conducted. Flow cytometry revealed no differences in the distribution of hematopoietic stem cells and immune cells and functional analysis with primary and cultured megakaryocytes (MKs) showed comparable results in all conducted assays. Thus, our data demonstrated that the faster and more efficient spinning method can be used for the isolation of bone marrow cells.
Rac1 is a small Rho GTPase that is activated in platelets upon stimulation with various ligands, including collagen and thrombin, which are ligands for the glycoprotein VI (GPVI) receptor and the protease-activated receptors, respectively. Rac1-deficient murine platelets have impaired lamellipodia formation, aggregation, and reduced PLCγ2 activation, but not phosphorylation. The objective of our study is to investigate the role of Rac1 in GPVI-dependent human platelet activation and downstream signalling. Therefore, we used human platelets stimulated using GPVI agonists (collagen and collagen-related peptide) in the presence of the Rac1-specific inhibitor EHT1864 and analysed platelet activation, aggregation, spreading, protein phosphorylation, and GPVI clustering and shedding. We observed that in human platelets, the inhibition of Rac1 by EHT1864 had no significant effect on GPVI clustering on collagen fibres but decreased the ability of platelets to spread or aggregate in response to GPVI agonists. Additionally, in contrast to what was observed in murine Rac1-deficient platelets, EHT1864 enhanced GPVI shedding in platelets and reduced the phosphorylation levels of PLCγ2 following GPVI activation. In conclusion, Rac1 activity is required for both human and murine platelet activation in response to GPVI-ligands, but Rac1’s mode of action differs between the two species.
Cyclophilin a is not acetylated at lysine-82 and lysine-125 in resting and stimulated platelets
(2022)
Cyclophilin A (CyPA) is widely expressed by all prokaryotic and eukaryotic cells. Upon activation, CyPA can be released into the extracellular space to engage in a variety of functions, such as interaction with the CD147 receptor, that contribute to the pathogenesis of cardiovascular diseases. CyPA was recently found to undergo acetylation at K82 and K125, two lysine residues conserved in most species, and these modifications are required for secretion of CyPA in response to cell activation in vascular smooth muscle cells. Herein we addressed whether acetylation at these sites is also required for the release of CyPA from platelets based on the potential for local delivery of CyPA that may exacerbate cardiovascular disease events. Western blot analyses confirmed the presence of CyPA in human and mouse platelets. Thrombin stimulation resulted in CyPA release from platelets; however, no acetylation was observed—neither in cell lysates nor in supernatants of both untreated and activated platelets, nor after immunoprecipitation of CyPA from platelets. Shotgun proteomics detected two CyPA peptide precursors in the recombinant protein, acetylated at K28, but again, no acetylation was found in CyPA derived from resting or stimulated platelets. Our findings suggest that acetylation of CyPA is not a major protein modification in platelets and that CyPA acetylation is not required for its secretion from platelets.