Clinical data has supported the early use of plasma in high ratios of plasma to red cells to patients in hemorrhagic shock. The benefit from plasma seems to extend beyond its hemostatic effects to include protection to the post-shock dysfunctional endothelium. Resuscitation of the endothelium by plasma and one of its major constituents, fibrinogen, involves cell surface stabilization of syndecan-1, a transmembrane proteoglycan and the protein backbone of the endothelial glycocalyx. The pathogenic role of miRNA-19b to the endothelium is explored along with the PAK-1-mediated intracellular pathway that may link syndecan-1 to cytoskeletal protection. Additionally, clinical studies using fibrinogen and cyroprecipitate to aid in hemostasis of the bleeding patient are reviewed and new data to suggest a role for plasma and its byproducts to treat the dysfunctional endothelium associated with nonbleeding diseases is presented.
These data suggest that in-vitro, fibrinogen associated with cell surface syndecan-1 and enhanced endothelial barrier integrity.
Syndecan-1 is considered a biomarker of injury to the endothelial glycocalyx following hemorrhagic shock, with shedding of sdc1 deleterious. Resuscitation with fresh frozen plasma (FFP) has been correlated with restitution of pulmonary sdc1 and reduction of lung injury, but the precise contribution of sdc1 to FFPs protection in the lung remains unclear. Human lung endothelial cells were used to assess the time and dose dependent effect of FFP on sdc1 expression and the effect of sdc1 silencing on in vitro endothelial cell permeability and actin stress fiber formation. Wild-type (WT) and syndecan-1−/− mice were subjected to hemorrhagic shock followed by resuscitation with lactated ringers (LR) or FFP and compared to shock alone and shams. Lungs were harvested after 3 hours for analysis of permeability, histology, and inflammation and for measurement of syndecan- 2 and 4 expression. In vitro, FFP enhanced pulmonary endothelial sdc1 expression in time- and dose-dependent manners and loss of sdc1 in pulmonary endothelial cells worsened permeability and stress fiber formation by FFP. Loss of sdc1 in vivo lead to equivalency between LR and FFP in restoring pulmonary injury, inflammation, and permeability after shock. Lastly, sdc1 −/− mice demonstrated a significant increase in pulmonary syndecan 4 expression after hemorrhagic shock and FFP based resuscitation. Taken together, our findings support a key role for sdc1 in modulating pulmonary protection by FFP after hemorrhagic shock. Our results also suggest that other members of the syndecan family may at least be contributing to FFP’s effects on the endothelium, an area that warrants further investigation.
Hemorrhagic shock results in systemic injury to the endothelium contributing to post-shock morbidity and mortality. The mechanism involves syndecan-1, the backbone of the endothelial glycocalyx. We have shown in a rodent model that lung syndecan-1 mRNA is reduced following hemorrhage, whereas the molecular mechanism underlying the mRNA reduction is not clear. In this study, we present evidence that miR-19b targets syndecan-1 mRNA to downregulate its expression. Our results demonstrate that miR-19b was increased in hemorrhagic shock patients and in-vitro specifically bound to syndecan-1 mRNA and caused its degradation. Further, hypoxia/reoxygenation (H/R), our in vitro hemorrhage model, increased miR-19b expression in human lung microvascular endothelial cells, leading to a decrease in syndecan-1 mRNA and protein. H/R insult and miR-19b mimic overexpression comparably exaggerated permeability and enhanced endothelial barrier breakdown. The detrimental role of miR-19b in inducing endothelial dysfunction was confirmed in vivo. Lungs from mice undergoing hemorrhagic shock exhibited a significant increase in miR-19b and a concomitant decrease in syndecan-1 mRNA. Pretreatment with miR-19b oligo inhibitor significantly decreased lung injury, inflammation, and permeability and improved hemodynamics. These findings suggest that inhibition of miR-19b may be a putative therapeutic avenue for mitigating post shock pulmonary endothelial dysfunction in hemorrhage shock.
We recently demonstrated that fibrinogen stabilizes syndecan-1 on the endothelial cell (EC) surface and contributes to EC barrier protection, though the intracellular signaling pathway remains unclear. P21 (Rac1) activated kinase 1 (PAK1) is a protein kinase involved in intracellular signaling leading to actin cytoskeleton rearrangement and plays an important role in maintaining endothelial barrier integrity. We therefore hypothesized that fibrinogen binding to syndecan-1 activated the PAK1 pathway. Methods: Primary human lung microvascular endothelial cells were incubated in 10% lactated Ringers (LR) solution or 10% fibrinogen saline solution (5 mg/mL). Protein phosphorylation was determined by Western blot analysis and endothelial permeability measured by fluorescein isothiocyanate (FITC)-dextran. Cells were silenced by siRNA transfection. Protein concentration was measured in the lung lavages of mice. Results: Fibrinogen treatment resulted in increased syndecan-1, PAK1 activation (phosphorylation), cofilin activation (dephosphorylation), as well as decreased stress fibers and permeability when compared with LR treatment. Cofilin is an actin-binding protein that depolymerizes F-actin to decrease stress fiber formation. Notably, fibrinogen did not influence myosin light chain activation (phosphorylation), a mediator of EC tension. Silencing of PAK1 prevented fibrinogen-induced dephosphorylation of cofilin and barrier integrity. Moreover, to confirm the in vitro findings, mice underwent hemorrhagic shock and were resuscitated with either LR or fibrinogen. Hemorrhage shock decreased lung p-PAK1 levels and caused significant lung vascular leakage. However, fibrinogen administration increased p-PAK1 expression to near sham levels and remarkably prevented the lung leakage. Conclusion: We have identified a novel pathway by which fibrinogen activates PAK1 signaling to stimulate/ dephosphorylate cofilin, leading to disassembly of stress fibers and reduction of endothelial permeability.
Metabolomics approaches could achieve accurate and comprehensive analysis in human space exploration.
Acute traumatic coagulopathy is a complex phenomenon following injury and a main contributor to hemorrhage. It remains a leading cause of preventable death in trauma patients. This phenomenon is initiated by systemic injury to the vascular endothelium that is exacerbated by hypoperfusion, acidosis, and hypothermia and leads to systemic activation of the coagulation cascades and resultant coagulopathy. Many previous studies have focused on endotheliopathy with targeted markers such as syndecan-1, soluble thrombomodulin, and plasma adrenaline as potential culprits for initiation and propagation of this state. However, in more recent studies, hyperadhesive von Willebrand factor (VWF), which is released following endothelial injury, and its cleaving metalloprotease ADAMTS13 have emerged as significant targets of the downstream effect of endothelial breakdown and coagulation dysregulation. Elucidation of the mechanism by which the dysregulated VWF-ADAMTS13 axis leads to endothelial dysfunction and coagulopathy after trauma can help identify new targets for therapy and sites for intervention. Much of what is known mechanistically regarding VWF stems from work done in traumatic brain injury. Following localized brain injury, brain-derived extracellular vesicles are released into circulation where they induce a hypercoagulable state that rapidly turns into consumptive coagulopathy. VWF released from injured endothelial cells binds to these extracellular vesicles to enhance their activity in promoting coagulopathy and increasing endothelial permeability. However, there are numerous gaps in our knowledge of VWF following injury, providing a platform for further investigation.
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