Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0036690 (sepsis)
 59,461 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Indications for fresh frozen plasma (FFP), once used routinely in the support of critically ill infants and children, have become more specific as evolving evidence has confirmed or disproved the efficacy of plasma in various circumstances. FFP is currently indicated to treat the coagulopathies of massive hemorrhage, liver failure and disseminated intravascular coagulation and sepsis. Whole blood reconstituted from FFP and packed red cells is the product of choice for exchange transfusion, as well as for circuit priming. In the US, FFP remains the only approved source of factors V, XI, protein C, protein S and plasminogen. Cryoprecipitate is used chiefly as a source of fibrinogen, factor VIII and factor XIII in consumptive coagulopathy; recombinant or viral inactivated plasma derivatives are preferred for congenital deficiencies of factor VIII and von Willebrand factor. Recombinant and highly purified, viral inactivated, plasma-derived proteins are preferred over FFP for congenital and acquired deficiencies. This chapter reviews evidence to support the use of plasma and plasma derivatives for pediatric patients.
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PMID:Pediatric hemostasis and use of plasma components. 1637 47

After a coagulation stimulus, the blood clotting cascade amplifies largely unchecked until very high levels of thrombin are generated. Natural anticoagulant mechanisms (for example, the protein C anticoagulant pathway) are amplified to prevent excessive thrombin generation. Thrombin binds to thrombomodulin (TM) and this complex and then activates protein C approximately 1000 times faster than free thrombin. Protein C activation is enhanced approximately 20-fold further by the endothelial cell protein C receptor (EPCR). Activated protein C proteolytically inactivates factor Va (FVa) and FVIIIa, thereby blocking the amplification of the coagulation system, a process that is accelerated by protein S. TM not only accelerates protein C activation, but also decreases endothelial cell activation by blocking high-mobility group protein-B1 inflammatory functions and suppressing both nuclear factor-kappa B nuclear translocation and the mitogen-activated protein kinase pathways. The thrombin-TM complex also activates thrombin-activatable fibrinolysis inhibitor, a procarboxypeptidase that renders fibrin resistant to clot lysis and neutralizes vasoactive molecules such as complement C5a. Activated protein C has a variety of antiinflammatory activities. It suppresses inflammatory cytokine elevation in animal models of severe sepsis, inhibits leukocyte adhesion, decreases leukocyte chemotaxis, reduces endothelial cell apoptosis, helps maintain endothelial cell barrier function through activation of the sphingosine-1 phosphate receptor, and minimizes the decrease in blood pressure associated with severe sepsis. Most of these functions are dependent on binding to EPCR. Overall this pathway is critical to both regulation of the blood coagulation process, and control of the innate inflammatory response and some of its associated downstream pathologies.
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PMID:Inflammation and the activated protein C anticoagulant pathway. 1667 66

The systemic inflammation associated to the simultaneous activation of blood coagulation and the alterated blood fibrinolysis, leads to microvascular endothelial injury, acute organ dysfunction and possibly death. Activated Protein C, a natural, multifunctional protein, has demonstrated antithrombotic, anti-inflammatory, and profibrinolitic properties and may be an important modulator of the vicious cycle whereby inflammation initiates coagulation and coagulation amplifies inflammation. Protein C couples with its receptor, EPCR (endothelial-cell protein-C receptor), and the ligand-receptor complex then interact with thrombin-thrombomodulin on endothelial surface to produce activated protein C (APC). Once activated, protein C then interact with its cofactor, protein S, to catalyze the inactivation of factors Va and VIIILa, two important accelerators of the clotting cascade, reducing thrombin generation and microvascular thrombosis. In addiction to its anticoagulant activity APC promotes profibrinolytic activity through the inhibition of plasminogen activator inhibitor-1, which is upregulated during inflammation. Inhibition of thrombin generation by APC decreases inflammation by inhibiting platelet activation, neutrophil recruitment, and mast-cell degranulation. APC also shows direct antiinflammatory properties, including blocking of cytokines production by monocytes and blocking cell adhesion. Moreover, APC has antiapoptotic properties that may contribute to its efficacy. In conclusion, APC, besides its physiologic role in the coagulation cascade, plays a key role in the pathophysiology of systemic inflammation justifying its potential therapeutic role in sepsis and systemic inflammatory responses.
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PMID:[The numerous properties of the anticoagulant protein C]. 1756 22

Enoxaparin, a low-molecular-weight heparin used to treat and prevent deep venous thrombosis, has been evaluated in several clinical trials. Thrombosis induced by enoxaparin with no evidence of heparin-induced thrombocytopenia (HIT) is seldom described. We report a rare case in which an 89-year-old African-American female developed large, multiple, painful lesions induced by enoxaparin administration. Laboratory investigations for HIT, disseminated intravascular coagulation, protein C, protein S, factor V, factor VIII, antithrombin III, and homocysteine deficiency were negative. Unfortunately, despite aggressive management for 2 weeks, the patient developed severe sepsis and died.
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PMID:Enoxaparin-induced skin necrosis: a fatal outcome. 1766 18

Identification of good surrogate end-points can greatly facilitate the design of clinical trials. Using data from PROWESS and ENHANCE, Shorr and colleagues explore the potential value of several plasma biomarkers for treatment trials of activated protein C for severe sepsis. Based on the framework proposed by Vasan, they tested the utility of several factors (protein C, interleukin-6, antithrombin III, prothrombin time, protein S, and d-dimers) as type 0, 1 and 2 biomarkers. Only protein C had acceptable performance characteristics as a type 2 biomarker, or surrogate end-point. The utility of protein C as a surrogate end-point for studies of severe sepsis must be validated in future prospective studies.
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PMID:Protein C as a surrogate end-point for clinical trials of sepsis. 1839 62

Inflammation shifts the hemostatic mechanisms in favor of thrombosis. Multiple mechanisms are at play including up regulation of tissue factor leading to the initiation of clotting, amplification of the clotting process by augmenting exposure of cellular coagulant phospholipids, inhibition of fibrinolysis by elevating plasminogen activator inhibitor 1 (PAI-1) and decreases in natural anticoagulant pathways, particularly targeted toward down regulation of the protein C anticoagulant pathway through multiple mechanisms. The decreased function of the natural anticoagulant pathways may be particularly problematic because these appear to play a role in dampening inflammatory responses. The protein C anticoagulant pathway provides a useful model for the impact of inflammation on coagulation. This pathway plays a major role in preventing microvascular thrombosis. The pathway is initiated when thrombin binds to thrombomodulin (TM) on the surface of the endothelium. An endothelial cell protein C receptor (EPCR) augments protein C activation by the thrombin-TM complex more than 10-fold in vivo. EPCR is shed from the endothelium by inflammatory mediators and thrombin. EPCR binds to activated neutrophils in a process that involves proteinase 3 and Mac-1 and appears to inhibit leukocyte extravisation. EPCR can undergo translocation from the plasma membrane to the nucleus where it redirects gene expression. During translocation it can carry activated protein C (APC) to the nucleus, possibly accounting for the ability of APC to modulate inflammatory mediator responses in the endothelium. TNF alpha and other inflammatory mediators can down-regulate EPCR and TM and IL-6 can depress levels of protein S in experimental animals. Inhibition of protein C pathway function increases cytokine elaboration, endothelial cell injury and leukocyte extravisation in response to endotoxin, processes that are decreased by infusion of APC. In vitro, APC inhibits TNF alpha elaboration from monocytes and to block leukocyte adhesion to selectins. Since thrombin can elicit many inflammatory responses in microvascular endothelium, loss of control of microvascular thrombin generation due to impaired protein C pathway function probably contributes to microvascular dysfunction in sepsis.
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PMID:Crosstalk between inflammation and thrombosis. 1506 84

This is a review of less well-known aspects of thrombophilia and hypercoagulability as they relate to thrombosis. Thrombosis is an abnormal fibrin clot that develops in circulating blood with clinical symptoms of one or more arterial and/or venous obstructions exclusively identified by imaging techniques. The terms thrombophilia and hypercoagulability are often used indiscriminately when they are in fact separate entities. Thrombophilia is an inherited or acquired clinical phenotype manifesting in selected individuals as a greater risk to develop recurrent thrombosis at a younger age than the general population, with considerable differences in the magnitude of risks among individuals in the same family with the same thrombophilic gene defect. Hypercoagulability is a laboratory phenotype whereby in vivo activation of clotting, fibrinolysis, endothelial cells and platelets is identified in vitro by specialized clotting techniques and by specific antibodies directed at biomarkers of clotting activation and damaged vasculature. Hypercoagulability may be provoked by drugs to treat bleeding in hemophilia, by sepsis, inflammation, surgery, blood stasis, atherosclerosis, and it manifests selectively in inherited and acquired thrombophilia. A chronology of the discovery of acquired and inherited thrombophilia puts in perspective the data analyzed in two representative large family studies that address whether venous and arterial thrombosis are a necessary outcome in thrombophilia, and the question, whether patients with inherited antithrombin, protein C and protein S deficiencies need to be treated after a first episode of thrombosis. The liberal use of case vignettes emphasizes a close relationship and the distinction between thrombosis, thrombophilia and hypercoagulability.
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PMID:Thrombophilia and hypercoagulability. 1979 18

Formation of nitric oxide and its derivative reactive nitrogen species during endotoxemia has been implicated in the pathogenesis of the associated cardiovascular dysfunction. This stress can promote nitrosative post-translational modifications of proteins that may alter their activity and contribute to dysregulation. We utilized the ascorbate-dependent biotin-switch method to assay protein S-nitrosylation and immunoblotted for tyrosine nitration to monitor changes in nitrosative protein oxidation during endotoxemia. Hearts from lipopolysaccharide (LPS)-treated rats showed no apparent variation in global protein S-nitrosylation, but this may be due to the poor sensitivity of the biotin-switch method. To sensitize our monitoring of protein S-nitrosylation we exposed isolated hearts to the efficient trans-nitrosylating agent nitrosocysteine (which generated a robust biotin-switch signal) and then identified a number of target proteins using mass spectrometry. We were then able to probe for these target proteins in affinity-capture preparations of S-nitrosylated proteins prepared from vehicle- or LPS-treated animals. Unexpectedly this showed a time-dependent loss in S-nitrosylation during sepsis, which we hypothesized, may be due to concomitant superoxide formation that may lower nitric oxide but simultaneously generate the tyrosine-nitrating agent peroxynitrite. Indeed, this was confirmed by immunoblotting for global tyrosine nitration, which increased time-dependently and temporally correlated with a decrease in mean arterial pressure. We assessed if tyrosine nitration was causative in lowering blood pressure using the putative peroxynitrite scavenger FeTPPS. However, FeTPPS was ineffective in reducing global protein nitration and actually exacerbated LPS-induced hypotension.
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PMID:Nitrosative protein oxidation is modulated during early endotoxemia. 2113 Jan 78

Purpura fulminans (PF) is a haematological emergency in which there is skin necrosis and disseminated intravascular coagulation. This may progress rapidly to multi-organ failure caused by thrombotic occlusion of small and medium-sized blood vessels. PF may complicate severe sepsis or may occur as an autoimmune response to otherwise benign childhood infections. PF may also be the presenting symptom of severe heritable deficiency of the natural anticoagulants protein C or protein S. Early recognition and treatment of PF is essential to reduce mortality and to prevent major long-term health sequelae. However, management strategies require accurate identification of the underlying cause. This review focuses on the clinical features, differential diagnosis and laboratory features of the range of PF disorders and includes expert consensus opinion about immediate and on-going management.
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PMID:Purpura fulminans: recognition, diagnosis and management. 2123 82

A new family of adenylyltransferases, defined by the presence of a Fic domain, was recently discovered to catalyze the addition of adenosine monophosphate (AMP) to Rho GTPases (Yarbrough, M. L., Li, Y., Kinch, L. N., Grishin, N. V., Ball, H. L., and Orth, K. (2009) Science 323, 269-272; Worby, C. A., Mattoo, S., Kruger, R. P., Corbeil, L. B., Koller, A., Mendez, J. C., Zekarias, B., Lazar, C., and Dixon, J. E. (2009) Mol. Cell 34, 93-103). This adenylylation event inactivates Rho GTPases by preventing them from binding to their downstream effectors. We reported that the Fic domain(s) of the immunoglobulin-binding protein A (IbpA) from the pathogenic bacterium Histophilus somni adenylylates mammalian Rho GTPases, RhoA, Rac1, and Cdc42, thereby inducing host cytoskeletal collapse, which allows H. somni to breach alveolar barriers and cause septicemia. The IbpA-mediated adenylylation occurs on a functionally critical tyrosine in the switch 1 region of these GTPases. Here, we conduct a detailed characterization of the IbpA Fic2 domain and compare its activity with other known Fic adenylyltransferases, VopS (Vibrio outer protein S) from the bacterial pathogen Vibrio parahaemolyticus and the human protein HYPE (huntingtin yeast interacting protein E; also called FicD). We also included the Fic domains of the secreted protein, PfhB2, from the opportunistic pathogen Pasteurella multocida, in our analysis. PfhB2 shares a common domain architecture with IbpA and contains two Fic domains. We demonstrate that the PfhB2 Fic domains also possess adenylyltransferase activity that targets the switch 1 tyrosine of Rho GTPases. Comparative kinetic and phylogenetic analyses of IbpA-Fic2 with the Fic domains of PfhB2, VopS, and HYPE reveal important aspects of their specificities for Rho GTPases and nucleotide usage and offer mechanistic insights for determining nucleotide and substrate specificities for these enzymes. Finally, we compare the evolutionary lineages of Fic proteins with those of other known adenylyltransferases.
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PMID:Comparative analysis of Histophilus somni immunoglobulin-binding protein A (IbpA) with other fic domain-containing enzymes reveals differences in substrate and nucleotide specificities. 2179 13


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