PathWhiz ID | Pathway | Meta Data |
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PW146012View Pathway |
drug action
Uridine triacetate Drug Metabolism Action PathwayHomo sapiens
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Creator: Ray Kruger Created On: October 07, 2023 at 17:11 Last Updated: October 07, 2023 at 17:11 |
PW125956View Pathway |
drug action
UrokinaseHomo sapiens
Urokinase is a serine protease that functions as a recombinant tissue plasminogen activator. It is administered intravenously and used to treat conditions caused by arterial blood clots such as acute ischemic stroke, acute myocardial infarction, acute massive pulmonary embolism and blocked central venous access devices. It targets plasminogen in blood vessels where these clots occur. The clotting process consists of two pathways, intrinsic and extrinsic, which converge to create stable fibrin which traps platelets and forms a hemostatic plug. The intrinsic pathway is activated by trauma inside the vasculature system, when there is exposed endothelial collagen. Endothelial collagen only becomes exposed when there is damage. The pathway starts with plasma kallikrein activating factor XII. The activated factor XIIa activates factor XI. Factor IX is then activated by factor XIa. Thrombin activates factor VIII and a Calicum-phospholipid-XIIa-VIIIa complex forms. This complex then activates factor X, the merging point of the two pathways. The extrinsic pathway is activated when external trauma causes blood to escape the vasculature system. Activation occurs through tissue factor released by endothelial cells after external damage. The tissue factor is a cellular receptor for factor VII. In the presence of calcium, the active site transitions and a TF-VIIa complex is formed. This complex aids in activation of factors IX and X. Factor V is activated by thrombin in the presence of calcium, then the activated factor Xa, in the presence of phospholipid, calcium and factor Va can convert prothrombin to thrombin. The extrinsic pathway occurs first, producing a small amount of thrombin, which then acts as a positive feedback on several components to increase the thrombin production. Thrombin converts fibrinogen to a loose, unstable fibrin and also activates factor XIII. Factors XIIIa strengthens the fibrin-fibrin and forms a stable, mesh fibrin which is essential for clot formation. The blood clot can be broken down by the enzyme plasmin. Plasmin is formed from plasminogen by tissue plasminogen activator. Urokinase acts as a tissue plasminogen activator. It binds to clots with fibrin where it causes hydrolysis of the arginine-valine bond in plasminogen, aiding its conversion to plasmin. The plasmin degrades the stable fibrin and causes lysis of the clot. The activity of Urokinase depends on the presence of fibrin. Only small amounts of plasmin is formed from plasminogen when there is no fibrin. Urokinase in the presence of fibrin obtains a higher affinity for plasminogen, thus leading to its increased activity. Urokinase undergoes metabolism by proteases and is excreted in bile and urine.
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Creator: Selena Created On: May 04, 2021 at 21:38 Last Updated: May 04, 2021 at 21:38 |
PW000306View Pathway |
drug action
Urokinase Action PathwayHomo sapiens
Urokinase is an enzyme that is part of the thrombolytics drug class, used to dissolve or break down blood clots. Urokinase activates plasminogen. Then zooming in even further to the endoplasmic reticulum within the liver, vitamin K1 2,3-epoxide uses vitamin K epoxide reductase complex subunit 1 to become reduced vitamin K (phylloquinone), and then back to vitamin K1 2,3-epoxide continually through vitamin K-dependent gamma-carboxylase. This enzyme also catalyzes precursors of prothrombin and coagulation factors VII, IX and X to prothrombin, and coagulation factors VII, IX and X. From there, these precursors and factors leave the liver cell and enter into the blood capillary bed. Once there, prothrombin is catalyzed into the protein complex prothrombinase complex which is made up of coagulation factor Xa/coagulation factor Va (platelet factor 3). These factors are joined by coagulation factor V. Through the two factors coagulation factor Xa and coagulation factor Va, thrombin is produced, which then uses fibrinogen alpha, beta, and gamma chains to create fibrin (loose). This is then turned into coagulation factor XIIIa, which is activated through coagulation factor XIII A and B chains. From here, fibrin (mesh) is produced which interacts with endothelial cells to cause coagulation. Plasmin is then created from fibrin (mesh), then joined by tissue-type plasminogen activator (urokinase) through plasminogen, and creates fibrin degradation products. These are enzymes that stay in your blood after your body has dissolved a blood clot. Coming back to the factors transported from the liver, coagulation factor X is catalyzed into a group of enzymes called the tenase complex: coagulation factor IX and coagulation factor VIIIa (platelet factor 3). This protein complex is also contributed to by coagulation factor VIII, which through prothrombin is catalyzed into coagulation factor VIIIa. From there, this protein complex is catalyzed into prothrombinase complex, the group of proteins mentioned above, contributing to the above process ending in fibrin degradation products. Another enzyme transported from the liver is coagulation factor IX which becomes coagulation factor IXa, part of the tense complex, through coagulation factor XIa. Coagulation factor XIa is produced through coagulation factor XIIa which converts coagulation XI to become coagulation factor XIa. Coagulation factor XIIa is introduced through chain of activation starting in the endothelial cell with collagen alpha-1 (I) chain, which paired with coagulation factor XII activates coagulation factor XIIa. It is also activated through plasma prekallikrein and coagulation factor XIIa which activate plasma kallikrein, which then pairs with coagulation factor XII simultaneously with the previous collagen chain pairing to activate coagulation XIIa. Lastly, the previously transported coagulation factor VII and tissue factor coming from a vascular injury work together to activate tissue factor: coagulation factor VIIa. This enzyme helps coagulation factor X catalyze into coagulation factor Xa, to contribute to the prothrombinase complex and complete the pathway.
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Creator: WishartLab Created On: August 22, 2013 at 10:45 Last Updated: August 22, 2013 at 10:45 |
PW145455View Pathway |
drug action
Ursodeoxycholic acid Drug Metabolism Action PathwayHomo sapiens
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Creator: Ray Kruger Created On: October 07, 2023 at 15:52 Last Updated: October 07, 2023 at 15:52 |
PW146495View Pathway |
drug action
Vaborbactam Drug Metabolism Action PathwayHomo sapiens
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Creator: Ray Kruger Created On: October 07, 2023 at 18:20 Last Updated: October 07, 2023 at 18:20 |
PW144694View Pathway |
drug action
Valaciclovir Drug Metabolism Action PathwayHomo sapiens
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Creator: Ray Kruger Created On: October 07, 2023 at 14:14 Last Updated: October 07, 2023 at 14:14 |
PW176160View Pathway |
Valaciclovir Predicted Metabolism Pathway newHomo sapiens
Metabolites of Valaciclovir are predicted with biotransformer.
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Creator: Omolola Created On: November 29, 2023 at 14:25 Last Updated: November 29, 2023 at 14:25 |
PW127460View Pathway |
drug action
Valacyclovir Action PathwayHomo sapiens
Valaciclovir (valacyclovir), also known as the brand name Valtrex, is an guanine nucleoside antiviral used to treat herpes exacerbations. Valaciclovir is the L-valine ester of aciclovir. Valacyclovir is rapidly and almost completely converted in man to aciclovir and valine, likely by the enzyme valacyclovir hydrolase. Aciclovir is transported from the liver into the blood via a drug transporter, then into the effected cells.
Acyclovir is a guanosine analog used to treat herpes simplex, varicella zoster, herpes zoster, herpes labialis, and acute herpetic keratitis. Acyclovir is becomes acyclovir monophosphate due to the action of viral thymidine kinase.5 Acyclovir monophosphate is converted to the diphosphate form by guanylate kinase.1 Acyclovir diphosphate is converted to acyclovir triphosphate by nucleoside diphosphate kinase, pyruvate kinase, creatine kinase, phosphoglycerate kinase, succinyl-CoA synthetase, phosphoenolpyruvate carboxykinase and adenylosuccinate synthetase. Acyclovir triphosphate inhibits the activity of DNA polymerase by competing with its substrate dGTP. Acyclovir triphosphate also gets incorporated into viral DNA, but since it lacks the 3'-OH group which is needed to form the 5′ to 3′ phosphodiester linkage essential for DNA chain elongation, this causes DNA chain termination, preventing the growth of viral DNA. Less Viral DNA is transported into the nucleus, therefore, less viral DNA is integrated into the host DNA. Less viral proteins produced, fewer viruses can form.
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Creator: Ray Kruger Created On: February 28, 2023 at 10:21 Last Updated: February 28, 2023 at 10:21 |
PW146467View Pathway |
drug action
Valbenazine Drug Metabolism Action PathwayHomo sapiens
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Creator: Ray Kruger Created On: October 07, 2023 at 18:16 Last Updated: October 07, 2023 at 18:16 |
PW000277View Pathway |
drug action
Valdecoxib Action PathwayHomo sapiens
Valdecoxib, a selective prostaglandin G/H synthase 2 (better known as cyclooxygenase-2 or COX-2) inhibitor, is classified as a nonsteroidal anti-inflammatory drug (NSAID). Valdecoxib was used for its anti-inflammatory, analgesic, and antipyretic effects in the management of osteoarthritis and for the treatment of dysmenorrhea or acute pain. Unlike celecoxib, valdecoxib lacks a sulfonamide chain and does not require CYP450 enzymes for metabolism. Both COX-1 and COX-2 catalyze the conversion of arachidonic acid to prostaglandin G2 (PGG2) and PGG2 to prostaglandin H2 (PGH2). PGH2 is the precursor of a number of prostaglandins, including prostaglandin E2 (PGE2), prostaglandin I2 (PGI2) and thomboxane A2 (TxA2). Valdecoxib selectively inhibits the cyclooxygenase-2 (COX-2) enzyme, a key enzyme in the production of PGE2. PGE2 is a potent mediator of pain, inflammation and fever. The first part of this figure depicts the anti-inflammatory, analgesic and antipyretic pathway of valdecoxib.
The latter portion of this figure depicts valdecoxib’s potential involvement in platelet aggregation. Prostaglandin synthesis varies across different tissue types. Platelets, anuclear cells derived from fragmentation from megakaryocytes, contain COX-1, but not COX-2. COX-1 activity in platelets is required for thromboxane A2 (TxA2)-mediated platelet aggregation. Platelet activation and coagulation do not normally occur in intact blood vessels. After blood vessel injury, platelets adhere to the subendothelial collagen at the site of injury. Activation of collagen receptors initiates phospholipase C (PLC)-mediated signaling cascades resulting in the release of intracellular calcium from the dense tubula system. The increase in intracellular calcium activates kinases required for morphological change, transition to procoagulant surface, secretion of granular contents, activation of glycoproteins, and the activation of phospholipase A2 (PLA2). Activation of PLA2 results in the liberation of arachidonic acid, a precursor to prostaglandin synthesis, from membrane phospholipids. The accumulation of TxA2, ADP and thrombin mediates further platelet recruitment and signal amplification. TxA2 and ADP stimulate their respective G-protein coupled receptors, thomboxane A2 receptor and P2Y purinoreceptor 12, and inhibit the production of cAMP via adenylate cyclase inhibition. This counteracts the adenylate cyclase stimulatory effects of the platelet aggregation inhibitor, PGI2, produced by neighbouring endothelial cells. Platelet adhesion, cytoskeletal remodeling, granular secretion and signal amplification are independent processes that lead to the activation of the fibrinogen receptor. Fibrinogen receptor activation exposes fibrinogen binding sites and allows platelet cross-linking and aggregation to occur.
Neighbouring endothelial cells found in blood vessels express both COX-1 and COX-2. COX-2 in endothelial cells mediates the synthesis of PGI2, an effective platelet aggregation inhibitor and vasodilator, while COX-1 mediates vasoconstriction and stimulates platelet aggregation. PGI2 produced by endothelial cells encounters platelets in the blood stream and binds to the G-protein coupled prostacyclin receptor. This causes G-protein mediated activation of adenylate cyclase, which catalyzes the conversion of adenosine triphosphate (ATP) to cyclic AMP (cAMP). Four cAMP molecules then bind to the regulatory subunits of the inactive cAMP-dependent protein kinase holoenzyme causing dissociation of the regulatory subunits and leaving two active catalytic subunit monomers. The active subunits of cAMP-dependent protein kinase catalyze the phosphorylation of a number of proteins. Phosphorylation of inositol 1,4,5-trisphosphate receptor type 1 on the endoplasmic reticulum (ER) inhibits the release of calcium from the ER. This in turn inhibits the calcium-dependent events, including PLA2 activation, involved in platelet activation and aggregation. Inhibition of PLA2 decreases intracellular TxA2 and inhibits the platelet aggregation pathway. cAMP-dependent kinase also phosphorylates the actin-associated protein, vasodilator-stimulated phosphoprotein. Phosphorylation inhibits protein activity, which includes cytoskeleton reorganization and platelet activation. Valdexocib preferentially inhibits COX-2 with little activity against COX-1. COX-2 inhibition in endothelial cells decreases the production of PGI2 and the ability of these cells to inhibit platelet aggregation and stimulate vasodilation. These effects are thought to be responsible for the rare, but severe, adverse cardiovascular effects observed with rofecoxib, a COX-2 inhibitor which was subsequently been withdrawn from the market. Valdexocib was withdrawn from the Canadian, U.S. and E.U. markets in 2005 due to concerns of possible increased risk of heart attack and stroke.
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Creator: WishartLab Created On: August 22, 2013 at 10:45 Last Updated: August 22, 2013 at 10:45 |