Sandbox Reserved 1725

From Proteopedia

(Difference between revisions)

Revision as of 20:04, 17 March 2022

This Sandbox is Reserved from February 28 through September 1, 2022 for use in the course CH462 Biochemistry II taught by R. Jeremy Johnson at the Butler University, Indianapolis, USA. This reservation includes Sandbox Reserved 1700 through Sandbox Reserved 1729.

To get started:

Click the edit this page tab at the top. Save the page after each step, then edit it again.
show the Scene authoring tools, create a molecular scene, and save it. Copy the green link into the page.
Add a description of your scene. Use the buttons above the wikitext box for bold, italics, links, headlines, etc.

More help: Help:Editing

Vitamin K Epoxide Reductase

This is a default text for your page '. Click above on edit this page' to modify. Be careful with the < and > signs.

You may include any references to papers as in: the use of JSmol in Proteopedia ^[1] or to the article describing Jmol ^[2] to the rescue.

1 Introduction
- 1.1 Vitamin K Cycle
- 1.2 Structural Overview
2 Catalytic Cycle
3 Medical Relevance
- 3.1 Warfarin
- 3.2 Superwarfarins

Introduction

Vitamin K Cycle

Vitamin K is essential for blood clotting in the body. The fully reduced form, KH2, allows the gamma carboxylation of blood clotting cofactors and is turned into the epoxide form in the process. Vitamin K epoxide reductase, abbreviated VKOR, turns the epoxide back to the fully reduced form so the reduced form can be used again. This transformation happens in two steps including converting the epoxide to the partially oxidized Vitamin K quinone then converting the quinone to the fully reduced hydroquinone (KH2). ^[3]

Structural Overview

VKOR consists of four transmembrane helices embedded in the endoplasmic reticulum membrane. The files on the RCSB Protein Data Bank include a barrel domain that is not pertinent to the function of VKOR. The images presented here have been edited to remove the barrel domain and renumbered to correspond with the article by Liu. ^[4] Helices one and two are connected by the beta hairpin region which contains two of the active cysteines, C43 and C51. VKOR also has a cap domain covering the active site, made up of an anchor, loop, and helix.

Catalytic Cycle

Overview

Catalytic Cysteines

VKOR uses four catalytic cysteines (43, 51, 132, and 135) to facilitate reduction and cause conformational changes via disulfide bridge formation. When an oxidized or partially oxidized Vitamin K enters the active site, VKOR has a stabilizing 51-132 disulfide bond. C43 attacks that bond, forming a new bond with C51. There are 4 catalytic cysteines that are important to VKOR, 43, 51, 132, and 135. To explain how this works, it is easiest to start with the second state. In the second state, an oxidized or partially oxidized Vitamin K has entered the active site. The stabilizing 51-132 disulfide bond is shown. Then in the third state, 43 has attacked the disulfide bond and made its own bond with 51. You can see 132 has an oxygen. That is because the researchers made a mutation from S to O to force the reaction to stop at that step so the structure could be deduced. In the natural VKOR, that would be a sulfur. The next state, the open state, results from 132 forming a bridge with 135. This allows release of the reduced or partially reduced Vitamin K. All of this disulfide rearranging was working to reduce the Vitamin K, particularly in the 135 position. If we go back to State 2, when Vitamin K first binds, you can see that 135 is not tied up in a disulfide bond. It is available to help the Vitamin K bond. So, it makes sense that once 135 gets forced to bond, the now reduced Vitamin K is released. State 5 is interesting because the disulfide bonds are similar to the open state, but warfarin is actually bound. This represents the binding of warfarin to the fully oxidized VKOR at the end of its cycle. Going back to State 1, the researchers used a mutation at 43 to mimic VKOR’s partially oxidized state. Warfarin can also bind to this state and notice that the disulfide bonds are the same as State 2. Also it is worth pointing out how the disulfide bonds contribute to conformational changes and are affected by conformational changes, which affects their proximity to each other and the active site.

Tyrosine 138 and Asparagine 80

Hydrophobic Interactions

Medical Relevance

Warfarin

Warfarin is a structural mimic of Vitamin K that is used clinically as an anticoagulant.

Superwarfarins

This is a sample scene created with SAT to by Group, and another to make of the protein. You can make your own scenes on SAT starting from scratch or loading and editing one of these sample scenes.

References

↑ Hanson, R. M., Prilusky, J., Renjian, Z., Nakane, T. and Sussman, J. L. (2013), JSmol and the Next-Generation Web-Based Representation of 3D Molecular Structure as Applied to Proteopedia. Isr. J. Chem., 53:207-216. doi:http://dx.doi.org/10.1002/ijch.201300024
↑ Herraez A. Biomolecules in the computer: Jmol to the rescue. Biochem Mol Biol Educ. 2006 Jul;34(4):255-61. doi: 10.1002/bmb.2006.494034042644. PMID:21638687 doi:10.1002/bmb.2006.494034042644
↑ Stafford DW. The vitamin K cycle. J Thromb Haemost. 2005 Aug;3(8):1873-8. doi: 10.1111/j.1538-7836.2005.01419.x. PMID:16102054 doi:http://dx.doi.org/10.1111/j.1538-7836.2005.01419.x
↑ Liu S, Li S, Shen G, Sukumar N, Krezel AM, Li W. Structural basis of antagonizing the vitamin K catalytic cycle for anticoagulation. Science. 2020 Nov 5. pii: science.abc5667. doi: 10.1126/science.abc5667. PMID:33154105 doi:http://dx.doi.org/10.1126/science.abc5667

Student Contributors

Izabella Jordan, Emma Varness

Retrieved from "http://52.214.119.220/wiki/index.php/Sandbox_Reserved_1725"

@@ Line 10: / Line 10: @@
 Vitamin K is essential for blood clotting in the body. The fully reduced form, KH2, allows the gamma carboxylation of blood clotting cofactors and is turned into the epoxide form in the process. Vitamin K epoxide reductase, abbreviated VKOR, turns the epoxide back to the fully reduced form so the reduced form can be used again. This transformation happens in two steps including converting the epoxide to the partially oxidized Vitamin K quinone then converting the quinone to the fully reduced hydroquinone (KH2). <ref name="Stafford">PMID:16102054</ref>
 === Structural Overview ===
-VKOR consists of four transmembrane helices embedded in the endoplasmic reticulum membrane. The files on the RCSB Protein Data Bank include a barrel domain that is not pertinent to the function of VKOR. The images presented here have been edited to remove the barrel domain and renumbered to correspond with the article by Liu. <ref name="Liu">PMID:33154105</ref> Helices one and two are connected by the beta hairpin region which contains two of the active cysteines, C43 and C51.
+VKOR consists of four transmembrane helices embedded in the endoplasmic reticulum membrane. The files on the RCSB Protein Data Bank include a barrel domain that is not pertinent to the function of VKOR. The images presented here have been edited to remove the barrel domain and renumbered to correspond with the article by Liu. <ref name="Liu">PMID:33154105</ref> Helices one and two are connected by the beta hairpin region which contains two of the active cysteines, C43 and C51. VKOR also has a cap domain covering the active site, made up of an anchor, loop, and helix.
-transmembrane helices embedded in ER anchor
-and 2 connected by beta hairpin which contains C43 and C51 (active) (luminal region/domain)
-Active site on inside of ER lumen
-Cap domain covers active site, has anchor, loop, and helix
-White portion is the barrel domain that the scientists used to help deduce the structure. That part is not important to our discussion.
-=== Function ===
 == Catalytic Cycle ==
@@ Line 24: / Line 17: @@
 ===Catalytic Cysteines===
+VKOR uses four catalytic cysteines (43, 51, 132, and 135) to facilitate reduction and cause conformational changes via disulfide bridge formation. When an oxidized or partially oxidized Vitamin K enters the active site, VKOR has a stabilizing 51-132 disulfide bond. C43 attacks that bond, forming a new bond with C51.
 There are 4 catalytic cysteines that are important to VKOR, 43, 51, 132, and 135. To explain how this works, it is easiest to start with the second state. In the second state, an oxidized or partially oxidized Vitamin K has entered the active site. The stabilizing 51-132 disulfide bond is shown. Then in the third state, 43 has attacked the disulfide bond and made its own bond with 51. You can see 132 has an oxygen. That is because the researchers made a mutation from S to O to force the reaction to stop at that step so the structure could be deduced. In the natural VKOR, that would be a sulfur. The next state, the open state, results from 132 forming a bridge with 135. This allows release of the reduced or partially reduced Vitamin K. All of this disulfide rearranging was working to reduce the Vitamin K, particularly in the 135 position. If we go back to State 2, when Vitamin K first binds, you can see that 135 is not tied up in a disulfide bond. It is available to help the Vitamin K bond. So, it makes sense that once 135 gets forced to bond, the now reduced Vitamin K is released. State 5 is interesting because the disulfide bonds are similar to the open state, but warfarin is actually bound. This represents the binding of warfarin to the fully oxidized VKOR at the end of its cycle. Going back to State 1, the researchers used a mutation at 43 to mimic VKOR’s partially oxidized state. Warfarin can also bind to this state and notice that the disulfide bonds are the same as State 2. Also it is worth pointing out how the disulfide bonds contribute to conformational changes and are affected by conformational changes, which affects their proximity to each other and the active site.