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Sandbox Reserved 1793

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Revision as of 17:06, 31 March 2023

This Sandbox is Reserved from February 27 through August 31, 2023 for use in the course CH462 Biochemistry II taught by R. Jeremy Johnson at the Butler University, Indianapolis, USA. This reservation includes Sandbox Reserved 1765 through Sandbox Reserved 1795.

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Sodium Bile Salt Co-Transporting Protein

1 Introduction
2 Structure
- 2.1 Binding Sites
- 2.2 Conformational Change
3 Bile Salt Transport
4 Medical Relevancy

Introduction

Sodium Taurocholate Co-Transporting Polypeptide, or NTCP, is a membrane transporter protein that is found in the plasma membrane of liver cells, or hepatocytes. NTCP's primary function is the transportation of taurocholates, or bile salts, into the liver and out of the liver to the small intestine ^[1] NTCP is part of the solute carrier superfamily, more specifically SLC10. NTCP is the founding member of the SLC10 family, first discovered in rat hepatocytes in 1978 ^[2] NTCP has a key role in Enterohepatic circulation, and it's unique ability to transport other solutes lends it therapeutic potential for lowering cholesterol and liver disease.

NTCP also serves as a binding site for hepatitis B virus and hepatitis d virus ^[3] Future studies into HBV binding mechanism can help understand infection pathways and the development of viral inhibitors.

Structure

Binding Sites

NTCP, among others in the SLC10 family, have . Many polar and negatively charged residues are characteristic of these active sites. The high level of conservation among sodium binding placement and interacting residues suggests sodium binding is coupled to bile salt transport. Additional mutations in the X-motif near sodium binding sites have shown that bile salt transport function is lost also suggesting that sodium allows bile salt binding. ^[4] It is understood that these sodium binding sites facilitate changes from open-pore to closed pore states of NTCP that allow for the binding or release of bile salts. Closed-pore state is favored in the absence of sodium ions, while open-pore state is favored in the presence of sodium ions. This also allows for sodium concentrations to regulate uptake of taurocholates. When intracellular sodium levels are higher, open-pore state is favored allowing for the diffusion of taurocholates. However, when extracellular sodium levels are high, closed-state is favored preventing diffusion of taurocholates. ^[4]

The is also characteristic of NTCP. The pore surface remains Hydrophobic, while lining of the open pore state is largely Polar. This pattern is believed to follow similar amphipathic patterns within taurocholate and other NTCP substrates, such as steroids and statins. ^[4] Thus the channel provides specificity while preventing leakage of other substrates. When observing the relevant it is shown that some residues form Van der Waals interactions while others will form dipole-dipole or ionic interactions with bile salt substrates. The core domain appears to contribute most of the polar domains, while the panel domain contributes more hydrophobic residues.

Conformational Change


	Cartoon representation of NTCP conformational change.


	Cartoon representation of NTCP conformational change.

Bile Salt Transport

Medical Relevancy

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

↑ Stieger B. The role of the sodium-taurocholate cotransporting polypeptide (NTCP) and of the bile salt export pump (BSEP) in physiology and pathophysiology of bile formation. Handb Exp Pharmacol. 2011;(201):205-59. doi: 10.1007/978-3-642-14541-4_5. PMID: 21103971. DOI: DOI: 10.1007/978-3-642-14541-4_5.
↑ Anwer MS, Stieger B. Sodium-dependent bile salt transporters of the SLC10A transporter family: more than solute transporters. Pflugers Arch. 2014 Jan;466(1):77-89. PMID:24196564 doi:10.1007/s00424-013-1367-0
↑ Park, JH., Iwamoto, M., Yun, JH. et al. Structural insights into the HBV receptor and bile acid transporter NTCP. Nature 606, 1027–1031 (2022). https://doi.org/10.1038/s41586-022-04857-0.
↑ ^4.0 ^4.1 ^4.2 Goutam, K., Ielasi, F.S., Pardon, E. et al. Structural basis of sodium-dependent bile salt uptake into the liver. Nature 606, 1015–1020 (2022). DOI: 10.1038/s41586-022-04723-z.

Retrieved from "http://52.214.119.220/wiki/index.php/Sandbox_Reserved_1793"

@@ Line 16: / Line 16: @@
 == Structure ==
-=== Active Sites ===
+=== Binding Sites ===
 NTCP, among others in the SLC10 family, have <scene name='95/952721/Sodium_binding/2'>two sodium binding sites</scene>. Many polar and negatively charged residues are characteristic of these active sites. The high level of conservation among sodium binding placement and interacting residues suggests sodium binding is coupled to bile salt transport. Additional mutations in the X-motif near sodium binding sites have shown that bile salt transport function is lost also suggesting that sodium allows bile salt binding.
 <Ref name = "Goutam"> Goutam, K., Ielasi, F.S., Pardon, E. et al. Structural basis of sodium-dependent bile salt uptake into the liver. Nature 606, 1015–1020 (2022). [https://doi.org/10.1038/s41586-022-04723-z DOI: 10.1038/s41586-022-04723-z]. </Ref> It is understood that these sodium binding sites facilitate changes from open-pore to closed pore states of NTCP that allow for the binding or release of bile salts. Closed-pore state is favored in the absence of sodium ions, while open-pore state is favored in the presence of sodium ions. This also allows for sodium concentrations to regulate uptake of taurocholates. When intracellular sodium levels are higher, open-pore state is favored allowing for the diffusion of taurocholates. However, when extracellular sodium levels are high, closed-state is favored preventing diffusion of taurocholates. <ref name="Goutam"/>
-The <scene name='95/952721/Hydrophobic_channel/8'>amphipathic pore</scene> is also characteristic of NTCP. The pore surface remains {{Template:ColorKey_Hydrophobic}}, while lining of the open pore state is largely {{Template:ColorKey_Polar}}. This pattern is believed to follow similar amphipathic patterns within taurocholate and other NTCP substrates, such as steroids and statins. <ref name="Goutam"/> Thus the channel provides specificity while preventing leakage of other substrates. When observing the relevant <scene name='95/952721/Bile_salts_res/3'>bile salt binding residues</scene> it is shown that some residues form Van der waals interactions while others will form dipole-dipole or ionic interactions with bile salt substrates. The core domain appears to contribute most of the polar domains, while the panel domain contributes more hydrophobic residues.
+The <scene name='95/952721/Amphipathic_patterns/1'>amphipathic pore</scene> is also characteristic of NTCP. The pore surface remains {{Template:ColorKey_Hydrophobic}}, while lining of the open pore state is largely {{Template:ColorKey_Polar}}. This pattern is believed to follow similar amphipathic patterns within taurocholate and other NTCP substrates, such as steroids and statins. <ref name="Goutam"/> Thus the channel provides specificity while preventing leakage of other substrates. When observing the relevant <scene name='95/952721/Bile_salts_res/3'>bile salt binding residues</scene> it is shown that some residues form Van der Waals interactions while others will form dipole-dipole or ionic interactions with bile salt substrates. The core domain appears to contribute most of the polar domains, while the panel domain contributes more hydrophobic residues.
 === Conformational Change ===
@@ Line 27: / Line 27: @@
 <table align='right' border='0' width='184' cellpadding='10' bgcolor='#d0d0d0' hspace='8'><tr><td rowspan='2'>&nbsp;</td><td bgcolor='#e8e8e8'>[[Image:Surface_NTCP_confchange.gif‎]]</td></tr><tr><td bgcolor='#e8e8e8'>Cartoon representation of NTCP conformational change.</td></tr></table>
 == Bile Salt Transport ==
-[[Image:Bile_transport_mech.png |550px|left|thumb]]
 == Medical Relevancy ==

Sandbox Reserved 1793

From Proteopedia

Revision as of 17:06, 31 March 2023

Sodium Bile Salt Co-Transporting Protein

Contents

Introduction

Structure

Binding Sites

Conformational Change

Bile Salt Transport

Medical Relevancy

References

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