Sandbox Reserved 1768

From Proteopedia

(Difference between revisions)

Revision as of 16:59, 27 March 2023

Sodium-taurocholate Co-transporting Polypeptide

1 Introduction
2 Structure
3 Function
- 3.1 Mechanism of Bile Salt Uptake
- 3.2 Mechanism of HBV/HDV Infection
4 Medical Relevance

Introduction

Sodium-taurocholate Co-transporting Polypeptide (NTCP) is found within the membrane of hepatocyte, and its primary role is to facilitate the transport of bile salts into hepatocytes from the bloodstream. This is important because 90% of human bile salts are recycled daily, so the function of NTCP is critical in providing bile salts to solubilize fats for digestion. Bile salts are derived from cholesterol, and they serve an important role in the mechanical digestion of fats and ultimately facilitate the chemical digestion of lipids. Their mixture of hydrophobic and hydrophilic regions allow them to act as a bridge between aqueous and lipid environments. In the small intestine, bile salts emulsify fats and cholesterol into micelles. Without bile, fats would spontaneously separate out of the aqueous mixture in the duodenum and would not be accessible to pancreatic lipase to break down fat in your diet. Proper fat digestion requires both pancreatic lipase and bile, so the working transport of bile salts through NTCP in necessary to facilitate this action. In addition to transporting bile salts into the cytoplasm of hepatocytes, NTCP also serves as a receptor for Hepatitis B (HBV) and Hepatitis D (HDV) viruses.

^[1]

^[2]

^[3]

^[4]

^[5]

^[6]

Structure

Structures were determined by cryogenic electron microscopy (Cryo-EM) of NTCP in complex with antibodies or nanobodies, revealing two key conformations in NTCP's transport mechanism. There are nine alpha helices spanning the membrane, with the N-terminus located on the extracellular side of the plasma membrane and the C-terminus located on the intracellular side. The panel domain is formed by transmembrane helices TM1, TM5, and TM6. The core domain is formed by the packing of a helix bundle consisting of TM2, TM3, and TM4 with another helix bundle consisting of TM7, TM8, and TM9. These two helix bundles are related by pseudo two-fold symmetry. Transmembrane helices are connected by short loops as well as extracellular and intracellular alpha helices that lie nearly parallel to the membrane.

Domains

NTCP contains two characteristic domains: the core and panel domains. Movement of these two domains allows recognition and transport of bile salts into hepatocytes.

Panel Domain: 1-44, 155-208
Core domain: 45-154, 209-309

Proline/Glycine Hinge

Glycine and proline residues in the connecting loops and extra- and intracellular helices act as hinges in the mechanism of bile salt uptake. The flexibility allows separation of the core and panel domains, creating a pore open to the extracellular space and exposing critical Na+ binding sites. Once substrate binds the open-pore state, this hinge allows transition to close this pore relative to the extracellular side and open to the cytoplasmic side, thus allowing release of substrate into the cell.

Sodium Binding Sites

To transport a single bile salt from the blood to the cytoplasm of the liver cell, two sodium ions are required to be bound to to NTCP in the open-pore state in association with specific residues of the molecule. This is because the transport of bile salts into the cell is so thermodynamically unfavorable , the reaction has to be coupled to the favorable transport of 2 sodium into into the cell. When the bile salts are released into the cell, the protein is then reverted to the inward facing conformation, in which the pore through which the bile salt had just passed is now closed. This is an example of secondary active transport. The residues interacting with the sodium ion in sodium binding site #1 includes S105, N106, E257, and T123. The residues interacting with the sodium ion in sodium binding site #2 includes Q261 and Q68. Mutations to these significant residues will inhibit the binding of sodium ions, and therefore, inhibit the overall function of NTCP.

Significant Residues

The vast majority of residues involved in bile salt uptake are also involved in HBV/HDV infection. (extracellular view) of Human NTCP have been shown to be vital for preS1 domain recognition along with bile salt uptake. These residues were replaced in mouse NTCP by human NTCP and conferred to successful binding of the virus. These residues are found in the extracellular loop connecting TM2 and TM3. (extracellular view) have also been shown to be vital for preS1 recognition and bile salt uptake. These residues were mutated in monkey NTCP to the human residues and preS1 binding was then successful. These residues are found on the N-terminal end of TM5. The absence of residues in either of these hinders preS1 binding and therefore HBV/HDV infection. Interestingly, residues 84-87 do not affect bile acid uptake, so it is a potential site for blocking HBV/HDV infection while maintaining NTCP's ability to perform its normal function. Another important residue was discovered to be a single-nucleotide polymorphism in a small population in East Asia. , which is normally serine, being mutated to phenylalanine prevents preS1 binding and does not support bile acid transport. This residue is also found extracellularly, on TM8 of NTCP. There are 3 additional leucine residues that when mutated, block both preS1 binding and HBV/HDV infection. Replacing L27, L31, and L35 (INSERT GREEN LINK) with tryptophan residues presumably blocks the preS1 binding site preventing proper infection.

Function

Mechanism of Bile Salt Uptake

Bile salts recognize and bind to the . After binding, bile salts pass through the amphipathic pore (INSERT BLUE LINK) and NTCP transitions into the . In this conformation, the pore closes off relative to the extracellular side and opens to the cytoplasmic side. Transition to the inward facing state allows release of bile salts and sodium ions. It is not yet known how this transition exactly proceeds.

Mechanism of HBV/HDV Infection

HBV and HDV viruses infect are transported through NTCP via secondary active transport. After binding to NTCP in the open-pore state, the viruses remain bound until low bile salt levels in the blood shift equilibria enough that endocytosis of NTCP occurs. Once in the cell, the viruses dissociate and infect. The exact mechanism of how HBV and HDV bind to NTCP is not certain, although two critical sites have been identified on NTCP: residues 84-87 and 157-165. Additionally, it has been shown that myristoylation (INSERT BLUE LINK) of the HBV/HDV capsid is vital for recognition by NTCP, as well as residues 8-17 on HBV/HDV (sequence: NPLGFFPDHQ). (INSERT CITING) has proposed two mechanisms for how HBV/HDV binds to NTCP. The first proposes binding of the myristoyl group to the host cell membrane, while residues 8-17 interact with NTCP residues 157-165. The second proposes binding of the myristoyl group with residues 157-165 in the pore.

Medical Relevance

References

↑ Asami J, Kimura KT, Fujita-Fujiharu Y, Ishida H, Zhang Z, Nomura Y, Liu K, Uemura T, Sato Y, Ono M, Yamamoto M, Noda T, Shigematsu H, Drew D, Iwata S, Shimizu T, Nomura N, Ohto U. Structure of the bile acid transporter and HBV receptor NTCP. Nature. 2022 Jun; 606 (7916):1021-1026. DOI: 10.1038/s41586-022-04845-4.
↑ Goutam K, Ielasi FS, Pardon E, Steyaert J, Reyes N. Structural basis of sodium-dependent bile salt uptake into the liver. Nature. 2022 Jun;606(7916):1015-1020. DOI: 10.1038/s41586-022-04723-z.
↑ Park JH, Iwamoto M, Yun JH, Uchikubo-Kamo T, Son D, Jin Z, Yoshida H, Ohki M, Ishimoto N, Mizutani K, Oshima M, Muramatsu M, Wakita T, Shirouzu M, Liu K, Uemura T, Nomura N, Iwata S, Watashi K, Tame JRH, Nishizawa T, Lee W, Park SY. Structural insights into the HBV receptor and bile acid transporter NTCP. Nature. 2022 Jun;606(7916):1027-1031. DOI: 10.1038/s41586-022-04857-0.
↑ Liu H, Irobalieva RN, Bang-Sørensen R, Nosol K, Mukherjee S, Agrawal P, Stieger B, Kossiakoff AA, Locher KP. Structure of human NTCP reveals the basis of recognition and sodium-driven transport of bile salts into the liver. Cell Res. 2022 Aug;32(8):773-776. DOI: 10.1038/s41422-022-00680-4.
↑ Qi X, Li W. Unlocking the secrets to human NTCP structure. Innovation (Camb). 2022 Aug 1;3(5):100294. doi: 10.1016/j.xinn.2022.100294. DOI: 10.1016/j.xinn.2022.100294.
↑ Zhang X, Zhang Q, Peng Q, Zhou J, Liao L, Sun X, Zhang L, Gong T. Hepatitis B virus preS1-derived lipopeptide functionalized liposomes for targeting of hepatic cells. Biomaterials. 2014 Jul;35(23):6130-41. doi: 10.1016/j.biomaterials.2014.04.037. DOI: 10.1016/j.biomaterials.2014.04.037.

Student Contributors

Ben Minor
Maggie Samm
Zac Stanley

Retrieved from "http://52.214.119.220/wiki/index.php/Sandbox_Reserved_1768"

@@ Line 1: / Line 1: @@
 =Sodium-taurocholate Co-transporting Polypeptide=
+<StructureSection load='OP14.pdb' size='350' side='right' frame='true' caption='Sodium-taurocholate co-transporting Polypeptide (NTCP) 7PQQ' scene='95/952697/Ntcp_open-pore_state/2'>
-<StructureSection load='7PQQ' size='350' side='right' frame='true' caption='Sodium-taurocholate co-transporting Polypeptide (NTCP) 7PQQ' scene=''>
 == Introduction ==
-Sodium-taurocholate Co-transporting Polypeptide (NTCP) is found within the membrane of [https://en.wikipedia.org/wiki/Hepatocyte hepatocyte], and its primary role is to facilitate the transport of [https://en.wikipedia.org/wiki/Bile_acid bile salts] into hepatocytes from the bloodstream. This is important because 90% of human bile salts are recycled daily, so the function of NTCP is critical in providing bile salts to solubilize fats for digestion. In addition to transporting bile salts into the cytoplasm of hepatocytes, NTCP also serves as a receptor for [https://en.wikipedia.org/wiki/Hepatitis_B Hepatitis B (HBV)] and [https://en.wikipedia.org/wiki/Hepatitis_D Hepatitis D (HDV)] viruses.
+Sodium-taurocholate Co-transporting Polypeptide (NTCP) is found within the membrane of [https://en.wikipedia.org/wiki/Hepatocyte hepatocyte], and its primary role is to facilitate the transport of [https://en.wikipedia.org/wiki/Bile_acid bile salts] into hepatocytes from the bloodstream. This is important because 90% of human bile salts are recycled daily, so the function of NTCP is critical in providing bile salts to solubilize fats for digestion. Bile salts are derived from [https://en.wikipedia.org/wiki/Cholesterol cholesterol], and they serve an important role in the mechanical digestion of fats and ultimately facilitate the chemical digestion of lipids. Their mixture of [https://en.wikipedia.org/wiki/Hydrophobe hydrophobic] and [https://en.wikipedia.org/wiki/Hydrophile hydrophilic] regions allow them to act as a bridge between aqueous and lipid environments. In the small intestine, bile salts [https://en.wikipedia.org/wiki/Emulsion emulsify] fats and cholesterol into [https://en.wikipedia.org/wiki/Micelle micelles]. Without bile, fats would spontaneously separate out of the aqueous mixture in the duodenum and would not be accessible to [https://en.wikipedia.org/wiki/Pancreatic_lipase_family#Human_pancreatic_lipase pancreatic lipase] to break down fat in your diet. Proper fat digestion requires both pancreatic lipase and bile, so the working transport of bile salts through NTCP in necessary to facilitate this action. In addition to transporting bile salts into the cytoplasm of hepatocytes, NTCP also serves as a receptor for [https://en.wikipedia.org/wiki/Hepatitis_B Hepatitis B (HBV)] and [https://en.wikipedia.org/wiki/Hepatitis_D Hepatitis D (HDV)] viruses.
-== Function ==
-=== Bile Salt Uptake ===
+<Ref name="Asami"> Asami J, Kimura KT, Fujita-Fujiharu Y, Ishida H, Zhang Z, Nomura Y, Liu K, Uemura T, Sato Y, Ono M, Yamamoto M, Noda T, Shigematsu H, Drew D, Iwata S, Shimizu T, Nomura N, Ohto U. Structure of the bile acid transporter and HBV receptor NTCP. Nature. 2022 Jun; 606 (7916):1021-1026. [https://dx.doi.org/10.1038/s41586-022-04845-4 DOI: 10.1038/s41586-022-04845-4]. </Ref>
-=== HBV/HDV Infection ===
+<Ref name="Goutam"> Goutam K, Ielasi FS, Pardon E, Steyaert J, Reyes N. Structural basis of sodium-dependent bile salt uptake into the liver. Nature. 2022 Jun;606(7916):1015-1020. [https://dx.doi.org/10.1038/s41586-022-04723-z DOI: 10.1038/s41586-022-04723-z]. </Ref>
+<Ref name="Park"> Park JH, Iwamoto M, Yun JH, Uchikubo-Kamo T, Son D, Jin Z, Yoshida H, Ohki M, Ishimoto N, Mizutani K, Oshima M, Muramatsu M, Wakita T, Shirouzu M, Liu K, Uemura T, Nomura N, Iwata S, Watashi K, Tame JRH, Nishizawa T, Lee W, Park SY. Structural insights into the HBV receptor and bile acid transporter NTCP. Nature. 2022 Jun;606(7916):1027-1031. [https://dx.doi.org/10.1038/s41586-022-04857-0 DOI: 10.1038/s41586-022-04857-0]. </Ref>
+<Ref name="Liu"> Liu H, Irobalieva RN, Bang-Sørensen R, Nosol K, Mukherjee S, Agrawal P, Stieger B, Kossiakoff AA, Locher KP. Structure of human NTCP reveals the basis of recognition and sodium-driven transport of bile salts into the liver. Cell Res. 2022 Aug;32(8):773-776. [https://dx.doi.org/10.1038/s41422-022-00680-4 DOI: 10.1038/s41422-022-00680-4]. </Ref>
+<Ref name="Qi"> Qi X, Li W. Unlocking the secrets to human NTCP structure. Innovation (Camb). 2022 Aug 1;3(5):100294. doi: 10.1016/j.xinn.2022.100294. [https://dx.doi.org/10.1016/j.xinn.2022.100294 DOI: 10.1016/j.xinn.2022.100294]. </Ref>
+<Ref name="Zhang"> Zhang X, Zhang Q, Peng Q, Zhou J, Liao L, Sun X, Zhang L, Gong T. Hepatitis B virus preS1-derived lipopeptide functionalized liposomes for targeting of hepatic cells. Biomaterials. 2014 Jul;35(23):6130-41. doi: 10.1016/j.biomaterials.2014.04.037. [https://dx.doi.org/10.1016/j.biomaterials.2014.04.037 DOI: 10.1016/j.biomaterials.2014.04.037]. </Ref>
 == Structure ==
-=== Proline/Glycine Hinge ===
+Structures were determined by [https://en.wikipedia.org/wiki/Cryogenic_electron_microscopy cryogenic electron microscopy (Cryo-EM)] of NTCP in complex with antibodies or nanobodies, revealing two key conformations in NTCP's transport mechanism. There are nine [https://en.wikipedia.org/wiki/Alpha_helix alpha helices] spanning the membrane, with the [https://en.wikipedia.org/wiki/N-terminus N-terminus] located on the extracellular side of the plasma membrane and the [https://en.wikipedia.org/wiki/C-terminus C-terminus] located on the intracellular side. The panel domain is formed by transmembrane helices TM1, TM5, and TM6. The core domain is formed by the packing of a helix bundle consisting of TM2, TM3, and TM4 with another helix bundle consisting of TM7, TM8, and TM9. These two helix bundles are related by pseudo two-fold symmetry. Transmembrane helices are connected by short loops as well as extracellular and intracellular alpha helices that lie nearly parallel to the membrane.
-=== Core & Panel Domains ===
+=== Domains ===
+NTCP contains two characteristic domains: the core and panel domains. Movement of these two domains allows recognition and transport of bile salts into hepatocytes.
+*<b><font color="orange">Panel Domain</font></b>: 1-44, 155-208
+*<b><font color="#0040e0">Core domain</font></b>: 45-154, 209-309
+=== Proline/Glycine Hinge ===
+Glycine and proline residues in the connecting loops and extra- and intracellular helices act as hinges in the mechanism of bile salt uptake. The flexibility allows separation of the core and panel domains, creating a pore open to the extracellular space and exposing critical Na+ binding sites. Once substrate binds the open-pore state, this hinge allows transition to close this pore relative to the extracellular side and open to the cytoplasmic side, thus allowing release of substrate into the cell.
 === Sodium Binding Sites ===
+To transport a single bile salt from the blood to the cytoplasm of the liver cell, two sodium ions are required to be bound to to NTCP in the open-pore state in association with specific residues of the molecule. This is because the transport of bile salts into the cell is so thermodynamically unfavorable , the reaction has to be coupled to the favorable transport of 2 sodium into into the cell. When the bile salts are released into the cell, the protein is then reverted to the inward facing conformation, in which the pore through which the bile salt had just passed is now closed. This is an example of secondary active transport. The residues interacting with the sodium ion in sodium binding site #1 includes S105, N106, E257, and T123. The residues interacting with the sodium ion in sodium binding site #2 includes Q261 and Q68. Mutations to these significant residues will inhibit the binding of sodium ions, and therefore, inhibit the overall function of NTCP.
+<scene name='95/952698/Sodium_binding_sites/1'>TextToBeDisplayed</scene>
 === Significant Residues ===
 The vast majority of residues involved in bile salt uptake are also involved in HBV/HDV infection. <scene name='95/952696/Residues_84-87_1/1'>Residues 84-87</scene> (extracellular view) of Human NTCP have been shown to be vital for preS1 domain recognition along with bile salt uptake. These residues were replaced in mouse NTCP by human NTCP and conferred to successful binding of the virus. These residues are found in the extracellular loop connecting TM2 and TM3. <scene name='95/952696/Residues_157-165/1'>Residues 157-165</scene> (extracellular view) have also been shown to be vital for preS1 recognition and bile salt uptake. These residues were mutated in monkey NTCP to the human residues and preS1 binding was then successful. These residues are found on the N-terminal end of TM5. The absence of residues in either of these <scene name='95/952696/Residues_84-87_and_157-165/1'>two extracellular patches</scene> hinders preS1 binding and therefore HBV/HDV infection. Interestingly, residues 84-87 do not affect bile acid uptake, so it is a potential site for blocking HBV/HDV infection while maintaining NTCP's ability to perform its normal function. Another important residue was discovered to be a [https://en.wikipedia.org/wiki/Single-nucleotide_polymorphism single-nucleotide polymorphism] in a small population in East Asia. <scene name='95/952696/Residue_267/1'>Residue 267</scene>, which is normally serine, being mutated to phenylalanine prevents preS1 binding and does not support bile acid transport. This residue is also found extracellularly, on TM8 of NTCP. There are 3 additional leucine residues that when mutated, block both preS1 binding and HBV/HDV infection. Replacing L27, L31, and L35 (INSERT GREEN LINK) with tryptophan residues presumably blocks the preS1 binding site preventing proper infection.
-== Molecular Mechanism ==
+== Function ==
 === Mechanism of Bile Salt Uptake ===
-<scene name='95/952697/Ntcp_open-pore_state_surface/1'>NTCP Open-Pore State</scene>
+Bile salts recognize and bind to the <scene name='95/952697/Ntcp_open-pore_state_surface/1'>open-pore state</scene>. After binding, bile salts pass through the amphipathic pore (INSERT BLUE LINK) and NTCP transitions into the <scene name='95/952697/Ntcp_inward_facing_state/1'>inward facing state</scene>. In this conformation, the pore closes off relative to the extracellular side and opens to the cytoplasmic side. Transition to the inward facing state allows release of bile salts and sodium ions. It is not yet known how this transition exactly proceeds.
 === Mechanism of HBV/HDV Infection ===
-HBV/HDV infection is reliant on multiple properties that must be present on both the virus itself and the NTCP protein. First, the HBV/HDV capsid must be [https://en.wikipedia.org/wiki/Myristoylation myristoylated] in order for proper recognition by NTCP. Residues 2-48 are the most significant residues of HBV/HDV that are highly conserved amongst these viruses that are vital for infection. Specifically, residues 8-17 on HBV/HDV have been identified as the most important. These residues are NPLGFFPDHQ. There are two proposed mechanisms as to how exactly HBV/HDV bind to NTCP and enter the cell. In both mechanisms, there is an initial translocation of the myristoylated preS1 HBV/HDV virus to interact with the host cell (hepatocyte). The first mechanism involves the myristoyl group of preS1 binding to the host cell membrane, not NTCP, and residues P8-H17 interacting with NTCP residues 157-165. The second mechanism involves the myristoyl group of preS1 binding directly into the open-pore of NTCP interacting with residues 157-165. In both proposed mechanisms, the interactions with the extracellular residues 84-87 of NTCP is unknown.
+HBV and HDV viruses infect are transported through NTCP via secondary active transport. After binding to NTCP in the open-pore state, the viruses remain bound until low bile salt levels in the blood shift equilibria enough that endocytosis of NTCP occurs. Once in the cell, the viruses dissociate and infect. The exact mechanism of how HBV and HDV bind to NTCP is not certain, although two critical sites have been identified on NTCP: residues 84-87 and 157-165. Additionally, it has been shown that myristoylation (INSERT BLUE LINK) of the HBV/HDV capsid is vital for recognition by NTCP, as well as residues 8-17 on HBV/HDV (sequence: NPLGFFPDHQ). (INSERT CITING) has proposed two mechanisms for how HBV/HDV binds to NTCP. The first proposes binding of the myristoyl group to the host cell membrane, while residues 8-17 interact with NTCP residues 157-165. The second proposes binding of the myristoyl group with residues 157-165 in the pore.
 == Medical Relevance ==
-== Relevance ==
-This is a sample scene created with SAT to <scene name="/12/3456/Sample/1">color</scene> by Group, and another to make <scene name="/12/3456/Sample/2">a transparent representation</scene> of the protein. You can make your own scenes on SAT starting from scratch or loading and editing one of these sample scenes.
 </StructureSection>
 === References ===
 <references/>
 === Student Contributors ===
-Ben Minor
+*Ben Minor
-Maggie Samm
+*Maggie Samm
-Zac Stanley
+*Zac Stanley