Opioid receptors

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Structure of κ-opioid receptor complex with opioid antagonist, citric acid, PEG and octadec-enoate derivative (PDB entry 4djh)

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Opioid receptors (OpR) are a Subfamily A4 G protein-coupled receptors with opioids as ligands^[1]. OpR types are classified according to the ligands which bind to them.

Tutorial: The opioid receptor, a molecular switch

You can check out the in the window on the right. It shows the mu opioid receptor bound to a peptide ligand and a G protein . The G protein ("G" because it binds to GTP) consists of three parts A , B , and C ).

The μ-opioid receptor binds morphine. For more details on μ-opioid receptor see

The binding of an opioid induces a in the μ-opioid receptor that activates an inhibitory G-protein (Gαi/o). This results in the dissociation of the G-protein complex. The Gα subunit then inhibits adenylyl cyclase. The Gβγ subunit acts to inhibit Ca2+ channels and activate K+ channels. .

- 6dde μ-opioid receptor: G protein complex
The κ-opioid receptor binds opium-type ligands. For details see Student Project 3 for UMass Chemistry 423 Spring 2015.

The κ-opioid receptor is a . The extracellular side is home to the proteins primary . These 2 units will span the length for the cell membrane to form the basis of the receptor molecule. , where helices I (in light blue) and helices VIII (in dark blue). This area will make up the basis for the intermembrane surface area. A distinguishing feature that separates the κ-opioid receptor from other receptors, is the large β-hairpin, , located near the main active site of the protein. It is believed that its function is to cap the active site of the receptor. Although in general, this protein is primarily composed of α-helices, not β-sheets (Compare to ). This evidence reinforces the idea that this protein is a transmembrane protein rather than one found inside the cytosol. In general transmembrane protein are composed almost entirely of α-helices (or β-sheet arranged in special fashion called a β-barrel), in order to have maximum stability inside the membrane. Interesting feature of the κ-opioid receptor is the formed by Cys131 and Cys210 which is conserved across all opioid receptors. of κ-opioid receptor. The human κ-opioid receptor ligand binding pocket displays a unique combination of key characteristics both shared with and distinct from those in the chemokine and aminergic receptor families.

The δ-opioid receptor binds enkephalins. For details see Delta opioid receptor.

Opioid receptors typically have 2 big portions: the upper portion, zoomed in here with shown in indigo, that is ligand specific and recognizes a particular ligand, and the lower portion which is highly conserved amongst all receptors. When approaches δ-opioid receptor, it is distinguished by the high hydrophobic interaction between the indole group on the ligand and leucine 300 on the receptor. As it glides deeper into the binding site facilitated by the hydrophobic interaction, the hydroxyl group of the tyrosine-like phenol group hydrogen bonds with water molecules which are hydrogen bound to a critical histidine 248. This holds the ligand by having both the phenol group and histidine anchored by a water molecule. The water molecules within the binding pocket flank both the ligand and receptor, serving almost as a scaffolding on which for both components to act. Adjacent to the phenol group, the oxygen of an ether is hydrogen bound to tyrosine 129 of the receptor. On the opposite side of the binding site, Asp128 forms a salt bridge with the charged amino group on the ligand. The rest of the ligand maintains hydrophobic contact with non-polar residues of the binding site. The phenol to water interaction is a conserved interaction between many opioid receptors and their respective ligands as evidenced by many natural antagonists having a tyrosine that interacts with a water molecule in a similar fashion.

The Nociceptin/orphanin FQ opioid receptor binds the heptadecapeptide orphanin^[2].

References

↑ Feng Y, He X, Yang Y, Chao D, Lazarus LH, Xia Y. Current research on opioid receptor function. Curr Drug Targets. 2012 Feb;13(2):230-46. PMID:22204322
↑ Donica CL, Awwad HO, Thakker DR, Standifer KM. Cellular mechanisms of nociceptin/orphanin FQ (N/OFQ) peptide (NOP) receptor regulation and heterologous regulation by N/OFQ. Mol Pharmacol. 2013 May;83(5):907-18. doi: 10.1124/mol.112.084632. Epub 2013 Feb , 8. PMID:23395957 doi:http://dx.doi.org/10.1124/mol.112.084632

Proteopedia Page Contributors and Editors (what is this?)

Alexander Berchansky, Michal Harel

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

@@ Line 39: / Line 39: @@
 **[[μ Opioid Receptors]]
 **[[Mu Opioid Receptor]]
+**[[Opioid receptor]]
 The binding of an opioid induces a <scene name='78/786661/Mor_on_off/2'>conformational change</scene> in the μ-opioid receptor that activates an inhibitory G-protein (Gαi/o). This results in the dissociation of the G-protein complex. The Gα subunit then inhibits adenylyl cyclase. The Gβγ subunit acts to inhibit Ca2+ channels and activate K+ channels. <scene name='87/874998/Mor_on_off/1'>Activation mechanism</scene>.
 **[[6dde]] μ-opioid receptor: G protein complex<br />
@@ Line 48: / Line 49: @@
 *  The '''Nociceptin/orphanin FQ opioid receptor''' binds the heptadecapeptide orphanin<ref>PMID:23395957</ref>.
+See also:
+*[[Receptor]]
+*[[Transmembrane (cell surface) receptors]]
+*[[G protein-coupled receptors]]
 </StructureSection>
 == References ==
 <references/>

Opioid receptors

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