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Wikipedia

Opioid receptor

January 26, 2023

Opioid receptors are a group of inhibitory G protein-coupled receptors with opioids as ligands.[1][2][3] The endogenous opioids are dynorphins, enkephalins, endorphins, endomorphins and nociceptin. The opioid receptors are ~40% identical to somatostatin receptors (SSTRs). Opioid receptors are distributed widely in the brain, in the spinal cord, on peripheral neurons, and digestive tract.

An animated view of the human κ-opioid receptor in complex with the antagonist JDTic.

Discovery

By the mid-1960s, it had become apparent from pharmacologic studies that opiate drugs were likely to exert their actions at specific receptor sites, and that there were likely to be multiple such sites.[4] Early studies had indicated that opiates appeared to accumulate in the brain.[5] The receptors were first identified as specific molecules through the use of binding studies, in which opiates that had been labeled with radioisotopes were found to bind to brain membrane homogenates. The first such study was published in 1971, using 3H-levorphanol.[6] In 1973, Candace Pert and Solomon H. Snyder published the first detailed binding study of what would turn out to be the μ opioid receptor, using 3H-naloxone.[7] That study has been widely credited as the first definitive finding of an opioid receptor, although two other studies followed shortly after.[8][9]

Purification

Purification of the receptor further verified its existence. The first attempt to purify the receptor involved the use of a novel opioid receptor antagonist called chlornaltrexamine that was demonstrated to bind to the opioid receptor.[10] Caruso later purified the detergent-extracted component of rat brain membrane that eluted with the specifically bound 3H-chlornaltrexamine.[11]

Major subtypes

There are four major subtypes of opioid receptors.[12] OGFr was originally discovered and named as a new opioid receptor zeta (ζ). However it was subsequently found that it shares little sequence similarity with the other opioid receptors, and has quite different function.

Receptor Subtypes Location[13][14] Function[13][14] G protein subunit
delta (δ)
DOR
OP1 (I)		 δ1,[15] δ2 Gi
kappa (κ)
KOR
OP2 (I)		 κ1, κ2, κ3 Gi
mu (μ)
MOR
OP3 (I)		 μ1, μ2, μ3 μ1:

μ2:

μ3:

Gi
Nociceptin receptor
NOR
OP4 (I)		 ORL1
zeta (ζ)
ZOR

(I). Name based on order of discovery

Evolution

The opioid receptor (OR) family originated from two duplication events of a single ancestral opioid receptor early in vertebrate evolution. Phylogenetic analysis demonstrates that the family of opioid receptors was already present at the origin of jawed vertebrates over 450 million years ago. In humans, this paralogon resulting from a double tetraploidization event resulted in the receptor genes being located on chromosomes 1, 6, 8, and 20. Tetraploidization events often result in the loss of one or more of the duplicated genes, but in this case, nearly all species retain all four opioid receptors, indicating biological significance of these systems. Stefano traced the co-evolution of OR and the immune system underlying the fact that these receptors helped earlier animals to survive pain and inflammation shock in aggressive environments.[16]

The receptor families delta, kappa, and mu demonstrate 55–58% identity to one another, and a 48–49% homology to the nociceptin receptor. Taken together, this indicates that the NOP receptor gene, OPRL1, has equal evolutionary origin, but a higher mutation rate, than the other receptor genes.[17]

Although opioid receptor families share many similarities, their structural differences lead to functional difference. Thus, mu-opioid receptors induce relaxation, trust, satisfaction, and analgesia.[18][19] This system may also help mediate stable, emotionally committed relationships. Experiments with juvenile guinea pigs showed that social attachment is mediated by the opioid system. The evolutionary role of opioid signaling in these behaviors was confirmed in dogs, chicks, and rats.[18] Opioid receptors also have a role in mating behaviors.[20] However, mu-opioid receptors do not just control social behavior because they also make individuals feel relaxed in a wide range of other situations.

Kappa- and delta-opioid receptors may be less associated with relaxation and analgesia because kappa-opioid receptor suppresses mu-opioid receptor activation, and delta-opioid receptor interacts differently with agonists and antagonists. Kappa-opioid receptors are involved in chronic anxiety's perceptual mobilization, whereas delta-opioid receptors induce action initiation, impulsivity, and behavioural mobilization.[19][21] These differences led some researches to suggest that up- or down-regulations within three opioid receptors families are the basis of different dispositional emotionality seen in psychiatric disorders.[22][23][24]

Human-specific opioid-modulated cognitive features are not attributable to coding differences for receptors or ligands, which share 99% similarity with primates, but to regulatory changes in expression levels.[25][26]

Nomenclature

The receptors were named using the first letter of the first ligand that was found to bind to them. Morphine was the first chemical shown to bind to "mu" receptors. The first letter of the drug morphine is m, rendered as the corresponding Greek letter μ. In similar manner, a drug known as ketocyclazocine was first shown to attach itself to "κ" (kappa) receptors,[27] while the "δ" (delta) receptor was named after the mouse vas deferens tissue in which the receptor was first characterised.[28] An additional opioid receptor was later identified and cloned based on homology with the cDNA. This receptor is known as the nociceptin receptor or ORL1 (opiate receptor-like 1).

The opioid receptor types are nearly 70% identical, with the differences located at the N and C termini. The μ receptor is perhaps the most important. It is thought that the G protein binds to the third intracellular loop of all opioid receptors. Both in mice and humans, the genes for the various receptor subtypes are located on separate chromosomes.

Separate opioid receptor subtypes have been identified in human tissue. Research has so far failed to identify the genetic evidence of the subtypes, and it is thought that they arise from post-translational modification of cloned receptor types.[29]

An IUPHAR subcommittee[30][31] has recommended that appropriate terminology for the 3 classical (μ, δ, κ) receptors, and the non-classical (nociceptin) receptor, should be MOP ("Mu OPiate receptor"), DOP, KOP and NOP respectively.

Additional receptors

Sigma (σ) receptors were once considered to be opioid receptors due to the antitussive actions of many opioid drugs' being mediated via σ receptors, and the first selective σ agonists being derivatives of opioid drugs (e.g., allylnormetazocine). However, σ receptors were found to not be activated by endogenous opioid peptides, and are quite different from the other opioid receptors in both function and gene sequence, so they are now not usually classified with the opioid receptors.

The existence of further opioid receptors (or receptor subtypes) has also been suggested because of pharmacological evidence of actions produced by endogenous opioid peptides, but shown not to be mediated through any of the four known opioid receptor subtypes. The existence of receptor subtypes or additional receptors other than the classical opioid receptors (μ, δ, κ) has been based on limited evidence, since only three genes for the three main receptors have been identified.[32][33][34] The only one of these additional receptors to have been definitively identified is the zeta (ζ) opioid receptor, which has been shown to be a cellular growth factor modulator with met-enkephalin being the endogenous ligand. This receptor is now most commonly referred to as the opioid growth factor receptor (OGFr).[35][36]

Epsilon (ε) opioid receptor

Another postulated opioid receptor is the ε opioid receptor. The existence of this receptor was suspected after the endogenous opioid peptide beta-endorphin was shown to produce additional actions that did not seem to be mediated through any of the known opioid receptors.[37][38] Activation of this receptor produces strong analgesia and release of met-enkephalin; a number of widely used opioid agonists, such as the μ agonist etorphine and the κ agonist bremazocine, have been shown to act as agonists for this effect (even in the presence of antagonists to their more well known targets),[39] while buprenorphine has been shown to act as an epsilon antagonist. Several selective agonists and antagonists are now available for the putative epsilon receptor;[40][41] however, efforts to locate a gene for this receptor have been unsuccessful, and epsilon-mediated effects were absent in μ/δ/κ "triple knockout" mice,[42] suggesting the epsilon receptor is likely to be either a splice variant derived from alternate post-translational modification, or a heteromer derived from hybridization of two or more of the known opioid receptors.

Mechanism of activation

Opioid receptors are a type of G protein–coupled receptor (GPCR). These receptors are distributed throughout the central nervous system and within the peripheral tissue of neural and non-neural origin. They are also located in high concentrations in the Periaqueductal gray, Locus coeruleus, and the Rostral ventromedial medulla.[43] The receptors consist of an extracellular amino acid N-terminus, seven trans-membrane helical loops, three extracellular loops, three intracellular loops, and an intracellular carboxyl C-terminus. Three GPCR extracellular loops provide a compartment where signaling molecules can attach to generate a response. Heterotrimeric G protein contain three different sub-units, which include an alpha (α) subunit, a beta (β) subunit, and a gamma (γ) sub-unit.[44] The gamma and beta sub-units are permanently bound together, producing a single Gβγ sub-unit. Heterotrimeric G proteins act as ‘molecular switches’, which play a key role in signal transduction, because they relay information from activated receptors to appropriate effector proteins. All G protein α sub-units contain palmitate, which is a 16-carbon saturated fatty acid, that is attached near the N-terminus through a labile, reversible thioester linkage to a cysteine amino acid. It is this palmitoylation that allows the G protein to interact with membrane phospholipids due to the hydrophobic nature of the alpha sub-units. The gamma sub-unit is also lipid modified and can attach to the plasma membrane as well. These properties of the two sub-units, allow the opioid receptor's G protein to permanently interact with the membrane via lipid anchors.[45]

When an agonistic ligand binds to the opioid receptor, a conformational change occurs, and the GDP molecule is released from the Gα sub-unit. This mechanism is complex, and is a major stage of the signal transduction pathway. When the GDP molecule is attached, the Gα sub-unit is in its inactive state, and the nucleotide-binding pocket is closed off inside the protein complex. However, upon ligand binding, the receptor switches to an active conformation, and this is driven by intermolecular rearrangement between the trans-membrane helices. The receptor activation releases an ‘ionic lock’ which holds together the cytoplasmic sides of transmembrane helices three and six, causing them to rotate. This conformational change exposes the intracellular receptor domains at the cytosolic side, which further leads to the activation of the G protein. When the GDP molecule dissociates from the Gα sub-unit, a GTP molecule binds to the free nucleotide-binding pocket, and the G protein becomes active. A Gα(GTP) complex is formed, which has a weaker affinity for the Gβγ sub-unit than the Gα(GDP) complex, causing the Gα sub-unit to separate from the Gβγ sub-unit, forming two sections of the G protein. The sub-units are now free to interact with effector proteins; however, they are still attached to the plasma membrane by lipid anchors.[46] After binding, the active G protein sub-units diffuses within the membrane and acts on various intracellular effector pathways. This includes inhibiting neuronal adenylate cyclase activity, as well as increasing membrane hyper-polarisation. When the adenylyl cyclase enzyme complex is stimulated, it results in the formation of Cyclic Adenosine 3', 5'-Monophosphate (cAMP), from Adenosine 5' Triphosphate (ATP). cAMP acts as a secondary messenger, as it moves from the plasma membrane into the cell and relays the signal.[47]

cAMP binds to, and activates cAMP-dependent protein kinase A (PKA), which is located intracellularly in the neuron. The PKA consists of a holoenzyme - it is a compound which becomes active due to the combination of an enzyme with a coenzyme. The PKA enzyme also contains two catalytic PKS-Cα subunits, and a regulator PKA-R subunit dimer. The PKA holoenzyme is inactive under normal conditions, however, when cAMP molecules that are produced earlier in the signal transduction mechanism combine with the enzyme, PKA undergoes a conformational change. This activates it, giving it the ability to catalyse substrate phosphorylation.[48] CREB (cAMP response element binding protein) belongs to a family of transcription factors and is positioned in the nucleus of the neuron. When the PKA is activated, it phosphorylates the CREB protein (adds a high energy phosphate group) and activates it. The CREB protein binds to cAMP response elements CRE, and can either increase or decrease the transcription of certain genes. The cAMP/PKA/CREB signalling pathway described above is crucial in memory formation and pain modulation.[49] It is also significant in the induction and maintenance of long-term potentiation, which is a phenomenon that underlies synaptic plasticity - the ability of synapses to strengthen or weaken over time.

Voltage-gated dependent calcium channel, (VDCCs), are key in the depolarisation of neurons, and play a major role in promoting the release of neurotransmitters. When agonists bind to opioid receptors, G proteins activate and dissociate into their constituent Gα and Gβγ sub-units. The Gβγ sub-unit binds to the intracellular loop between the two trans-membrane helices of the VDCC. When the sub-unit binds to the voltage-dependent calcium channel, it produces a voltage-dependent block, which inhibits the channel, preventing the flow of calcium ions into the neuron. Embedded in the cell membrane is also the G protein-coupled inwardly-rectifying potassium channel. When a Gβγ or Gα(GTP) molecule binds to the C-terminus of the potassium channel, it becomes active, and potassium ions are pumped out of the neuron.[50] The activation of the potassium channel and subsequent deactivation of the calcium channel causes membrane hyperpolarization. This is when there is a change in the membrane's potential, so that it becomes more negative. The reduction in calcium ions causes a reduction neurotransmitter release because calcium is essential for this event to occur.[51] This means that neurotransmitters such as glutamate and substance P cannot be released from the presynaptic terminal of the neurons. These neurotransmitters are vital in the transmission of pain, so opioid receptor activation reduces the release of these substances, thus creating a strong analgesic effect.

Pathology

Some forms of mutations in δ-opioid receptors have resulted in constant receptor activation.[52]

Protein–protein interactions

Receptor heteromers

See also

References

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Further reading

  • Stein C (2016). "Opioid Receptors". Annual Review of Medicine. 67: 433–51. doi:10.1146/annurev-med-062613-093100. PMID 26332001.
  • Valentino RJ, Volkow ND (December 2018). "Untangling the complexity of opioid receptor function". Neuropsychopharmacology. 43 (13): 2514–2520. doi:10.1038/s41386-018-0225-3. PMC 6224460. PMID 30250308.

External links

  • Opioid+Receptors at the US National Library of Medicine Medical Subject Headings (MeSH)
  • "How opioid drugs activate receptors". National Institute of Health.
  • "Opioid Receptors". IUPHAR Database of Receptors and Ion Channels. International Union of Basic and Clinical Pharmacology.
  • Corbett A, McKnight S, Henderson G. "Opioid Receptors". BLTC Research. Retrieved 2008-03-21.
  • Guzman F. "Video lectures on opioid receptors". Pharmacology Corner. Retrieved 2012-07-30.
  • Lomize A, Lomize M, Pogozheva I. . University of Michigan. Archived from the original on 2014-01-03. Retrieved 2008-03-21.

January 26, 2023
opioid, receptor, group, inhibitory, protein, coupled, receptors, with, opioids, ligands, endogenous, opioids, dynorphins, enkephalins, endorphins, endomorphins, nociceptin, opioid, receptors, identical, somatostatin, receptors, sstrs, distributed, widely, bra. Opioid receptors are a group of inhibitory G protein coupled receptors with opioids as ligands 1 2 3 The endogenous opioids are dynorphins enkephalins endorphins endomorphins and nociceptin The opioid receptors are 40 identical to somatostatin receptors SSTRs Opioid receptors are distributed widely in the brain in the spinal cord on peripheral neurons and digestive tract An animated view of the human k opioid receptor in complex with the antagonist JDTic Contents 1 Discovery 2 Purification 3 Major subtypes 4 Evolution 5 Nomenclature 6 Additional receptors 6 1 Epsilon e opioid receptor 7 Mechanism of activation 8 Pathology 9 Protein protein interactions 9 1 Receptor heteromers 10 See also 11 References 12 Further reading 13 External linksDiscovery EditBy the mid 1960s it had become apparent from pharmacologic studies that opiate drugs were likely to exert their actions at specific receptor sites and that there were likely to be multiple such sites 4 Early studies had indicated that opiates appeared to accumulate in the brain 5 The receptors were first identified as specific molecules through the use of binding studies in which opiates that had been labeled with radioisotopes were found to bind to brain membrane homogenates The first such study was published in 1971 using 3H levorphanol 6 In 1973 Candace Pert and Solomon H Snyder published the first detailed binding study of what would turn out to be the m opioid receptor using 3H naloxone 7 That study has been widely credited as the first definitive finding of an opioid receptor although two other studies followed shortly after 8 9 Purification EditPurification of the receptor further verified its existence The first attempt to purify the receptor involved the use of a novel opioid receptor antagonist called chlornaltrexamine that was demonstrated to bind to the opioid receptor 10 Caruso later purified the detergent extracted component of rat brain membrane that eluted with the specifically bound 3H chlornaltrexamine 11 Major subtypes EditThere are four major subtypes of opioid receptors 12 OGFr was originally discovered and named as a new opioid receptor zeta z However it was subsequently found that it shares little sequence similarity with the other opioid receptors and has quite different function Receptor Subtypes Location 13 14 Function 13 14 G protein subunitdelta d DOR OP1 I d1 15 d2 brain pontine nuclei amygdala olfactory bulbs deep cortex peripheral sensory neurons analgesia antidepressant effects convulsant effects physical dependence may modulate m opioid receptor mediated respiratory depression Gikappa k KOR OP2 I k1 k2 k3 brain hypothalamus periaqueductal gray claustrum spinal cord substantia gelatinosa peripheral sensory neurons analgesia anticonvulsant effects depression dissociative hallucinogenic effects diuresis miosis dysphoria neuroprotection sedation stress Gimu m MOR OP3 I m1 m2 m3 brain cortex laminae III and IV thalamus striosomes periaqueductal gray rostral ventromedial medulla spinal cord substantia gelatinosa peripheral sensory neurons intestinal tract m1 analgesia physical dependencem2 respiratory depression miosis euphoria reduced GI motility physical dependencem3 possible vasodilation GiNociceptin receptor NOROP4 I ORL1 brain cortex amygdala hippocampus septal nuclei habenula hypothalamus spinal cord anxiety depression appetite development of tolerance to m opioid agonistszeta z ZOR heart liver skeletal muscle kidney brain pancreas fetal tissue liver kidney tissue growth embryonic development regulation of cancer cell proliferation I Name based on order of discoveryEvolution EditThe opioid receptor OR family originated from two duplication events of a single ancestral opioid receptor early in vertebrate evolution Phylogenetic analysis demonstrates that the family of opioid receptors was already present at the origin of jawed vertebrates over 450 million years ago In humans this paralogon resulting from a double tetraploidization event resulted in the receptor genes being located on chromosomes 1 6 8 and 20 Tetraploidization events often result in the loss of one or more of the duplicated genes but in this case nearly all species retain all four opioid receptors indicating biological significance of these systems Stefano traced the co evolution of OR and the immune system underlying the fact that these receptors helped earlier animals to survive pain and inflammation shock in aggressive environments 16 The receptor families delta kappa and mu demonstrate 55 58 identity to one another and a 48 49 homology to the nociceptin receptor Taken together this indicates that the NOP receptor gene OPRL1 has equal evolutionary origin but a higher mutation rate than the other receptor genes 17 Although opioid receptor families share many similarities their structural differences lead to functional difference Thus mu opioid receptors induce relaxation trust satisfaction and analgesia 18 19 This system may also help mediate stable emotionally committed relationships Experiments with juvenile guinea pigs showed that social attachment is mediated by the opioid system The evolutionary role of opioid signaling in these behaviors was confirmed in dogs chicks and rats 18 Opioid receptors also have a role in mating behaviors 20 However mu opioid receptors do not just control social behavior because they also make individuals feel relaxed in a wide range of other situations Kappa and delta opioid receptors may be less associated with relaxation and analgesia because kappa opioid receptor suppresses mu opioid receptor activation and delta opioid receptor interacts differently with agonists and antagonists Kappa opioid receptors are involved in chronic anxiety s perceptual mobilization whereas delta opioid receptors induce action initiation impulsivity and behavioural mobilization 19 21 These differences led some researches to suggest that up or down regulations within three opioid receptors families are the basis of different dispositional emotionality seen in psychiatric disorders 22 23 24 Human specific opioid modulated cognitive features are not attributable to coding differences for receptors or ligands which share 99 similarity with primates but to regulatory changes in expression levels 25 26 Nomenclature EditThe receptors were named using the first letter of the first ligand that was found to bind to them Morphine was the first chemical shown to bind to mu receptors The first letter of the drug morphine is m rendered as the corresponding Greek letter m In similar manner a drug known as ketocyclazocine was first shown to attach itself to k kappa receptors 27 while the d delta receptor was named after the mouse vas deferens tissue in which the receptor was first characterised 28 An additional opioid receptor was later identified and cloned based on homology with the cDNA This receptor is known as the nociceptin receptor or ORL1 opiate receptor like 1 The opioid receptor types are nearly 70 identical with the differences located at the N and C termini The m receptor is perhaps the most important It is thought that the G protein binds to the third intracellular loop of all opioid receptors Both in mice and humans the genes for the various receptor subtypes are located on separate chromosomes Separate opioid receptor subtypes have been identified in human tissue Research has so far failed to identify the genetic evidence of the subtypes and it is thought that they arise from post translational modification of cloned receptor types 29 An IUPHAR subcommittee 30 31 has recommended that appropriate terminology for the 3 classical m d k receptors and the non classical nociceptin receptor should be MOP Mu OPiate receptor DOP KOP and NOP respectively Additional receptors EditSigma s receptors were once considered to be opioid receptors due to the antitussive actions of many opioid drugs being mediated via s receptors and the first selective s agonists being derivatives of opioid drugs e g allylnormetazocine However s receptors were found to not be activated by endogenous opioid peptides and are quite different from the other opioid receptors in both function and gene sequence so they are now not usually classified with the opioid receptors The existence of further opioid receptors or receptor subtypes has also been suggested because of pharmacological evidence of actions produced by endogenous opioid peptides but shown not to be mediated through any of the four known opioid receptor subtypes The existence of receptor subtypes or additional receptors other than the classical opioid receptors m d k has been based on limited evidence since only three genes for the three main receptors have been identified 32 33 34 The only one of these additional receptors to have been definitively identified is the zeta z opioid receptor which has been shown to be a cellular growth factor modulator with met enkephalin being the endogenous ligand This receptor is now most commonly referred to as the opioid growth factor receptor OGFr 35 36 Epsilon e opioid receptor Edit Another postulated opioid receptor is the e opioid receptor The existence of this receptor was suspected after the endogenous opioid peptide beta endorphin was shown to produce additional actions that did not seem to be mediated through any of the known opioid receptors 37 38 Activation of this receptor produces strong analgesia and release of met enkephalin a number of widely used opioid agonists such as the m agonist etorphine and the k agonist bremazocine have been shown to act as agonists for this effect even in the presence of antagonists to their more well known targets 39 while buprenorphine has been shown to act as an epsilon antagonist Several selective agonists and antagonists are now available for the putative epsilon receptor 40 41 however efforts to locate a gene for this receptor have been unsuccessful and epsilon mediated effects were absent in m d k triple knockout mice 42 suggesting the epsilon receptor is likely to be either a splice variant derived from alternate post translational modification or a heteromer derived from hybridization of two or more of the known opioid receptors Mechanism of activation EditOpioid receptors are a type of G protein coupled receptor GPCR These receptors are distributed throughout the central nervous system and within the peripheral tissue of neural and non neural origin They are also located in high concentrations in the Periaqueductal gray Locus coeruleus and the Rostral ventromedial medulla 43 The receptors consist of an extracellular amino acid N terminus seven trans membrane helical loops three extracellular loops three intracellular loops and an intracellular carboxyl C terminus Three GPCR extracellular loops provide a compartment where signaling molecules can attach to generate a response Heterotrimeric G protein contain three different sub units which include an alpha a subunit a beta b subunit and a gamma g sub unit 44 The gamma and beta sub units are permanently bound together producing a single Gbg sub unit Heterotrimeric G proteins act as molecular switches which play a key role in signal transduction because they relay information from activated receptors to appropriate effector proteins All G protein a sub units contain palmitate which is a 16 carbon saturated fatty acid that is attached near the N terminus through a labile reversible thioester linkage to a cysteine amino acid It is this palmitoylation that allows the G protein to interact with membrane phospholipids due to the hydrophobic nature of the alpha sub units The gamma sub unit is also lipid modified and can attach to the plasma membrane as well These properties of the two sub units allow the opioid receptor s G protein to permanently interact with the membrane via lipid anchors 45 When an agonistic ligand binds to the opioid receptor a conformational change occurs and the GDP molecule is released from the Ga sub unit This mechanism is complex and is a major stage of the signal transduction pathway When the GDP molecule is attached the Ga sub unit is in its inactive state and the nucleotide binding pocket is closed off inside the protein complex However upon ligand binding the receptor switches to an active conformation and this is driven by intermolecular rearrangement between the trans membrane helices The receptor activation releases an ionic lock which holds together the cytoplasmic sides of transmembrane helices three and six causing them to rotate This conformational change exposes the intracellular receptor domains at the cytosolic side which further leads to the activation of the G protein When the GDP molecule dissociates from the Ga sub unit a GTP molecule binds to the free nucleotide binding pocket and the G protein becomes active A Ga GTP complex is formed which has a weaker affinity for the Gbg sub unit than the Ga GDP complex causing the Ga sub unit to separate from the Gbg sub unit forming two sections of the G protein The sub units are now free to interact with effector proteins however they are still attached to the plasma membrane by lipid anchors 46 After binding the active G protein sub units diffuses within the membrane and acts on various intracellular effector pathways This includes inhibiting neuronal adenylate cyclase activity as well as increasing membrane hyper polarisation When the adenylyl cyclase enzyme complex is stimulated it results in the formation of Cyclic Adenosine 3 5 Monophosphate cAMP from Adenosine 5 Triphosphate ATP cAMP acts as a secondary messenger as it moves from the plasma membrane into the cell and relays the signal 47 cAMP binds to and activates cAMP dependent protein kinase A PKA which is located intracellularly in the neuron The PKA consists of a holoenzyme it is a compound which becomes active due to the combination of an enzyme with a coenzyme The PKA enzyme also contains two catalytic PKS Ca subunits and a regulator PKA R subunit dimer The PKA holoenzyme is inactive under normal conditions however when cAMP molecules that are produced earlier in the signal transduction mechanism combine with the enzyme PKA undergoes a conformational change This activates it giving it the ability to catalyse substrate phosphorylation 48 CREB cAMP response element binding protein belongs to a family of transcription factors and is positioned in the nucleus of the neuron When the PKA is activated it phosphorylates the CREB protein adds a high energy phosphate group and activates it The CREB protein binds to cAMP response elements CRE and can either increase or decrease the transcription of certain genes The cAMP PKA CREB signalling pathway described above is crucial in memory formation and pain modulation 49 It is also significant in the induction and maintenance of long term potentiation which is a phenomenon that underlies synaptic plasticity the ability of synapses to strengthen or weaken over time Voltage gated dependent calcium channel VDCCs are key in the depolarisation of neurons and play a major role in promoting the release of neurotransmitters When agonists bind to opioid receptors G proteins activate and dissociate into their constituent Ga and Gbg sub units The Gbg sub unit binds to the intracellular loop between the two trans membrane helices of the VDCC When the sub unit binds to the voltage dependent calcium channel it produces a voltage dependent block which inhibits the channel preventing the flow of calcium ions into the neuron Embedded in the cell membrane is also the G protein coupled inwardly rectifying potassium channel When a Gbg or Ga GTP molecule binds to the C terminus of the potassium channel it becomes active and potassium ions are pumped out of the neuron 50 The activation of the potassium channel and subsequent deactivation of the calcium channel causes membrane hyperpolarization This is when there is a change in the membrane s potential so that it becomes more negative The reduction in calcium ions causes a reduction neurotransmitter release because calcium is essential for this event to occur 51 This means that neurotransmitters such as glutamate and substance P cannot be released from the presynaptic terminal of the neurons These neurotransmitters are vital in the transmission of pain so opioid receptor activation reduces the release of these substances thus creating a strong analgesic effect Pathology EditSome forms of mutations in d opioid receptors have resulted in constant receptor activation 52 Protein protein interactions EditReceptor heteromers Edit d k 53 d m k m m ORL1 d CB1 m CB1 k CB1 d a2A d b2 k b2 m a2A d CXCR4 d SNSR4 k APJ m CCR5 m1D GRPR m mGlu5 m 5 HT1A m NK1 m sst2ASee also EditList of opioids Opioid antagonist OpioidergicReferences Edit Dhawan BN Cesselin F Raghubir R Reisine T Bradley PB Portoghese PS Hamon M December 1996 International Union of Pharmacology XII Classification of opioid receptors 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signaling and behavior Anesthesiology 115 6 1363 81 doi 10 1097 ALN 0b013e318238bba6 PMC 3698859 PMID 22020140 Introduction to Essentials of Cell Biology Learn Science at Scitable www nature com Retrieved 2017 11 08 Wedegaertner PB Wilson PT Bourne HR January 1995 Lipid modifications of trimeric G proteins The Journal of Biological Chemistry 270 2 503 6 doi 10 1074 jbc 270 2 503 PMID 7822269 Philip F Sengupta P Scarlata S June 2007 Signaling through a G Protein coupled receptor and its corresponding G protein follows a stoichiometrically limited model The Journal of Biological Chemistry 282 26 19203 16 doi 10 1074 jbc M701558200 PMID 17420253 Steer ML November 1975 Adenyl cyclase Annals of Surgery 182 5 603 9 doi 10 1097 00000658 197511000 00012 PMC 1344045 PMID 172034 Keshwani MM Kanter JR Ma Y Wilderman A Darshi M Insel PA Taylor SS October 2015 Mechanisms of cyclic AMP protein kinase A and glucocorticoid mediated apoptosis using S49 lymphoma cells as a model system Proceedings of the National Academy of Sciences of the United States of America 112 41 12681 6 Bibcode 2015PNAS 11212681K doi 10 1073 pnas 1516057112 PMC 4611605 PMID 26417071 Shao XM Sun J Jiang YL Liu BY Shen Z Fang F et al 2016 Inhibition of the cAMP PKA CREB Pathway Contributes to the Analgesic Effects of Electroacupuncture in the Anterior Cingulate Cortex in a Rat Pain Memory Model Neural Plasticity 2016 5320641 doi 10 1155 2016 5320641 PMC 5206448 PMID 28090359 Yamada M Inanobe A Kurachi Y December 1998 G protein regulation of potassium ion channels Pharmacological Reviews 50 4 723 60 PMID 9860808 Kosten TR George TP July 2002 The neurobiology of opioid dependence implications for treatment Science amp Practice Perspectives 1 1 13 20 doi 10 1151 spp021113 PMC 2851054 PMID 18567959 Befort K Zilliox C Filliol D Yue S Kieffer BL June 1999 Constitutive activation of the delta opioid receptor by mutations in transmembrane domains III and VII The Journal of Biological Chemistry 274 26 18574 81 doi 10 1074 jbc 274 26 18574 PMID 10373467 Fujita W Gomes I Devi LA September 2014 Revolution in GPCR signalling opioid receptor heteromers as novel therapeutic targets IUPHAR review 10 British Journal of Pharmacology 171 18 4155 76 doi 10 1111 bph 12798 PMC 4241085 PMID 24916280 Further reading EditStein C 2016 Opioid Receptors Annual Review of Medicine 67 433 51 doi 10 1146 annurev med 062613 093100 PMID 26332001 Valentino RJ Volkow ND December 2018 Untangling the complexity of opioid receptor function Neuropsychopharmacology 43 13 2514 2520 doi 10 1038 s41386 018 0225 3 PMC 6224460 PMID 30250308 External links EditOpioid Receptors at the US National Library of Medicine Medical Subject Headings MeSH How opioid drugs activate receptors National Institute of Health Opioid Receptors IUPHAR Database of Receptors and Ion Channels International Union of Basic and Clinical Pharmacology Corbett A McKnight S Henderson G Opioid Receptors BLTC Research Retrieved 2008 03 21 Guzman F Video lectures on opioid receptors Pharmacology Corner Retrieved 2012 07 30 Lomize A Lomize M Pogozheva I Orientations of Proteins in Membranes OPM database University of Michigan Archived from the original on 2014 01 03 Retrieved 2008 03 21 Retrieved from https en wikipedia org w index php title Opioid receptor amp oldid 1131208226, wikipedia, wiki, book, books, library,

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