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G protein-gated ion channel

March 15, 2024

G protein-gated ion channels are a family of transmembrane ion channels in neurons and atrial myocytes that are directly gated by G proteins.

Generalized diagram of G protein-gated ion channel: (A) Typically, the activated effector protein begins a signaling cascade which leads to the eventual opening of the ion channel. (B) The GTP-bound α-subunit in some cases can directly activate the ion channel. (C) In other cases, the activated βγ-complex of the G protein may interact with the ion channel.

Overview of mechanisms and function edit

Generally, G protein-gated ion channels are specific ion channels located in the plasma membrane of cells that are directly activated by a family of associated proteins. Ion channels allow for the selective movement of certain ions across the plasma membrane in cells. More specifically, in nerve cells, along with ion transporters, they are responsible for maintaining the electrochemical gradient across the cell.

G proteins are a family of intracellular proteins capable of mediating signal transduction pathways. Each G protein is a heterotrimer of three subunits: α-, β-, and γ- subunits. The α-subunit (Gα) typically binds the G protein to a transmembrane receptor protein known as a G protein-coupled receptor, or GPCR. This receptor protein has a large, extracellular binding domain which will bind its respective ligands (e.g. neurotransmitters and hormones). Once the ligand is bound to its receptor, a conformational change occurs. This conformational change in the G protein allows Gα to bind GTP. This leads to yet another conformational change in the G protein, resulting in the separation of the βγ-complex (Gβγ) from Gα.[1] At this point, both Gα and Gβγ are active and able to continue the signal transduction pathway. Different classes of G protein-coupled receptors have many known functions including the cAMP and Phosphatidylinositol signal transduction pathways.[2] A class known as metabotropic glutamate receptors play a large role in indirect ion channel activation by G proteins. These pathways are activated by second messengers which initiate signal cascades involving various proteins which are important to the cell's response.

G protein-gated ion channels are associated with a specific type of G protein-coupled receptor. These ion channels are transmembrane ion channels with selectivity filters and a G protein binding site. The GPCRs associated with G protein-gated ion channels are not involved in signal transduction pathways. They only directly activate these ion channels using effector proteins or the G protein subunits themselves (see picture). Unlike most effectors, not all G protein-gated ion channels have their activity mediated by Gα of their corresponding G proteins. For instance, the opening of inwardly rectifying K+ (GIRK) channels is mediated by the binding of Gβγ.[3]

G protein-gated ion channels are primarily found in CNS neurons and atrial myocytes, and affect the flow of potassium (K+), calcium (Ca2+), sodium (Na+), and chloride (Cl) across the plasma membrane.[4]

Types of G Protein-gated ion channels edit

Potassium channels edit

Main article: G protein-coupled inwardly-rectifying potassium channel

Structure edit

Four G protein gated inwardly-rectifying potassium (GIRK) channel subunits have been identified in mammals: GIRK1, GIRK2, GIRK3, and GIRK4. The GIRK subunits come together to form GIRK ion channels. These ion channels, once activated, allow for the flow of potassium ions (K+) from the extracellular space surrounding the cell across the plasma membrane and into the cytoplasm. Each channel consists of domains which span the plasma membrane, forming the K+-selective pore region through which the K+ ions will flow.[5][6] Both the N-and C-terminal ends of the GIRK channels are located within the cytoplasm. These domains interact directly with the βγ-complex of the G protein, leading to activation of the K+ channel. .[7] These domains on the N-and C-terminal ends which interact with the G proteins contain certain residues which are critical for the proper activation of the GIRK channel. In GIRK4, the N-terminal residue is His-64 and the C-terminal residue is Leu-268; in GIRK1 they are His-57 and Leu-262, respectively. Mutations in these domains lead to the channel's desensitivity to the βγ-complex and therefore reduce the activation of the GIRK channel.[3]

The four GIRK subunits are 80-90% similar in their pore-forming and transmembrane domains, a feature accountable by the similarities in their structures and sequences. GIRK2, GIRK3, and GIRK4 share an overall identity of 62% with each other, while GIRK1 only shares 44% identity with the others.[6] Because of their similarity, the GIRK channel subunits can come together easily to form heteromultimers (a protein with two or more different polypeptide chains). GIRK1, GIRK2, and GIRK3 show abundant and overlapping distribution in the central nervous system (CNS) while GIRK1 and GIRK4 are found primarily in the heart.[4] GIRK1 combines with GIRK2 in the CNS and GIRK4 in the atrium to form heterotetramers; each final heterotetramer contains two GIRK1 subunits and two GIRK2 or GIRK4 subunits. GIRK2 subunits can also form homotetramers in the brain, while GIRK4 subunits can form homotetramers in the heart.[7] GIRK1 subunits have not been shown to be able to form functional homotetramers. Though GIRK3 subunits are found in the CNS, their role in forming functional ion channels is still unknown.[4]

Subtypes and respective functions edit

  • GIRKs found in the heart

One G protein-gated potassium channel is the inward-rectifing potassium channel (IKACh) found in cardiac muscle (specifically, the sinoatrial node and atria),[8] which contributes to the regulation of heart rate.[9] These channels are almost entirely dependent on G protein activation, making them unique when compared to other G protein-gated channels.[10] Activation of the IKACh channels begins with release of acetylcholine (ACh) from the vagus nerve[9] onto pacemaker cells in the heart.[10] ACh binds to the M2 muscarinic acetylcholine receptors, which interact with G proteins and promote the dissociation of the Gα subunit and Gβγ-complex.[11] IKACh is composed of two homologous GIRK channel subunits: GIRK1 and GIRK4. The Gβγ-complex binds directly and specifically to the IKACh channel through interactions with both the GIRK1 and GIRK4 subunits.[12] Once the ion channel is activated, K+ ions flow out of the cell and cause it to hyperpolarize.[13] In its hyperpolarized state, the neuron cannot fire action potentials as quickly, which slows the heartbeat.[14]

  • GIRKs found in the brain

The G protein inward rectifying K+ channel found in the CNS is a heterotetramer composed of GIRK1 and GIRK2 subunits[4] and is responsible for maintaining the resting membrane potential and excitability of the neuron.[9] Studies have shown the largest concentrations of the GIRK1 and GIRK2 subunits to be in the dendritic areas of neurons in the CNS.[4] These areas, which are both extrasynaptic (exterior to a synapse) and perisynaptic (near a synapse), correlate with the large concentration of GABAB receptors in the same areas. Once the GABAB receptors are activated by their ligands, they allow for the dissociation of the G protein into its individual α-subunit and βγ-complex so it can in turn activate the K+ channels. The G proteins couple the inward rectifying K+ channels to the GABAB receptors, mediating a significant part of the GABA postsynaptic inhibition.[4]

Furthermore, GIRKs have been found to play a role in a group of serotonergic neurons in the dorsal raphe nucleus, specifically those associated with the neuropeptide hormone orexin.[15] The 5-HT1A receptor, a serotonin receptor and type of GPCR, has been shown to be coupled directly with the α-subunit of a G protein, while the βγ-complex activates GIRK without use of a second messenger. The subsequent activation of the GIRK channel mediates hyperpolarization of orexin neurons, which regulate the release of many other neurotransmitters including noradrenaline and acetylcholine.[15]

Calcium channels edit

Structure edit

In addition to the subset of potassium channels that are directly gated by G proteins, G proteins can also directly gate certain calcium ion channels in neuronal cell membranes. Although membrane ion channels and protein phosphorylation are typically indirectly affected by G protein-coupled receptors via effector proteins (such as phospholipase C and adenylyl cyclase) and second messengers (such as inositol triphosphate, diacylglycerol and cyclic AMP), G proteins can short circuit the second-messenger pathway and gate the ion channels directly.[16] Such bypassing of the second-messenger pathways is observed in mammalian cardiac myocytes and associated sarcolemmal vesicles in which Ca2+ channels are able to survive and function in the absence of cAMP, ATP or protein kinase C when in the presence of the activated α-subunit of the G protein.[17] For example, Gα, which is stimulatory to adenylyl cyclase, acts on the Ca2+ channel directly as an effector. This short circuit is membrane-delimiting, allowing direct gating of calcium channels by G proteins to produce effects more quickly than the cAMP cascade could.[16] This direct gating has also been found in specific Ca2+ channels in the heart and skeletal muscle T tubules.[18]

Function edit

Several high-threshold, slowly inactivating calcium channels in neurons are regulated by G proteins.[13] The activation of α-subunits of G proteins has been shown to cause rapid closing of voltage-dependent Ca2+ channels, which causes difficulties in the firing of action potentials.[1] This inhibition of voltage-gated Calcium channels by G protein-coupled receptors has been demonstrated in the dorsal root ganglion of a chick among other cell lines.[13] Further studies have indicated roles for both Gα and Gβγ subunits in the inhibition of Ca2+ channels. The research geared to defining the involvement of each subunit, however, has not uncovered the specificity or mechanisms by which Ca2+ channels are regulated.

The acid-sensing ion channel ASIC1a is a specific G protein-gated Ca2+ channel. The upstream M1 muscarinic acetylcholine receptor binds to Gq-class G proteins. Blocking this channel with the agonist oxotremorine methiodide was shown to inhibit ASIC1a currents.[19] ASIC1a currents have also been shown to be inhibited in the presence of oxidizing agents and potentiated in the presence of reducing agents. A decrease and increase in acid-induced intracellular Ca2+ accumulation were found, respectively.[20]

Sodium channels edit

Patch clamp measurements suggest a direct role for Gα in the inhibition of fast Na+ current within cardiac cells.[21] Other studies have found evidence for a second-messenger pathway which may indirectly control these channels.[22] Whether G proteins indirectly or directly activate Na+ ion channels not been defined with complete certainty.

Chloride channels edit

Chloride channel activity in epithelial and cardiac cells has been found to be G protein-dependent. However, the cardiac channel that has been shown to be directly gated by the Gα subunit has not yet been identified. As with Na+ channel inhibition, second-messenger pathways cannot be discounted in Cl channel activation.[23]

Studies done on specific Cl channels show differing roles of G protein activation. It has been shown that G proteins directly activate one type of Cl channel in skeletal muscle.[10] Other studies, in CHO cells, have demonstrated a large conductance Cl channel to be activated differentially by CTX- and PTX-sensitive G proteins.[10] The role of G proteins in the activation of Cl channels is a complex area of research that is ongoing.

Clinical significance and ongoing research edit

Mutations in G proteins associated with G protein-gated ion channels have been shown to be involved in diseases such as epilepsy, muscular diseases, neurological diseases, and chronic pain, among others.[4]

Epilepsy, chronic pain, and addictive drugs such as cocaine, opioids, cannabinoids, and ethanol all affect neuronal excitability and heart rate. GIRK channels have been shown to be involved in seizure susceptibility, cocaine addiction, and increased tolerance for pain by opioids, cannabinoids, and ethanol.[24] This connection suggests that GIRK channel modulators may be useful therapeutic agents in the treatment of these conditions. GIRK channel inhibitors may serve to treat addictions to cocaine, opioids, cannabinoids, and ethanol while GIRK channel activators may serve to treat withdrawal symptoms.[24]

Alcohol intoxication edit

Alcohol intoxication has been shown to be directly connected to the actions of GIRK channels. GIRK channels have a hydrophobic pocket that is capable of binding ethanol, the type of alcohol found in alcoholic beverages.[25][26] When ethanol acts as an agonist, GIRK channels in the brain experience prolonged opening. This causes decreased neuronal activity, the result of which manifests as the symptoms of alcohol intoxication. The discovery of the hydrophobic pocket capable of binding ethanol is significant in the field of clinical pharmacology. Agents that can act as agonists to this binding site can be potentially useful in the creation of drugs for the treatment of neurological disorders such as epilepsy in which neuronal firing exceeds normal levels.[26]

Breast cancer edit

Studies have shown that a link exists between channels with GIRK1 subunits and the beta-adrenergic receptor pathway in breast cancer cells responsible for growth regulation of the cells. Approximately 40% of primary human breast cancer tissues have been found to carry the mRNA which codes for GIRK1 subunits.[27] Treatment of breast cancer tissue with alcohol has been shown to trigger increased growth of the cancer cells. The mechanism of this activity is still a subject of research.[27]

Down syndrome edit

Altered cardiac regulation is common in adults diagnosed with Down syndrome and may be related to G protein-gated ion channels. The KCNJ6 gene is located on chromosome 21 and encodes for the GIRK2 protein subunit of G protein-gated K+ channels.[28] People with Down Syndrome have three copies of chromosome 21, resulting in an overexpression of the GIRK2 subunit. Studies have found that recombinant mice overexpressing GIRK2 subunits show altered responses to drugs that activate G protein-gated K+ channels. These altered responses were limited to the sino-atrial node and atria, both areas which contain many G protein-gated K+ channels.[28] Such findings could potentially lead to the development of drugs that can help regulate the cardiac sympathetic-parasympathetic imbalance in Down Syndrome adults.

Chronic atrial fibrillation edit

Atrial fibrillation (abnormal heart rhythm) is associated with shorter action potential duration and believed to be affected by the G protein-gated K+ channel, IK,ACh.[29] The IK,ACh channel, when activated by G proteins, allows for the flow of K+ across the plasma membrane and out of the cell. This current hyperpolarizes the cell, thus terminating the action potential. It has been shown that in chronic atrial fibrillation there an increase in this inwardly rectifying current because of constantly activated IK,ACh channels.[29] Increase in the current results in shorter action potential duration experienced in chronic atrial fibrillation and leads to the subsequent fibrillating of the cardiac muscle. Blocking IK,ACh channel activity could be a therapeutic target in atrial fibrillation and is an area under study.

Pain management edit

GIRK channels have been demonstrated in vivo to be involved in opioid- and ethanol-induced analgesia.[30] These specific channels have been the target of recent studies dealing with genetic variance and sensitivity to opioid analgesics due to their role in opioid-induced analgesia. Several studies have shown that when opioids are prescribed to treat chronic pain, GIRK channels are activated by certain GPCRs, namely opioid receptors, which leads to the inhibition of nociceptive transmission, thus functioning in pain relief.[31] Furthermore, studies have shown that G proteins, specifically the Gi alpha subunit, directly activate GIRKs which were found to participate in propagation of morphine-induced analgesia in inflamed spines of mice.[32] Research pertaining to chronic pain management continues to be performed in this field.

See also edit

References edit

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March 15, 2024
protein, gated, channel, family, transmembrane, channels, neurons, atrial, myocytes, that, directly, gated, proteins, generalized, diagram, typically, activated, effector, protein, begins, signaling, cascade, which, leads, eventual, opening, channel, bound, su. G protein gated ion channels are a family of transmembrane ion channels in neurons and atrial myocytes that are directly gated by G proteins Generalized diagram of G protein gated ion channel A Typically the activated effector protein begins a signaling cascade which leads to the eventual opening of the ion channel B The GTP bound a subunit in some cases can directly activate the ion channel C In other cases the activated bg complex of the G protein may interact with the ion channel Contents 1 Overview of mechanisms and function 2 Types of G Protein gated ion channels 2 1 Potassium channels 2 1 1 Structure 2 1 2 Subtypes and respective functions 2 2 Calcium channels 2 2 1 Structure 2 2 2 Function 2 3 Sodium channels 2 4 Chloride channels 3 Clinical significance and ongoing research 3 1 Alcohol intoxication 3 2 Breast cancer 3 3 Down syndrome 3 4 Chronic atrial fibrillation 3 5 Pain management 4 See also 5 ReferencesOverview of mechanisms and function editGenerally G protein gated ion channels are specific ion channels located in the plasma membrane of cells that are directly activated by a family of associated proteins Ion channels allow for the selective movement of certain ions across the plasma membrane in cells More specifically in nerve cells along with ion transporters they are responsible for maintaining the electrochemical gradient across the cell G proteins are a family of intracellular proteins capable of mediating signal transduction pathways Each G protein is a heterotrimer of three subunits a b and g subunits The a subunit Ga typically binds the G protein to a transmembrane receptor protein known as a G protein coupled receptor or GPCR This receptor protein has a large extracellular binding domain which will bind its respective ligands e g neurotransmitters and hormones Once the ligand is bound to its receptor a conformational change occurs This conformational change in the G protein allows Ga to bind GTP This leads to yet another conformational change in the G protein resulting in the separation of the bg complex Gbg from Ga 1 At this point both Ga and Gbg are active and able to continue the signal transduction pathway Different classes of G protein coupled receptors have many known functions including the cAMP and Phosphatidylinositol signal transduction pathways 2 A class known as metabotropic glutamate receptors play a large role in indirect ion channel activation by G proteins These pathways are activated by second messengers which initiate signal cascades involving various proteins which are important to the cell s response G protein gated ion channels are associated with a specific type of G protein coupled receptor These ion channels are transmembrane ion channels with selectivity filters and a G protein binding site The GPCRs associated with G protein gated ion channels are not involved in signal transduction pathways They only directly activate these ion channels using effector proteins or the G protein subunits themselves see picture Unlike most effectors not all G protein gated ion channels have their activity mediated by Ga of their corresponding G proteins For instance the opening of inwardly rectifying K GIRK channels is mediated by the binding of Gbg 3 G protein gated ion channels are primarily found in CNS neurons and atrial myocytes and affect the flow of potassium K calcium Ca2 sodium Na and chloride Cl across the plasma membrane 4 Types of G Protein gated ion channels editPotassium channels edit Main article G protein coupled inwardly rectifying potassium channel Structure edit Four G protein gated inwardly rectifying potassium GIRK channel subunits have been identified in mammals GIRK1 GIRK2 GIRK3 and GIRK4 The GIRK subunits come together to form GIRK ion channels These ion channels once activated allow for the flow of potassium ions K from the extracellular space surrounding the cell across the plasma membrane and into the cytoplasm Each channel consists of domains which span the plasma membrane forming the K selective pore region through which the K ions will flow 5 6 Both the N and C terminal ends of the GIRK channels are located within the cytoplasm These domains interact directly with the bg complex of the G protein leading to activation of the K channel 7 These domains on the N and C terminal ends which interact with the G proteins contain certain residues which are critical for the proper activation of the GIRK channel In GIRK4 the N terminal residue is His 64 and the C terminal residue is Leu 268 in GIRK1 they are His 57 and Leu 262 respectively Mutations in these domains lead to the channel s desensitivity to the bg complex and therefore reduce the activation of the GIRK channel 3 The four GIRK subunits are 80 90 similar in their pore forming and transmembrane domains a feature accountable by the similarities in their structures and sequences GIRK2 GIRK3 and GIRK4 share an overall identity of 62 with each other while GIRK1 only shares 44 identity with the others 6 Because of their similarity the GIRK channel subunits can come together easily to form heteromultimers a protein with two or more different polypeptide chains GIRK1 GIRK2 and GIRK3 show abundant and overlapping distribution in the central nervous system CNS while GIRK1 and GIRK4 are found primarily in the heart 4 GIRK1 combines with GIRK2 in the CNS and GIRK4 in the atrium to form heterotetramers each final heterotetramer contains two GIRK1 subunits and two GIRK2 or GIRK4 subunits GIRK2 subunits can also form homotetramers in the brain while GIRK4 subunits can form homotetramers in the heart 7 GIRK1 subunits have not been shown to be able to form functional homotetramers Though GIRK3 subunits are found in the CNS their role in forming functional ion channels is still unknown 4 Subtypes and respective functions edit GIRKs found in the heartOne G protein gated potassium channel is the inward rectifing potassium channel IKACh found in cardiac muscle specifically the sinoatrial node and atria 8 which contributes to the regulation of heart rate 9 These channels are almost entirely dependent on G protein activation making them unique when compared to other G protein gated channels 10 Activation of the IKACh channels begins with release of acetylcholine ACh from the vagus nerve 9 onto pacemaker cells in the heart 10 ACh binds to the M2 muscarinic acetylcholine receptors which interact with G proteins and promote the dissociation of the Ga subunit and Gbg complex 11 IKACh is composed of two homologous GIRK channel subunits GIRK1 and GIRK4 The Gbg complex binds directly and specifically to the IKACh channel through interactions with both the GIRK1 and GIRK4 subunits 12 Once the ion channel is activated K ions flow out of the cell and cause it to hyperpolarize 13 In its hyperpolarized state the neuron cannot fire action potentials as quickly which slows the heartbeat 14 GIRKs found in the brainThe G protein inward rectifying K channel found in the CNS is a heterotetramer composed of GIRK1 and GIRK2 subunits 4 and is responsible for maintaining the resting membrane potential and excitability of the neuron 9 Studies have shown the largest concentrations of the GIRK1 and GIRK2 subunits to be in the dendritic areas of neurons in the CNS 4 These areas which are both extrasynaptic exterior to a synapse and perisynaptic near a synapse correlate with the large concentration of GABAB receptors in the same areas Once the GABAB receptors are activated by their ligands they allow for the dissociation of the G protein into its individual a subunit and bg complex so it can in turn activate the K channels The G proteins couple the inward rectifying K channels to the GABAB receptors mediating a significant part of the GABA postsynaptic inhibition 4 Furthermore GIRKs have been found to play a role in a group of serotonergic neurons in the dorsal raphe nucleus specifically those associated with the neuropeptide hormone orexin 15 The 5 HT1A receptor a serotonin receptor and type of GPCR has been shown to be coupled directly with the a subunit of a G protein while the bg complex activates GIRK without use of a second messenger The subsequent activation of the GIRK channel mediates hyperpolarization of orexin neurons which regulate the release of many other neurotransmitters including noradrenaline and acetylcholine 15 Calcium channels edit Structure edit In addition to the subset of potassium channels that are directly gated by G proteins G proteins can also directly gate certain calcium ion channels in neuronal cell membranes Although membrane ion channels and protein phosphorylation are typically indirectly affected by G protein coupled receptors via effector proteins such as phospholipase C and adenylyl cyclase and second messengers such as inositol triphosphate diacylglycerol and cyclic AMP G proteins can short circuit the second messenger pathway and gate the ion channels directly 16 Such bypassing of the second messenger pathways is observed in mammalian cardiac myocytes and associated sarcolemmal vesicles in which Ca2 channels are able to survive and function in the absence of cAMP ATP or protein kinase C when in the presence of the activated a subunit of the G protein 17 For example Ga which is stimulatory to adenylyl cyclase acts on the Ca2 channel directly as an effector This short circuit is membrane delimiting allowing direct gating of calcium channels by G proteins to produce effects more quickly than the cAMP cascade could 16 This direct gating has also been found in specific Ca2 channels in the heart and skeletal muscle T tubules 18 Function edit Several high threshold slowly inactivating calcium channels in neurons are regulated by G proteins 13 The activation of a subunits of G proteins has been shown to cause rapid closing of voltage dependent Ca2 channels which causes difficulties in the firing of action potentials 1 This inhibition of voltage gated Calcium channels by G protein coupled receptors has been demonstrated in the dorsal root ganglion of a chick among other cell lines 13 Further studies have indicated roles for both Ga and Gbg subunits in the inhibition of Ca2 channels The research geared to defining the involvement of each subunit however has not uncovered the specificity or mechanisms by which Ca2 channels are regulated The acid sensing ion channel ASIC1a is a specific G protein gated Ca2 channel The upstream M1 muscarinic acetylcholine receptor binds to Gq class G proteins Blocking this channel with the agonist oxotremorine methiodide was shown to inhibit ASIC1a currents 19 ASIC1a currents have also been shown to be inhibited in the presence of oxidizing agents and potentiated in the presence of reducing agents A decrease and increase in acid induced intracellular Ca2 accumulation were found respectively 20 Sodium channels edit Patch clamp measurements suggest a direct role for Ga in the inhibition of fast Na current within cardiac cells 21 Other studies have found evidence for a second messenger pathway which may indirectly control these channels 22 Whether G proteins indirectly or directly activate Na ion channels not been defined with complete certainty Chloride channels edit Chloride channel activity in epithelial and cardiac cells has been found to be G protein dependent However the cardiac channel that has been shown to be directly gated by the Ga subunit has not yet been identified As with Na channel inhibition second messenger pathways cannot be discounted in Cl channel activation 23 Studies done on specific Cl channels show differing roles of G protein activation It has been shown that G proteins directly activate one type of Cl channel in skeletal muscle 10 Other studies in CHO cells have demonstrated a large conductance Cl channel to be activated differentially by CTX and PTX sensitive G proteins 10 The role of G proteins in the activation of Cl channels is a complex area of research that is ongoing Clinical significance and ongoing research editMutations in G proteins associated with G protein gated ion channels have been shown to be involved in diseases such as epilepsy muscular diseases neurological diseases and chronic pain among others 4 Epilepsy chronic pain and addictive drugs such as cocaine opioids cannabinoids and ethanol all affect neuronal excitability and heart rate GIRK channels have been shown to be involved in seizure susceptibility cocaine addiction and increased tolerance for pain by opioids cannabinoids and ethanol 24 This connection suggests that GIRK channel modulators may be useful therapeutic agents in the treatment of these conditions GIRK channel inhibitors may serve to treat addictions to cocaine opioids cannabinoids and ethanol while GIRK channel activators may serve to treat withdrawal symptoms 24 Alcohol intoxication edit Alcohol intoxication has been shown to be directly connected to the actions of GIRK channels GIRK channels have a hydrophobic pocket that is capable of binding ethanol the type of alcohol found in alcoholic beverages 25 26 When ethanol acts as an agonist GIRK channels in the brain experience prolonged opening This causes decreased neuronal activity the result of which manifests as the symptoms of alcohol intoxication The discovery of the hydrophobic pocket capable of binding ethanol is significant in the field of clinical pharmacology Agents that can act as agonists to this binding site can be potentially useful in the creation of drugs for the treatment of neurological disorders such as epilepsy in which neuronal firing exceeds normal levels 26 Breast cancer edit Studies have shown that a link exists between channels with GIRK1 subunits and the beta adrenergic receptor pathway in breast cancer cells responsible for growth regulation of the cells Approximately 40 of primary human breast cancer tissues have been found to carry the mRNA which codes for GIRK1 subunits 27 Treatment of breast cancer tissue with alcohol has been shown to trigger increased growth of the cancer cells The mechanism of this activity is still a subject of research 27 Down syndrome edit Altered cardiac regulation is common in adults diagnosed with Down syndrome and may be related to G protein gated ion channels The KCNJ6 gene is located on chromosome 21 and encodes for the GIRK2 protein subunit of G protein gated K channels 28 People with Down Syndrome have three copies of chromosome 21 resulting in an overexpression of the GIRK2 subunit Studies have found that recombinant mice overexpressing GIRK2 subunits show altered responses to drugs that activate G protein gated K channels These altered responses were limited to the sino atrial node and atria both areas which contain many G protein gated K channels 28 Such findings could potentially lead to the development of drugs that can help regulate the cardiac sympathetic parasympathetic imbalance in Down Syndrome adults Chronic atrial fibrillation edit Atrial fibrillation abnormal heart rhythm is associated with shorter action potential duration and believed to be affected by the G protein gated K channel IK ACh 29 The IK ACh channel when activated by G proteins allows for the flow of K across the plasma membrane and out of the cell This current hyperpolarizes the cell thus terminating the action potential It has been shown that in chronic atrial fibrillation there an increase in this inwardly rectifying current because of constantly activated IK ACh channels 29 Increase in the current results in shorter action potential duration experienced in chronic atrial fibrillation and leads to the subsequent fibrillating of the cardiac muscle Blocking IK ACh channel activity could be a therapeutic target in atrial fibrillation and is an area under study Pain management edit GIRK channels have been demonstrated in vivo to be involved in opioid and ethanol induced analgesia 30 These specific channels have been the target of recent studies dealing with genetic variance and sensitivity to opioid analgesics due to their role in opioid induced analgesia Several studies have shown that when opioids are prescribed to treat chronic pain GIRK channels are activated by certain GPCRs namely opioid receptors which leads to the inhibition of nociceptive transmission thus functioning in pain relief 31 Furthermore studies have shown that G proteins specifically the Gi alpha subunit directly activate GIRKs which were found to participate in propagation of morphine induced analgesia in inflamed spines of mice 32 Research pertaining to chronic pain management continues to be performed in this field See also editG protein G protein coupled receptor Metabotropic receptorReferences edit a b Stryer L Berg JM Tymoczko JL 2007 Biochemistry 6th ed San Francisco W H Freeman ISBN 978 0 7167 8724 2 Gilman AG 1987 G Proteins Transducers of Receptor Generated Signals Annual Review of Biochemistry 56 615 49 doi 10 1146 annurev bi 56 070187 003151 PMID 3113327 a b He C Yan X Zhang H Mirshahi T Jin T Huang A Logothetis DE February 2002 Identification of critical residues controlling G protein gated inwardly rectifying K channel activity through interactions with the beta gamma subunits of G proteins The Journal of Biological Chemistry 277 8 6088 96 doi 10 1074 jbc M104851200 PMID 11741896 a b c d e f g Koyrakh L Lujan R Colon J Karschin C Kurachi Y Karschin A Wickman K December 2005 Molecular and cellular diversity of neuronal G protein gated potassium channels The Journal of Neuroscience 25 49 11468 78 doi 10 1523 JNEUROSCI 3484 05 2005 PMC 6725904 PMID 16339040 Neer EJ Clapham DE Jan Feb 1992 Signal transduction through G proteins in the cardiac myocyte Trends in Cardiovascular Medicine 2 1 6 11 doi 10 1016 1050 1738 92 90037 S PMID 21239281 a b Jelacic TM Sims SM Clapham DE May 1999 Functional expression and characterization of G protein gated inwardly rectifying K channels containing GIRK3 The Journal of Membrane Biology 169 2 123 9 doi 10 1007 s002329900524 PMID 10341034 S2CID 13538678 a b Yakubovich D Pastushenko V Bitler A Dessauer CW Dascal N May 2000 Slow modal gating of single G protein activated K channels expressed in Xenopus oocytes The Journal of Physiology 524 Pt 3 737 55 doi 10 1111 j 1469 7793 2000 00737 x PMC 2269908 PMID 10790155 Nikolov EN Ivanova Nikolova TT May 2004 Coordination of membrane excitability through a GIRK1 signaling complex in the atria The Journal of Biological Chemistry 279 22 23630 6 doi 10 1074 jbc M312861200 PMID 15037627 a b c Mark MD Herlitze S October 2000 G protein mediated gating of inward rectifier K channels European Journal of Biochemistry 267 19 5830 6 doi 10 1046 j 1432 1327 2000 01670 x PMID 10998041 a b c d Wickman KD Clapham DE June 1995 G protein regulation of ion channels Current Opinion in Neurobiology 5 3 278 85 doi 10 1016 0959 4388 95 80039 5 PMID 7580149 S2CID 27125330 Ivanova Nikolova TT Nikolov EN Hansen C Robishaw JD August 1998 Muscarinic K channel in the heart Modal regulation by G protein beta gamma subunits The Journal of General Physiology 112 2 199 210 doi 10 1085 jgp 112 2 199 PMC 2525744 PMID 9689027 Corey S Krapivinsky G Krapivinsky L Clapham DE February 1998 Number and stoichiometry of subunits in the native atrial G protein gated K channel IKACh The Journal of Biological Chemistry 273 9 5271 8 doi 10 1074 jbc 273 9 5271 PMID 9478984 a b c Morris AJ Malbon CC October 1999 Physiological regulation of G protein linked signaling Physiological Reviews 79 4 1373 430 doi 10 1152 physrev 1999 79 4 1373 PMID 10508237 S2CID 26873265 Fitzpatrick D Purves D Augustine G 2004 Neuroscience Sunderland Mass Sinauer ISBN 978 0 87893 725 7 a b Nishino S Sakuri T eds 2006 The Orexin Hypocretin System Totowa NJ Humana Press ISBN 978 1 58829 444 9 a b Brown AM Yatani A Imoto Y Kirsch G Hamm H Codina J et al 1988 Direct coupling of G proteins to ionic channels Cold Spring Harbor Symposia on Quantitative Biology 53 1 365 73 doi 10 1101 sqb 1988 053 01 044 PMID 3151174 Yatani A Codina J Imoto Y Reeves JP Birnbaumer L Brown AM November 1987 A G protein directly regulates mammalian cardiac calcium channels Science 238 4831 1288 92 Bibcode 1987Sci 238 1288Y doi 10 1126 science 2446390 PMID 2446390 Brown AM Birnbaumer L March 1988 Direct G protein gating of ion channels The American Journal of Physiology 254 3 Pt 2 H401 10 doi 10 1152 ajpheart 1988 254 3 H401 PMID 2450476 Dorofeeva NA Karpushev AV Nikolaev MV Bolshakov KV Stockand JD Staruschenko A October 2009 Muscarinic M1 modulation of acid sensing ion channels NeuroReport 20 15 1386 91 doi 10 1097 WNR 0b013e3283318912 PMID 19730136 S2CID 36155539 Chu XP Close N Saugstad JA Xiong ZG May 2006 ASIC1a specific modulation of acid sensing ion channels in mouse cortical neurons by redox reagents The Journal of Neuroscience 26 20 5329 39 doi 10 1523 JNEUROSCI 0938 06 2006 PMC 3799800 PMID 16707785 Schubert B VanDongen AM Kirsch GE Brown AM August 1989 Beta adrenergic inhibition of cardiac sodium channels by dual G protein pathways Science 245 4917 516 9 Bibcode 1989Sci 245 516S doi 10 1126 science 2547248 PMID 2547248 Ling BN Kemendy AE Kokko KE Hinton CF Marunaka Y Eaton DC December 1990 Regulation of the amiloride blockable sodium channel from epithelial tissue Molecular and Cellular Biochemistry 99 2 141 50 doi 10 1007 BF00230344 PMID 1962846 S2CID 24533531 Fargon F McNaughton PA Sepulveda FV October 1990 Possible involvement of GTP binding proteins in the deactivation of an inwardly rectifying K current in enterocytes isolated from guinea pig small intestine Pflugers Archiv 417 2 240 2 doi 10 1007 BF00370706 PMID 1707517 S2CID 8807951 a b Kobayashi T Washiyama K Ikeda K October 2004 Modulators of G protein activated inwardly rectifying K channels potentially therapeutic agents for addictive drug users Annals of the New York Academy of Sciences 1025 1 590 4 Bibcode 2004NYASA1025 590K doi 10 1196 annals 1316 073 PMID 15542767 S2CID 26047083 Aryal P Dvir H Choe S Slesinger PA August 2009 A Discrete Alcohol Pocket Involved in GIRK Channel Activation Nature Neuroscience 12 8 988 95 doi 10 1038 nn 2358 PMC 2717173 PMID 19561601 a b Lewohl JM Wilson WR Mayfield RD Brozowski SJ Morrisett RA Harris RA December 1999 G protein coupled inwardly rectifying potassium channels are targets of alcohol action PDF Nature Neuroscience 2 12 1084 90 doi 10 1038 16012 PMID 10570485 S2CID 292545 Archived from the original PDF on 2005 01 23 a b Dhar MS Plummer HK August 2006 Protein expression of G protein inwardly rectifying potassium channels GIRK in breast cancer cells BMC Physiology 6 8 doi 10 1186 1472 6793 6 8 PMC 1574343 PMID 16945134 a b Lignon JM Bichler Z Hivert B Gannier FE Cosnay P del Rio JA et al April 2008 Altered heart rate control in transgenic mice carrying the KCNJ6 gene of the human chromosome 21 Physiological Genomics 33 2 230 9 doi 10 1152 physiolgenomics 00143 2007 PMID 18303085 a b Dobrev D Friedrich A Voigt N Jost N Wettwer E Christ T et al December 2005 The G protein gated potassium current I K ACh is constitutively active in patients with chronic atrial fibrillation Circulation 112 24 3697 706 doi 10 1161 CIRCULATIONAHA 105 575332 PMID 16330682 Marker CL Lujan R Loh HH Wickman K April 2005 Spinal G protein gated potassium channels contribute in a dose dependent manner to the analgesic effect of mu and delta but not kappa opioids The Journal of Neuroscience 25 14 3551 9 doi 10 1523 JNEUROSCI 4899 04 2005 PMC 6725379 PMID 15814785 Nishizawa D Nagashima M Katoh R Satoh Y Tagami M Kasai S et al September 2009 Zanger U ed Association between KCNJ6 GIRK2 Gene Polymorphisms and Postoperative Analgesic Requirements after Major Abdominal Surgery PLOS ONE 4 9 e7060 Bibcode 2009PLoSO 4 7060N doi 10 1371 journal pone 0007060 PMC 2738941 PMID 19756153 Gonzalez Rodriguez S Hidalgo A Baamonde A Menendez L January 2010 Involvement of Gi o proteins and GIRK channels in the potentiation of morphine induced spinal analgesia in acutely inflamed mice Naunyn Schmiedeberg s Archives of Pharmacology 381 1 59 71 doi 10 1007 s00210 009 0471 3 PMID 19940980 S2CID 10134890 Retrieved from https en wikipedia org w index php title G protein gated ion channel amp oldid 1192695746, wikipedia, wiki, book, books, library,

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