G protein-gated ion channel
G protein-gated ion channels are a family of transmembrane ion channels in neurons and atrial myocytes that are directly gated by G proteins.
Overview of mechanisms and function
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 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. 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 from Gα. 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. 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. 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+ channels is mediated by the binding of Gβγ.
G protein-gated ion channels are primarily found in CNS neurons and atrial myocytes, and affect the flow of potassium, calcium, sodium, and chloride across the plasma membrane.
Types of G Protein-gated ion channels
Potassium channels
Structure
Four G protein gated inwardly-rectifying potassium 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 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. 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. . 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.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. Because of their similarity, the GIRK channel subunits can come together easily to form heteromultimers. GIRK1, GIRK2, and GIRK3 show abundant and overlapping distribution in the central nervous system while GIRK1 and GIRK4 are found primarily in the heart. 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. 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.
Subtypes and respective functions
- GIRKs found in the heart
- GIRKs found in the brain
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. 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.
Calcium channels
Structure
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 and second messengers, G proteins can short circuit the second-messenger pathway and gate the ion channels directly. 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. 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. This direct gating has also been found in specific Ca2+ channels in the heart and skeletal muscle T tubules.Function
Several high-threshold, slowly inactivating calcium channels in neurons are regulated by G proteins. 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. 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. 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. 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.
Sodium channels
Patch clamp measurements suggest a direct role for Gα in the inhibition of fast Na+ current within cardiac cells. Other studies have found evidence for a second-messenger pathway which may indirectly control these channels. Whether G proteins indirectly or directly activate Na+ ion channels not been defined with complete certainty.Chloride channels
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.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. Other studies, in CHO cells, have demonstrated a large conductance Cl− channel to be activated differentially by CTX- and PTX-sensitive G proteins. 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
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.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. 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.