Voltage-dependent calcium (Ca2+) channels are involved in many specialized cellular functions, and are controlled by intracellular signals such as heterotrimeric G-proteins, protein kinases and calmodulin (CaM). However, the direct role of small G-proteins in the regulation of Ca2+ channels is unclear. We report here that the GTP-bound form of kir/Gem, identified originally as a Ras-related small G-protein that binds CaM, inhibits high-voltage-activated Ca2+ channel activities by interacting directly with the beta-subunit. The reduced channel activities are due to a decrease in alpha1-subunit expression at the plasma membrane. The binding of Ca2+/CaM to kir/Gem is required for this inhibitory effect by promoting the cytoplasmic localization of kir/Gem. Inhibition of L-type Ca2+ channels by kir/Gem prevents Ca2+-triggered exocytosis in hormone-secreting cells. We propose that the small G-protein kir/Gem, interacting with beta-subunits, regulates Ca2+ channel expression at the cell surface.
The role of small, hydrophobic peptides that are associated with ion pumps or channels is still poorly understood. By using the Xenopus oocyte as an expression system, we have characterized the structural and functional properties of the γ peptide which co‐purifies with Na,K‐ATPase. Immuno‐radiolabeling of epitope‐tagged γ subunits in intact oocytes and protease protection assays show that the γ peptide is a type I membrane protein lacking a signal sequence and exposing the N‐terminus to the extracytoplasmic side. Co‐expression of the rat or Xenopus γ subunit with various proteins in the oocyte reveals that it specifically associates only with isozymes of Na,K‐ATPase. The γ peptide does not influence the formation and cell surface expression of functional Na,K‐ATPase α–β complexes. On the other hand, the γ peptide itself needs association with Na,K‐ATPase in order to be stably expressed in the oocyte and to be transported efficiently to the plasma membrane. γ subunits do not associate with individual α or β subunits but only interact with assembled, transport‐competent α–β complexes. Finally, electrophysiological measurements indicate that the γ peptide modulates the K+ activation of Na,K pumps. These data document for the first time the membrane topology, the specificity of association and a potential functional role for the γ subunit of Na,K‐ATPase.
The biological role of small membrane proteins of the new FXYD family is largely unknown. The best characterized FXYD protein is the γ‐subunit of the Na,K‐ATPase (NKA) that modulates the Na,K‐pump function in the kidney. Here, we report that, similarly to γa and γb splice variants, the FXYD protein CHIF (corticosteroid‐induced factor) is a type I membrane protein which is associated with NKA in renal tissue, and modulates the Na,K‐pump transport when expressed in Xenopus oocytes. In contrast to γa and γb, which both decrease the apparent Na+ affinity of the Na,K‐pump, CHIF significantly increases the Na+ affinity and decreases the apparent K+ affinity due to an increased Na+ competition at external binding sites. The extracytoplasmic FXYD motif is required for stable γ‐subunit and CHIF interaction with NKA, while cytoplasmic, positively charged residues are necessary for the γ‐subunit's association efficiency and for CHIF's functional effects. These data document that CHIF is a new tissue‐specific regulator of NKA which probably plays a crucial role in aldosterone‐responsive tissues responsible for the maintenance of body Na+ and K+ homeostasis.
Individual members of the RGK family of Ras-related GTPases, which comprise Rad, Gem/Kir, Rem and Rem2, have been implicated in important functions such as the regulation of voltage-gated calcium channel activity and remodeling of cell shape. The GTPase Kir/Gem inhibits the activity of calcium channels by interacting with the β-subunit and also regulates cytoskeleton dynamics by inhibiting the Rho-Rho kinase pathway. In addition, Kir/Gem interacts with 14-3-3 and calmodulin, but the significance of this interaction on Kir/Gem function is poorly understood. Here, we present a comprehensive analysis of the binding of 14-3-3 and calmodulin to Kir/Gem. We show that 14-3-3, in conjunction with calmodulin, regulates the subcellular distribution of Kir/Gem between the cytoplasm and the nucleus. In addition, 14-3-3 and calmodulin binding modulate Kir/Gem-mediated cell shape remodeling and downregulation of calcium channel activity. Competition experiments show that binding of 14-3-3, calmodulin and calcium channel β-subunits to Kir/Gem is mutually exclusive, providing a rationale for the observed regulatory effects of 14-3-3 and calmodulin on Kir/Gem localization and function.
kir/Gem, Rad, Rem and Rem2 comprise the RGK (Rad/Gem/kir) family of Ras-related small G-proteins. Two important functions of RGK proteins are the regulation of the VDCC (voltage-dependent Ca2+ channel) activity and cell-shape remodelling. RGK proteins interact with 14-3-3 and CaM (calmodulin), but their role on RGK protein function is poorly understood. In contrast with the other RGK family members, Rem2 has been reported to bind neither 14-3-3 nor induce membrane extensions. Furthermore, although Rem2 inhibits VDCC activity, it does not prevent cell-surface transport of Ca2+ channels as has been shown for kir/Gem. In the present study, we re-examined the functions of Rem2 and its interaction with 14-3-3 and CaM. We show that Rem2 in fact does interact with 14-3-3 and CaM and induces dendrite-like extensions in COS cells. 14-3-3, together with CaM, regulates the subcellular distribution of Rem2 between the cytoplasm and the nucleus. Rem2 also interacts with the beta-subunits of VDCCs in a GTP-dependent fashion and inhibits Ca2+ channel activity by blocking the alpha-subunit expression at the cell surface. Thus Rem2 shares many previously unrecognized features with the other RGK family members.
ATP-sensitive potassium (K(ATP)) channels play important roles in many cellular functions such as hormone secretion and excitability of muscles and neurons. Classical ATP-sensitive potassium (K(ATP)) channels are heteromultimeric membrane proteins comprising the pore-forming Kir6.2 subunits and the sulfonylurea receptor subunits (SUR1 or SUR2). The molecular mechanism by which hormones and neurotransmitters modulate K(ATP) channels via protein kinase A (PKA) is poorly understood. We mutated the PKA consensus sequences of the human SUR1 and Kir6.2 subunits and tested their phosphorylation capacities in Xenopus oocyte homogenates and in intact cells. We identified the sites responsible for PKA phosphorylation in the C-terminus of Kir6.2 (S372) and SUR1 (S1571). Kir6.2 can be phosphorylated at its PKA phosphorylation site in intact cells after G-protein (Gs)-coupled receptor or direct PKA stimulation. While the phosphorylation of Kir6.2 increases channel activity, the phosphorylation of SUR1 contributes to the basal channel properties by decreasing burst duration, interburst interval and open probability, and also increasing the number of functional channels at the cell surface. Moreover, the effect of PKA could be mimicked by introducing negative charges in the PKA phosphorylation sites. These data demonstrate direct phosphorylation by PKA of the K(ATP) channel, and may explain the mechanism by which Gs-coupled receptors stimulate channel activity. Importantly, they also describe a model of heteromultimeric ion channels in which there are functionally distinct roles of the phosphorylation of the different subunits.
P.Be Âguin and G.Crambert contributed equally to this workRecently, corticosteroid hormone-induced factor (CHIF) and the g-subunit, two members of the FXYD family of small proteins, have been identi®ed as regulators of renal Na,K-ATPase. In this study, we have investigated the tissue distribution and the structural and functional properties of FXYD7, another family member which has not yet been characterized. Expressed exclusively in the brain, FXYD7 is a type I membrane protein bearing N-terminal, post-translationally added modi®cations on threonine residues, most probably O-glycosylations that are important for protein stabilization. Expressed in Xenopus oocytes, FXYD7 can interact with Na,K-ATPase a1±b1, a2±b1 and a3±b1 but not with a±b2 isozymes, whereas, in brain, it is only associated with a1±b isozymes. FXYD7 decreases the apparent K + af®nity of a1±b1 and a2±b1, but not of a3±b1 isozymes. These data suggest that FXYD7 is a novel, tissue-and isoformspeci®c Na,K-ATPase regulator which could play an important role in neuronal excitability.
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