Diverse trafficking patterns due to multiple traffic motifs in G protein-activated inwardly rectifying potassium channels from brain and heart

G protein-activated inwardly rectifying potassium channels (Kir3, GIRK) provide an important mechanism for neurotransmitter regulation of membrane excitability. GIRK channels are tetramers containing various combinations of Kir3 subunits (Kir3.1--Kir3.4). We find that different combinations of Kir3 subunits exhibit a surprisingly complex spectrum of trafficking phenotypes. Kir3.2 and Kir3.4, but not Kir3.1, contain ER export signals that are important for plasma membrane expression of Kir3.1/Kir3.2 and Kir3.1/Kir3.4 heterotetramers, the GIRK channels found in the brain and the heart, respectively. Additional motifs in Kir3.2 and Kir3.4 control the trafficking between endosome and plasma membrane. In contrast, the Kir3.3 subunit potently inhibits plasma membrane expression by diverting the heterotetrameric channels to lysosomes. Such rich trafficking behaviors provide a mechanism for dynamic regulation of GIRK channel density in the plasma membrane.     

Intracellular trafficking and assembly of specific Kir3 channel/G protein complexes

We have previously demonstrated that Kir3.1 channels and Gβ1γ2 subunits initially interact in the endoplasmic reticulum (ER). To elucidate the role that anterograde protein trafficking pathways may play in the formation of these complexes, we used dominant negative (DN) mutants of the small G proteins Sar 1 and various compartment-specific Rabs which impede anterograde protein trafficking at different steps. Sar 1 H79G and Rab 1 S25N mutants efficiently blocked the plasma membrane trafficking of the Kir3.1/Kir3.4 complex however they did not block the Gβ1γ2/Kir3.1 interaction as measured using bioluminescence resonance energy transfer (BRET). This interaction was also insensitive to the presence of DN Rabs 2, 6, 8, and 11. These results confirm that Gβγ/Kir3 complexes form early during channel biosynthesis and trafficking. Using a combination of BRET, protein complementation assays and co-immunoprecipitation, we demonstrate that Gβ1-4 can interact with Kir3.1 in the absence of Kir3.4. Gβ5 does not directly interact with the channel but can still be co-immunoprecipated as part of a larger complex. The interaction between Gβ and Kir3.1 was selectively fostered by co-expression with different Gγ subunits. When Gγ1 or Gγ11 was co-expressed with eGFP-Gβ3 or eGFP-Gβ4, the interaction with the effector was lost. Kir3.2 was capable of interacting with Gβ1-3 and not Gβ4 or Gβ5. These interactions were again fostered by co-expression with Gγ and were also insensitive to DN Sar 1 or Rab 1. Taken together, our data show that these “precocious” channel/G protein interactions are specific and may have implications beyond their basic function in signalling events.     

Kir2.6 regulates the surface expression of Kir2.x inward rectifier potassium channels

Precise trafficking, localization, and activity of inward rectifier potassium Kir2 channels are important for shaping the electrical response of skeletal muscle. However, how coordinated trafficking occurs to target sites remains unclear. Kir2 channels are tetrameric assemblies of Kir2.x subunits. By immunocytochemistry we show that endogenous Kir2.1 and Kir2.2 are localized at the plasma membrane and T-tubules in rodent skeletal muscle. Recently, a new subunit, Kir2.6, present in human skeletal muscle, was identified as a gene in which mutations confer susceptibility to thyrotoxic hypokalemic periodic paralysis. Here we characterize the trafficking and interaction of wild type Kir2.6 with other Kir2.x in COS-1 cells and skeletal muscle in vivo. Immunocytochemical and electrophysiological data demonstrate that Kir2.6 is largely retained in the endoplasmic reticulum, despite high sequence identity with Kir2.2 and conserved endoplasmic reticulum and Golgi trafficking motifs shared with Kir2.1 and Kir2.2. We identify amino acids responsible for the trafficking differences of Kir2.6. Significantly, we show that Kir2.6 subunits can coassemble with Kir2.1 and Kir2.2 in vitro and in vivo. Notably, this interaction limits the surface expression of both Kir2.1 and Kir2.2. We provide evidence that Kir2.6 functions as a dominant negative, in which incorporation of Kir2.6 as a subunit in a Kir2 channel heterotetramer reduces the abundance of Kir2 channels on the plasma membrane.     

Surface expression of inward rectifier potassium channels is controlled by selective Golgi export

Traffic of integral membrane proteins along the secretory pathway is not simply a default process but can be selective. Such selectivity is achieved by sequence information within the cargo protein that recruits coat protein complexes to drive the formation of transport vesicles. A number of sequence motifs have been identified in the cytoplasmic domains of ion channels that regulate early trafficking events between the endoplasmic reticulum and the Golgi complex. Here, we demonstrate that the following trafficking step from the Golgi compartment to the plasma membrane can also be selective. The N-terminal domain of the inward rectifier potassium channel Kir2.1 contains specific sequence information that is necessary for its efficient export from the Golgi complex. Lack of this information results in accumulation of the protein within the Golgi and a significant decrease in cell surface expression. As similar results were obtained for the N terminus of another Kir channel subfamily member, Kir4.1, which could functionally substitute for the Kir2.1 N terminus, we propose a more general role of the identified N-terminal domains for post-Golgi trafficking of Kir channels.     

Identification of MarvelD3 as a tight junction-associated transmembrane protein of the occludin family

Background

Protein translocation across the membrane of the Endoplasmic Reticulum (ER) is the first step in the biogenesis of secretory and membrane proteins. Proteins enter the ER by the Sec61 translocon, a proteinaceous channel composed of three subunits, α, β and γ. While it is known that Sec61α forms the actual channel, the function of the other two subunits remains to be characterized.

Results

In the present study we have investigated the function of Sec61β in Drosophila melanogaster. We describe its role in the plasma membrane traffic of Gurken, the ligand for the Epidermal Growth Factor (EGF) receptor in the oocyte. Germline clones of the mutant allele of Sec61β show normal translocation of Gurken into the ER and transport to the Golgi complex, but further traffic to the plasma membrane is impeded. The defect in plasma membrane traffic due to absence of Sec61β is specific for Gurken and is not due to a general trafficking defect.

Conclusion

Based on our study we conclude that Sec61β, which is part of the ER protein translocation channel affects a post-ER step during Gurken trafficking to the plasma membrane. We propose an additional role of Sec61β beyond protein translocation into the ER.     

Endosomal KATP channels as a reservoir after myocardial ischemia: a role for SUR2 subunits

ATP-sensitive K(+) (K(ATP)) channels, composed of inward rectifier K(+) (Kir)6.x and sulfonylurea receptor (SUR)x subunits, are expressed on cellular plasma membranes. We demonstrate an essential role for SUR2 subunits in trafficking K(ATP) channels to an intracellular vesicular compartment. Transfection of Kir6.x/SUR2 subunits into a variety of cell lines (including h9c2 cardiac cells and human coronary artery smooth muscle cells) resulted in trafficking to endosomal/lysosomal compartments, as assessed by immunofluorescence microscopy. By contrast, SUR1/Kir6.x channels efficiently localized to the plasmalemma. The channel turnover rate was similar with SUR1 or SUR2, suggesting that the expression of Kir6/SUR2 proteins in lysosomes is not associated with increased degradation. Surface labeling of hemagglutinin-tagged channels demonstrated that SUR2-containing channels dynamically cycle between endosomal and plasmalemmal compartments. In addition, Kir6.2 and SUR2 subunits were found in both endosomal and sarcolemmal membrane fractions isolated from rat hearts. The balance of these K(ATP) channel subunits shifted to the sarcolemmal membrane fraction after the induction of ischemia. The K(ATP) channel current density was also increased in rat ventricular myocytes isolated from hearts rendered ischemic before cell isolation without corresponding changes in subunit mRNA expression. We conclude that an intracellular pool of SUR2-containing K(ATP) channels exists that is derived by endocytosis from the plasma membrane. In cardiac myocytes, this pool can potentially play a cardioprotective role by serving as a reservoir for modulating surface K(ATP) channel density under stress conditions, such as myocardial ischemia.     

Secretagogue-induced exocytosis recruits G protein-gated K+ channels to plasma membrane in endocrine cells

Stimulation-regulated fusion of vesicles to the plasma membrane is an essential step for hormone secretion but may also serve for the recruitment of functional proteins to the plasma membrane. While studying the distribution of G protein-gated K+ (KG) channels in the anterior pituitary lobe, we found KG channel subunits Kir3.1 and Kir3.4 localized on the membranes of intracellular dense core vesicles that contained thyrotropin. Stimulation of these thyrotroph cells with thyrotropin-releasing hormone provoked fusion of vesicles to the plasma membrane, increased expression of Kir3.1 and Kir3.4 subunits in the plasma membrane, and markedly enhanced KG currents stimulated by dopamine and somatostatin. These data indicate a novel mechanism for the rapid insertion of functional ion channels into the plasma membrane, which could form a new type of negative feedback control loop for hormone secretion in the endocrine system.     

A role of the sulfonylurea receptor 1 in endocytic trafficking of ATP-sensitive potassium channels

The ATP-sensitive potassium (K(ATP) ) channel consisting of sulfonylurea receptor 1 (SUR1) and inward-rectifier potassium channel 6.2 (Kir6.2) has a well-established role in insulin secretion. Mutations in either subunit can lead to disease due to aberrant channel gating, altered channel density at the cell surface or a combination of both. Endocytic trafficking of channels at the plasma membrane is one way to influence surface channel numbers. It has been previously reported that channel endocytosis is dependent on a tyrosine-based motif in Kir6.2, while SUR1 alone is unable to internalize. In this study, we followed endocytic trafficking of surface channels in real time by live-cell imaging of channel subunits tagged with an extracellular minimal α-bungarotoxin-binding peptide labeled with a fluorescent dye. We show that SUR1 undergoes endocytosis independent of Kir6.2. Moreover, mutations in the putative endocytosis motif of Kir6.2, Y330C, Y330A and F333I are unable to prevent channel endocytosis. These findings challenge the notion that Kir6.2 bears the sole endocytic signal for K(ATP) channels and support a role of SUR1 in this trafficking process.     

Regulation of KATP Channel Expression and Activity by the SUR1 Nucleotide Binding Fold 1

ATP-sensitive K+ (KATP) channels are oligomeric complexes of pore-forming Kir6 subunits and regulatory Sulfonylurea Receptor (SUR) subunits. SUR, an ATP-Binding Cassette (ABC) transporter, confers Mg-nucleotide stimulation to the channel via nucleotide interactions with its two cytoplasmic domains (Nucleotide Binding Folds 1 and 2; NBF1 and NBF2). Regulation of KATP channel expression is a complex process involving subunit assembly in the ER, SUR glycosylation in the Golgi, and trafficking to the plasma membrane. Dysregulation can occur at different steps of the pathway, as revealed by disease-causing mutations. Here, we have addressed the role of SUR1 NBF1 in gating and expression of reconstituted channels. Deletion of NBF1 severely impairs channel expression and abolishes MgADP stimulation. Total SUR1 protein levels are decreased, suggestive of increased protein degradation, but they are not rescued by treatment with sulfonylureas or the proteasomal inhibitor MG-132. Similar effects of NBF1 deletion are observed in recombinant KATP channels obtained by "splitting" SUR1 into two separate polypeptides (a N-terminal "half" and a C-terminal "half"). Interestingly, the location of the "splitting point" in the vicinity of NBF1 has marked effects on the MgADP stimulation of resulting channels. Finally, ablation of the ER retention motif upstream of NBF1 (in either "split" or full-length SUR1) does not rescue expression of channels lacking NBF1. These results indicate that, in addition to NBF1 being required for MgADP stimulation of the channel, it plays an important role in the regulation of channel expression that is independent of the ER retention checkpoint and the proteasomal degradation pathway.     

A phosphorylation-dependent export structure in ROMK (Kir 1.1) channel overrides an endoplasmic reticulum localization signal

The cell surface density of functional Kir1.1 (ROMK, KCNJ1) channels in the renal collecting duct is precisely regulated to maintain potassium balance. Here, we explore the mechanism by which phosphorylation of Kir1.1a serine 44 controls plasmalemma expression. Studies in Xenopus oocytes, expressing wild-type, phosphorylation mimic (S44D), or phosphorylation null (S44A) Kir1.1a, revealed that phosphorylation of serine 44 is required to stimulate traffic of newly synthesized channels to the plasma membrane through a brefeldin A-sensitive pathway. ROMK channels were found to acquire mature glycosylation in a serine 44 phosphorylation-dependent manner, consistent with a phosphorylation-dependent trafficking step within the endoplasmic reticulum/Golgi. Serine 44 neighbors a string of three "RXR" motifs, reminiscent of basic trafficking signals involved in directing early transport steps within the secretory pathway. Replacement of the arginine residues with alanine (R35A, R37A, R39A, R41A, or all Arg to Ala) did not restore cell surface expression of the phospho-null S44A channel, making it unlikely that phosphorylation abrogates a nearby RXR-type endoplasmic reticulum (ER) localization signal. Instead, analysis of the compound S44D phospho-mimic mutants revealed that the neighboring arginine residues are also necessary for cell surface expression, identifying a structure that determines export in the biosynthetic pathway. Suppressor mutations in a putative dibasic ER retention signal, located within the cytoplasmic C terminus (K370A, R371A), restored cell surface expression of the phospho-null S44A channel to levels exhibited by the phospho-mimic S44D channel. Taken together, these studies indicate that phosphorylation of Ser44 drives an export step within the secretory pathway to override an independent endoplasmic reticulum localization signal.     

Involvement of Golgin-160 in cell surface transport of renal ROMK channel: co-expression of Golgin-160 increases ROMK currents.

The weak inward rectifier potassium channel ROMK is important for water and salt reabsorption in the kidney. Here we identified Golgin-160 as a novel interacting partner of the ROMK channel. By using yeast two-hybrid assays and co-immunoprecipitations from transfected cells, we demonstrate that Golgin-160 associates with the ROMK C-terminus. Immunofluorescence microscopy confirmed that both proteins are co-localized in the Golgi region. The interaction was further confirmed by the enhancement of ROMK currents by the co-expressed Golgin-160 in Xenopus oocytes. The increase in ROMK current amplitude was due to an increase in cell surface density of ROMK protein. Golgin-160 also stimulated current amplitudes of the related Kir2.1, and of voltage-gated Kv1.5 and Kv4.3 channels, but not the current amplitude of co-expressed HERG channel. These results demonstrate that the Golgi-associated Golgin-160 recognizes the cytoplasmic C-terminus of ROMK, thereby facilitating the transport of ROMK to the cell surface. However, the stimulatory effect on the activity of more distantly-related potassium channels suggests a more general role of Golgin-160 in the trafficking of plasma membrane proteins.     

Adjacent basic amino acid residues recognized by the COP I complex and ubiquitination govern endoplasmic reticulum to cell surface trafficking of the nicotinic acetylcholine receptor alpha-Subunit

The nicotinic acetylcholine receptor in muscle is a ligand-gated ion channel with an ordered subunit arrangement of alpha-gamma-alpha-delta-beta. The subunits are sequestered in the endoplasmic reticulum (ER) and assembled into the pentameric arrangement prior to their exit to the cell surface. Mutating the Arg(313)-Lys(314) sequence in the large cytoplasmic loop of the alpha-subunit to K314Q promotes the trafficking of the mutant unassembled alpha-subunit from the ER to the Golgi in transfected HEK cells, identifying an important determinant that modulates the ER to Golgi trafficking of the subunit. The association of the K314Q alpha-subunit with gamma-COP, a component of COP I coats implicated in Golgi to ER anterograde transport, is diminished to a level comparable to that observed for wild-type alpha-subunits when co-expressed with the beta-, delta-, and gamma-subunits. This suggests that the Arg(313)-Lys(314) sequence is masked when the subunits assemble, thereby enabling ER to Golgi trafficking of the alpha-subunit. Although unassembled K314Q alpha-subunits accumulate in the Golgi, they are not detected at the cell surface, suggesting that a second post-Golgi level of capture exists. Expressing the K314Q alpha-subunit in the absence of the other subunits in ubiquitinating deficient cells (ts20) results in detecting this subunit at the cell surface, indicating that ubiquitination functions as a post-Golgi modulator of trafficking. Taken together, our findings support the hypothesis that subunit assembly sterically occludes the trafficking signals and ubiquitination at specific sites. Following the masking of these signals, the assembled ion channel expresses at the cell surface.     

Distribution of the muscarinic K+ channel proteins Kir3.1 and Kir3.4 in the ventricle, atrium, and sinoatrial node of heart.

The functionally important effects on the heart of ACh released from vagal nerves are principally mediated by the muscarinic K+ channel. The aim of this study was to determine the abundance and cellular location of the muscarinic K+ channel subunits Kir3.1 and Kir3.4 in different regions of heart. Western blotting showed a very low abundance of Kir3.1 in rat ventricle, although Kir3.1 was undetectable in guinea pig and ferret ventricle. Although immunofluorescence on tissue sections showed no labeling of Kir3.1 in rat, guinea pig, and ferret ventricle and Kir3.4 in rat ventricle, immunofluorescence on single ventricular cells from rat showed labeling in t-tubules of both Kir3.1 and Kir3.4. Kir3.1 was abundant in the atrium of the three species, as shown by Western blotting and immunofluorescence, and Kir3.4 was abundant in the atrium of rat, as shown by immunofluorescence. Immunofluorescence showed Kir3.1 expression in SA node from the three species and Kir3.4 expression in the SA node from rat. The muscarinic K+ channel is activated by ACh via the m2 muscarinic receptor and, in atrium and SA node from ferret, Kir3.1 labeling was co-localized with m2 muscarinic receptor labeling throughout the outer cell membrane.     

Identification and characterization of site‐specific N‐glycosylation in the potassium channel Kv3.1b

The potassium ion channel Kv3.1b is a member of a family of voltage‐gated ion channels that are glycosylated in their mature form. In the present study, we demonstrate the impact of N‐glycosylation at specific asparagine residues on the trafficking of the Kv3.1b protein. Large quantities of asparagine 229 (N229)‐glycosylated Kv3.1b reached the plasma membrane, whereas N220‐glycosylated and unglycosylated Kv3.1b were mainly retained in the endoplasmic reticulum (ER). These ER‐retained Kv3.1b proteins were susceptible to degradation, when co‐expressed with calnexin, whereas Kv3.1b pools located at the plasma membrane were resistant. Mass spectrometry analysis revealed a complex type Hex₃HexNAc₄Fuc₁ glycan as the major glycan component of the N229‐glycosylated Kv3.1b protein, as opposed to a high‐mannose type Man₈GlcNAc₂ glycan for N220‐glycosylated Kv3.1b. Taken together, these results suggest that trafficking‐dependent roles of the Kv3.1b potassium channel are dependent on N229 site‐specific glycosylation and N‐glycan structure, and operate through a mechanism whereby specific N‐glycan structures regulate cell surface expression.     

COPI-mediated retrograde trafficking from the Golgi to the ER regulates EGFR nuclear transport

Emerging evidence indicates that cell surface receptors, such as the entire epidermal growth factor receptor (EGFR) family, have been shown to localize in the nucleus. A retrograde route from the Golgi to the endoplasmic reticulum (ER) is postulated to be involved in the EGFR trafficking to the nucleus; however, the molecular mechanism in this proposed model remains unexplored. Here, we demonstrate that membrane-embedded vesicular trafficking is involved in the nuclear transport of EGFR. Confocal immunofluorescence reveals that in response to EGF, a portion of EGFR redistributes to the Golgi and the ER, where its NH₂-terminus resides within the lumen of Golgi/ER and COOH-terminus is exposed to the cytoplasm. Blockage of the Golgi-to-ER retrograde trafficking by brefeldin A or dominant mutants of the small GTPase ADP-ribosylation factor, which both resulted in the disassembly of the coat protein complex I (COPI) coat to the Golgi, inhibit EGFR transport to the ER and the nucleus. We further find that EGF-dependent nuclear transport of EGFR is regulated by retrograde trafficking from the Golgi to the ER involving an association of EGFR with γ-COP, one of the subunits of the COPI coatomer. Our findings experimentally provide a comprehensive pathway that nuclear transport of EGFR is regulated by COPI-mediated vesicular trafficking from the Golgi to the ER, and may serve as a general mechanism in regulating the nuclear transport of other cell surface receptors.     

Functional expression of the pore forming subunit of the ATP-sensitive potassium channel in Saccharomyces cerevisiae

We have expressed the pore-forming subunits (Kir 6.1 and Kir 6.2) of the mammalian ATP-sensitive potassium channel in a potassium-transport deficient yeast strain (trk1 trk2). Functional expression of Kir 6.2 and Kir 6.1 can complement growth deficiency weakly and strongly respectively of the yeast strain on low-potassium medium. Mutations of Kir 6.2 that abolish ATP sensitivity (K185Q, I182Q) and enhance trafficking to the plasma membrane surface (Kir 6.2DeltaC36) lead to significantly better growth rescue. Growth rescue of Kir 6.1, Kir 6.2 and the above mutants can be inhibited by pharmacological agents (cesium ions, phentolamine and quinine) known to decrease channel activity by direct interaction with the pore forming subunit. Thus we have developed a system in yeast that can report both loss and gain of function mutations in these subunits and pharmacological interventions.     

Identification and pharmacological correction of a membrane trafficking defect associated with a mutation in the sulfonylurea receptor causing familial hyperinsulinism.

Persistent hyperinsulinemic hypoglycemia of infancy (PHHI) is a genetic disorder characterized by excess secretion of insulin and hypoglycemia. In most patients, the disease is caused by mutations in sulfonylurea receptor-1 (SUR1), which, in association with Kir6.2, constitutes the functional ATP-sensitive potassium (K(ATP)) channel of the pancreatic beta-cell. Previous studies reported that coexpression of the PHHI mutant R1394H-SUR1 with Kir6.2 in COS cells produces no functional channels. To investigate if the loss of function could be due to impaired trafficking of mutant channels to the cell membrane, we have cotransfected wild-type and mutant SUR1 subunits with Kir6.2 into HEK293 cells and examined their cellular localization by immunofluorescent staining. Our results show that unlike the wild-type subunits, which showed fluorescence at the cell surface, the mutant subunits displayed fluorescence in punctate structures. Co-immunostaining with antibodies against organelle-specific marker proteins identified these structures as the trans-Golgi network. Limited localization in clathrin-positive, but transferrin receptor-negative vesicles was also observed. The post-endoplasmic reticulum localization suggests that the mutation does not impair the folding and assembly of the channels so as to cause its retention by the endoplasmic reticulum. Diazoxide, a K(ATP) channel opener drug that is used in the treatment of PHHI, restored the surface expression in a manner that could be prevented by the channel blocker glibenclamide. When expressed in Xenopus oocytes, R1394H-SUR1 formed functional channels with Kir6.2, indicating that the primary consequence of the mutation is impairment of trafficking rather than function. Thus, our data uncover a novel mechanism underlying the therapeutic action of diazoxide in the treatment of PHHI, i.e. its ability to recruit channels to the membrane. Furthermore, this is the first report to describe a trafficking disorder effecting retention of mutant proteins in the trans-Golgi network.     

Expression of ATP sensitive K+ channel subunit Kir6.1 in rat kidney

ATP-sensitive K+ (K(ATP)) channels in kidney are considered to play roles in regulating membrane potential during the change in intracellular ATP concentration. They are composed of channel subunits (Kir6.1, Kir6.2), which are members of the inwardly rectifying K+ channel family, and sulphonylurea receptors (SUR1, SUR2A and SUR2B), which belong to the ATP-binding cassette superfamily. In the present study, we have investigated the expression and localization of Kir6.1 in rat kidney with Western blot analysis, immunohistochemistry, in situ hybridization histochemistry, and immunoelectron microscopy. Western blot analysis showed that Kir6.1 was expressed in the mitochondria and microsome fractions of rat kidney and very weakly in the membrane fractions. Immunohistochemistry revealed that Kir6.1 was widely distributed in renal tubular epithelial cells, glomerular mesangial cells, and smooth muscles of blood vessels. In immunoelectron microscopy, Kir6.1 is mainly localized in the mitochondria, endoplasmic reticulum (ER), and very weakly in cell membranes. Thus, Kir6.1 is contained in the kidney and may be a candidate of mitochondrial K(ATP) channels.     

KCNE1 subunits require co-assembly with K+ channels for efficient trafficking and cell surface expression

KCNE peptides are a class of type I transmembrane beta subunits that assemble with and modulate the gating and ion conducting properties of a variety of voltage-gated K(+) channels. Accordingly, mutations that disrupt the assembly and trafficking of KCNE-K(+) channel complexes give rise to disease. The cellular mechanisms responsible for ensuring that KCNE peptides assemble with voltage-gated K(+) channels have yet to be elucidated. Using enzymatic deglycosylation, immunofluorescence, and quantitative cell surface labeling experiments, we show that KCNE1 peptides are retained in the early stages of the secretory pathway until they co-assemble with specific K(+) channel subunits; co-assembly mediates KCNE1 progression through the secretory pathway and results in cell surface expression. We also address an apparent discrepancy between our results and a previous study in human embryonic kidney cells, which showed wild type KCNE1 peptides can reach the plasma membrane without exogenously expressed K(+) channel subunits. By comparing KCNE1 trafficking in three cell lines, our data suggest that the errant KCNE1 trafficking observed in human embryonic kidney cells may be due, in part, to the presence of endogenous voltage-gated K(+) channels in these cells.     

Functional Consequences of the Interactions among the Neural Cell Adhesion Molecule NCAM,the Receptor Tyrosine Kinase TrkB,and the Inwardly Rectifying K+ Channel KIR3.3

Cell adhesion molecules and neurotrophin receptors are crucial for the development and the function of the nervous system. Among downstream effectors of neurotrophin receptors and recognition molecules are ion channels. Here, we provide evidence that G protein-coupled inwardly rectifying K⁺ channel Kir3.3 directly binds to the neural cell adhesion molecule (NCAM) and neurotrophin receptor TrkB. We identified the binding sites for NCAM and TrkB at the C-terminal intracellular domain of Kir3.3. The interaction between NCAM, TrkB, and Kir3.3 was supported by immunocytochemical co-localization of Kir3.3, NCAM, and/or TrkB at the surface of hippocampal neurons. Co-expression of TrkB and Kir3.1/3.3 in Xenopus oocytes increased the K⁺ currents evoked by Kir3.1/3.3 channels. This current enhancement was reduced by the concomitant co-expression with NCAM. Both surface fluorescence measurements of microinjected oocytes and cell surface biotinylation of transfected CHO cells indicated that the cell membrane localization of Kir3.3 is regulated by TrkB and NCAM. Furthermore, the level of Kir3.3, but not of Kir3.2, at the plasma membranes was reduced in TrkB-deficient mice, supporting the notion that TrkB regulates the cell surface expression of Kir3.3. The premature expression of developmentally late appearing Kir3.1/3.3 in hippocampal neurons led to a reduction of NCAM-induced neurite outgrowth. Our observations indicate a decisive role for the neuronal K⁺ channel in regulating NCAM-dependent neurite outgrowth and attribute a physiologically meaningful role to the functional interplay of Kir3.3, NCAM, and TrkB in ontogeny.