Glutamate 268 regulates transport probability of the anion/proton exchanger ClC-5

The Cl(-)/H(+) exchange mediated by ClC transporters can be uncoupled by external SCN(-) and mutations of the proton glutamate, a conserved residue at the internal side of the protein. We show here for the mammalian ClC transporter ClC-5 that acidic internal pH led to a greater increase in currents upon exchanging extracellular Cl(-) for SCN(-). However, transport uncoupling, unitary current amplitudes, and the voltage dependence of the depolarization-induced activation were not altered by low pH values. Therefore, it is likely that an additional gating process regulates ClC-5 transport. Higher internal [H(+)] and the proton glutamate mutant E268H altered the ratio between ClC-5 transport and nonlinear capacitance, indicating that the gating charge movements in ClC-5 arise from incomplete transport cycles and that internal protons increase the transport probability of ClC-5. This was substantiated by site-directed sulfhydryl modification of the proton glutamate mutant E268C. The mutation exhibited small transport currents together with prominent gating charge movements. The charge restoration using a negatively charged sulfhydryl reagent reinstated also the WT phenotype. Neutralization of the charge of the gating glutamate 211 by the E211C mutation abolished the effect of internal protons, showing that the increased transport probability of ClC-5 results from protonation of this residue. S168P (a mutation that decreases the anion affinity of the central binding site) reduced also the internal pH dependence of ClC-5. These results support the idea that protonation of the gating glutamate 211 at the central anion-binding site of ClC-5 is mediated by the proton glutamate 268.     

An internalization signal in ClC-5, an endosomal Cl-channel mutated in dent's disease

The ClC-5 chloride channel resides mainly in vesicles of the endocytotic pathway and contributes to their acidification. Its disruption in mice entails a broad defect in renal endocytosis and causes secondary changes in calciotropic hormone levels. Inactivating mutations in Dent's disease lead to proteinuria and kidney stones. Possibly by recycling, a small fraction of ClC-5 also reaches the plasma membrane. Here we identify a carboxyl-terminal internalization motif in ClC-5. It resembles the PY motif, which is crucial for the endocytosis and degradation of epithelial Na(+) channels. Mutating this motif increases surface expression and currents about 2-fold. This is probably because of interactions with WW domains, because dominant negative mutants of the ubiquitin-protein ligase WWP2 increased surface expression and currents of ClC-5 only when its PY motif was intact. Stimulating endocytosis by expressing rab5 or its GTPase-deficient Q79L mutant decreased WT ClC-5 currents but did not affect channels with mutated motifs. Similarly, decreasing endocytosis by expressing the inactive S34N mutant of rab5 increased ClC-5 currents only if its PY-like motif was intact. Thus, the endocytosis of ClC-5, which itself is crucial for the endocytosis of other proteins, depends on the interaction of a carboxyl-terminal internalization signal with ubiquitin-protein ligases containing WW domains.     

Biochemical and pharmacological study of N-linked glycosylation of the human serotonin 5-HT₇a receptor

The 5-hydroxytryptamine (5-HT)(7(a)) receptor is a G-protein-coupled receptor critically involved in human psychiatric and neurological disorders. In the present study, we evaluate the presence and the functional role of N-glycosylation of the human 5-HT(7) receptor. Western blot analysis of HEK293T cells transiently expressing the 5-HT(7(a)) receptor in the presence of tunicamycin gave rise to a band shift, indicating the existence of an N-glycosylated form of the 5-HT(7(a)) receptor. To further investigate this, we mutated the two predicted N-glycosylation sites (N5Q and N66Q) and compared the molecular mass of the immunoreactive bands with those of the wild-type receptor, indicating that both asparagines were N-glycosylated. The mutant receptors had the same binding affinity for [(3) H]5-CT and the same potency and efficacy with regard to 5-HT-induced activation of adenylyl cyclase. However, there was a reduction in maximal ligand binding for the single and double mutants compared to the wild-type receptor. Next, membrane labelling and immunocytochemical studies demonstrated that the N-glycosylation mutants were expressed at the cell surface. We conclude that N-glycosylation is not important for cell surface expression of the 5-HT(7) receptor.     

Comparison of Amphibian and Human ClC-5: Similarity of Functional Properties and Inhibition by External pH

Loss of function mutations of the renal chloride channel, ClC-5, have been implicated in Dent's disease, a genetic disorder characterized by low weight proteinuria, hypercalciuria, nephrolithasis and, in some cases, eventual renal failure. Recently, our laboratory used an RT-PCR/RACE cloning strategy to isolate an amphibian cDNA from the renal epithelial cell line A6 that had high homology to human ClC-5. We now report a full-length native ClC-5 clone (xClC-5, containing 5′ and 3′ untranslated regions) isolated by screening a cDNA library from A6 cells that was successfully expressed in Xenopus oocytes. In addition, we compared the properties of xClC-5 and hClC-5 using isogenic constructs of xClC-5 and hClC-5 consisting of the open reading frame subcloned into an optimized Xenopus expression vector. Expression of the full-length ``native' xClC-5 clone resulted in large, strongly rectifying, outward currents that were not significantly affected by the chloride channel blockers DIDS, DPC, and 9AC. The anion conductivity sequence was NO⁻ ₃ > Cl⁻= I⁻ > HCO⁻ ₃ >> glutamate for xClC-5 and NO⁻ ₃ > Cl⁻ > HCO⁻ ₃ > I⁻ >> glutamate for hClC-5. Reduction of the extracellular pH (pH _o ) from 7.5 to 5.7 inhibited outward ClC-5 currents by 27 ± 9% for xClC-5 and 39 ± 7% for hClC-5. The results indicate that amphibian and mammalian ClC-5 have highly similar functional properties. Unlike hClC-5 and most other ClC channels, expression of xClC-5 in oocytes does not require the removal of its untranslated 5′ and 3′ regions. Acidic solutions inhibited both amphibian and human ClC-5 currents, opposite to the stimulatory effects of low external pH on other ClC channels, suggesting a possibly distinct regulatory mechanism for ClC-5 channels. Received: 28 August 1998/Revised: 13 January 1999     

Expression and regulation of ClC-5 chloride channels: effects of antisense and oxidants

Genetic mutations of theCl channel ClC-5 cause Dent's disease in humans. Werecently cloned an amphibian ortholog of Xenopus ClC-5(xClC-5) from the A6 cell line. We now compare the properties and regulation of ClC-5 currents expressed in mammalian (COS-7) cellsand Xenopus oocytes. Whole cell currents in COS-7 cells transfected with xClC-5 cDNA had strong outward rectification, Cl > I anion sensitivity, and wereinhibited at low pH, similar to previous results in oocytes. Inoocytes, antisense xClC-5 cRNA injection had no effect on endogenousmembrane currents or the heterologous expression of human ClC-5.Activators of cAMP and protein kinase C inhibitors had nosignificant effects on ClC-5 currents expressed in either COS-7 cellsor oocytes, whereas H-89, a cAMP-dependent protein kinase (PKA)inhibitor, and hydrogen peroxide decreased the currents. We concludethat the basic properties of ClC-5 currents were independent of thehost cell type used for expression. In addition, ClC-5 channels may bemodulated by PKA and reactive oxygen species.

     

Effect of block deletions in the C-terminus on the functional expression of human anion exchanger 1 (AE1)

The human anion exchanger 1 (AE1) is the most abundant integral membrane protein in red cells and is responsible for the exchange of Cl(-) for HCO(3)(-). However, the detailed role played by the AE1 C-terminal region in the anion translocation and membrane trafficking process remains unclear. In this paper, we created four mutants in the human AE1 C-terminus by deletion of the residues Ala(891)-Phe(895), Asp(896)-Glu(899), Asp(902)-Glu(906) and Val(907)-Val(911), to investigate the role of these sequences in functional expression of AE1. WT AE1 and its deletion mutant constructs were expressed in HEK 293 cells. Western blotting showed that deletions of Ala(891)-Phe(895), Asp(896)-Glu(899), and Val(907)-Val(911) induced high expression of AE1, whereas loss of Asp(902)-Glu(906) results in stable low expression. Pulse chase assays of WT AE1 and its mutants showed that the stability of protein is unaffected by the levels of expression of the AE1 and its mutants. Ala(891)-Phe(895), Asp(902)-Glu(906) and Val(907)-Val(911) mutants exhibited lower levels of trafficking to the plasma membrane compared with WT AE1, while the Asp(896)-Glu(899) mutant was more highly expressed at the plasma membrane. The decreased ability of the mutants to mediate Cl(-)/HCO(3)(-) exchange in transfected cells revealed that the deletion sequences have an important role in transport activity. These results demonstrate that the studied residues in the AE1 C-terminus differently affect the expression, membrane trafficking and functional folding of AE1.     

The structural role of N-linked glycans on human glypican-1

Glypicans are cell-surface heparan sulfate proteoglycans that regulate developmental signaling pathways by binding growth factors to their heparan sulfate chains. The primary structures of glypican core proteins contain potential N-glycosylation sites, but the importance of N-glycosylation in glypicans has never been investigated in detail. Here, we studied the role of the possible N-glycosylation sites at Asn-79 and Asn-116 in recombinant anchorless glypican-1 expressed in eukaryotic cells. Mutagenesis and enzymatic cleavage indicated that the potential N-glycosylation sites are invariably occupied. Experiments using the drug tunicamycin to inhibit the N-linked glycosylation of glypican-1 showed that secretion of anchorless glypican-1 was reduced and that the protein did not accumulate inside the cells. Heparan sulfate substitution of N-glycosylation mutant N116Q was similar to wild-type glypican-1 while the N79Q mutant and also the double mutant N79Q,N116Q were mostly secreted as high-molecular-weight heparan sulfate proteoglycan. N-Glycosylation mutants and N-deglycosylated glypican-1 had far-UV circular dichroism and fluorescence emission spectra that were highly similar to those of N-glycosylated glypican-1. A single unfolding transition at high concentrations of urea was found for both N-deglycosylated glypican-1 and glypican-1 in which the N-glycosylation sites had been removed by mutagenesis when chemical denaturation was monitored by circular dichroism and fluorescence emission spectroscopy. In summary, we have found that the potential N-glycosylation sites in glypican-1 are invariably occupied and that the N-linked glycans on glypican-1 affect protein expression and heparan sulfate substitution but that correct folding can be obtained in the absence of N-linked glycans.     

Electrophysiological Characteristics of Six Mutations in hClC-1 of Korean Patients with Myotonia Congenita

ClC-1 is a member of a large family of voltage-gated chloride channels, abundantly expressed in human skeletal muscle. Mutations in ClC-1 are associated with myotonia congenita (MC) and result in loss of regulation of membrane excitability in skeletal muscle. We studied the electrophysiological characteristics of six mutants found among Korean MC patients, using patch clamp methods in HEK293 cells. Here, we found that the autosomal dominant mutants S189C and P480S displayed reduced chloride conductances compared to WT. Autosomal recessive mutant M128I did not show a typical rapid deactivation of Cl⁻ currents. While sporadic mutant G523D displayed sustained activation of Cl⁻ currents in the whole cell traces, the other sporadic mutants, M373L and M609K, demonstrated rapid deactivations. V_1/2 of these mutants was shifted to more depolarizing potentials. In order to identify potential effects on gating processes, slow and fast gating was analyzed for each mutant. We show that slow gating of the mutants tends to be shifted toward more positive potentials in comparison to WT. Collectively, these six mutants found among Korean patients demonstrated modifications of channel gating behaviors and reduced chloride conductances that likely contribute to the physiologic changes of MC.     

Investigation of Human Cyclooxygenase-2 Glycosylation Heterogeneity and Protein Expression in Insect and Mammalian Cell Expression Systems

Human cyclooxygenase-2 (hCox-2) is a key enzyme in the biosynthesis of prostaglandins and the target of nonsteroidal anti-inflammatory drugs. Recombinant hCox-2 overexpressed in a vaccinia virus (VV)-COS-7 system comprises two glycoforms. Removal of the N-glycosylation consensus sequence at Asn⁵⁸⁰(N580Q and S582A mutants) resulted in the expression of protein comprising a single glycoform, consistent with the partial N-glycosylation at this site in the wild-type (WT) enzyme. The specific cyclooxygenase activities of the purified WT and N580Q mutant were equivalent (40 ± 3 μmol O₂/min/mg) and titrations with diclofenac showed no difference in inhibitor sensitivities of WT and both mutants. Results of the expression of WT and N580Q hCox-2 in aDrosophilaS2 cell system were also consistent with the N-glycosylation at this site, but low levels of activity were obtained. High levels of N-glycosylation heterogeneity are observed in hCox-2 expressed using recombinant baculovirus (BV) in Sf9 cells. Expression of a double N-glycosylation site mutant in Sf9 cells, N580Q/N592Q, resulted in a decrease in glycosylation but no clear decrease in heterogeneity, indicating that the high degree of N-glycosylation heterogeneity observed with the BV-Sf9 system is not due to partial glycosylation of both Asn⁵⁸⁰and Asn⁵⁹². N-linked oligosaccharide profiling of purified VV and BV WT and S582A mutant hCox-2 showed the presence of high mannose structures, (Man)_n(GlcNAc)₂,n= 9, 8, 7, 6. The S582A mutant was the most homogeneous with (Man)₉(GlcNAc)₂comprising greater than 50% of oligosaccharides present. Analysis of purified VV WT and S582A mutant hCox-2 by liquid chromatography–electrospray ionization–mass spectrometry showed an envelope of peaks separated by approximately 160 Da, corresponding to differences of a single monosaccharide. The difference between the highest mass peaks of the two envelopes, of approximately 1500 Da, is consistent with the wild-type enzyme containing an additional high mannose oligosaccharide.     

Involvement of the Tubular ClC-Type Exchanger ClC-5 in Glomeruli of Human Proteinuric Nephropathies

Glomerular protein handling mechanisms have received much attention in studies of nephrotic syndrome. Histopathological findings in renal biopsies from severely proteinuric patients support the likelihood of protein endocytosis by podocytes. ClC-5 is involved in the endocytosis of albumin in the proximal tubule.

Aim

To investigate whether ClC-5 is expressed in the glomerular compartment and whether it has a role in proteinuric nephropathies. ClC-5 expression was studied using Real-time PCR in manually- and laser-microdissected biopsies from patients with type 2 diabetes (n 37) and IgA nephropathy (n 10); in biopsies of membranous glomerulopathy (MG) (n 14) immunohistochemistry for ClC-5 (with morphometric analysis) and for WT1 was done. Controls: cortical tissue (n 23) obtained from unaffected parts of tumor-related nephrectomy specimens.

Results

ClC-5 was expressed at glomerular level in all biopsies. Glomerular ClC-5 levels were significantly higher in diabetic nephropaty and MG at both mRNA and protein level (p<0.002; p<0.01). ClC-5 and WT1 double-staining analysis in MG showed that ClC-5 was localized in the podocytes. ClC-5 ultrastructural immunolocalization was demonstrated in podocytes foot processes. Our study is the first to demonstrate that ClC-5 is expressed in human podocytes. The ClC-5 overexpression found in biopsies of proteinuric patients suggests that proteinuria may play a part in its expression and that podocytes are likely to have a key role in albumin handling in proteinuric states.     

Identification and functional significance of N-glycosylation of the 5-ht5A receptor

The presence and roles of N-glycosylation of the human (h) 5-ht(5A) receptor were investigated using a heterologous expression system. Following transient transfection of COS-7 cells with h5-ht(5A) receptor cDNA, SDS-PAGE/Western blot analysis of immunoreactivity demonstrated two protein species; a predominant species with a molecular weight of approximately 35-45 kDa and a minor species of approximately 45-55 kDa. Transfected cells grown in the presence of the N-glycosylation inhibitor tunicamycin, failed to express the minor immunoreactive species indicating this represented the N-glycosylated form of the h5-ht(5A) receptor. Comparison of the molecular weights of immunoreactive bands arising from the wild-type and each of the mutant 5-ht(5A) receptors with disruption of the predicted N-glycosylation sites (N6S and N21S) demonstrated that both identified asparagines were N-glycosylated. Immunocytochemical and ELISA studies demonstrated that the [N6S]h5-ht(5A) receptor mutation, but not the [N21S]h5-ht(5A) receptor mutation, reduced protein expression in the cell membrane, indicating that N-glycosylation of the N6 residue is important for the membrane expression of this neurotransmitter receptor; a requirement for receptor function.     

Clcn2 encodes the hyperpolarization-activated chloride channel in the ducts of mouse salivary glands

Transepithelial Cl(-) transport in salivary gland ducts is a major component of the ion reabsorption process, the final stage of saliva production. It was previously demonstrated that a Cl(-) current with the biophysical properties of ClC-2 channels dominates the Cl(-) conductance of unstimulated granular duct cells in the mouse submandibular gland. This inward-rectifying Cl(-) current is activated by hyperpolarization and elevated intracellular Cl(-) concentration. Here we show that ClC-2 immunolocalized to the basolateral region of acinar and duct cells in mouse salivary glands, whereas its expression was most robust in granular and striated duct cells. Consistent with this observation, nearly 10-fold larger ClC-2-like currents were observed in granular duct cells than the acinar cells obtained from submandibular glands. The loss of inward-rectifying Cl(-) current in cells from Clcn2(-/-) mice confirmed the molecular identity of the channel responsible for these currents as ClC-2. Nevertheless, both in vivo and ex vivo fluid secretion assays failed to identify significant changes in the ion composition, osmolality, or salivary flow rate of Clcn2(-/-) mice. Additionally, neither a compensatory increase in Cftr Cl(-) channel protein expression nor in Cftr-like Cl(-) currents were detected in Clcn2 null mice, nor did it appear that ClC-2 was important for blood-organ barrier function. We conclude that ClC-2 is the inward-rectifying Cl(-) channel in duct cells, but its expression is not apparently required for the ion reabsorption or the barrier function of salivary ductal epithelium.     

Glycosylation of BRI2 on asparagine 170 is involved in its trafficking to the cell surface but not in its processing by furin or ADAM10

Two different mutated forms of BRI2 protein are linked with familial British and Danish dementias, which present neuropathological similarities with Alzheimer's disease. BRI2 is a type II transmembrane protein that is trafficked through the secretory pathway to the cell surface and is processed by furin and ADAM10 (a disintegrin and metalloproteinase domain 10) to release secreted fragments of unknown function. Its apparent molecular mass (42-44 kDa) is significantly higher than that predicted by the number and composition of amino acids (30 kDa) suggesting that BRI2 is glycosylated. In support, bioinformatics analysis indicated that BRI2 bears the consensus sequence Asn-Thr-Ser (residues 170-173) and could be N-glycosylated at Asn170. Given that N-glycosylation is considered essential for protein folding, processing and trafficking, we examined whether BRI2 is N-glycosylated. Treatment of HEK293 (human embryonic kidney) cells expressing BRI2 with the N-glycosylation inhibitor tunicamycin or mutation of Asn170 to alanine reduced its molecular mass by ~2 kDa. These data indicate that BRI2 is N-glycosylated at Asn170. To examine the effect of N-glycosylation on BRI2 trafficking at the cell surface, we performed biotinylation and (35)S methionine pulse-chase experiments. These experiments showed that mutation of Asn170 to alanine reduced BRI2 trafficking at the cell surface and its steady state levels at the plasma membrane. Furthermore, we obtained data indicating that this mutation did not affect cleavage of BRI2 by furin or ADAM10. Our results confirm the theoretical predictions that BRI2 is N-glycosylated at Asn170 and show that this post-translational modification is essential for its expression at the cell surface but not for its proteolytic processing.     

Respective roles of calcitonin receptor-like receptor (CRLR) and receptor activity-modifying proteins (RAMP) in cell surface expression of CRLR/RAMP heterodimeric receptors

Receptor activity modifying proteins RAMP1, RAMP2, and RAMP3 are responsible for defining affinity to ligands of the calcitonin receptor-like receptor (CRLR). It has also been proposed that receptor activity-modifying proteins (RAMP) are molecular chaperones required for CRLR transport to the cell surface. Here, we have studied the respective roles of CRLR and RAMP in transporting CRLR/RAMP heterodimers to the plasma membrane by using a highly specific binding assay that allows quantitative detection of cell surface-expressed CRLR or RAMP in the Xenopus oocytes expression system. We show that: (i) heterodimer assembly is not a prerequisite for efficient cell surface expression of CRLR, (ii) N-glycosylated RAMP2 and RAMP3 are expressed at the cell surface and their transport to the plasma membrane requires N-glycans, (iii) RAMP1 is not N-glycosylated and is transported to the plasma membrane only upon formation of heterodimers with CRLR, and (iv) introduction of N-glycosylation sites in the RAMP1 sequence (D58N/G60S, Y71N, and K103N/P105S) allows cell surface expression of these mutants at levels similar to that of wild-type RAMP1 co-expressed with CRLR. Our data argue against a chaperone function for RAMP and identify the role of N-glycosylation in targeting these molecules to the cell surface.     

C-terminal truncation impairs glycosylation of transmembrane collagen XVII and leads to intracellular accumulation

Collagen XVII, a type II transmembrane protein in hemidesmosomes, is involved in the anchorage of stratified epithelia to the underlying mesenchyme. Its functions are regulated by ectodomain shedding, and its genetic defects lead to epidermal detachment in junctional epidermolysis bullosa (JEB), a heritable skin fragility syndrome, but the molecular disease mechanisms remain elusive. Here we used a spontaneously occurring homozygous COL17A1 deletion mutant in JEB to discern glycosylation of collagen XVII. The mutation truncated the distal ectodomain and positioned the only N-glycosylation site 34 amino acids from the newly formed C terminus, which impaired efficient N-glycosylation. Immunofluorescence staining of authentic JEB keratinocytes and of COS-7 cells transfected with the mutant indicated intracellular accumulation of collagen XVII precursor molecules. Cell surface biotinylation and quantification of ectodomain shedding demonstrated that only about 15% of the truncated collagen XVII reached the cell surface. The cell surface-associated molecules were N-glycosylated in a normal manner, in contrast to the molecules retained within the cells, indicating that N-glycosylation of the ectodomain is required for targeting of collagen XVII to the plasma membrane and that reduced accessibility of the N-glycosylation site negatively regulates this process. Functional consequences of the strong reduction of collagen XVII on the cell surface included scattered deposition of cell adhesion molecule laminin 5 into the extracellular environment and, as a consequence of faulty collagen XVII-laminin ligand interactions, aberrant motility of the mutant cells.     

Regulation of intracellular Cl- concentration through volume-regulated ClC-3 chloride channels in A10 vascular smooth muscle cells

We previously found that antisense oligonucleotide specific to ClC-3 (ClC-3 antisense) prevented rat aortic smooth muscle cell proliferation, which was related to cell volume regulation. In the present study, we further characterized the regulation of intracellular Cl(-) concentrations ([Cl(-)](i)) via volume-regulated ClC-3 Cl(-) channels in an embryo rat aortic vascular smooth muscle cell line (A10 cell) and ClC-3 cDNA-transfected A10 cells (ClC-3-A10) using multiple approaches including [Cl(-)](i) measurement, whole cell patch clamp, and application of ClC-3 antisense and intracellular dialysis of an anti-ClC-3 antibody. We found that hypotonic solution decreased [Cl(-)](i) and evoked a native I(Cl.vol) in A10 cells. The responses of [Cl(-)](i) and I(Cl.vol) to hypotonic challenge were enhanced by expression of ClC-3, and inhibited by ClC-3 antisense. The currents in A10 (I(Cl.vol)) and in ClC-3-A10 cells (I(Cl.ClC-3)) were remarkably inhibited by intracellular dialysis of anti-ClC-3 antibody. Reduction in [Cl(-)](i) and activation of I(Cl.vol) and I(Cl.ClC-3) in A10 and ClC-3-A10 cells, respectively, were significantly inhibited by activation of protein kinase C (PKC) by phorbol-12,13-dibutyrate (PDBu) and inhibition of tyrosine protein kinase by genistein. Sodium orthovanadate (vanadate), a protein-tyrosine phosphatase inhibitor, however, enhanced the cell swelling-induced reduction in [Cl(-)](i), accompanied by the activation of I(Cl.vol) and I(Cl.ClC-3) in a voltage-independent manner. Our results suggest that the volume-regulated ClC-3 Cl(-) channels play important role in the regulation of [Cl(-)](i) and cell proliferation of vascular smooth muscle cells.     

Mutations of the asparagine117 residue of a receptor activity-modifying protein 1-dependent human calcitonin gene-related peptide receptor result in selective loss of function

The initially orphan human calcitonin (CT) receptor-like receptor (hCRLR) interacts with novel accessory receptor activity-modifying protein 1 (RAMP1) to reveal a functional CT gene-related peptide (CGRP) receptor. In mammalian cells, RAMP1 is required for mature N-glycosylation of the hCRLR predicted to occur at Asn(60), Asn(112), and/or Asn(117) in the amino-terminal extracellular domain. Here we have shown that the substitution of Asn(117) with Ala, Gln, Thr, or Pro abolished CGRP-evoked cAMP formation which was left unchanged when the Asn(117) was replaced with Asp. Moreover, the hCRLR and the Asn(117) mutants exhibited comparable N-glycosylation and cell surface expression, and the association with RAMP1 was only slightly impaired. In contrast, the hCRLR Asn(60,112) to Thr double mutant exhibited defective RAMP1-dependent N-glycosylation, and impaired cell surface expression and CGRP receptor function. Unlike Asn(60) and Asn(112), Asn(117) is normally not N-glycosylated, but essential for CGRP binding to the hCRLR-RAMP1 complex.     

Oxidation induces ClC-3-dependent anion channels in human leukaemia cells

To test for redox regulation of anion channels in erythroid cells, we exposed K562 cells to oxidants and measured changes in transmembrane Cl(-) currents using patch-clamp, and in intracellular Cl(-) content using the Cl(-) selective dye MQAE. Oxidation with tert-butylhydroperoxide or H(2)O(2) produced a plasma membrane anion permeability with a permselectivity of NO(3)(-)>lactate(-)>gluconate(-). The permeability increase was paralleled by insertion of ClC-3 protein into the plasma membrane as evident from immunofluorescence microscopy and surface biotinylation. Down-regulation of ClC-3 protein by RNA interference as assessed by immunoblotting decreased the oxidation-stimulated permeability. In conclusion, oxidation induces surface expression of ClC-3 and activation of a ClC-3-dependent anion permeability in K562 cells.     

Hyposmotic activation of ICl,swell in rabbit nonpigmented ciliary epithelial cells involves increased ClC-3 trafficking to the plasma membrane.

In mammalian nonpigmented ciliary epithelial (NPE) cells, hyposmotic stimulation leading to cell swelling activates an outwardly rectifying Cl(-) conductance (I(Cl,swell)), which, in turn, results in regulatory volume decrease. The aim of this study was to determine whether increased trafficking of intracellular ClC-3 Cl channels to the plasma membrane could contribute to the I(Cl,swell) following hyposmotic stimulation. Our results demonstrate that hyposmotic stimulation reversibly activates an outwardly rectifying Cl(-) current that is inhibited by phorbol-12-dibutyrate and niflumic acid. Transfection with ClC-3 antisense, but not sense, oligonucleotides reduced ClC-3 expression as well as I(Cl,swell). Intracellular dialysis with 2 different ClC-3 antibodies abolished activation of I(Cl,swell). Immunofluorescence microscopy showed that hyposmotic stimulation increased ClC-3 immunoreactivity at the plasma membrane. To determine whether this increased expression of ClC-3 at the plasma membrane could be due to increased vesicular trafficking, we examined membrane dynamics with the fluorescent membrane dye FM1-43. Hyposmotic stimulation rapidly increased the rate of exocytosis, which, along with ICl,swell, was inhibited by the phosphoinositide-3-kinase inhibitor wortmannin and the microtubule disrupting agent, nocodazole. These findings suggest that ClC-3 channels contribute to I(Cl,swell) following hyposmotic stimulation through increased trafficking of channels to the plasma membrane.