Expression Of ClC-2 Research Articles

Evidence for a Functional Interaction between the ClC-2 Chloride Channel and the Retrograde Motor Dynein Complex

The ClC-2 chloride channel has been implicated in essential physiological functions. Analyses of ClC-2 knock-out mice suggest that ClC-2 expression in retinal pigment epithelia and Sertoli cells normally supports the viability of photoreceptor cells and male germ cells, respectively. Further, other studies suggest that ClC-2 expression in neurons may modify inhibitory synaptic transmission via the gamma-aminobutyric acid, type A receptor. However, complete understanding of the physiological functions of ClC-2 requires elucidation of the molecular basis for its regulation. Using cell imaging and biochemical and electrophysiological techniques, we show that expression of ClC-2 at the cell surface may be regulated via an interaction with the dynein motor complex. Mass spectrometry and Western blot analysis of eluate from a ClC-2 affinity matrix showed that heavy and intermediate chains of dynein bind ClC-2 in vitro. The dynein intermediate chain co-immunoprecipitates with ClC-2 from hippocampal membranes suggesting that they also interact in vivo. Disruption of dynein motor function perturbs ClC-2 localization and increases the functional expression of ClC-2 in the plasma membranes of COS7 cells. Thus, cell surface expression of ClC-2 may be regulated by dynein motor activity. This work is the first to demonstrate an in vivo interaction between an ion channel and the dynein motor complex.

Mast cells express chloride channels of the ClC family.

The expression of specific Cl- channels in mast cells (MC) is poorly understood. Because the largest and most ubiquitously expressed family of Cl- channels is the ClC, we studied MC mRNA and protein expression for members of the ClC family. Specific primers were designed to ClC-1 to -7 and reverse-transcriptase polymerase chain reaction (RT-PCR) was performed on RNA from highly purified rat peritoneal mast cells (PMC) and the rat cultured mast cell line (RCMC). Protein expression of ClC-2, -3 and -7 chloride channels in PMC and RCMC was studied using western blotting. RT-PCR showed that RCMC expressed mRNA for the Cl- channels (ClC)-2, -3, -4, -5 and -7, while PMC expressed ClC-7. Using Western Blotting, we found protein expression of ClC-2 and ClC-7, but not ClC-3, in RCMC, whereas in PMC neither of these proteins could be detected. These results indicate that MC express several members of the ClC family and that these Cl- channels might be important in MC functions.

The ClC-3 chloride channel promotes acidification of lysosomes in CHO-K1 and Huh-7 cells.

ClC-3 is a voltage-gated Cl- channel that is highly conserved and widely expressed, although its function, localization, and properties remain a matter of considerable debate. In this study, we have shown that heterologous expression of ClC-3 in either Chinese hamster ovary (CHO-K1) or human hepatoma (Huh-7) cells results in the formation of large, acidic vesicular structures within cells. Vesicle formation is prevented by bafilomycin, an inhibitor of the vacuolar ATPase, and is not induced by an E224A mutant of ClC-3 with altered channel activity. This demonstrates that vesicle formation requires both proton pumping and Cl- channel activity. Manipulation of the intracellular Cl- concentration demonstrated that the ClC-3-associated vesicles shrink and swell consistent with a highly Cl--permeable membrane. The ClC-3 vesicles were identified as lysosomes based on their colocalization with the lysosome-associated proteins lamp-1, lamp-2, and cathepsin D and on their failure to colocalize with fluorescently labeled endosomes. We conclude that ClC-3 is an intracellular channel that conducts Cl- when it is present in intracellular vesicles. Its overexpression results in its appearance in enlarged lysosome-like structures where it contributes to acidification by charge neutralization.

Aldosterone and high-NaCl diet modulate ClC-2 chloride channel gene expression in rat kidney.

It is well known that Na+ reabsorption in the kidney can be regulated by aldosterone. Although Cl- is the most abundant anion present in the extra cellular fluids the involvement of aldosterone in the regulation of Cl- conductance through Cl- channels at the molecular level is unknown. In this study, the effects of aldosterone and high-Na+ diet on the expression of ClC-2, a cell volume-, pH- and voltage-sensitive Cl- channel, was examined in the rat kidney. Total RNA isolated from Wistar rats fed a high-Na+ diet for 5 days, furosemide treatment, adrenalectomy and adrenalectomy with replacement of normal plasma levels of aldosterone were compared by the use of ribonuclease protection assay (RPA), and/or a semi-quantitative RT-PCR. The high-Na+ diet reduced renal mRNA and protein ClC-2 expression. The renal expression of ClC-2 mRNA decreased in adrenalectomized rats and was restored by plasma aldosterone replacement. In addition, the semi-quantitative RT-PCR in different segments of the nephron showed that these changes were secondary to the modulation of ClC-2 mRNA expression by aldosterone in the cortical and medullary segments of thick ascending limbs of Henle's loop. These results suggest that ClC-2 may be involved with aldosterone-induced Cl- transport in the kidney.

Distribution of ClC-2 chloride channel in rat and human epithelial tissues.

The ubiquitous ClC-2 Cl(-) channel is thought to contribute to epithelial Cl(-) secretion, but the distribution of the ClC-2 protein in human epithelia has not been investigated. We have studied the distribution of ClC-2 in adult human and rat intestine and airways by immunoblotting and confocal microscopy. In the rat, ClC-2 was present in the lateral membranes of villus enterocytes and was predominant at the basolateral membranes of luminal colon enterocytes. The expression pattern of ClC-2 in the human intestine differed significantly, because ClC-2 was mainly detected in a supranuclear compartment of colon cells. We found significant expression of ClC-2 at the apex of ciliated cells in both rat and human airways. These results show that the distribution of ClC-2 in airways is consistent with participation of ClC-2 channels in Cl(-) secretion and indicate that extrapolation of results from studies of ClC-2 function in rat intestine to human intestine is not straightforward.

Expression of swelling- and/or pH-regulated chloride channels (ClC-2, 3, 4 and 5) in human leukemic and normal immune cells

Chloride channels on immune cells reportedly play important roles in cell volume regulation, cell proliferation and immune functions, but they are not well characterized at the molecular level. We examined the expression of swelling-and/or pH-regulated chloride channels (ClC-2, 3, 4 and 5) in human leukemic cell lines [Jurkat and Hut-78 (T cells), Raji and Daudi (B cells), K-562 and HL-60 (myeloid cells)] and T cells, B cells and neutrophils from 8 normal subjects to clarify the difference of their expression among different cell types and maturity. Semi-quantitative RT-PCR and Northern blot analysis showed that ClC-3 was most abundantly expressed in all cells regardless of the cell types and maturity, while expression of ClC-2 was weak in these cells. Expression of ClC-4 was observed mainly in leukemic B cell lines, and in B cells and neutrophils from normal subjects. ClC-5 was expressed in all cell lines, while it was observed in only T and B cells but not in neutrophils from normal subjects. Thus, these chloride channels (ClC-2, 3, 4 and 5) showed distinct distribution among human immune cells, suggesting that they have specific roles in these cells. Molecular identification of chloride channels in leukocytes of different types and maturity may provide a new approach for the treatment of leukemia.

Arginine vasopressin regulates CFTR and ClC-2 mRNA expression in rat kidney cortex and medulla.

The presence of both CFTR and ClC-2 proteins in the kidney suggest that they are involved in chloride transport along the nephron but their physiological roles in this organ are not known. To further understand the role of these chloride channels we studied Wistar rats subjected to dehydration for 2 days and also the homozygous Brattleboro rats, a strain of Long-Evans rats carrying an autosomal recessive mutation that leads to a deficiency of arginine-vasopressin (AVP) secretion in the plasma. The expression of CFTR was increased in the medulla of dehydrated Wistar rats and no variation was observed in the cortex. The expression of both ClC-2 and CFTR mRNAs was low in the renal cortex and medulla of the homozygous Brattleboro rats but returned to normal levels after AVP reposition. By the use of Madine-Darby canine kidney (MDCK) type I epithelial cells, it was observed that AVP (10(-8), 10(-7) and 10(-6) M) increased CFTR mRNA expression "in vitro" but no effect was observed when changes in the medium tonicity were caused by the addition of sucrose, NaCl, manitol or urea. The modulation of both CFTR and ClC-2 mRNA by AVP, the main hormone involved in the regulation of body fluid osmolality, suggests the participation of these two chloride channels in the renal tubule transcellular chloride transport modulated by AVP.

Expression of volume-sensitive Cl(-) channels and ClC-3 in acinar cells isolated from the rat lacrimal gland and submandibular salivary gland.

1. The expression of ClC-3 was examined in rat lacrimal gland and submandibular salivary gland cells using RT-PCR and Western analysis. Whole-cell patch clamp methods were used to investigate the expression of volume-sensitive anion channels in acinar cells isolated from these tissues. 2. Expression of mRNA encoding ClC-3, and ClC-3 protein, was found in rat submandibular gland by RT-PCR and Western analysis. Rat lacrimal gland cells, however, did not appear to express mRNA encoding for ClC-3, nor the ClC-3 protein. 3. Volume-sensitive anion conductances were observed in both rat lacrimal gland and submandibular salivary gland acinar cells. The conductance was of a similar size in the two cell types, but was much slower to activate in the lacrimal cells. 4. The properties of the conductances in lacrimal and submandibular cells were similar, e.g. halide selectivity sequence (P(I) > P(Cl) > P(aspartate)) and inhibition by 4,4'-diisothiocyanostilbene-2,2'-disulphonic acid, 5-nitro-2-(3-phenylpropylamino)-benzoate and tamoxifen. 5. The data suggest that the expression of ClC-3 is not an absolute requirement for the activity of volume-sensitive anion channels in rat lacrimal gland acinar cells.

Human ClC-3 Is Not the Swelling-activated Chloride Channel Involved in Cell Volume Regulation

Volume regulation is essential for normal cell function. A key component of the cells' response to volume changes is the activation of a channel, which elicits characteristic chloride currents (I(Cl, Swell)). The molecular identity of this channel has been controversial. Most recently, ClC-3, a protein highly homologous to the ClC-4 and ClC-5 channel proteins, has been proposed as being responsible for I(Cl, Swell). Subsequently, however, other reports have suggested that ClC-3 may generate chloride currents with characteristics clearly distinct from I(Cl, Swell). Significantly different tissue distributions for ClC-3 have also been reported, and it has been suggested that two isoforms of ClC-3 may be expressed with differing functions. In this study we generated a series of cell lines expressing variants of ClC-3 to rigorously address the question of whether or not ClC-3 is responsible for I(Cl, Swell). The data demonstrate that ClC-3 is not responsible for I(Cl, Swell) and has no role in regulatory volume decrease, furthermore, ClC-3 is not activated by intracellular calcium and fails to elicit chloride currents under any conditions tested. Expression of ClC-3 was shown to be relatively tissue-specific, with high levels in the central nervous system and kidney, and in contrast to previous reports, is essentially absent from heart. This distribution is also inconsistent with the previous proposed role in cell volume regulation.

Expression of the Voltage-Dependent Chloride Channel ClC-3 in Human Nasal Tissue

In the present study, ClC-3, one of the voltage-dependent chloride channels, was identified in human nasal tissue. In situ hybridization and immunohistochemical investigations demonstrated the localization of ClC-3 in the serous acini and ductal portions of submucosal nasal glands, which are the primary source of nasal secretion. Our data suggest that this channel contributes to nasal secretion via chloride transport. Its dysfunction might lead to abnormal nasal secretion in such pathological states as sinusitis.

Molecular distribution of volume-regulated chloride channels (ClC-2 and ClC-3) in cardiac tissues.

The molecular identification of cardiac chloride channels has provided probes to investigate their distribution and abundance in heart. In this study, the molecular expression and distribution of volume-regulated chloride channels ClC-2 and ClC-3 in cardiac tissues were analyzed and quantified. Total RNA was isolated from atria and ventricles of several species (dog, guinea pig, and rat) and subjected to a quantitative RT-PCR strategy. ClC-2 and ClC-3 mRNA expression were calculated relative to beta-actin expression within these same tissues. The transcriptional levels of ClC-3 mRNA were between 1.8 and 10.2% of beta-actin expression in atria and between 3.4 and 8.6% of beta-actin in ventricles (n = 3 for each tissue). The levels of ClC-2 in both atria and ventricles were significantly less than those measured for ClC-3 (n = 3; P < 0.05). ClC-2 mRNA levels were between 0.04-0.08% and 0.03-0.18% of beta-actin expression in atria and ventricles, respectively (n = 3 for each tissue). Immunoblots of atrial and ventricular wall protein extracts demonstrated ClC-2- and ClC-3-specific immunoreactivity at 97 and 85 kDa, respectively. Immunohistochemical localization in guinea pig cardiac muscle demonstrates a ubiquitous distribution of ClC-2 and ClC-3 channels in the atrial and ventricular wall. Confocal analysis detected colocalization of ClC-2 and ClC-3 in sarcolemmal membranes and distinct ClC-3 immunoreactivity in cytoplasmic regions. The molecular expression of ClC-2 and ClC-3 in cardiac tissue is consistent with the proposed role of these chloride channels in the regulation of cardiac cell volume and the modulation of cardiac electrical activity.

Involvement of ion channels in human eosinophil respiratory burst

Background: Human eosinophils possess a variety of ion channels that play a crucial role in the regulation of cellular activity. During eosinophil respiratory burst, efflux of H+ ions through H+ channels provides an efficient mechanism of H+ extrusion and charge compensation. Interestingly, recent studies suggest that other ion channels may also be involved in this process. Objective: We sought to investigate the role of ion channels in phorbol 12-myristate 13-acetate–induced superoxide (O2•–) generation by human eosinophils. Methods: O2•– production was measured by using the superoxide dismutase–inhibitable reduction of cytochrome c. Ion channel expression and function were studied by using RT-PCR and the patch clamp technique, respectively. Results: O2•– generation was affected by several ion channel blockers, especially 4,4-diisothio-cyanostilbene-2,2′-disulfonic acid. The involvement of Cl– channels in this process was confirmed by replacement of Cl– with gluconate or other anions. The halide dependence of O2•– production could be described by the sequence Cl–≥Br–>I–, which is similar to the selectivity sequence of several members of the chloride channel (ClC) family. RT-PCR studies performed with primers for ClC-2, ClC-3, ClC-4, ClC-5, ClC-6, and the cystic fibrosis transmembrane conductance regulator showed only the expression of ClC-3. The presence of phorbol 12-myristate 13-acetate–sensitive Cl– channels in human eosinophils with biophysical properties similar to the ClC-3 channel has been studied. Conclusion: Cl– channels play an important role in the regulation of O2•– production by human eosinophils. (J Allergy Clin Immunol 2000;106:272-9.)

A Novel Anionic Inward Rectifier in Native Cardiac Myocytes

Although the cationic inward rectifiers (Kir and hyperpolarization-activated I(f) channels) have been well characterized in cardiac myocytes, the expression and physiological role of anionic inward rectifiers in heart are unknown. In the present study, we report the functional and molecular identification of a novel chloride (Cl(-)) inward rectifier (Cl.ir) in mammalian heart. Under conditions in which cationic inward rectifier channels were blocked, membrane hyperpolarization (-40 to -140 mV) activated an inwardly rectifying whole-cell current in mouse atrial and ventricular myocytes. Under isotonic conditions, the current activated slowly with a biexponential time course (time constants averaging 179.7+/-23.4 [mean+/-SEM] and 2073.6+/-287.6 ms at -120 mV). Hypotonic cell swelling accelerated the activation and increased the current amplitude whereas hypertonic cell shrinkage inhibited the current. The inwardly rectifying current was carried by Cl(-) (I(Cl.ir)) and had an anion permeability sequence of Cl(-)>I(-)>>aspartate. I(Cl.ir) was blocked by 9-anthracene-carboxylic acid and cadmium but not by stilbene disulfonates and tamoxifen. A similar I(Cl.ir) was also observed in guinea pig cardiac myocytes. The properties of I(Cl.ir) are consistent with currents generated by expression of ClC-2 Cl(-) channels. Reverse transcription polymerase chain reaction and Northern blot analysis confirmed transcriptional expression of ClC-2 in both atrial and ventricular tissues and isolated myocytes of mouse and guinea pig hearts. These results indicate that a novel I(Cl.ir) is present in mammalian heart and support a potentially important role of ClC-2 channels in the regulation of cardiac electrical activity and cell volume under physiological and pathological conditions.

Developmental expression of ClC-2 in the rat nervous system

Regulation of expression of the voltage-gated chloride channel, ClC-2, was investigated during development and adult life in rat brain. RNase protection assays demonstrated a marked increase in levels of expression of ClC-2 in brain during early postnatal development which was also detected in adult brain. In situ hybridization of E15 and E18 rat brains demonstrated ClC-2 expression in deep brain nuclei and scattered cells within the neuroepithelial layers, but not in the regions of subventricular zone that primarily give rise to glial populations. By E18 all neurons within the emerging cortical plate and its equivalent in other areas of the CNS were heavily labeled. During the first postnatal week, ClC-2 was highly expressed in most neurons. By P7 a pattern of differential expression emerged with evidence of decreased expression of ClC-2 mRNA in many neuronal populations. In adult rat brain, ClC-2 was expressed at highest levels in large neurons as found within layer V of cortex, Ammon's Horn of hippocampus, or mitral cells of the olfactory bulb and Purkinje cells within the cerebellum. Many smaller neurons within the diencephalon maintained significant levels of expression. A functional conductance was readily detected in hippocampal neurons during the first postnatal week, which had the same characteristic properties as the conductance observed in adult neurons. The observed expression and functional presence of ClC-2 suggest a widespread role in neuronal chloride homeostasis in early postnatal life, and demonstrated that cell specific shut-down resulted in the adult pattern of expression.

Chloride channel CLC-3 is expressed by gallbladder epithelium: A potential regulator of Cl− secretion

Gallbladder epithelium exhibits uncoupled Na + absorption and CIsecretion in prairie dogs. Prominent gallbladder C1permeability suggests the presence of an unidentified apical CIchannel. In renal tubules, disorders of epithelial transport function such as Dent's disease have been found to originate in altered C1channel function. We have recently found that gallbladder C1secretion is increased prior to cholesterol-induced gallstone formation. The mechanism for gallbladder CIsecretion, however, is not completely understood. Recent molecular cloning experiments have identified two distinct families of chloride channels: the CIC and CLC channels. The CLC family includes several molecular isoforms, CLC0-7, with tissue-specific distribution and function. CLC-2,-3 and -4 are expressed by several tissues, whereas CLC-KI and CLC-5 are highly kidney-specific. We hypothesized that CLC-3 is expressed by gallbladder epithelium and may regulate gallbladder C1transport with important implications in gallstone formation. Total RNA was extracted from both prairie dog and human gallbladder epithelia, reverse transcribed, and amplified by PCR using CLC-3 specific primers. Molecular cloning and sequence analysis demonstrated the predicted 508 bp eDNA with 94% nucleotide homology between prairie dog and human CLC-3 cDNAs. The deduced 168 amino acid sequences were 99% identical. Subsequent RT-PCR analysis confirmed the expression of CLC-3 by the human gallbladder following gallstone formation. This is the first report that CLC-3 is expressed by human gallbladder during gallstone formation. Alterations in CLC-3 activity may alter epithelial CIpermeability and promote gallstones.

Analysis of ClC-2 channels as an alternative pathway for chloride conduction in cystic fibrosis airway cells.

Cystic fibrosis (CF) is a lethal inherited disease that results from abnormal chloride conduction in epithelial tissues. ClC-2 chloride channels are expressed in epithelia affected by CF and may provide a key "alternative" target for pharmacotherapy of this disease. To explore this possibility, the expression level of ClC-2 channels was genetically manipulated in airway epithelial cells derived from a cystic fibrosis patient (IB3-1). Whole-cell patch-clamp analysis of cells overexpressing ClC-2 identified hyperpolarization-activated Cl- currents (HACCs) that displayed time- and voltage-dependent activation, and an inwardly rectifying steady-state current-voltage relationship. Reduction of extracellular pH to 5.0 caused significant increases in HACCs in overexpressing cells, and the appearance of robust currents in parental IB3-1 cells. IB3-1 cells stably transfected with the antisense ClC-2 cDNA showed reduced expression of ClC-2 compared with parental cells by Western blotting, and a significant reduction in the magnitude of pH-dependent HACCs. To determine whether changes in extracellular pH alone could initiate chloride transport via ClC-2 channels, we performed 36Cl- efflux studies on overexpressing cells and cells with endogenous expression of ClC-2. Acidic extracellular pH increased 36Cl- efflux rates in both cell types, although the ClC-2 overexpressing cells had significantly greater chloride conduction and a longer duration of efflux than the parental cells. Compounds that exploit the pH mechanism of activating endogenous ClC-2 channels may provide a pharmacologic option for increasing chloride conductance in the airways of CF patients.

Functional and molecular expression of volume-regulated chloride channels in canine vascular smooth muscle cells.

1. We examined the possibility of functional and molecular expression of volume-regulated Cl- channels in vascular smooth muscle using the whole-cell patch-clamp technique and quantitative reverse transcriptase-polymerase chain reaction (RT-PCR) on cells from canine pulmonary and renal arteries. 2. Decreasing external osmolarity induced cell swelling, which was accompanied by activation of Cl--dependent outward-rectifying membrane currents with an anion permeability sequence of SCN- > I- > Br- > Cl- > aspartate-. These currents were sensitive to block by DIDS, extracellular ATP and the antioestrogen compound tamoxifen. 3. Experiments were performed to determine whether the molecular form of the volume-regulated chloride channel (ClC-3) is expressed in pulmonary and renal arteries. Quantitative RT-PCR confirmed expression of ClC-3 in both types of smooth muscle. ClC-3 expression was 76.4 % of beta-actin in renal artery and 48.0 % of beta-actin in pulmonary artery. 4. We conclude that volume-regulated Cl- channels are expressed in vascular smooth muscle cells and exhibit functional properties similar to those found in other types of cells, presumably contributing to the regulation of cell volume, electrical activity and, possibly, myogenic tone.

Molecular dissection of gating in the ClC-2 chloride channel.

The ClC-2 chloride channel is probably involved in the regulation of cell volume and of neuronal excitability. Site-directed mutagenesis was used to understand ClC-2 activation in response to cell swelling, hyperpolarization and acidic extracellular pH. Similar to equivalent mutations in ClC-0, neutralizing Lys566 at the end of the transmembrane domains results in outward rectification and a shift in voltage dependence, but leaves the basic gating mechanism, including swelling activation, intact. In contrast, mutations in the cytoplasmic loop between transmembrane domains D7 and D8 abolish all three modes of activation by constitutively opening the channel without changing its pore properties. These effects resemble those observed with deletions of an amino-terminal inactivation domain, and suggest that it may act as its receptor. Such a 'ball-and-chain' type mechanism may act as a final pathway in the activation of ClC-2 elicited by several stimuli.

Alteration of GABA A Receptor Function Following Gene Transfer of the CLC-2 Chloride Channel

The effect of GABA A receptor activation varies from inhibition to excitation depending on the state of the transmembrane anionic concentration gradient (▿ anion). ▿ anion was genetically altered in cultured dorsal root ganglion neurons via adenoviral vector–mediated expression of ClC-2, a Cl − channel postulated to regulate the Cl − concentration in neurons in which GABA A receptor activation is predominantly inhibitory. ClC-2 expression was verified by the presence of the appropriate mRNA, protein, and membrane conductance. ClC-2 expression resulted in a large negative shift in the Cl − equilibrium potential (E Cl) that attenuated the GABA-mediated membrane depolarization and prevented GABA A receptor–mediated action potentials. These results establish that gene transfer of transmembrane ion channels to neurons can be used to demonstrate their physiological function, and that ▿ anion can be genetically manipulated to alter the function of neuronal GABA A receptors in situ.