Low-conductance Chloride Channel Research Articles

Chlorotoxin-Fc Fusion Inhibits Release of MMP-2 from Pancreatic Cancer Cells

Chlorotoxin (CTX) is a 36-amino acid peptide derived from Leiurus quinquestriatus (scorpion) venom, which inhibits low-conductance chloride channels in colonic epithelial cells. It has been reported that CTX also binds to matrix metalloproteinase-2 (MMP-2), membrane type-1 MMP, and tissue inhibitor of metalloproteinase-2, as well as CLC-3 chloride ion channels and other proteins. Pancreatic cancer cells require the activation of MMP-2 during invasion and migration. In this study, the fusion protein was generated by joining the CTX peptide to the amino terminus of the human IgG-Fc domain without a hinge domain, the monomeric form of chlorotoxin (M-CTX-Fc). The resulting fusion protein was then used to target pancreatic cancer cells (PANC-1) in vitro. M-CTX-Fc decreased MMP-2 release into the media of PANC-1 cells in a dose-dependent manner. M-CTX-Fc internalization into PANC-1 cells was observed. When the cells were treated with chlorpromazine (CPZ), the internalization of the fusion protein was reduced, implicating a clathrin-dependent internalization mechanism of M-CTX-Fc in PANC-1 cells. Furthermore, M-CTX-Fc clearly exhibited the inhibition of the migration depending on the concentration, but human IgG, as negative control of Fc, was not affected. The M-CTX-Fc may be an effective instrument for targeting pancreatic cancer.

Chlorotoxin Fused to IgG-Fc Inhibits Glioblastoma Cell Motility via Receptor-Mediated Endocytosis

Chlorotoxin is a 36-amino acid peptide derived from Leiurus quinquestriatus (scorpion) venom, which has been shown to inhibit low-conductance chloride channels in colonic epithelial cells. Chlorotoxin also binds to matrix metalloproteinase-2 and other proteins on glioma cell surfaces. Glioma cells are considered to require the activation of matrix metalloproteinase-2 during invasion and migration. In this study, for targeting glioma, we designed two types of recombinant chlorotoxin fused to human IgG-Fcs with/without a hinge region. Chlorotoxin fused to IgG-Fcs was designed as a dimer of 60 kDa with a hinge region and a monomer of 30 kDa without a hinge region. The monomeric and dimeric forms of chlorotoxin inhibited cell proliferation at 300 nM and induced internalization in human glioma A172 cells. The monomer had a greater inhibitory effect than the dimer; therefore, monomeric chlorotoxin fused to IgG-Fc was multivalently displayed on the surface of bionanocapsules to develop a drug delivery system that targeted matrix metalloproteinase-2. The target-dependent internalization of bionanocapsules in A172 cells was observed when chlorotoxin was displayed on the bionanocapsules. This study indicates that chlorotoxin fused to IgG-Fcs could be useful for the active targeting of glioblastoma cells.

A low conductance chloride channel in the basolateral membranes of the non-pigmented ciliary epithelium of the rabbit eye

PURPOSE. Chloride efflux plays an important role in aqueous p < humor production. Chloride currents have been described in bovine non-pigmented ciliary epithelium (NPE), in transformed cultured human NPE, and in volume-activated chloride channels described in the latter. It is the basolateral membranes of the NPE of ocular ciliary processes that comprise the exit pathway for the process of aqueous secretion performed by the double syncytial layer of ciliary epithelium, however. Therefore, we studied both cell-attached, and, excised, inside-out patches from basolateral membranes of the NPE. METHODS. Cell-attached and cell-free excised patches were formed from the basolateral membranes of NPE and single channel currents recorded with a Dagan 3900A patCH clamp amplifier. RESULTS. A low conductance channel of 14 pS was observed and recorded in 30% of cell attached patches and in 35% of excised inside out patches under symmetrical conditions (160 mM chloride). This channel displayed a nearly linear current-voltage relationship, with an open probability that was not volt-age-dependent. The channel was chloride-selective: N-methyl-D-glucamine (NMDG) used as cation did not alter the current profile nor the reversal potential. Further, with inside-out patches, the reversal potential was close to zero (0.3 ± 0.5 mV (10) in symmetrical (160 mM) chloride, but shifted to -32.3 ± 0.5 mV (5) when the concentration of chloride in the bathing solution was reduced to 40 mM while the recording pipette was held at 160 mM. This value approaches the theoretical equilibrium potential of chloride for these conditions. The channel anion permeability sequence was: I - > NO 3 - = Br - > Cl - > gluconate - ˜ aspartate -. Three different chloride-channel blockers inhibited the channel activity. CONCLUSION. A low conductance channel, selective for chloride, and, modulated by beta adrenergic and VIP stimulation, based on its sensitivity to exogenously added cAMP, ATP and the catalytic subunit of PKA, is present in the exit basolateral membranes of rabbit NPE and contributes to the process of aqueous humor formation.

Ion Channels in the Chloroplast Envelope Membrane

Isolated chloroplast envelope membranes were fused with azolectin liposomes. Ion transport across the membrane of these liposomes was investigated by the patch-clamp technique and in planar bilayers. Our results show that the chloroplast envelope contains voltage-dependent anion- and cation-selective channels as well as anion- and cation-selective pores with high conductances. At least one of the high-conductance pores could be located in the chloroplast outer envelope membrane. The low-conductance chloride channel and the potassium channel showed complex gating behavior with subconductant states. Potassium channel gating was affected by monovalent and divalent cations as well as by millimolar concentrations of ATP. Low concentrations of Cs+ induced a flickering block. Voltage dependence of the open probability reveals that macroscopic currents of potassium channels are rectified with preferential potassium uptake into the chloroplast. Flux measurements and determinations of the stroma pH of intact chloroplasts confirm the presence of a potassium channel that is regulated by divalent cations (Mg2+) and by ATP. The fully open potassium channel revealed a conductance of lambda approximately equal to 100 pS in asymmetric KCl (250/20 mM KCl), and the fully open chloride channel revealed a conductance of lambda approximately equal to 60 ps in 100 mM Tris/HCl. One high-conductance channel, mainly active at holding potentials > 60 mV, was slightly selective for glutamate anions (PK+/PGlu- approximately equal to 2) and revealed fast voltage-dependent gating. This high-conductance channel had a conductance of lambda approximately equal to 540 pS (in 250/20 mM potassium glutamate) and was closed most of the time. A second type of high-conductance channel, mainly open and active at holding potentials below 30 mV, was slightly selective for cations (PGlu-/PK+ approximately equal to 2) with a conductance of lambda approximately equal to 1.14 nS (in 250/20 mM potassium glutamate).

The non‐specific ion channel in Torpedo ocellata fused synaptic vesicles.

1. Synaptic vesicles were isolated and fused into large structures with a diameter of more than 20 microns to characterize their ionic channels. The 'cell'-attached and inside-out configurations of the patch clamp technique were used. 2. Two types of ion channels were most frequently observed: a low conductance chloride channel and a high conductance non-specific channel. 3. The non-specific channel has a main conducting state and a substate. The main conducting state has a slope conductance of 246 +/- 15 pS (+/- S.E.M., n = 15), in the presence of different combinations of KCl and potassium glutamate. 4. From the reversal potentials of the current-voltage (I-V) relation, it was concluded that this channel conducts both Cl- and K+. 5. The non-specific channel is highly voltage dependent: under steady-state voltages it has a high open probability near 0 mV and does not inactivate; when the membrane is hyperpolarized (pipette side more positive), the open probability decreases dramatically. 6. Voltage pulses showed that upon hyperpolarization (from holding potentials between -20 and + 20 mV), the channels deactivated; when the membrane was stepped back to the holding potential, the channels reactivated rapidly. 7. In a number of experiments, when the pipette side was made more negative than the bath, the open probability also decreased. 8. Frequently, a substate with a conductance of about 44 +/- 4% (+/- S.E.M., n = 3) of the main state was detected. 9. We speculate that this non-specific ion channel may have different roles at the various stages of the life cycle of the synaptic vesicle. When the synaptic vesicle is an intracellular structure, it might help its transmitter-concentrating capacity by dissipating the polarization. After fusion with the surface membrane, it might constitute an additional conductance pathway, taking part in frequency modulation of synaptic transmission.

CAMP-activated chloride channels in a MR-transfected pancreatic adenocarcinoma-derived cell line, pANS6

Pancreatic adenocarcinoma cell lines rarely express the CFTR gene, despite the high levels of CFTR protein that are present in primary pancreatic duct cells. We have attempted to generate a non-CF pancreatic adenocarcinoma cell line that stably produces high levels of CFTR mRNA and protein by transfecting a vector containing the CFTR cDNA, driven by a strong mammalian promoter, into the poorly differentiated pancreatic adenocarcinoma cell line, Panc-1. The pANS6 pancreatic duct cell line expresses substantial levels of CFTR mRNA, but little CFTR protein. Despite this we were able to detect low conductance chloride channels in 40% of patches, stimulated with cAMP, that have similar biophysical properties to CFTR.

Endothelin and vasopressin activate low conductance chloride channels in aortic smooth muscle cells.

The non-contractile aortic smooth muscle cell line A7r5 was used to study the membrane events involved in the effect of vasoconstrictor peptides. Whole-cell voltage-clamp and membrane potential recording techniques were used to demonstrate the contribution of an increased Cl- conductance to the late depolarization induced by endothelin-1 and vasopressin. During cell-attached patch recording with N-methyl-D-glucamine in the pipette, bath application of endothelin or vasopressin induced single-channel inward currents in the following minutes. The current/potential (I/V) curve of the most frequently observed channel type--a small conductance Cl- (SCl) channel--reversed near the cell membrane potential and showed a single-channel conductance of 1.8 pS for inward currents. After patch excision in an extracellular solution containing CaCl2 (2 mM), the frequency of SCl channel openings increased. Patch excision in the absence of peptide stimulation also produced this channel activity. Replacement of CaCl2 by a Ca2+ chelator on the intracellular face of a patch reversibly inhibited the channel activity, indicating that these SCl channels are Ca(2+)-activated Cl- channels. The single-channel I/V characteristic showed outward rectification above +50 mV. An analysis of the gating kinetics of the SCl channel is given. Another channel type was recorded less frequently after peptide stimulation. It had a lower conductance (1.0-1.3 pS) and slower kinetics and was designated a very small conductance Cl- channel. It is concluded that activation of two types of Cl- channels (at least one of which is Ca2+ dependent) is involved in the late depolarization produced by vasoconstrictor peptides in vascular smooth muscle cells of the aortic cell line A7r5.

Intracellular calcium ions activate a low-conductance chloride channel in smooth-muscle cells isolated from human mesenteric artery.

Calcium-activated chloride currents were studied by the patch-clamp technique in vascular smooth muscle cells (VSMC) isolated from human mesenteric arteries. Bath application of 20 mM caffeine caused the cell membrane to depolarize by a calcium-activated inward current that peaked to -654 +/- 230 pA (holding potential -50 mV). Cell-attached, at the same time inwardly directed single-channel currents were detected with an amplitude of -0.22 pA. In open-cell-attached patches channel activity was triggered by elevating [Ca2+]i to 10 microM. At -60 mV the mean amplitude of the current was -0.24 pA and the mean open time of the channels was 28 ms. Plotting the amplitude of the current versus the test potential yielded a single-channel conductance of 2.8 +/- 0.5 pS. The currents disappeared when [Cl-] was reduced from 150 mM to 5 mM at the cytosolic side of the inside-out patch at a holding potential of -60 mV (calculated reversal potential -58 mV) suggesting that the calcium-activated current was a chloride current. This suggests that, in human mesenteric VSMC, elevation of [Ca2+]i activates a low-conductance chloride channel, which may mediate the agonist-induced depolarization of the cell membrane.

Low-conductance chloride channels in IEC-6 and CF nasal cells expressing CFTR.

The properties of the cystic fibrosis gene product (CFTR) were studied by expression of cloned cDNA in different cell systems. Infection of both simian fibroblast (Vero) cells and immortalized CF nasal polyp cells (NCF3A) with a vaccinia virus encoding CFTR induced forskolin-induced Cl- permeability and low-conductance (8 pS) Cl- channels. By stable transfection of the rat intestinal crypt-derived cell line IEC-6 we have isolated a clone, IEC-CF7, which expresses CFTR mRNA and antigen. IEC-CF7 cells, but not IEC-6, display forskolin-induced Cl- permeability and multiple linear low-conductance (+/- 8 pS) Cl- channels in cell-attached membrane patches. In excised patches of IEC-CF7 cells, low-conductance Cl- channels could be activated by addition of the catalytic subunit of the adenosine 3',5'-cyclic monophosphate-dependent protein kinase A (PKA) plus ATP. During bath fluid replacement studies, the activated low-conductance channel remained active in the absence of ATP at room temperature and showed saturation kinetics. Rectifying (32 pS) Cl- channels were not observed in either IEC-6 cells or IEC-CF7 cells, indicating that there is no relation between CFTR expression and the incidence of this channel. Our data strongly support the conclusion that CFTR can act as a low-conductance Cl- channel, gated by PKA. The IEC-6-derived cell line IEC-CF7 may prove to be a useful model in the study of CFTR function because of the absence of 32-pS Cl- channel activity and its potential for differentiation.

CFTR, a channel with the structure of a transporter

The cystic fibrosis transmembrane conductance regulator (CFTR) belongs to a superfamily of active transport molecules. However, when expressed in a wide variety of heterologous cell systems and when purified to homogeneity and reconstituted in planar lipid bilayers, it exhibits low conductance chloride channel activity. We postulate that the active transport capability of the molecule has been adapted to provide very stringent metabolic control of this channel which is responsible for chloride secretion and hydration of wet epithelial surfaces.

CFTR, a channel with the structure of a transporter

The cystic fibrosis transmembrane conductance regulator (CFTR) belongs to a superfamily of active transport molecules. However, when expressed in a wide variety of heterologous cell systems and when purified to homogeneity and reconstituted in planar lipid bilayers, it exhibits low conductance chloride channel activity. We postulate that the active transport capability of the molecule has been adapted to provide very stringent metabolic control of this channel which is responsible for chloride secretion and hydration of wet epithelial surfaces.

The cystic fibrosis transmembrane conductance regulator chloride channel. Iodide block and permeation

Cystic fibrosis (CF) is a common autosomal-recessivediseasecharacterizedby abnormallylow chlorideconduc­tance in epithelial cell membranes (1). The CF genesequence predicts a protein having two sets of sixtransmembranespanningregions, two nucleotide (ATP)binding folds, and a highly charged regulatory domainwith concensus phosphorylation sites for protein kinasesA and C (2,3). An ohmic, low-conductance chloridechannel is generated when this protein (named CFTRfor cystic fibrosis transmembrane conductance regula­tor) is expressed in insect cells, and the channels andCFTR protein appear with the same time course (4).The same CI channel is also produced when the gene isexpressed in CFTR-transfectedCHO cells (5) and inXenopus oocytes injected with cRNA (6). Moreover, amacroscopic CI conductance having properties consis­tent with this channel is generated in HeLa cellstransiently expressing CFTR, and the apparent selectiv­ity of this conductance can be altered by mutatingresidues within the first and sixth transmembrane span­ning regions (7). Taken together, the single channel andmutagenesis data strongly suggest CFTR is the cAMP­activated Cl channel which has been characterizedpreviously in human pancreatic duct (8), thyroid (12),and thecolonic cell line T84 (9).The channel generated in CFTR-expressingcells canbe activated in excised patches by exposure to proteinkinases (5), making it possible to study single channelselectivity in detail. Iodide selectivity has recently beenused for identifying this channel macroscopically(7,10,11), but previous studies of iodide permeabilityhave led toconflicting results. In this paperwe use CHOcells stably transfected with the CFTR gene to studyiodide effects at the single channel level under biionicconditions. We report that iodide blocks the channel atnormal (150 mM) ionic strengthand thatpermeabilitytoiodide is higher than to chloride when measured fromthe cytoplasmic side.

Cl- channel activity in Xenopus oocytes expressing the cystic fibrosis gene.

The expression of the cystic fibrosis (CF) gene on its introduction into nonepithelial somatic cells has recently been shown to result in the appearance of distinctive low conductance chloride channels stimulated by cyclic AMP (Kartner, N., Hanrahan, J.W., Jensen, T.J., Naismith, A.L., Sun, S., Ackerley, C.A., Reyes, E.F., Tsui, L.-C., Rommens, J.M., Bear, C.E., and Riordan, J.R. (1991) Cell 64, 681-691; Anderson, M. P., Rich, D.P., Gregory, R.J., Smith, A.E., and Welsh, M.J. (1991) Science 251, 679-682). Since Xenopus oocytes provide a powerful system for ion channel characterization, we have examined whole cell and single channel currents in them after injection of cRNA to program the synthesis of the cystic fibrosis transmembrane conductance regulator (CFTR). This has enabled the direct demonstration that the cyclic AMP activation is mediated by protein kinase A and that CFTR is without effect on the endogenous calcium-activated chloride channels of the oocyte, which have been well characterized previously and widely used as reporters of the expression of G-protein-coupled receptors. These findings strengthen the argument that the CF gene codes for a novel regulated chloride channel rather than a regulatory protein which can modulate separate chloride channel molecules.

Low-conductance chloride channel activated by cAMP in the epithelial cell line T 84

We have studied the modulation and pharmacological properties of two anion channels in T 84 cells by recording single channel and transepithelial currents. One channel had an outwardly rectifying current-voltage I/V curve, was rarely active in cell-attached patches, and was unaffected by cAMP. The other channel had lower conductance (8.7 pS at 37°C) and a more ohmic I/V relationship. Exposure to cAMP increased the probability of observing low-conductance channel activity in cell-attached patches > 6-fold. Extracellular DIDS (4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid) or IAA-94 (an indanyloxyacetic acid) inhibited the outward rectifier but did not affect the low-conductance channel or cAMP-stimulated transepithelial current. These results suggest the low-conductance Cl channel may contribute to apical membrane conductance during cAMP-stimulated secretion.