From the Department of Medicine and Pathophysiology, Osaka University Medical School, Suita, Osaka 565, Japan
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ABSTRACT |
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In excitable cells, intracellular Ca2+ is released via the ryanodine receptor from the intracellular Ca2+ storing structure, the sarcoplasmic reticulum. To determine whether this released Ca2+ propagates through gap junctions to neighboring cells and thereby constitutes a long range signaling network, we developed a cell system in which cells expressing both connexin-43 and ryanodine receptor are surrounded by cells expressing only connexin-43. When the ryanodine receptor in cells was activated by caffeine, propagation of Ca2+ from these caffeine-responsive cells to neighboring cells was observed with a Ca2+ imaging system using fura-2/AM. Inhibitors of gap junctional communication rapidly and reversibly abolished this propagation of Ca2+. Together with the electrophysiological analysis of transfected cells, the observed intercellular Ca2+ wave was revealed to be due to the reconstituted gap junction of transfected cells.
We next evaluated the functional roles of cysteine residues in the extracellular loops of connexin-43 in gap junctional communication. Mutations of Cys54, Cys187, Cys192, and Cys198 to Ser showed the failure of Ca2+ propagation to neighboring cells in accordance with the electrical uncoupling between transfected cells, whereas mutations of Cys61 and Cys68 to Ser showed the same pattern as the wild type. [14C]Iodoacetamide labeling of free thiols of cysteine residues in mutant connexin-43s showed that two pairs of intramolecular disulfide bonds are formed between Cys54 and Cys192 and between Cys187 and Cys198. These results suggest that intercellular Ca2+ signaling takes place in cultured cells expressing connexin-43, leading to their own synchronization and that the extracellular disulfide bonds of connexin-43 are crucial for this process.
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INTRODUCTION |
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The intercellular transmission of molecules through channels in a specialized cell membrane structure, the gap junction, is a mechanism for direct signaling between adjacent cells. In the nervous system, intercellular Ca2+ signaling between glial cells may represent a system of widespread non-synaptic communication (1-5). A Ca2+ imaging system has shown that a wave of elevated intracellular Ca2+ level ([Ca2+]i)1 that passes through a confluent monolayer of glial cells is triggered on micropipette stimulation of a single glial cell (2, 4, 5), topical application of glutamate (1, 5), or localized photo-stimulation (5). In the cardiac cells, [Ca2+]i changes periodically during the cycle of excitation-contraction coupling (6, 7), and muscle contraction is induced by thousand-fold increases in [Ca2+]i released through activated ryanodine receptor from sarcoplasmic reticulum. However, no studies to date have demonstrated intercellular propagation of the increased [Ca2+]i. If increased [Ca2+]i propagates across cells, this should be a mechanism for the synchronization of excitable cells in a wide range.
Gap junctions are assemblies of cell-cell channels (8-10). Each channel is formed through the docking of two hemichannels located in apposing cell membranes, and each hemichannel is composed of a hexamer of connexin monomers. The gap junction permits the passage of soluble molecules of up to 1 kDa in size (11-13), including cAMP, Ca2+, inositol(1,4,5)-triphosphate (InsP3), ATP, and morphogens (8, 14, 15). The permeability of the gap junction can be reversibly regulated by several factors, including pH, Ca2+, cAMP, and cGMP (16-18).
Since cDNAs encoding the connexin gene family were isolated, two experimental systems have been exploited for functional characterization of isolated connexin genes. Connexin cRNA has been injected into Xenopus oocytes (19-21). Channel properties of gap junctional channels between oocytes placed in close contact has been studied by the dual voltage clamp method. As an alternative to the oocyte expression system, connexin has been expressed in cultured mammalian cells, and its function was assayed as the transfer of a microinjected fluorescent dye or electrophysiologically (22-25). Although the two expression systems yielded comparable results, recent studies demonstrated that there is no distinct correlation between junctional conductance, dye transfer, and/or ion selectivity of gap junctions in either system (26, 27). In a mammalian expression system, differences in the extent of dye transfer have been detected between several types of connexin transfectants, although they showed similar junctional conductance (26, 27). Therefore, analysis of serial changes in [Ca2+]i by a Ca2+ imaging system should be required to study the functional role of gap junction on an intercellular Ca2+ signaling. We designed a cell system in which cells expressing both connexin-43 and ryanodine receptor are surrounded by cells expressing only connexin-43 on the basis of preliminary results: 1) HEK293 cells do not express caffeine-sensitive Ca2+ release channel ryanodine receptor nor functional gap junction, and 2) transfected HEK293 cells express ryanodine receptor and connexin-43 functioning in a proper manner. By using a Ca2+ imaging system, we could observe an intercellular Ca2+ wave from a cell triggering Ca2+ excitation through a confluent monolayer of cells.
A hydrophobicity plot of connexin-43 showed it consists of four hydrophobic membrane spanning domains separated by hydrophilic segments (9, 28). The two hydrophilic extracellular loops (encompassing amino acids 44-68 and 185-207 of connexin-43) are highly conserved in all connexin isoforms. The most striking feature of these two extracellular loops is the presence of six cysteine residues. Each loop has three cysteine residues with the consensus for the first loop being CX6CX3C (Cys54, Cys61, and Cys68 in connexin-43) and for the second loop CX4CX5C (Cys187, Cys192 and Cys198 in connexin-43). In the structure of the intercellular channel, it is the extracellular domain where the homophilic docking of hemichannels must occur that eventually results in the opening of the cell-cell channel. In general, two cysteine residues at different points on the polypeptide chain but adjacent in the three-dimensional structure of a protein can be oxidized to form a disulfide bond, which stabilizes the correct folding of the protein. In this study, we determined whether the formation of disulfide bonds in the extracellular domain directs the correct assembly of the gap junction.
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EXPERIMENTAL PROCEDURES |
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Construction of Mutant Connexin-43s--
The sequence
corresponding to rat connexin-43 cDNA was amplified by reverse
transcription-polymerase chain reaction using mRNA isolated from
rat heart and cloned into the Bluescript KS(+) vector. Polymerase chain
reaction primers were designed according to the published sequence (28)
with an EcoRI site at the 5-end to facilitate cloning. The
cloned sequences were verified by nucleotide sequencing.
Stable Expression of Connexin-43 in HEK293 Cells-- HEK293 cells were grown in Dulbecco's modified Eagle's medium (high glucose) supplemented with 10% fetal calf serum and penicillin at 37 °C under an atmosphere containing 5% CO2. Connexin-43 cDNA was ligated into the EcoRI site of the pcDNA3 vector (Invitrogen), containing the neomycin (G418)-resistant gene as a dominant selectable marker. HEK293 cells were transfected with expression vectors using the calcium phosphate precipitation technique and then the transfected cells were grown for selection in medium containing 800 µg/ml G418. Each of the clones selected with G418 was further analyzed by Northern blot and immunoblot analyses.
Transient Expression of the Ryanodine Receptor in Connexin-43-expressing Clones-- The selected clones expressing connexin-43 or HEK293 cells were grown on glass coverslips in the usual medium without G418. When the cells had grown to a confluence level of approximately 30%, they were transfected with the ryanodine receptor cDNA in the PMT2 expression vector and then grown for 24-48 h before experimentation.
Northern Blot RNA Analysis-- Total cellular RNA from HEK293 cells and transfected cells was extracted, electrophoretically separated in a 1.2% agarose-formaldehyde gel, and then capillary-blotted onto nitrocellulose. The blots were hybridized with 32P-labeled connexin-43 cDNA or ryanodine receptor cDNA probes and then examined by autoradiography.
Protein Immunoblot Analysis-- Cells of each type were harvested and pelleted with a microcentrifuge. Plasma membrane-enriched protein fractions of HEK293 cells transfected with the pcDNA3 vector alone or pcDNA3 containing connexin-43 cDNA were prepared by lysing the pellets in 0.5% Nonidet P-40, followed by repelleting by centrifugation at 10,000 rpm for 3 min. Microsomal membrane protein fractions of HEK293 cells transfected with the pcDNA3 vector alone or PMT2 containing ryanodine receptor cDNA were prepared by the method previously described (30). Then samples were solubilized in the SDS loading buffer and resolved on 12% SDS-polyacrylamide gels, followed by electrophoretic transfer to nitrocellulose. The nitrocellulose blots were incubated with a monoclonal mouse anti-connexin-43 IgG antibody (Zymed Laboratories Inc.), a monoclonal mouse anti-ryanodine receptor IgM antibody (Zymed Laboratories Inc.), or a monoclonal mouse anti-InsP3 receptor IgG antibody (American Research Products Inc.). The blots were then washed three times with TBS containing 0.1% Tween 20, incubated with a peroxidase-labeled affinity purified anti-mouse IgG (H+L) antibody or a peroxidase-labeled whole anti-mouse Ig antibody, washed again, and then developed using an enhanced chemiluminescence system.
Immunofluorescence Analysis-- Cells on a glass cover slide were fixed with 3% paraformaldehyde for 10 min and permeabilized with 0.1% Triton X-100 for 10 min. After blocking with 5% bovine serum albumin in phosphate-buffered saline for 30 min, cells were incubated with either a monoclonal mouse anti-connexin-43 IgG antibody or a monoclonal mouse anti-ryanodine receptor IgM antibody for 2 h. Anti-connexin-43 antibody-antigen complexes were visualized using biotinylated anti-mouse IgG (Vector Laboratories Inc.) for 1 h, followed by fluorescein isothiocyanate-conjugated streptavidin (Vector Laboratories Inc.) for 1 h. Anti-ryanodine receptor antibody-antigen complexes were visualized using rhodamine-labeled anti-mouse IgM (Organon Teknika Corp.) for 1 h. Cover slides were then mounted in Mowiol 4-88 (Vector Laboratories Inc.). The cells were photographed on a Olympus Provis AX80 microscope fitted with the appropriate filters.
Measurement of [Ca2+]i-- [Ca2+]i was determined by measurement of fura-2/AM fluorescence (Molecular Probe Inc.). Cells on a glass cover slide were loaded with fura-2/AM by incubation in the usual medium containing 5 µM fura-2/AM and 0.06% pluronic F127 (Molecular Probe Inc.) for 30 min at room temperature. After loading, the cells were washed with the medium twice and then used for the experiment immediately. A glass cover slide of dye-loaded cells was mounted in a laminar flow perfusion chamber and placed on the stage of an inverted microscope. The cells were continuously superfused with HEPES buffer comprising 15 mM HEPES, pH 7.4, 140 mM NaCl, 5 mM KCl, 0.3 mM MgCl2, 10 mM glucose, and 10 mM CaCl2. Fluorescence images were obtained by alternate excitation at 340 and 380 nm using twin xenon arc lamps with an image processor (Argus-50/Ca, Hamamatsu Photonics, Hamamatsu, Japan). [Ca2+]i was calculated as the ratio of the fluorescence intensities at 340 and 380 nm at 2-s intervals. Application of caffeine, an activator of the ryanodine receptor (31, 32), was performed by replacing the control HEPES buffer with the same buffer containing 15 mM caffeine, during which maps of [Ca2+]i in all cells in frame were obtained using the image processor.
Inhibitors of gap junctional communication, octanol and doxyl stearic acids (DSA) (33, 34) were examined as to their effects on cell-cell coupling of connexin-43-expressing cells. Cells were first superfused with HEPES buffer containing 15 mM caffeine to establish the presence of cell-cell coupling by demonstrating an intercellular Ca2+ wave. Following recovery, the cells were superfused with HEPES buffer containing 500 µM octanol or 50 µM DSA to block the cell-cell coupling. After 5 min, the cells were superfused with the HEPES buffer containing 15 mM caffeine a second time. After washing out of the octanol or DSA with the HEPES buffer, the cells were superfused with the HEPES buffer containing 15 mM caffeine a third time to demonstrate the reversibility of the actions of the drugs. The role of InsP3-mediated Ca2+ release mechanism on the intercellular Ca2+ wave was examined by using activators and inhibitors of InsP3 production. Histamine and vasopressin activate phospholipase C, leading to a dramatic increase in intracellular InsP3 production (35). Application of histamine or vasopressin was performed by replacing the control HEPES buffer with same buffer containing 10 µM histamine or 0.5 nM vasopressin. U73122 inhibits phospholipase C, leading to a block of intracellular InsP3 production (36, 37). Cells were first superfused with HEPES buffer containing 15 mM caffeine to establish the presence of cell-cell coupling by demonstrating an intercellular Ca2+ wave. Following recovery, the cells were superfused with HEPES buffer containing 10 µM U73122 to block the InsP3 production. After 5 min, the cells were superfused with the HEPES buffer containing 15 mM caffeine a second time.Electrophysiology--
Gap junctional conductance was measured
with the double whole cell patch-clamp procedure (16, 38) using
Geneclamp 500 amplifier (Axon Instruments, Inc.). Cell pairs were
obtained by freshly dissociating pure populations of confluent cultures
on 1-cm diameter glass coverslips. The coverslip was transferred to the
stage of a Nikon Diaphot microscope, where experiments were performed
at room temperature while exchanging the bath solution (133 mM NaCl, 3.6 mM KCl, 1.0 mM
CaCl2, 0.3 mM MgCl2, 16 mM glucose, 3.0 mM HEPES, pH 7.2). Each cell of
a pair was voltage-clamped using patch-type pipette made on Narishige
NA-9 vertical puller and filled with a solution at pCa 8 (135 mM CsCl, 0.5 mM CaCl2, 2 mM MgCl2, 5.5 mM EGTA, 5.0 mM HEPES, pH 7.2). High resistance seals (>109
ohms) were formed on each cell with the aid of gentle suction, and
access to the cell interior was then gained by brief strong suction
applied to the patch-type pipette. Cells were voltage-clamped at
holding potentials of 40 mV and applied 10 mV voltage pulses to each
cell of the pair. Junctional current (Ij) was measured as the current
evoked in one cell by the voltage step in the other cell (Vj).
Junctional conductance (Gj) was calculated by the equation Ij/Vj.
Isolation of Mutant Connexin-43s-- Highly enriched connexins were obtained by an alkaline extraction procedure (39). The transfected cells were harvested and pelleted. The pellets were resuspended in 2 M NaCl, 10 mM EDTA, 1 mM phenylmethylsulfonyl fluoride, and 100 mM glycine NaOH, pH 10, with the aid of a 23-gauge syringe needle, and then sonicated for about 20 s in a bath sonicator. The sample was centrifuged at 100,000 × g for 60 min at 4 °C. The resulting supernatant was concentrated with a Centriprep 30 microconcentrator (Amicon). The concentrated protein was applied to a column packed with Superose 6 prep grade (Pharmacia Fine Chemicals) and eluted with 50 mM HEPES, pH 8.0, 500 mM NaCl, and 5 mM EDTA. Fractions collected from the column were analyzed by Western blotting with a monoclonal anti-connexin-43 antibody. Then the fractions containing connexin-43 were pooled.
Reaction of Isolated Mutant Connexin-43s with [14C]Iodoacetamide-- By repeated concentration and redilution in a Centriprep 30 microconcentrator, the pooled protein was equilibrated against 7 M guanidine hydrochloride, 500 mM Tris-HCl, pH 8.0, and 2 mM EDTA in the presence or absence of 0.1 mM tri-n-butylphosphine (TBP), a powerful reagent for the specific cleavage of disulfide bonds in proteins (40). The sample was incubated for 20 min at 60 °C, cooled to 23 °C, and then transferred to a tube containing 20 µCi of [14C]iodoacetamide (8 mM final concentration), as described (41). The reaction mixture was immunoprecipitated with a monoclonal anti-connexin-43 antibody mixed with an affinity purified anti-mouse IgG(Fc) antibody and 50 µl of Protein A-Sepharose in a buffer comprising 50 mM HEPES, pH 7.2, 150 mM NaCl, 1% Triton X-100, 10% glycerol, 1 mM phenylmethylsulfonyl fluoride, 10 µg/ml of aprotinin, and 10 µg/ml leupeptin. The immunoprecipitated samples were washed with 50 mM Tris-HCl, pH 7.0, solubilized in SDS loading buffer, and then resolved on 12% SDS-polyacrylamide gels. The gels were dried and examined by autoradiography.
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RESULTS |
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Expression of Transfected Connexin-43 and the Ryanodine Receptor in Cells-- Compared with the trivial amounts of connexin-43 mRNA and protein in HEK293 cells, the transfection of HEK293 cells with connexin-43 cDNA resulted in clones with high levels of its mRNA and protein (Fig. 1, A and B). Furthermore, clones expressing connexin-43 showed a significantly decreased rate of cellular proliferation, as previously demonstrated in an experiment on C6 glioma cells (23). Immunocytochemical localization of the connexin-43 protein in clones expressing connexin-43 revealed a pattern of dense immunoreactivity at cell-cell interfaces (Fig. 1C), in contrast to those in HEK293 cells which showed no detectable immunoreactive sites between cells (data not shown).
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Intercellular Propagation of Ca2+ in Connexin-43-expressing Cells-- When connexin-43-expressing cells were transfected with pMT2 vector containing ryanodine receptor cDNA, application of caffeine increased [Ca2+]i in two separate cells in cell cluster, and then the increased [Ca2+]i was propagated cell by cell in all directions to surrounding cells in culture. The magnitude of the increase in [Ca2+]i reached 500 nM and lasted for 30 s as long as the application of caffeine was continued (Fig. 2B-1). Thus, Ca2+ released from an intracellular store through the activated ryanodine receptor triggered large scale Ca2+ propagation to surrounding cells.
To determine whether the propagation of Ca2+ between cells occurred through gap junctions composed of connexin-43, we next added an inhibitor of gap junctional communication to the superfusion. We used octanol and DSA, which are known to block gap junctional communication rapidly and reversibly in many cell types, including cardiac myocytes (33, 34), and chick lens epithelial cells (42). Five minutes after the start of octanol administration, caffeine was applied to the same cells. In contrast to the extensive Ca2+ propagation response without the inhibitor, caffeine application increased [Ca2+]i in two cells, which were the same caffeine-responsive cells in the initial experiment, but the propagation of Ca2+ did not occur (Fig. 2B-2). After washing out of octanol for 5 min with HEPES buffer, caffeine induced the propagation of Ca2+, which showed the same spatial pattern as that in the initial experiment (Fig. 2B-3). When we used DSA as an alternative inhibitor of gap junctional communication, the same phenomenon was observed (data not shown). After observing the Ca2+ levels of cells by the Ca2+ imaging system, the ryanodine receptor proteins in transfected cells were localized with the same cells by the immunofluorescence assay (Fig. 2C). The localization of ryanodine receptor-expressing cells appeared to be superimposed on the caffeine-responsive cells. Thus, connexin-43s expressed in HEK293 cells form a functional gap junctional pathway for Ca2+ at the sites of intercellular connection. To determine the conductance properties of expressed connexin-43, whole cell voltage-clamp recordings were obtained from cell pairs as described previously (16, 38) (Fig. 3). Repetitive 10 mV pulses (V1, V2) were applied to a pair of voltage-clamped transfected cells. Upward going responses in current trace I1 and I2 represent current flowing through junctional membranes. Downward going responses are currents flowing through nonjunctional and junctional membranes. Junctional current (Ij) was measured as the current evoked in one cell by the voltage step in the other, divided by the amplitude of the voltage step delivered to the other (Vj) (16). Control HEK293 cells typically displayed junctional conductance below the level of sensitivity (<20 pS), whereas the expression of connexin-43 increased the conductance markedly to approximately 48.2 ± 27.4 nS (n = 16), which is compatible with the reported conductance of connexin-43-expressing SKHep1 cell pairs (26, 43). The exposure of a voltage-clamped cell pair to solution containing octanol or DSA rapidly reduced junctional conductance (Fig. 3). Thus, electrophysiological results indicated that expressed connexin-43s reconstitute gap junction between transfected cells and confirmed the notion that the intercellular Ca2+ wave is due to the propagation of mediators or Ca2+ itself through the reconstituted gap junction between cells.
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Mechanisms of Intercellular Propagation of Ca2+-- In connexin-43-expressing cells, [Ca2+]i in surrounding cells after caffeine application reached the same value as those in primarily caffeine-responsive cells. We therefore speculated that a regenerative mechanism of a messenger in each cell should take place. InsP3 has been shown to mediate the intercellular Ca2+ wave between airway epithelial cells (44). We examined whether InsP3-mediated Ca2+ release process participates in the intercellular Ca2+ wave in this cell system by using activators and inhibitors of InsP3 production. Histamine and vasopressin, which enhance the activity of phospholipase C, leading to a dramatic increase in the rate of InsP3 production (35), were examined as to their effects on [Ca2+]i in connexin-43-expressing cells. Immediately after the start of 10 µM histamine or 0.5 nM vasopressin administration, almost all cells showed extensively increased [Ca2+]i (Fig. 4A), which lasted for more than 30 s after the histamine solution was replaced by HEPES buffer. Together with the detection of the endogenous InsP3 receptor in HEK293 cells (Fig. 1B), this indicated that endogenous InsP3 receptors respond to the produced InsP3, resulting in Ca2+ release from intracellular Ca2+ stores.
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Intercellular Propagation of Ca2+ in Mutant Connexin-43-expressing Cells-- To determine whether the conserved cysteine residues in the extracellular loops play an important structural or functional role in gap junctional communication, we constructed six connexin-43 mutants, in which each of the six cysteine residues in the extracellular loops was replaced by a serine residue, and stably expressed them in HEK293 cells. All connexin-43 mutants were overexpressed in the same amount as that of wild type and localized at the interfaces between cells (Fig. 5). The functional properties of each mutant were determined with a Ca2+ imaging system using fura-2/AM, as described for the wild-type connexin-43. Regarding the three cysteine residues in the first extracellular loop, the Cys54 to Ser mutant responded to caffeine but lost the ability of propagation of Ca2+ across neighboring cells (Fig. 6B). On the contrary, the Cys61 and Cys68 to Ser mutants still showed an extensive Ca2+ propagation response to caffeine, and pretreatment with octanol inhibited this Ca2+ wave rapidly and reversibly (Fig. 6A). Thus, the Ca2+ propagation properties of these mutants appeared to be indistinguishable from those of the wild-type connexin-43. As to the three cysteine residues in the second extracellular loop, the Cys187, Cys192, and Cys198 to Ser mutants lost the ability of propagation of Ca2+ (Fig. 6B). We usually confirmed our results using at least three clones for each mutant. Although the amounts of mutant connexin-43 mRNA and protein varied in individual clones, the spatial patterns of the propagated Ca2+ response to caffeine were indistinguishable among the clones for each mutant.
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Reaction of Isolated Mutant Connexin-43 with [14C]Iodoacetamide-- Of the six cysteine residues present in the extracellular loops, four were essential for the formation of the correct structure of gap junctions. To investigate whether these four cysteine residues form disulfide bonds, isolated mutant proteins were reacted with [14C]iodoacetamide, which is incorporated into the free thiol of cysteine but not into the disulfide bond between cysteines. If the TBP-reduced form of a mutant connexin is a much better substrate for alkylation with iodoacetamide than the nonreduced form, this indicates that cysteine residues in the mutant connexin form disulfide bonds. We first constructed a mutant with mutations of Cys260, Cys271, and Cys298 to Ser (Cx43-1) to eliminate the possibility of disulfide bond formation by cysteine residues in the cytoplasmic tail region. By a Ca2+ imaging system, the Cx43-1 showed the Ca2+ propagation properties to be the same as the wild type (data not shown). We next introduced other mutations of cysteine into the Cx43-1; Cys61 and Cys68 were mutated to Ser (Cx43-2); Cys61, Cys68, Cys187, and Cys198 were mutated to Ser (Cx43-3), and Cys61, Cys68, Cys54, and Cys192 were mutated to Ser (Cx43-4), as shown in Fig. 7A. We transfected the mutant cDNA into HEK293 cells and then isolated the proteins by an alkaline extraction method. Immunoblot of expressed proteins stained with anti-connexin-43 antibodies showed that these proteins were expressed and isolated properly (Fig. 8B).
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DISCUSSION |
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Intercellular Ca2+ Signaling Occur via Gap Junctions-- We demonstrated that the released [Ca2+]i in caffeine-responsive cells propagates to surrounding cells only when they express the gap junctional protein, connexin-43. Inhibitors of gap junction such as octanol and DSA rapidly and reversibly inhibited the propagation of Ca2+ across cells. Results of Ca2+ imaging system correspond relatively well to the electrophysiological analysis of transfected cell pairs. We therefore concluded that expressed connexin-43 in cultured cells could form the functional gap junction, which is involved in the intercellular Ca2+ wave.
How the Ca2+ wave crosses a gap junction is unknown, but it could depend upon the diffusion of either Ca2+ itself or InsP3 (14, 44). With regard to the diffusion of these messenger molecules, free or cytosolically buffered Ca2+ exhibits a short range and short lifetimes of less than a second, whereas InsP3 is considered as a long range messenger, showing lifetimes between 1 and 60 s (45). In this study, there was no gradual decrease in peak [Ca2+]i in surrounding cells compared with that in primarily caffeine-responsive cells during an intercellular propagation of Ca2+. We therefore hypothesized that regenerative production and local diffusion of messengers such as Ca2+ or InsP3 through gap junctions across cells should take place. The intercellular Ca2+ wave may occur through an InsP3-mediated process, because heparin, an antagonist of the InsP3 receptor, has been demonstrated to inhibit the propagation of Ca2+ between airway epithelial cells (44). We tested the possibility of InsP3-mediated Ca2+ release mechanism in our cell system by using activators and inhibitors of InsP3 production. Activators of phospholipase C such as histamine and vasopressin increased [Ca2+]i in cultured cells, whereas inhibitor of phospholipase C such as U73122 decreased intercellular propagation of Ca2+ across connexin-43-expressing cells without affecting junctional conductance. Thus, sequential increases in [Ca2+]i in connexin-43-expressing cells during intercellular Ca2+ wave should be due to the activation of InsP3-mediated Ca2+ release cell by cell. Although the [Ca2+]i sufficient for induction of InsP3-mediated Ca2+ release were not known in this study, there have been evidences that phospholipase C is activated by Ca2+ (46, 47) and the InsP3 receptor releases Ca2+ from intracellular stores by [Ca2+]i in a dose-dependent manner with a certain level of InsP3 (48-51). Therefore, we concluded that local diffusion of InsP3 and possibly Ca2+ through reconstituted gap junction across cells activate the InsP3-mediated Ca2+ release process, promoting the intercellular Ca2+ wave. Recently, another type of Ca2+ wave in isolated basophilic leukemic cells, which do not require cell contact, has been found (52). In these cells, ATP released from mechanically stimulated cells acts as an extracellular messenger that diffuses to adjacent cells to increase [Ca2+]i through the activation of the P2-purinergic receptors (53, 54). Therefore, the Ca2+ wave was always biased by an extracellular flow of fluid, in contrast to the intercellular Ca2+ wave through gap junction in this study and others (55). [Ca2+]i of the proximal cell often reaches its peak during the lag period of intercellular communication before the initiation of a response by an adjacent cell. This period may represent the time taken for the concentration of messengers to reach the threshold, triggering the initiation of Ca2+ release from an intracellular store. Increases in [Ca2+]i have been observed to decrease gap junctional coupling in a number of different cell types (8, 9, 17). If the increase in [Ca2+]i associated with the Ca2+ wave results in the closure of gap junctions, this should interrupt the intercellular propagation of the messenger that mediates the Ca2+ wave. Assuming that an adjacent cell responds directly to a threshold concentration of a messenger, a Ca2+ response to the messenger in an adjacent cell should not occur after the peak increase in [Ca2+]i in the proximal cell, in contrast to our observation. Thus, we suggested that increases in [Ca2+]i of up to 500 nM, which was the peak increase in [Ca2+]i observed in this study, did not inhibit gap junctional communication.Cysteine Residues in the Extracellular Loops Are Crucial for Gap Junctions-- The presence of intramolecular disulfide bonds, including inter-loop ones, in connexin has been proposed (56-59). We observed that Cys54 in the first loop and Cys187, Cys192, and Cys198 in the second loop of connexin-43 are crucial for the intercellular Ca2+ wave. On [14C]iodoacetamide labeling of free thiols of cysteine residues, two disulfide bonds between Cys54 and Cys192 and between Cys187 and Cys198 were revealed to form. Thus, the disulfide bonds of the extracellular loops of connexin-43 are necessary for gap junctional communication.
It is unclear at which step cysteine mutants of connexin-43 failed to form functional gap junctions from the results of the functional assay, because it relies solely on open channels. As inferred from the results of structural studies on isolated gap junctions (60, 61), the assembly of a gap junction is a multistage process, which comprises the oligomerization of six connexin monomers, integration of oligomerized connexins into the plasma membrane through the endoplasmic reticulum to the Golgi transport system, dense clustering at the cell-cell interface, and docking with an oligomerized connexin in an apposing cell membrane to form an intercellular channel. In this study, we observed the immunological localization of connexin-43 mutants at the interfaces between cells and the disulfide bond formation between Cys54 and Cys192 and between Cys187 and Cys198 in the extracellular loops, which should occur outside the cell, namely in an oxidative environment. Therefore, connexin-43 mutants should be integrated into the plasma membrane, such that their extracellular loops are positioned outside the cell. Thus, the gap junctional discommunication in the mutants containing mutations of Cys54, Cys187, Cys192, and Cys198 to Ser probably occurred at the steps of hemichannel docking and/or channel opening. An electrophysiological study involving a paired oocyte system has demonstrated that the mutation of all six cysteine residues to serine abolished the junctional communication (56, 57). On the contrary, our results showed that the Cys61 and Cys68 mutants showed an intercellular Ca2+ wave as well as electrical coupling. Immunohistochemical analysis of these mutants on the surface of oocytes revealed the same distribution as in the case of the wild type (57). Therefore, the discrepancy between the two studies may be due to differences in the regulation of channel opening. The assembly of connexin into a gap junction is very dependent on connexin phosphorylation (62, 63) and other cell-cell adhesion molecules, such as cadherins (64, 65). Since HEK293 cells did not require exogenously introduced adhesion molecules for functional gap junction, we suggest that HEK293 cells are equipped with a mechanism for the proper assembly of gap junctions. The present findings substantiate the hypothesis of Sanderson and colleagues that the intercellular Ca2+ wave results from the flux of Ca2+ through InsP3 receptor in the Ca2+ storing structure and that the Ca2+ excitation reflects a regenerative action of [Ca2+]i toward the InsP3 receptor. Although the Ca2+ wave that reflects the excitability of excitable cells progresses thousands of times more slowly than the electrical counterpart, i.e. changes in membrane potential, it is this formal parallel between electrical excitability and Ca2+-based excitability that may have major and multiple modulating effects on the long range signaling network in excitable cells. ![]() |
ACKNOWLEDGEMENTS |
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We are indebted to Dr. David H. MacLennan for the ryanodine receptor cDNA and Dr. Noriyuki Yamada for help in the electrophysiological analysis.
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FOOTNOTES |
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* This study was supported in part by the Japanese Ministry of Education, Science and Culture.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
To whom correspondence should be addressed: Dept. of
Pathophysiology, Osaka University Medical School, 2-2 Yamada-oka,
Suita, Osaka 565, Japan. Tel.: 81-6-879-3273; Fax: 81-6-879-3279;
E-mail: toyofuku{at}mr-path.med.osaka-u.ac.jp.
1 The abbreviations used are: [Ca2+]i, intracellular Ca2+ concentration; InsP3, inositol(1,4,5)-triphosphate; DSA, doxyl stearic acids; TBP, tri-n-butylphosphine; Cx, connexin.
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REFERENCES |
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