Ineffectiveness of oxytocin on intercellular communication between term pregnant human myometrial cells before labor

OBJECTIVE

The effects of the uterotonic agent oxytocin on intercellular communication between term pregnant human myometrial cells before labor were studied to investigate its contribution to the synchronicity of uterine contractions.

STUDY DESIGN

The membrane potential and the input resistance of myometrial cells were measured with intracellular micropipettes, and dye-coupling assays were concomitantly performed while the tissues were perfused with three concentrations of oxytocin (10(-8) mol/L, 10(-7) mol/L, and 10(-6) mol/L). The results were compared with those obtained from tissues perfused with gap junctional uncoupling agent octanol and those with Tyrode's solution (control).

RESULTS

Octanol increased input resistance and inhibited dye coupling but did not affect membrane potential compared with controls. Oxytocin depolarized membrane potential at all studied concentrations. The mean input resistance values and detectable dye propagation with oxytocin were similar to controls.

CONCLUSION

Oxytocin does not contribute to gap junctional intercellular communication in term pregnant human myometrium before labor but may affect contractions by depolarizing membrane potential.

Transient low-affinity agonist binding to Torpedo postsynaptic membranes resolved by using sequential mixing stopped-flow fluorescence spectroscopy

We have detected the binding of the fluorescent agonist Dns-C6-Cho to both low- and high-affinity states of the nicotinic acetylcholine receptor (nAcChoR) using sequential mixing stopped-flow fluorescence spectroscopy. Our approach to resolving low- and high-affinity binding was to first preincubate receptor membranes with the fluorescent partial agonist Dns-C6-Cho for 15 ms to 1000 s and then to follow the fluorescence decay upon chemical dilution into excess acetylcholine. The fast and slow decays, reflecting Dns-C6-Cho dissociation from low- and high-affinity receptors, had rates of 140 +/- 27 s-1 and 0.1 +/- 0.02 s-1, respectively. With increasing preincubation times, the number of low-affinity receptors decreased while the number of high-affinity receptors increased in a Dns-C6-Cho concentration-dependent manner consistent with current models for agonist-induced affinity state conversion. At receptor-activating concentrations of Dns-C6-Cho, the apparent rates with which high-affinity receptors formed approximated those of ion flux desensitization, implying that the fast desensitized state has an agonist dissociation rate that is indistinguishable from the equilibrium slow desensitized state. The KD for the low-affinity binding site was determined to be 1.1 microM from the increase in the amplitude of the fast decay with Dns-C6-Cho concentration with preincubation times that were sufficiently brief to minimize affinity state conversion. Assuming a bimolecular association rate of 10(8) M-1 s-1, a second estimate of 1.4 microM was made for low-affinity binding. We also detected a fluorescence enhancement consistent with a conformational isomerization of Dns-C6-Cho-inhibited nAcChoRs.

Nitric oxide sensitive depolarization-induced hyperpolarization: a possible role for gap junctions during development

Electrical coupling is a widespread feature of developing neuronal circuits and it contributes to the generation of patterned activity. In the developing rat hippocampus, release of GABA by coactive hilar interneurones generates widespread synchronized activity. Here it is shown that hilar interneurones strongly rectify in the outward direction when depolarized. This depolarization-induced hyperpolarization, abolished by gap junction uncouplers, is modulated by nitric oxide. This phenomenon might represent a current-shunting mechanism of the excess current by providing functional inhibition at a developmental stage when GABA is excitatory. Spatial buffering of the current might represent an osmotic mechanism for growth and differentiation.

Functional coupling in bovine ciliary epithelial cells is modulated by carbachol

The functional coupling of the ciliary epithelium was studied in isolated pairs (couplets) of pigmented ciliary epithelial (PCE) and nonpigmented ciliary epithelial (NPCE) cells using the whole cell patch clamp and the fluorescent dye lucifer yellow. One cell of the pair (usually the NPCE cell of a NPCE-PCE cell couplet) was accessed with a 2-5 M omega electrode, containing 1-2 mM lucifer yellow, in the whole cell configuration of the patch clamp. After voltage-clamp experiments were completed, cells were viewed under a fluorescent microscope to confirm that the cells were coupled. The electrical coupling of the cells was also studied by calculating the capacitance (using the time-domain technique), assuming a "supercell" model for coupled cells. The mean capacitance of coupled pairs was 79.8 +/- 4.3 (SE) pF (n = 47) compared with single cell capacitances of 36.8 +/- 3.4 pF (n = 10) for PCE cells and 38.1 +/- 3.1 pF (n = 15) for NPCE cells. Octanol, carbachol (CCh), and raised extracellular Ca2+ concentration ([Ca2+]o) all caused uncoupling in pairs (couplets) of coupled NPCE and PCE cells. At room temperature (22-24 degrees C), the capacitance of the couplets decreased from 70.5 +/- 8.0 to 48.0 +/- 5.2 pF (n = 5) when exposed to octanol (1 mM), from 73.8 +/- 9.2 to 43.2 +/- 9.5 pF (n = 4) when exposed to CCh (100 microM), and from 80.5 +/- 6.7 to 49.9 +/- 7.8 pF (n = 4) when exposed to 10 mM [Ca2+]o. The response to CCh was dose dependent; at higher temperatures of 34-37 degrees C, 10 microM CCh caused a 38% reduction in capacitance, from 53.7 +/- 9.7 to 33.5 +/- 3.3 pF (n = 7) with a half-time of 249 s, and 100 microM CCh caused a 49% reduction in capacitance, from 51.3 +/- 5.6 to 26.0 +/- 2.4 pF (n = 7) with a half-time of 124 s. After pairs uncoupled and the uncoupling agent was washed out, the cell pairs often exhibited an increase in capacitance that we interpreted as "recoupling" or a reopening of the gap junctional communication pathway; the half-time for this process was 729 s after uncoupling with 100 microM CCh and 211 s after uncoupling with 10 microM CCh. This interpretation was confirmed optically by the spread of lucifer yellow into both cells of an uncoupled pair with a time course corresponding to the increase in electrical coupling. The controllable coupling of ciliary epithelial cells extends the idea of a functional syncytium involved in active transport. PCE cells take up solute and water from the blood, which then cross to NPCE cells via gap junctions and from there are secreted into the posterior chamber of the eye. Modulation of the coupling between NPCE and PCE cells may provide a mechanism to control secretion.

Inwardly rectifying, voltage-dependent and resting potassium currents in rat pancreatic acinar cells in primary culture

1. In exocrine pancreatic acinar cells in primary culture an inwardly rectifying, a voltage-dependent and a permanent resting K+ current were characterized. 2. Inwardly rectifying K+ currents could be elicited by elevation of the extracellular K+ concentration. The K+ inward currents were almost completely blocked by 5 mM Ba2+, whereas 10 mM TEA+ had only a partial effect. 3. Depolarizing voltage steps from negative clamp potentials evoked transient activation of a voltage-dependent K+ current. This voltage-dependent current could be blocked by 10 mM TEA+ and 1 mM 4-aminopyridine, but not by 5 mM Ba2+. 4. Neither the K+ inward rectifier nor the voltage-dependent K+ conductance produced a significant negative cell potential. Stable membrane potentials (-38.7 +/- 2.3 mV, n = 38) could only be recorded on cell clusters (> or = 5 cells). 5. Cell clusters, in contrast to single cells, had a permanent resting K+ conductance in addition to the inward rectifier and the voltage-dependent current. This resting K+ conductance was not blocked by TEA+, Ba2+, 4-aminopyridine or by the chromanol 293B. 6. Cytosolic alkalization by addition of NH4Cl to the bath solution decreased the resting K+ current. In parallel, electrical uncoupling of the cells and breakdown of the resting potential could be observed. The same effects could be produced when the cells were uncoupled by 0.2-1.0 mM n-octanol. It can be concluded that cell coupling is essential for maintenance of stable resting membrane potentials in pancreatic acinar cells.

Synchronized calcium spiking resulting from spontaneous calcium action potentials in monolayers of NRK fibroblasts

The correlation between the intracellular Ca2+ concentration ([Ca2+]i) and membrane potential in monolayers of density-arrested normal rat kidney (NRK) fibroblasts was investigated. Using the fluorescent probe Fura-2, spontaneous repetitive spike-like increases in [Ca2+]i (Ca2+ spikes) were observed that were synchronised throughout the entire monolayer. Ca2+ spikes disappeared in Ca(2+)-free solutions and could be blocked by the L-type Ca2+ channel antagonist felodipine. Simultaneous measurements of [Ca2+]i and membrane potential showed that these Ca2+ spikes were paralleled by depolarisations of the plasma membrane. Using patch clamp measurements, action potential-like depolarisations consisting of a fast spike depolarisation followed by a plateau phase were seen with similar kinetics as the Ca2+ spikes. The action potentials could be blocked by L-type Ca2+ channel blockers and were dependent on extracellular Ca2+. The plateau phase was predominantly determined by a Cl- conductance and was dependent on intracellular Ca2+. The presence of voltage-dependent L-type Ca2+ channels in NRK cells was confirmed by patch clamp measurements in single cells. It is concluded that monolayers of density-arrested NRK fibroblasts exhibit spontaneous Ca2+ action potentials leading to synchronised Ca2+ spiking. This excitability of monolayers of fibroblasts may represent a novel Ca2+ signaling pathway in electrically coupled fibroblasts, cells that were hitherto considered to be inexcitable.

Gap junctions equalize intracellular Na+ concentration in astrocytes

Gap junctions between glial cells allow intercellular exchange of ions and small molecules. We have investigated the influence of gap junction coupling on regulation of intracellular Na+ concentration ([Na+]i) in cultured rat hippocampal astrocytes, using fluorescence ratio imaging with the Na+ indicator dye SBFI (sodium-binding benzofuran isophthalate). The [Na+]i in neighboring astrocytes was very similar (12.0 +/- 3.3 mM) and did not fluctuate under resting conditions. During uncoupling of gap junctions with octanol (0.5 mM), baseline [Na+]i was unaltered in 24%, increased in 54%, and decreased in 22% of cells. Qualitatively similar results were obtained with two other uncoupling agents, heptanol and alpha-glycyrrhetinic acid (AGA). Octanol did not alter the recovery from intracellular Na+ load induced by removal of extracellular K+, indicating that octanol's effects on baseline [Na+]i were not due to inhibition of Na+, K+-ATPase activity. Under control conditions, increasing [K+]o from 3 to 8 mM caused similar decreases in [Na+]i in groups of astrocytes, presumably by stimulating Na+, K+-ATPase. During octanol application, [K+]o-induced [Na+]i decreases were amplified in cells with increased baseline [Na+]i, and reduced in cells with decreased baseline [Na+]i. This suggests that baseline [Na+]i in astrocytes "sets" the responsiveness of Na+, K+-ATPase to increases in [K]o. Our results indicate that individual hippocampal astrocytes in culture rapidly develop different levels of baseline [Na+]i when they are isolated from one another by uncoupling agents. In astrocytes, therefore, an apparent function of coupling is the intercellular exchange of Na+ ions to equalize baseline [Na+]i, which serves to coordinate physiological responses that depend on the intracellular concentration of this ion.

Asymmetric gap junctional coupling between glial cells in the rat retina

Gap junctional communication between glial cells is thought to play a role in K+ spatial buffering, in the propagation of inter-astrocytic Ca2+ waves, and in glial-neuronal signaling. In the present study, we characterize dye coupling between astrocytes, and between astrocytes and Müller cells, in the isolated rat retina. Whole-cell patch recordings were obtained from retinal astrocytes and Müller cells and the cells filled with Lucifer Yellow and neurobiotin. Spread of Lucifer Yellow to two to ten neighboring astrocytes occurred in 90% of the astrocyte recordings. After fixation and incubation of the retina with fluorescent conjugated streptavidin, neurobiotin was seen to label clusters of 13-88 astrocytes, as well as > 100 Müller cells. In contrast, when Müller cells were filled with Lucifer Yellow and neurobiotin, both tracers were confined solely to the recorded Müller cell. The uncoupling agents octanol, halothane, and doxyl-stearic acid were tested for their ability to uncouple retinal glia in situ. All three agents eliminated the visible spread of Lucifer Yellow from the injected astrocyte and the spread of neurobiotin into Müller cells. However, only doxyl-stearic acid combined with octanol eliminated the spread of neurobiotin between astrocytes. These results demonstrate that astrocytes in the rat retina are coupled to each other and to Müller cells. The astrocyte-to-Müller cell coupling is asymmetric, allowing transfer of the tracer in the forward direction only. In addition, astrocyte-to-Müller cell coupling is more sensitive to the uncoupling agents tested than is astrocyte-to-astrocyte coupling.

Synchronized Ca2+ oscillations induced in Madin Darby canine kidney cells by bradykinin and thrombin but not by ATP

In an earlier report, we described synchronous Ca2+ oscillations in globally stimulated, subconfluent MDCK cells [Røttingen J-A, Enden T., Camerer E., Iversen J-G., Prydz H. Binding of human factor VIIa to tissue factor induces cytosolic Ca2+ signals in J82 cells, transfected COS-1 cells, Madin-Darby canine kidney cells and in human endothelial cells induced to synthesize tissue factor. J Biol Chem 1995; 270: 4650-4660]. In order to elucidate the mechanisms behind these oscillations, we have analyzed the fluctuations in cytosolic Ca2+ in single, Fura-2 loaded, MDCK cells grown to subconfluence, after stimulation with bradykinin, thrombin and ATP. All three agonists gave rise to an initial Ca2+ spike followed by oscillations or transients. Both the initial and subsequent spikes appeared to be due mainly to release of Ca2+ from internal stores, since they remained after Ca2+ influx was impeded by either La3+ or by chelation of extracellular Ca2+ with EGTA. The secondary spikes were apparently synchronized when the cells were (permanently and globally) stimulated with bradykinin or thrombin, but each cell seemed to oscillate independently when stimulated in the same way with ATP. Synchronized secondary spikes arose with a constant frequency and amplitude, independent of agonist concentration in contrast to most Ca2+ oscillations observed. Pretreatment of the cells with octanol to block gap junctions, or with EGTA or La3+ to inhibit Ca2+ influx, abolished the synchronization induced by bradykinin or thrombin. We observed that in the MDCK cell layer there are some "pacemaker' cells and hypothesize that these have a higher sensitivity for the agonists than their neighboring cells. From these pacemakers, an intercellular Ca2+ wave can be seen to spread to adjacent cells in the presence of intact gap junctions, thereby initiating concurrent transients in all cells. The Ca2+ wave is amplified by release from internal stores, probably owing to the bell-shaped Ca2+ activation curve of the IP3 receptor and by subsequent Ca2+ influx through Ca2+ release activated channels.

Involvement of pre- and postsynaptic mechanisms in posttetanic potentiation at Aplysia synapses

Posttetanic potentiation (PTP) is a common form of short-term synaptic plasticity that is generally thought to be entirely presynaptic. Consistent with that idea, PTP of evoked excitatory postsynaptic potentials at Aplysia sensory-motor neuron synapses in cell culture was reduced by presynaptic injection of a slow calcium chelator and was accompanied by an increase in the frequency but not the amplitude of spontaneous excitatory postsynaptic potentials. However, PTP was also reduced by postsynaptic injection of a rapid calcium chelator or postsynaptic hyperpolarization. Thus, PTP at these synapses is likely to involve a postsynaptic induction mechanism in addition to the known presynaptic mechanisms.

Intercellular communication between dorsal root ganglion cells and colonic smooth muscle cells in vitro

The mechanism(s) by which intestinal smooth muscle tension is signaled to extrinsic primary afferent neurons is poorly understood. In order to characterize myocyte-neuron communication, we developed a coculture system using rat dorsal root ganglion (DRG) neurons and myocytes obtained from the circular muscle layer of the rat distal colon. Both cell types maintained their phenotype in culture, as demonstrated by positive immunocytochemical staining for neuron-specific enolase and smooth muscle actin. Myocytes showed mechanosensitivity in the form of increases in [Ca2+]i in response to light mechanical touch of the plasma membrane. This increase in [Ca2+]i was independent of extracellular Ca2+ and passed as a propagated wave from muscle cells into adjacent DRG neurites. The inhibitory effect of octanol on this intercellular propagation suggests propagation of [Ca2+]i gradients via heterologous gap junctions. This preparation may serve a useful model system for the study of the interaction of visceral afferents and their target cells.

A caffeine/ryanodine-sensitive Ca2+ pool is involved in triggering spontaneous variations of Ca2+ in Jurkat T lymphocytes by a Ca(2+)-induced Ca2+ release (CICR) mechanism

Caffeine and ryanodine triggered an increase in [Ca2+]i (73 +/- 22 and 61 +/- 18 nM, respectively) in Jurkat cell populations that was independent of external Ca2+. In individual cells, caffeine and ryanodine induced Ca2+ spikes. Jurkat cell populations initially exposed to caffeine did not respond further to ryanodine and vice versa, suggesting an overlap of the Ca2+ pool that was contained within the thapsigargin-sensitive Ca2+ reserve. [3H]ryanodine bound to a single class of sites of Jurkat microsomes (KD, 18.4 +/- 5.7 nM; Bmax, 24.3 +/- 7.7 fmol/mg protein). Photolytic release (Nitr5) of caged Ca2+ induced a time-dependent increase of Ca2+ in individual Jurkat cells. The profile of the release of Ca2+ was characterized, 1) by a kinetic (0.55 +/- 0.07 nM s-1) slower than the Ca2+ response to caffeine (3.93 +/- 0.66 nM s-1) or to ryanodine (3.96 +/- 0.94 nM s-1), 2) by a release of Ca2+ (131 +/- 43 nM) that slowly returned to baseline and during which low amplitude oscillations were present (room temperature) or Ca2+ spikes (37 degrees C) and, 3) by a lack of dependency on an influx of Ca2+. Inhibitors of CICR (ruthenium red and 1-octanol) prevented the photolysis-dependent increase in [Ca2+]i but not the InsP3-dependent Ca2+ response. Our data suggest that Jurkat T cells possess at least two Ca2+ pools, one that is sensitive to InsP3 and one that is insensitive. These two Ca2+ pools may be involved in a CICR that generates spontaneous Ca2+ spikes and oscillations in these cells.

Triggered propagated contractions in rat cardiac trabeculae. Inhibition by octanol and heptanol

We studied the role of Ca2+ diffusion through gap junctions (GJs) in triggering and propagation of damage-induced contractions in cardiac muscle (TPCs) by evaluating effects of the GJ blockers octanol and heptanol (O&H) on TPCs. TPCs were elicited in trabeculae from rat right ventricle superfused with Krebs-Henseleit solution at 20 degrees C and 0.7 to 1.75 mmol/L [Ca2+]o. Force was measured with a silicon strain gauge; sarcomere length, by laser diffraction techniques. O&H (3 to 300 mumol/L) decreased force, propagation velocity, and triggering rate of TPCs in a dose-dependent manner. At 300 mumol/L, O&H decreased TPC force to 21.3% and 25.7%, propagation velocity to 15.4% and 13.0%, and triggering rate to 26.5% and 25.7%. At 300 mumol/L. O&H decreased twitch force to 79.0% and 77.8% and reduced time to 90% relaxation by 10% to 15%. Above 1 mmol/L, O&H abolished twitch force and TPCs. Image analysis of spread of the fluorescence profile of microinjected fura 2 salt revealed an effective diffusion coefficient for fura 2 of 21.0 +/- 3.3 microns2/s, which decreased to 12.6+/-1.5 and 7.07 +/- 0.7 microns2/s after 1 and 3 hours of exposure, respectively, to 100 mumol/L octanol, with a time constant of decline of 1.5+/-0.5 hours. These results are consistent with the hypothesis that propagation of TPCs is due to Ca(2+)-induced Ca2+ release mediated by Ca2+ diffusion from cell to cell through GJs. Reduction of propagation velocity reduces the number of activated sarcomeres in the TPC, which reduces TPC force. O&H slow triggering of TPCs, presumably by blocking Ca2+ diffusion from myocytes within damaged areas to adjacent normal cells.

Inhibition of nitric oxide-induced vasodilation by gap junction inhibitors: a potential role for a cGMP-independent nitric oxide pathway

Studies have provided evidence for the role of gap junctional intercellular communication in syncytial tissue function. This study tested the hypothesis that the vasodilating effects of nitric oxide (NO) rely on gap junctions. The effects of the gap junction inhibitors octanol (10(-4) mol/l) and heptanol (10(-3) mol/l) were examined on acetylcholine-, the NO-donor S-nitroso-N-acetyl-penicillamine (SNAP)-, and guanosine-3',5'-cyclic monophosphate (cGMP)-induced relaxation. In addition, we tested varying concentrations of the gap junction inhibitor sucrose on SNAP-induced relaxation in the presence and absence of methylene blue, an inhibitor of guanylate cyclase. Helical strips of rat thoracic aorta were placed in muscle baths for isometric force measurements. Tissues treated with SNAP and cGMP were denuded of endothelium. Tissues incubated in octanol and heptanol exhibited 4- to 7-fold rightward shifts in acetylcholine-induced and 6- to 15-fold rightward shifts in SNAP-induced relaxation. Both octanol and heptanol produced 2-fold rightward shifts in cGMP-induced relaxation, comparably less in magnitude than shifts produced in acetylcholine- and SNAP-induced relaxation. Sucrose (10(-2) to 10(-1) mol/l) produced a concentration-dependent rightward shift of up to 30-fold in relaxation to SNAP. Incubation with methylene blue (10(-6) mol/l) altered this rightward shift only slightly, indicating a possible cGMP-independent mechanism for NO. These findings support the hypothesis that NO-induced vasodilation, through both cGMP-dependent and -independent pathways, relies on gap junctional communication.

Steroid hormone effects on intercellular communication between term pregnant human myometrial cells before labor

The appearance of gap junctions (GJs) between myometrial smooth muscle cells is one of the major events associated with the onset of labor. We have employed dye-coupling and electrical-current injection techniques to study the mechanisms by which steroid hormones regulate GJs in term pregnant myometrium of women before labor. Progesterone (P4) did not alter the input resistance (Ro) of the tissues when added to Tyrode's solution, which was used as control treatment. Octanol, the putative gap junctional uncoupling agent, increased the Ro of the cells compared to the control and P4-treated groups. The membrane potential (Em) did not differ between these groups. However, when P4 was applied after the tissue was perfused with estradiol (E2), the results changed dramatically: the Em hyperpolarized, and the Ro increased. Octanol increased the Ro in E2-treated tissues, but did not affect the Em. Consecutive application of E2, octanol, E2, and P4 resulted in rapid changes in the Ro of the cells. Dye-coupling was mostly detected between cells from controls and E2-treated tissues. These results indicate that P4 exerts its effects in the presence of E2 and that P4 has rapid effects on the intercellular communication between human myometrial cells.

Are there functional gap junctions or junctional hemichannels in macrophages?

The existence of functional gap junctions in migratory cells of the immune system is a controversial issue. In this report, we have focused on one particular cell type, namely the macrophages, because connexin-43, a protein that forms gap junctions, has been described in peritoneal macrophages and a macrophage cell line (J774), by Northern and Western blot analysis. To test whether these cell types expressed functional gap junctions, we assayed dye coupling by intracellular injection of Lucifer Yellow. We observed that nonstimulated macrophages are not coupled among themselves and did not form functional gap junctions with an epithelial cell line, which expresses functional gap junctions formed by connexin-43. Dye coupling was also not detected between macrophages previously activated by lipopolysaccharide or interferon-gamma. We further examined the presence of functional coupling using the more sensitive technique of dual whole cell patch-clamp, and again, did not find electrical coupling between macrophages, consistent with the dye microinjection data. We also examined the possible presence of hemigap junction channels activated by extracellular adenosine triphosphate (ATP) using a dye uptake assay and the whole cell patch-clamp technique. Conditions expected to close gap junction hemichannels (exposure to octanol and low intracellular pH) did not decrease ATP-induced Lucifer Yellow uptake, whereas conditions expected to increase hemichannel opening either did not affect ATP permeabilization (dibutyryl adenosine monophosphate) or decreased it (zero extracellular CA+2). Finally, in experiments using resident macrophages derived from conexin-43 knockout mice, we observed ATP induced dye uptake. Our experimental data thus indicate that macrophages in vitro do not form functional gap junctions and that the permeability pathway activated by extracellular ATP is not formed by a hemigap junction channel.

Are there functional gap junctions or junctional hemichannels in macrophages?

The existence of functional gap junctions in migratory cells of the immune system is a controversial issue. In this report, we have focused on one particular cell type, namely the macrophages, because connexin-43, a protein that forms gap junctions, has been described in peritoneal macrophages and a macrophage cell line (J774), by Northern and Western blot analysis. To test whether these cell types expressed functional gap junctions, we assayed dye coupling by intracellular injection of Lucifer Yellow. We observed that nonstimulated macrophages are not coupled among themselves and did not form functional gap junctions with an epithelial cell line, which expresses functional gap junctions formed by connexin-43. Dye coupling was also not detected between macrophages previously activated by lipopolysaccharide or interferon-gamma. We further examined the presence of functional coupling using the more sensitive technique of dual whole cell patch-clamp, and again, did not find electrical coupling between macrophages, consistent with the dye microinjection data. We also examined the possible presence of hemigap junction channels activated by extracellular adenosine triphosphate (ATP) using a dye uptake assay and the whole cell patch-clamp technique. Conditions expected to close gap junction hemichannels (exposure to octanol and low intracellular pH) did not decrease ATP-induced Lucifer Yellow uptake, whereas conditions expected to increase hemichannel opening either did not affect ATP permeabilization (dibutyryl adenosine monophosphate) or decreased it (zero extracellular CA+2). Finally, in experiments using resident macrophages derived from conexin-43 knockout mice, we observed ATP induced dye uptake. Our experimental data thus indicate that macrophages in vitro do not form functional gap junctions and that the permeability pathway activated by extracellular ATP is not formed by a hemigap junction channel.

Fast Na+ spike generation in dendrites of guinea-pig substantia nigra pars compacta neurons

Electric fields were applied to study the regenerative properties of substantia nigra pars compacta neurons in guinea-pig brain slices. Two types of spikes, of high or low amplitude, were generated in both the soma-hyperpolarizing and the soma-depolarizing directions of the field. The different sensitivity of the spikes to somatic polarization suggested that the high-amplitude spikes were generated near the cell body, whereas the low-amplitude spikes were generated at a distance from the soma. Application of tetrodotoxin or intracellular injection of QX 314 abolished both types of spike. The spikes were not inhibited in the presence of glutamate receptor antagonists or during Ca2+ channel blockade. Blockers of gap junctional conductance (sodium propionate, octanol and halothane) did not affect the field-induced spikes. The spike generation was highly sensitive to changes in membrane conductance induced by current injection in the soma or by external field application. The ability of a conditioning field stimulation to affect the spike generation in different neuronal compartments suggested that a transient outward current was generated in the dendrites. The field-induced spikes were facilitated by synaptic stimulation and, in some neurons, low-amplitude spikes were generated by synaptic potentials in the absence of field application. These results suggest that channels responsible for Na+ spike generation reside in the dendrites, and are influenced by spatially distributed voltage-dependent K+ currents and by synaptic input.

Intercellular calcium waves in neurons

Spontaneous intercellular Ca2+ waves were observed in groups of neurons in two different culture preparations: primary mouse cortical neurons and GT1-1 immortalized neurons. Waves of increased intracellular Ca2+ concentration propagated at rates of 100-200 microns/s over as many as 200 cells and were abolished by the removal of extracellular calcium, by nimodipine, by tetrodotoxin, and by the gap junction inhibitor octanol. A sister clone of the GT1 line, GT1-7 neurons, showed no intercellular Ca2+ waves and were found to have a significantly lower level of connexin26 mRNA than the GT1-1 line. Although we cannot definitively rule out a role for synaptic communication, we propose that intercellular Ca2+ waves in cultured neurons are generated by Ca2+ influx caused primarily by the propagation of depolarization via gap junctions. Intercellular Ca2+ signaling via gap junctions may represent an important mechanism for nonsynaptic neuronal signaling.

Inhibition of gap junction intercellular communications of cultured rat hepatocytes by ethanol: role of ethanol metabolism

BACKGROUND/AIMS

In a previous study, we reported that in cultured rat hepatocytes, ethanol inhibits intercellular communication which is known to play a central role in the regulation of cell growth and differentiation. This work was designed to find out if ethanol exerts a direct action on cell membranes, comparable to other long-chain (C6-C9) alcohols, or an indirect action.

METHODS

Intercellular communication was measured on short-term cultured rat hepatocytes by the fluorescent Lucifer-Yellow CH transfer method. Intracellular pH was measured by spectrofluorimetry and membrane expression of connexin 32 by indirect immunofluorescence.

RESULTS

Under our conditions, ethanol (20 mM) inhibited intercellular communication of hepatocytes to the same extent as did octanol and 1 mM. Immunofluorescence semi-quantitative studies of connexin 32 suggested that the observed inhibition was not related to a decrease in the number of gap junction plaques. In contrast with those of octanol, the inhibitory effects of ethanol appeared to be indirect because the inhibition of ethanol metabolism by 4-methyl pyrazole abolished its effects on intercellular communication, while 4-methyl pyrazole did not influence the effects of octanol. Acetaldehyde, the main metabolite of ethanol was without effect on gap junctions.

CONCLUSIONS

This suggests that the inhibition of intercellular communication induced by ethanol may be included among the consequences of intermediary cell metabolism disturbances indirectly due to ethanol oxidation. This may be one of the mechanisms by which ethanol metabolism exerts a hepatotoxic possibly carcinogenic action.

Determination of gap junctional intercellular communication by capacitance measurements

Electrical coupling between cells is usually measured using the double-patch-clamp technique with cell pairs. Here, a single patch-clamp technique that is not limited to cell pairs is described to determine electrical coupling between cells. Capacitance measurements in clusters of normal rat kidney (NRK) fibroblasts were used to study intercellular communication. In the whole-cell patch-clamp configuration capacitive transients were evoked by applying small voltage pulses. Total membrane capacitance was calculated from these capacitive transients after determination of access resistance, membrane conductance, and the decay constant of the transients, or alternatively by integrating the current transient. We found that in clusters of one to ten cells, membrane capacitance increased linearly with cell number, showing that the cells are electrically coupled. Membrane conductance of the cluster of cells also increased, as expected for cells that are well coupled. In subconfluent and confluent cultures, high membrane conductances together with large capacitive transients were observed, indicative of electrical coupling. Capacitance could only be determined qualitatively under these conditions, due to space clamp problems. In the presence of the gap junctional inhibitors halothane, heptanol or octanol, capacitance of all clusters of cells fell to single-cell levels, showing a complete uncoupling of the cells. The tumour promoter 12-O-tetradecanoylphorbol-13-acetate (TPA) also uncoupled the cells completely, with 10 min. We conclude that capacitance measurements can provide a useful tool to study changes in intercellular communication in clusters of cells.

Octanol, a gap junction uncoupling agent, changes intracellular [H+] in rat astrocytes

Octanol rapidly closes gap junction channels but its mechanism of action is not known. Because intracellular [H+], pHi, also affects the conductance of gap junctions, we studied octanol's effects on pHi in cultured rat astrocytes, which are highly coupled cells. Octanol (1 mM) caused an acid shift in the pHi of 90% of rat hippocampal astrocytes which averaged -0.19 +/- 0.09 pH units in magnitude. In 58% of the cells tested, a biphasic change in pHi was seen; octanol produced an initial acidification lasting approximately 10 min that was followed by a persistent alkalinization. The related gap junction uncoupling agent, heptanol, had similar effects on pHi. Octanol-induced changes in pHi were similar in nominally HCO(3-)-free and HCO(3-)-containing solutions, although the rate of initial acidification was significantly greater in the presence of HCO3-. The initial acidification was inhibited in the presence of the stilbene DIDS, an inhibitor of Na+/HCO3- cotransport, indicating that octanol caused acidification by blocking this powerful acid extruder. The alkalinization was inhibited by amiloride which blocks the Na+/H+ exchanger (NHE), an acid extruder, suggesting that the alkaline shift induced by octanol was caused by stimulation of NHE. As expected, octanol's effects on astrocytic pHi were prevented by removal of external Na+, which blocks both Na+/HCO3- cotransport and NHE. Octanol had only small effects on intracellular Ca2+ (Ca2+i) in astrocytes. Hepatocytes which, like astrocytes, are strongly coupled to one another, showed no change in pHi with octanol application. Fluorescence recovery after photobleaching (FRAP) was used to study the effect of changes in astrocyte pHi on degree of coupling in hippocampal astrocytes. Coupling was decreased by intracellular acid shifts approximately -0.2 pH units in size. Octanol's effects on astrocyte pHi were complex but a prompt initial acidification was nearly always seen and could contribute to the uncoupling action of this drug in astrocytes. Because octanol uncouples hepatocytes without changing their pHi, this compound clearly can influence gap junctional conductance independent of changes in pHi.

Cyclic AMP induces rapid increases in gap junction permeability and changes in the cellular distribution of connexin43

The rapid effects of cAMP on gap junction-mediated intercellular communication were examined in several cell types which express different levels of the gap junction protein, connexin43 (Cx43), including immortalized rat hepatocyte and granulosa cells, bovine coronary venular endothelial cells, primary rat myometrial and equine uterine epithelial cells. Functional analysis of changes in junctional communication induced by 8-bromo-cAMP was monitored by a fluorescence recovery after photobleaching assay in subconfluent cultures in the presence or absence of 1.0 mM 1-octanol (an agent which uncouples cells by closing gap junction channels). Communicating cells treated with 1.0 mM 8-bromo-cAMP alone exhibited significant increases in the percent of fluorescence recovery which were detected within 1-3 min depending on cell type, and junctional communication remained significantly elevated for up to 24 hr. Addition of 1.0 mM 8-bromo-cAMP to cultured cells, which were uncoupled with 1.0 mM octanol for 1 min, exhibited partial restoration of gap junctional permeability beginning within 3-5 min. Identical treatments were performed on cultures that were subsequently processed for indirect immunofluorescence to monitor Cx43 distribution. The changes in junctional permeability of cells correlated with changes in the distribution of immunoreactive Cx43. Cells treated for 2 hr with 10 microM monensin exhibited a reduced communication rate which was accompanied by increased vesicular cytoplasmic Cx43 staining and reduced punctate surface staining of junctional plaques. Addition of 1.0 mM 8-bromo-cAMP to these cultures had no effect on the rate of communication or the distribution of Cx43 compared to cultures treated with monensin alone. These data suggest that an effect of cyclic AMP on Cx43 gap junctions is to promote increases in gap junctional permeability by increasing trafficking and/or assembly of Cx43 to plasma membrane gap junctional plaques.

Halothane and octanol block Ca2+ oscillations in pancreatic acini by multiple mechanisms

This study has investigated halothane and octanol, reported inhibitors of gap junction permeability, for their effects on acinar cell intracellular Ca2+ concentration ([Ca2+]i) signaling. Halothane and octanol alone at maximal concentrations induced a sustained rise in [Ca2+]i of 23 +/- 4 and 29 +/- 5 nM, respectively. Cholecystokinin (CCK, 20 pM) induced [Ca2+]i oscillations in single acinar cells within the acinus to a peak of 275 +/- 17 nM, rising from a basal level of 55 +/- 3 nM. These oscillations were completely abolished by superfusion with both halothane (4 mM) and octanol (1 mM), concentrations that blocked the spread of Lucifer yellow from cell to cell within an acinus. Lower concentrations of octanol markedly reduced the oscillation frequency (0.2 and 0.5 mM octanol: reduction in oscillation frequency of 69 +/- 6 and 43 +/- 6%, respectively). These agents however, over the same concentration range, also exhibited similar inhibitory effects on [Ca2+]i oscillations in single cells dispersed from the acinus (reduction in oscillation frequency of 75 +/- 10 and 32 +/- 12% for 0.2 and 0.5 mM octanol, respectively), suggesting additional effects other than on gap junctions. Halothane inhibited inositol 1,4,5-trisphosphate [Ins(1,4,5)P3] production in response to both 1 and 10 nM CCK (31 and 40% inhibition, respectively), possibly explaining its effects on [Ca2+]i oscillations, whereas octanol showed no significant inhibition. Octanol, unlike halothane, blocked Ins(1,4,5)P3-induced Ca2+ release from permeabilized acini, an effect that was most pronounced at a more physiological Ins(1,4,5)P3 concentration. Octanol did not affect Ins(1,4,5)P3 binding to Ins(1,4,5)P3 receptor preparation. In conclusion, although halothane and octanol block gap junction permeability in pancreatic acinar cells, these agents also affect Ins(1,4,5)P3 production and Ca2+ mobilization in response to agonist stimulation.