Increase in pancreatic exocrine secretion during uncoupling: evidence for a protein kinase C-independent effect

It has been demonstrated that blockade of the normal communication between pancreatic acinar cells leads to an increase in amylase release. Although the physiological mechanisms that regulate the gating of gap junction channels are unknown, the involvement of protein kinase C (PKC) in the inhibition of cell coupling has been reported in various cell lines. Since the activation of PKC also stimulates amylase secretion of pancreatic acinar cells, we sought to determine whether blockers of gap junctions and activators of PKC modify basal secretion by a similar mechanism. Thus, we have studied the effects of heptanol and of 12-O-tetradecanoylphorbol-13-acetate (TPA) on the subcellular distribution of PKC, dye coupling, and amylase release of dispersed pancreatic acini. The data show that TPA activates PKC and stimulates amylase secretion without affecting the extensive dye coupling of acinar cells. By contrast, heptanol inhibits cell-to-cell coupling and increases enzyme output without altering the subcellular distribution of PKC. Heptanol also enhances significantly the secretion evoked by TPA. These results indicate that the stimulation of amylase release caused by uncoupling of acinar cells occurs by a mechanism(s) that does not involve the activation of PKC.     

Effects of n-alcohols on junctional coupling and amylase secretion of pancreatic acinar cells

We have tested the effects of alcohols differing by their alkyl chain length on the membrane channels and amylase secretion of rat pancreatic acinar cells. In intact acini, alcohols with a chain of seven, eight, or nine carbons (C-7, C-8, and C-9) induced dye uncoupling and increased basal amylase release. These effects were readily reversible after alcohol removal. By contrast, an alcohol with a chain of 15 carbons (C-15) and several alcohols with chains of fewer than six carbons (C-2, C-4, and C-6) did not uncouple acinar cells and had no effects of amylase secretion. Neither did alkanes and oxidized derivatives of C-7 and C-8 alcohols did not affect dye coupling. Double patch-clamp experiments on pairs of acinar cells, under conditions of strong cytosolic Ca2+ and pH buffering, showed that C-7, C-8, and C-9 alcohols blocked completely and reversibly the electrical conductance of junctional channels. Furthermore, studies of single voltage-clamped acinar cells revealed that the uncoupling alcohols did not affect the resting nonjunctional membrane conductances. Thus the alcohols that did not affect acinar cells coupling did not affect amylase secretion, whereas the alcohols that caused uncoupling increased secretion. The latter effect was not mediated by changes in the conductance of nonjunctional membrane, cytosolic Ca2+, and pH and, as revealed by an immunological hemolytic plaque assay for amylase, had a time course consistent with the rapid (within 1 min) inhibition of coupling. These data provide new support for the view that the regulation of cell-to-cell communications is correlated with that of digestive enzyme secretion.     

Heterogeneity and contact-dependent regulation of amylase release by individual acinar cells

We have used a reverse hemolytic plaque assay to investigate the amylase release of single and aggregated pancreatic acinar cells. We have found that a minority of single acinar cells released detectable amounts of amylase under basal conditions and were modestly stimulated, in a dose-dependent manner, during a 30-min exposure to concentrations of carbamylcholine (CCh) ranging from 10^?8 to 10^?5 M. This stimulation was largely accounted for by the recruitment of additional secreting cells, rather than by a significant increase in their individual secretory output. We have also observed that aggregates comprising two to five acinar cells secreted more frequently and released more amylase than single acinar cells in the presence of each of the CCh concentrations tested. Under both basal conditions and following CCh stimulation, the proportion of secreting aggregates and their amylase output increased linearly with the aggregate size. Under basal conditions as well as in the presence of secretagogue concentrations in the 10^?8?10^?7 M range, individual cells contributed similarly to amylase secretion whether they were single or part of aggregates. By contrast, following stimulation by 10^?6?10^?5 M CCh, aggregated cells showed a much higher average secretion than single cells. Investigating the mechanism of this contact-dependent effect, we found that 10^?3 M heptanol did not significantly modify the secretion of single cells and markedly promoted the basal amylase release of acinar cell pairs. This effect was associated with a marked reduction in gap junctional communication between acinar cells, as evaluated by microinjection of Lucifer yellow, and was not observed during exposure to high concentrations of CCh, which also reduced junctional communication. These data show that pancreatic acinar cells are intrinsically heterogeneous in their ability to release amylase and that their basal as well as stimulated secretion are promoted by the establishment of direct intercellular contacts. Our experiments also suggest that junctional coupling contributes to the contact-dependent mechanism which enhances the recruitment of secreting cells and their individual output. These observations strengthen the view that direct interactions between acinar cells are essential in the control of pancreatic secretion. © 1994 Wiley-Liss, Inc.     

Rapid in vitro formation of smooth endoplasmic reticulum aggregates within peptide-producing islet cells

We report here that heptanol (3.5 mM) induces in vitro a rapid formation of smooth endoplasmic reticulum aggregates (SERA) within isolated islets of Langerhans. SERA appeared after only 15 min of exposure to the alkanol and increased in number during the first 30 min of incubation. At that time, SERA represented 2% and 6% of the volume of B- and non-B-cells, respectively. Removal of heptanol resulted in the rapid disappearance of SERA, whereas reintroduction of the alkanol rapidly induced these structures again. SERA formation was seen in different types of endocrine and nonendocrine islet cells. In the insulin-producing B-cells, SERA formation was not modified by conditions known to alter the secretory activity and the microtubular-microfilament network or to inhibit protein synthesis. By contrast, SERA formation was inhibited by low temperature and by conditions depleting the energy sources of the cells. Similar observations were made in the presence of either octanol (1 mM) or nonanol (1 mM) but not of shorter chain alkanols, alkanes, oxidative derivates of either heptanol or octanol, and of other unrelated lipid-soluble compounds. Incubations in the presence of long-chain alkanols provide, therefore, a unique model to study in vitro the formation and disposal of smooth endoplasmic reticulum, as well as a system in which rapid membrane biogenesis is amenable to direct experimental testing.     

Synchronization of Ca(2+)-signals within insulin-secreting pseudoislets: effects of gap-junctional uncouplers

The secretory response of the intact islet is greater than the response of individual beta-cells in isolation, and functional coupling between cells is critical in insulin release. The changes in intracellular Ca(2+)([Ca(2+)](i)) which initiate insulin secretory responses are synchronized between groups of cells within the islet, and gap-junctions are thought to play a central role in coordinating signalling events. We have used the MIN6 insulin-secreting cell line, to examine whether uncoupling gap-junctions alters the synchronicity of nutrient- and non-nutrient-evoked Ca(2+)oscillations, or affects insulin secretion. MIN6 cells express mRNA species that can be amplified using PCR primers for connexin 36. A commonly used gap-junctional inhibitor, heptanol, inhibited glucose- and tolbutamide-induced Ca(2+)-oscillations to basal levels in MIN6 cell clusters at concentrations of 0.5 mM and greater, and it had similar effects in pseudoislets when used at 2.5 mM. Lower heptanol concentrations altered the frequency of Ca(2+)transients without affecting their synchronicity, in both monolayers and pseudoislets. Heptanol also had effects on insulin secretion from MIN6 pseudoislets such that 1 mM enhanced secretion while 2.5 mM was inhibitory. These data suggest that heptanol has multiple effects in pancreatic beta-cells, none of which appears to be related to uncoupling of synchronicity of Ca(2+)signalling between cells. A second gap-junction uncoupler, 18 alpha-glycyrrhetinic acid, also failed to uncouple synchronized Ca(2+)-oscillations, and it had no effect on insulin secretion. These data provide evidence that Ca(2+)signalling events occur simultaneously across the bulk mass of the pseudoislet, and suggest that gap-junctions are not required to coordinate the synchronicity of these events, nor is communication via gap junctions essential for integrated insulin secretory responses.     

Gap junctional communication of primary human keratinocytes: characterization by dual voltage clamp and dye transfer.

We have compared dye coupling in pairs of small (less than 10 microns in diameter) and large (greater than 20 microns in diameter) keratinocytes isolated from normal human epidermis, using Lucifer yellow microinjection. Under control conditions, dye coupling was found in only 1 out of the 25 small pairs tested, whereas it was evident in 75% of the large pairs (n = 52). After a 30-min incubation of the latter pairs in the presence of 10(-6) and 10(-4) M all-transretinoic acid (RA), the percentage of coupling was 53% (n = 15; NS) and 7% (n = 14; P less than 0.001), respectively. The almost complete uncoupling observed after 10(-4) M RA was not reversible even 30 min after return to control medium (n = 8). Dual whole-cell patch-clamp recordings from large keratinocyte pairs showed a macroscopic junctional conductance (gj) of 9 +/- 2 nS (n = 43), which was abolished by heptanol (3.5 mM) in a fully reversible way. Compared to heptanol, 10(-4) M RA abolished keratinocyte gj more slowly and irreversibly (n = 10). By contrast, 10(-6) M RA had no significant effect on gj (n = 8). Single-gap junctional channels were also identified between large keratinocytes. Events histograms of 152 transitions from three experiments revealed three main unitary conductances (gamma j) of 45 +/- 4, 78 +/- 4, and 106 +/- 7 pS. The dye coupling results indicate that junctional communication is markedly different in pairs of small and large cells, which showed the phenotype and keratin markers of basal and suprabasal keratinocytes, respectively. In the latter cell type, coupling is ensured by channels of three sizes and is blocked irreversibly by pharmacologic concentrations of RA.     

Ultrastructural aspects of cat submandibular glands

Submandibular glands of five adult female cats were examined by conventional electron microscopic techniques. All gland acini are mucous secreting and each acinus is capped with mucous secreting demilunar cells. Secretory product of demilunar cells is more electron lucent than that of acinar cells. The demilunes show intercellular tissue spaces and intercellular canaliculi whereas similar specializations are absent between acinar cells. Mitochondria and arrays of granular endoplasmic reticulum are more numerous in demilunar cells than in acinar cells. In acinar and demilunar cells secretory droplets first appear as enlarged Golgi saccules which subsequently become closely related to cisternae of the granular endoplasmic reticulum. Filamentous structures, interpreted as mucin molecules, are present in secretory droplets of acinar cells. Intercalated ducts are short, consisting of several junctional cells between acini and striated ducts. Striated ducts are long and tortuous and contain light cells, dark cells and basal cells. Light cells contain numerous membrane bound granules in their distal ends whereas dark cells show electron lucent vesicles in the same position. Basal cells contain a paucity of organelles and membrane plications but exhibit hemidesmosomes along their basal plasma membranes. Myoepithelial cells are abundant in relation to acinar and demilunar cells. Nerve terminals are present in some instances between acinar cells or between acinar and myoepithelial cells.     

Multiple effects of Na+ removal on pancreatic secretion in vitro

Summary The effects of removing Na⁺ from the incubation medium on basal and secretagogue induced zymogen release by pancreatic fragments and isolated pancreatic acini were studied by both morphological evaluation and measurement of amylase release. In both fragments and isolated acini, removal of Na⁺ led to an increased basal secretion of zymogen granule contents from acinar cells via exocytosis; secretory material, however, accumulated in acinar and ductular lumina as a result of the lack of fluid secretion necessary to wash out the enzymes. In studies with fragments, after Na⁺ removal there was no significant increase in amylase release into the medium; isolated acini, in contrast, showed an increased amylase release consistent with the shorter distance from the acinar lumen to the bathing medium. Stimulation with either bethanechol or caerulein led to a further depletion of zymogen granules in both preparations; in the absence of Na⁺ secretory product accumulated in intracellular lakes as well as in duct lumens. The hypothesis that Na⁺ influx is important in stimulus-secretion coupling to release intracellular Ca²⁺ was directly tested by measuring ⁴⁵Ca²⁺ efflux. No effect of removing Na⁺ on ⁴⁵Ca²⁺ efflux was seen. It was concluded, therefore, that while Na⁺ is essential for pancreatic fluid secretion, it is not necessary for the secretion of zymogen granule contents into acinar lumina.Supported by NIH grant GM-19998 from the United States Public Health Service     

Inhibition of CCK or carbachol-stimulated amylase release by nicotine

This study was undertaken to investigate the mechanisms of action of nicotine on receptor mediated enzyme secretion in isolated rat pancreatic acini. Acinar cells were isolated from untreated and nicotine treated rats by collagenase digestion and differential centrifugation. Cells from the untreated animals were incubated with either varying concentrations of nicotine (range 10 microM to 30 mM) or with a fixed dose of 10 mM nicotine with varying concentrations of carbachol(10nM to 100 microM). Cells from the nicotine treated animals(16 weeks in drinking water) were incubated with either a fixed dose of CCK-8(10(-10) M) or carbachol(10(-5) M). All incubations were conducted at 37 C for 30 min. Amylase released in the media was measured by spectrophotometry. In pancreatic acinar cells isolated from control rats, amylase release stimulated by carbachol was inhibited by nicotine. Acinar cells isolated from rats treated with nicotine at nicotine concentrations of 1.23 mM also showed significant inhibition of amylase release in response to CCK-8 and carbachol compared to their identical controls. Nicotine induced inhibition curves of amylase release stimulated by carbachol were non-parallel suggesting that the effect of nicotine on acinar cells is regulated by mechanisms other than carbachol receptors. Nicotine may have a direct inhibitory effect on the intracellular mechanisms of pancreatic enzyme secretion. We conclude that the mechanism by which nicotine inhibits pancreatic enzyme secretion is complex.     

Octanol blocks fluid secretion by inhibition of capacitative calcium entry in rat mandibular salivary acinar cells

The aliphatic alcohol octanol is thought to modulate enzyme secretion from the exocrine pancreas by the inhibition of gap junction permeability. We have now investigated the effects of octanol on salivary secretion and intracellular calcium concentration ([Ca2+]i), measured in isolated perfused rat mandibular glands and in isolated mandibular acinar cells respectively. Stimulation of perfused glands with 10 microM carbachol (CCh) evoked a rapid increase in fluid secretion followed by a decrease to a sustained elevated level. Application of 1 mM octanol during CCh stimulation inhibited fluid secretion reversibly. In isolated acini, the CCh-induced [Ca2+]i increase was reversibly inhibited by the same concentration of octanol. However, octanol also inhibited the increase in [Ca2+]i in single acinar cells where gap junctions were no longer functional, indicating that octanol directly affected the intracellular Ca2+ signalling pathway. The initial increase in [Ca2+]i induced by 0.5-10 microM CCh, which is due to Ca2+ release from IP3-sensitive Ca2+ stores, was not affected by pretreatment with octanol. In contrast, CCh-, phenylephrine- or thapsigargin-induced Ca2+ entry was almost completely and reversibly inhibited by octanol. Octanol also blocked agonist-evoked Ca2+ entry in pancreatic acinar cells, and thapsigargin-evoked Ca2+ entry in fibroblasts. These data strongly suggest that octanol blocks salivary secretion from mandibular gland by the inhibition of capacitative Ca2+ entry, and raise the possibility that octanol may be a useful tool for inhibiting agonist-evoked Ca2+ entry pathways.     

Biophysical properties of gap junctions between freshly dispersed pairs of mouse pancreatic beta cells.

Coupling between beta cells through gap junctions has been postulated as a principal mechanism of electrical synchronization of glucose-induced activity throughout the islet of Langerhans. We characterized junctional conductance between isolated pairs of mouse pancreatic beta cells by whole-cell recording with two independent patch-clamp circuits. Most pairs were coupled (67%, n = 155), although the mean junctional conductance (gj) (215 +/- 110 pS) was lower than reported in other tissues. Coupling could be recorded for long periods, up to 40 min. Voltage imposed across the junctional or nonjunctional membranes had no effect on gj. Up to several hours of treatment to increase intracellular cAMP levels did not affect gj. Electrically coupled pairs did not show transfer of the dye Lucifer yellow. Octanol (2 mM) reversibly decreased gj. Lower concentrations of octanol (0.5 mM) and heptanol (0.5 mM) than required to uncouple beta cells decreased voltage-dependent K+ and Ca2+ currents in nonjunctional membranes. Although gj recorded in these experiments would be expected to be provided by current flowing through only a few channels of the unitary conductance previously reported for other gap junctions, no unitary junctional currents were observed even during reversible suppression of gj by octanol. This result suggests either that the single channel conductance of gap junction channels between beta cells is smaller than in other tissues (less than 20 pS) or that the small mean conductance is due to transitions between open and closed states that are too rapid or too slow to be resolved.     

Guinea pig pancreatic acini prepared with purified collagenase

Dispersed guinea pig pancreatic acinar cells have been used to investigate several aspects of stimulus-secretion coupling but possess the disadvantage that they are less sensitive and less responsive to secretagogues than in vitro preparations of intact pancreatic tissue (lobules). To overcome the poor responsiveness of isolated acinar cells, we have developed a new procedure for preparing dispersed, intact pancreatic acini whose sensitivity to secretagogues and morphological characteristics are similar to those of pancreatic lobules. Dispersed acini can be manipulated as suspensions of cells and full access of macromolecular probes to apical and basolateral plasmalemmal domains is obtained. Acini were prepared in good yields (~70% on a DNA basis) using only purified collagenase and mild mechanical shear in medium containing 2.0 mM Ca²⁺. Morphologically, acinar cells in the preparations retained intact junctional complexes, asymmetrical distribution of intramembranous particles between apical and basolateral plasmalemmal domains, and polarized distribution of intracellular organelles as found in intact pancreas. Dose-response curves of acini and mechanically prepared lobules to caerulein, carbachol, and bombesin were similar though acini were more sensitive to the C-terminal octapeptide of cholecystokinin. Net stimulated secretory protein discharge was ~36% over 2 h. Crude collagenase was purified for use in preparation of acini by Sephadex G-75 column chromatography which resolved collagenase from clostripain and a non-sulfhydryl-requiring protease. The purified collagenase contained at least four proteins with molecular weights between 85 000 and 110 000. Collagenase with <0.14 units of protease per unit of collagenase produced highly responsive acini; collagenase with >0.9 units of protease per unit of collagenase yielded unresponsive acini. Acini incubated with crude collagenase, chymotrypsin, or the non-sulfhydryl-requiring protease showed depressed secretory response to caerulein. Freeze-fracture electron microscopy of protease-treated acini indicated that the intramembranous particles aggregated and that many of the tight junctions had undergone a proliferation of non-cross-linked sealing strands which extended far down the basolateral plasma membrane and encircled gap junctions. Acini incubated with purified collagenase or with a clostripain-containing fraction from the Sephadex G-75 column appeared unaltered. This procedure produces acini which are morphologically and biochemically similar to the in situ pancreas and overcomes the poor response to secretagogues by isolated pancreatic acinar cells.     

Delayed inhibition of gap-junctional intercellular communication in the acinar cells of rat submandibular glands induced by parasympathectomy and cholinergic agonists

In this study, the effects of parasympathectomy and cholinergic agonists on gap-junctional intercellular communication and salivary secretion were investigated to clarify the involvement of salivary secretion in delayed uncoupling between acinar cells of rat submandibular glands. Gap-junctional intercellular communication was monitored as dye-coupling in the acinar cells of isolated acini by the transfer of Lucifer Yellow CH. Parasympathectomy induced dye-uncoupling in the acinar cells isolated from denervated salivary glands 12 hr after parasympathectomy-induced salivary secretion. Intraperitoneal application of carbachol (CCh), acetylcholine, pilocarpine, but not isoproterenol, stimulated salivary secretion, and then induced dye-uncoupling in the acinar cells 12 hr later. Atropine suppressed both the salivary secretion and delayed dye-uncoupling induced by parasympathectomy and CCh, when atropine was applied intraperitoneally before the induction of salivary secretion. However, atropine did not suppress the delayed dye-uncoupling by intraperitoneal application of CCh, when atropine was injected after the cessation of CCh-induced secretion. These results suggest that delayed inhibition of gap-junctional intercellular communication by parasympathectomy and cholinergic agonists in rat submandibular glands might be related to the change of secretory function after salivary secretion.     

Varied effects of 1-octanol on gap junctional communication between ovarian epithelial cells and oocytes of Oncopeltus fasciatus, Hyalophora cecropia, and Drosophila melanogaster

In insect gap junctions, species-specific differences occur in response to the purported gap junction uncoupling agent, 1-octanol. Changes in gap junctional communication between oocytes and their epithelial cells following treatment with 1-octanol were assayed in Oncopeltus fasciatus (the milkweed bug), Hyalophora cecropia (the American silk moth), and Drosophila melanogaster. In all three species, microinjection of untreated control follicles with Lucifer yellow CH revealed extensive dye coupling among epithelial cells and between epithelial cells and their oocytes. Also for all three species, treatment with octanol appeared to completely block dye coupling and increase oocyte input resistance. The effect on electrical coupling varied. In Drosophila, octanol diminished the electrical coupling from 64% (0.64 coupling coefficient) in controls to 53% in treated follicles. In Hyalophora, the coupling ratio remained the same following treatment. In Oncopeltus, octanol actually increased the electrical coupling ratio from 84% in controls to 94% in treated follicles. While 0.5 mM octanol left some Oncopeltus epithelial cells dye coupled to the oocyte, the electrical coupling ratio was increased slightly more by this concentration than by 1 or 5 mM octanol solutions, although the differences were not significant. While input resistance (R(o )) increased in all three following treatment with octanol, there was considerable difference in the magnitude of the response. Average oocyte R(o ) for Oncopeltus increased the least of the three species, rising from 196-240 kOhm. Both Hyalophora, with a nearly fourfold increase from 230-900 kOhm or more, and Drosophila, with a twofold increase from 701 kOhm to over 1.2 MegOhm showed much larger changes. Results shown here indicate that insect gap junctions have more varied responses to this common gap junction antagonist than have been reported for their vertebrate counterparts. Arch.     

Ultrastructure of bovine parotid glands

Bovine parotid glands exhibit outstanding structural differences when compared with those of non-ruminant mammals. The acini are tortuous, branched and lined with cells of different heights, imparting a scalloped appearance to acinar lumina. Numerous microvilli, ca. 1.5 μ in length, extend into the lumina and intercellular canaliculi. Intercellular canaliculi measure ca. 3 μ in diameter and interweave in close association with intercellular tissue spaces. Intercellular tissue spaces are separated from the extraacinar spaces across a basal lamina only, whereas junctional complexes guard canaliculi from direct continuity with tissue spaces and/or extraacinar spaces. Flattened cytoplasmic lamellae extend from adjacent acinar cells and loosely interdigitate with one another across the tissue spaces. Acinar cells contain more mitochondria and less granular endoplasmic reticulum than parotid glands of non-ruminant mammals. Two types of secretory material, in the form of inclusions which vary in size and electron density, are present in the acinar cells. Intercalated ducts connect acini with striated ducts which in turn, empty into collecting ducts located between gland lobules. In terms of frequency of “basal infoldings” and numbers of mitochondria, striated ducts of calf parotid glands are not as well developed as those of certain other salivary glands. Myoepithelial cells are most often present at junctions of acini and intercalated ducts where they may attach to both acinar and ductal epithelium. Nerve “terminals” were not observed on the epithelial side of basement membranes in relation to the secretory cells.     

Electrical coupling and uncoupling of exocrine acinar cells

The electrical communication network in the mouse pancreatic acinar tissue has been investigated using simultaneous intracellular recording with two separate microelectrodes and direct microscopical control of the localizations of the microelectrode tips. All cells within one acinus were electrically coupled, and the coupling coefficient (the electrotonic potential change in a cell neighboring to the cell into which current is injected [V2] divided by the electrotonic potential change in the cell of current injection [V1]) between two cells near each other (less than 50 micron) was always close to 1. Cells farther apart (50-100 micron) were, in some cases, coupled; in other cases, there was no coupling at all. Coupling coefficients varied between 0 and 1. There was rarely electrical coupling over distances of more than 110 micron. Using microiontophoretic acetylcholine (ACh) application, it was possible to evoke almost complete electrical uncoupling of two previously coupled pancreatic or lacrimal acinar cells from different acini or within one acinus. The effects were fully and quickly reversible. While the ACh-evoked uncoupling in the pancreas was associated with membrane depolarization, ACh caused hyperpolarization in the lacrimal acinar cells. The uncoupling was associated with a very marked reduction in electrical time constant, indicating a reduction in input capacitance (effective surface cell membrane area). The concentrations of stimulants needed to evoke reduction in pancreatic cell-to-cell coupling were 1 micron for ACh, 0.14 nM for caerulein, and 3 nM for bombesin. These concentrations are smaller than those required to evoke maximal enzyme secretion.     

Is Intercellular Communication Via Gap Junctions Required for Myoblast Fusion?

Fusion of myoblasts to form syncitial muscle cells results from a complex series of sequential events including cell alignment, cell adhesion and cell communication. The aim of the present investigation was to assess whether intercellular communication through gap junctions would be required for subsequent membrane fusion. The presence of the gap junction protein connexin 43 at areas of contact between prefusing rat L6 myoblasts was established by immunofluorescent staining. These myoblasts were dye-coupled, as demonstrated by the use of the scrape-loading/dye transfer technique. L6 myoblast dye coupling was reversibly blocked by heptanol in short term experiments as well as after chronic treatment. After a single addition of 3.5 mM heptanol, gap junctions remained blocked for up to 8 hours, then this inhibitory effect decreased gradually, likely because the alcohol was evaporated. Changing heptanol solutions every 8 hours during the time course of L6 differentiation resulted in a lasting drastic inhibition of myoblast fusion. We further investigated the effect of heptanol and of other uncoupling agents on the differentiation of primary cultures of embryonic chicken myoblasts. These cells are transiently coupled by gap junctions before myoblast fusion and prolonged application of heptanol, octanol and 18-β-glycyrrhetinic acid also inhibited their fusion. The effect of heptanol and octanol was neither due to a cytotoxic effect nor to a modification of cell proliferation. Moreover, heptanol treatment did not alter myoblast alignment and adhesion. Taken together these observations suggest that intercellular communication might be a necessary step for myoblast fusion.     

Is Intercellular Communication Via Gap Junctions Required for Myoblast Fusion?

Fusion of myoblasts to form syncitial muscle cells results from a complex series of sequential events including cell alignment, cell adhesion and cell communication. The aim of the present investigation was to assess whether intercellular communication through gap junctions would be required for subsequent membrane fusion. The presence of the gap junction protein connexin 43 at areas of contact between prefusing rat L6 myoblasts was established by immunofluorescent staining. These myoblasts were dye-coupled, as demonstrated by the use of the scrape-loading/dye transfer technique. L6 myoblast dye coupling was reversibly blocked by heptanol in short term experiments as well as after chronic treatment. After a single addition of 3.5 mM heptanol, gap junctions remained blocked for up to 8 hours, then this inhibitory effect decreased gradually, likely because the alcohol was evaporated. Changing heptanol solutions every 8 hours during the time course of L6 differentiation resulted in a lasting drastic inhibition of myoblast fusion. We further investigated the effect of heptanol and of other uncoupling agents on the differentiation of primary cultures of embryonic chicken myoblasts. These cells are transiently coupled by gap junctions before myoblast fusion and prolonged application of heptanol, octanol and 18-β-glycyrrhetinic acid also inhibited their fusion. The effect of heptanol and octanol was neither due to a cytotoxic effect nor to a modification of cell proliferation. Moreover, heptanol treatment did not alter myoblast alignment and adhesion. Taken together these observations suggest that intercellular communication might be a necessary step for myoblast fusion.     

Isoproterenol-induced desensitization of mucin release in isolated rat submandibular acini

Release of [14C]glucosamine-labelled mucins was studied in vitro using well-characterised preparations of rat submandibular acini. Mucin release was stimulated by forskolin, an activator of the catalytic subunit of adenylate cyclase, and 3-isobutyl-1-methylxanthine (IBMX), a cyclic nucleotide phosphodiesterase inhibitor. Both stimulated in a dose-dependent manner to the same maximum as that seen with isoproterenol. Neither forskolin nor IBMX added in the presence of isoproterenol increased secretion above the maximum in response to isoproterenol alone, suggesting a similar mechanism of action, mediated by cyclic AMP. Prior exposure of acini to isoproterenol (10 microM) for 45 min, followed by washout resulted in (a) persistent increase in basal secretion which was abolished by propranolol and (b) reduced stimulation of mucin secretion in response to either a second isoproterenol challenge, noradrenaline or forskolin. Thus, exposure of rat submandibular acini in vitro desensitizes the cells to subsequent stimulation. Although this mimics the decreased beta-adrenergic secretory responses seen in submandibular cells from cystic fibrosis patients, results suggest that the isoproterenol-induced desensitization is at the level of beta-receptor and adenylate cyclase, rather than distal to cyclic AMP.