Cyclic AMP has distinct effects from Ca(2+) in evoking priming and fusion/exocytosis in parotid amylase secretion

Rat parotid acinar cells were perfused in small quartz columns to examine the role of cAMP and Ca(2+) in the priming and fusion/exocytosis of amylase secretion. Carbachol (CCh) evoked a biphasic response of amylase secretion with an initial rapidly occurring large peak and a subsequent sustained plateau. Isoproterenol produced slowly increasing amylase secretion that reached the plateau greater than that induced by CCh. Combined stimulation with isoproterenol and CCh greatly potentiated amylase secretion. The rise and decay of amylase secretion induced by the combined stimulation was similar to those induced by CCh but not by isoproterenol, suggesting that the potentiation is caused by isoproterenol-induced modification of the CCh effect. Concentration-dependent responses of CCh-induced amylase secretion with and without isoproterenol showed that isoproterenol greatly enhances both the sensitivity and maximum effect of CCh. Similar potentiation was observed when the Ca(2+) effect was directly examined in cells permeabilized to Ca(2+) with ionomycin instead of CCh. In a Ca(2+)-free medium, CCh evoked an initial peak but did not produce a sustained plateau. Isoproterenol did not enhance the effect of CCh on [Ca(2+)](i). 2,4-Dintrophenol and carbonyl cyanide m-chlorophenyl hydrazone did not decrease the CCh-induced initial peak of amylase secretion but markedly decreased the sustained responses induced by isoproterenol and CCh. These results suggest that CCh, via Ca(2+), has two distinct effects on amylase secretion: triggering of fusion/exocytosis and the priming of secretory granules. Isoproterenol, via cyclic AMP, also has two distinct effects: direct stimulation of priming and enhancement of the sensitivity to the Ca(2+)effects. Thus, isoproterenol stimulates amylase secretion by increasing the primed pools of secretory granules, whereas CCh increases the flux of secretory granules into/from the primed pools, which is greatly enhanced by isoproterenol.     

Cell-enlargement-related polypeptides are induced via beta(1)-adrenoceptors in mouse parotids

Induction of cell and gland enlargement (growth-in-size) and induction of a group of secretory polypeptides (polypeptides C-G) seem to occur in close relationship in mouse parotid glands stimulated chronically by the nonselective beta-adrenergic agonist isoproterenol. To determine whether beta(1), beta(2), or both subtypes of beta-adrenergic receptors are involved in those responses, dose-dependency studies were carried out during a 7-day period of daily stimulations to assess the relative abilities of the selective beta-adrenergic agonists dobutamine (beta(1)) and salbutamol (beta(2)) to induce polypeptides C-G and growth-in-size. The relative abilities of the selective beta-adrenoceptor antagonists atenolol (beta(1)) and I.C.I. 118.551 (beta(2)) to interfere with the induction of both responses by chronic treatment with the various beta-adrenergic agonists were also studied. Parotid growth-in-size was assessed by evaluating wet weight, whole protein content, and light microscopy histology. The presence of polypeptides C-G was evaluated after SDS-polyacrylamide gel electrophoresis and Coomassie blue staining. Under these experimental conditions, dobutamine was found to be at least one order of magnitude more potent than salbutamol at inducing growth-in-size. Dobutamine was also found to be clearly stronger than salbutamol as an inducer of polypeptides C-G. On the other hand, atenolol was more effective than I.C.I. 118.551 at preventing the induction of polypeptides C-G and growth-in-size by isoproterenol, dobutamine, or salbutamol. Taken together, these results suggest that in mouse parotid glands, polypeptides C-G and growth-in-size are induced preferentially via adrenergic receptors of the beta(1)-subtype.     

Beta-adrenergic regulation of secretion from Clara cell adenomas of the mouse lung

Ethylnitrosourea-induced pulmonary adenomas of the mouse have been reported as being predominantly Clara cell in origin. The response of these tumor cells in vivo to the secretory agonist, isoproterenol (10 mg/kg) and the antagonist, propranolol (2.0 mg/kg) 1 hour after intraperitoneal injection into 120-day-old tumor-bearing mice was examined. Ultrastructural morphometry was used to quantitate the secretory response of tumor cells by measuring the volume density of the secretory granules. In the intact animal, isoproterenol stimulated secretion in the Clara cell adenomas (40% decrease in volume density with no change in surface to volume ratio of granules), while propranolol prevented this effect. In addition, beta-adrenergic receptors on isolated tumor cells were demonstrated by radioligand-binding assay by using [125I]iodocyanopindolol (ICYP). Scatchard analysis of data derived from whole cells indicates a maximum receptor-binding capacity of 27 fmoles/mg of protein and a KD of 0.029 nM. Isoproterenol displacement of ICYP binding yields an IC50 of 8 X 10(-7) M and a calculated KD of 3.36 X 10(-7) M. The beta 2 identity of these receptors was determined by utilizing the relatively specific beta 1 and beta 2 antagonists practolol and ICI-118,551, respectively. Practolol failed to displace more than 30% of ICYP binding even at 100 microM, while ICI-118,551 displacement of ICYP yielded a linear Hofstee plot (r = 0.93) and a KD of 5.04 X 10(-9) M. These findings suggest that the secretory activity of Clara cell-like pulmonary adenomas is under beta-adrenergic control similar to that of normal bronchiolar Clara cells.     

Effects of continuous light on rat parotid gland structure and reactivity

Summary The effects of continuous light on ultrastructural organization and sympathetic secretory responses of the rat parotid gland are reported.After 50 days of continuous light exposure, the fine structure of the parotid gland exhibited features of enhanced secretory activity as judged by the striking development of rough endoplasmic reticulum and Golgi complexes, the depletion of secretory granules and the increased turnover of secretory cells. The secretory responses of parotid gland to isoproterenol revealed that continuous light induced a 30% increase in amylase release. This secretory hyperactivity appears to be related to a postsynaptic supersensitivity of sympathetic fibers of the autonomic nervous system.     

Differential distribution of salivary agglutinin and amylase in the Golgi apparatus and secretory granules of human salivary gland acinar cells.

The secretory granules of salivary glands often display complex internal substructures, yet little is known of the molecular organization of their contents or the mechanisms involved in packaging of the secretory proteins. We used post-embedding immunogold labeling with antibodies to two secretory proteins, agglutinin and alpha-amylase, to determine their distribution in the Golgi apparatus and secretory granules of the human submandibular gland acinar cells. With monoclonal antibodies specific for carbohydrate epitopes of the agglutinin, reactivity was found in the trans Golgi saccules, trans Golgi network, and immature and mature secretory granules. In the granules, labeling was seen in regions of low and medium electron density, but not in the dense cores. Reactivity seen on the apical and basolateral membranes of acinar and duct cells was attributed to a shared epitope on a membrane glycoprotein. Labeling with a polyclonal antibody to amylase was found in the Golgi saccules, immature and mature secretory granules, but not in the trans Golgi network. In the granules, amylase was present in the dense cores and in areas of medium density, but not in the regions of low density. These results indicate that these two proteins are distributed differently within the secretory granules, and suggest that they follow separate pathways between the Golgi apparatus and forming secretory granules. Small vesicles and tubular structures that labeled only with the antibodies to the agglutinin were observed on both faces of the Golgi apparatus and in the vicinity of the cell membrane. These structures may represent constitutive secretion vesicles involved in transport of the putative membrane glycoprotein to the cell membrane.     

Differential distribution of salivary agglutinin and amylase in the Golgi apparatus and secretory granules of human salivary gland acinar cells

The secretory granules of salivary glands often display complex internal substructures, yet little is known of the molecular organization of their contents or the mechanisms involved in packaging of the secretory proteins. We used post-embedding immunogold labeling with antibodies to two secretory proteins, agglutinin and α-amylase, to determine their distribution in the Golgi apparatus and secretory granules of the human submandibular gland acinar cells. With monoclonal antibodies specific for carbohydrate epitopes of the agglutinin, reactivity was found in the trans Golgi saccules, trans Golgi network, and immature and mature secretory granules. In the granules, labeling was seen in regions of low and medium electron density, but not in the dense cores. Reactivity seen on the apical and basolateral membranes of acinar and duct cells was attributed to a shared epitope on a membrane glycoprotein. Labeling with a polyclonal antibody to amylase was found in the Golgi saccules, immature and mature secretory granules, but not in the trans Golgi network. In the granules, amylase was present in the dense cores and in areas of medium density, but not in the regions of low density. These results indicate that these two proteins are distributed differently within the secretory granules, and suggest that they follow separate pathways between the Golgi apparatus and forming secretory granules. Small vesicles and tubular structures that labeled only with the antibodies to the agglutinin were observed on both faces of the Golgi apparatus and in the vicinity of the cell membrane. These structures may represent constitutive secretion vesicles involved in transport of the putative membrane glycoprotein to the cell membrane.     

Morphological and histochemical changes in the secretory granules of mucous cells in the early postnatal mouse parotid gland

It has previously been known that the developing parotid glands in humans and rats contain mucous cells in their terminal clusters and acini, but these cells disappear within a short period of time. Using rat parotid glands, IKEDA and AIYAMA (1997, 1999) suggested that the mucous cells might change into serous cells in the early postnatal period, but it is uncertain whether mucous cells appear only in the developing parotid gland of a few species such as humans and rats, or whether the cell transformation actually occurs. To clarify these points, the present study investigated the developing mouse parotid glands. Light microscopy showed cells with secretory granules that stained extensively with PAS and alcian blue in the terminal clusters of a 1-day-old mouse parotid gland. Mucous cell numbers in the terminal clusters and the acini reached a peak on day 5 and decreased on day 7. By day 10, the mucous cells had disappeared altogether. Thus, the presence of mucous cells in the developing mouse parotid gland was confirmed. Electron microscopy showed granules of low-electron-density and bipartite granules in the mucous cells. Bipartite granules and highly electron-dense granules sometimes co-existed in a single cell. Immuno-electron microscopy revealed a positive reaction for amylase to the low-electron-density granules and the low-electron-density portions of the bipartite granules, in addition to the highly electron-dense granules and the electrondense cores of the bipartite granules. No mucous cells with nuclei displaying characteristics of apoptosis were recognizable. Lectin histochemistry both at the light and electron microscopic levels showed that the secretory granules in the mouse parotid gland mucous cells had sugar residues similar to those of the mature serous granules. These findings demonstrate that mucous cells appear in the early postnatal mouse parotid gland, and that almost all of these cells may be converted into serous cells.     

Beta-adrenergic receptors and salivary gland secretion during aging.

Beta-adrenergic signal transduction is primarily responsible for the control of the protein secretions by salivary cells. To examine the relationship between beta-adrenergic signal transduction and beta-adrenergic agonist-stimulated salivary secretion, we simultaneously assessed beta-adrenergic receptor number and pilocarpine-isoproterenol-stimulated salivary flow and secreted proteins in parotid and submandibular glands from 3-, 12- and 24-month-old female NNIA F-344 rats. There were no age-related changes in the density of beta-adrenergic receptors in the parotid gland or in the submandibular gland. In the parotid gland there was a significant increase in saliva flow rate in the oldest age group and no changes in the amount of total proteins secreted over 30 min. However, when normalized to gland weight, flow rate was unchanged and the amount of total secreted proteins decreased with age. In the submandibular gland there were age-related increases in both absolute volume and total secreted protein, but when normalized to gland weight there were no longer changes with age. Changes in flow rate were paralleled by reciprocal changes in protein secretory function such that changes in the salivary protein concentrations for the most part were unchanged with age for both the parotid and the submandibular gland. These parameters were compared to our previous data on adenylate cyclase activity, and collectively, these data suggest that in the submandibular gland salivary secretory function does not correlate with changes in beta-adrenergic receptor density or isoproterenol-stimulated adenylate cyclase activity.     

Ultrastructure of the secretory response of male mouse submandibular gland granular tubules

The organization and fine structure of granular convoluted tubule cells (GCT) from male mouse submandibular glands have been examined in controls and in animals injected with adrenergic and cholinergic secretagogues. Control submandibular glands exhibited a single population of GCT cells with numerous homogeneous granules filling the apical two-thirds of the cytoplasm. A zone of transition cells, exhibiting characteristics of both GCT and striated duct cells, was found between the agranular intercalated duct and GCT segments. These transition cells possessed apical granules of variable size as well as prominent basal striations. Dramatic changes in the morphology of GCT cells followed administration of the alpha-adrenergic agent, phenylephrine. The extensive degranulation involved formation of "secretory pools" of fused granules and release of secretory material into the lumen. The appearance of numerous smooth vesicles near luminal membranes suggested extensive membrane retrieval. Intracellular membrane-limited aggregates of membrane fragments suggested that much of the retrieved membrane was destined for degradation. Rough endoplasmic reticulum was highly dilated but there was no indication of increased size or activity of the Golgi complex. Ultrastructural evidence indicated that the secretory responses to isoproterenol, a beta-adrenergic agent, and to pilocarpine, a cholinergic agent, were much more modest, but it is clear that some secretory response to these agents does occur. The other cell types of the duct and tubule system did not exhibit comparable morphological changes in response to the agents used.     

Exocytosis of secretory granules in the juxtaglomerular granular cells of kidneys

Background: There is little agreement as to the secretory process of renin granules in juxtaglomerular granular cells (JG cells) of kidneys, although a large number of studies of the regulation of renin secretion have been reported. Methods: The structural correlation between the stimuli and the secretory process was examined in mouse JG cells on renal cortical slice incubated with the beta-adrenergic agonist, isoproterenol; the loop diuretic, furocemide; the Ca²⁺ chelator, EGTA; and the actin filament-disrupting agent, cytochalasin B. Results and Conclusions: Treatment with isoproterenol (10⁻⁵−10⁻³ M) or furocemide (10⁻³M) in Ca²⁺-containing medium did not significantly affect the ultrastructure of JG cells. In slices incubated with isoproterenol or furocemide in the Ca²⁺-free medium, JG cells occasionally contained a few electron-lucent granules at the cell periphery in addition to the electrondense mature granules observed in the control slices. On rare occasions, the JG cells displayed omega-shaped cavities with electron-lucent matrices, a feature similar to the contents of electron-lucent granules. Cytochalasin B markedly promoted the effects of these stimulants in Ca²⁺-free medium. These findings suggest the participation of actin filament disassembly in the exocytotic process of the mature granules in JG cells. © 1995 Wiley-Liss, Inc.     

Tracheobronchial epithelium of the sheep: IV. Lectin histochemical characterization of secretory epithelial cells

Conventional histochemical characterization of the mucus secretory apparatus is often difficult to reconcile with the biochemical analysis of respiratory secretions. This study was designed to examine the secretory glycoconjugates in airways using lectins with biochemically defined affinities for main sugar residues of mucus. We used five biotinylated lectins--DBA (Dolichos biflorus) and SBA (Glycine max) for N-acetyl galactosamine (galNAc), BSA I (Bandeiraea simplicifolia) and PNA (Arachis hypogea) for galactose (gal), and UEA I (Ulex europeus)--for detection of fucose (fuc) in HgCl2-fixed, paraffin-embedded, serially sectioned trachea, lobar and segmental bronchi and bronchioles of nine sheep. Lectins selectively localized the carbohydrate residues in luminal secretions, on epithelial cell surfaces, and in secretory cells. In proximal airways, the major carbohydrate residues in luminal secretions, cell surfaces, goblet cells, and glands were fuc and gal-NAc. PNA reacted mainly with apical granules of less than 10% of goblet cells, and gal residues were only detected in some of the mucous cells and on basolateral cell surfaces. Distal airways contained sparse secretion in the lumen, mucous cells contained weakly reactive fuc and gal-NAc, and the epithelial surfaces of Clara cells contained gal. Sugars abundant in the airway secretions were also the major component of cells in glands. We conclude that there is a correlation between specific sugar residues in secretory cells, glycocalyx, and luminal secretions in proximal and distal airways. This suggests that lectins may be used to obtain information about airway secretory cell composition from respiratory secretions.     

Ontogeny of small-granule APUD cells in hamster lung: a morphological study

Development of small-granule APUD cells and cell clusters was studied in 13-day to 15-day fetal hamster lungs by periodic acid-Schiff (PAS)-lead hematoxylin staining, monoamine fluorescence, and transmission electron microscopy. We examined 11-day and 12-day fetal, early postnatal, and adult animals only by PAS-lead hematoxylin. Precursors of small-granule cells first appear as PAS-negative clear cells in proximal airways of 13-day lung, occurring singly or in clusters of 2-25 cells and standing out among their undifferentiated, glycogen-laden, PAS-positive neighbors. By 14 days, developing small-granule cell clusters are prominent in main and lobar bronchi, extending 2-3 airway generations into the periphery. Clear-cell clusters, similar to those seen in 13-day lung, appear in peripheral airways and reach within one generation of developing terminal sacs. By 15 days, a few small, small-granule cell clusters are located at bronchioloalveolar junctions. Comparatively mature clusters occur in proximal airways; they are characterized by specific formaldehyde-induced monoamine fluorescence demonstrable after exposure in vitro to 5-hydroxytryptophan. In early postnatal stages, PAS-positive granules are resolvable toward the base of some endocrine cells. Ultrastructurally, pulmonary APUD cells contain numerous membrane-limited granules (180-nm diameter) of varying electron density. In 13-day lung, granules sparsely populate the cytoplasm of clear cells, but as the cells mature, the granule population increases and becomes concentrated in the basal cytoplasm. Fetal development of small-granule cells is therefore compressed into the last 4 days before birth. Most clusters appearing in neonatal lungs are not yet fully mature, and not all subtypes of this population are present until some time later.     

Low beta-adrenergic receptor concentration on human thymocytes.

Several agents are known that can elevate cyclic AMP levels in lymphoid cells, e.g. isoproterenol, PGE1 and adenosine. We have studied the cyclic AMP increasing effect of these agents on thymocytes from mouse and man and on human peripheral T lymphocytes. In contrast to mouse thymocytes and human peripheral T lymphocytes, human thymocytes appeared to be insensitive to isoproterenol, but did respond to PGE1 and adenosine. Furthermore, the density of beta-adrenergic receptors on the cells was determined by measuring the specific binding of 3H-dihydroalprenolol. A correlation was found between the receptor density on the cells and the rise in intracellular cyclic AMP induced by isoproterenol: human thymocytes appeared to have very few beta-adrenergic receptors, in contrast to thymocytes from mouse or to T lymphocytes from human blood. We conclude that the development of beta-adrenergic receptors in T cell ontogeny is different for mice and human beings. Comparison of animal models with the situation in man should be made with caution.     

The actions of methacholine,phenylephrine, salbutamol and histamine on mucus secretion from the ferretin-vitro trachea

Methacholine, phenylephrine and histamine produced highly significant and salbutamol significant increases in the rate of mucus secretion from the ferret trachea.Methacholine, phenylephrine and histamine all produced highly significant increases in the rate of output of lysozyme, but the concentration of lysozyme in the mucus was significantly increased only by phenylephrine.Salbutamol produced no significant change in the output of lysozyme, and the concentration of lysozyme in the mucus was significantly decreased.It is concluded that methacholine, phenylephrine and histamine are potent stimulators of serous cell secretion whereas salbutamol has only a weak secretory action on these cells. Methacholine, histamine and salbutamol probably stimulate secretion from mucous cells as well as from serous cells.The increase in the concentration of lysozyme produced by phenylephrine may be due to stimulation of a fluid reabsorption mechanism.     

In vivo effects of endotoxin on intraepithelial mucosubstances in rat pulmonary airways. Quantitative histochemistry.

Bacteria-induced bronchopneumonias are often characterized by an influx of neutrophils and excess mucus in pulmonary airways. This study determined how endotoxin, a component of gram-negative bacteria and a potent inflammatory agent, affects the ultrastructure of the mucociliary apparatus and the amount of stored intraepithelial mucosubstances in the main axial airways within the lung. Rats were intranasally instilled, once a day for 3 days, with endotoxin or saline (controls). Animals were sacrificed 1, 2, or 7 days after the last instillation. Microdissected intrapulmonary axial airways (generations 8-11) from the right caudal lobes of infusion-fixed lungs were processed for light and electron microscopy. Morphometric techniques were used to determine the volume densities (Vs) of histochemically stained intraepithelial mucosubstances and numerical densities of airway epithelial cells. There were marked increases, compared with controls, in the amount of intraepithelial mucosubstances in the intrapulmonary axial airways at generations 8 and 11 in the right caudal lobes from endotoxin-instilled rats sacrificed 1, 2, and 7 days after the last instillation. There were significantly greater numbers of surface epithelial cells per length of basal lamina (i.e., hyperplasia) in endotoxin-exposed airways compared with airways from controls. This endotoxin-induced hyperplasia was due primarily to an increase in the number of mucus-secretory cells, which in endotoxin-exposed epithelium were columnar and contained numerous, large confluent, electronlucent, secretory granules composed of acidic and neutral glycoproteins. In contrast, secretory cells in airway epithelium from controls were cuboidal and contained small discrete, electron-dense, granules composed of only neutral glycoproteins. The numbers of ciliated cells and basal cells were similar in both control and endotoxin-exposed epithelium. Only endotoxin-exposed epithelium, however, contained atypical epithelial cells with numerous basal bodies, few cilia, and few apical secretory granules. These results indicate that repeated airway instillations of endotoxin induce an increase in the amount of intraepithelial mucosubstances, secretory cell hyperplasia, and excess luminal mucus in pulmonary airways. Therefore, endotoxin released from gram-negative bacteria may be partially responsible for the structural alterations, in the airway surface epithelium, which result in the excess luminal mucus observed in bacteria-induced bronchopneumonias.     

Epidermal growth factor and insulin-like growth factor I are localized in different compartments of salivary gland duct cells. Immunohistochemical evidence

Immunohistochemical methods were used to map EGF (epidermal growth factor) and IGF-I (insulin-like growth factor I; somatomedin C) immunoreactivities in salivary glands of adult rodents. Epidermal growth factor is, as is NGF (nerve growth factor), limited in distribution to the granules in granular duct cells in the submandibular gland. Insulin-like growth factor I is, in contrast, cytoplasmic and has a much more widespread distribution. It is seen in intercalated, striated and granulated duct cells as well as in apical parts of excretory duct cells. The parotid and the palatine salivary glands, lacking EGF immunoreactivity, have their IGF-I immunoreactivity similarly distributed as the submandibular gland. Isoproterenol treatment of adult male rats results in rapid and extensive growth of the submandibular and the parotid glands, which double their weights in just a few days. Isoproterenol causes release of granules from the submandibular granular duct cells and decrease in frequency of EGF immunoreactive cells. However, there is no or only minor concomitant changes in the distribution and intensity of the IGF-I immunoreactivity in these duct cells. Our results indicate that the trophic peptides EGF (and NGF) and IGF-I are localized in different compartments in salivary gland duct cells and that divergent pathways control their release.     

Epidermal growth factor and insulin-like growth factor I are localized in different compartments of salivary gland duct cells. lmmunohistochemical evidence

Immunohistochemical methods were used to map EGF (epidermal growth factor) and IGF-I (insulin-like growth factor I; somatomedin C) immunoreactivities in salivary glands of adult rodents. Epidermal growth factor is, as is NGF (nerve growth factor), limited in distribution to the granules in granular duct cells in the submandibular gland. Insulin-like growth factor I is, in contrast, cytoplasmic and has a much more widespread distribution. It is seen in intercalated, striated and granulated duct cells as well as in apical parts of excretory duct cells. The parotid and the palatine salivary glands, lacking EGF immunoreactivity, have their IGF-I immunoreactivity similarly distributed as the submandibular gland. Isoproterenol treatment of adult male rats results in rapid and extensive growth of the submandibular and the parotid glands, which double their weights in just a few days. Isoproterenol causes release of granules from the submandibular granular duct cells and decrease in frequency of EGF immunoreactive cells. However, there is no or only minor concomitant changes in the distribution and intensity of the IGF-I immunoreactivity in these duct cells. Our results indicate that the trophic peptides EGF (and NGF) and IGF-I are localized in different compartments in salivary gland duct cells and that divergent pathways control their release.     

Comparison of real and simulated acupuncture and isoproterenol in methacholine-induced asthma.

In a double-blind (patient and evaluator), crossover study effects of real acupuncture, simulated acupuncture, nebulized isoproterenol, nebulized saline and no treatment in reversing methacholine-induced bronchospasm were compared in 12 asthmatics (ages 16 to 64). Saline and simulated acupuncture did not result in any significant improvement in specific airway conductance (SGaw), thoracic gas volume (Vtg) or forced expiratory flow rates compared with no treatment following methacholine-induced bronchospasm. Isoproterenol and real acupuncture were both followed by increases in SGaw and flow rates and decreases in Vtg which were significantly different from the changes observed following no treatment, saline or simulated acupuncture, although isoproterenol produced greater improvement than real acupuncture, although isoproterenol produced greater improvement than real acupuncture. These findings suggest that stimulation of specific acupuncture loci reduces methacholine-induced bronchospasm and hyperinflation to an extent greater than can be attributed to placebo phenomena.     

Activation of BK channels in GH3 cells by a c-PLA2-dependent G-protein signaling pathway

BK-channels in GH3 cells are activated by arachidonic acid produced by c-PLA2. beta-adrenergic agonists also activate BK channels and were presumed to do so via production of cAMP. We, however, show for the first time in GH3 cells that a beta-adrenergic agonist activates a pertussis-toxin-sensitive G protein that activates c-PLA2. The arachidonic acid produced by c-PLA2 then activates BK channels. We examined BK channels in cell-attached patches and in excised patches from untreated GH3 cells and from GH3 cells exposed to c-PLA2 antisense oligonucleotides. For the cell-attached patch experiments, physiologic pipette and bath solutions were used. For the excised patches, 150 mM KCl was used in both the pipette and bath solutions, and the cytosolic surface contained 1 microM free Ca2+ (buffered with 5 mM K2EGTA). Treatment of GH3 cells with the G protein activator, fluoroaluminate, (AlF4-) produced an increase in the Po of BK channels of 177 +/- 41% (mean +/- SD) in cell-attached patches. Because G proteins are membrane associated, we also added an activator of G proteins, 100 microM GTP-gamma-S, to the cytosolic surface of excised patches. This treatment leads to an increase in Po of 50 +/- 9%. Similar treatment of excised patches with GDP-beta-S had no effect on Po. Isoproterenol (1 microM), an activator of beta-adrenergic receptors and, consequently, some G proteins, increased BK channel activity 229 +/- 37% in cell-attached patches from cultured GH3 cells. Western blot analysis showed that GH3 cells have beta-adrenergic receptor protein and that isoproterenol acts through these receptors because the beta-adrenergic receptor antagonist, propanolol, blocks the action of isoproterenol. To test whether G protein activation of BK channels involves c-PLA2, we studied the effects of GTP-gamma-S on excised patches and isoproterenol on cell attached patches from GH3 cells previously treated with c-PLA2 antisense oligonucleotides or pharmacological inhibitors of c-PLA2. Neither isoproterenol nor GTP-gamma-S had any effect on Po in these patches. Similarly, neither isoproterenol nor GTP-gamma-S had any effect on Po in cultured GH3 cells pretreated with pertussis toxin. Isoproterenol also significantly increased the rate of arachidonic production in GH3 cells. These results show that some receptor-linked, pertussis-toxin-sensitive G protein in GH3 cells can activate c-PLA2 to increase the amount of arachidonic acid present and ultimately increase BK-channel activity.     

The histology and fine structure of glands in the rat respiratory tract

The structure of rat respiratory glands has been investigated by light and electron microscopy. The glands exhibited a tubulo-acinar organization. Individual secretory units were composed of serous tubules or serous demilunes and mucous tubules with narrow lumens at the blind end (proximally), and of mucous ducts with wide lumens which opened to the tracheal lumen distally. Near the junction of the duct with the trachea, mitochondria-rich cells and a few ciliated cells were interspersed with mucous cells. It was found that the histology as well as the ultrastructure of the secretory product of these gland cells varied depending upon the location of the glands in the airway. For this reason, the glands of the epiglottis, larynx and trachea have been described separately. Epiglottal glands consisted of many mucous tubules, a few serous elements and an occasional mucous duct. Laryngeal glands contained many serous and mucous tubules and a few mucous ducts. Tracheal glands were composed of serous tubules, a few mucous tubules and prominent mucous ducts. Serous tubule cell granules formed a uniform population within a cell profile but varied in cells of the epiglottis, compared with those of the larynx and trachea. Granules in mucous tubule cells differed from those of serous cells. Mucous cell granules also appeared uniform within a single cell but differed from cell to cell and at different levels of the respiratory tract. A particular granule type was predominant at each level. Cells of mucous ducts differed somewhat from those of mucous tubules and comprised two general secretory cell populations. Proximal mucous duct cells contained abundant granules that generally resembled those of mucous tubule cells but were localized in two areas of the cytoplasm. Dilated cisternae of rough endoplasmic reticulum with a bizonal content similar in density to zones seen in mature granules further characterized proximal mucous duct cells. The distal mucous duct cell generally contained sparse apical granules and lacked dilated rough endoplasmic reticulum.