Three‐dimensional imaging of the mucus secretory process in the cryofixed frog respiratory epithelium

Puchelle, Édith; Beorchia, A.; Ménager, M.; Zahm, Jean‐Marie; Ploton, Dominique

doi:10.1016/0248-4900(91)90090-a

Cited by 22 publications

(11 citation statements)

References 22 publications

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“…7) clearly suggested the presence of partially discharged granules with limited SHGFP-MUC5AC/CK and likely no intragranular matrix. Hence, these results support the notion that transient simple exocytosis, rather than massive compound exocytosis (63) or apocrine secretion (64), is prevalent in HT29-SGFP-MUC5AC/CK cells under the conditions assayed. Such a mechanism would suggest that the decondensation and expansion of the mucin matrix take place extracellularly, either as the matrix traverses the fusion pore or shortly thereafter.…”

Section: Discussionsupporting

confidence: 78%

Mucin Granule Intraluminal Organization in Living Mucous/Goblet Cells

Pérez-Vilar

Mabolo

McVaugh

et al. 2006

Journal of Biological Chemistry

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Section: Discussionsupporting

confidence: 78%

Mucin Granule Intraluminal Organization in Living Mucous/Goblet Cells

Pérez-Vilar

Mabolo

McVaugh

et al. 2006

Journal of Biological Chemistry

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“…MUC1, where the N-terminal domain is shed from the cell surface leaving the C-terminal in the membrane (Thathiah, Blobel, & Carson, 2003). Cryofixation studies have indicated that secretion from goblet cells may, in part, occur via an apocrine mechanism involving discharge of whole secretory granules (Puchelle, Beorcia, Ménager, Zahm, & Ploton, 1991).…”

Section: Discussionmentioning

confidence: 99%

MUC16 is produced in tracheal surface epithelium and submucosal glands and is present in secretions from normal human airway and cultured bronchial epithelial cells

Davies

Kirkham

Svitacheva

et al. 2007

The International Journal of Biochemistry & Cell Biology

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“…This system of "mucociliary clearance" serves to remove particles trapped in the mucous gel. The concept of two layers of airway surface liquid (ASL) has been supported by a variety of microscopy studies [2][3][4][5] (fig. 1).…”

Section: R Re Eg Gu Ul La At Ti Io On N O Of F D De Ep Pt Th H a An Nmentioning

confidence: 99%

“…Frozen tissues, cryosectioned and then freeze-dried and substituted have provided excellent differentiation between the sol and the gel [2,5]. However, freeze substitution is associated with tissue shrinkage of 11% in the linear dimension [44], and portions of the ASL may be fractured away during cryosectioning [45].…”

Section: Depth Of Aslmentioning

confidence: 99%

Regulation of depth and composition of airway surface liquid

Widdicombe¹,

Bastacky²,

Wu³

et al. 1997

Eur Respir J

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R Re eg gu ul la at ti io on n o of f d de ep pt th h a an nd d c co om mp po os si it ti io on n o of f a ai ir rw wa ay y s su ur rf fa ac ce e l li iq qu ui id dThe airways are lined with a film of fluid, which is 5-20 µm deep in healthy individuals. This fluid is believed to consist of two phases [1]. A watery fluid of low viscosity, the "periciliary sol" surrounds the cilia. Above this lies a viscous mucous gel. The cilia are able to beat in the sol. Their tips contact the underside of the mucous blanket and propel it towards the mouth. This system of "mucociliary clearance" serves to remove particles trapped in the mucous gel. The concept of two layers of airway surface liquid (ASL) has been supported by a variety of microscopy studies [2][3][4][5] (fig. 1).Factors influencing the liquid content of sol and gel have been identified but their relative contributions are imperfectly understood. Water will move into the airway lumen in response to active Cl -secretion across the epithelia of the tracheal surface and of submucosal glands. Active absorption of Na + across the surface epithelium serves to remove liquid. These active ion transport processes move liquid by generating local osmotic gradients across the epithelium [6]. Hydrostatic pressure gradients across the epithelium, and differences in osmotic pressure between the media bathing the epithelium's two surfaces, will also influence the net movement of liquid into or out of the lumen. Evaporation is an important factor in the upper airways. Finally, forces of surface tension generated by the closely packed cilia SERIES "AIRWAY MUCUS" Edited by P.K. JefferyNumber 6 in this Series may serve to hold liquid in the airway lumen [7]. These factors are considered in turn below. Additionally, we describe recent experiments in which we have used lowtemperature scanning electron microscope (LT-SEM) to determine the depth and composition of the airway surface liquid (ASL). Gland secretionThe adult human trachea has about 10 submucosal gland openings per mm 2 of airway surface [8]. It is unknown how the structure and numbers of glands change down the airways, except that bronchi have glands, whereas bronchioles do not [9]. In each gland, a ciliated duct leads from the airway surface to an expanded collecting duct into which empty ~10 secretory tubules, each with multiple branches ending in closed acini [10]. The acini are lined by serous cells, the tubules by mucous cells [11]. It is believed that the serous cells secrete fluid which serves to flush out mucins released by the more proximal mucous cells [12]. Consistent with this hypothesis, gland serous cells contain much the highest levels of the cystic fibrosis transmembrane conductance regulator of any cell type in the airways [13] Respir J 1997; 10: 1914-1917

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Three‐dimensional imaging of the mucus secretory process in the cryofixed frog respiratory epithelium

Cited by 22 publications

References 22 publications

Mucin Granule Intraluminal Organization in Living Mucous/Goblet Cells

Mucin Granule Intraluminal Organization in Living Mucous/Goblet Cells

MUC16 is produced in tracheal surface epithelium and submucosal glands and is present in secretions from normal human airway and cultured bronchial epithelial cells

Regulation of depth and composition of airway surface liquid

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