Flucher BE et al. (1986), Skin peptides in Xenopus laevis: morphological ...

XB-ART-28447

J Cell Biol 1986 Dec 01;1036 Pt 1:2299-309.

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Skin peptides in Xenopus laevis: morphological requirements for precursor processing in developing and regenerating granular skin glands.

Flucher BE , Lenglachner-Bachinger C , Pohlhammer K , Adam H , Mollay C .

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The biosynthesis of the peptides caerulein and PGLa in granular skin glands of Xenopus laevis proceeds through a pathway that involves discrete morphological rearrangements of the entire secretory compartment. Immunocytochemical localization of these peptides during gland development indicates that biosynthetic precursors are synthesized in intact secretory cells, whereas posttranslational processing requires morphological reorganization to a vacuolated stage. The bulk of the processed secretory material is then stored in vacuolae-derived storage granules. In the mature gland, storage granules are still formed at a low level. However, in this case processing takes place in a distinct cytoplasmic structure, the multicored body, which we suggest to be functionally equivalent to vacuolae. When granular glands regenerate after having lost all their storage granules upon strong stimuli, another morphological pathway is used. 2 wk after gland depletion, secretory cells become arranged in a monolayer that covers the luminal surface of the gland. Storage granules are formed continuously within these intact secretory cells. Here, precursor processing does not require a vacuolated stage as in newly generated glands but occurs in multicored bodies. Most storage granules seem to be formed in the third week of regeneration. The high biosynthetic activity is also reflected by the high activity of the putative processing enzyme dipeptidyl aminopeptidase during this period of regeneration.

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Species referenced: Xenopus laevis
Genes referenced: acin1 adm arhgef5 dap fubp1 pgla tsc1 xt6l

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	Figure 1. Light micrographs of the skin of adult Xenopus laevis. (a) Overall view of Bouin-fixed and azocarmin-aniline blue stained sections show mature granular glands (G), mucous glands (M), and the vacuolated stage (V) of premature granular glands. The glands lie in the dennis and open towards the surface via ducts. (b) Early stage in granular gland development where the cell membranes of the secretory cells are still intact. (c) Detail of the vacuolated stage. Cell membranes have now disappeared and the nuclei are situated at the periphery of the acinus, however, storage granules are still absent at this stage. (a) Bar, 100 lam. (b) Bar, 10 ~tm. (c) Bar, 10 I.tm.
	Figure 2. Electron micrographs of the vacuolated stage of a premature granular gland. The tissue was fixed in Karnovsky's solution and 1% OSO4. (a) Residual cell organelles are confined to areas close to the nucleus (N) at the periphery of the acinus. Near the Golgi apparatus (GA) vesicular structures can be observed (arrowheads). (b) The interior of the gland is filled with vacuolated material. The vacuoles (V) contain droplets and electron-opaque cores (arrows), the sites where immunoreactive material first becomes aggregated during granular gland development. (a) Bar, 1 ~m. (b) Bar, 1 lain.
	Figure 3. (a and b) Electron micrographs of granular skin glands in adult Xenopus laevis. The tissue was fixed in Karnovsky's solution and l% OSO4. Cytoplasmic organelles, such as Golgi apparatus (GA) and multicored bodies (arrow), are confined to the area around the nucleus (N) at the periphery of the gland. The interior of the acinus is filled with spheroid storage granules (G). The storage granules in (b) show sites of immunoreactivity after incubation with anti-caerulein antiserum and gold-labeled goat anti-rabbit IgG (gold particle size, 10 nrn). The granular gland is surrounded by a myoepithelial cell layer (ME). (c) Light micrograph of freeze-dried tissue. Arrows indicate the narrow cytoplasmic area between the myoepithelial cells and the storage granules. (a) Bar, 1/am. (b) Bar, 1 ~,n. (c) Bar, 10 p.m.
	Figure 4. Caerulein and PYL~-immunocytochemistry. (a and b) Colocalization of caerulein- and PYL~-immunoreactive material in the granular gland. 6-~tm sections of Bouin-fixed tissue were treated with anti-caerulein (a) or anti-PYL ~ antisera (b), followed by a routine PAP staining method (for details see Materials and Methods). Caerulein- and PYL~-immunoreactive material could be demonstrated within the same granular gland (G) in serial sections, whereas the vacuolated stage (V) and the mucous gland (M) showed no immunoreactivity. (c-e) Electron micrographs of immunolabeled storage granules. Ultrathin sections of 4% paraformaldehyde/0.25 % glutaraldehyde- (c and d) or Karnovsky-fixed (e) tissue were subsequently incubated with anti-caerulein (c) or anti-PYL a antisera (d and e) and goldlabeled goat anti-rabbit IgG (gold particle size, 10 nm). Embedding media: (c) LR-White; (d) polyvinyl-alcohol. (c and d) Both, caeruleinand PYLa-immunoreactive material is located within the storage granules. (e) In the vacuolated stage immunoreactive material is localized in the electron-opaque cores within the vacuoles (arrows). Here, the secretory peptides can be demonstrated first during granular gland development. (a and b) Bar, 100 ~tm. (c) Bar, 0.5 tim. (d) Bar, 0.5 ~tm. (e) Bar, 0.5 ~tm.
	Figure 5. Electron micrographs of multicored bodies in mature granular glands. Xenopus laevis skin was fixed in Karnovsky's solution (a) or 4 % paraformaldehyde/0.25 % glutaraldehyde (b) and 1% OsO4. Ultrathin sections were then incubated with anti-caerulein (a) or anti-PYL" antisera and gold-labeled goat anti-rabbit IgG (gold particle size, 20 nm [a] and 10 nm [b]). (a) The multicored bodies are located near the Golgi apparatus (GA). Immunoreactive material seems to become concentrated in a granular-like dense core (arrow), which finally buds off from the organelle (b); nucleus (N), storage granule (G). (a) Bar, 0.5 Ixm. (b) Bar, 0.5 ~tm.
	Figure 6. Appearance of the regenerating gland after experimental discharge of storage granules at different times of regeneration. Xenopus laevis skin sections (5 lam, Bouin-fixed and embedded in paraffin): (a) In glands regenerating for 1 wk, the myoepithelial cells are still contracted. Cells in the interior of the gland proliferate (arrows). No storage granules can be seen at this stage. (b) 2 wk after stimulation, the secretory cells begin to fuse and form small syncytial compartments (arrows). (c) After 3 wk, the lumen is filled with mature storage granules (SG) and the gland has formed a cellular secretory epithelium. (b' and c') Immunocytochemistry in regenerating granular skin glands. Sections were incubated with anti-caerulein antibody and processed with a routine PAP staining technique. (b') 2 wk after stimulation immunoreactive caerulein can first be observed; (c') the secretory epithelium within the 3 wk regenerating gland reveals intensive immunoreactivity. (a) Bar, 50 p.m. (b) Bar, 50 lam. (c) Bar, 50 I.tm. (b') Bar, 50 p.m. (c') Bar, 100 p.m.
	Figure 7. Electron micrographs of secretory compartments of regenerating granular glands: the tissue was fixed in a solution of 4 % paraformaldehyde and 0.25 % glutaraldehyde and (a) was postfixed in OsO4. (a) Syncytial secretory compartment in a 2 wk regenerating granular gland contains extended rough endoplasmic reticulum (ER), multicored bodies (arrows), and some mature storage granules (arrowheads). (b) The secretory epithelium of a gland 3 wk after extrusion of secretory granules is packed with rough endoplasmic reticulum (ER) and contains large multicored bodies (arrows) as well as mature storage granules (arrowheads). Nucleus (N); myoepithelial cells (M). (a) Bar, 1 ~rn. (b) Bar, 1 p.m.
	Figure 8. SDS PAGE of total protein content and partially purified DAP isolated from granules derived from regenerating glands. Lanes 1-5, proteins in storage granules expelled by glands that were allowed to regenerate for (1) 8, (2) 1, (3) 2, (4) 3, and (5) 4 wk. Lanes 6--10, DAP partially purified from secretory granules isolated from glands aged (6) 8, (7) 1, (8) 2, (9) 3, and (10) 4 wk. The band previously identified as DAP (reference 9) is indicated by a dot.

References [+] :

Anastasi, Isolation and amino acid sequence of caerulein, the active decapeptide of the skin of hyla caerulea. 1968, Pubmed