Androgen regulation of the cellular Distribution of the true tissue kallikrein mK1 in the submandibular gland of the mouse.

The kallikrein gene family encodes for at least four different proteases in the mouse submandibular gland (SMG): mK1 (true tissue kallikrein), mK9, mK13, and mK22. These enzymes and many other biologically active proteins are synthesized by the granular convoluted tubule (GCT), a specialized segment of the SMG duct system. The GCT is under multihormonal regulation by androgens, thyroid hormones, and adrenocortical hormones. Androgens suppress synthesis of mK1 in the SMG but enhance expression of the other three kallikreins. We prepared an antibody with limited immunoreactivity for mK1 and used it to examine the effects of androgen status on the distribution of this isozyme in the SMGs of developing and mature mice by immunoperoxidase staining for the light microscope and immunogold labeling for the electron microscope. In prepubertal mice, every immature GCT cell contains mK1, confined to an accumulation of small granules in the subluminal cytoplasm. In mature mice, not every GCT cell contains mK1, and in those cells that do there is considerable intergranular variation in the intensity of staining for mK1. GCT cells containing mK1 are much more abundant in the glands of females than of males, resulting in a peculiar sexually dimorphic mosaic distribution of this isozyme in the mature SMG. Castration of adult males increases the number of GCT cells expressing mK1. Administration of androgen to intact or castrated males or to intact females reduces the number of cells staining for mK1. In all cases, immunogold labeling for mK1 is confined to secretory granules. No fine structural differences were noted between cells that were positively or negatively stained for mK1. Therefore, although GCT cells appear to be composed of a uniform population of cells on the basis of morphology alone, they are not homogeneous in their content of secretory proteins. These results indicate that androgen regulation of GCT cells is more complex than has been appreciated to date.

Ultrastructural study of hormonally responsive striated duct cells in the mouse sublingual gland.

In semithin sections stained with Heidenhain's iron hematoxylin, a few scattered granular cells were observed in the striated ducts (SDs) of sublingual glands (SLGs) of the mouse; they were seen normally only in the glands of adult males. However, it was shown by electron microscopy that many SD cells, other than these granular cells, had apical secretory granules, thus forming a granular striated tubule (named the GST in this study) in a portion of SD segments in both sexes. Sublingual GST cells had very small dense secretory granules near the apical surface, with the nucleus in the apical one-third to one-half of the cell; small Golgi apparatus; sparse rough endoplasmic reticulum (RER); and well-developed basal infoldings. However, some granular cells in male GSTs had abundant large dense secretory granules in the apical two-thirds of the cell, a basal nucleus, and modest basal infoldings. Such granular SD cells disappeared after castration in males. Granular SD cells could be induced in the GSTs of females by the injection of 5 alpha-dihydrotestosterone (DHT), triiodothyronine (T(3)), and/or dexamethasone (Dex); given simultaneously, these hormones acted synergistically in this induction. These results indicate a close similarity between the duct systems of the SLG and those of the submandibulan gland (SMG) of the mouse: granular SD cells of the GST in the SLG resemble GCT cells in the SMG in expressing some of the same biologically active polypeptides, in being sexually dimorphic, and in being under the same multihormonal regulation.

An unusual sexually dimorphic mosaic distribution of a subset of kallikreins in the granular convoluted tubule of the mouse submandibular gland detected by an antibody with restricted immunoreactivity.

The granular convoluted tubule of the mouse submandibular gland contains a wide variety of biologically active proteins, including several kallikreins. The tubule is under multihormonal regulation, and is sexually dimorphic, being larger in males than in females. Correspondingly, levels of its various protein secretory products are more abundant in males than in females. However, isoelectric focussing studies show that the true tissue kallikrein, mK1, is more abundant in the female than in the male submandibular gland. In this study, an antiserum was prepared with restricted immunoreactivity for mouse mK1, and possibly other kallikrein family members of low abundance in the mouse submandibular gland, and used for the immunocytochemical staining of the granular convoluted tubule cells in the submandibular gland of adult male and female mice, by indirect enzyme-labeled and immunogold-labeled antibody methods for light and electron microscopy, respectively. The distribution of immunoreactive tubule cells showed an unusual sexual dimorphism. In males only a few scattered slender tubule cells were strongly stained, while the more typical large tubule cells were only occasionally weakly positive, and many of them were not stained. By contrast, in females slender tubule cells were not seen, and about two thirds of the more typical tubule cells showed moderate to strong immunostaining. Immunoelectron microscopy revealed that immunostaining was confined to the secretion granules in granular convoluted tubule cells in both sexes. The slender tubule cells of males had many strongly stained small apical secretion granules and occasional basal infoldings; in the weakly positive larger more typical tubule cells not all secretion granules were positive, and there was intergranular variation in the intensity of staining of positive granules. In females, although more tubule cells were stained, intergranular variations in staining intensity were also noted. In both sexes, many tubule cells did not contain any secretion granules that showed immunogold labeling for kallikreins. These findings establish that, in contrast to the situation for the majority of granular convoluted tubules proteins, mK1 and possibly other minor kallikrein family members are more abundant in the granular convoluted tubules of female mice, and that there is considerable variation in the content of these kallikreins not only between different tubule cells, but also in individual secretion granules in any given tubule cell in either sex.

Salivary gland tissue kallikrein family and processing of growth factor precursors and proenzymes.

Four major enzymes of the tissue kallikrein family were purified from the mouse submandibular gland and characterized. The sequences indicated that they were mK1, mK9, mK13, and mK22. All four enzymes showed kinin-releasing activity, with mK1 exhibiting the highest activity. Like mK13, mK9 and mK22 also processed prorenin to give renin and/or arginyl renin, although their activities were less than that of mK13. The results suggest that tissue kallikrein family enzymes bearing higher kinin-releasing activity have lower prorenin-converting activity and vice versa. These enzymes may possibly have a physiological role in the tissue renin-angiotensin system.

Production and characterization of specific anti-peptide antiserum against free alpha-subunit of rat pituitary glycoprotein hormones.

To obtain an antibody specific for the alpha-subunit of rat pituitary glycoprotein hormones, we synthesized a peptide corresponding to the sequence 37-53 (ST-7: Phe-Ser-Arg-Ala-Tyr-Pro-Thr-Pro-Ala-Arg-Ser-Lys-Lys-Thr-Met-Leu-Val) of the rat alpha-subunit. The polyclonal antiserum against this peptide was generated in rabbits. This region is hydrophilic and highly conserved among several mammalian species. Noncompetitive binding tests showed that the ST-7 antiserum had specific affinity for the rat free alpha-subunit, but not for rat intact LH, FSH, and TSH. The ST-7 antiserum immunostained two types of cells in the rat anterior pituitary, i.e., gonadotrophs and thyrotrophs. This was also the case in mouse, cattle, sheep, and pig, which have an identical sequence of ST-7 in their alpha-subunit. The pituitary cells of horse (Arg substituted for Lys as residue 48 of the rat alpha-subunit), human, and eel (Leu for Ala at residue 45), chicken (Met for Ala at residue 45), and bullfrog (Tyr for Phe at residue 37 and Met for Ala at residue 45) were not stained with the ST-7 antiserum. This study indicated that the ST-7 antiserum is sequence-specific for the alpha-subunit and is therefore useful for immunohistochemical studies on the secretory pathway of the free alpha-subunit.

Immunocytochemical localization of prohormone convertases PC1 and PC2 in the anuran pituitary gland: subcellular localization in corticotrope and melanotrope cells.

Specific antisera against mammalian prohormone convertases PC1 and PC2 have been used to examine, light-immunocytochemically, the distribution of these enzymes in the pituitary gland of five different species of anuran amphibians (Rana catesbeiana, Bufo japonicus formosus, Xenopus laevis, Rana brevipoda porosa, and Buergeria japonica). A differential pattern of immunoreactivity of PC1 and PC2 was found among these species. Only PC1 was found in the corticotrope cells of the pars distalis in R. catesbeiana, B. japonicus formosus, and X. laevis. Only PC2 was observed in these cells in B. japonica, whereas both PC1 and PC2 were present in these cells in R. brevipoda porosa. PC2 immunoreactivity was always observed in melanotrope cells in the pars intermedia of all of the species, but it coexisted with PC1 immunoreactivity only in R. catesbeiana and X. laevis. The nerve fibers and terminals in the pars nervosa in all of the species were intensely immunopositive with both PC1 and PC2 antibodies. Immunoelectron microscopy on B. japonicus formosus and B. japonica, by means of double-labeling with gold particles of different sizes, revealed that almost all the adrenocorticotropin-positive secretory granules in the corticotrope cells and alpha-melanophore-stimulating-hormone-positive secretory granules in the melanotrope cells were also labeled with either PC1 or PC2 antibodies. This study suggests that PC1 and PC2 are involved in the intracellular proteolytic cleavage of proopiomelanocortin in amphibian pituitary glands, a situation similar to that proposed for mammals.

The secretory granule and pro-opiomelanocortin processing in Xenopus melanotrope cells during background adaptation.

In this immunocytochemical study, we used light and electron microscopic observations in combination with morphometry to analyze the processing of pro-opiomelanocortin (POMC) in melanotrope cells of the intermediate pituitary of Xenopus laevis adapted to either a white or a black background. An antiserum was raised against a synthetic peptide including the cleavage site between ACTH and beta-lipotropic hormone in Xenopus. Western blotting revealed that this antiserum recognizes only a 38-kD protein, the POMC prohormone, from extracts of Xenopus neurointermediate pituitary. Light immunocytochemistry showed differential immunostaining for anti-POMC compared to anti-alpha-MSH. Anti-POMC was predominantly found in the perinuclear region, whereas anti-alpha-MSH yielded staining throughout the cytoplasm. Immunogold double labeling revealed that electron-dense secretory granules (DGs) show high immunoreactivity for anti-POMC and low immunoreactivity for anti-alpha-MSH. Electron-lucent granules (LGs) are immunoreactive to anti-alpha-MSH only. Moderately electron-dense granules (MGs) revealed intermediate reactivity compared to DGs and LGs. Background light intensity has significant effects on the morphology and the immunoreactivity of the secretory granules. Black-adapted animals have 4.5 times as many DGs and MGs as white-adapted animals. In addition, the MGs in black animals show 42% more anti-alpha-MSH immunogold than the MGs in white animals. Together, these findings indicate that the three granule types represent subsequent stages in granule maturation. Adaptation to a black background stimulates the formation of young immature granules, while at the same time the processing rate during granule maturation increases.

Immunocytochemical localization of prohormone convertases PC1/PC3 and PC2 in rat pancreatic islets.

The prohormone convertases PC1/PC3 and PC2 are endoproteases involved in prohormone cleavage at pairs of basic amino acids. To determine the cellular and subcellular distribution of PC1/PC3 and PC2 in the rat pancreas, we generated their polyclonal antisera in rabbits, using as immunogens two synthetic peptide antigens corresponding to amino acids 442-459 (ST-28) of PC1/PC3 and 613-629 (ST-29) of PC2 and two bacterially expressed antigens covering amino acids 145-414 (KN-1) of PC1/PC3 and 385-637 (KN-2) of PC2. Western blot analysis revealed the presence of PC1/PC3 (87 and 68 kDa) and PC2 (75 and 70 kDa) in rat pancreatic islets, indicating that the antisera are specific for the corresponding antigens. Immunocytochemical staining of serial sections demonstrated that the antibody against PC1/PC3 immunostained only insulin-producing cells, whereas the PC2 antibody stained insulin, glucagon-, somatostatin-, and pancreatic polypeptide-producing cells. Double-immunolabeling of the prohormone convertases and pancreatic hormones with gold particles of different sizes revealed that insulin-positive secretory granules were also immunolabeled with PC1/PC3 and PC2 antibodies, whereas glucagon-, somatostatin-, or pancreatic polypeptide-positive granules were labeled only with the PC2 antibody. This differential localization of PC1/PC3 and PC2 provides a further problem on the substrate-specificity of these enzymes in the processing of pancreatic prohormones.

Ultrastructural changes of secretory cells of salamander lingual salivary glands under varying conditions.

BACKGROUND: In general the ultrastructure of secretory cells can be modified under secretory stimulated and non-stimulated conditions. The ultrastructure of the lingual salivary glands of hibernating salamanders in the natural environment was examined and compared to those of fasted and fed animals kept in the laboratory. METHODS: Hibernating salamanders of the species Hynobius tokyoensis were collected from the natural environment during the winter breeding season and sacrificed for this study. One group was sacrificed immediately, another group was kept under fasted condition, and another group was regularly fed; both of the latter groups were kept at room temperature for 1 month and then sacrificed. The tongue was fixed for electron microscopy and processed by conventional method, and semithin sections were histochemically examined for glycoconjugates. RESULTS: The lingual salivary glands of this salamander species were composed of simple or often branched tubular glands opening onto the dorsal surface of the tongue. The secretory cells which composed their terminal portions were all columnar in morphology and histochemically mucous in nature. Under hibernation or prolonged fasting at room temperature, the mucous granules of these columnar secretory cells were decreased in number and the Golgi apparatus appeared inactive. A conspicuous structural peculiarity was multiple fingerprint-like structures of the rough-surfaced endoplasmic reticulum (RER). Most of these membranes were composed of stacks of tightly packed cisternae. Under regular feeding, the mucous granules were closely packed in the cytoplasm of the secretory cells and the basal nucleus was slightly enlarged. The Golgi apparatus showed progressive activation with distended saccules. The unique membranous arrangement of the RER which was observed in the fasting animals was completely absent, and the cisternae were irregular in width with considerable variation of the intercisternal spaces. CONCLUSIONS: The tongue of the salamander H. tokyoensis has numerous tubular salivary glands which are mucous in nature. The architecture of the organelles in the secretory cells is subject to modification in response to the cellular metabolism.

Fine structure of nuptial pad surface of male ranid frogs.

The nuptial pad, a cutaneous secondary sexual characteristic, developed on the ventrolateral aspect of the first digit (the thumb) of the male ranid frogs was observed. Under scanning electron microscopy, numerous small elevations were observed rising above the pad's surface; they were rounded in Rana brevipoda porosa and R. rugosa, conical in R. nigromaculata, and rather tall and gradually tapering in R. ornativentris. These elevations were densely crowded, and in some cases several elevations were seen to have fused to form ridges in the R. rugosa pads. Accessory microprocesses completely covered the outermost layer of cells of the elevations. Numerous pile-like microprocesses gradually shortened from the top toward the side of the elevation in R. ornativentris and R. nigromaculata. Those on the top were noticeably longer than those on the side in R. rugosa. The bundles of thick processes radically projected above the top in R. brevipoda porosa. In R. brevipoda porosa nuptial pads were observed under transmission electron microscopy, and the outermost monolayer cells of an elevation were usually keratinized, devoid of organelles and containing closely packed, fine filaments within a dense matrix. The accessory processes also contained dense fibrous matrices.

Effects of an augmented nerve supply on forelimb regeneration in the adult mud frog, Rana rugosa.

Forelimbs of the adult mud frog Rana rugosa, when amputated midway through the zeugopodium, regenerate heteromorphically. The resulting regenerative outgrowths were mostly rod shaped and consisted of a cartilaginous core, in which the base was ossified, and muscle elongated distally along the cartilage, the whole being covered by connective tissue and skin. The tip of the regenerating muscle reached a point distally about one third of the length of the regenerative outgrowths. When the innervation of forelimb stumps was augmented by surgical diversion of the ipsilateral sciatic nerve, the amputated limbs regenerated mostly as spatula-shaped outgrowths, which were longer than those of normally innervated forelimbs. Such hyperinnervated regenerates exhibited less ossification of cartilage, or sometimes none at all. However, the regeneration of muscle was more extensive. That is, it reached more than half way along the regenerative outgrowth. Furthermore, denervation resulted in the absence of regeneration in all cases examined. These results clearly indicate that limb regeneration in Rana rugosa is dependent upon the degree of innervation, not only for the early stages of regeneration, but also for the growth and differentiation of the regenerative outgrowth.

Relationship between innervation and forelimb regenerative capacity in the postmetamorphic pond frog Rana brevipoda porosa.

The limb regenerative capacity and the quantity of innervation (the percentage of a cross-sectional area of amputation forelimb stump occupied by nerves) in the pond frog, Rana brevipoda porosa, was investigated in postmetamorphic froglets and adults of various sizes by means of amputating forelimbs through the zeugopodium. Nearly all the amputated limbs of newly metamorphosed froglets, 18-19 mm in snout-vent length, showed heteromorphic regeneration. However, the larger the body size, the lower the presence of limb regeneration. Limb regenerative capacity was completely lost in froglets and adults with snout-vents larger than 35 mm. The quantity of innervation of limbs was highest in newly metamorphosed froglets, gradually decreasing with growth. The nerve quantity in adults with a snout-vent length between 60-67 mm was approximately half that of the froglets. When the nerve supply was augmented by deviating ipsilateral sciatic nerve bundles to the forelimb stump, almost all limbs, which were usually non-regenerative with normal innervation, regenerated heteromorphically. These results show that the decline in limb regenerative capacity during postmetamorphic growth is in part attributable to the reduction in innervation levels to below the threshold level required for regeneration.

Loss of limb regenerative capacity during postmetamorphic growth in the tree frog, Hyla arborea japonica.

Anuran limb regenerative capacity was investigated in froglets of various sizes (snout-vent length) and adults of the Japanese tree frog, Hyla arborea japonica by amputating forelimbs through the zeugopodium and stylopodium. Almost all limbs amputated through the zeugopodium showed heteromorphic regeneration in postmetamorphic froglets 14 to 18 mm in length. However, the larger the froglet, the lower the capacity of limb regeneration. Regenerative capacity was completely lost in adults of more than about 30 mm in length. When froglet and adult limbs were amputated through the stylopodium, no signs of limb regeneration were observed. Complete denervation of limb stumps resulted in no regeneration in all cases examined. When partial denervation was performed on limbs amputated through the zeugopodium, there were signs of regeneration in the presence of the remaining nerves, but this was limited to very young froglets. Nevertheless, the regenerates obtained were limited in gross structure compared with normal limb regenerates. However, when the nerve supply to the distal forelimb was augmented by surgically diverting ipsilateral sciatic nerve bundles, the limbs of normally nonregenerating adults regenerated after amputation through the zeugopodium. Furthermore, normally nonregenerating limbs amputated through the stylopodium also regained a limited regenerative capacity, if supported by an ipsilaterally augmented nerve. These results show that the loss of limb regenerative capacity in Hyla arborea japonica during postmetamorphic growth is caused by a deficiency in the quantity of innervation.

[Histochemical properties of secretory granules and fine structure of terminal portion in the Japanese Macaque labial gland].

The terminal portion of the Japanese macaque (Macaca fuscata) labial gland was examined ultrastructurally and histochemically. The results obtained are as follows. 1) The Japanese macaque, Macaca fuscata has the upper and the lower labial glands, which can be described as a compound tubulo-acinar gland. 2) The terminal portion of the labial gland appears to be consisted of the mucous acini and the demilunes when examined with the light microscope. 3) The secretory granules containing in the glandular cells of the mucous acini and the demilunes are negative with napthol yellow S, ninhydrin-Schiff and DMAB nitrite. 4) The secretory granules containing in the glandular cells of mucous acini stain intensely with PAS, alcian blue (pH1.0, 2.5, 3.5), colloidal iron and PA-methenamine silver, while those of demilunes are negative with alcian blue (pH1.0). The glandular cells of demilune with the PA-methenamine silver method shows weak positive granules and positive granules which are limited to the hallo of them. 5) In the mucous acini the mucous granules are ejected from glandular cells by the process of exocytosis. 6) The myoepithelial cell can be seen in the terminal portion. This cell surrounds the acini with long processes. These findings suggest that the glandular cells of the demilune have the granules containing mucopoly saccharides and a small quantity of protein in addition to the mucous granules, although the terminal portion of the Japanese macaque labial gland is nearly composed of mucous cells.

Changes in polyamine content during limb regeneration in adult Xenopus laevis.

Polyamine contents in the regenerates were determined at various stages after amputation of the forelimbs of the adult female Xenopus laevis. Putrescine, spermidine, spermine, and sym-homospermidine were detected in all the specimens examined. Cadaverine was detected only in a limited number of samples. At 5 days after amputation of forelimbs, well before the formation of regenerates, the putrescine content in the stump tissues increased, followed by the increase in spermidine content. The putrescine level in the forelimb regenerates was highest between 30 and 50 days after amputation, and then decreased. The spermidine concentration in the regenerates was about 20 times greater than that in intact forelimbs all throughout the experiments. The concentration of spermine was initially lower than that of both putrescine and spermidine and further decreased soon after amputation. The concentration of sym-homospermidine was originally very low and increased slightly during regeneration. The significance of these results, with respect to the function of polyamines in forelimb regeneration of Xenopus laevis, is discussed.