Ultrastructural and cytochemical study on the enzyme gland of the foot of a mollusc

The enzyme gland of the foot of the mussel Mytilus has been so far considered a gland producing and exporting a phenol oxidase catalysing the general tanning processes of byssus threads. In contrast, the present study shows that this gland produces mainly secretory granules which form the cortical layers of byssus threads. Cytochemical methods at the ultrastructural level (phosphotungstic acid at low pH, silver methenamine, periodic acid-thiosemicarbazide-silver proteinate, silver methenamine for sulphur-rich proteins demonstration) and enzyme digestion tests (pepsin, trypsin, alpha-chymotrypsin) indicate that secretory granules contain glycoproteins rich in sulphydryl groups and in aromatic amino acids. The cytochemical demonstration of phenol oxidase shows that enzyme activity is present in Golgi complex, whereas it is absent in secretory granules. For this reason, phenol oxidase does not seem to be exported and utilized for tanning of byssus threads, but it might rather be involved in the elaboration and tanning of the content of the secretory granules in the enzyme gland itself.     

Histology,histochemistry, and ultrastructure of the harderian gland of the snake Coluber viridiflavus

Analyses of the histology, histochemistry, and ultrastructre of the Harderian gland of Coluber viridiflavus prove the gland to be compound acinar and to produce a seromucous secretion. Acinar cells (type I) contain secretory granules that are composite, consisting ultrastructurally of three distinct parts that are sharply separated. They are similar to the “special secretory granules” described in the cells of the Harderian gland of the lizard Podarcis s. sicula. Some acini of the most anterior and posterior parts of the gland are mucous. Acinar cells (type II) of this type contain secretory granules that are Alcian blue/PAS positve. At the ultrastructural level, they appear homogeneous and of low density, characteristic of mucous secretions. These mucus-secreting anterior and posterior parts of the Harderian gland may by considered as regions of intial differentiation of the anterior and posterior lacrimal galnds.     

Identification of lactotropes (PRL cells), somatotropes (GH cells), corticotropes (ACTH cells) and thyrotropes (TSH cells) in the pituitary gland of the musk shrew, Suncus murinus L. (Insectivora), by immunohistochemistry

By means of immunohistochemistry, lactotropes, somatotropes, corticotropes and thyrotropes in the pituitary of the male musk shrew, Suncus murinus L., were identified at the electron-microscopic level. Lactotropes were classified into three types: type I containing large (200-450 nm in diameter) round secretory granules, type II with medium-sized (150-250 nm in diameter) ones and type III with small (50-150 nm in diameter) ones. Somatotropes were also classified into type I somatotropes that contain large (450 nm in diameter) spherical secretory granules and type II somatotropes containing comparatively small (300 nm in diameter) round granules. Both type I and II somatotropes were small and sometimes contained rod-shaped granules. Corticotropes were round or oval cells with round secretory granules in various densities and sizes (150-500 nm in diameter) scattered all over the cytoplasm. Thyrotropes were angular or polyhedral cells containing electron-transparent round secretory granules (200-300 nm in diameter) and large irregularly shaped granules with a maximum diameter of about 1,500 nm. Each type of the cells may be distinguished by its respective ultrastructural characteristics alone without the aid of immunohistochemistry.     

Electron microscopic demonstration of calcitonin in human medullary carcinoma of thyroid by the immuno gold staining method

In a human medullary carcinoma of thyroid gland containing calcitonin in light microscopic demonstration by the avidin biotin complex (ABC) method characteristic secretory granules were found electron microscopically in the cytoplasm of the tumour cells. They consisted in so-called type I granules (270 +/- 25 nm) and type II granules (135 +/- 17 nm). By the immuno gold staining (IGS) method the content of many secretory granules measuring 85-270 nm (152 +/- 18 nm) in diameter could be identified as calcitonin. These granules seemed to be predominantly of type II because of their nearly corresponding size and feature. The type I granules were less frequent in number and they showed no or little immunoreactivity. The results indicate that the IGS-method is practicable to demonstrate the ultrastructural localization of calcitonin and to identify clearly the nature of intracytoplasmic granules in electron microscopy.     

Changes in cells's secretory organelles and extracellular matrix during endochondral ossification in the mandibular condyle of the growing rat

The mandibular condyle from 20-day-old rats was examined in the electron microscope with particular attention to intracellular secretory granules and extracellular matrix. Moreover, type II collagen was localized by an immunoperoxidase method. The condyle has been divided into five layers: (1) the most superficial, articular layer, (2) polymorphic cell layer, (3) flattened cell layer, (4) upper hypertrophic, and (5) lower hypertrophic cell layers. In the articular layer, the cells seldom divide, but in the polymorphic layer and upper part of the flattened cell layer, mitosis gives rise to new cells. In these layers, cells produce two types of secretory granules, usually in distinct stacks of the Golgi apparatus; type a, cylindrical granules, in which 300-nm-long threads are packed in bundles which appear "lucent" after formaldehyde fixation; and type b, spherical granules loaded with short, dotted filaments. The matrix is composed of thick banded "lucent" fibrils in a loose feltwork of short, dotted filaments. The cells arising from mitosis undergo endochondral differentiation, which begins in the lower part of the flattened cell layer and is completed in the upper hypertrophic cell layer; it is followed by gradual cell degeneration in the lower hypertrophic cell layer. The cells produce two main types of secretory granules: type b as above; and type c, ovoid granules containing 300-nm-long threads associated with short, dotted filaments. A possibly different secretory granule, type d, dense and cigar-shaped, is also produced. The matrix is composed of thin banded fibrils in a dense feltwork. In the matrix of the superficial layers, the "lucency" of the fibrils indicated that they were composed of collagen I, whereas the "lucency" of the cylindrical secretory granules suggested that they transported collagen I precursors to the matrix. Moreover, the use of ruthenium red indicated that the feltwork was composed of proteoglycan; the dotted filaments packed in spherical granules were similar to, and presumably the source of, the matrix feltwork. The superficial layers did not contain collagen II and were collectively referred to as perichondrium. In the deep layers, the ovoid secretory granules displayed collagen II antigenicity and were likely to transport precursors of this collagen to the matrix, where it appeared in the thin banded fibrils. That these granules also carried proteoglycan to the matrix was suggested by their content of short dotted filaments. Thus the deep layers contained collagen II and proteoglycan as in cartilage; they were collectively referred to as the hyaline cartilage region.     

Flask cells and flask-shaped glandular cells of amphibian skin specifically produce fucose-rich glycoproteins

A battery of horseradish peroxidase-conjugated lectins has been employed as a cytochemical tool for the labelling of specific cell types in amphibian epidermis. Among the lectins used, onlyUlex europaeus I (UEA I) showed specific reaction with the cytoplasm of flask cells. In addition, UEA I stained flask-shaped secretory cells in dermal glands and a reaction on glandular ductal cells was also observed. At the electron microscopic level, lect-in binding was found in granules distributed among mitochondria in the cytoplasm of flask cells and in larger mucous granules of flask-shaped glandular cells, which were released into the lumen. UEA I also stained the extracellular space above flask cells. The labelling was due mainlty to a glycoprotein of mol. wt. approx. 27 kDa. Structural and cytochemical similarities between flask cells and flask-shaped cells of dermal glands could be a consequence of a common secretory role of both cell types.     

An ultrastructural study of byssus stem formation in Mytilus californianus

In Mytilus californianus, root lamellae of the byssus stem are formed by two morphologically distinct exocrine cell types. Type 1 cells contain large ellipsoid granules which are ultrastructurally identical to those of the collagen gland associated with byssus thread formation: these granules are secreted only at the base of the stem generator. Type 2 cells contain small cylindroid granules which are secreted only from the lateral surfaces of generator septa. The resultant matrix is biphasic because the two secretions are incompletely mixed. Lamellar sheets of matrix are propelled outward by the action of cilia and are molded into a cylinder at the neck region of the stem. However, the stem retains a lamellar pattern. Byssus threads are attached to the stem by flattened rings formed from thread material which is secreted into the cervical crevice surrounding the neck. The microanatomy of the stem forming region is described and a new term, “stem generator,” is proposed for this organ.     

Electron microscopic demonstration of calcitonin in human medullary carcinoma of thyroid by the immuno gold staining method

Summary In a human medullary carcinoma of thyroid gland containing calcitonin in light microscopic demonstration by the avidin biotin complex (ABC) method characteristic secretory granules were found electron microscopically in the cytoplasm of the tumour cells. They consisted in so-called type I granules (270±25 nm) and type II granules (135±17 nm). By the immuno gold staining (IGS) method the content of many secretory granules measuring 85–270 nm (152±18 nm) in diameter could be identified as calcitonin. These granules seemed to be predominantly of type II because of their nearly corresponding size and feature. The type I grnaules were less frequent in number and they showed no or little immunoreactivity. The results indicate that the IGS-method is practicable to demonstrate the ultrastructural localization of calcitonin and to identify clearly the nature of intracytoplasmic granules in electron microscopy.     

Fine structure of the gastric mucous and endocrine cells of the toad,Bufo marinus

Summary The ultrastructure of the mucous and endocrine cells of the gastric mucosa of the cane toad (Bufo marinus) has been examined. Surface mucous cells line the entire gastric mucosa and pits. Many of their secretory granules contain an electron-dense core that remains unreactive after cytochemical testing for glycoproteins. A second spatially and structurally discrete population of mucous cells is present in the gastric glands. These glandular mucous cells are probably homologous with the antral gland and mucous neck cells of mammals; their secretory granules also contain non-glycoprotein cores. Three distinct populations of endocrine cells show structural homologies with gastric hormone-storing cells of higher vertebrates.This study was supported by grants from N.H. & M.R.C. (Australia) and the Clive and Vera Ramaeiotti Foundations     

Classifications of somatotropes, lactotropes and corticotropes in the mouse adenohypophysis with immunohistochemistry

Somatotropes, lactotropes and corticotropes of adult male mice were identified with immunohistochemistry in the adenohypophysis fixed by OsO4 alone. Somatotropes were classified into type I somatotropes that contain large (350 nm in diameter) round secretory granules and type II somatotropes that contain small (100-200 nm in diameter) round secretory granules. Most somatotropes were type I somatotropes. Lactotropes were also classified into type I lactotropes that contain irregularly shaped secretory granules and type II lactotropes containing small (100-200 nm in diameter) round secretory granules. Corticotropes are irregular stellate or slender cells with little cytoplasm. They contain round solid secretory granules in various densities along the cell periphery. Most of these are low-density granules (200-300 nm in diameter) and a few are high-density granules (200-250 nm in diameter). These data were compared with the classical data of mouse adenohypophysial cells that were fixed in OsO4 alone and identified only by conventional electron microscopy.     

The Golgi complex in the esophageal mucous glands of the newly hatched chick

The general morphology of the mucous gland cell and the nature of the secretory granule in esophageal glands of the newly hatched chick have been described. Lightly basophilic supporting cells, attached to secretory cells by desmosomes and containing tonofilaments, are located on the basal lamina. Electron microscopic studies showed a morphological polarity of the Golgi complex which suggests that mucous precursors are transported from other sites within the cell to the Golgi complex for further packaging into secretory granules. Finally, acid mucopolysaccharides (AMPS) were specifically stained using the Thorotrast technique and not detected in the rough endoplasmic reticulum, the transitional elements, or in the lamellae at the forming face of the Golgi complex. Conversely, AMPS are found in the vicinity of the mature face of the Golgi complex, and in the secretory granules. The acquisition of cytochemical reactivity for AMPS within the Golgi complex is discussed.     

Immunocytochemical and immuno-electron-microscopical study of growth hormone cells in male and female rats of various ages

Summary Growth hormone (GH) secretory cells were identified by immunogold cytochemistry, and were classified on the basis of the size of secretory granules. Type I cells contained large secretory granules (250\2-350 nm in diameter). Type II cells contained the large secretory granules and small secretory granules (100\2-150 nm in diameter). Type III cells contained the small secretory granules. The percentages of each GH cell type changed with aging in male and female rats of the Wistar/Tw strain. Type I cells predominated throughout development; the proportion of type I cell was highest at 6 months of age, and decreased thereafter. The proportion of type II and type III cells decreased from 1 month to 6 months of age, but then increased at 12 and 18 months of age. The pituitary content of GH was highest at 6 months of age, and decreased thereafter. Estrogen and androgen, which are known to affect GH secretion, caused changes in the proportion of each GH cell type. The results suggest that when GH secretion is more active the proportion of type I GH cell increased, and when GH secretion is less active the proportion of type II and type III cells increased. The type III GH cell may therefore be an immature type of GH cell, and the type I cell the mature type of GH cell. Type II cells may be intermediate between type I and III cells.     

The kidney of a teleost, Spinachia spinachia II. Histochemical identification of sialic acid-containing glycoprotein and fine structure of mucus secreting cells

Kidney cells of the marine stickleback Spinachia have been studied with histochemical methods for the demonstration of glycoconjugates. The fine structure of epithelial cells is described. Mucus threads in the nephronic tubule of sexually mature males consist of neutral glycoprotein which corresponds with the secretory granules in proximal tubule segment II cells. Large lysosome-like inclusions, which also react with PAS, are present in many P II cells. All cells of the collecting duct epithelium differentiate into mucous cells in male Spinachia. The nature of their secretory products, which are well preserved by freeze-drying, is discussed. Sialylated glycoprotein is present in mucus granules and sulphated glycoprotein can be demonstrated at the apex of collecting duct cells. Collecting duct cell mucus can be digested with testicular hyaluronidase indicating that proteoglycans may be involved in the structure of macromolecules. The observations are compared with studies of mucus production in the urinary apparatus of several other vertebrates.     

Ultrastructural and cytochemical studies in the mantle of Anodonta cygnea

The large central region of the mantle of Anodonta cygnea was studied using transmission and scanning electron microscopy (TEM and SEM) for ultrastructural analysis and light microscopy (LM) and TEM for cytochemical analysis. X-ray diffraction studies of the organic matrix pellicle deposited on the inner surface of the shell were also carried out. Two groups of columnar cells presenting desmosomes on the apical region were observed in the outer epithelium. One group secretes a structural and neutral mucopolysaccharide (MPS) identified with chitin, normally excreted to form the organic matrix of the shell. Another group presents numerous cytoplasmic vesicles and constitutes the predominant cells of this epithelium. Two different types of mucous cells were found in the inner epithelium. One type secretes a faintly acid mucopolysaccharide (MPS) with sulphate groups and another type secretes an association of this polysaccharide with a neutral MPS. Staining for sulfhydryl groups (probably cysteine) was also positive, suggesting the presence of proteoglycans in these secretions. A third type of cells was also observed presenting a very different ultrastructural aspect (columnar form) without large secretion masses. They may correspond to the replacing cells in this highly secretory epithelium. Elastic fibers were found on the base of the outer epithelium and amoebocytes were observed in the interepithelial tissue.     

Foot glands in Perna indica and Perna viridis (Pelecypoda: mytilidae) histology and histochemistry

The foot of Perna viridis is found to contain three main types of glands, the white gland, phenol gland and the enzyme gland. But in Perna indica there are only two glands, the phenol gland and the enzyme gland. Besides these, mucous glands are found in both of the species. The shape and size of the cells of these glands vary from species to species. Glycogen and 1 : 2 glycol groups are found in these gland cells. Proteins rich in disulfides and sulfhydryls are present in the phenol glands of both the species and in the white gland of p. viridis but they vary in the intensity of staining. The presence of phenols is confirmed in the phenol gland cells. Phospholipids and lipoproteins are intense in the white and phenol gland cells. They are absent in the enzyme gland. Alkaline and acid phosphatases activity in the enzyme gland cells could be demonstrated. The secretions of these glands help in the formation of the byssus threads. The mucous gland cells are subepithelial localised they secrete acid and neutral mucopolysaccharides together with glycoproteins. Which participate in the attachment of the byssus disc.     

The epidermis of Timarete filigera (Polychaeta, Cirratulidae): histochemical and ultrastructural analysis of the gland cells

The aim of this study was to verify whether different living conditions of Polychaeta are correlated with morphological and functional differences in the organization of the integument. For this purpose, we decided to study the epidermis of Timarete filigera, a non-tubicolous polychaete. With this objective in mind, we have identified the various cellular types responsible for mucous secretion in the epidermis of this species and defined the histochemical composition of the mucus produced by different types of gland cells. Three types of gland cells have been identified by histochemical and ultrastructural studies in the epidermis of this polychaete. The histochemistry was carried out using standard techniques and peroxidase-labelled lectins. In type 1 cells, the secretory granules contain neutral glycoproteins with glucosidic residues of GalNAc, Galbeta 1,3 GalNAc, glucosidic and/or mannosidic residues. In type 2 cells, the secretory granules contain acid glycoproteins mainly sulphated with glucosidic residues of GalNAc, Galbeta 1,3 GalNAc, glucosidic and/or mannosidic residues, and some terminal sialic acid. In type 3 cells, the residual granules have the same chemical composition as that of granules present in type 2 cells. The secretion of these glandular mucous cells consists of mainly sulphated acidic glycoproteins and GAG resistant to testis jaluronidase. In these cells, the residual granules have the same chemical composition as that of their secretion. The heterogeneity of mucus composition may be correlated with its different functions.     

Ultrastructural study on cocoon formation in the freshwater oligochaete,Tubifex hattai

The clitellar epithelium of the freshwater oligochaete, Tubifex hattai, is composed of four types of gland cells (Type I, II, III, and IV), in addition to the cells generally found in the epidermis of this worm. The possible function of these gland cells in cocoon formation was studied with the electron microscope. Type I cells discharge their secretory granules by means of compound exocytosis and provide the materials for the future cocoon membrane. Immediately after completion of the discharge from Type I cells, Type II and III cells simultaneously discharge their secretory granules by means of compound exocytosis. The secretions from Type II cells constitute a colloid in the cocoon lumen and probably cause structural modifications in the future cocoon membrane. The secretory products from Type III cells form the cocoon plug. Although the process of discharge of secretory granules from Type IV cells was not observed, the contribution of these cells to the cocoon formation, producing hoops on the outer surface of the future cocoon membrane and fixing its anterior ends on the clitellum, is inferred from a morphological comparison of the hoop and the structure of the secretory granules.     

Localization by immunoelectron microscopy of somatostatin-containing cells in the gastric mucosa of a teleost fish, Perca fluviatilis

Somatostatin-immunoreactive cells were localized on semithin and ultrathin sections of Epon-embedded samples of perch gastric mucosa, classically fixed with aldehydes and osmium tetroxide. On semithin sections, somatostatin cells were identified by using the immunoperoxidase method. The ultrastructural localization of somatostatin immunoreactivity was achieved using the colloidal gold method. Cells showing somatostatin immunoreactivity are found to be scattered among the surface mucous cells and the mucous neck cells. Somatostatin appears to be localized in cytoplasmic granules. Somatostatin-containing cells are identified as the type I cells which were described in a previous ultrastructural study. The present report also points out that tissue samples which have been classically processed for ultrastructural study could be in some cases suitable for immunocytochemical investigations.     

The cells of the rat gastric groove and cardia

The distal wall of the groove between the rat forestomach and glandular stomach is lined with a special type of columnar cells (CCGG) and with fibrillovesicular cells (FVC). The cardiac glands contain cardiac mucosa (CMC) and serous cells (CSC). The CCGG contain small mucous granules and special vesicles and tubules. The CMC are filled with large mucous granules and resemble mucous neck cells. The CSC are filled with large proteinaceous granules. The FVC are characterized by long microvilli, apical bundles of microfilaments and a complex "tubulovesicular system". The pattern of 3H-thymidine incorporation and the presence of immature and transitional forms indicate a possible origin of all the cell types concerned from a common undifferentiated precursor. The membranes of the tubulovesicular system of FVC as well as the apical cell membrane were reactive to Thiéry's carbohydrate stain. However, lanthanum tracing of the extracellular space and ultrastructural stereoscopy did not reveal a permanent continuity between both membrane systems. The absence of 3H-thymidine label showed that FVC were not proliferative. The structural characteristics of FVC do not account for a secretory, resorptive or receptive function. The special arrangement of microfilaments and the tubulovesicular system suggests an ability to fast changes in surface area.