Ultrastructure of the dental epithelium and odontoblasts during enameloid matrix deposition in cichlid teeth

Teleost enameloid matrix has been proposed to be an ectodermal, mesodermal, or joint ectodermal-mesodermal product. To determine its origin we examined the ultrastructure of the inner dental epithelium (IDE), odontoblasts, enameloid, and dentin matrices of cichlid tooth buds at the stage of enameloid formation. © Alan R. Liss, Inc. Columnar IDE cells had apical and basal terminal webs and contained organelles associated with protein synthesis, including elongated secretory granules containing fibrillar material having cross-striations with 60-nm periodicity. The morphology of IDE secretory granules was typical of procollagen granules observed in a large variety of ectodermal and mesodermal cells synthesizing collagen. In contrast, the paucity of secretory granules within three odontoblast types indicates that these cells probably do not synthesize enameloid matrix. These observations are consistent with the idea that the bulk of the enameloid matrix is itself an ectodermal collagen synthesized and secreted by IDE cells.     

Ultrastructure of odontogenic cells during enameloid matrix synthesis in tooth buds from an elasmobranch, Raja erinacae

The ultrastructure of the inner dental epithelial cells (IDE) and odontoblasts in elasmobranch (Raja erinacae) tooth buds was investigated by transmission electron microscopy to determine what contribution each cell type makes to the forming enameloid matrix. Row II, early stage, IDE cells contained few organelles associated with protein synthesis, whereas preodontoblasts appeared competent to initiate extracellular matrix production. Row III IDE cells are also devoid of organelles related to secretory protein synthesis, although these IDE cells accumulated large pools of intracellular glycogen. The glycogen appeared to be packaged into vesicles and exocytosed into the lateral extracellular space toward the forming enameloid matrix. Row III odontoblasts had a morphology consistent with an active protein secretory cell. No procollagen granules were present within the odontoblasts, however, nor were many collagen fibers observed in the enameloid matrix. Instead, non-collagenous "giant" fibers having 17.5-nm periodic cross striations were associated with the invaginations of odontoblast cell processes. Giant fibers, which spanned a clear zone adjacent to the odontoblasts, terminated within the enameloid matrix. Smaller 25-nm-wide "unit" fibers emanated from the giant fiber tips to form the bulk of the enameloid matrix. The clear zone, which separated the odontoblasts from the enameloid matrix at early stages, diminished in size at later stages until the odontoblast processes were completely embedded in the enameloid matrix. Nascent enameloid crystallites were observed only after a layer of unmineralized predentin was deposited beneath fully formed enameloid matrix. The results suggest that the major constituent of the enameloid matrix in skates is a non-collagenous protein derived from the odontoblasts. The inner dental epithelial cells appear to contribute large quantities of carbohydrates to the forming enameloid matrix.     

The penetration of exogenous tracers through the enameloid organ of developing teleost fish teeth

In order to determine whether exogenous materials permeate to the forming tooth enameloid matrix, teleost species were injected intramuscularly with horseradish peroxidase (HRP) or myoglobin, or; intracardially with lanthanum nitrate or HRP, then killed a predetermined intervals post-injection. Tooth bearing bones were processed for transmission electron microscopy. At the enameloid matrix formation stage, capillaries associated with the enameloid organ were few in number and rarely fenestrated. Both organic tracers reached the matrix at cervical but not coronal, regions of the teeth in all species examined. Lanthanum was rarely observed extravascularly and never extended to the enameloid matrix at the secretion stage. At the enameloid mineralization stage, fenestrated capillaries were closely associated with the outer dental epithelial cells (ODE). All tracers were observed in the plasma membrane invaginations of the ODE. Only intracardially injected HRP compromised the apical intercellular junctions of the inner dental epithelial cells (IDE) to reach the mineralizing enameloid Lanthanum did not extend past the ODE-IDE cell junctions. It is concluded that the close association of mineralization stage fenestrated capillaries with the highly invaginated ODE cells result in increased tracer penetration compared to the secretory stage. The deeper penetration of the organic tracers, compared with lanthanum, between mineralization stage IDE cells may be due to longer in vivo circulation of the former material. The apical junctions of mineralization stage IDE cells, however, remained impermeable to the organic tracers. The absence of mineral in secretory stage enameloid mineral could not be due to specialized cell junctions preventing access of molecules to the matrix. It is suggested that controlling factors other than cellular permeability initiate enameloid mineralization.     

Morphological heterogeneity of secretory granules of rat Clara cells: an immunocytochemical study.

The secretory granules of rat bronchiolar Clara cells were classified into different types by their ultrastructural appearances followed by immunocytochemistry using anti-rat 10 kDa Clara cell-specific protein (10 kDa CCSP) antibody. One predominant type was the oval to round granule (type A granule), of which the matrix was composed of a map-like mixture of electron-dense and less electron-dense material. Another predominant type was the rod-shaped granule (type B granule). The content of type B granules varied from a finely fibrillar (type B1 granule) to an electron-dense, rod-like (type B3 granule) structure. Various intermediate types (type B2 granule) between type B1 and B3 granules were also found. Small cytoplasmic vesicles were found occasionally in close proximity to type B2 or B3 granule. Another type of granule (type C granule) was large, up to 8 microns in diameter, and contained a moderately electron-dense amorphous matrix. Both type A and C granules stained at a similar density with the antibody. The nascent form of type A granules, which was found in the vicinity to the trans face of the Golgi apparatus, was also labeled. On the other hand, the labeling density of type B granules varied: type B1 granules were almost devoid of immunolabeling, whereas type B3 granules were intensely labeled. Type B2 granules stained with the antibody; however, the labeling density was less than that of type B3 granules. The small cytoplasmic vesicles of type B2 granules were labeled.(ABSTRACT TRUNCATED AT 250 WORDS)     

An ultrastructural study of dentinogenesis and amelogenesis in rat molar tooth germs cultured in vitro

Summary Molar tooth germs from three-day-old rats were cultured successfully for fourteen days, permitting the study of the development in vitro of both extracellular matrix and cellular elements such as odontoblasts and ameloblasts. The ultrastructure of the cultured tooth germs was compared with the ultrastructure of tooth germs in vivo at a comparable developmental stage. Progenitor cells of odontoblasts and ameloblasts were found to differentiate in vitro. Odontoblasts seemed to contain more lysosome-like bodies and fewer secretory granules than in vivo. They formed normally mineralizing dentine or a thick layer of dense, unmineralized predentine with incidentally some amorphous, extracellular material. Enamel was exclusively present opposite well developed dentine. It was often hyperor hypomineralized and enamel rods were not as regularly shaped as in vivo. In places where no enamel formation had taken place, large amounts of amorphous extracellular material were sometimes seen. From these observations it can be concluded that cellular development in cultured tooth germs appeared more or less normal, but extracellular matrix formation and mineralization were sometimes disturbed.     

Morphological heterogeneity of secretory granules of rat Clara cells: an immunocytochemical study

Summary The secretory granules of rat bronchiolar Clara cells were classified into different types by their ultrastructural appearances followed by immunocytochemistry using anti-rat 10 kDa Clara cell-specific protein (10 kDa CCSP) antibody. One predominant type was the oval to round granule (type A granule), of which the matrix was composed of a map-like mixture of electron-dense and less electron-dense material. Another predominant type was the rod-shaped granule (type B granule). The content of type B granules varied from a finely fibrillar (type B1 granule) to an electron-dense, rod-like (type B3 granule) structure. Various intermediate types (type B2 granule) between type B1 and B3 granules were also found. Small cytoplasmic vesicles were found occasionally in close proximity to type B2 or B3 granule. Another type of granule (type C granule) was large, up to 8 m in diameter, and contained a moderately electron-dense amorphous matrix. Both type A and C granules stained at a similar density with the antibody. The nascent form of type A granules, which was found in the vicinity to the trans face of the Golgi apparatus, was also labeled. On the other hand, the labeling density of type B granules varied: type B1 granules were almost devoid of immunolabeling, whereas type B3 granules were intensely labeled. Type B2 granules stained with the antibody; however, the labeling density was less than that of type B3 granules. The small cytoplasmic vesicles of type B2 granules were labeled. From these findings, it is suggested that the granules of rat Clara cells consist of two types of granules of distinct origin; one appears to derive from condensing vacuoles of Golgi origin, whereas the other may be formed by membranefusions with small cytoplasmic vesicles of unknown source.     

Fine structural and cytochemical observations of dental epithelial cells during the enameloid formation stages in red stingrays Dasyatis akajei

The fine structure and the localization of nonspecific acid phosphatase (ACPase), nonspecific alkaline phosphatase (ALPase), and calcium-dependent adenosine triphosphatase (Ca-ATPase) activities in the dental epithelial cells in tooth germs of Dasyatis akajei in the later stages of enameloid formation were investigated. Numerous invaginations of the distal cell membrane of the inner dental epithelial (IDE) cells were observed at the early stage of enameloid maturation. The invaginations contain many fine granular and filamentous substances; the lamina densa, which was thicker during the former stages, is obscure. Granules exhibiting defined ACPase activity were usually found in the IDE cells during the stages of enameloid mineralization and maturation. IDE cells are putatively involved in the removal of degenerated enameloid matrix during these stages. Marked ALPase activity was detected at the proximal and the lateral cell membranes of the IDE cells from the late stage of enameloid matrix formation to the early stage of enameloid maturation. Strong activity of Ca-ATPase was localized at the proximal and the lateral cell membranes of the IDE cells during the stages of enameloid mineralization and maturation. ALPase and Ca-ATPase activity is probably related to crystal formation in the enameloid and the removal of degenerated enameloid matrix from the enameloid.     

An ultrastructural study of the clitellar epithelium of the earthworm Metaphire posthuma (vail.)

The ultrastructure of clitellar epithelium of Metuphire posthuma revealed mainly three types of secretory cells. Most prominent among these are the large slender granular cells which contain a large number of secretory granules filling in the entire columncr region of the cell. The secretory granules are 2-4mu in diameter with a limiting membrane and containing numerous tiny vesicles in a matrix of varying electron density. Basolateral rough endoplasmic reticulum and extensive Golgi cisternae were seen interspersed with the secretory granules. The Golgi cisternae in these cells were quite prominent extending all around the secretory granules. The secretory granules of type 2 cells are spheroid bodies with motley appearance due to varying electron density of the matrix. The immature granules contain fibrillar material. Type 3 cells contained electron lucent membrane-bound mucous like secretory granules which are reticulated with filamentous materials. All the three cell types open to the exterior at the cuticular region which is characterised by the presence of numerous microvilli.     

The ultrastructure of the thyroid medullary carcinoma

The ultrastructure and the morphometrical pattern of secretory granules were studied in six cases of thyroid medullary carcinoma. The tumor cells were fusiform or polyhedral with irregular, mostly elongated nuclei. Phagolysosomes containing a crystalloid material, probably degraded lipoprotein complexes, degeneratively changed mitochondria, moderately developed rough endoplasmic reticulum and Golgi complexes were commonly found. Amyloid occurred as small fibrils in intercellular spaces. Marked dystrophic lesions of tumor cells surrounding amyloid fibrils were found. Numerous roundshaped electron-dense secretory granules were noticed in tumor cell cytoplasms. The morphometrical analysis showed that the size of granules oscillated between 60 and 450 nm with mean values ranging from 171.4 +/- 31.8 to 227.7 +/- 28.1 nm. Frequency distribution curves showed at least two peaks varying with the investigated case at different intervals. In two cases two distinct groups of granules were found within the same cells: one group of electron-dense, compact, smaller sized granules and another group of larger, finely granulated, less dense granules. In the other four cases the granule sizes were more homogeneous. These results might indicate that the granule size depends on the maturation degree and functional activity or that there are several kinds of granules specialized in the secretion of various substances.     

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.     

Action of colchicine on hepatic schistosomal granuloma

Amorphous material and altered collagen fragments within dilated secretory vesicles and cisternae of fibroblast cytoplasm were the main ultrastructural changes seen in hepatic periovular granulomas formed in mice infected with Schistosoma mansoni and treated with colchicine. Despite promoting ultrastructural changes in the fibroblasts found in hepatic periovular granulomas, colchicine administration to infected mice did not significantly change the light microscopic appearance of the hepatic schistosomal lesions, did not diminish the amount of total hepatic collagen, and did not change the collagen isotypes in the granulomas, as observed after a comparative study with non-colchicine treated infected control mice. When administered to mice two weeks after curative treatment of schistosomiasis with praziquantel, colchicine did not seem to increase extracellular collagen degradation or to induce a more rapid resorption of hepatic periovular granulomas, although still promoting ultrastructural alterations in fibroblasts.     

The ultrastructural identity of pancreatic polypeptide cells in chicks

A very similar ultrastructure has been attributed to pancreatic polypeptide and somatostatin cells in chickens. In order to characterize any possible differences between them, cells shown to be immunoreactive for these hormones in semi-thin sections of chick pancreas were identified in adjacent thin sections prepared for conventional electron microscopy. In this way the ultrastructural features of the immunoreactive cells could be determined. In general, in somatostatin-immunoreactive cells, granule profiles are almost exclusively round, whereas in pancreatic polypeptide cells there are elongate as well round profiles. Within cells of both types the electron density of the granule matrix varies from one granule to another, but the range of density is greater in pancreatic polypeptide granules. The latter are slightly smaller than somatostatin granules.     

Ultrastructure of mouse incisor ameloblasts after vascular perfusion with colchicine

Summary In order to revalue the effects of colchicine on incisor secretory ameloblasts, entire mice were perfused with Krebs solution supplemented with a buffer and amino acids, through the right common carotid artery. The normal ultrastructure of the cells was maintained for 2 h with the perfusate alone. When colchicine (0.3–3.0 g/ml) was added to the perfusate, it induced ultrastructural changes, such as the loss of cytoplasmic microtubules, the loss of secretory granules in Tomes' process, the abnormal accumulation and secretion of secretory granules, disarranged Golgi apparatus and the fragmentation of rough endoplasmic reticulum. Vesicles (150–400 nm in diameter) resembling immature secretory granules also accumulated, the degree of accumulation depending on the duration of colchicine treatment. The accumulation of secretory granules and these vesicles suggests that the intracellular transport system was affected by colchicine but that the production of secretory granules was continuous throughout the experimental period. The present perfusion system has enabled us to treat ameloblasts with an agent that is a useful experimental tool for elucidating cell functions, despite being lethal to animals in vivo.     

Localization of glycoproteins in insulin secretory granules by ultrastructural autoradiography

To determine whether or not the secretory granules of insulin-secreting cells contained glycoproteins, isolated rat pancreatic islets were incubated for 2 and 4 hr in a medium containing L-[3H]-fucose. Quantitative analysis of high-resolution electron microscopic autoradiographs of the insulin-secreting beta cells demonstrated that glycoproteins with fucose residues are contained within the insulin secretory granule.     

Immunohistochemical localization of procollagens. II. Electron microscopic distribution of procollagen I antigenicity in the odontoblasts and predentin of rat incisor teeth by a direct method using peroxidase linked antibodies.

In an attempt to locate procollagen I in rats odontoblasts, antibodies raised in rabbits were purified by affinity methods and linked to peroxidase. They were then incubated with chopped slices from the growing end of rat incisor teeth. The antibodies binding to the antigens in the slices were visualized by reacting the peroxidase moiety with diaminobenzidine in the presence of hydrogen peroxide. The slices were then embedded in Epon and sectioned for ultrastructural study. Within odontoblasts, the immunostaining indicative of procollagen I antigenicity is moderate in rough endoplasmic reticulum cisternae, strong in spherical and cylindrical Golgi distensions, intense in secretory granules, and variable in lysosomal structures. In predentin, immunostaining is intense close to the odontoblast layer, but decreases gradually in a distal direction. Hence, procollagen I (and/or substances endowed with similar antigenicity such as pro alpha (I) chains and procollagen fragments) is present: 1) along the intracellular pathway of collagen precursors where its concentration gradually increases to reach a maximum in secretory granules; 2) in predentin, into which it is released from the granules for transformation into nonimmunoreactive collagen I; and 3) in lysosomal structures where some of it is hydrolyzed.     

Influence of colchicine on the addition of a sugar to the enamel protein in secretory ameloblasts of cultured germs of rat molar tooth by 3H-galactose radioautography

Summary The influence of colchicine on the addition of ³H-galactose to the enamel protein in secretory amelloblasts of cultured germs of rat molar tooth was investigated by light- and electron-microscopic radioautography. In tooth germs cultured without colchicine, the reaction products of ³H-galactose were observed over Golgi cisternae at early chase times and then localized over the enamel with time. In tooth germs cultured with colchicine, the silver grains were seen over the Golgi cisternae, condensing granules and accumulated secretory granules. Some grains also appeared with time over the pale granular material precipitated in the intercellular space with colchicine treatment. In quantitative analysis with light microscopic radioautography, values of silver grain counts over the unit area (100 m²) on ameloblasts and enamel of colchicine-treated tooth germs were significantly lower at both 0 min and 30 min chase after 30 min pulse than those of control tooth germs, respectively. This finding indicates that colchicine diminished the incorporation of ³H-galactose into the secretory ameloblast of cultured tooth germs. It is suggested that colchicine decreases the activity of the Golgi apparatus with regared to the addition of sugar to the synthesizing glycoprotein in the secretory ameloblast.     

Morphology of the salivary glands of three Squamata species: Podarcis sicula sicula, Tarentola mauritanica and Coluber viridiflavus

The histology, histochemistry and ultrastructure of the salivary glands of three species of squamata, Podarcis sicula sicula (mandibular glands), Tarentola mauritanica (sublingual gland) and Coluber viridiflavus (supra- and infralabial glands) were studied. Each gland contained acidic cells, positive for both periodic acid Schiff and Alcian blue reactions. These cells can be distinguished as seromucous and mucous types based on the different electron density of their granules. α-Amylase, until now detected only in mammalian salivary glands, was not found in any of the salivary glands examined. The ultrastructural study revealed that the salivary glandular cells of T. mauritanica lack intercellular canaliculi, which by contrast, are present between the seromucous cells in the salivary glands of C. viridiflavus and P. s. sicula . Comparable variation is also seen when the ultrastructural features of the secretory granules in salivary glands of the three Squamata species are compared. The salivary granules of T. mauritanica and C. viridiflavus are more or less dense but structureless, while the mucous granules of P. s. sicula have a distinctive and characteristic substructure. Therefore, this study, designed to obtain comparative data on the histology, histochemistry and ultrastructure of the salivary glands of three representative, but hitherto unstudied, species of Squamata, reveals great variation in the structure of these glands within the Squamata lineage, even when compared to previously documented species.     

The ultrastructural identity of pancreatic polypeptide cells in chicks

Summary A very similar ultrastructure has been attributed to pancreatic polypeptide and somatostatin cells in chickens. In order to characterize any possible differences between them, cells shown to be immunoreactive for these hormones in semi-thin sections of chick pancreas were identified in adjacent thin sections prepared for conventional electron microscopy. In this way the ultrastructural features of the immunoreactive cells could be determined. In general, in somatostatin-immunoreactive cells, granule profiles are almost exclusively round, whereas in pancreatic polypeptide cells there are elongate as well as round profiles. Within cells of both types the electron density of the granule matrix varies from one granule to another, but the range of density is greater in pancreatic polypeptide granules. The latter are slightly smaller than somatostatin granules.     

The use of tannic acid for the ultrastructural visualization of hyaluronic acid

Summary This study describes a method, which makes use of tannic acid (2%) as a component of a paraformaldehyde-glutaraldehyde based fixative, to reveal the presence and ultrastructure of glycosaminoglycans in the extracellular matrix. The ultrastructure of the extracellular matrix in the stage 24 chick embryo wing is examined after fixation by several procedures. After fixation in the absence of tannic acid, the intercellular spaces contain little extracellular matrix, except for occasional fibrils (collagen?). On the other hand, when tannic acid is included in the primary fixative, the intercellular spaces contain considerable amounts extracellular matrix which includes 3±0.5 nm filaments, ±30 nm granules, as well as putative collagen fibrils. The 3±0.5 nm diameter fibrils are not observed when the limbs had been injected in ovo with Streptomyces hyaluronidase (specific for hyaluronic acid) prior to fixation. Furthermore, the 3±0.5 nm fibrils resemble authentic hyaluronic acid that had been fixed by the same procedure in the presence of tannic acid. Limbs treated with tannic acid after osmication contained only small amounts of extracellular material, which was confined largely to cell surfaces. These results demonstrate that the use of tannic acid in the primary fixative can serve as a useful method for the ultrastructural visualization of several extracellular matrix materials, including hyaluronic acid.This study was supported by NIH grant HD 05505