Localization of phosphophoryn in rat incisor dentin using immunocytochemical techniques

We studied the distribution of the phosphophoryn present in rat incisors by immunolocalization and histochemical techniques. The polyclonal antibody used reacts with both phosphorylated and de-phosphorylated phosphophoryn. Technical problems encountered in immunostaining and in preparing sections from mineralized dentin were resolved by use of peroxidase-conjugated protein A as the "second antibody" in indirect immunostaining reactions and by surface etching of partially demineralized sections. Staining with anti-rat incisor alpha-phosphophoryn antibody showed light staining over the odontoblasts and proximal odontoblastic processes, no stain over the predentin, dense staining over the intertubular dentin, and no stain over the mantle dentin. In the intertubular dentin the stain intensity was directly related to the distribution of mineral. These findings were directly corroborated by staining with Stains All. The mineralization of dentin and the distribution of phosphophoryn within the dentin may be much less uniform than previously supposed.     

Developmental expression of a 53 KD dentin sialoprotein in rat tooth organs.

Rat dentin contains a major sialic acid-rich glycoprotein, DSP, with an overall composition similar to that of bone sialoproteins but whose biological role in dentinogenesis is unknown. Using polyclonal affinity-purified antibodies to rat DSP and four immunohistochemical methods of detection, we studied the cell and tissue localization of DSP and the time course of its appearance during odontoblast differentiation. DSP first appeared within young odontoblasts concomitant with early secretion of pre-dentin matrix and before the onset of mineralization but was absent in pre-odontoblasts. DSP immunostaining also localized within secretory odontoblasts and was intense in odontoblastic processes. Early pre-dentin stained positive for DSP, in contrast to more mature pre-dentin, where immunoreactivity was less intense and more restricted to odontoblastic processes. In the zone of mineralized dentin matrix, a moderate and uniform staining pattern was evident. Intense immunostaining was also seen within the cells and matrix of dental pulp during dentinogenesis. Other cells and tissues within the tooth organ and those surrounding it were non-reactive. These findings suggest that DSP is developmentally expressed in cells of the odontoblastic lineage and may be a biochemical marker of odontoblastic activity.     

Immunohistochemical demonstration of nerves in the predentin and dentin of human third molars with the use of an antiserum against neurofilament protein (NFP)

Summary Immunohistochemistry by use of an antiserum against neurofilament protein (NFP) was applied for staining nerve fibers in the predentin and dentin of human third molars. By devising methods for fixation, decalcification and immunostaining, nerve fibers were clearly and specifically demonstrated in thick (more than 50 m) sections of teeth. Numerous NFP-positive fibers were distributed in the predentin throughout the coronal region, while a few positive fibers penetrated only a short distance into the dentin. The NFP-positive nerve fibers in the predentin took transverse and complicated courses across, rather than penetrating longitudinally through, the dentinal tubules. Pain sensation in the teeth might be attributable to these complex nerve fibers showing two or three-dimensional extensions.     

Temporo-spatial distribution of matrix and microfilament components during odontoblast and ameloblast differentiation

Summary Several extracellular matrix components (procollagen type III, fibronectin, collagen type IV, laminin and nidogen) and microfilament constituents (actin, α-actinin and vinculin) were localized by indirect immunofluorescence microscopy in frozen sections of embryonic mouse molars. Nidogen was present at the epithelio-mesenchymal junction during polarization and initial steps of functional differentiation of odontoblasts. Nidogen disappeared at a stage where direct contacts between preameloblasts and predentin were required to allow the initiation of ameloblast polarization. Our observations concerning the distribution of procollagen type III and fibronectin during odontoblast differentiation add to current knowledge. Procollagen type III and fibronectin surrounding preodontoblasts accumulated at the apical part of polarizing and functional odontoblasts secreting “initial” predentin. Procollagen type III, but not fibronectin, disappeared in front of functional odontoblasts synthesizing “late” predentin and dentin. Fibronectin, present in “initial” predentin, was no longer detected in “late” predentin and dentin but was found between odontoblasts secreting “late” predentin and dentin. Actin, α-actinin and vinculin were concentrated in the peripheral cytoplasm of preameloblasts and accumulated at the apical and basal poles of functional ameloblasts. During differentiation of odontoblasts, the three proteins accumulated at the apical pole of these cells. Time and space correlations between matrix and microfilament modifications during odontoblast and ameloblast differentiation are documented. The possibility is discussed that there is transmembranous control of the cytoskeletal activities of odontoblasts and ameloblasts by the extracellular matrix.     

S100 protein-immunoreactive trigeminal neurons innervating the rat molar tooth pulp

S100-immunoreactivity (ir) was examined in tooth pulp primary neurons of the rat. An immunofluorescence method demonstrated that the molar tooth pulp contained S100-immunoreactive (ir) nerve fibers. In the root pulp, pulp horn and roof of the pulp chamber, S100-ir smooth and varicose fibers ramified and formed subodontoblastic nerve plexuses. All the fibers became varicose at the base of the odontoblastic layer and extended to the odontoblastic layer. Some varicose endings could be traced into the dentin. The trigeminal neurons retrogradely labeled with fluorogold (FG) from the first and second maxillary molar tooth pulps exhibited S100- and parvalbumin-ir. Approximately 60% and 24% of the labeled cells were ir for S100 and parvalbumin, respectively. Virtually all parvalbumin-ir FG-labeled cells showed S100-ir, while 40% of S100-ir ones coexpressed parvalbumin-ir. An immunoelectron microscopic method revealed that all myelinated axons and half of the unmyelinated axons in the root pulp contained S100-ir. In the odontoblastic layer, predentin and dentin, S100-ir neurites lost the Schwann cell ensheathment and made close contact with cell bodies and processes of odontoblasts. The odontoblastic layer also contained parvalbumin-ir neurites. These neurites were devoid of the Schwann cell ensheathment and in close apposition to cell bodies and processes of odontoblasts. S100-ir pulpal axons seemed to be insensitive to repeated neonatal capsaicin treatment. This study suggests that S100-ir tooth pulp primary neurons are mostly myelinated and that S100-ir unmyelinated axons in the root pulp are preterminal segments of myelinated stem axons.     

Changes in the matrix proteins, fibronectin and collagen, during differentiation of mouse tooth germ.

The distribution of the matrix protein fibronectin was studied by indirect immunofluorescence in differentiating mouse molars from bud stage to the stage of dentin and enamel secretion, and compared to that of collagenous proteins procollagen type III and collagen type I. Fibronectin was seen in mesenchymal tissue, basement membranes, and predentin. The dental mesenchyme lost fibronectin staining when differentiating into odontoblasts. Fibronectin was not detected in mineralized dentin. Epithelial tissues were negative except for the stellate reticulum within the enamel organ. Particularly intense staining was seen at the epithelio-mesenchymal interface between the dental epithelium and mesenchyme. Fibronectin may here be involved in anchorage of the mesenchymal cells during their differentiation into odontoblasts. Procollagen type III was lost from the dental mesenchyme during odontoblast differentiation but reappeared with advancing vascularization of the dental papilla. Similarly, procollagen type III present in the dental basement membrane during the bud and cap stages disappeared from the cuspal area along with odontoblast differentiation. Weak staining was seen in predentin but not in mineralized dentin. The staining with anti-collagen type I antibodies was weak in dental mesenchyme but intense in predentin as well as in mineralized dentin.     

Immunohistochemical localization of procollagens. I. Light microscopic distribution of procollagen I, III and IV antigenicity in the rat incisor tooth by the indirect peroxidase-anti-peroxidase method.

Frozen sections of the growing end of the rat incisor tooth were exposed to antisera or affinity prepared antibodies against partially purified type I, II, or IV procollagen in the hope of detecting the location of the corresponding antigens by the peroxidase-anti-peroxidase technique. The distribution of immunostaining was similar with antisera as with purified antibodies of a given type, but differed for each type; that is, predentin, odontoblasts, pulp and periodontal tissue were the sites of type I; blood vessel walls, pulp and periodontal tissue, of type III; and basement membranes, of type IV antigenicity. It was demonstrated, at least in cases of type I and III, that immunostaining detected the corresponding procollagens and related substances, but not the corresponding collagens. The interpretation of these observations is that: 1) odontoblasts elaborate procollagen I for release to predentin and subsequent transformation to dentinal collagen I; 2) pulp and periodontal cells produce procollagens I and III which presumably become collagens I and III respectively, while the adventitial cells of blood vessels give rise to collagen III; and 3) procollagen IV is associated with basement membranes and, occasionally, adjacent cells.     

Ultrastructural localization of complex carbohydrates in odontoblasts, predentin, and dentin

Glycosaminoglycans (GAGs) and glycoproteins (GPs) are essential components for dentinogenesis. We have examined rat odontoblasts, predentin, and dentin decalcified with EDTA and stained with: 1) Spicer's hig-iron diamine-thiocarbohydrazide-silver proteinate (HID-TCH-SP) method for sulfated glycoconjugates, and 2) Thiéry's periodate-thiocarbohydrazide-silver proteinate (PA-TCH-SP) method for vicinal glycol-containing glycoconjugates. HIS-TCH-SP stained distended portions of Golgi saccules and secretory granules. The predentin contained three times the number of HID-TCH-SP stain precipitates when compared to the mineralization front of the dentin matrix. PA-TCH-SP weakly stained membranes of Golgi saccules and cisternae of rough endoplasmic reticulum (RER), whereas stronger staining was observed in secretory granules, lysosomes, and multivesicular bodies (MVBs). Collagen fibrils in predentin demonstrated moderate PA-TCH-SP staining. In contrast, strong PA-TCH-SP staining was observed on and between collagen fibrils in the mineralization front of the dentin matrix. TCH-SP controls of unosmicated specimens lacked significant staining, however, osmicated control specimens did contain some TCH-SP stain deposits in the mineralization front. These results indicate that sulfated and vicinal glycol-containing glycoconjugates are packaged in the same type of secretory granule and released into the extracellular matrix; subsequently vicinal glycol-containing glycoconjugates concentrate in the calcification front, whereas sulfated glycoconjugates accumulate in the predentin and are either removed or masked to staining in the dentin.     

Changes in the distribution of type IV collagen,laminin, proteoglycan,and fibronectin during mouse tooth development

The distribution of certain basement membrane (BM) components including type IV collagen, laminin, BM proteoglycan, and fibronectin was studied in developing mouse molar teeth, using antibodies or antisera specific for these substances in indirect immunofluorescence. At the onset of cuspal morphogenesis, type IV collagen, laminin, and BM proteoglycan were found to be present throughout the basement membranes of the tooth. Fibronectin was abundant under the inner enamel epithelium at the region of differentiating odontoblasts and also in the mesenchymal tissues. After the first layer of predentin had been secreted by the odontoblasts at the epithelial-mesenchymal interface, laminin remained in close association with the epithelial cells whereas type IV collagen, BM proteoglycan, and fibronectin were distributed uniformly throughout this area. Later when dentin had been produced and the epithelial cells had differentiated into ameloblasts, basement membrane components disappeared from the cuspal area. These matrix components were not detected in dentin while BM proteoglycan and fibronectin were present in predentin. The observed changes in the collagenous and noncollagenous glycoproteins and the proteoglycan appear to be closely associated with cell differentiation and matrix secretion in the developing tooth.     

Effects of gamma radiation on hard dental tissues of albino rats: investigation by light microscopy

The present work aims at studying the effect of gamma radiation on the hard dental tissues. Eighty adult male albino rats with weights of about 250 g were used. The rats were irradiated at 0.2, 0.5, 1.0, 2.0, 4.0 and 6.0 Gy whole-body gamma doses. The effects on hard dental tissue samples were investigated after 48 h in histological and ground sections using light microscopy. Areas of acid phosphatase activity were detected using tartrate-resistant acid phosphatase (TRAP) stains. Observation of histological sections revealed disturbance in predentin thickness and odontoblastic layer as the irradiation dose increased. In cementum, widened cementocytes lacunae were occasionally detected even with low irradiated doses. On the other hand, relatively homogenous enamel was detected with darkened areas in enamel surface at doses over than 0.5 Gy. TRAP-positive cells were detected on the surface of the dentin of irradiated groups as well as cementum surface. Minimal detectable changes were observed in ground sections.     

Immunohistochemical localization of glycosaminoglycans and proteoglycans in predentin and dentin of rat incisors.

We examined immunocytochemically the type and distribution of glycosaminoglycans and proteoglycans (PG) in predentin and dentin demineralized with EDTA after aldehyde fixation of rat incisors using (a) four monoclonal antibodies (1-B-5,9-A-2,3-B-3, and 5-D-4) which recognize epitopes in unsulfated chondroitin (C0-S), chondroitin 4-sulfate (C4-S), chondroitin 6-sulfate (C6-S), and keratan sulfate (KS) associated with the PG, and (b) monoclonal (5-D-5) and polyclonal antibodies specific for the core protein of large and small dermatan sulfate (DS) PG. Light microscope immunoperoxidase staining after pre-treatment of tissue sections with chondroitinase ABC localized the majority of stainable PG (C4-S, KS, DSPG, C0-S, and C6-S) in predentin and, to a lesser extent (C4-S and small DSPG), in the dentin matrix. The former site demonstrated relatively homogeneous PG distribution, whereas the latter site revealed that strong staining of C4-S and small DSPG was confined mostly to dentinal tubules surrounding odontoblastic processes, with only weak staining in the rest of the dentin matrix. These results indicate that there is not only a definite difference between PG of predentin and dentin but also a selective decrease in the concentration or alteration of these macromolecules during dentinogenesis and mineralization.     

Immunodetection of osteoadherin in murine tooth extracellular matrices

An antiserum was generated from synthetic peptides highly conserved between different mammalian species to immunolocalise the small leucine-rich proteoglycan osteoadherin (OSAD) in murine teeth. In 19-day-old embryos of rats and mice, a positive staining was found in incisor predentin and alveolar bone surrounding developing incisors and molars. In newborns, OSAD was detected at the tip of the first molar cusp where it accumulated in predentin concomitantly with odontoblast differentiation. In 2-day-old rats and mice, in the first molar, immunostaining revealed positive predentin, enamel matrix close to the apical pole of ameloblasts and a strong signal in dentin. At this stage, OSAD was detected in predentin in the second molar. Ultrastructural immunocytochemistry showed gold particles associated with collagen fibres in predentin and in foci at the dentin mineralisation front. Gold particles were also detected near the secretory pole of ameloblasts where enamel crystallites elongate. No staining was detected in pulp tissue and dental follicle. Restriction of OSAD expression to the extracellular matrix of bone, dentin and enamel suggests a role of this proteoglycan in the organisation of mineralised tissues.     

Suramin-induced mucopolysaccharidosis in rat incisor

Two weeks after a single injection of suramin, the secretory and post-secretory ameloblasts of the rat incisor were filled with large lysosome-like vacuoles. At the light-microscope level, these vacuoles were positively stained with Alcian blue when MgCl₂ was used at a critical electrolyte concentration varying between 0.1 and 0.3 M, whereas no staining appeared when MgCl₂ varied between 0.7 and 0.9 M. Hyaluronidase digestion markedly reduced but did not totally abolish the staining, indicating that glycosaminoglycans were accumulated inside these vacuoles. Examination of these cells with the electron microscope revealed a polymorphic population of large vesicles, filled to various degrees with cetylpyridinium chloride (CPC)-positive and malachite green aldehyde (MGA)-positive material. The same pattern was observed in secretory odontoblasts but to a lesser extent. In the extracellular matrix, suramin-induced alterations appeared as large defects occurring during enamel formation. In predentin and dentin, the number and/or size of electron-dense aggregates resulting from CPC and MGA fixation, were enhanced in the suramin-injected rats. These aggregates were largely reduced or suppressed respectively by hyaluronidase digestion and chloroform/methanol treatment of the sections. The accumulation of glycosaminoglycans and phospholipids reported here inside ameloblasts and odontoblasts and in predentin and dentin supports the occurrence of suramin-induced mucopolysaccharidosis and lipidosis in this experimental animal model.     

Ultrastructural patterns of human dentinal tubules, odontoblasts processes and nerve fibres

The structure of the dentin, consists of the following elements: the odontoblastic processes, dentinal tubules and their periodontoblastic spaces. The odontoblasts are aligned in a single layer in the periphery of the dental pulp and secrete the organic components of dentin. The vitality of dentin is mediated too by the nerve fibres. The ultrastructure of the trigeminal sensory nerves in dentin, especially in relation to odontoblasts remains to be clarified. We studied the third molars and young premolars. The specimens were fixed in glutaraldehyde immediately after extraction. Our investigations give evidence to prove that the distribution of the dentinary tubules is homogeneous, containing a principal odontoblastic prolongation in the regions of the inner dentine, and only in special cases more than one. The area of the dentinary tubules and the odontoblastic prolongations' area were studied. The nervous fibres appeared accompanying 30-70% of the odontoblastic prolongations and their synapsis-like relation with the odontotoblastic processes was demonstrated. The existence of very few periodontoblastic spaces, and intradentinal sensory axons, as well as the intercellular connections will allow us to discover more about the mechanisms of the dentinary permeability, and its significance in maintenance and repair of the human pulpodentinal complex.     

Fibromodulin-deficient mice display impaired collagen fibrillogenesis in predentin as well as altered dentin mineralization and enamel formation.

To determine the functions of fibromodulin (Fmod), a small leucine-rich keratan sulfate proteoglycan in tooth formation, we investigated the distribution of Fmod in dental tissues by immunohistochemistry and characterized the dental phenotype of 1-day-old Fmod-deficient mice using light and transmission electron microscopy. Immunohistochemistry was also used to compare the relative protein expression of dentin sialoprotein (DSP), dentin matrix protein-1 (DMP 1), bone sialoprotein (BSP), and osteopontin (OPN) between Fmod-deficient mice and wild-type mice. In normal mice and rats, Fmod immunostaining was mostly detected in the distal cell bodies of odontoblasts and in the stratum intermedium and was weaker in odontoblast processes and predentin. The absence of Fmod impaired dentin mineralization, increased the diameter of the collagen fibrils throughout the whole predentin, and delayed enamel formation. Immunohistochemistry provides evidence for compensatory mechanisms in Fmod-deficient mice. Staining for DSP and OPN was decreased in molars, whereas DMP 1 and BSP were enhanced. In the incisors, labeling for DSP, DMP 1, and BSP was strongly increased in the pulp and odontoblasts, whereas OPN staining was decreased. Positive staining was also seen for DMP 1 and BSP in secretory ameloblasts. Together these studies indicate that Fmod restricts collagen fibrillogenesis in predentin while promoting dentin mineralization and the early stages of enamel formation.     

The distribution of peritubular matrix in human coronal dentin

Thin semi-serial ground sections of coronal dentin were examined radiographically. The bulk of the coronal dentin was characterized by the majority of the tubules having a distinct peritubular zone. With the exception of the tubules running from the tip of the cusp to the pulp cornu, the bulk of peritubular matrix forming the walls of the tubules was disposed eccentrically. The matrix was thicker on the cervical sides of the tubule than it was on the incisal sides. In a relatively narrow layer of the coronal dentin between the bulk of the dentin and the predentindentin border area the thickness of the peritubular matrix varied considerably. It was extremely narrow or absent in some tubules and reached its greatest thickness in others. The tubules in the predentin border area showed little or no evidence of peritubular matrix. The area of dentin beneath the central developmental groove differed somewhat from the bulk of the dentin. Many of the tubules at all levels of this area showed little radiographic evidence of peritubular matrix. Obliterated tubules were seen in some of the sections taken immediately above the predentin-dentin border area in the region of the pulp cornu and were always seen at the junction of the mantle dentin and the circumpulpal dentin beneath the central developmental groove.     

Cell pellets from dental papillae can reexhibit dental morphogenesis and dentinogenesis

We isolated dental papilla mesenchymal cells (DPMCs) from different rat incisor germs at the late bell stage and incubated them as cell pellets in polypropylene tubes. In vitro pellet culture of DPMCs presented several crucial characteristics of odontoblasts, as indicated by accelerated mineralization, positive immunostaining for dentin sialophosphoprotein and dentin matrix protein 1, and expression of dentin sialophosphoprotein mRNA. The allotransplantation of these pellets into renal capsules was also performed. Despite the absence of dental epithelial components, dissociated DPMCs with a complete loss of positional information rapidly underwent dentinogenesis and morphogenesis, and formed a cusp-like dentin-pulp complex containing distinctive odontoblasts, predentin, dentin, and dentinal tubules. These results imply that DPMCs at the late bell stage can reexhibit the dental morphogenesis and dentinogenesis by themselves, and epithelial-mesenchymal interactions at this stage may not be indispensable. Furthermore, different DPMC populations from the similar stage may keep the same developmental pattern.     

Changes in the predentin thickness and mineralization front configuration in developing human premolars

The thickness of the predentin layer was studied at three different levels of developing human premolars. The results demonstrate that at the growing end next to the apex, where dentinogenesis is most active, predentin exhibits its greatest thickness (mean value 40.4 micron). However, at the coronal region, where primary dentin has been completely formed, predentin width is reduced to a mean value of 14.8 micron. Changes in the calcospheritic configuration of the mineralization front were established for each of the predentin levels studied. A comparative analysis of these calcospheritic changes and the morphology of fluorescent tetracycline lines detected in ground sections of premolars was established. Fluorescent lines observed at the coronal circumpulpal dentin showed large calcospheritic forms beneath the mantle dentin. However, lines found near the dentin-pulp border showed small calcospherites. It is concluded that the thickness of the predentin layer and the mineralization front configuration vary as a function of dentinogenic activity during development of human premolars.     

Developmental expression of 44-kDa bone phosphoprotein (osteopontin) and bone γ-carboxyglutamic acid (Gla)-containing protein (osteocalcin) in calcifying tissues of rat

New aspects of the distribution and developmental appearance of the 44-kDa bone phosphoprotein (44K BPP, also called sialoprotein I or osteopontin) and bone gamma-carboxyglutamic acid (Gla)-containing protein (BGP, also called osteocalcin) during osteogenesis and dentinogenesis were investigated with immunocytochemical techniques using monospecific, affinity-purified polyclonal antibodies. Sections from newborn rat incisors and from various bone anlagen of newborn animals and fetuses were processed for detection of 44K BPP or BGP antigenicity. In addition, histochemical reactions for detection of alkaline phosphatase or calcium salts were performed on a number of the sections. The 44K BPP appears to be synthesized and secreted by chondrocytes only in the areas of cartilage-to-bone transition; these cells could participate indirectly in the process of bone formation by providing a suitable scaffold onto which primary marrow osteoblasts attach and spread. During osteogenesis, 44K BPP is found in bone-forming cells almost concomitantly with the appearance of alkaline phosphatase and before osteoid deposition, whereas BGP is still absent during early stages of mineralization. We hypothesize that this dramatic difference between the developmental appearance of 44K BPP and BGP reflects the delayed expression of the BGP gene relative to that of 44K BPP. In long-term cultures of bone marrow from adult mice, some fibroblastic cells expressed the 44K BPP phenotype; these cells could represent early osteogenic progenitor cells. Some experiments also suggested that, as with BGP, 44K BPP or an immunologically related protein is synthesized by some odontoblasts and secreted into predentin, prior to the onset of mineralization.     

Mucopolysaccharides in odontogenesis

Summary Localization of sulfomucopolysaccharides in developing teeth of Swiss albino mice was detected by S³⁵ autoradiography and histochemistry.A positive correlation was found to exist between autoradiographic and histochemical data with regard to the localization of sulfomucopolysaccharides. Autoradiography, however, revealed some sites of localization which were not detectable by histochemistry, namely, the odontoblasts and stratum intermedium.Fetuses which received the isotope via maternal injection at the cap stage of tooth development and were sacrificed after 2 hours of isotope action displayed rapid incorporation of the isotope in the components of the dental papilla. In the enamel organ, however, only moderate activity was recorded. When the time interval between injection and sacrifice of the experimental animals was increased to 20 hours, intense activity was observed in the enamel organ. With progressively longer intervals between injection and sacrifice, S³⁵ was demonstrable first in odontoblasts and later in the predentin. This occurred as a band or active zone which migrated toward the dentino-enamel junction. With the increasing intervals between injection and sacrifice, first the odontoblasts were active, then predentin was active while the odontoblasts became reduced in activity, after which the dentin matrix gained activity while the predentin decreased somewhat in activity. This pattern is consistent with appositional growth. A linear band of activity was not observed in the enamel matrix; rather, the activity was present as a diffuse stippling over a relatively large area of the matrix. The sulfomucopolysaccharide which existed in dentin matrix was postulated to have originated from the cells of both the odontoblastic layer and the dental papilla.Supported by PHS Grant No 2800-02, Tooth Germ Development, National Institute of Dental Research, National Institutes of Health.