Immunofluorescent localization of collagens,fibronectin, and laminin during terminal differentiation of odontoblasts

The localization of collagens types I, II, III, IV, laminin, and fibronectin was analyzed in mouse embryonic molars by indirect immunofluorescence. Using affinity-purified antibodies, all these antigens except collagen type II were detected in tooth germs and particularly at the epithelio-mesenchymal junction. Collagens type I, type IV, and laminin were localized at the junction before, during, and after odontoblasts terminal differentiation. The staining patterns corresponding to type III collagen and fibronectin were modified during the polarization of odontoblasts. Collagen type III present at the epithelio-mesenchymal junction could no longer be detected in this region when odontoblasts were polarized. Fibronectin, surrounding preodontoblasts, was confined to the epithelio-mesenchymal junction when odontoblasts were fully polarized. Previous studies had shown that the presence of a basement membrane and associated material was a prerequisite for the polarization of odontoblasts. Therefore, the redistribution of collagen type III and fibronectin was discussed in terms of fibronectin-collagen interactions and transmembranous control of the cytoskeleton activity in the differentiating odontoblasts.     

35S]autoradiographic study of sulfated GAG accumulation and turnover in embryonic mouse tooth germs

The accumulation of sulfated GAG in embryonic mouse molars before, during, and after terminal differentiation of odontoblasts was localized by [35S]autoradiography combined with the use of chondroitin ABC lyase. Much more sulfated GAG were accumulated in the dental papilla than in the dental epithelium. High incorporation of [35S]sulfate occurred at the epithelio-mesenchymal junction, which is the site of dental basement membrane and predentin. Before terminal differentiation of odontoblasts, the distribution of sulfated GAG was uniform at the basement membrane. After the onset of terminal differentiation of odontoblasts, much more sulfated GAG accumulated at the tip of principal cusps than at the apical (inferior) parts of cusps, and sulfated GAG were then found to be degraded more rapidly at the epithelio-mesenchymal junction than at other parts of the tooth germ. Thus regional variation in the rate of degradation of GAG exists in the tooth germs. Trypsin-isolated dental epithelia cultured in vitro synthesized a new basement membrane that could be labeled with [3H]glucosamine but not with 35SO4(-2). The epithelial-derived basal lamina contains little or no sulfatated GAG.     

Effects of cytochalasin B and colchicine on dental cytodifferentiation in vitro]

The effects of various concentrations of cytochalasin B and colchicine on the polarization of odontoblasts and ameloblasts of mouse tooth buds cultivated in vitro, were studies. It was shown that cytochalasin B, deside its action on the microfilaments, had important cytotoxic effects; dilatation of the odontoblast's processus, accumulation of secretory granules in the Golgi apparatus, dilatation of mitochondria, inhibition of polarization or depolarization of odontoblasts and ameloblasts. These modifications resulted chiefly from the lesion of microtubules which seem to play an important role in the polarization of the cells studies.     

Basal bodies in the odontoblasts of the limpet,Patella coerulea L. (Gastropoda)

Summary The odontoblasts in the long radular gland of Patella coerulea L. are arranged in a terminal position; therefore newly formed teeth already have an upright position. The long and slender odontoblasts have only one to three lengthy and ramifying apical microvilli. Between these pinnate microvilli a fine filamentous material appears which probably corresponds to chitin microfibrils. Therefore, the pattern of chitin microfibrils seems to depend on the arrangement of odontoblasts' microvilli. For the first time, basal bodies were found in the apical part of odontoblasts which led to the assumption that the radular gland originally might have been a mucous gland, the secretion of which was transported by cilia.     

Cell-matrix interactions and odontoblast differentiation]

The terminal differentiation of odontoblasts requires the integrity of the cytoskeleton and is controlled by cell-matrix interactions. These interactions implicate both matrix molecules and matrix-associated growth factors. On the one hand, predentin-dentin constituents were found to initiate odontoblast differentiation and to allow the maintenance of this state; TGF-beta or related molecules are implicated. Fibronectin on the other hand can induce the differentiation of second generation odontoblasts and interacts with three high molecular weight proteins present in membrane prepared from dental mesenchymal cells. One of these proteins (165 kDa) was localized on the surface of odontoblasts and is involved in the organization of microfilaments. Two main axes of research will have to be developed in the future in order to understand how matrix molecules and growth factors interactions can be modulated in time and space by epithelial and mesenchymal cells, and how such modulations can affect the phenotype of these cells.     

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.     

Expression and localization of reelin in human odontoblasts.

Reelin is a large extracellular matrix (ECM) glycoprotein strongly expressed during embryonic development in the central nervous system and involved in architectonic brain development. It could participate in axon plasticity processes or adhesion-recognition between nerve fibers in adulthood. Previously identified from a subtractive cDNA library of fully differentiated human odontoblasts, reelin might be involved in the relationship between dental nerves and odontoblasts in as so far the latter are in close association with pulpal nerve fibers. Here, we show by in situ hybridization and immunohistochemistry that reelin is specifically expressed by human odontoblasts in vivo and in vitro and that an intense expression of the reelin gene is detected in odontoblasts in comparison with pulpal cells (PC). Co-cultures of rat trigeminal ganglion (TG) and odontoblasts allow to mimic odontoblast innervation and demonstrate that neurites contact these cells with reelin molecules as observed in vivo in human dental pulp. Moreover, by RT-PCR, we show that both reelin receptors (namely apolipoprotein E receptor [ApoER-2], very low density lipoprotein receptor [VLDLR] and cadherin-related neuronal receptor [CNR]) and the cytoplasmic adapter Disabled-1 implicated in the reelin signal transduction, were expressed by trigeminal ganglion. On the basis of these data, we suggest that reelin might be an extracellular matrix molecule involved in the terminal innervation of the dentin-pulp complex, promoting adhesion between dental nerve endings and odontoblasts.     

Localization of actin during differentiation of the ameloblast, its related epithelial cells and odontoblasts in the rat incisor using NBD-phallacidin

Using NBD-phallacidin, which specifically binds to F-actin, we investigated changes in the localization of actin during the differentiation of ameloblasts, related epithelial cells and odontoblasts in rat incisors. In cryosections treated with NBD-phallacidin, intense fluorescence was observed in undifferentiated epithelial cells in the apical loop and at the proximal extremity of undifferentiated inner enamel epithelial cells. During differentiation, the distal extremity began to exhibit strong fluorescence. In cross-sections of secretory ameloblasts, the fluorescence took the form of polygons of uniform intensity at the proximal end, and of rectangles of non-uniform intensity at the distal end. At the distal end, the fluorescence was more intense at right angles to the long axis of the incisor. At the distal end, this pattern was established just before the appearance of the enamel layer. These patterns were maintained during the secretory stage of ameloblasts. The location, pattern and time of appearance of these sites were identical to those of the terminal webs in ameloblasts. NBD-phallacidin weakly labelled the peripheral cytoplasm of the cell body of ameloblasts, and also labelled Tomes' process. The cells forming the stratum intermedium were mainly labelled at their periphery (i.e. forming larger polygons), while the overlying epithelial cells exhibited labelling throughout their cytoplasm. Except for the terminal webs, the cell bodies of odontoblasts were weakly labelled throughout the period of differentiation. Young odontoblasts secreting predentin were first labelled on the terminal web, with the fluorescence becoming gradually more intense as the thickness of the dentin increased.(ABSTRACT TRUNCATED AT 250 WORDS)     

A substractive PCR-based cDNA library from human odontoblast cells: identification of novel genes expressed in tooth forming cells.

Odontoblasts are highly specialized cells aligned at the edge of the dental pulp. As a step towards understanding the complex mechanisms underlying their terminal differentiation, the gene expression pattern was examined in human cultured odontoblast cells. Suppression substractive hybridization (SSH) was used to establish a substracted cDNA library specific for human odontoblasts. For this purpose, cDNAs from human cultured fibroblastic pulp cells were substracted to cDNA from human cultured odontoblasts. The nucleotide sequence of 154 substracted cDNA clones was determined. We identified 130 preferentially expressed gene fragments in odontoblasts as compared with the fibroblastic pulp cells. Ten of them were already identified in odontoblasts such as DSPP, BSP, enamelysin and Col1A1. We confirmed their overexpression by RT-PCR on the cultured cells and in vivo by in situ hybridization on human molars. Another 64 clones corresponded to known genes. Among them, two clones were of particular interest: reelin, which was first detected in the brain and osteoadherin, which was first located in bone. Fifty-six clones were unknown genes even though 82% matched expressed sequence tags or genomic clones. A reverse Northern dot blot showed that 96% of them were overexpressed at different rates in cultured odontoblasts. These latest results indicate that there are still unknown genes that are associated with the control of the odontoblast phenotype. Thus, cloning of odontoblast differentiation-associated genes not only opens up new methods of elucidating the normal development but also the recruitment of odontoblasts when required to initiate repair of dentin.     

Odontoblast expression of semaphorin 7A during innervation of human dentin.

Semaphorin 7A (SEMA 7A) is a membrane-anchored member of the semaphorin family of guidance proteins, previously identified in the immune system. Expressed in central and peripheral nervous system during embryonic and post-natal stages, it can mediate neuronal functions by promoting axonal growth. We show here that SEMA 7A is expressed in human odontoblasts in vivo and in vitro and that its expression is correlated with the establishment of dentin-pulp complex terminal innervation . Co-cultures of trigeminal ganglion (TG) with COS cells overexpressing SEMA 7A demonstrate that SEMA 7A can promote the growth of trigeminal nerve fibers. Finally, by RT-PCR and immunochemistry, we show that beta1-integrin, a SEMA 7A putative receptor, is expressed in pulpal nerve fibers but we failed to detect a co-localization between nerves and odontoblasts through these molecules. On the basis of these data, we suggest that SEMA 7A might be a molecule involved in the terminal innervation of the dentin-pulp complex.     

Immuno-electron-microscopic localization of laminin and collagen type IV in normal and denervated tooth pulp of the cat

Summary The distribution of laminin-like immunoreactivity in adult normal and denervated cat mandibular tooth pulps was studied by the use of fluorescence microscopy and pre-embedding immunogold electron microscopy. Immunoreactivity to collagen IV was also assessed in order to distinguish basement membranes. In normal pulps, light-microscope laminin-like immunoreactivity was strong along blood vessels and Schwann cell sheaths, and a faint immunoreactivity was seen also in the odontoblast layer. Electron microscopy confirmed the laminin-like immunoreactivity of endothelial and Schwann cell basement membranes at all pulpal levels. In the odontoblast layer and the predentine, nerve-like structures lacking basement membranes but possessing strong membrane laminin-like immunoreactivity were encountered. In addition, a clear-cut laminin-like immunoreactivity of plasma membranes of the somata and processes of odontoblasts was seen. Observations on denervated pulps as well as pulps in which nerve regeneration had taken place did not reveal any changes in the pattern of laminin-immunoreactivity in basement membranes or odontoblasts. Distribution of collagen IV-like immunoreactivity was very similar to laminin-like immunoreactivity in basement membranes of blood vessels and Schwann cells, and appeared unaffected by denervation. The odontoblasts and nerve-like profiles in the odontoblast layer were devoid of collagen IV-like immunoreactivity. We propose that odontoblast-associated laminin could be of significance as guidance for regenerating terminal pulpal nerve fibers to appropriate targets.     

Facts and Hypotheses Concerning the Control of Odontoblast Differentiation

Numerous studies using amphibians have demonstrated that preodontoblasts emerging from the dental papilla are derived from cranial neural crest cells [4, 12, 46, 64]. However this has not been established for mammals. The history of odontogenesis begins during the early stages of cranial-facial development when the maxillary and mandibular processes develop. Continuous epithelio-mesenchymal interactions condition the histogenesis and morphogenesis of the teeth [24–26, 43, 44, 49, 51,58] as well as the terminal differentiation of odontoblasts and ameloblasts [23, 47, 52, 54, 59, 61, 67].
During recent years a considerable amount of experimental data relating to differentiation of odontoblasts has been published. We summarize these data and attempt to integrate them in deductive hypotheses concerning the control of odontoblast differentiation.     

Neurotrophin receptors and nerve growth factor are differentially expressed in adjacent nonneuronal cells of normal and injured tooth pulp

High-affinity tyrosine kinase A (trkA) neurotrophin receptors on neurons and nonneuronal cells elicit differentiation or survival functions in response to nerve growth factor (NGF), whereas the low-affinity neurotrophin (p75) receptor modulates trkA activity or can independently cause apoptosis or NFkappaB-mediated survival functions. We examined dental tissues for the presence of trkA-like immunoreactivity (trkA-IR), to determine which nonneuronal cell types express it in normal compared with inflamed teeth and how the trkA-positive cells relate to those expressing the p75 receptor and/or NGF. Normal and injured rat molars (dentin cavity for 4 h, 16-24 h, 3 days, 16 days, or 5 weeks) were immunoreacted using the ABC detection system for two anti-trkA antibodies (sTA, Santa Cruz Biotechnology; rTA, L. Reichardt) and antibodies against p75 and NGF, all of which also stained pulpal nerve fibers. We report that, when using the sTA antibody (recognizing the intracellular carboxy terminal), nonneuronal trkA-IR was found in odontoblasts of normal teeth and also in invading polymorphonuclear leukocytes (PMNs) and reparative odontoblasts after injury. When using rTA (recognizing the extracellular domain of the receptor), nonneuronal trkA-IR was only found in odontoblasts. Odontoblasts also had NGF-IR but did not label for NGF mRNA. The lack of odontoblast NGF mRNA suggests that NGF is passed from fibroblasts to the adjacent odontoblasts, where it is picked up by receptor-mediated mechanisms for regulation of odontoblast function. Tooth injury disrupts this system such that trkA-IR decreases in injured odontoblasts, p75 decreases in fibroblasts, and NGF is upregulated by fibroblasts and accumulates in the injured pulp and surviving odontoblasts. Pulpal NGF may contribute to chemoattraction for the invading leukocytes or their sTA-IR may have been induced in response to pulpal NGF. Thus, tooth pulp has a different distribution of nonneuronal NGF and its paracrine receptors during inflammation compared with normal conditions.     

Production of monoclonal antibodies against mouse molar papilla cells

To develop markers for the analysis of the molecular mechanisms of dental papilla cells differentiation, 10 monoclonal antibodies were produced against trypsin-isolated mouse molar dental papilla cells. These antibodies identify matrix components, cell membrane associated antigens and intracellular-constituents. Changes of the staining patterns were correlated with a typological hierarchy of dental papilla cells and with terminal differentiation of odontoblasts.     

Early odontoblastic layer response to cavity preparation and acid etching in rats

The aim of this study was to establish the early odontoblastic layer response and quantitatively to estimate the number of odontoblasts after cavity preparation with and without acid etching. Half of 56 cavities prepared on rats' first upper molars were acid etched. Qualitative and morphometric analyses were made on histological and ultrathin sections 5 min, 6 h, 24 h and 72 h post-operatively. Under the etched cavity, a greater disarrangement of odontoblasts was found, modifications in nuclear shape and condensed chromatin 5 min. post-operatively. An additional reduction of odontoblast number was detected and an increase of aspirated cell number 5 min, 6 h and 24 h post-operatively, pronounced hyperaemia 6, 24 and 72 hours post-operatively and increased odontoblast number 72 hours post-operatively, compared to unetched cavities. In conclusion, injury to the odontoblastic layer was greater, but numerical renewal of the odontoblastic layer began earlier in etched cavities compared to unetched cavities.     

Change of microtubular arrangement around centrioles in rat incisor odontoblasts during cell differentiation

Three stages during cell differentiation of rat incisor odontoblasts were classified, and change of microtubular arrangement around centrioles in the odontoblasts was examined with three-dimensional analyses using serial ultrathin sections. In the undifferentiated odontoblasts, microtubules were observed to radiate from the pericentriolar area, whereas, in the differentiating odontoblasts, some microtubules became poorly related to the centrioles. In the differentiated odontoblasts, arrangement of most microtubules appeared to have a poor relationship to the centrioles. Throughout the differentiation of the odontoblasts, one of the centriolar pair was ciliated, and Golgi apparatus was invariably observed near the centrioles. The present study suggests that a pericentriolar area, or a centrosome, could function as a microtubule-organizing center (MTOC) in the undifferentiated odontoblasts, but their function might be attenuated during cell differentiation.     

The Ultrastructure of the Plumula of the Tooth of Lytechinus variegatus (Echinodermata: Echinoidea)

The plumula is enclosed by a single layer of epithelial cells. There are two types of odontoblasts: syncytial and free odontoblasts. Syncytial odontoblasts are arranged linearly on the abaxial side and have a highly active Golgi complex, rough endoplasmic reticulum, large and round mitochondria, and small coated vesicles indicative of a high level of secretory activity. Free odontoblasts cluster on the adaxial side and have patchy chromatin and little cytoplasm. The free odontoblasts migrate to the abaxial side, where their structure changes to that of syncytial odontoblasts. Calcareous deposits are formed intracellularly by syncytial odontoblasts within two membranes: an outer plasma membrane and an inner vacuolar membrane. The vacuolar membrane has organic particles on the surface of the membrane. There is no trace of organic matter within the calcareous deposit. Fibroblasts are located on the adaxial side. Collagen fibers are located primarily on the adaxial side adjacent to the calcareous depositing membranes and between free odontoblasts, but they are not located in the deposits. Collagen fibers may play a role in cell migration and thus in calcification. The morphological changes of the plumulae are closely related to calcification.