Expression and localization of Nell-1 during murine molar development

Nel-like molecule-1 (Nell-1) is a recently discovered secreted protein that plays an important role in osteoblast differentiation, bone formation, and bone regeneration. However, its expression and distribution during tooth development are largely unknown. The aim of this study was to investigate the expression patterns of Nell-1 during murine molar development by immunohistochemistry. Nell-1 protein was expressed during molar development in embryonic and postnatal Kunming mice, but its expression levels and patterns at various developmental stages differed. At embryonic day 13.5 (E13.5) and E14.5, Nell-1 was found in both the entire enamel organ and the underlying mesenchyme. At E16.5, it was detected in the inner and outer enamel epithelia, stratum intermedium, secondary enamel knot, and dental papilla. At E18.5, Nell-1 was expressed in the differentiating ameloblasts, differentiating odontoblasts, and stratum intermedium. Positive staining was also found in the outer enamel epithelium. At postnatal day 2.5 (P2.5), P5, and P7, Nell-1 appeared in the secretory and mature ameloblasts and odontoblasts (odontoblastic bodies and processes) as well as immature enamel. Hertwig’s epithelial root sheath also stained positively at P7. At P13.5, positive staining was restricted to the reduced dental epithelium and odontoblasts, whereas Nell-1 disappeared in the mature enamel. During tooth eruption, Nell-1 was observed only in the odontoblastic bodies, odontoblastic processes, and endothelial cells of blood vessels. The spatiotemporal expression patterns of Nell-1 during murine tooth development suggest that it might play an important role in ameloblast and odontoblast differentiation, secretion and mineralization of the extracellular enamel matrix, molar crown morphogenesis, as well as root formation.     

Spatial and temporal expression of histone demethylase,Kdm2a,during murine molar development

The histone demethylase, lysine (K)-specific demethylase 2A (Kdm2a), is highly conserved and expressed ubiquitously. Kdm2a can regulate cell proliferation and osteo/dentinogenic, adipogenic and chondrogenic differentiation of mesenchymal stem cells (MSCs) derived from dental tissue. We used quantitative real-time RT-PCR analysis and immunohistochemistry to detect Kdm2a expression during development of the murine molar at embryonic days E12, E14, E16 and E17 and postnatal days P3 and P14. Immunohistochemistry results showed no positive staining of Kdm2a at E12. At E14, Kdm2a was expressed weakly in the inner enamel epithelium, stellate reticulum cells and dental sac. At E16, Kdm2a was expressed mainly in the inner and outer enamel epithelium, stratum intermedium and dental sac, but weaker staining was found in cervical loop and dental papilla cells adjacent to the basement membrane. At E17, the strongest Kdm2a staining was detected in the ameloblasts and stronger Kdm2a staining also was detected in the stratum intermedium, outer enamel epithelium and dental papilla cells compared to the expression at E16. Postnatally, we found that Kdm2a was localized in secretory and mature ameloblasts and odontoblasts, and dentin was unstained. Real-time RT-PCR showed that Kdm2a mRNA levels in murine germ cells increased from E12 to E14 and from E14 to E16; no significant change occurred at E16, E17 or P3, then the levels decreased at P14 compared to P3. Kdm2a expression may be closely related to cell proliferation, to ameloblast and odontoblast differentiation and to the secretion of extracellular enamel and dentin during murine tooth development.     

Expression of clock proteins in developing tooth

Morphological and functional changes during ameloblast and odontoblast differentiation suggest that enamel and dentin formation is under circadian control. Circadian rhythms are endogenous self-sustained oscillations with periods of 24h that control diverse physiological and metabolic processes. Mammalian clock genes play a key role in synchronizing circadian functions in many organs. However, close to nothing is known on clock genes expression during tooth development. In this work, we investigated the expression of four clock genes during tooth development. Our results showed that circadian clock genes Bmal1, clock, per1, and per2 mRNAs were detected in teeth by RT-PCR. Immunohistochemistry showed that clock protein expression was first detected in teeth at the bell stage (E17), being expressed in EOE and dental papilla cells. At post-natal day four (PN4), all four clock proteins continued to be expressed in teeth but with different intensities, being strongly expressed within the nucleus of ameloblasts and odontoblasts and down-regulated in dental pulp cells. Interestingly, at PN21 incisor, expression of clock proteins was down-regulated in odontoblasts of the crown-analogue side but expression was persisting in root-analogue side odontoblasts. In contrast, both crown and root odontoblasts were strongly stained for all four clock proteins in first molars at PN21. Within the periodontal ligament (PDL) space, epithelial rests of Malassez (ERM) showed the strongest expression among other PDL cells. Our data suggests that clock genes might be involved in the regulation of ameloblast and odontoblast functions, such as enamel and dentin protein secretion and matrix mineralization.     

Immunohistochemical localization of Pax6 in the developing tooth germ of mice

Recent studies have reported that supernumerary teeth were observed in the maxillary incisor area in several Pax6 homozygous mutant mouse and rat strains. To date, it remains unknown whether Pax6 is expressed during tooth development in any species. The study aimed to analyze the expression of Pax6 during mouse incisor and molar development. C57BL/6J mouse embryos on days E12.5, E13.5, E14.5, E16.5 and E18.5 were produced. Heads from these embryos, as well as from P1.5 mice, were processed for paraffin wax embedding (N ≥ 3 for each stage) and prepared for immunohistochemistry. Pax6 immunostaining was found in all tooth germs examined. At the E12.5 dental placode, E13.5 bud stage, E14.5 cap stage and E16.5 early bell stage, Pax6 was expressed in ectodermally derived tissues of tooth germs and oral epithelia adjacent to the tooth germs. Cells in the underlying dental ectomesenchyme that showed Pax9 expression were Pax6 negative. At E18.5 and P1.5, Pax6 was expressed in more differentiated ameloblasts and cells of the stratum intermedium and stellate reticulum that were derived from the oral epithelium, as well as in mesenchyme-derived differentiated odontoblasts. Pax6 expression was also observed in the submandibular gland, tongue filiform papilla and hair follicle at E16.5 and P1.5. The present study demonstrated that Pax6 was expressed in incisor and molar germs during mouse tooth development. The results provide a basis for exploring the function of Pax6 during tooth development.     

In situ expression of 15 kDa interferon alpha responsive gene in the developing tooth germ of the mouse lower first molar

We previously performed cDNA subtraction between the mouse mandibles at embryonic day 10.5 (E10.5) and E12.0 to make a profile of the regulator genes for odontogenesis. Fifteen kDa interferon alpha responsive gene (Ifrg15) is one of several highly-expressed genes in the E12.0 mandible. The current study examined the precise expression patterns of Ifrg15 mRNA in the mouse mandibular first molar by in situ hybridization to evaluate the possible functional roles of this gene in odontogenesis. Ifrg15 mRNA was expressed in the epithelial and mesenchymal tissues of the mandible at E10.5 and E12.0. The Ifrg15 in situ signal was detected in the epithelial bud and the surrounding mesenchyme at E14.0, and was present in the enamel organ including the primary enamel knot, and in the underlying mesenchyme at E15.0. The in situ signal was restricted in the inner and outer enamel epithelia and the stratum intermedium at E16.0. The signal of Ifrg15 mRNA was further restricted to the inner enamel epithelium and the adjacent stratum intermedium at E17.0 and E18.0. Consequently, the expression of Ifrg15 mRNA was localized in the ameloblasts and odontoblasts at postnatal days 1.0 to 3.0. However, the in situ signal was markedly weaker than at the embryonic period. The expression of Ifrg15 mRNA was coincidently observed in various craniofacial organs as well as in the tooth germ. These results suggest that Ifrg15 is closely related to odontogenesis, especially the differentiation of the ameloblasts and odontoblasts, and to the morphogenesis of the craniofacial organs.     

In situ expression of heat shock proteins,Hsc73, Hsj2 and Hsp86 in the developing tooth germ of mouse lower first molar

This study examined the detailed gene expression pattern of three different heat shock proteins (HSPs), Hsc73, Hsj2, and Hsp86, by means of an in situ hybridization method. Hsc73, Hsj2, and Hsp86 were shown in our previous study to be differentially expressed in the mouse embryonic mandible at day 10.5 (E10.5) gestational age. These HSP genes showed similar expression patterns during development of the mouse lower first molar. HSPs-expressing cells were widely distributed in both the epithelial and underlying ectomesenchymal cells at E10.5, and then were slightly localized at E12 in an area where the tooth germ of the lower first molar is estimated to be formed. A strong expression of HSPs was observed in the tooth germ at E13.5. At the cap stage, HSPs were expressed in the enamel organ and dental papilla. At the bell stage, HSPs were distinctly expressed in the inner enamel epithelium and dental papilla cells facing the inner enamel epithelial layer, which later differentiate into ameloblasts and odontoblasts, respectively. This study is the first report in which Hsc73, Hsj2, and Hsp86 were distinctly expressed in the developing tooth germ, thus suggesting these HSPs are related to the development and differentiation of odontogenic cells.     

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.     

Gene expression of β–catenin is up-regulated in inner dental epithelium and enamel knots during molar tooth morphogenesis in the mouse

Beta–catenin is a multi–functional molecule that is involved in both cell–cell adhesion and signaling. We analyzed changes in β–catenin gene expression during mouse molar tooth development by in situ hybridization. Prominent up–regulation of the expression of this gene was evident exclusively in the enamel knot at the early cap stage. During the cap and bell stages, the enamel knot, inner dental epithelium, and differentiating stratum intermedium expressed the β–catenin gene more strongly than other parts of the enamel organ. During these stages, the strength of the gene expression changed heterogeneously within the inner dental epithelium and stratum intermedium. However, the heterogeneity was not evident at the late bell stage, when the cells in the inner dental epithelium had differentiated into ameloblasts at the cusp tip. No spatiotemporal change in β–catenin gene expression was apparent in the dental papilla except for the cells that differentiated into odontoblasts, which became negative for the expression of the gene after their differentiation. Thus, the up-regulated expression of the β–catenin gene was strongly associated with epithelial morphogenesis. These findings raise the possibility that the up–regulation of the gene expression and the stabilization of the protein by Wnt signaling play a role in the regulation of the activities of β–catenin in tooth morphogenesis.     

Wnt10a regulates dentin sialophosphoprotein mRNA expression and possibly links odontoblast differentiation and tooth morphogenesis

We have explored the role of Wnt signaling in dentinogenesis of mouse molar teeth. We found that Wnt10a was specifically associated with the differentiation of odontoblasts and that it showed striking colocalization with dentin sialophosphoprotein (Dspp) expression in secretory odontoblasts. Dspp is a tooth specific non-collagenous matrix protein and regulates dentin mineralization. Transient overexpression of Wnt10 in C3H10T1/2, a pluripotent fibroblast cell line induced Dspp mRNA. Interestingly, this induction occurred only when transfected cells were cultured on Matrigel basement membrane extracts. These findings indicated that Wnt10a is an upstream regulatory molecule for Dspp expression, and that cell-matrix interaction is essential for induction of Dspp expression. Furthermore, Wnt10a was specifically expressed in the epithelial signaling centers regulating tooth development, the primary and secondary enamel knots. The spatial and temporal distribution of Wnt10a mRNA demonstrated that the expression shifts from the secondary enamel knots, to the underlying preodontoblasts in the tips of future cusps. The expression patterns and overexpression studies together indicate that Wnt10a is a key molecule for dentinogenesis and that it is associated with the cell-matrix interactions regulating odontoblast differentiation. We conclude that Wnt10a may link the differentiation of odontoblasts and cusp morphogenesis.     

Expression of Set-α during Morphogenesis of Mouse Lower First Molar

The detailed in situ expression pattern of the Set-α gene has been studied. Previously we showed that Set-α is a differentially expressed gene in the embryonic mouse mandible at day 10.5 (E10.5) gestational age. Cells expressing Set-α were widely distributed in both the epithelial and underlying ectomesenchymal cells at E10.5. At E12, they were slightly aggregated in an area where tooth germ of the lower first molar is estimated to be formed. At E13.5, Set-α was strongly expressed in the tooth germ. At the cap stage, Set-α was expressed in the enamel organ and dental papilla. At the bell stage, Set-α was distinctly expressed in the inner enamel epithelial and dental papilla cells facing the inner enamel epithelial layer, which were intended to differentiate into ameloblasts and odontoblasts, respectively. Interestingly, Set-α was also expressed in several embryonic craniofacial tissues derived from the ectoderm. This study is the first report that Set-α is distinctly expressed in the developing tooth germ, and suggests that Set-α plays an important role in both the initiation and the growth of the tooth germ, as well as in the differentiation of ameloblasts and odontoblasts.     

An endoplasmic reticulum stress regulator,Tmbim6, modulates secretory stage of mice molar

To understand the role of endoplasmic reticulum (ER)-stress in mice molar development, we studied Tmbim6 that antagonizes the unfolded protein response, using Tmbim6 knockout (KO) mice and in vitro organ cultivation with knocking down using small interfering RNA. During molar development, Tmbim6 is expressed in developing tooth at E14–E16, postnatal0 (PN0), and PN6. Mineral content in Tmbim6 KO enamel was reduced while dentin was slightly increased revealing ultrastructural changes in pattern formation of both enamel and dentin. Moreover, odontoblast differentiation was altered with increased Dspp expression at PN0 followed by altered AMELX localizations at PN5. These results were confirmed by in vitro organ cultivation and showed altered Bmp signaling, proliferation, and actin rearrangement in the presumptive ameloblast and odontoblasts that followed the altered expression of differentiation and ER stress-related signaling molecules at E16.5. Overall, ER stress modulated by Tmbim6 would play important roles in patterned dental hard tissue formation in mice molar within a limited period of development.     

Light and electron microscopical immunohistochemical localization of large proteoglycans in human tooth germs at the bell stage

Summary The immunohistochemical localization of large hyaluronate-binding proteoglycans has been studied in human tooth germs at the bell stage using a monoclonal antibody, 5D5, which is derived from bovine sclera and specifically recognizes the core protein of large proteoglycans, such as versican, neurocan and brevican, but not that of aggrecan. In the early bell stage before predentine secretion, when the enamel organs consisted of the inner and outer enamel epithelia, stratum intermedium and stellate reticulum, the enamel organs were not stained by 5D5, but the dental papillae and follicles stained strongly. Concomitant with the secretion of predentine, dentine and subsequent enamel matrix, strong 5D5 immunostaining distributed over the entire cell surfaces of secretory ameloblasts was observed. The forming enamel matrix showed strong staining. While most of the inner and outer enamel epithelia and stratum intermedium lacked staining, the cervical loop region and stellate reticulum showed weak staining. Although the forming dentine and odontoblasts appeared to lack 5D5 affinity, the predentine, dental papilla and dental follicle demonstrated moderate to strong reactivity. At the ultrastructural level, specific immunoreaction by immunogold particle deposition was clearly detected over the basal lamina of presecretory ameloblasts, secretion granules of secretory ameloblasts and the forming enamel matrix. These results indicate that a marked increase in the large proteoglycan associated with secretory ameloblasts may correlate with cell differentiation and enamel matrix biosynthesis. This revised version was published online in November 2006 with corrections to the Cover Date.     

Epithelial-Directed Mesenchyme Differentiation in vitro

To assess the requirement for specific or possibly non-specific epithelial instructions for mesenchymal cell differentiation, we designed studies to evaluate and compare homotypic with heterotypic tissue recombinations across vertebrate species. These studies further tested the hypothesis that determined dental papilla mesenchyme requires epithelial-derived instructions to differentiate into functional odontoblast cells using a serumless, chemically-defined medium. Theiler stage 25 C57BL/6 or Swiss Webster cap stage mandibular first molar tooth organs or trypsin-dissociated, homotypic epithelial-mesenchymal tissue recombinants resulted in the differentiation of odontoblasts within 3 days. Epithelial differentiation into functional ameloblasts was observed within 7 days. Trypsin-dissociated and isolated mesenchyme did not differentiate into odontoblasts under these experimental conditions. Heterotypic recombinants between quail Hamburger-Hamilton stages 22–26 mandibular epithelium and Theiler stage 25 dental papilla mesenchyme routinely resulted in odontoblast differentiation within 3 days in vitro. Odontoblast differentiation and the production of dentine extracellular matrix continued throughout the 10 days in organ culture. Ultrastructural observations of the interface between quail and mouse tissues indicated the reconstitution of the basal lamina as well as the maintenance of an intact basal lamina during 10 days in vitro. Quail epithelial cells did not differentiate into ameloblasts and no enamel extracellular matrix was observed. These results show that quail mandibular epithelium can provide the required developmental instructions for odontoblast differentiation in the absence of serum or other exogenous humoral factors in a chemically-defined medium. They also suggest the importance of reciprocal epithelial-mesenchymal interactions during epidermal organogenesis.     

Cell surface proteoglycan expression correlates with epithelial-mesenchymal interaction during tooth morphogenesis

Tooth morphogenesis and differentiation of the dental cells are guided by interactions between epithelial and mesenchymal tissues. Because the extracellular matrix is involved in these interactions, the expression of matrix receptors located at the cell surface may change during this developmental sequence. We have examined the distribution of an epithelial cell surface proteoglycan antigen, known to behave as a receptor for interstitial matrix, during tooth morphogenesis. Intense staining was seen around the cells of the embryonic oral epithelium as well as the dental epithelium at the early bud stage. With development, expression was greatly reduced in the enamel organ. Differentiation of these cells into ameloblasts was associated with the loss of expression, while the epithelial cells remaining in the stratum intermedium and stellate reticulum regained intense staining. The PG antigen was weakly expressed in the loose neural crest-derived jaw mesenchyme but it became strongly reactive in the condensed dental papilla mesenchyme when extensive morphogenetic movements took place. With development, the PG antigen disappeared from the advanced dental papilla mesenchyme but persisted in the dental sac mesenchyme, which gives rise to periodontal tissues. The PG antigen was not expressed by odontoblasts. Hence, the expression of the PG antigen changes during the epithelial-mesenchymal interactions of tooth development and is lost during terminal cell differentiation. The expression follows morphogenetic rather than histologic boundaries. The acquisition and loss of expression in epithelial and mesenchymal tissues during tooth development suggest that this proteoglycan has specific functions in the epithelial-mesenchymal interactions that guide morphogenesis.     

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.     

Immunolocalization of connexin 43 in the tooth germ of the neonatal rat

Summary Rabbit polyclonal antibodies to amino acids 346–360 of connexin 43, the ‘heart’ gap junction protein, were employed to immunolocalize connexin 43 gap junctions in the neonatal rat molar tooth germ. Connexin 43 appears early in the differentiation of both ectodermally derived and ectomesenchymally derived cells of the developing tooth. Connexin 43 immunoreactivity is present in the epithelial components of the enamel organ, including the area of the proximal and distal junctional complexes of the ameloblast layer, and the stratum intermedium, stellate reticulum and outer enamel epithelium. Secretory odontoblasts and developing alveolar bone also display a pattern of connexin 43 immunostaining. Both the epithelial and ectomesenchymally-derived components of the developing tooth acquire connexin 43 channels in a manner that correlates with cell differentiation. In addition, three regions can be defined by connexin 43 immunostaining: the epithelia of the enamel organ that are derived from the oral epithelium, the odontoblast layer derived from the ectomesenchyme, and the alveolar bone. The results suggest that connexin 43 may provide the mechanism for functional compartmentalization of the tissues associated with tooth formation. Compartmentalization suggested by connexin 43 expression could play important roles in the development and functions of these tissues.