Dependence of kidney morphogenesis on the expression of nerve growth factor receptor.

Nerve growth factor receptor (NGFR) serves as the binding site for the neurotrophic growth factors. Although NGFR has been found in several embryonic tissues outside the nervous system, the function of NGFR in embryogenesis of non-neuronal organs remains unknown. NGFR is transiently synthesized by embryonic rat kidney and disappears from nephrons upon their terminal differentiation. Anti-sense oligonucleotide inhibition of NGFR expression inhibits kidney morphogenesis. Therefore, NGFR is required not only for development of the nervous system, but also for differentiation of the kidney tubules.

The enamel knot as a signaling center in the developing mouse tooth.

Mammalian tooth forms are produced during development by folding of the enamel epithelium but the molecular mechanisms involved in the formation and patterning of tooth cusps are not understood. We now report that several key signaling molecules found in well-known vertebrate signaling tissues such as the node, the notochord, the apical ectodermal ridge, and the zone of polarizing activity in the limb bud are specifically expressed in cells of the enamel knot, which is a transient cluster of dental epithelial cells. By comparing three-dimensional reconstructions of serial sections following in situ hybridization we localized Sonic hedgehog, Bone morphogenetic proteins-2, -4 and -7, as well as Fibroblast growth factor-4 in nested domains within the enamel knot. We suggest that the enamel knot acts as a signaling or organizing center, which provides positional information for tooth morphogenesis and regulates the growth of tooth cusps.

Regulation of organogenesis. Common molecular mechanisms regulating the development of teeth and other organs.

Vertebrate organs develop from epithelial and mesenchymal tissues, and during their early development they share common morphological features. These include condensation of the mesenchymal cells and thickening, folding or branching of epithelial sheets. Sequential and reciprocal interactions between the epithelial and mesenchymal tissues play central roles in regulation of the morphogenesis of all organs. During recent years increasing amounts of molecular data have accumulated from studies describing developmental changes in expression patterns of molecules, as well as from functional in vitro studies and from the generation of transgenic mice. In this review article, we discuss common features in the molecular regulation that appear to be shared by the developing tooth and other organs. Several growth factors have been shown to act as inductive signals mediating epithelial-mesenchymal interactions in different organs. The early signals are proposed to regulate the expression of master regulatory genes, such as transcription factors. In early tooth germ, bone morphogenetic proteins BMP-2 and BMP-4 regulate expression of the homeobox containing genes Msx-1 and Msx-2. These may specify early patterning of organs through regulation of molecules at the cell surface and the extracellular matrix, such as syndecan-1 and tenascin. Changes in cell adhesion and matrix remodelling, particularly in the organ-specific mesenchyme and in basement membrane contribute to formation of mesenchymal cell condensations and to epithelial morphogenesis. Several growth factors and their receptors, particularly in the TGF beta-, FGF- and EGF- families, have been implicated in formation of mesenchymal condensates and in epithelial morphogenesis of many organs, including the tooth. It is apparent that molecules which regulate morphogenesis in different organs are potential candidate genes for congenital malformation syndromes in which several organs are affected.

Expression of type I collagen pro-alpha 2 chain mRNA in adult human permanent teeth as revealed by in situ hybridization.

The expression of the gene COL1A2, coding for the pro-alpha 2 chain of type I pro-collagen, was analyzed in fully developed human permanent teeth. The teeth were fixed with formalin, demineralized with EDTA for about ten weeks, and embedded in paraffin. Pro-alpha 2(I) mRNA was localized in the sections by in situ hybridization, with use of [35S)]-labeled single-stranded RNA probes. The amount of mRNA for pro-alpha 2(I) collagen chain, as indicated by the relative densities of silver grains and the grain counts per cell in autoradiography, was high in odontoblasts, whereas in pulpal fibroblasts it was low. High levels of pro-alpha 2(I)mRNA expression were also present in those odontoblasts which had elaborated new dentin matrix in response to dental caries. Expression in the periodontal ligament, including the cementoblast layer, was slightly stronger than that in odontoblasts. The intense expression of pro-alpha 2(I) mRNA in odontoblasts of adult teeth suggests that even after the completion of primary dentin formation, they continue to synthesize heterotrimeric type I collagen molecules. Cell type-specific differences in the expression of pro-alpha 2(I) mRNA imply that type I collagen probably plays a major role in the regulation of the structure and function of dental tissues. Finally, in situ hybridization enabled pro-alpha 2(I) collagen mRNA to be detected in tissue sections even after prolonged demineralization, and thus it proved to be a valuable technique for analysis of gene expression in adult dental tissues, as shown here for COL1A2.

The role of growth factors in determination and differentiation of the odontoblastic cell lineage.

In developing teeth the differentiation of odontoblasts is triggered by the enamel epithelium and is tightly coupled with morphogenesis. There is substantial evidence that even in mature teeth the cells of the dental pulp retain the capability to differentiate into odontoblasts under suitable conditions. However, cells from other than the dental mesenchymal cell lineage apparently do not possess this potential. Thus, it is conceivable that the dental mesenchymal cells acquire cell type-specific potential to differentiate into odontoblasts during their developmental history. Therefore, the understanding of the mechanisms which regulate the terminal differentiation of odontoblasts requires that the molecular changes and mechanisms that are associated with their progressive determination be clarified. It can be speculated that there are key transition points in the developmental sequence during which the mesenchymal cells acquire new levels of differentiation. These include, (1) the condensation of the neural crest-derived mesenchymal cells around the epithelial bud, (2) their entrance into the dental papilla lineage during cap stage, and (3) the differentiation of the cells underlying the enamel epithelium into odontoblasts during bell stage. The transition points are conceivably characterized by amplification or onset of expression of new sets of genes encoding transcription factors, growth factors as well as structural proteins. We have applied in situ hybridization for localization of the expression of two growth factors during mouse molar morphogenesis: transforming growth factor beta 1 (TGF beta 1) and int-2 (a proto-oncogene coding for a fibroblast growth factor-related protein). During bud stage, expression of TGF beta 1 was first detected in the epithelium and shortly thereafter in the condensed dental mesenchyme. The expression was weak during early bell stage but a high number of transcripts appeared in secretory odontoblasts as well as in presecretory ameloblasts. int-2 mRNA appeared in the dental papilla mesenchyme at the onset of cap stage, persisted in the cuspal mesenchyme during bell stage and was lost upon completion of morphogenesis. Our findings suggest that cell type-specific expression of TGF beta 1 and int-2 is associated with phenotypic properties of the odontoblastic cell lineage. For instance, TGF beta 1 may regulate matrix deposition by increasing tenascin and syndecan expression in the condensed dental mesenchyme and by controlling dentin matrix deposition by odontoblasts. TGF beta 1 and int-2 may also be involved in signalling between the epithelial and mesenchymal tissues and in regulation of gene expression at the transition points of the developmental sequence that leads to the differentiation of odontoblasts.

Apoptosis in the developing tooth: association with an embryonic signaling center and suppression by EGF and FGF-4.

Apoptosis was localized in developing mouse teeth from initiation of morphogenesis to completion of cusp formation by using modified TUNEL method for serial sections and Nile Blue staining for whole mounts. Apoptosis was first detected at bud stage (E12-E13) in the central cells of the invaginating dental epithelium suggesting involvement of cell death in epithelial budding morphogenesis. During cusp development, apoptotic cells were located in the enamel knots, which are transient clusters of dental epithelial cells proposed to act as signaling centers directing the morphogenesis of tooth cusps. Apoptosis was also detected in other restricted epithelial cell populations including the dental lamina, ameloblasts, as well as stratum intermedium and stellate reticulum cells suggesting that the removal of these epithelial cells occurs by apoptosis. Apoptotic cells, presumably osteoclasts, were also located on the surfaces of the developing alveolar bone. When dissected E13 dental epithelium or mesenchyme were cultured in isolation, apoptotic cells were abundant throughout the tissues, whereas when cultured together, apoptosis was inhibited in both tissues close to their interface indicating that epithelial-mesenchymal tissue interactions prevent apoptosis. Epidermal growth factor (EGF) and fibroblast growth factor-4 (FGF-4) inhibited apoptosis in the dental mesenchyme when applied locally using agarose or heparin-coated acrylic beads, suggesting involvement of these or related growth factors in the prevention of apoptosis in dental tissues in vivo. The spatially and temporally restricted distribution patterns of apoptotic cells suggest multiple roles for programmed cell death in dental development. Of particular interest is the removal of the enamel knots by apoptosis which may terminate their tasks as regulators of the patterning of the tooth cusps. The apical ectodermal ridge (AER) of the limb bud has similar signaling characteristics as the enamel knot, and it also undergoes apoptosis. Hence, apoptosis may be a general mechanism for the silencing of embryonic signaling centers.

Associations between transforming growth factor beta 1 RNA expression and epithelial-mesenchymal interactions during tooth morphogenesis.

We have studied the expression of transforming growth factor beta-1 (TGF-beta 1) RNA during mouse tooth development, using in situ hybridization and experimental tissue recombinations. Analysis of the serial sections revealed the appearance of local expression of TGF-beta 1 RNA in the dental epithelium at bud-staged teeth (13-day embryos). Just before transition to the cap stage, TGF-beta 1 RNA expression rapidly increased in the epithelial bud, and it also extended to the condensed dental mesenchyme. At cap stage (14- and 15-day embryos), there was an intense expression of TGF-beta 1 RNA in the morphologically active cervical loops of the dental epithelium. During early bell stage (16- and 17-day embryos), TGF-beta 1 RNA expression was detected in the inner enamel epithelium where it subsequently almost disappeared (18-day embryos). After birth TGF-beta 1 transcripts transiently appeared in these cells when they were differentiating into ameloblasts (1-day mice). The transcripts were lost from the ameloblasts when they became secretory (4-day mice), but the expression continued in ameloblasts in enamel-free areas. Transient expression of TGF-beta 1 RNA was also detected in epithelial stratum intermedium cells at the time of ameloblast differentiation. In the mesenchyme, TGF-beta 1 RNA was not detected during bell stage until it appeared in differentiated odontoblasts (18-day embryos). The secretory odontoblasts continued to express TGF-beta 1 RNA at all stages studied including the odontoblasts of incisor roots. Analysis of the distribution of bromodeoxyuridine (BrdU) incorporation indicated apparent correlations between TGF-beta 1 RNA expression and cell proliferation at the bud and cap stages but not at later stages of tooth development. Tissue recombination experiments of bud-staged (13-day embryos) dental and non-dental tissues showed that tooth epithelium, when cultured together with tooth mesenchyme, expressed TGF-beta 1 RNA. When the tooth epithelium was combined with non-dental jaw mesenchyme, TGF-beta 1 transcripts were not expressed. However, TGF-beta 1 RNA expression was seen in oral epithelium cultured with dental mesenchyme, while no expression of TGF-beta 1 transcripts was seen in the oral epithelium during normal development. Thus, TGF-beta 1 RNA expression seems to be regulated by epithelial-mesenchymal interactions.

Advances in histological methods open up new perspectives for craniofacial growth research.

Changes in the tissue architecture and composition which accompany growth and development have traditionally been mapped using histological methods. The modern technology now offers new possibilities which can be used in connection with light microscopy and electron microscopy. These techniques, particularly immunohistochemistry and in situ hybridization allow studies on spatial and temporal changes in molecular patterns of substances during tissue organization and cell differentiation. In this paper, we describe the principles of immunohistology, autoradiography, and in situ hybridization, and review our recent studies in which we have applied such methods to assess craniofacial development. We have used autoradiography to localize cell proliferation and epidermal growth factor (EGF) receptors in the developing mandibular condyle. We have also used immunohistochemistry to localize the extracellular matrix component, tenascin, in differentiating chondrocytes of the mandibular condyle, employing specific antibodies. In studies on the odontogenic potential of dental papilla mesenchyme, we have used hybridoma technology, and produced monoclonal antibodies against dental papilla mesenchyme. Most recently, we have used in situ hybridization, which allows detection of gene expression in tissue sections to localize transcripts of a fibroblast-growth-factor related gene (Int-2 proto-oncogene) in developing teeth. In future, successful combination of such new histological methods and traditional experimental procedures can be expected to produce new answers to the questions about the regulation of craniofacial growth.

Molecular changes during determination and differentiation of the dental mesenchymal cell lineage.

The lineage of dental mesenchymal cells originates in the cranial neural crest, and after sequential determination and differentiation, gives rise to all structures of the tooth and its supporting tissues, except the enamel. Reciprocal interactions between the epithelial and mesenchymal tissues are conceivably the most important regulators of dental mesenchymal cell differentiation. The molecular mechanisms of this epigenetic regulation are not known at present. In order to examine the mechanisms of regulation of gene expression in the lineage of dental mesenchymal cells, information is needed on the molecular changes that accompany advancing differentiation. By using the molar tooth germ of mouse embryos as a model system, the changes in the expression of some molecules have been analysed by immunohistological localization and in situ hybridization, and the roles of tissue interactions in this process examined. This has shown that syndecan, a recently characterized cell surface proteoglycan, and tenascin, a matrix glycoprotein, appear in the condensing dental mesenchyme during the bud stage of tooth development. During the cap stage, dental mesenchyme is characterized by continued intense expression of syndecan, but this is lost during terminal differentiation of odontoblasts. Tenascin and syndecan may mediate cell-matrix interactions during condensation of dental mesenchymal cells. Expression of the Int-2 proto-oncogene, coding for a fibroblast growth factor-related molecule, can be detected by in situ hybridization in dental mesenchyme at the cap stage. This expression persists in cuspal mesenchyme at the bell stage but is lost from odontoblasts and from pulpal mesenchyme at progressive stages of tooth development. The advancement of tooth morphogenesis from cap to bell stage is accompanied by expression of alkaline phosphatase in the cuspal mesenchyme. Also tenascin, which is only weakly expressed during the cap stage, appears in the cuspal areas and shows codistribution with alkaline phosphatase. These observations indicate that the sequential determination and differentiation of the dental mesenchymal cells are characterized by a cascade of specific molecular changes. The cell surface proteoglycan syndecan and the Int-2 proto-oncogene are specific and transient markers of early dental mesenchymal cell differentiation. This information allows studies on the mechanisms of developmental regulation. These experimental tissue recombination studies indicate that the expression of syndecan and tenascin in the early dental mesenchyme is induced by the presumptive dental epithelium.(ABSTRACT TRUNCATED AT 400 WORDS)

Epithelial-mesenchymal signaling during tooth development.

Classic studies on experimental embryology have shown that organ development in an embryo is largely regulated by so called inductive tissue interactions which mostly take place between epithelial and mesenchymal tissues. Also in the developing tooth, both morphogenesis and cell differentiation are governed by such interactions. Characteristic features of epithelial-mesenchymal interactions are that they are sequential and reciprocal, i.e. "induction" appears to consist of a chain of signaling events between the tissues. During the last decade, the expression patterns of numerous molecules have been studied in developing organs by in situ hybridization and immunohistology. Many of them have been associated with epithelial-mesenchymal interactions, and it is apparent that same molecules participate in regulation of morphogenesis in a number of different organs. Transcription factors such as Msx-1, Msx-2 and Egr-1, growth factors, including TGF beta's, BMPs, and FGFs, and structural proteins such as syndecan and tenascin are expressed in transient, time and space-specific patterns in many organ rudiments, including the tooth. We have shown by tissue recombination studies that the expression of certain molecules is indeed regulated by epithelial-mesenchymal interactions in the early tooth germ. In particular, during the early stages of morphogenesis, when the dental epithelium induces the condensation of mesenchymal cells around the epithelial bud, the expression of many genes is upregulated in the condensed mesenchyme. Previous experimental tissue recombination studies have indicated that at the same time the capacity to instruct tooth morphogenesis shifts from the dental epithelium to the dental mesenchyme.(ABSTRACT TRUNCATED AT 250 WORDS)

Molecular mechanisms of cell and tissue interactions during early tooth development.

BACKGROUND: Morphogenesis and cell differentiation during the development of all organs, including the tooth, are regulated by interactions between cells and tissues. The developing tooth is one of the organs in which the molecular mechanisms of such interactions are starting to be elucidated. RESULTS: Homotypic cell interactions take place between cells of the same developmental history, and they are a central mechanism in the formation of mesenchymal cell condensates during the bud stage of tooth development. Syndecan-1, a cell surface heparan sulfate proteoglycan, is transiently expressed in the dental mesenchyme and may regulate dental mesenchymal cell condensation. It binds tenascin, a matrix glycoprotein abundant in dental mesenchyme, suggesting involvement of cell-matrix interactions. Syndecan also binds growth factors, and its association with cell proliferation in the dental mesenchyme suggests roles in the regulation of cell number in the condensing cells. Inductive interactions between the epithelial and mesenchymal tissues regulate tooth development at all stages. In the early dental mesenchyme, the expression of several molecules, including syndecan and tenascin, are regulated by the epithelium. There is evidence that growth factors act as diffusible signals mediating these interactions. BMP-2 and BMP-4 (bone morphogenetic proteins), which belong to the TGF beta superfamily, are expressed in the early dental epithelium, and their effects on the dental mesenchyme mimic those of the epithelium. In particular, BMPs induce the expression of the homeobox-containing transcription factors Msx-1 and Msx-2 in the dental mesenchyme. CONCLUSIONS: Based on current knowledge about the molecular changes accompanying tooth development and the results of experimental studies, we present a model for molecular regulation of early tooth development.

Transient expression of type III collagen by odontoblasts: developmental changes in the distribution of pro-alpha 1(III) and pro-alpha 1(I) collagen mRNAs in dental tissues.

The expression of pro-alpha 1(III) and pro-alpha 1(I) collagen mRNAs in mouse and human dental tissues during tooth development and after its completion was analyzed by in situ hybridization, with use of [35S]-labeled RNA probes. The expression of pro-alpha 1(III) mRNA was also compared to that of the protein product, as localized by immunostaining with polyclonal antibodies to type III collagen and the N-terminal propeptide of type III procollagen. Contrary to many previous reports, our results suggest that odontoblasts express type III collagen. While pro-alpha 1(III) transcripts were less intensely expressed in odontoblasts than pro-alpha 1(I) transcripts, the amounts of both mRNAs increased in odontoblasts with progressing dentin formation, and decreased toward its completion. In contrast to pro-alpha 1(III) mRNA, pro-alpha 1(I) mRNA was still detectable in odontoblasts of fully developed teeth. Type III collagen immunoreactivity was observed in the early predentin, and again in predentin toward the completion of dentinogenesis, when mRNA was no longer detected. Also in the pulp, the protein product, unlike pro-alpha 1(III) mRNA, was relatively strongly expressed. Hence, these immunostaining patterns were inversely related to the expression of pro-alpha 1(III) mRNA, suggesting accumulation of the protein. The mesenchymal cells, when condensed in the region of the future mandibular bone, expressed pro-alpha 1(III) mRNA intensely, whereas osteoblasts expressed pro-alpha 1(I) but not pro-alpha 1(III) transcripts strongly. Cell type- and developmental stage-related differences in the expression of the two mRNAs suggest that type I/type III collagen ratio influences the structure of dental tissues.

Expression of syndecan gene is induced early, is transient, and correlates with changes in mesenchymal cell proliferation during tooth organogenesis.

Syndecan is an integral cell surface proteoglycan which contains an extracellular matrix-binding domain and a cytoskeleton-associated domain and may therefore transfer changes in the extracellular environment to cellular behavior. Changes in syndecan gene expression during embryonic and early postnatal mouse tooth development were analyzed by in situ hybridization and compared with the distribution of syndecan core protein and cell proliferation studied by immunohistochemistry. Syndecan RNA became accumulated in the condensing mesenchymal cells around the invaginating epithelial tooth bud during early development, and this accumulation became more intense when morphogenesis advanced to the cap stage. During the bell stage, when the cuspal pattern of the tooth is established, syndecan transcripts were lost, and RNA was not detected in the terminally differentiated or postmitotic odontoblasts. In the epithelium, syndecan RNA was intensely expressed in the invaginating epithelial bud, but the expression was reduced during the cap and bell stages. However, local stimulation in syndecan gene expression was observed in the epithelial preameloblasts immediately preceding their terminal differentiation into ameloblasts, which was accompanied by a complete loss of transcripts. There was a close correlation between the changes in syndecan transcripts and the distribution of syndecan core protein. Furthermore, analysis of cell proliferation by immunohistochemical detection of BrdU incorporation revealed that in the mesenchyme, but not in the epithelium, syndecan was intensely expressed by proliferating cells. The analysis of mRNA by Northern blot indicated that the transcripts in mesenchymal and epithelial cells were of similar size. In the slot-blot analysis the changes in syndecan transcripts correlated with the overall changes observed in the in situ hybridization analysis. The role of tissue interactions in the regulation of the syndecan gene was studied by using tissue recombination cultures of separated epithelial and mesenchymal components of the early tooth germ. The in situ hybridization and Northern blot analysis of these explants showed that the expression was increased in the mesenchyme cultured in contact with the epithelium. Our results indicate that syndecan gene expression in the embryonic tooth mesenchyme is induced by epithelial-mesenchymal interactions and thereafter expressed stage-dependently and transiently by the differentiating cells during organogenesis. The association of syndecan expression with mesenchymal cell proliferation raises the possibility that, in addition to behaving as a matrix receptor, syndecan may have a role in controlling growth and that syndecan may have different functions in epithelial and mesenchymal cells.

Enhanced expression of the tie receptor tyrosine kinase in endothelial cells during neovascularization.

We have recently cloned a novel human receptor tyrosine kinase, tie, from human leukemia cells showing megakaryoblastoid differentiation. We report here that the 4.4-kb tie messenger RNA (mRNA) is present in all human fetal and mouse embryonic tissues. By in situ hybridization, the tie mRNA was localized to the endothelia of blood vessels and endocardium of 9.5- to 18.5-day mouse embryos. However, tie was not expressed by endothelial cells of developing hepatic sinusoids. Increased tie mRNA signal was seen in proliferating ovarial capillaries during hormone-induced superovulation. Only a weak tie signal was obtained from adult skin, except during wound healing, when the proliferating capillaries in the granulation tissue contained abundant tie RNA. These results suggest that tie may have a role in neovascularization.