Pablo Bringas

Conditional inactivation of Tgfbr2 in cranial neural crest causes cleft palate and calvaria defects.

Cleft palate and skull malformations represent some of the most frequent congenital birth defects in the human population. Previous studies have shown that TGFβ signaling regulates the fate of the medial edge epithelium during palatal fusion and postnatal cranial suture closure during skull development. It is not understood, however, what the functional significance of TGFβ signaling is in regulating the fate of cranial neural crest (CNC) cells during craniofacial development. We show that mice with Tgfbr2 conditional gene ablation in the CNC have complete cleft secondary palate, calvaria agenesis, and other skull defects with complete phenotype penetrance. Significantly, disruption of the TGFβ signaling does not adversely affect CNC migration. Cleft palate in Tgfbr2 mutant mice results from a cell proliferation defect within the CNC-derived palatal mesenchyme. The midline epithelium of the mutant palatal shelf remains functionally competent to mediate palatal fusion once the palatal shelves are placed in close contact in vitro. Our data suggests that TGFβ IIR plays a crucial, cell-autonomous role in regulating the fate of CNC cells during palatogenesis. During skull development, disruption of TGFβ signaling in the CNC severely impairs cell proliferation in the dura mater, consequently resulting in calvaria agenesis. We provide in vivo evidence that TGFβ signaling within the CNC-derived dura mater provides essential inductive instruction for both the CNC- and mesoderm-derived calvarial bone development. This study demonstrates that TGFβ IIR plays an essential role in the development of the CNC and provides a model for the study of abnormal CNC development.

Conserved function of mSpry-2, a murine homolog of Drosophila sprouty, which negatively modulates respiratory organogenesis

In Drosophila embryos, the loss of sprouty gene function enhances branching of the respiratory system. Three human sprouty homologues (h-Spry1-3) have been cloned recently, but their function is as yet unknown [1]. Here, we show that a murine sprouty gene (mSpry-2), the product of which shares 97% homology with the respective human protein, is expressed in the embryonic murine lung. We used an antisense oligonucleotide strategy to reduce expression of mSpry-2 by 96%, as measured by competitive reverse transcriptase PCR, in E11. 5 murine embryonic lungs cultured for 4 days [2]. Morphologically, the decrease in mSpry-2 expression resulted in a 72% increase in embryonic murine lung branching morphogenesis as well as a significant increase in expression of the lung epithelial marker genes SP-C, SP-B and SP-A. These results support a striking conservation of function between the Drosophila and mammalian sprouty gene families to negatively modulate respiratory organogenesis.

Role of Hertwig's Epithelial Root Sheath Cells in Tooth Root Development

During tooth development, after the completion of crown formation, the apical mesenchyme forms the developing periodontium while the inner and outer enamel epithelia fuse below the level of the crown cervical margin to produce a bilayered epithelial sheath termed Hertwigs epithelial root sheath (HERS). The role of HERS cells in root formation is widely accepted; however, the precise function of these cells remains controversial. Functions suggested have ranged from structural (subdivide the dental ectomesenchymal tissues into dental papilla and dental follicle), regulators of timing of root development, inducers of mesenchymal cell differentiation into odontoblasts and cementoblasts, to cementoblast cell precursors. The characterization of the HERS phenotype has been hindered by the small amount of tissue present at a given time during root formation. In this study, we report the establishment of an immortal HERS‐derived cell line that can be maintained in culture and then induced to differentiate in vitro. Characterization of the HERS phenotype using reverse transcriptase‐polymerase chain reaction and Western blot immunostaining suggests that HERS cells initially synthesize and secrete some enamel‐related proteins such as ameloblastin, and then these cells appear to change their morphology and produce a mineralized extracellular matrix resembling acellular cementum. These studies suggest that the acellular and cellular cementum are synthesized by two different types of cells, the first one by HERS‐derived cementoblasts and the later by neural crest‐derived cementoblasts. Developmental Dynamics 228:651–663, 2003.

Morphoregulation of teeth: modulating the number, size, shape and differentiation by tuning Bmp activity

Summary During development and evolution, the morphology of ectodermal organs can be modulated so that an organism can adapt to different environments. We have proposed that morphoregulation can be achieved by simply tilting the balance of molecular activity. We test the principles by analyzing the effects of partial downregulation of Bmp signaling in oral and dental epithelia of the keratin 14‐Noggin transgenic mouse. We observed a wide spectrum of tooth phenotypes. The dental formula changed from 1.0.0.3/1.0.0.3 to 1.0.0.2(1)/1.0.0.0. All mandibular and M3 maxillary molars were selectively lost because of the developmental block at the early bud stage. First and second maxillary molars were reduced in size, exhibited altered crown patterns, and failed to form multiple roots. In these mice, incisors were not transformed into molars. Histogenesis and differentiation of ameloblasts and odontoblasts in molars and incisors were abnormal. Lack of enamel caused misocclusion of incisors, leading to deformation and enlargement in size. Therefore, subtle differences in the level, distribution, and timing of signaling molecules can have major morphoregulatory consequences. Modulation of Bmp signaling exemplifies morphoregulation hypothesis: simple alteration of key signaling pathways can be used to transform a prototypical conical‐shaped tooth into one with complex morphology. The involvement of related pathways and the implication of morphoregulation in tooth evolution are discussed.

Epithelial-mesenchyme interactions during odontogenesis: IV. Morphological evidence for direct heterotypic cell-cell contacts

Abstract During embryonic and neonatal mouse incisor tooth morphogenesis, direct epithelial-mesenchymal cell contacts were observed by electron microscopy. These direct contacts were evident along the epithelial-mesenchymal interface in the differentiation zone in which inner enamel epithelium was as yet a dividing cell population which had not as yet synthesized and secreted the enamel organic matrix. This region of cell differentiation was also characterized by the appearance of cell processes which extended from the epithelia through the basal lamina. Following the appearance of epithelial cell processes penetrating through the basal lamina, ectomesenchymal cell processes extended across the extracellular matrix and penetrated through the basal lamina and resulted in the formation of contact zones. Following degradation of the basal lamina, the mesenchymal cell processes penetrated into clefts within the preameloblast cells and formed cell contacts. By a combination of tannic acid and uranium acetate staining we observed that the tannic acid stain penetrated through intercellular spaces formed between the apposing mesenchymal and epithelial plasma membrane surfaces. We speculate that direct heterotypic cell contacts, which occur prior to the cessation of preameloblast cell division and precede the secretion of enamel proteins, may be instructive in the induction of enamel protein biosynthesis.

Ectodermal Smad4 and p38 MAPK are functionally redundant in mediating TGF-β/BMP signaling during tooth and palate development

Smad4 is a central intracellular effector of TGF-beta signaling. Smad-independent TGF-beta pathways, such as those mediated by p38 MAPK, have been identified in cell culture systems, but their in vivo functional mechanisms remain unclear. In this study, we investigated the role of TGF-beta signaling in tooth and palate development and noted that conditional inactivation of Smad4 in oral epithelium results in much milder phenotypes than those seen with the corresponding receptor mutants, Bmpr1a and Tgfbr2, respectively. Perturbed p38 function in these tissues likewise has no effect by itself; however, when both Smad4 and p38 functions are compromised, dramatic recapitulation of the receptor mutant phenotypes results. Thus, our study demonstrates that p38 and Smad4 are functionally redundant in mediating TGF-beta signaling in diverse contexts during embryonic organogenesis. The ability of epithelium to utilize both pathways illustrates the complicated nature of TGF-beta signaling mechanisms in development and disease.

Human and mouse cementum proteins immunologically related to enamel proteins.

SDS-polyacrylamide gel electrophoresis, immunoblot and amino acid composition analyses were applied to human and mouse acellular cementum proteins immunologically related to enamelins and amelogenins. In this analysis, anti-mouse amelogenin, anti-human enamelin and synthetic peptide (e.g., -LPPHPGHPGYIC-) antibodies were shown to cross-react with tooth crown-derived enamelin with a molecular mass of 72,000 Da (72 kDa), amelogenins (26 kDa), and also to four human cementum proteins (72, 58, 50 and 26 kDa) and two mouse cementum proteins (72 and 26 kDa). Each of the antibodies recognized tooth root-derived cementum polypeptides which share one or more epitopes with tooth crown-derived enamel proteins. The molecular mass and isoelectric points for crown-derived and root-derived enamel-related proteins were similar. Analysis of human and mouse cementum proteins revealed a characteristic amino acid composition enriched in glutamyl, serine, glycine, alanine, proline, valine and leucine residues; compared to the major enamel protein amelogenin, cementum proteins were low in proline, histidine and methionine. The human and mouse putative intermediate cementum proteins appear to represent a distinct class of enamel-related proteins. Moreover, these results support the hypothesis that epithelial root sheath epithelia express several cementum proteins immunologically related to canonical enamel proteins.

Bioactive nanofibers instruct cells to proliferate and differentiate during enamel regeneration.

During tooth development, ectoderm‐derived ameloblast cells create enamel by synthesizing a complex protein mixture serving to control cell to matrix interactions and the habit of hydroxyapatite crystallites. Using an in vitro cell and organ culture system, we studied the effect of artificial bioactive nanostructures on ameloblasts with the long‐term goal of developing cell‐based strategies for tooth regeneration. We used branched peptide amphiphile molecules containing the peptide motif Arg‐Gly‐Asp, or “RGD” (abbreviated BRGD‐PA), known to self‐assemble in physiologic environments into nanofibers that display on their surfaces high densities of this biological signal. Ameloblast‐like cells (line LS8) and primary enamel organ epithelial (EOE) cells were cultured within PA hydrogels, and the PA was injected into the enamel organ epithelia of mouse embryonic incisors. The expression of amelogenin, ameloblastin, integrin α5, and integrin α6 was detected by quantitative real‐time PCR and immunodetection techniques. We performed cell proliferation assay using BrdU labeling and a biomineralization assay using Alizarin red S staining with quantitative Ca2+ measurements. In the cell culture model, ameloblast‐like cells (LS8) and primary EOE cells responded to the BRGD‐PA nanostructures with enhanced proliferation and greater amelogenin, ameloblastin, and integrin expression levels. At the site of injection of the BRGD‐PA in the organ culture model, we observed EOE cell proliferation with differentiation into ameloblasts as evidenced by their expression of enamel specific proteins. Ultrastructural analysis showed the nanofibers within the forming extracellular matrix, in contact with the EOE cells engaged in enamel formation and regeneration. This study shows that BRGD‐PA nanofibers present with enamel proteins participate in integrin‐mediated cell binding to the matrix with delivery of instructive signals for enamel formation.

Fate of HERS during tooth root development.

Tooth root development begins after the completion of crown formation in mammals. Previous studies have shown that Hertwigs epithelial root sheath (HERS) plays an important role in root development, but the fate of HERS has remained unknown. In order to investigate the morphological fate and analyze the dynamic movement of HERS cells in vivo, we generated K14-Cre;R26R mice. HERS cells are detectable on the surface of the root throughout root formation and do not disappear. Most of the HERS cells are attached to the surface of the cementum, and others separate to become the epithelial rest of Malassez. HERS cells secrete extracellular matrix components onto the surface of the dentin before dental follicle cells penetrate the HERS network to contact dentin. HERS cells also participate in the cementum development and may differentiate into cementocytes. During root development, the HERS is not interrupted, and instead the HERS cells continue to communicate with each other through the network structure. Furthermore, HERS cells interact with cranial neural crest derived mesenchyme to guide root development. Taken together, the network of HERS cells is crucial for tooth root development.

Smad4‐Shh‐Nfic signaling cascade–mediated epithelial‐mesenchymal interaction is crucial in regulating tooth root development

Transforming growth factor β (TGF‐β)/bone morphogenetic protein (BMP) signaling is crucial for regulating epithelial‐mesenchymal interaction during organogenesis, and the canonical Smad pathway–mediated TGF‐β/BMP signaling plays important roles during development and disease. During tooth development, dental epithelial cells, known as Hertwigs epithelial root sheath (HERS), participate in root formation following crown development. However, the functional significance of HERS in regulating root development remains unknown. In this study we investigated the signaling mechanism of Smad4, the common Smad for TGF‐β/BMP signaling, in HERS in regulating root development. Tissue‐specific inactivation of Smad4 in HERS results in abnormal enamel and dentin formation in K14‐Cre;Smad4fl/fl mice. HERS enlarges but cannot elongate to guide root development without Smad4. At the molecular level, Smad4‐mediated TGF‐β/BMP signaling is required for Shh expression in HERS and Nfic (nuclear factor Ic) expression in the cranial neural crest (CNC)‐derived dental mesenchyme. Nfic is crucial for root development, and loss of Nfic results in a CNC‐derived dentin defect similar to the one of K14‐Cre;Smad4fl/fl mice. Significantly, we show that ectopic Shh induces Nfic expression in dental mesenchyme and partially rescues root development in K14‐Cre;Smad4fl/fl mice. Taken together, our study has revealed an important signaling mechanism in which TGF‐β/BMP signaling relies on a Smad‐dependent mechanism in regulating Nfic expression via Shh signaling to control root development. The interaction between HERS and the CNC‐derived dental mesenchyme may guide the size, shape, and number of tooth roots.