Your search keyword '"Enamel knot"' showing total 249 results

1. Local and Systemic Regulation of Mineralization: Role of Coupling Factors, Pyrophosphate, Polyphosphates, Vitamin D, Fetuin, Matrix Gla Protein, and Osteopontin

Author

Shapiro, Irving M., Landis, William J., Shapiro, Irving M., and Landis, William J.

Published

2023

2. Corrigendum: Single cell RNA sequencing reveals human tooth type identity and guides in vitro hiPSC derived odontoblast differentiation (iOB)

Author

Sesha Hanson-Drury, Anjali P. Patni, Deborah L. Lee, Ammar Alghadeer, Yan Ting Zhao, Devon Duron Ehnes, Vivian N. Vo, Sydney Y. Kim, Druthi Jithendra, Ashish Phal, Natasha I. Edman, Thomas Schlichthaerle, David Baker, Jessica E. Young, Julie Mathieu, and Hannele Ruohola-Baker

Subjects

odontoblast, single cell RNA sequencing, enamel knot, cell signaling, de novo designed mini protein binders, human tooth, Dentistry, RK1-715

Published

2023

3. FGF4 and FGF9 have synergistic effects on odontoblast differentiation.

Author

Hoshino, Tatsuki, Onodera, Shoko, Kimura, Motoyoshi, Suematsu, Makoto, Ichinohe, Tatsuya, and Azuma, Toshifumi

Subjects

*RUNX proteins, *FIBROBLAST growth factors, *EXTRACELLULAR matrix proteins, *FERULIC acid, *TRANSGENIC mice, *DENTAL adhesives

Abstract

The purpose of this study was to investigate whether fibroblast growth factor 4 (FGF4) and FGF9 are active in dentin differentiation. Dentin matrix protein 1 (Dmp1) -2A-Cre transgenic mice, which express the Cre-recombinase in Dmp1-expressing cells, were crossed with CAG-tdTomato mice as reporter mouse. The cell proliferation and tdTomato expressions were observed. The mesenchymal cell separated from neonatal molar tooth germ were cultured with or without FGF4, FGF9, and with or without their inhibitors ferulic acid and infigratinib (BGJ398) for 21 days. Their phenotypes were evaluated by cell count, flow cytometry, and real-time PCR. Immunohistochemistry for FGFR1, 2, and 3 expression and the expression of DMP1 were performed. FGF4 treatment of mesenchymal cells obtained promoted the expression of all odontoblast markers. FGF9 failed to enhance dentin sialophosphoprotein (Dspp) expression levels. Runt-related transcription factor 2 (Runx2) was upregulated until day 14 but was downregulated on day 21. Compared to Dmp1-negative cells, Dmp1-positive cells expressed higher levels of all odontoblast markers, except for Runx2. Simultaneous treatment with FGF4 and FGF9 had a synergistic effect on odontoblast differentiation, suggesting that they may play a role in odontoblast maturation. [ABSTRACT FROM AUTHOR]

Published

2023

4. Single cell RNA sequencing reveals human tooth type identity and guides in vitro hiPSC derived odontoblast differentiation (iOB)

Author

Sesha Hanson-Drury, Anjali P. Patni, Deborah L. Lee, Ammar Alghadeer, Yan Ting Zhao, Devon Duron Ehnes, Vivian N. Vo, Sydney Y. Kim, Druthi Jithendra, Ashish Phal, Natasha I. Edman, Thomas Schlichthaerle, David Baker, Jessica E. Young, Julie Mathieu, and Hannele Ruohola-Baker

Subjects

odontoblast, single cell RNA sequencing, enamel knot, cell signaling, de novo designed mini protein binders, human tooth, Dentistry, RK1-715

Abstract

Over 90% of the U.S. adult population suffers from tooth structure loss due to caries. Most of the mineralized tooth structure is composed of dentin, a material produced and mineralized by ectomesenchyme derived cells known as odontoblasts. Clinicians, scientists, and the general public share the desire to regenerate this missing tooth structure. To bioengineer missing dentin, increased understanding of human tooth development is required. Here we interrogate at the single cell level the signaling interactions that guide human odontoblast and ameloblast development and which determine incisor or molar tooth germ type identity. During human odontoblast development, computational analysis predicts that early FGF and BMP activation followed by later HH signaling is crucial. Here we generate a differentiation protocol based on this sci-RNA-seq analysis to produce mature hiPSC derived odontoblasts in vitro (iOB). Further, we elucidate the critical role of FGF signaling in odontoblast maturation and its biomineralization capacity using the de novo designed FGFR1/2c isoform specific minibinder scaffolded as a C6 oligomer that acts as a pathway agonist. Using computational tools, we show on a molecular level how human molar development is delayed compared to incisors. We reveal that enamel knot development is guided by FGF and WNT in incisors and BMP and ROBO in the molars, and that incisor and molar ameloblast development is guided by FGF, EGF and BMP signaling, with tooth type specific intensity of signaling interactions. Dental ectomesenchyme derived cells are the primary source of signaling ligands responsible for both enamel knot and ameloblast development.

Published

2023

5. Clinical, genetic, epidemiologic, evolutionary, and functional delineation of TSPEAR-related autosomal recessive ectodermal dysplasia 14

Author

Adam Jackson, Sheng-Jia Lin, Elizabeth A. Jones, Kate E. Chandler, David Orr, Celia Moss, Zahra Haider, Gavin Ryan, Simon Holden, Mike Harrison, Nigel Burrows, Wendy D. Jones, Mary Loveless, Cassidy Petree, Helen Stewart, Karen Low, Deirdre Donnelly, Simon Lovell, Konstantina Drosou, Gaurav K. Varshney, Siddharth Banka, J.C. Ambrose, P. Arumugam, R. Bevers, M. Bleda, F. Boardman-Pretty, C.R. Boustred, H. Brittain, M.A. Brown, M.J. Caulfield, G.C. Chan, A. Giess, J.N. Griffin, A. Hamblin, S. Henderson, T.J.P. Hubbard, R. Jackson, L.J. Jones, D. Kasperaviciute, M. Kayikci, A. Kousathanas, L. Lahnstein, A. Lakey, S.E.A. Leigh, I.U.S. Leong, F.J. Lopez, F. Maleady-Crowe, M. McEntagart, F. Minneci, J. Mitchell, L. Moutsianas, M. Mueller, N. Murugaesu, A.C. Need, P. O‘Donovan, C.A. Odhams, C. Patch, D. Perez-Gil, M.B. Pereira, J. Pullinger, T. Rahim, A. Rendon, T. Rogers, K. Savage, K. Sawant, R.H. Scott, A. Siddiq, A. Sieghart, S.C. Smith, A. Sosinsky, A. Stuckey, M. Tanguy, A.L. Taylor Tavares, E.R.A. Thomas, S.R. Thompson, A. Tucci, M.J. Welland, E. Williams, K. Witkowska, S.M. Wood, M. Zarowiecki, Olaf Riess, Tobias B. Haack, Holm Graessner, Birte Zurek, Kornelia Ellwanger, Stephan Ossowski, German Demidov, Marc Sturm, Julia M. Schulze-Hentrich, Rebecca Schüle, Christoph Kessler, Melanie Wayand, Matthis Synofzik, Carlo Wilke, Andreas Traschütz, Ludger Schöls, Holger Hengel, Peter Heutink, Han Brunner, Hans Scheffer, Nicoline Hoogerbrugge, Alexander Hoischen, Peter A.C. ’t Hoen, Lisenka E.L.M. Vissers, Christian Gilissen, Wouter Steyaert, Karolis Sablauskas, Richarda M. de Voer, Erik-Jan Kamsteeg, Bart van de Warrenburg, Nienke van Os, Iris te Paske, Erik Janssen, Elke de Boer, Marloes Steehouwer, Burcu Yaldiz, Tjitske Kleefstra, Anthony J. Brookes, Colin Veal, Spencer Gibson, Marc Wadsley, Mehdi Mehtarizadeh, Umar Riaz, Greg Warren, Farid Yavari Dizjikan, Thomas Shorter, Ana Töpf, Volker Straub, Chiara Marini Bettolo, Sabine Specht, Jill Clayton-Smith, Elizabeth Alexander, Laurence Faivre, Christel Thauvin, Antonio Vitobello, Anne-Sophie Denommé-Pichon, Yannis Duffourd, Emilie Tisserant, Ange-Line Bruel, Christine Peyron, Aurore Pélissier, Sergi Beltran, Ivo Glynne Gut, Steven Laurie, Davide Piscia, Leslie Matalonga, Anastasios Papakonstantinou, Gemma Bullich, Alberto Corvo, Carles Garcia, Marcos Fernandez-Callejo, Carles Hernández, Daniel Picó, Ida Paramonov, Hanns Lochmüller, Gulcin Gumus, Virginie Bros-Facer, Ana Rath, Marc Hanauer, Annie Olry, David Lagorce, Svitlana Havrylenko, Katia Izem, Fanny Rigour, Giovanni Stevanin, Alexandra Durr, Claire-Sophie Davoine, Léna Guillot-Noel, Anna Heinzmann, Giulia Coarelli, Gisèle Bonne, Teresinha Evangelista, Valérie Allamand, Isabelle Nelson, Rabah Ben Yaou, Corinne Metay, Bruno Eymard, Enzo Cohen, Antonio Atalaia, Tanya Stojkovic, Milan Macek, Jr., Marek Turnovec, Dana Thomasová, Radka Pourová Kremliková, Vera Franková, Markéta Havlovicová, Vlastimil Kremlik, Helen Parkinson, Thomas Keane, Dylan Spalding, Alexander Senf, Peter Robinson, Daniel Danis, Glenn Robert, Alessia Costa, Christine Patch, Mike Hanna, Henry Houlden, Mary Reilly, Jana Vandrovcova, Francesco Muntoni, Irina Zaharieva, Anna Sarkozy, Vincent Timmerman, Jonathan Baets, Liedewei Van de Vondel, Danique Beijer, Peter de Jonghe, Vincenzo Nigro, Sandro Banfi, Annalaura Torella, Francesco Musacchia, Giulio Piluso, Alessandra Ferlini, Rita Selvatici, Rachele Rossi, Marcella Neri, Stefan Aretz, Isabel Spier, Anna Katharina Sommer, Sophia Peters, Carla Oliveira, Jose Garcia Pelaez, Ana Rita Matos, Celina São José, Marta Ferreira, Irene Gullo, Susana Fernandes, Luzia Garrido, Pedro Ferreira, Fátima Carneiro, Morris A. Swertz, Lennart Johansson, Joeri K. van der Velde, Gerben van der Vries, Pieter B. Neerincx, Dieuwke Roelofs-Prins, Sebastian Köhler, Alison Metcalfe, Alain Verloes, Séverine Drunat, Caroline Rooryck, Aurelien Trimouille, Raffaele Castello, Manuela Morleo, Michele Pinelli, Alessandra Varavallo, Manuel Posada De la Paz, Eva Bermejo Sánchez, Estrella López Martín, Beatriz Martínez Delgado, F. Javier Alonso García de la Rosa, Andrea Ciolfi, Bruno Dallapiccola, Simone Pizzi, Francesca Clementina Radio, Marco Tartaglia, Alessandra Renieri, Elisa Benetti, Peter Balicza, Maria Judit Molnar, Ales Maver, Borut Peterlin, Alexander Münchau, Katja Lohmann, Rebecca Herzog, Martje Pauly, Alfons Macaya, Anna Marcé-Grau, Andres Nascimiento Osorio, Daniel Natera de Benito, Rachel Thompson, Kiran Polavarapu, David Beeson, Judith Cossins, Pedro M. Rodriguez Cruz, Peter Hackman, Mridul Johari, Marco Savarese, Bjarne Udd, Rita Horvath, Gabriel Capella, Laura Valle, Elke Holinski-Feder, Andreas Laner, Verena Steinke-Lange, Evelin Schröck, and Andreas Rump

Subjects

TSPEAR, Ectodermal dysplasia, Enamel knot, WNT10A, Hypodontia, Conical teeth, Genetics, QH426-470

Abstract

Summary: TSPEAR variants cause autosomal recessive ectodermal dysplasia (ARED) 14. The function of TSPEAR is unknown. The clinical features, the mutation spectrum, and the underlying mechanisms of ARED14 are poorly understood. Combining data from new and previously published individuals established that ARED14 is primarily characterized by dental anomalies such as conical tooth cusps and hypodontia, like those seen in individuals with WNT10A-related odontoonychodermal dysplasia. AlphaFold-predicted structure-based analysis showed that most of the pathogenic TSPEAR missense variants likely destabilize the β-propeller of the protein. Analysis of 100000 Genomes Project (100KGP) data revealed multiple founder TSPEAR variants across different populations. Mutational and recombination clock analyses demonstrated that non-Finnish European founder variants likely originated around the end of the last ice age, a period of major climatic transition. Analysis of gnomAD data showed that the non-Finnish European population TSPEAR gene-carrier rate is ∼1/140, making it one of the commonest AREDs. Phylogenetic and AlphaFold structural analyses showed that TSPEAR is an ortholog of drosophila Closca, an extracellular matrix-dependent signaling regulator. We, therefore, hypothesized that TSPEAR could have a role in enamel knot, a structure that coordinates patterning of developing tooth cusps. Analysis of mouse single-cell RNA sequencing (scRNA-seq) data revealed highly restricted expression of Tspear in clusters representing enamel knots. A tspeara−/−;tspearb−/− double-knockout zebrafish model recapitulated the clinical features of ARED14 and fin regeneration abnormalities of wnt10a knockout fish, thus suggesting interaction between tspear and wnt10a. In summary, we provide insights into the role of TSPEAR in ectodermal development and the evolutionary history, epidemiology, mechanisms, and consequences of its loss of function variants.

Published

2023

6. A Mutation in CACNA1S Is Associated with Multiple Supernumerary Cusps and Root Maldevelopment.

Author

Kantaputra, Piranit, Leelaadisorn, Niramol, Hatsadaloi, Athiwat, Quarto, Natalina, Intachai, Worrachet, Tongsima, Sissades, Kawasaki, Katsushige, Ohazama, Atsushi, Ngamphiw, Chumpol, and Wiriyakijja, Paswach

Subjects

*SUPERNUMERARY teeth, *DENTITION, *TOOTH roots, *GENETIC variation, *MOLARS, *IMPACTION of teeth, *BICUSPIDS

Abstract

Background: Enamel knots and Hertwig epithelial root sheath (HERS) regulate the growth and folding of the dental epithelium, which subsequently determines the final form of tooth crown and roots. We would like to investigate the genetic etiology of seven patients affected with unique clinical manifestations, including multiple supernumerary cusps, single prominent premolars, and single-rooted molars. Methods: Oral and radiographic examination and whole-exome or Sanger sequencing were performed in seven patients. Immunohistochemical study during early tooth development in mice was performed. Results: A heterozygous variant (c. 865A>G; p.Ile289Val) in CACNA1S was identified in all the patients, but not in an unaffected family member and control. Immunohistochemical study showed high expression of Cacna1s in the secondary enamel knot. Conclusions: This CACNA1S variant seemed to cause impaired dental epithelial folding; too much folding in the molars and less folding in the premolars; and delayed folding (invagination) of HERS, which resulted in single-rooted molars or taurodontism. Our observation suggests that the mutation in CACNA1S might disrupt calcium influx, resulting in impaired dental epithelium folding, and subsequent abnormal crown and root morphology. [ABSTRACT FROM AUTHOR]

Published

2023

7. Lineage tracing of epithelial cells in developing teeth reveals two strategies for building signaling centers

Author

Du, Wei, Hu, Jimmy Kuang-Hsien, Du, Wen, and Klein, Ophir D

Subjects

Biological Sciences, Biomedical and Clinical Sciences, Dentistry, Stem Cell Research, Stem Cell Research - Nonembryonic - Non-Human, Pediatric, Underpinning research, 1.1 Normal biological development and functioning, Animals, Cell Lineage, Cell Tracking, Epithelial Cells, Mice, Mice, Inbred C57BL, Signal Transduction, Tooth, SOX2, enamel knot, epithelium, lineage tracing, morphogenesis, mouse genetics, signaling center, sonic hedgehog, tooth development, Chemical Sciences, Medical and Health Sciences, Biochemistry & Molecular Biology, Biological sciences, Biomedical and clinical sciences, Chemical sciences

Abstract

An important event in organogenesis is the formation of signaling centers, which are clusters of growth factor-secreting cells. In the case of tooth development, sequentially formed signaling centers known as the initiation knot (IK) and the enamel knot (EK) regulate morphogenesis. However, despite the importance of signaling centers, their origin, as well as the fate of the cells composing them, remain open questions. Here, using lineage tracing of distinct epithelial populations, we found that the EK of the mouse incisor is derived de novo from a group of SRY-box 2 (Sox2)-expressing cells in the posterior half of the tooth germ. Specifically, EK progenitors are located in the posterior ventral basal layer, as demonstrated by DiI labeling of cells. Lineage tracing the formed EK with ShhCreER , which encodes an inducible Cre recombinase under the control of the Sonic hedgehog promoter, at subsequent developmental stages showed that, once formed, some EK cells in the incisor give rise to differentiated cells, whereas in the molar, EK cells give rise to the buccal secondary EK. This work thus establishes the developmental origin as well as the fate of the EK and reveals two strategies for the emergence of serially formed signaling centers: one through de novo establishment and the other by incorporation of progeny from previously formed signaling centers.

Published

2017

8. A Mutation in CACNA1S Is Associated with Multiple Supernumerary Cusps and Root Maldevelopment

Author

Piranit Kantaputra, Niramol Leelaadisorn, Athiwat Hatsadaloi, Natalina Quarto, Worrachet Intachai, Sissades Tongsima, Katsushige Kawasaki, Atsushi Ohazama, Chumpol Ngamphiw, and Paswach Wiriyakijja

Subjects

calcium homeostasis, calcium influx, enamel knot, root maldevelopment, supernumerary cusps, single-rooted molars, Medicine (General), R5-920

Abstract

Background: Enamel knots and Hertwig epithelial root sheath (HERS) regulate the growth and folding of the dental epithelium, which subsequently determines the final form of tooth crown and roots. We would like to investigate the genetic etiology of seven patients affected with unique clinical manifestations, including multiple supernumerary cusps, single prominent premolars, and single-rooted molars. Methods: Oral and radiographic examination and whole-exome or Sanger sequencing were performed in seven patients. Immunohistochemical study during early tooth development in mice was performed. Results: A heterozygous variant (c. 865A>G; p.Ile289Val) in CACNA1S was identified in all the patients, but not in an unaffected family member and control. Immunohistochemical study showed high expression of Cacna1s in the secondary enamel knot. Conclusions: This CACNA1S variant seemed to cause impaired dental epithelial folding; too much folding in the molars and less folding in the premolars; and delayed folding (invagination) of HERS, which resulted in single-rooted molars or taurodontism. Our observation suggests that the mutation in CACNA1S might disrupt calcium influx, resulting in impaired dental epithelium folding, and subsequent abnormal crown and root morphology.

Published

2023

9. Cells, Development, and Evolution: Teeth Studies at the Intersection of Fields

Author

MacCord, Kate, Maienschein, Jane, and Delisle, Richard G., editor

Published

2017

10. Cell cycle of the enamel knot during tooth morphogenesis.

Author

Jung, Seo-Yoon, Green, David William, Jung, Han-Sung, and Kim, Eun-Jung

Subjects

*CELL cycle, *MORPHOGENESIS, *DENTITION, *CELL proliferation, *CYTOLOGY

Abstract

Enamel knot (EK) is known to be a central organ in tooth development, especially for cusp patterning. To trace the exact position and movement among the inner dental epithelium (IDE) and EK cells, and to monitor the relationship between the EK and cusp patterning, it is essential that we understand the cell cycle status of the EK in early stages of tooth development. In this study, thymidine analogous (IdU, BrdU) staining was used to evaluate the cell cycle phase of the primary EK at the early casp stage (E13.0) and the gerbil embryo (E19) in a developing mouse embryo. The centerpiece of this study was to describe the cell cycle phasing and sequencing during proliferation in the IDE according to the expression of IdU and BrdU following their injection at calculated time points. The interval time between IdU injection and BrdU injection was set at 4 h. As a result, the cell cycle in the IDE of the mouse and gerbil was found to be synchronous. Conversely, the cell cycle in primary EKs of mice was much longer than that of the IDE. Therefore, the difference of cell cycle of the IDE and the EK is related to the diversity of cusp patterning and would provide a new insight into tooth morphogenesis. [ABSTRACT FROM AUTHOR]

Published

2018

11. Implications of specific gene expression patterns in enamel knot in tooth development

Author

Wern-Joo Sohn, Sanjiv Neupane, Seo-Young An, Tae-Young Kim, Jung-Hong Ha, KimJi-Youn, Chang-Hyeon An, Seo Jo-Young, Kim， Jae Young, Eui-Seon Lee, Yam Prasad Aryal, and Lee Youngkyun

Subjects

0301 basic medicine, Molar, Embryogenesis, Organogenesis, 030206 dentistry, Biology, Epithelium, Enamel knot, Cell biology, stomatognathic diseases, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, stomatognathic system, Gene expression, medicine, Epithelial tissue, Gene

Abstract

Enamel knot (EK)—a signaling center—refers to a transient morphological structure comprising epithelial tissue. EK is believed to regulate tooth development in early organogenesis without its own cellular alterations, including proliferation and differentiation. EKs show a very simple but conserved structure and share functions with teeth of recently evolved vertebrates, suggesting conserved signaling in certain organs, such as functional teeth, through the course of evolution. In this study, we examined the expression patterns of key EK-specific genes including Dusp26 , Fat4, Meis2, Sln , and Zpld1 during mice embryogenesis. Expression patterns of these genes may reveal putative differentiation mechanisms underlying tooth morphogenesis.

Published

2020

12. Altered tooth morphogenesis after silencing the planar cell polarity core component, Vangl2.

Author

Wu, Zhaoming, Epasinghe, Don, He, Jinquan, Li, Liwen, Green, David, Lee, Min-Jung, and Jung, Han-Sung

Subjects

*TOOTH germ (Dentition), *MORPHOGENESIS, *SMALL interfering RNA, *APOPTOSIS, *KIDNEY transplantation, *CELL proliferation

Abstract

Vangl2, one of the core components of the planar cell polarity (PCP) pathway, has an important role in the regulation of morphogenesis in several tissues. Although the expression of Vangl2 has been detected in the developing tooth, its role in tooth morphogenesis is not known. In this study, we show that Vangl2 is expressed in the inner dental epithelium (IDE) and in the secondary enamel knots (SEKs) of bell stage tooth germs. Inhibition of Vangl2 expression by siRNA treatment in in vitro-cultured tooth germs resulted in retarded tooth germ growth with deregulated cell proliferation and apoptosis. After kidney transplantation of Vangl2 siRNA-treated tooth germs, teeth were observed to be small and malformed. We also show that Vangl2 is required to maintain the proper pattern of cell alignment in SEKs, which maybe important for the function of SEKs as signaling centers. These results suggest that Vangl2 plays an important role in the morphogenesis of teeth. [ABSTRACT FROM AUTHOR]

Published

2016

13. An ancient dental signalling centre supports homology of an enamel knot in sharks

Author

Ariane Standing, Gareth J. Fraser, Alexandre P. Thiery, and Rory L. Cooper

Subjects

FGF10, Enamel paint, Morphogenesis, Wnt signaling pathway, Biology, Fibroblast growth factor, Phenotype, Enamel knot, stomatognathic diseases, stomatognathic system, Evolutionary biology, visual_art, visual_art.visual_art_medium, Cusp (anatomy)

Abstract

Development of tooth cusps is regulated by the enamel knot signalling centre. Fgf signalling regulates differential proliferation between the enamel knot and adjacent dental epithelia during tooth development, leading to formation of the dental cusp. The presence of an enamel knot in non-mammalian vertebrates is debated given differences in signalling. Here we show the conservation and restriction of fgf10 and fgf3 to the sites of future dental cusps in the shark (Scyliorhinus canicula), whilst also highlighting striking differences between the shark and mouse. We reveal shifts in tooth size, shape and cusp number following small molecule perturbations of canonical Wnt signalling. Resulting tooth phenotypes mirror observed effects in mammals, where canonical Wnt has been implicated as an upstream regulator of enamel knot signalling. In silico modelling of shark dental morphogenesis demonstrates how subtle changes in activatory and inhibitory signals can alter tooth shape, resembling phenotypes observed following experimental Wnt perturbation. Our results support the functional conservation of an enamel knot-like signalling centre throughout vertebrates and suggest that varied tooth types from sharks to mammals follow a similar developmental bauplan. Lineage-specific differences in signalling are not sufficient in refuting homology of this signalling centre, which is likely older than teeth themselves.

Published

2021

14. Identification of enamel knot gene signature within the developing mouse molar

Author

Winchester Ew and Justin Cotney

Subjects

Molar, Mesenchyme, Regeneration (biology), Tooth eruption, food and beverages, Biology, Gene signature, Epithelium, Enamel knot, Cell biology, stomatognathic diseases, medicine.anatomical_structure, stomatognathic system, medicine, Gene

Abstract

In most mammals, the primary teeth develop in utero and the cells capable of contributing to hard surface regeneration are lost before tooth eruption. These cells differentiate through a series of reciprocal induction steps between the epithelium and mesenchyme, initially orchestrated by an epithelial signaling center called the enamel knot. While the factors secreted by this structure are of interest to the dental regeneration and development communities, its small size makes it difficult to isolate for analysis. Here we describe our work to identify the enamel knot from whole E14 molars using publicly available scRNA-seq data. We identified 335 genes differentially expressed in the enamel knot compared to the surrounding tissues, including known enamel knot marker genes. We validated expression of the most highly enriched enamel knot marker genes and identified 42 novel marker genes of the enamel knot which provide excellent targets for future dental regeneration investigations.

Published

2021

15. Role of Cell Death in Cellular Processes During Odontogenesis

Author

Poongodi Geetha-Loganathan, Marcela Buchtová, Marie Šulcová, and John Abramyan

Subjects

0301 basic medicine, Programmed cell death, QH301-705.5, Cell, Morphogenesis, morphogenesis, Review, Biology, dental lamina, Cell and Developmental Biology, 03 medical and health sciences, 0302 clinical medicine, stomatognathic system, Dental disorder, medicine, Biology (General), teeth, Cell growth, Autophagy, apoptosis, Cell Biology, Dental lamina, Enamel knot, Cell biology, stomatognathic diseases, 030104 developmental biology, medicine.anatomical_structure, odontogenesis, 030217 neurology & neurosurgery, Developmental Biology

Abstract

The development of a tooth germ in a precise size, shape, and position in the jaw, involves meticulous regulation of cell proliferation and cell death. Apoptosis, as the most common type of programmed cell death during embryonic development, plays a number of key roles during odontogenesis, ranging from the budding of the oral epithelium during tooth initiation, to later tooth germ morphogenesis and removal of enamel knot signaling center. Here, we summarize recent knowledge about the distribution and function of apoptotic cells during odontogenesis in several vertebrate lineages, with a special focus on amniotes (mammals and reptiles). We discuss the regulatory roles that apoptosis plays on various cellular processes during odontogenesis. We also review apoptosis-associated molecular signaling during tooth development, including its relationship with the autophagic pathway. Lastly, we cover apoptotic pathway disruption, and alterations in apoptotic cell distribution in transgenic mouse models. These studies foster a deeper understanding how apoptotic cells affect cellular processes during normal odontogenesis, and how they contribute to dental disorders, which could lead to new avenues of treatment in the future.

Published

2021

16. Clinical, genetic, epidemiologic, evolutionary, and functional delineation of TSPEAR -related autosomal recessive ectodermal dysplasia 14.

Author

Jackson A, Lin SJ, Jones EA, Chandler KE, Orr D, Moss C, Haider Z, Ryan G, Holden S, Harrison M, Burrows N, Jones WD, Loveless M, Petree C, Stewart H, Low K, Donnelly D, Lovell S, Drosou K, Varshney GK, and Banka S

Subjects

Animals, Mice, Phylogeny, Zebrafish, Ectodermal Dysplasia epidemiology, Tooth pathology

Abstract

TSPEAR variants cause autosomal recessive ectodermal dysplasia (ARED) 14. The function of TSPEAR is unknown. The clinical features, the mutation spectrum, and the underlying mechanisms of ARED14 are poorly understood. Combining data from new and previously published individuals established that ARED14 is primarily characterized by dental anomalies such as conical tooth cusps and hypodontia, like those seen in individuals with WNT10A -related odontoonychodermal dysplasia. AlphaFold-predicted structure-based analysis showed that most of the pathogenic TSPEAR missense variants likely destabilize the β-propeller of the protein. Analysis of 100000 Genomes Project (100KGP) data revealed multiple founder TSPEAR variants across different populations. Mutational and recombination clock analyses demonstrated that non-Finnish European founder variants likely originated around the end of the last ice age, a period of major climatic transition. Analysis of gnomAD data showed that the non-Finnish European population TSPEAR gene-carrier rate is ∼1/140, making it one of the commonest AREDs. Phylogenetic and AlphaFold structural analyses showed that TSPEAR is an ortholog of drosophila Closca , an extracellular matrix-dependent signaling regulator. We, therefore, hypothesized that TSPEAR could have a role in enamel knot, a structure that coordinates patterning of developing tooth cusps. Analysis of mouse single-cell RNA sequencing (scRNA-seq) data revealed highly restricted expression of Tspear in clusters representing enamel knots. A tspeara -/- ; tspearb -/- double-knockout zebrafish model recapitulated the clinical features of ARED14 and fin regeneration abnormalities of wnt10a knockout fish, thus suggesting interaction between tspear and wnt10a. In summary, we provide insights into the role of TSPEAR in ectodermal development and the evolutionary history, epidemiology, mechanisms, and consequences of its loss of function variants., Competing Interests: The authors declare no competing interests., (© 2023 The Author(s).)

Published

2023

17. Tooth and scale morphogenesis in shark: an alternative process to the mammalian enamel knot system.

Author

Debiais-Thibaud, Mélanie, Chiori, Roxane, Enault, Sébastien, Oulion, Silvan, Germon, Isabelle, Martinand-Mari, Camille, Casane, Didier, and Borday-Birraux, Véronique

Subjects

*TEETH, *MORPHOGENESIS, *ENAMEL & enameling, *GENETIC regulation, *MAMMALOGICAL research

Abstract

Background: The gene regulatory network involved in tooth morphogenesis has been extremely well described in mammals and its modeling has allowed predictions of variations in regulatory pathway that may have led to evolution of tooth shapes. However, very little is known outside of mammals to understand how this regulatory framework may also account for tooth shape evolution at the level of gnathostomes. In this work, we describe expression patterns and proliferation/apoptosis assays to uncover homologous regulatory pathways in the catshark Scyliorhinus canicula. Results: Because of their similar structural and developmental features, gene expression patterns were described over the four developmental stages of both tooth and scale buds in the catshark. These gene expression patterns differ from mouse tooth development, and discrepancies are also observed between tooth and scale development within the catshark. However, a similar nested expression of Shh and Fgf suggests similar signaling involved in morphogenesis of all structures, although apoptosis assays do not support a strictly equivalent enamel knot system in sharks. Similarities in the topology of gene expression pattern, including Bmp signaling pathway, suggest that mouse molar development is more similar to scale bud development in the catshark. Conclusions: These results support the fact that no enamel knot, as described in mammalian teeth, can be described in the morphogenesis of shark teeth or scales. However, homologous signaling pathways are involved in growth and morphogenesis with variations in their respective expression patterns. We speculate that variations in this topology of expression are also a substrate for tooth shape evolution, notably in regulating the growth axis and symmetry of the developing structure. [ABSTRACT FROM AUTHOR]

Published

2015

18. Hippo pathway/Yap regulates primary enamel knot and dental cusp patterning in tooth morphogenesis.

Author

Kwon, Hyuk-Jae, Li, Liwen, and Jung, Han-Sung

Subjects

*DENTAL crowns, *MORPHOGENESIS, *DENTAL enamel, *CELL proliferation, *GENE expression, *ANIMAL models in research

Abstract

The shape of an individual tooth crown is primarily determined by the number and arrangement of its cusps, i.e., cusp patterning. Enamel knots that appear in the enamel organ during tooth morphogenesis have been suggested to play important roles in cusp patterning. Animal model studies have shown that the Hippo pathway effector Yap has a critical function in tooth morphogenesis. However, the role of the Hippo pathway/Yap in cusp patterning has not been well documented and its specific roles in tooth morphogenesis remain unclear. Here, we provide evidence that Yap is a key mediator in tooth cusp patterning. We demonstrate a correlation between Yap localization and cell proliferation in developing tooth germs. We also show that, between the cap stage and bell stage, Yap is crucial for the suppression of the primary enamel knot and for the patterning of secondary enamel knots, which are the future cusp regions. When Yap expression is stage-specifically knocked down during the cap stage, the activity of the primary enamel knot persists into the bell-stage tooth germ, leading to ectopic cusp formation. Our data reveal the importance of the Hippo pathway/Yap in enamel knots and in the proper patterning of tooth cusps. [ABSTRACT FROM AUTHOR]

Published

2015

19. Roles of Wnt inhibitory factor 1 during tooth morphogenesis.

Author

Lee, Min-Jung, Kim, Eun-Jung, Li, Liwen, and Jung, Han-Sung

Subjects

*WNT genes, *DENTITION, *MORPHOGENESIS, *CATENINS, *CELL communication, *APOPTOSIS

Abstract

The activation of Wingless-type (Wnt)/β-catenin signaling is of fundamental importance in organogenesis. Wnt signaling is also known to regulate signaling crucial for tooth development. However, the underlying mechanism of Wnt activation or inhibition remains largely unknown. Here, we demonstrate that Wnt inhibitory factor 1 (Wif1), a secreted Wnt antagonist, localizes to the dental epithelium and mesenchyme during early tooth development. Specifically, Wif1 is strictly expressed in the enamel knot at embryonic day 14.5 (E14.5) and E16.5. The functional significance of Wif1 during tooth morphogenesis remains to be clarified. Our results reveal that the promotion of apoptosis by the knockdown of Wif1 leads to a delay in an early event during tooth development. This study therefore provides novel insights into the role of Wif1 and validates Wif1 as a potent target in WNT signaling during tooth development. We suggest that the enamel knots are central regulators of tooth development. Furthermore, Wif1 localizes to the enamel knot in which Wif1 regulates apoptosis by mediating and regulating Wnt-β-catenin signaling. Thus, Wif1 plays an essential role in tooth development. [ABSTRACT FROM AUTHOR]

Published

2015

20. The role of APCDD1 in epithelial rearrangement in tooth morphogenesis.

Author

Neupane, Sanjiv, Sohn, Wern-Joo, Gwon, Gi-Jeong, Kim, Ki-Rim, Lee, Sanggyu, An, Chang-Hyeon, Suh, Jo-Young, Shin, Hong-In, Yamamoto, Hitoshi, Cho, Sung-Won, Lee, Youngkyun, and Kim, Jae-Young

Subjects

*ADENOMATOUS polyposis coli, *DOWNREGULATION, *DENTITION, *WNT proteins, *CELL communication, *MORPHOGENESIS

Abstract

Adenomatosis polyposis coli downregulated 1 (APCDD1), a negative regulator of Wnt signaling, was examined to understand detailed mechanisms underlying Wnt signaling tooth development. In situ hybridization showed that Apcdd1 was expressed in the condensed mesenchyme at the bud stage, and in the inner enamel epithelium (IEE), including enamel knot (EK) at the cap stage. In vitro organ cultivation by using Apcdd1 antisense oligodeoxynucleotides was performed at E13.5 for 2 days to define the developmental functions of APCDD1 during tooth development. Analysis of histogenesis and cellular events such as cell adhesion, proliferation, apoptosis and epithelial rearrangement after Apcdd1 knockdown showed altered morphogenesis of the tooth germ with decreased cell proliferation and altered localization of cell adhesion molecules. Actin filament staining and 1,1′-dioctadecyl-3,3,3′,3′-tetramethylindocarbocyanine perchlorate (DiI) labeling of IEE cells showed that Apcdd1 knockdown enhanced epithelial rearrangement in the IEE and EK. To understand the precise signaling regulations of Apcdd1, we evaluated the altered expression patterns of signaling molecules, related with Wnt and enamel knot signalings using RT-qPCR. Tooth germs at cap stage were transplanted into the kidney capsules and were allowed to develop into calcified teeth for 3 weeks. Apcdd1 knockdown increased the number of ectopic cusps on the mesial side of the tooth. Our results suggested that APCDD1 modulates the gene expression of Wnt- and EK-related signaling molecules at the cap stage of tooth development, and is involved in tooth cusp patterning by modulating the epithelial rearrangement in the IEE. [ABSTRACT FROM AUTHOR]

Published

2015

21. Sprouty gene dosage influences temporal-spatial dynamics of primary enamel knot formation.

Author

Lochovska, Katerina, Peterkova, Renata, Pavlikova, Zuzana, and Hovorakova, Maria

Subjects

*DENTAL enamel, *BICUSPIDS, *DENTITION, *SPATIOTEMPORAL processes, *GENE expression

Abstract

Background: The mouse embryonic mandible comprises two types of tooth primordia in the cheek region: progressive tooth primordia of prospective functional teeth and rudimentary tooth primordia in premolar region - MS and R2. Mice lacking Sprouty genes develop supernumerary tooth in front of the lower M1 (first molar) primordium during embryogenesis. We focused on temporal-spatial dynamics of Sonic Hedgehog expression as a marker of early odontogenesis during supernumerary tooth development. Results: Using mouse embryos with different dosages of Spry2 and Spry4 genes, we showed that during the normal development of M1 in the mandible the sooner appearing Shh signaling domain of the R2 bud transiently coexisted with the later appearing Shh expression domain in the early M1 primordium. Both domains subsequently fused together to form the typical signaling center representing primary enamel knot (pEK) of M1 germ at embryonic day (E) 14.5. However, in embryos with lower Spry2;Spry4 gene dosages, we observed a non-fusion of original R2 and M1 Shh signaling domains with consequent formation of a supernumerary tooth primordium from the isolated R2 bud. Conclusions: Our results bring new insight to the development of the first lower molar of mouse embryos and define simple tooth unit capable of individual development, as well as determine its influence on normal and abnormal development of the tooth row which reflect evolutionarily conserved tooth pattern. Our findings contribute significantly to existing knowledge about supernumerary tooth formation. [ABSTRACT FROM AUTHOR]

Published

2015

22. Development and evolution of dentition patterns and their genetic basis.

Abstract

Introduction A fundamental question in developmental biology is how patterns are established, and in evolutionary biology how patterns are changed. The pattern of vertebrate dentitions (tooth morphology, number, and location) is of obvious importance to the survival of individual organisms and a great diversity of patterns exists among vertebrate taxa (Peyer, 1968). Furthermore, the abundance of teeth and jaws in the fossil record provides a tremendous amount of information about the evolutionary changes that have occurred in these patterns. However, despite the accumulation of histological and molecular information on the development of individual teeth (Thesleff et al., 1996; Ruch, 1987), little is known about the control of the pattern of the dentition as a whole during embryonic development. Such information is crucial for understanding the mechanisms of evolutionary change in the vertebrate dentition. In this chapter, we review aspects of the evolution of dentition patterns, models that have been proposed for the developmental mechanisms responsible for these patterns and candidate genes for controlling them. Although the dentitions of mammals constitute only a small portion of the diversity observed in vertebrates, we will concentrate on this group because of the much greater availability of developmental and genetic data. For the purposes of this chapter, ‘dentition pattern’ refers to the number, location, and arrangement of differently shaped teeth, while ‘dental pattern’ is used to describe the crown structure of individual teeth, e.g. location, shape and size of cusps. Axial definitions for the adult dentition and embryonic jaws Various axial definitions for the adult dentition and embryonic mandible have been used in the literature (Table 11.1). However, these definitions can be inconsistent or confusing. [ABSTRACT FROM AUTHOR]

Published

2000

23. Homeobox genes in initiation and shape of teeth during development in mammalian embryos.

Abstract

Introduction The past decade has seen remarkable advances in our understanding of the genetic control of embryonic development. We now know that developmental processes are initiated and controlled by interacting pathways of extracellular signalling molecules, receptors, intracellular signalling proteins and nuclear (transcription) factors. The different types of proteins (genes) that carry out these functions most often occur as members of families of related proteins characterised by possessing conserved amino acid motifs but which do not necessarily have similar functions in development. Thus for example, the transforming growth factor-beta (TGFβ) superfamily of secreted signalling proteins consists of a large family of proteins that share some homology with TGFβ, and in many cases share cell surface receptors (Kingsley, 1994). However, within this family different members have very different and specific functions in development. The bone morphogenetic protein Bmp-4, for example, probably has multiple functions as a signalling molecule in embryogenesis, including a role in lung morphogenesis, but targeted mutation of Bmp-4 (gene knock-out) shows a requirement for this protein for early mesoderm formation (Winnier et al., 1995; Bellusci et al., 1996). Bmp-7 on the other hand appears to have no direct role in mesoderm formation but is required for skeletal development (Luo et al., 1995). This illustrates a recurring theme in development where similar molecules have multiple functions, some of which overlap with other family members whereas others are unique. This almost certainly reflects the evolution of these gene families by gene duplication resulting in some shared and some unique functions. The First of these families of developmental genes to be discovered and the one which has produced the greatest interest is that of the homeobox genes. [ABSTRACT FROM AUTHOR]

Published

2000

24. Return of lost structure in the developmental control of tooth shape.

Abstract

Introduction Perhaps one of the main attractions, both scientifically and aesthetically, of mammalian teeth is their diversity. Among other things, differently shaped teeth are a good reminder of both evolutionary flexibility and precision of developmental control mechanisms. In this respect, mammalian teeth offer a good opportunity to use the fossil record to test our models of development. However, although the diversity of tooth shapes has been described in great detail and their evolutionary history has been relatively well reconstructed, our current knowledge of general mechanisms controlling tooth shape development is limited. As a first approximation, a great deal of mammalian molar tooth diversity derives from different combinations of cusps (Chapter 19). Cusp number, size and shape can vary from one tooth to the next and often cusps are connected by crests (lophs). Even this ‘gross tooth’ diversity constitutes a considerable challenge to a developmental biologist wishing to study the development of tooth shapes. Indeed, the list of students of comparative tooth development is extensive and extends back in time to Richard Owen (e.g. Owen, 1845; Leche, 1915; Bolk, 1920–22; Butler, 1956; Gaunt, 1961). While the enthusiasm to study comparative ontogeny of different tooth shapes appears to have slowly declined, molecular studies of mouse tooth development have flourished (see Weiss, 1993; Thesleff et al., 1995; Thesleff and Sahlberg, 1996 for reviews). As a subject of study, the diversity of biological shapes has been transposed by the diversity of genes and their products. In practical terms this implies that, of total mammalian tooth diversity, we are left with the dentition of a mouse. This does not imply that mouse teeth are somehow uninteresting. [ABSTRACT FROM AUTHOR]

Published

2000

25. Pitx2-Sox2-Lef1 interactions specify progenitor oral/dental epithelial cell signaling centers

Author

Shankar Rengasamy Venugopalan, Zhao Sun, Steven Eliason, Brad A. Amendt, Michael L. Paine, Wenjie Yu, Mason Sweat, Huojun Cao, and Yan Yan Sweat

Subjects

0303 health sciences, congenital, hereditary, and neonatal diseases and abnormalities, Cellular differentiation, Cervical loop, Biology, Stem Cells and Regeneration, Embryonic stem cell, Cell biology, Enamel knot, 03 medical and health sciences, stomatognathic diseases, 0302 clinical medicine, SOX2, stomatognathic system, embryonic structures, Transcriptional regulation, sense organs, Progenitor cell, Molecular Biology, 030217 neurology & neurosurgery, 030304 developmental biology, Developmental Biology, Progenitor

Abstract

Epithelial signaling centers control epithelial invagination and organ development, but how these centers are specified remains unclear. We report that Pitx2 (the first transcriptional marker for tooth development) controls the embryonic formation and patterning of epithelial signaling centers during incisor development. We demonstrate using Krt14Cre/Pitx2flox/flox (Pitx2cKO) embryos, and Rosa26CreERT/Pitx2flox/flox mice that loss of Pitx2 delays epithelial invagination, decreases progenitor cell proliferation, and dental epithelium cell differentiation. Developmentally, Pitx2 regulates formation of the Sox2+ labial cervical loop (LaCL) stem cell niche in concert with two signaling centers, the initiation knot (IK) and enamel knot (EK). The loss of Pitx2 disrupted the patterning of these two signaling centers resulting in tooth arrest at E14.5. Mechanistically, Pitx2 transcriptional activity and DNA binding is inhibited by Sox2, and this interaction controls gene expression in specific Sox2 and Pitx2 co-expression progenitor cell domains. We demonstrate new transcriptional mechanisms regulating signaling centers by Pitx2, Sox2, Lef-1 and Irx1.

Published

2020

26. Stage-specific expression patterns of ER stress-related molecules in mice molars: Implications for tooth development

Author

Eui-Seon Lee, Hitoshi Yamamoto, Jo-Young Suh, Yam Prasad Aryal, Shijin Sung, Seo-Young An, Jung-Hong Ha, Jae-Kwang Jung, Chang-Hyeon An, Jae-Young Kim, Wern-Joo Sohn, Ji-Youn Kim, Tae-Young Kim, Youngkyun Lee, and Sung Won Cho

Subjects

XBP1, Biology, Real-Time Polymerase Chain Reaction, 03 medical and health sciences, Mice, 0302 clinical medicine, stomatognathic system, Genetics, Morphogenesis, Animals, Molecular Biology, In Situ Hybridization, 030304 developmental biology, 0303 health sciences, ATF6, Binding protein, Endoplasmic reticulum, Gene Expression Regulation, Developmental, Endoplasmic Reticulum Stress, Molar, Enamel knot, Cell biology, Odontoblast, Unfolded protein response, Unfolded Protein Response, Ameloblast, Tooth, 030217 neurology & neurosurgery, Developmental Biology, Signal Transduction

Abstract

The endoplasmic reticulum (ER) is a site where protein folding and posttranslational modifications occur, but when unfolded or misfolded proteins accumulate in the ER lumen, an unfolded protein response (UPR) occurs. A UPR activates ER-stress signalling genes, including inositol-requiring enzyme-1 (Ire1), activating transcription factor 6 (Atf6), and double-stranded RNA-activated protein kinase-like endoplasmic reticulum kinase (Perk), to maintain homeostasis. The involvement of ER stress molecules in metabolic disease and hard tissue matrix formation has been established; however, an understanding of the role of ER-stress signalling molecules in tooth development is lacking. The aims of this study are to define the stage-specific expression patterns of ER stress-related molecules and to elucidate their putative functions in the organogenesis of teeth. This study leverages knowledge of the tissue morphology and expression patterns of a range of signalling molecules during tooth development. RT-qPCR, in situ hybridization, and immunohistochemistry analyses were performed to determine the stage-specific expression patterns of ER-stress-related signalling molecules at important stages of tooth development. RT-qPCR analyses showed that Atf6 and Perk have similar expression levels during all stages of tooth development; however, the expression levels of Ire1 and its downstream target X-box binding protein (Xbp1) increased significantly from the cap to the secretory stage of tooth development. In situ hybridization results revealed that Atf6 and Xbp1 were expressed in cells that form the enamel knot at cap stage and ameloblasts and odontoblasts at secretory stage in stage-specific patterns. In addition, Atf6, Ire1, and Xbp1 expression exhibited distinct localization patterns in secretory odontoblasts and ameloblasts of PN0 molars. Overall, our results strongly suggest that ER-stress molecules are involved in tooth development in response to protein overload that occurs during signaling modulations from enamel knots at cap stage and extracellular matrix secretion at secretory stage.

Published

2020

27. Bioengineered Tooth Buds Exhibit Features of Natural Tooth Buds

Author

Weibo Zhang, S. Angstadt, Ali Khademhosseini, Elizabeth E. Smith, Nelson Monteiro, and Pamela C. Yelick

Subjects

0301 basic medicine, Swine, Dentistry, Cell Count, Biology, 03 medical and health sciences, stomatognathic system, Tissue engineering, Human Umbilical Vein Endothelial Cells, Tooth loss, medicine, Animals, Humans, General Dentistry, Tissue Engineering, Tissue Scaffolds, business.industry, Stem Cells, Regeneration (biology), Tooth Germ, Implant failure, Research Reports, X-Ray Microtomography, Enamel knot, stomatognathic diseases, 030104 developmental biology, Odontoblast, Odontogenesis, medicine.symptom, Stem cell, business, Ameloblast

Abstract

Tooth loss is a significant health issue currently affecting millions of people worldwide. Artificial dental implants, the current gold standard tooth replacement therapy, do not exhibit many properties of natural teeth and can be associated with complications leading to implant failure. Here we propose bioengineered tooth buds as a superior alternative tooth replacement therapy. We describe improved methods to create highly cellularized bioengineered tooth bud constructs that formed hallmark features that resemble natural tooth buds such as the dental epithelial stem cell niche, enamel knot signaling centers, transient amplifying cells, and mineralized dental tissue formation. These constructs were composed of postnatal dental cells encapsulated within a hydrogel material that were implanted subcutaneously into immunocompromised rats. To our knowledge, this is the first report describing the use of postnatal dental cells to create bioengineered tooth buds that exhibit evidence of these features of natural tooth development. We propose future bioengineered tooth buds as a promising, clinically relevant tooth replacement therapy.

Published

2018

28. EpithelialCdc42Deletion Induced Enamel Organ Defects and Cystogenesis

Author

L. Wu, A. J. Yoon, Z. Tian, X. Nie, Ling He, M. Vats, Schiff, Xin Zhang, Jeremy J. Mao, L. Xiang, and J. Zheng

Subjects

rho GTP-Binding Proteins, 0301 basic medicine, Cytoskeleton organization, Blotting, Western, Apoptosis, macromolecular substances, Biology, Real-Time Polymerase Chain Reaction, Epithelium, Stratum intermedium, Mice, 03 medical and health sciences, Microscopy, Electron, Transmission, stomatognathic system, Ameloblasts, In Situ Nick-End Labeling, Animals, General Dentistry, Stellate reticulum, Enamel paint, Cysts, Outer enamel epithelium, Autophagosomes, Enamel Organ, Enamel organ, Cell Differentiation, Research Reports, Actins, Enamel knot, Cell biology, Cytoskeletal Proteins, stomatognathic diseases, Intercellular Junctions, 030104 developmental biology, visual_art, Ameloblast differentiation, visual_art.visual_art_medium

Abstract

Cdc42, a Rho family small GTPase, regulates cytoskeleton organization, vesicle trafficking, and other cellular processes in development and homeostasis. However, Cdc42’s roles in prenatal tooth development remain elusive. Here, we investigated Cdc42 functions in mouse enamel organ. Cdc42 showed highly dynamic temporospatial patterns in the developing enamel organ, with robust expression in the outer enamel epithelium, stellate reticulum (SR), and stratum intermedium layers. Strikingly, epithelium-specific Cdc42 deletion resulted in cystic lesions in the enamel organ. Cystic lesions were first noted at embryonic day 15.5 and progressively enlarged during gestation. At birth, cystic lesions occupied the bulk of the entire enamel organ, with intracystic erythrocyte accumulation. Ameloblast differentiation was retarded upon epithelial Cdc42 deletion. Apoptosis occurred in the Cdc42 mutant enamel organ prior to and synchronously with cystogenesis. Transmission electron microscopy examination showed disrupted actin assemblies, aberrant desmosomes, and significantly fewer cell junctions in the SR cells of Cdc42 mutants than littermate controls. Autophagosomes were present in the SR cells of Cdc42 mutants relative to the virtual absence of autophagosome in the SR cells of littermate controls. Epithelium-specific Cdc42 deletion attenuated Wnt/β-catenin and Shh signaling in dental epithelium and induced aberrant Sox2 expression in the secondary enamel knot. These findings suggest that excessive cell death and disrupted cell-cell connections may be among multiple factors responsible for the observed cystic lesions in Cdc42 mutant enamel organs. Taken together, Cdc42 exerts multidimensional and pivotal roles in enamel organ development and is particularly required for cell survival and tooth morphogenesis.

Published

2018

29. Cell cycle of the enamel knot during tooth morphogenesis

Author

Han Sung Jung, Seo Yoon Jung, Eun Jung Kim, and David W. Green

Subjects

0301 basic medicine, Histology, Biology, Gerbil, Epithelium, Mice, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, stomatognathic system, Morphogenesis, medicine, Animals, Dental Enamel, Molecular Biology, Mice, Inbred ICR, Cell Cycle, Embryo, Cell Biology, Cell cycle, Cell biology, Enamel knot, Medical Laboratory Technology, 030104 developmental biology, medicine.anatomical_structure, chemistry, Cusp (anatomy), Gerbillinae, Thymidine, Tooth, Developmental biology, 030217 neurology & neurosurgery

Abstract

Enamel knot (EK) is known to be a central organ in tooth development, especially for cusp patterning. To trace the exact position and movement among the inner dental epithelium (IDE) and EK cells, and to monitor the relationship between the EK and cusp patterning, it is essential that we understand the cell cycle status of the EK in early stages of tooth development. In this study, thymidine analogous (IdU, BrdU) staining was used to evaluate the cell cycle phase of the primary EK at the early casp stage (E13.0) and the gerbil embryo (E19) in a developing mouse embryo. The centerpiece of this study was to describe the cell cycle phasing and sequencing during proliferation in the IDE according to the expression of IdU and BrdU following their injection at calculated time points. The interval time between IdU injection and BrdU injection was set at 4 h. As a result, the cell cycle in the IDE of the mouse and gerbil was found to be synchronous. Conversely, the cell cycle in primary EKs of mice was much longer than that of the IDE. Therefore, the difference of cell cycle of the IDE and the EK is related to the diversity of cusp patterning and would provide a new insight into tooth morphogenesis.

Published

2018

30. Current knowledge of tooth development: patterning and mineralization of the murine dentition.

Author

Catón, Javier and Tucker, Abigail S.

Subjects

*DENTISTRY, *TOOTH care & hygiene, *MOLARS, *CUSPIDS, *DENTAL enamel, *AMELOGENIN, *DENTAL pellicle

Abstract

The integument forms a number of different types of mineralized element, including dermal denticles, scutes, ganoid scales, elasmoid scales, fin rays and osteoderms found in certain fish, reptiles, amphibians and xenarthran mammals. To this list can be added teeth, which are far more widely represented and studied than any of the other mineralized elements mentioned above, and as such can be thought of as a model mineralized system. In recent years the focus for studies on tooth development has been the mouse, with a wealth of genetic information accrued and the availability of cutting edge techniques. It is the mouse dentition that this review will concentrate on. The development of the tooth will be followed, looking at what controls the shape of the tooth and how signals from the mesenchyme and epithelium interact to lead to formation of a molar or incisor. The number of teeth generated will then be investigated, looking at how tooth germ number can be reduced or increased by apoptosis, fusion of tooth germs, creation of new tooth germs, and the generation of additional teeth from existing tooth germs. The development of mineralized tissue will then be detailed, looking at how the asymmetrical deposition of enamel is controlled in the mouse incisor. The continued importance of epithelial–mesenchymal interactions at these later stages of tooth development will also be discussed. Tooth anomalies and human disorders have been well covered by recent reviews, therefore in this paper we wish to present a classical review of current knowledge of tooth development, fitting together data from a large number of recent research papers to draw general conclusions about tooth development. [ABSTRACT FROM AUTHOR]

Published

2009

31. Expression patterns of the Tmem16 gene family during cephalic development in the mouse

Author

Gritli-Linde, Amel, Vaziri Sani, Forugh, Rock, Jason R., Hallberg, Kristina, Iribarne, Daniela, Harfe, Brian D., and Linde, Anders

Subjects

*GENE expression, *MEMBRANE proteins, *NEUROGENETICS, *LABORATORY mice, *EPITHELIUM, *MOTOR neurons, *AXONS, *CARTILAGE cells

Abstract

Abstract: Tmem16a, Tmem16c, Tmem16f, Tmem16h and Tmem16k belong to the newly identified Tmem16 gene family encoding eight-pass transmembrane proteins. We have analyzed the expression patterns of these genes during mouse cephalic development. In the central nervous system, Tmem16a transcripts were abundant in the ventricular neuroepithelium, whereas the other Tmem16 family members were readily detectable in the subventricular zone and differentiating fields. In the rostral spinal cord, Tmem16f expression was highest in the motor neuron area. In the developing eye, the highest amounts of Tmem16a transcripts were detected in the lens epithelium, hyaloid plexus and outer layer of the retina, while the other family members were abundant in the retinal ganglionic cell layer. Interestingly, throughout development, Tmem16a expression in the inner ear was robust and restricted to a subset of cells within the epithelium, which at later stages formed the organ of Corti. The stria vascularis was particularly rich in Tmem16a and Tmem16f mRNA. Other sites of Tmem16 expression included cranial nerve and dorsal root ganglia, meningeal precursors and the pituitary. Tmem16c and Tmem16f transcripts were also patent in the submandibular autonomic ganglia. A conspicuous feature of Tmem16a was its expression along the walls of blood vessels as well as in cells surrounding the trigeminal and olfactory nerve axons. In organs developing through epithelial–mesenchymal interactions, such as the palate, tooth and tongue, the above five Tmem16 family members showed interesting dynamic expression patterns as development proceeded. Finally and remarkably, osteoblasts and chondrocytes were particularly loaded with Tmem16a, Tmem16c and Tmem16f transcripts. [Copyright &y& Elsevier]

Published

2009

32. The large functional spectrum of the heparin-binding cytokines MK and HB-GAM in continuously growing organs: The rodent incisor as a model

Author

Mitsiadis, Thimios A., Caton, Javier, De Bari, Cosimo, and Bluteau, Gilles

Subjects

*HEPARIN, *ANTICOAGULANTS, *CYTOKINES, *GENE expression

Abstract

Abstract: The heparin binding molecules MK and HB-GAM are involved in the regulation of growth and differentiation of many tissues and organs. Here we analyzed the expression of MK and HB-GAM in the developing mouse incisors, which are continuously growing organs with a stem cell compartment. Overlapping but distinct expression patterns for MK and HB-GAM were observed during all stages of incisor development (initiation, morphogenesis, cytodifferentiation). Both proteins were detected in the enamel knot, a transient epithelial signaling structure that is important for tooth morphogenesis, and the cervical loop where the stem cell niche is located. The functions of MK and HB-GAM were studied in dental explants and organotypic cultures in vitro. In mesenchymal explants, MK stimulated HB-GAM expression and, vice-versa, HB-GAM upregulated MK expression, thus indicating a regulatory loop between these proteins. BMP and FGF molecules also activated expression of both cytokines in mesenchyme. The proliferative effects of MK and HB-GAM varied according to the mesenchymal or epithelial origin of the tissue. Growth, cytodifferentiation and mineralization were inhibited in incisor germs cultured in the presence of MK neutralizing antibodies. These results demonstrate that MK and HB-GAM are involved in stem cells maintenance, cytodifferentiation and mineralization processes during mouse incisor development. [Copyright &y& Elsevier]

Published

2008

33. Initiation and patterning of the snake dentition are dependent on Sonic Hedgehog signaling

Author

Buchtová, Marcela, Handrigan, Gregory R., Tucker, Abigail S., Lozanoff, Scott, Town, Liam, Fu, Katherine, Diewert, Virginia M., Wicking, Carol, and Richman, Joy M.

Subjects

*SNAKES, *DENTITION, *CELL growth, *CELL proliferation

Abstract

Abstract: Here we take the first look at cellular dynamics and molecular signaling in the developing snake dentition. We found that tooth formation differs from rodents in several respects. The majority of snake teeth bud off of a deep, ribbon-like dental lamina rather than as separate tooth germs. Prior to and after dental lamina ingrowth, we observe asymmetries in cell proliferation and extracellular matrix distribution suggesting that localized signaling by a secreted protein is involved. We cloned Sonic hedgehog from the African rock python Python sebae and traced its expression in the species as well as in two other snakes, the closely-related Python regius and the more derived corn snake Elaphe guttata (Colubridae). We found that expression of Shh is first confined to the odontogenic band and defines the position of the future dental lamina. Shh transcripts in pythons are progressively restricted to the oral epithelium on one side of the dental lamina and remain in this position throughout the prehatching period. Shh is expressed in the inner enamel epithelium and the stellate reticulum of the tooth anlagen, but is absent from the outer enamel epithelium and its derivative, the successional lamina. This suggests that signals other than Shh are responsible for replacement tooth formation. Functional studies using cyclopamine to block Hh signaling during odontogenesis prevented initiation and extension of the dental lamina into the mesenchyme, and also affected the directionality of this process. Further, blocking Hh signaling led to disruptions of the inner enamel epithelium. To explore the role of Shh in lamina extension, we looked at its expression in the premaxillary teeth, which form closer to the oral surface than elsewhere in the mouth. Oral ectodermal Shh expression in premaxillary teeth is lost soon after the teeth form reinforcing the idea that Shh is controlling the depth of the dental lamina. In summary, we have found diverse roles for Shh in patterning the snake dentition but, have excluded the participation of this signal in replacement tooth formation. [Copyright &y& Elsevier]

Published

2008

34. Asymmetrical growth, differential cell proliferation, and dynamic cell rearrangement underlie epithelial morphogenesis in mouse molar development.

Author

Obara, Nobuko and Lesot, Hervé

Subjects

*CELL proliferation, *CELL populations, *CELL growth, *MORPHOGENESIS, *CELL differentiation, *MORPHOGENESIS -- Molecular aspects

Abstract

During molar development from the cap to bell stage, the morphology of the enamel knots, inner dental epithelium, and epithelial-mesenchymal junction dynamically changes, leading to the formation of multiple cusps. To study the basic histological features of this morphogenetic change, we have investigated the cell arrangement, mitosis, and apoptosis simultaneously in the developing first lower molar of the mouse by means of BrdU injection and immunostaining for P-cadherin, BrdU, and single-stranded DNA. At the typical cap stage, the primary enamel knot shows a characteristic cell arrangement, absence of mitosis, and abundant apoptosis, but also actively dividing cells at its lateral margins. Two secondary enamel knots then appear in the anterior part of the tooth germ. One is completely non-proliferating, whereas the other contains dividing cells, indicating asymmetrical growth of the inner dental epithelium. From this transitional stage to the early bell stage, additional minor BrdU-negative domains appear, and at the same time, the cell arrangement in the inner dental epithelium rapidly changes to show regional differences. Comparisons between the histology and the distribution of BrdU-positive cells have revealed that both the regionally different cell rearrangement and the differential cell proliferation in the enamel knots and inner dental epithelium probably play a significant role in multiple cusp formation. [ABSTRACT FROM AUTHOR]

Published

2007

35. The primary enamel knot determines the position of the first buccal cusp in developing mice molars.

Author

Sung-Won Cho, Hyun-A Lee, Jinglei Cai, Min-Jung Lee, Jae-Young Kim, Ohshima, Hayato, and Han-Sung Jung

Subjects

DENTAL enamel, POLAR cusp, MOLARS, EPITHELIAL cells, DECIDUOUS teeth, MICE

Abstract

The enamel knot (EK), which is located in the center of bud and cap stage tooth germs, is a transitory cluster of non-dividing epithelial cells. The EK acts as a signaling center that provides positional information for tooth morphogenesis and regulates the growth of tooth cusps by inducing secondary EKs. The morphological, cellular, and molecular events leading to the relationship between the primary and secondary EKs have not been described clearly. This study investigated the relationship between the primary and secondary EKs in the maxillary and mandibular first molars of mice. The location of the primary EK and secondary EKs was investigated by chasing Fgf4 expression patterns in tooth germ at some intervals of in vitro culture, and the relationship between the primary EK and secondary EK was examined by tracing the primary EK cells in the E13.5 tooth germs which were frontally half sliced to expose the primary EK. After 48 hr, the primary EK cells in the sliced tooth germs were located on the buccal secondary EKs, which correspond to the future paracone in maxilla and protoconid in mandible. The Bmp4 expression in buccal part of the dental mesenchyme might be related with the lower growth in buccal epithelium than in lingual epithelium, and the Msx2 expressing area in epithelium was overlapped with the enamel cord (or septum) and cell dense area. The enamel cord might connect the primary EK with enamel navel to fix the location of the primary EK in the buccal side during the cap to bell stages. Overall, these results suggest that primary EK cells strictly contribute to form the paracone or protoconid, which are the main cusps of the tooth in the maxilla or mandible. [ABSTRACT FROM AUTHOR]

Published

2007

36. Temporospatial tissue interactions regulating the regeneration of the enamel knot in the developing mouse tooth.

Author

Sung-Won Cho, Jae-Young Kim, Jinglei Cai, Jong-Min Lee, Eun-Jung Kim, Hyun-A Lee, Hitoshi Yamamoto, and Han-Sung Jung

Subjects

DENTAL pathology, DENTAL enamel, MOLARS, EPITHELIUM, TISSUES, MICE

Abstract

The enamel knot (EK), which is a transient signaling center in the tooth germ, regulates both the differential growth of the dental epithelium and the tooth shape. In this study, the regeneration of the EK was evaluated. The EK regions were removed from the E14 and E16 dental epithelia, and the remaining epithelia were recombined with their original dental mesenchymes. All these tooth germs could develop into calcified teeth after being transplanted into the kidney capsule for 3 weeks. One primary EK was regenerated earlier, and two or three secondary EKs were regenerated later in culture. When simply recombined without removing the EK, the tooth germ, which had four secondary EKs and four cuspal areas of the dental papilla, generated one primary EK first and subsequent secondary EKs. These results indicate that the patterning of the EK in all tooth germs always starts from a primary EK independent of the direct epithelial or mesenchymal control. This suggests that neither the dental epithelium nor the dental mesenchyme can dictate the pattern or number of the EK formation, but the interaction between the dental epithelium and the dental mesenchyme is essential for the regeneration and patterning of the EKs. [ABSTRACT FROM AUTHOR]

Published

2007

37. Spatiotemporal Expression of Wnt/β-catenin Signaling during Morphogenesis and Odontogenesis of Deciduous Molar in Miniature Pig

Author

Jinsong Wang, Songlin Wang, Yan Li, Yang Li, Lei Hu, Xiaoshan Wu, Fu Wang, and Chunmei Zhang

Subjects

0301 basic medicine, miniature pig, Lymphoid Enhancer-Binding Factor 1, Swine, Biology, Applied Microbiology and Biotechnology, Wnt-5a Protein, 03 medical and health sciences, Spatio-Temporal Analysis, stomatognathic system, Wnt3A Protein, AXIN2, Basic Helix-Loop-Helix Transcription Factors, Morphogenesis, Animals, Humans, tooth, Dental papilla, Molecular Biology, development, Wnt Signaling Pathway, Ecology, Evolution, Behavior and Systematics, Inner enamel epithelium, Wnt signaling pathway, Cell Biology, Anatomy, Wnt signaling, Immunohistochemistry, Enamel knot, Cell biology, stomatognathic diseases, 030104 developmental biology, DKK1, Intercellular Signaling Peptides and Proteins, Odontogenesis, Ameloblast, Developmental Biology, Research Paper

Abstract

The canonical Wnt/β-catenin signaling pathway has been shown to play essential roles in tooth initiation and early tooth development. However, the role of Wnt/β-catenin signaling in cusp patterning and crown calcification in large mammals are largely unknown. In our previous study, miniature pigs were used as the animal model due to the similarity of tooth anatomy and replacement pattern between miniature pig and human. Dynamic gene expression of third deciduous molar (DM3) in miniature pig at early stages was profiled using microarray method and expression of Wnt genes was significantly correlate with odontogenesis. In the present study, dynamic expression patterns of Wnt/β-catenin signaling genes of DM3 at cap, early bell and late bell (secretory) stage were identified. We found that Lef1 and Axin2 were expressed in the enamel knot and underlying mesenchyme regions. Meanwhile, Dkk1 was expressed in the peripheral and lower parts of dental papilla, thus forming the potential Wnt signaling gradient. We also found that β-Catenin, Axin2 and Lef1 were expressed strongly in undifferentiated cells of the inner enamel epithelium (IEE), but weakly in differentiated ameloblasts. Furthermore, we found that both Wnt signaling read-out gene Lef1 and the inhibitor Dkk1 were co-expressed in the pre-odontoblasts. In conclusion, the spatiotemporal distribution and potential gradient of Wnt signaling may contribute to cusp patterning and crown calcification. These data may yield insight into future study of precise control of crown morphogenesis and regeneration in large mammals.

Published

2017

38. Lineage tracing of epithelial cells in developing teeth reveals two strategies for building signaling centers

Author

Ophir D. Klein, Wei Du, Jimmy Kuang-Hsien Hu, and Wen Du

Subjects

0301 basic medicine, Biochemistry & Molecular Biology, 1.1 Normal biological development and functioning, Cellular differentiation, SOX2, Morphogenesis, morphogenesis, Cre recombinase, Organogenesis, Inbred C57BL, signaling center, Medical and Health Sciences, Biochemistry, Mice, sonic hedgehog, 03 medical and health sciences, lineage tracing, stomatognathic system, Underpinning research, Animals, Cell Lineage, Sonic hedgehog, Progenitor cell, Molecular Biology, enamel knot, Pediatric, Genetics, biology, tooth development, Epithelial Cells, Cell Biology, Biological Sciences, Stem Cell Research, Cell biology, Enamel knot, Mice, Inbred C57BL, mouse genetics, stomatognathic diseases, 030104 developmental biology, Cell Tracking, Chemical Sciences, biology.protein, Stem Cell Research - Nonembryonic - Non-Human, epithelium, Tooth, Developmental Biology, Signal Transduction

Abstract

An important event in organogenesis is the formation of signaling centers, which are clusters of growth factor-secreting cells. In the case of tooth development, sequentially formed signaling centers known as the initiation knot (IK) and the enamel knot (EK) regulate morphogenesis. However, despite the importance of signaling centers, their origin, as well as the fate of the cells composing them, remain open questions. Here, using lineage tracing of distinct epithelial populations, we found that the EK of the mouse incisor is derived de novo from a group of SRY-box 2 (Sox2)-expressing cells in the posterior half of the tooth germ. Specifically, EK progenitors are located in the posterior ventral basal layer, as demonstrated by DiI labeling of cells. Lineage tracing the formed EK with ShhCreER , which encodes an inducible Cre recombinase under the control of the Sonic hedgehog promoter, at subsequent developmental stages showed that, once formed, some EK cells in the incisor give rise to differentiated cells, whereas in the molar, EK cells give rise to the buccal secondary EK. This work thus establishes the developmental origin as well as the fate of the EK and reveals two strategies for the emergence of serially formed signaling centers: one through de novo establishment and the other by incorporation of progeny from previously formed signaling centers.

Published

2017

39. Dental epithelial histo-morphogenesis in the mouse: positional information versus cell history

Author

Hu, Bing, Nadiri, Amal, Bopp-Kuchler, Sabine, Perrin-Schmitt, Fabienne, Wang, Songlin, and Lesot, Hervé

Subjects

*LABORATORY mice, *MESENCHYME, *DENTISTRY, *EPITHELIAL cells

Abstract

Summary: Reciprocal epithelial–mesenchymal interactions control odontogenesis and the cap stage tooth germ mesenchyme specifies crown morphogenesis. The aim of this work was to determine whether this mesenchyme could also control epithelial histogenesis. Dental mesenchyme and enamel organ were dissociated from mouse first lower molars at E14. At this early cap stage, the enamel organ consists of four cell types forming the inner dental epithelium (IDE), primary enamel knot (PEK), outer dental epithelium (ODE) and the stellate reticulum (SR). Pelleted trypsin-dissociated single dental epithelial cells, which had lost all positional information, were reassociated to either dental mesenchyme or dissociated mesenchymal cells and cultured in vitro. Although with different timings, teeth developed in both types of experiments showing a characteristic dental epithelial histogenesis, cusp formation, and the differentiation of functional odontoblasts and ameloblasts. The rapid progression of the initial steps of histogenesis suggested that the cell history was not memorized. The dental mesenchyme, as well as dissociated mesenchymal cells, induced the formation of a PEK indicating that no specific organisation in the mesenchyme is required for this step. However, the proportion of well-formed multicusped teeth was much higher when intact mesenchyme was used instead of dissociated mesenchymal cells. The mesenchymal cell dissociation had consequences for the functionality of the newly-formed PEK. [Copyright &y& Elsevier]

Published

2005

40. Runx2 mediates FGF signaling from epithelium to mesenchyme during tooth morphogenesis

Author

Åberg, Thomas, Wang, Xiu-Ping, Kim, Jung-Hwan, Yamashiro, Takashi, Bei, Marianna, Rice, Ritva, Ryoo, Hyun-Mo, and Thesleff, Irma

Subjects

*EPITHELIUM, *MORPHOGENESIS, *LABORATORY mice, *GENES

Abstract

Runx2 (Cbfa1) is a runt domain transcription factor that is essential for bone development and tooth morphogenesis. Teeth form as ectodermal appendages and their development is regulated by interactions between the epithelium and mesenchyme. We have shown previously that Runx2 is expressed in the dental mesenchyme and regulated by FGF signals from the epithelium, and that tooth development arrests at late bud stage in Runx2 knockout mice [Development 126 (1999) 2911]. In the present study, we have continued to clarify the role of Runx2 in tooth development and searched for downstream targets of Runx2 by extensive in situ hybridization analysis. The expression of Fgf3 was downregulated in the mesenchyme of Runx2 mutant teeth. FGF-soaked beads failed to induce Fgf3 expression in Runx2 mutant dental mesenchyme whereas in wild-type mesenchyme they induced Fgf3 in all explants indicating a requirement of Runx2 for transduction of FGF signals. Fgf3 was absent also in cultured Runx2-/- calvarial cells and it was induced by overexpression of Runx2. Furthermore, Runx2 was downregulated in Msx1 mutant tooth germs, indicating that it functions in the dental mesenchyme between Msx1 and Fgf3. Shh expression was absent from the epithelial enamel knot in lower molars of Runx2 mutant and reduced in upper molars. However, other enamel knot marker genes were expressed normally in mutant upper molars, while reduced or missing in lower molars. These differences between mutant upper and lower molars may be explained by the substitution of Runx2 function by Runx3, another member of the runt gene family that was upregulated in upper but not lower molars of Runx2 mutants. Shh expression in mutant enamel knots was not rescued by FGFs in vitro, indicating that in addition to Fgf3, Runx2 regulates other mesenchymal genes required for early tooth morphogenesis. Also, exogenous FGF and SHH did not rescue the morphogenesis of Runx2 mutant molars. We conclude that Runx2 mediates the functions of epithelial FGF signals regulating Fgf3 expression in the dental mesenchyme and that Fgf3 may be a direct target gene of Runx2. [Copyright &y& Elsevier]

Published

2004

41. Tooth Morphogenesis and Pattern of Odontoblast Differentiation.

Author

Lisi, S., Peterková, R., Peterka, M., Vonesch, J. L., Ruch, J. V., and Lesot, H.

Subjects

*CELL communication, *CELL differentiation, *MORPHOGENESIS, *TEETH, *DENTAL enamel

Abstract

The terminal differentiation of odontoblasts is controlled by the inner dental epithelium (IDE) and occurs according to a tooth-specific pattern. It requires temporospatially regulated epigenetic signaling and the expression of specific competence. The patterning of cusp formation was compared with that of odontoblast differentiation in the first lower molar in mice. Histology, immunostaining, and three dimensional reconstructions were completed by experimental approaches in vitro. The mesenchyme controls the pattern of cusp formation. During the cap-bell transition in the molar, a subpopulation of nondividing IDE cells from the enamel knot (EK) undergo a tooth-specific segregation in as many subpopulations as cusps will form. Epithelial cell-basement membrane interactions seem to be involved in the segregation of EK cells. The timing and spatial pattern of the segregation of EK cells correlate with cusps formation. However, the temporal pattern of odontoblast terminal differentiation is different. This discrepancy might result from cusp-specific differences either in the timing of the initiation of odontoblast terminal differentiation and/or in cell proliferation kinetics. [ABSTRACT FROM AUTHOR]

Published

2003

42. Lunatic Fringe, FGF, and BMP Regulate the Notch Pathway during Epithelial Morphogenesis of Teeth

Author

Mustonen, Tuija, Tümmers, Mark, Mikami, Tadahisa, Itoh, Nobuyuki, Zhang, Niang, Gridley, Thomas, and Thesleff, Irma

Subjects

*TEETH, *MORPHOGENESIS

Abstract

Teeth develop as epithelial appendages, and their morphogenesis is regulated by epithelial–mesenchymal interactions and conserved signaling pathways common to many developmental processes. A key event during tooth morphogenesis is the transition from bud to cap stage when the epithelial bud is divided into specific compartments distinguished by morphology as well as gene expression patterns. The enamel knot, a signaling center, forms and regulates the shape and size of the tooth. Mesenchymal signals are necessary for epithelial patterning and for the formation and maintenance of the epithelial compartments. We studied the expression of Notch pathway molecules during the bud-to-cap stage transition of the developing mouse tooth. Lunatic fringe expression was restricted to the epithelium, where it formed a boundary flanking the enamel knot. The Lunatic fringe expression domains overlapped only partly with the expression of Notch1 and Notch2, which were coexpressed with Hes1. We examined the regulation of Lunatic fringe and Hes1 in cultured explants of dental epithelium. The expression of Lunatic fringe and Hes1 depended on mesenchymal signals and both were positively regulated by FGF-10. BMP-4 antagonized the stimulatory effect of FGF-10 on Lunatic fringe expression but had a synergistic effect with FGF-10 on Hes1 expression. Recombinant Lunatic fringe protein induced Hes1 expression in the dental epithelium, suggesting that Lunatic fringe can act also extracellularly. Lunatic fringe mutant mice did not reveal tooth abnormalities, and no changes were observed in the expression patterns of other Fringe genes. We conclude that Lunatic fringe may play a role in boundary formation of the enamel knot and that Notch-signaling in the dental epithelium is regulated by mesenchymal FGFs and BMP. [Copyright &y& Elsevier]

Published

2002

43. Cell-Cell and Cell-Matrix Interactions During Initial Enamel Organ Histomorphogenesis in the Mouse.

Author

Lesot, H., Kieffer-Combeau, S., Fausser, J. L., Meyer, J. M., Perrin-Schmitt, F., Peterková, R., Peterka, M., and Ruch, J. V.

Subjects

*DENTITION, *TEETH, *DENTAL enamel, *EPITHELIUM, *MORPHOGENESIS

Abstract

Relationships between cell-cell/cell-matrix interactions and enamel organ histomorphogenesis were examined by immunostaining and electron microscopy. During the cap-bell transition in the mouse molar, laminin-5 (LN5) disappeared from the basement membrane (BM) associated with the inner dental epithelium (IDE), and nondividing IDE cells from the enamel knot (EK) underwent a tooth-specific segregation in as many subpopulations as cusps develop. In the incisor, the basement membrane (BM) in contact with EK cells showed strong staining for LN5 and integrin α6β4. LN5 seems to provide stable adhesion, while its proteolytic processing might facilitate cell segregation. In both teeth, immunostaining for antigens associated with desmosomes or adherens junctions was similar for EK cells and neighboring IDE cells. Outside the EK, IDE cell-BM interactions changed locally during the initial molar cusp delimitation and on the labial part of the incisor cervical loop. Conversely, cell-cell junctions stabilized the anterior part of the incisor during completion of morphogenesis. Time and space regulation of cell-matrix and cell-cell interactions might thus play complementary roles in allowing plasticity during tooth morphogenesis and stabilization at later stages of epithelial histogenesis. [ABSTRACT FROM AUTHOR]

Published

2002

44. Enamel Knots as Signaling Centers Linking Tooth Morphogenesis and Odontoblast Differentiation.

Author

Thesleff, Irma, Keranen, Soile, and Jernvall, Jukka

Subjects

DENTITION, DENTAL enamel, MESENCHYME, MORPHOGENESIS, EPITHELIUM, DENTAL research

Abstract

Odontoblasts differentiate from the cells of the dental papilla, and it has been well-established that their differentiation in developing teeth is induced by the dental epithelium. In experimental studies, no other mesenchymal cells have been shown to have the capacity to differentiate into odontoblasts, indicating that the dental papilla cells have been committed to odontoblast cell lineage during earlier developmental stages. We propose that the advancing differentiation within the odontoblast cell lineage is regulated by sequential epithelial signals. The first epithelial signals from the early oral ectoderm induce the odontogenic potential in the cranial neural crest cells. The next step in the determination of the odontogenic cell lineage is the development of the dental papilla from odontogenic mesenchyme. The formation of the dental papilla starts at the onset of the transition from the bud to the cap stage of tooth morphogenesis, and this is regulated by epithelial signals from the primary enamel knot. The primary enamel knot is a signaling center which forms at the tip of the epithelial tooth bud. It becomes fully developed and morphologically discernible in the cap-stage dental epithelium and expresses at least ten different signaling molecules belonging to the BMP, FGF, Hh, and Wnt families. In molar teeth, secondary enamel knots appear in the enamel epithelium at the sites of the future cusps. They also express several signaling molecules, and their formation precedes the folding and growth of the epithelium. The differentiation of odontoblasts always starts from the tips of the cusps, and therefore, it is conceivable that some of the signals expressed in the enamel knots may act as inducers of odontoblast differentiation. The functions of the different signals in enamel knots are not precisely known. We have shown that FGFs stimulate the proliferation of mesenchymal as well as epithelial cells, and they may also regulate the growth of the cusps. We have proposed that the enamel knot signals also have important roles, together with mesenchymal signals, in regulating the patterning of the cusps and hence the shape of the tooth crown. We suggest that the enamel knots are central regulators of tooth development, since they link cell differentiation to morphogenesis. [ABSTRACT FROM AUTHOR]

Published

2001

45. Six1 is required for signaling center formation and labial-lingual asymmetry in developing lower incisors

Author

Keiko Ikeda, Tetsushi Sakuma, Yoshiko Nakagawa, Takashi Yamamoto, Masanori Takahashi, Kiyoshi Kawakami, and Masaki Ohmuraya

Subjects

0301 basic medicine, Mesenchyme, Morphogenesis, Biology, 03 medical and health sciences, Mice, 0302 clinical medicine, stomatognathic system, Incisor, otorhinolaryngologic diseases, medicine, Animals, Homeodomain Proteins, Mice, Knockout, Enamel paint, Odontoblasts, Gene Expression Regulation, Developmental, Tooth Germ, Enamel knot, Cell biology, stomatognathic diseases, 030104 developmental biology, Odontoblast, medicine.anatomical_structure, visual_art, visual_art.visual_art_medium, Homeobox, Odontogenesis, Ameloblast, 030217 neurology & neurosurgery, Developmental Biology, Signal Transduction

Abstract

Background The structure of the mouse incisor is characterized by its asymmetric accumulation of enamel matrix proteins on the labial side. The asymmetric structure originates from the patterning of the epithelial incisor placode through the interaction with dental mesenchymal cells. However, the molecular basis for the asymmetric patterning of the incisor germ is largely unknown. Results A homeobox transcription factor SIX1 was shown to be produced in the mandibular mesenchyme, and its localization patterns changed dynamically during lower incisor development. Six1-/- mice exhibited smaller lower incisor primordia than wild-type mice. Furthermore, Six1-/- mice showed enamel matrix production on both the lingual and labial sides and disturbed odontoblast maturation. In the earlier stages of development, the formation of signaling centers, the initiation knot and the enamel knot, which are essential for the morphogenesis of tooth germs, were impaired in Six1-/- embryos. Notably, Wnt signaling activity, which shows an anterior-posterior gradient, and the expression patterns of genes involved in incisor formation were altered in the mesenchyme in Six1-/- embryos. Conclusion Our results indicate that Six1 is required for signaling center formation in lower incisor germs and the labial-lingual asymmetry of the lower incisors by regulating the anterior-posterior patterning of the mandibular mesenchyme.

Published

2019

46. Mesenchymal Sufu Regulates Development of Mandibular Molars via Shh Signaling

Author

Jianfeng Li, Zunyi Zhang, Mengsheng Qiu, B. Wang, Jiayun Xu, Lei Wang, Xiaoyun Zhang, Qihui Wang, and Ying Cui

Subjects

0301 basic medicine, animal structures, Mesenchyme, Morphogenesis, Mesoderm, 03 medical and health sciences, Mice, 0302 clinical medicine, stomatognathic system, GLI1, FGF4, medicine, Animals, Hedgehog Proteins, Sonic hedgehog, General Dentistry, biology, Gene Expression Regulation, Developmental, 030206 dentistry, Molar, Enamel knot, Cell biology, RUNX2, Repressor Proteins, stomatognathic diseases, 030104 developmental biology, medicine.anatomical_structure, embryonic structures, biology.protein, Odontogenesis, Signal transduction, Signal Transduction

Abstract

Sonic hedgehog ( Shh) in dental epithelium regulates tooth morphogenesis by epithelial-mesenchymal signaling transduction. However, the action of Shh signaling regulation in this process is not well understood. Here we find that mesenchymal Suppressor of Fused ( Sufu), a major negative regulator of Shh signaling, plays an important role in modulating the tooth germ morphogenesis during the bud-to-cap stage transition. Deletion of Sufu in dental mesenchyme by Dermo1-Cre mice leads to delayed development of mandibular molar into cap stage with defect of primary enamel knot (EK) formation. We show the disruption of cell proliferation and programmed cell death in dental epithelium and mesenchyme in Sufu mutants. Epithelial-specific adhesion molecule E-cadherin is evidently reduced in the bilateral basal cells of tooth germ at E14.5. The cells in the presumptive EK, predominantly expressing P-cadherin, appear stratified but fail to condense. Moreover, the transcripts of primary EK marker genes, including Shh, Fgf4, and p21, are significantly decreased compared to controls. In contrast, we find that deficiency of Sufu results in elevation of Shh signaling in mesenchyme, indicated by the significant upregulation of Gli1 and Ptch1. Meanwhile, the expression of Bmp4 and Fgf3, the critical factors of mesenchymal-epithelial induction, is significantly inhibited in dental mesenchyme. Furthermore, the expression of Runx2 experiences a transient decrease at the bud stage. Taken together, these data suggest that mesenchymal Sufu is necessary for tuning the Shh signaling, which may act as an upstream modulator of Bmp4 and Fgf3 to coordinate the interplay between the dental mesenchyme and epithelium of tooth germ.

Published

2019

47. Ectodermal and ectomesenchymal marker expression in primary cell lines of complex and compound odontomas: a pilot study

Author

Bogdan R Navarro-Bustos, Javier Portilla-Robertson, Luis Fernando Jacinto-Alemán, Elba Rosa Leyva-Huerta, and David A. Trejo-Remigio

Subjects

Pathology, medicine.medical_specialty, Immunocytochemistry, Pilot Projects, Biology, Cell Line, 03 medical and health sciences, 0302 clinical medicine, Odontoma, Dental Enamel Proteins, stomatognathic system, medicine, Humans, AMBN, Complex Odontoma, Compound Odontoma, 030206 dentistry, medicine.disease, Jaw Neoplasms, Enamel knot, stomatognathic diseases, Otorhinolaryngology, Immunohistochemistry, Surgery, Oral Surgery, PAX9, Biomarkers, 030217 neurology & neurosurgery

Abstract

BACKGROUND Odontomas are odontogenic tumors with hamartoma features that are classified as compound or complex. Our objective was to characterize the proliferation of ectodermal and ectomesenchymal profile markers of primary cell cultures of complex and compound odontomas. METHODS Four samples of compound odontomas (OdCm) and three of complex odontomas (OdCx) were obtained from patients attending the Oral Pathology and Medicine Clinic of the Graduate Dental School, National Autonomous University of Mexico for primary culture generation. MTT, immunocytochemistry and RT-PCR assays of CD34, Sox2, Amel, Ambn, p21, EDAR, Msx1, Msx2, Pax9, RUNX2, BSP, OPN, Barx1 and GAPDH (control) were performed. Additionally, six paraffin-embedded odontomas were obtained for immunocytochemistry and RT-PCR validation assays. The mean and standard deviation were determined, and ANOVA and Kruskall-Wallis tests were performed. RESULTS Cultured compound odontoma exhibited higher proliferation, and an ectomesenchymal immunocytochemistry profile with predominant expression of Amel, BSP, Pax9, EDAR, Barx and Msx2; in complex cultured odontoma Sox2, CD34, RUNX2 and OPN predominated. Our statistical analysis showed a significant difference in PCR analysis (P

Published

2019

48. Establishment of tooth blood supply and innervation is developmentally regulated and takes place through differential patterning processes

Author

Päivi Kettunen, Rajib Chaulagain, Omnia Shadad, and Keijo Luukko

Subjects

0301 basic medicine, Vascular Endothelial Growth Factor A, Histology, Mesenchyme, In situ hybridization, Biology, Muscle, Smooth, Vascular, 03 medical and health sciences, chemistry.chemical_compound, Mice, 0302 clinical medicine, stomatognathic system, medicine, Animals, Dental papilla, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Body Patterning, Plexus, Enamel organ, Gene Expression Regulation, Developmental, Tooth Germ, Cell Biology, Original Articles, Vascular Endothelial Growth Factor Receptor-2, Cell biology, Enamel knot, Vascular endothelial growth factor, stomatognathic diseases, 030104 developmental biology, medicine.anatomical_structure, chemistry, Blood Vessels, Odontogenesis, Anatomy, Tooth, 030217 neurology & neurosurgery, Developmental Biology, Blood vessel, Signal Transduction

Abstract

Teeth are richly supported by blood vessels and peripheral nerves. The aim of this study was to describe in detail the developmental time-course and localization of blood vessels during early tooth formation and to compare that to innervation, as well as to address the putative role of vascular endothelial growth factor (VEGF), which is an essential regulator of vasculature development, in this process. The localization of blood vessels and neurites was compared using double immunofluorescence staining on sections at consecutive stages of the embryonic (E) and postnatal (PN) mandibular first molar tooth germ (E11-PN7). Cellular mRNA expression domains of VEGF and its signaling receptor VEGFR2 were studied using sectional radioactive in situ hybridization. Expression of VEGF mRNA and the encoded protein were studied by RT-PCR and western blot analysis, respectively, in the cap and early bell stage tooth germs, respectively. VEGFR2 was immunolocalized on tooth tissue sections. Smooth muscle cells were investigated by anti-alpha smooth muscle actin (αSMA) antibodies. VEGF showed developmentally regulated epithelial and mesenchymal mRNA expression domains including the enamel knot signaling centers that correlated with the growth and navigation of the blood vessels expressing Vegfr2 and VEGFR2 to the dental papilla and enamel organ. Developing blood vessels were present in the jaw mesenchyme including the presumptive dental mesenchyme before the appearance of the epithelial dental placode and dental neurites. Similarly, formation of a blood vessel plexus around the bud stage tooth germ and ingrowth of vessels into dental papilla at E14 preceded ingrowth of neurites. Subsequently, pioneer blood vessels in the dental papilla started to receive smooth muscle coverage at the early embryonic bell stage. Establishment and patterning of the blood vessels and nerves during tooth formation are developmentally regulated, stepwise processes that likely involve differential patterning mechanisms. Development of tooth vascular supply is proposed to be regulated by local, tooth-specific regulation by epithelial-mesenchymal tissue interactions and involving tooth target expressed VEGF signaling. Further investigations on tooth vascular development by local VEGF signaling, as well as how tooth innervation and development of blood vessels are integrated with advancing tooth organ formation by local signaling mechanisms, are warranted.

Published

2019

49. Expression pattern of transcriptional enhanced associate domain family member 1 (Tead1) in developing mouse molar tooth

Author

Yukiho Kobayashi, Keiji Moriyama, and Yuki Niki

Subjects

Biology, Mice, 03 medical and health sciences, 0302 clinical medicine, stomatognathic system, Genetics, medicine, Animals, Dental Enamel, Molecular Biology, TEAD1, Adaptor Proteins, Signal Transducing, 030304 developmental biology, 0303 health sciences, Hippo signaling pathway, Outer enamel epithelium, Connective Tissue Growth Factor, TEA Domain Transcription Factors, Epithelial Cells, Mesenchymal Stem Cells, YAP-Signaling Proteins, Molar, Dental lamina, Epithelium, Cell biology, Enamel knot, Mice, Inbred C57BL, CTGF, stomatognathic diseases, medicine.anatomical_structure, Hippo signaling, Female, 030217 neurology & neurosurgery, Developmental Biology

Abstract

The Hippo pathway is essential for determining organ size by regulating cell proliferation. Previous reports have shown that impairing this pathway causes abnormal tooth development. However, the precise expression profile of the members of the transcriptional enhanced associate domain family (Tead), which are key transcription factors mediating Yap function, during tooth development is unclear. In this study, among the four isoforms of Tead (Tead1 - 4), only the expression of Tead1 mRNA was observed using semiquantitative RT- PCR in murine developing tooth germ at E16.5. The expression level of Tead1 mRNA in the excised murine mandibular molar tooth germ was significantly higher at E16.5 than at other developmental stages, as determined using quantitative PCR. We found that the mRNA expression of connective tissue growth factor (Ctgf), which is one of the Yap target genes directly controlling cell growth, changed consistently with that of Tead1 in developing molars. Fluorescent immunostaining revealed that Tead1 protein was expressed in both epithelial cells and mesenchymal cells of the dental lamina and dental epithelium, including the primary enamel knot during the cap stage. During the early bell stage (E16.5), Tead1 was expressed intensely in the inner and outer enamel epithelium, including the secondary enamel knot and the neighboring mesenchymal cells. Tead1 then specifically localized to the inner and outer enamel epithelium, which is responsible for enamel formation during the bell stage. These expression patterns were consistent with those of Yap, Taz, and Ctgf protein in developing molars. These results suggest that Tead1 acts as a mediator of the biological functions of Yap, such as the morphogenesis of cusp formation, during tooth development.

Published

2021

50. The Patterning Cascade Model and Carabelli's trait expression in metameres of the mixed human dentition: exploring a morphogenetic model

Author

Claudia M. Astorino, Kathleen S. Paul, and Shara E. Bailey

Subjects

0301 basic medicine, Molar, Wilcoxon signed-rank test, Dentistry, Biology, Logistic regression, Models, Biological, Anthropology, Physical, 03 medical and health sciences, 0302 clinical medicine, stomatognathic system, Dentition, Humans, Child, Tooth Crown, business.industry, 030206 dentistry, Trait expression, Enamel knot, 030104 developmental biology, Sample size determination, Evolutionary biology, Child, Preschool, Anthropology, Cusp (anatomy), Anatomy, business, Tooth

Abstract

Objectives The Patterning Cascade Model (PCM) provides an evolutionary developmental framework for exploring diversity in tooth crown form. According to the model, proximity of secondary enamel knots and tooth germ size track underlying developmental processes that dictate ultimate crown morphology (i.e., cusp number, accessory cusp presence/size). Previous research has shown the model to successfully predict variation in Carabelli's trait expression between antimeric and metameric pairs of human permanent molars. In this study, we quantify Carabelli's trait expression for metameres of the mixed dentition (dm2 and M1) and assess the PCM's potential for explaining differences in expression between the two elements. Materials and methods Crown dimensions, intercusp distances, and Carabelli's trait expression were collected from 49 subadults possessing observable dm2/M1 pairs. Wilcoxon signed-rank tests and paired t-tests were performed to assess whether metameres differ significantly in morphometric variables. We explored the relationships between relative intercusp distances (RICDs) and Carabelli's trait expression using proportional odds logistic regression. Results Intra-individual dm2/M1 pairs differed significantly in Carabelli's trait expression (p = 0.01), with dm2 exhibiting higher grades of expression more commonly despite its smaller crown size. Paired molars differed in only one statistically significant RICD: metacone-hypocone (p

Published

2016