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Abstract

Functional tooth germs in mammals, reptiles, and chondrichthyans are initiated from a dental lamina. The longevity of the lamina plays a role in governing the number of tooth generations. Monophyodont species have no replacement dental lamina, while polyphyodont species have a permanent continuous lamina. In diphyodont species, the dental lamina fragments and regresses after initiation of the second tooth generation. Regression of the lamina seems to be an important mechanism in preventing the further development of replacement teeth. Defects in the complete removal of the lamina lead to cyst formation and has been linked to ameloblastomas. Here, we show the previously unknown mechanisms behind the disappearance of the dental lamina, involving a combination of cell migration, cell-fate transformation, and apoptosis. Lamina regression starts with the loss of the basement membrane, allowing the epithelial cells to break away from the lamina and migrate into the surrounding mesenchyme. Cells deactivate epithelial markers (E-cadherin, cytokeratin), up-regulate Slug and MMP2, and activate mesenchymal markers (vimentin), while residual lamina cells are removed by apoptosis. The uncovering of the processes behind lamina degradation allows us to clarify the evolution of diphyodonty, and provides a mechanism for future manipulation of the number of tooth generations.

Keywords

developmental biology dental morphology tooth development odontogenesis apoptosis epithelial-mesenchymal interactions

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References

Ahlstrom

Erickson

(2009). The neural crest epithelial-mesenchymal transition in 4D: a ‘tail’ of multiple non-obligatory cellular mechanisms. Development 136:1801-1812.

Baum

Settleman

Quinlan

(2008). Transitions between epithelial and mesenchymal states in development and disease. Semin Cell Dev Biol 19:294-308.

Boyer

Erickson

Runyan

(1999). Epithelial-mesenchymal transformation in the embryonic heart is mediated through distinct pertussis toxin-sensitive and TGFbeta signal transduction mechanisms. Dev Dyn 214:81-91.

Boyer

Tucker

Valles

Franke

Thiery

(1989). Rearrangements of desmosomal and cytoskeletal proteins during the transition from epithelial to fibroblastoid organization in cultured rat bladder carcinoma cells. J Cell Biol 109(4 Pt 1):1495-1509.

Buchtová

Handrigan

Tucker

Lozanoff

Town

. (2008). Initiation and patterning of the snake dentition are dependent on Sonic hedgehog signaling. Dev Biol 319:132-145.

Eversole

(1999). Malignant epithelial odontogenic tumors. Semin Diagn Pathol 16:317-324.

Fejerskov

(1972). Excision wounds in palatal epithelium in guinea pigs. Scand J Dent Res 80:139-154.

Franke

Grund

Kuhn

Jackson

Illmensee

(1982). Formation of cytoskeletal elements during mouse embryogenesis. III. Primary mesenchymal cells and the first appearance of vimentin filaments. Differentiation 23:43-59.

Fraser

Smith

(2011). Evolution of developmental pattern for vertebrate dentitions: an oro-pharyngeal specific mechanism. J Exp Zool B Mol Dev Evol 316(B):99-112.

10.

Handrigan

Richman

(2010). A network of Wnt, hedgehog and BMP signaling pathways regulates tooth replacement in snakes. Dev Biol 348:130-141.

11.

Hatakeyama

Tomichi

Ohara-Nemoto

Satoh

(2000). The immunohistochemical localization of Fas and Fas ligand in jaw bone and tooth germ of human fetuses. Calcif Tissue Int 66:330-337.

12.

Huang

Gronthos

Shi

(2009). Mesenchymal stem cells derived from dental tissues vs. those from other sources: their biology and role in regenerative medicine. J Dent Res 88:792-806.

13.

Ivaska

(2011). Vimentin: central hub in EMT induction? Small GTPases 2:51-53.

14.

Jarvinen

Salazar-Ciudad

Birchmeier

Taketo

Jernvall

Thesleff

(2006). Continuous tooth generation in mouse is induced by activated epithelial Wnt/beta-catenin signaling. Proc Natl Acad Sci USA 103:18627-18632.

15.

Jarvinen

Tummers

Thesleff

(2009). The role of the dental lamina in mammalian tooth replacement. J Exp Zool B Mol Dev Evol 312(B):281-291.

16.

Jin

Ding

(2006). Analysis of cell migration, transdifferentiation and apoptosis during mouse secondary palate fusion. Development 133:3341-3347.

17.

Karafiat

Dvorakova

Krejci

Kralova

Pajer

Snajdr

. (2005). Transcription factor c-Myb is involved in the regulation of the epithelial-mesenchymal transition in the avian neural crest. Cell Mol Life Sci 62:2516-2525.

18.

Kindaichi

(1980). An electron microscopic study of cell death in molar tooth germ epithelia of mouse embryos. Arch Histol Jpn 43:289-304.

19.

Matalova

Antonarakis

Sharpe

Tucker

(2005). Cell lineage of primary and secondary enamel knots. Dev Dyn 233:754-759.

20.

Matalova

Fleischmannova

Sharpe

Tucker

(2008). Tooth agenesis: from molecular genetics to molecular dentistry. J Dent Res 87:617-623.

21.

Moskow

Bloom

(1983). Embryogenesis of the gingival cyst. J Clin Periodontol 10:119-130.

22.

Prindull

Zipori

(2004). Environmental guidance of normal and tumor cell plasticity: epithelial mesenchymal transitions as a paradigm. Blood 103:2892-2899.

23.

Sasaki

Sato

Kozawa

(2001). Apoptosis in regressive deciduous tooth germs of Suncus murinus evaluated by the the TUNEL method and electron microscopy. Arch Oral Biol 46:649-660.

24.

Stembirek

Buchtová

Kral

Matalova

Lozanoff

Misek

(2010). Early morphogenesis of heterodont dentition in minipigs. Eur J Oral Sci 118:547-558.

25.

Suzuki

Inoue

Shimono

Yamada

(2002). Behavior of epithelial root sheath during tooth root formation in porcine molars: TUNEL, TEM, and immunohistochemical studies. Anat Embryol (Berl) 206:13-20.

26.

Thiery

Acloque

Huang

Nieto

(2009). Epithelial-mesenchymal transitions in development and disease. Cell 139:871-890.

27.

Vaahtokari

Åberg

Thesleff

(1996). Apoptosis in the developing tooth: association with an embryonic signaling center and suppression by EGF and FGF-4. Development 122:121-129.

28.

Zeichner-David

Oishi

Zakartchenko

Chen

Arzate

. (2003). Role of Hertwig’s epithelial root sheath cells in tooth root development. Dev Dyn 228:651-663.

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Early Regression of the Dental Lamina Underlies the Development of Diphyodont Dentitions

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