Splitting placodes: effects of bone morphogenetic protein and Activin on the patterning and identity of mouse incisors

• Published in: Evolution & development Vol. 12; no. 4; pp. 383 - 392
• Main Authors: Munne, Pauliina M, Felszeghy, Szabolcs, Jussila, Maria, Suomalainen, Marika, Thesleff, Irma, Jernvall, Jukka
• Format: Journal Article
• Language: English
• Published: Malden, USA Malden, USA : Blackwell Publishing Inc 01.07.2010; Blackwell Publishing Inc; Blackwell Publishing Ltd
• Subjects: Activins - genetics; Activins - metabolism; Activins - physiology; Animals; Body Patterning; Bone Morphogenetic Proteins - genetics; Bone Morphogenetic Proteins - metabolism; Bone Morphogenetic Proteins - physiology; Carrier Proteins - metabolism; Embryo, Mammalian - metabolism; Embryonic Development; Evolutionary biology; Follistatin - metabolism; Follistatin - physiology; Incisor - anatomy & histology; Incisor - embryology; Mammals; Mice; Proteins; Rodents; Signal Transduction
• ISSN: 1520-541X; 1525-142X
• DOI: 10.1111/j.1525-142X.2010.00425.x

The single large rodent incisor in each jaw quadrant is evolutionarily derived from a mammalian ancestor with many small incisors. The embryonic placode giving rise to the mouse incisor is considerably larger than the molar placode, and the question remains whether this large incisor placode is a developmental requisite to make a thick incisor. Here we used in vitro culture system to experiment with the molecular mechanism regulating tooth placode development and how mice have thick incisors. We found that large placodes are prone to disintegration and formation of two to three small incisor placodes. The balance between one large or multiple small placodes was altered through the regulation of bone morphogenetic protein (BMP) and Activin signaling. Exogenous Noggin, which inhibits BMP signaling, or exogenous Activin cause the development of two to three incisors. These incisors were more slender than normal incisors. Additionally, two inhibitor molecules, Sostdc1 and Follistatin, which regulate the effects of BMPs and Activin and have opposite expression patterns, are likely to be involved in the incisor placode regulation in vivo. Furthermore, inhibition of BMPs by recombinant Noggin has been previously suggested to cause a change in the tooth identity from the incisor to the molar. This evidence has been used to support a homeobox code in determining tooth identity. Our work provides an alternative interpretation, where the inhibition of BMP signaling can lead to splitting of the large incisor placode and the formation of partly separate incisors, thereby acquiring molar-like morphology without a change in tooth identity.