Johanna Laurikkala scite author profile

Heterozygous germline mutations in p63, a transcription factor of the p53 family, result in abnormal morphogenesis of the skin and its associated structures, including hair follicles and teeth. In mice lacking p63, all ectodermal organs fail to develop, and stratification of the epidermis is absent. We show that the ectodermal placodes that mark early tooth and hair follicle morphogenesis do not form in p63-deficient embryos, although the multilayered dental lamina that precedes tooth placode formation develops normally. The N-terminally truncated isoform of p63 (⌬Np63) was expressed at high levels in embryonic ectoderm at all stages of tooth and hair development, and it was already dominant over the transactivating TAp63 isoform prior to epidermal stratification. Bmp7, Fgfr2b, Jag1 and Notch1 transcripts were co-expressed with ⌬Np63 in wild-type embryos, but were not detectable in the ectoderm of p63 mutants. In addition, ␤-catenin and Edar transcripts were significantly reduced in skin ectoderm. We also demonstrate that BMP2, BMP7 and FGF10 are potent inducers of p63 in cultured tissue explants. Hence, we suggest that p63 regulates the morphogenesis of surface ectoderm and its derivatives via multiple signalling pathways.

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Identification of a secreted BMP antagonist, ectodin, integrating BMP, FGF, and SHH signals from the tooth enamel knot

Laurikkala

Kassai

Pakkasjärvi

et al. 2003

Developmental Biology

240

222

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We have identified mouse and human cDNAs encoding a novel secreted BMP inhibitor, which we have named ectodin. It is most homologous (approximately 37% amino acid identity) to sclerostin that is a secreted BMP antagonist. Recombinant ectodin protein produced in cultured cells was efficiently secreted as a antagonist. Ectodin inhibited the activity of BMP2, BMP4, BMP6, and BMP7 for mouse preosteoblastic MC3T3-E1 cells, and bound to these BMPs with high affinity. Ectodin is intensely expressed in developing ectodermal organs, including teeth, vibrissae, and hair follicles. However, it is absent from the hair placodes and from the enamel knot signaling centers in teeth. In addition, several cell layers surrounding the enamel knots were completely devoid of ectodin transcripts. We analyzed the regulation and function of ectodin in tooth germs. Recombinant ectodin protein antagonized the BMP-mediated induction of Msx2 expression in cultured tooth explants, indicating that ectodin is a secreted BMP inhibitor. BMP2 and BMP7 stimulated ectodin expression in tooth explants, showing that it is part of a feedback mechanism controlling the activity of BMPs. The stimulation of ectodin expression by BMP was prevented by SHH and FGF4 but not by Wnt6. Hence, the feedback mechanism whereby BMPs upregulate their own inhibitor is counteracted by signals coexpressed with BMPs in the enamel knot. We conclude that ectodin is a novel BMP inhibitor which integrates BMP signaling with the SHH and FGF signal pathways and contributes in defining the exact spatiotemporal domain of BMP target field around the ectodermal signaling centers.

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Associations of FGF-3 and FGF-10 with signaling networks regulating tooth morphogenesis

Kettunen¹,

Laurikkala²,

Itäranta³

et al. 2000

Dev. Dyn.

240

218

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The morphogenesis and cell differentiation in developing teeth is governed by interactions between the oral epithelium and neural crest‐derived ectomesenchyme. The fibroblast growth factors FGF‐4, ‐8, and ‐9 have been implicated as epithelial signals regulating mesenchymal gene expression and cell proliferation during tooth initiation and later during epithelial folding morphogenesis and the establishment of tooth shape. To further evaluate the roles of FGFs in tooth development, we analyzed the roles of FGF‐3, FGF‐7, and FGF‐10 in developing mouse teeth. In situ hybridization analysis showed developmentally regulated expression during tooth formation for Fgf‐3 and Fgf‐10 that was mainly restricted to the dental papilla mesenchymal cells. Fgf‐7 transcripts were restricted to the developing bone surrounding the developing tooth germ. Fgf‐10 expression was observed in the presumptive dental epithelium and mesenchyme during tooth initiation, whereas Fgf‐3 expression appeared in the dental mesenchyme at the late bud stage. During the cap and bell stage, both Fgf‐3 and Fgf‐10 were intensely expressed in the dental papilla mesenchymal cells both in incisors and molars. It is of interest that Fgf‐3 expression was also observed in the primary enamel knot, a putative signaling center of the tooth, whereas no transcripts were seen in the secondary enamel knots that appear in the tips of future cusps of the bell stage tooth germs. Down‐regulation of Fgf‐3 and Fgf‐10 expression in postmitotic odontoblasts correlated with the terminal differentiation of the odontoblasts and the neighboring ameloblasts. In the incisors, mesenchymal cells of the cervical loop area showed partially overlapping expression patterns for all studied Fgfs. In vitro analyses showed that expression of Fgf‐3 and Fgf‐10 in the dental mesenchyme was dependent on dental epithelium and that epithelially expressed FGFs, FGF‐4 and ‐8 induced Fgf‐3 but not Fgf‐10 expression in the isolated dental mesenchyme. Beads soaked in Shh, BMP‐2, and TGF‐β1 protein did not induce either Fgf‐3 or Fgf‐10 expression. Cells expressing Wnt‐6 did not induce Fgf‐10 expression. Furthermore, FGF‐10 protein stimulated cell proliferation in the dental epithelium but not in the mesenchyme. These results suggest that FGF‐3 and FGF‐10 have redundant functions as mesenchymal signals regulating epithelial morphogenesis of the tooth and that their expressions appear to be differentially regulated. In addition, FGF‐3 may participate in signaling functions of the primary enamel knot. The dynamic expression patterns of different Fgfs in dental epithelium and mesenchyme and their interactions suggest existence of regulatory signaling cascades between epithelial and mesenchymal FGFs during tooth development. © 2000 Wiley‐Liss, Inc.

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