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Primary cilia regulate Shh activity in the control of molar tooth number - PubMed

️Mon Apr 07 0223

. 2009 Mar;136(6):897-903.

doi: 10.1242/dev.027979. Epub 2009 Feb 11.

Courtney J Haycraft, Maisa Seppala, James Blackburn, Sarah Ghafoor, Martyn Cobourne, David C Martinelli, Chen-Ming Fan, Renata Peterkova, Herve Lesot, Bradley K Yoder, Paul T Sharpe

Affiliations

PMID: 19211681
PMCID: PMC2727556
DOI: 10.1242/dev.027979

Primary cilia regulate Shh activity in the control of molar tooth number

Atsushi Ohazama et al. Development. 2009 Mar.

Abstract

Primary cilia mediate Hh signalling and mutations in their protein components affect Hh activity. We show that in mice mutant for a cilia intraflagellar transport (IFT) protein, IFT88/polaris, Shh activity is increased in the toothless diastema mesenchyme of the embryonic jaw primordia. This results in the formation of ectopic teeth in the diastema, mesial to the first molars. This phenotype is specific to loss of polaris activity in the mesenchyme since loss of Polaris in the epithelium has no detrimental affect on tooth development. To further confirm that upregulation of Shh activity is responsible for the ectopic tooth formation, we analysed mice mutant for Gas1, a Shh protein antagonist in diastema mesenchyme. Gas1 mutants also had ectopic diastema teeth and accompanying increased Shh activity. In this context, therefore, primary cilia exert a specific negative regulatory effect on Shh activity that functions to repress tooth formation and thus determine tooth number. Strikingly, the ectopic teeth adopt a size and shape characteristic of premolars, a tooth type that was lost in mice around 50-100 million years ago.

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Figures

**Fig. 1.**
**Lower molar tooth phenotypes and *Shh* signalling in *Tg737^orpk* homozygous mutant mice.** (**A-D**) Whole teeth (A,B) and sagittal sections (C,D) show that supernumerary teeth develop mesial to the first molars (sn in B,D) in mutants. (E,F) Increase of Ptch1-*lacZ* staining in the mandible of *Tg737^orpk* mutants with Ptch1-*lacZ* allele at E13.5. Ptch1-*lacZ* staining was expanded into the diastema region (arrowhead). Arrows indicate molar germs. (**G-J**) Radioactive in situ hybridisation on sagittal sections showing *Gli1* (G,H), *Gas1* (I,J) and *Shh* (G',H',I',J') expression in mandibles of embryo heads at E12.5. (G,H,I,J) Yellow circles represent positions of *Shh* expression in adjacent sections (blue arrowheads in G',H',I',J'). *Gli1* expression (H) was expanded into the diastema and *Gas1* (J) was downregulated in the diastema of *Tg737^orpk* mutants (green arrowheads). (**K-N**) Sagittal sections (N) and three-dimensional reconstructions (K-M) of the dental epithelium of the mandible molar region at E15.5 (N) and E16.5 (K-M) in *Tg737^orpk* mutants. The supernumerary tooth buds (arrows in K-M) were observed in the position of the mesial swellings (arrowhead in N). (**O-T**) SEM analysis shows that the lingual cusp of maxillary supernumerary tooth (red line in T) is more prominent in comparison with that of mandibular supernumerary tooth (red line in S). (U,V) Horizontal micro-CT sections of *Tg737^orpk* show that maxillary supernumerary teeth have concave roots (circle in V) and in mandibles show round roots (circle in U). m1, first molar; m2, second molar; m3, third molar; mand, mandible jaw; max, maxillary jaw.

**Fig. 2.**
**Cilia, and Tg737 expression and localisation in tooth germs.** (**A-C**) Acetylated α-tubulin-positive cells (immunohistochemistry) are found in both tooth epithelium and mesenchyme of wild type (A,B). There are no significant differences between wild-type and *Tg737^orpk* mice, or between first molar (m1) and supernumerary tooth (sn) in *Tg737^orpk* mice (C). (D,E) γ-Tubulin-positive cells are observed in both tooth epithelium and mesenchyme of wild-type (D) and *Tg737^orpk* mice (E). (**F-I**) TEM analysis of molar teeth show that cilia were found in both epithelium (G) and mesenchyme (F) of molar tooth germs in wild-type (F,G) and in molar tooth epithelium (H) and mesenchyme (I) in *Tg737^orpk* (arrows). (J,K) β-Gal expression in molar of *Tg737*^Δ*^2-3*^β*^-gal* show that Tg737 was expressed in both epithelium and mesenchyme. (L,M) Immunohistochemistry sections also show that polaris protein is localised in both dental epithelium (DE) and dental mesenchyme (DM). Frontal sections (A,B,D-J,L,M) and sagittal sections (C,K) of lower molars at E10.5 (A), E13.5 (B,D-J,L), E14.5 (C), E16.5 (M) and E18.5 (K) of wild-type littermates (A,B,D,F,G,J-M) and *Tg737^orpk* mutants (C,E,H,I). Dots represent boundaries between epithelium and mesenchyme (A,M). Tooth epithelium is outlined in red (B-E) or green (L). Nuclei are shown in blue by DAPI (A'-E',L,M).

**Fig. 3.**
**Molar teeth of K5-Cre/polaris^flox/flox mice and Wnt1-Cre/polaris^flox/flox mice.** (A,B) There are no supernumerary teeth in K5Cre (A) and K5-Cre/polaris^flox/flox (B) mice. (C) Sagittal sections showing first molar (m1) and second molar (m2) in mandible. (D) Supernumerary teeth (sn) were observed in Wnt1-Cre/polaris^flox/flox mice. (**E-F**′) Radioactive in situ hybridisation on sagittal sections showing *Gli1* (E,F) and *Shh* (E',F') expression in mandibles of embryo heads. (E,F) Yellow circles represent positions of *Shh* expression in adjacent sections (blue arrowheads in E',F'). *Gli1* expression (E,F) was expanded into the diastema of Wnt1-Cre/Polaris^flox/flox mice (green arrowheads). Images show lower mandibles of E11.5 (E-F'), newborn (C,D) and adult (A,B).

**Fig. 4.**
**Molar tooth phenotypes of *Gas1* mutant mice.** (**A-F**) Sagittal sections (A-D) and micro-CT analysis (E,F) show that supernumerary teeth develop mesial to the first molars (sn in C,F). Micro-CT analysis showed that supernumerary teeth were smaller than first molars and had fewer cusps (F). At the section level of the second molar, the supernumerary teeth were not visible (D). (G,H) Radioactive in situ hybridisation on sagittal sections, showing *Gas1* expression in mandibles of embryo heads at E13.5. *Gas1* was expressed in the diastema region (arrowheads), whereas it was absent in tooth regions (incisor in G; molar in H). (I,J) Whole-mount in situ hybridisation showing *Ptch1* expression in the mandibular process of embryo heads at E12.5. *Ptch1* expression was expanded into the diastema region in *Gas1* mutants (arrowheads in J). (K,L) Radioactive in situ hybridisation on sagittal sections showing *Gli1* expression in mandibles of embryo heads at E14.5. *Gli1* expression was expanded into the diastema region of *Gas1* mice (arrowhead in L). (N,P,R) Radioactive in situ hybridisation on sagittal sections showing *Shh* expression in maxillae of embryo heads at E14.5. *Shh* expression was found in both supernumerary (sn in R) and the first molars in *Gas1* mutants (m1 in P). (M,O,Q) Haematoxylin and Eosin stained sections adjacent to N, P and R, respectively. Shh expression could not be seen in the first molar at the section level of the supernumerary tooth (R). (**S-U**) Immunohistochemistry on sagittal sections showing Shh protein localisation in mandibles of embryo heads at E12.5. Shh localisation was found in the diastema region of *Gas1* mice (between arrowheads in U), as well as endogenous tooth germs (arrowheads in T); it was not observed in the diastema of wild type (between arrowheads in S). Shh protein deposition could not be seen in the incisors and molars at the section level of the diastema showing Shh expression (U). m1, first molar; m2, second molar; sn, supernumerary tooth. Lingual cusps (L1-L3) and extra cusp (ec). Scale bar: 500 μm.

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Primary cilia regulate Shh activity in the control of molar tooth number - PubMed

Primary cilia regulate Shh activity in the control of molar tooth number

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