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J. Biol. Chem., Vol. 281, Issue 27, 18363-18369, July 7, 2006

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Functional Consequences of Interactions between Pax9 and Msx1 Genes in Normal and Abnormal Tooth Development^*

Takuya Ogawa, Hitesh Kapadia, Jian Q. Feng^¶, Rajendra Raghow^||1, Heiko Peters^**, and Rena N. D'Souza²

From the Department of Orthodontics, University of Texas Health Science Center at Houston-Dental Branch, Houston, Texas 77030, the Program in Genes and Development, Graduate School of Biomedical Sciences (GSBS), University of Texas Health Science Center and M.D. Anderson Cancer Center, Houston, Texas 77030, the ^¶Department of Oral Biology, School of Dentistry, University of Missouri-Kansas City, Kansas City, Missouri 64108, the ^||Department of Pharmacology, University of Tennessee Health Science Center and Department of Veterans Affairs Medical Center, Memphis, Tennessee 38104, the ^**Institute of Human Genetics, University of Newcastle, International Centre for Life, Central Parkway, Newcastle upon Tyne, NE1 3BZ, United Kingdom, and the Department of Biomedical Sciences, Baylor College of Dentistry, Dallas, Texas 75246

Received for publication, February 17, 2006

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Pax9 and Msx1 encode transcription factors that are known to be essential for the switch in odontogenic potential from the epithelium to the mesenchyme. Multiple lines of evidence suggest that these molecules play an important role in the maintenance of mesenchymal Bmp4 expression, which ultimately drives morphogenesis of the dental organ. Here we demonstrate that Pax9 is able to directly regulate Msx1 expression and interact with Msx1 at the protein level to enhance its ability to transactivate Msx1 and Bmp4 expression during tooth development. In addition, we tested how a missense mutation (T62C) in the paired domain of PAX9 that is responsible for human tooth agenesis (1) affects its functions. Our data indicate that although the mutant Pax9 protein (L21P) can bind to the Msx1 protein, it fails to transactivate the Msx1 and Bmp4 promoter, presumably because of its inability to bind cognate paired domain recognition sequences. In addition, synergistic transcriptional activation of the Bmp4 promoter was lost with coexpression of mutant Pax9 and wild-type Msx1. This suggests that Pax9 is critical for the regulation of Bmp4 expression through its paired domain rather than Msx1. Our findings demonstrate the partnership of Pax9 and Msx1 in a signaling pathway that involves Bmp4. Furthermore, the regulation of Bmp4 expression by the interaction of Pax9 with Msx1 at the level of transcription and through formation of a protein complex determines the fate of the transition from bud to cap stage during tooth development.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
The formation of mammalian dentition is a remarkable developmental process that provides a valuable model for studying genes that control three-dimensional patterning and morphogenesis. The genetic control of tooth development is underscored by the findings that mutations in genes that encode transcription factors involved in tooth signaling lead to tooth agenesis, a commonly inherited disorder in humans (hypodontia (MIM 106600 [OMIM] )). Tooth agenesis occurs in syndromic and nonsyndromic forms and is classified as a genetically and clinically heterogeneous condition affecting various combinations of teeth (2–4). The presence of inter- and intra-familial variability as it relates to the number and types of missing teeth also suggests that common variants in genes that are involved in tooth signaling may influence the background responsible for the phenotype. To date, several reports have described the association of dominant mutations in MSX1 and PAX9, two transcription factors that are expressed in dental mesenchyme (1, 3–11). More recently, AXIN2, a Wnt-signaling receptor was identified as responsible for a nonsyndromic form of tooth agenesis (12, 13). When compared with a fairly mixed pattern of tooth agenesis seen in individuals with a nonsense mutation in AXIN2, the phenotypes reported in MSX1 and PAX9 affected families are more restricted to posterior dentition. Although mutations in MSX1 contribute to a pattern that mainly involves premolars and more rarely molars, PAX9 mutations show a strong association with molar agenesis and sometimes premolars. In family members with PAX9 mutations the congenital absence of premolars in addition to molars may reflect a secondary down-regulation in MSX1 expression. This implies that PAX9 shares an upstream genetic epistasis with MSX1.

Studies of tooth development in mice also indicate a molecular relationship between Pax9 and Msx1. Both genes are coexpressed in dental mesenchyme and appear critical for tooth morphogenesis, because in Msx1 and Pax9 homozygous null mutants, tooth organs arrest at the bud stage (14, 15). However, there is little known about the interactions of Pax9 with Msx1 at the level of gene regulation and function. It is possible that Pax9 could interact directly with Msx1 or activate a regulator of Msx1. Alternatively, the molecular relationship shared by Pax9 and Msx1 could involve functional interactions on the post-transcriptional or protein level.

Clues about a potential downstream effector gene of the Pax9-Msx1 pathway come from the observation that in Msx1 and Pax9 single homozygous mutant mice, Bmp4 expression is markedly reduced in dental mesenchyme (15, 16). This suggests that both genes may be required for the modulation of Bmp4 in dental mesenchyme. As an effector molecule, Bmp4 is known to be involved in downstream signaling events that result in the induction of the enamel knot, a transient signaling center within dental epithelium (17). Subsequent changes in the enamel organ result in the progress of cuspal morphogenesis. Initial molecular studies of the BMP4 promoter identified a region between –1100 and +45 as important for basal transcription (18). Although a variant of the Bmp4 promoter has been shown to be a target for regulation by a number of transcription factors (16, 19, 20), there are no data available on the modulation of the Bmp4 promoter by either Pax9 or Msx1, or both.

Here we report that Pax9 interacts with Msx1 at both the gene and protein levels and that the interaction enhances the ability of Pax9 to transactivate Msx1 and Bmp4 expression during tooth development. In addition, we tested how a missense mutation (T62C) in the paired domain of PAX9 that is responsible for human tooth agenesis (1) affects its functions. Our data indicate that although the mutant Pax9 protein (L21P) can bind to both wild-type Msx1 and Pax9 proteins, it fails to transactivate either the Msx1 or the Bmp4 promoter. Furthermore, synergistic transcriptional activation of the Bmp4 promoter was lost with coexpression of mutant Pax9 and wild-type Msx1. These data suggest that Pax9 is critical for the regulation of Bmp4 expression through its paired domain rather than Msx1. Together, these findings demonstrate a signaling pathway involving Pax9, Msx1, and Bmp4 that is critical for the progress of tooth morphogenesis from the bud to cap stage.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Pax9-deficient Mice and in Situ Hybridization—The generation of Pax9 knock-out alleles in mice and the preparation of paraffin sections of mutant tooth organs have been described previously (15). Conditions for in situ hybridizations using a ³⁵S-labeled riboprobe specific for murine Msx1 were followed as described earlier (21).

Plasmid Constructs and Site-directed Mutagenesis—The mammalian expression vector pCMV-Pax9 with c-Myc epitope tag was used as previously described (22). Expression plasmids containing the cytomegalovirus promoter linked to the full coding sequence of Msx1 were constructed in pCMV-Tag2b (Stratagene, CA). A murine Msx1 cDNA clone comprising the full-length coding sequence region was kindly provided by Dr. John Rubenstein (University of California at San Francisco). The FLAG epitope is in frame with the amino terminus of Msx1. Three fragments of the Msx1 promoter (–3.5 kb/+106 bp, –1282/106 bp, and –165/+106 bp) containing the luciferase gene and the 5' region of the Bmp4 promoter (–2372/+258 bp) within the luciferase vector were described previously (23–25).

To construct pCMV-L21PPax9, in vitro site-directed mutagenesis was performed using the QuikChange mutagenesis kit (Stratagene). The specific primer sets used for the generation of mutant Pax9 cDNA were as follows: L21P, forward, 5'-CGGAAGGCCGCCGCCCCAACGCCAT-3'; and reverse, 5'-ATGGCGTTGGGCGGCGGCCTTCCG-3'. The mutated construct was sequenced entirely to confirm the point mutation. The Myc epitope was in frame with the amino terminus of mutant Pax9.

Electrophoretic Mobility Shift Assay—Oligonucleotides corresponding to e5 and CD19-2(A-ins) were synthesized (Sigma/Genosys), and gel retardation assays were performed as previously described (22). The oligonucleotide probes used are two previously established high affinity paired domain recognition sequences. The e5 sequence, which was originally derived from the Drosophila even skipped promoter for the Eve transcription factor (26), is a known binding sequence for Pax9 (27). CD19-2(A-ins) is a classical paired domain recognition sequence (28). Radiolabeled e5 or CD19-2(A-ins) was incubated with 1 µg of nuclear extracts from COS7 cells transfected with the appropriate expression plasmid (wild-type Pax9, L21PPax9, or 219InsGPax9 in pCMV-Myc). The generation of the 219InsG expression vector was previously described (22). After incubation at room temperature for 30 min, 1 ml of -Pax9 or -c-Myc (Santa Cruz Biotechnology) was added to the reaction mixture. The entire reaction was loaded onto a polyacrylamide gel as described previously (22).

Coimmunoprecipitation—COS7 cells were obtained from American Type Culture Collection and grown as described previously (22). COS7 cells were cotransfected with Myc-Pax9 or Myc-L21PPax9, and FLAG-Msx1 using FuGENE 6 (Roche Applied Science) according to the manufacturer's instructions. After 48 h, the cells were resuspended in lysis buffer (50 mM Tris, pH 8.0, 400 mM NaCl, 1% Triton X-100) with protease inhibitor mixture tablets (Roche Applied Science) and incubated for 30 min on ice. The cell lysates were added to 20 µl of anti-FLAG M2 affinity gel (Sigma) and rotated at 4 °C overnight. The affinity gels were washed with lysis buffer four times and TBS once, eluted with Laemmli buffer, and analyzed by Western blotting with 1:200 dilution -c-Myc (9E10) monoclonal antibody (Santa Cruz Biotechnology) or 1:1000 dilution mouse -FLAG M2 monoclonal antibody (Sigma) using an ECL kit (Amersham Biosciences).

Luciferase--Galactosidase Assays—Each well received 0.25 µg of reporter plasmid and 0.2–1.0 µg of expression plasmids. 0.25 µg of pCMV-SPORT plasmid (Invitrogen) was used as the internal control for transfection efficiency. Cell extracts prepared 48h after transfection were assayed for -galactosidase and luciferase activity and measured using kits purchased from Promega and Invitrogen, respectively.

Immunolocalization of the Mutant Proteins in Mammalian Cells—To demonstrate the in vivo expression of wild-type and mutant Pax9, the cells were harvested 48 h post-transfection. Transfections of COS7 cells were carried out using FuGENE 6 (Roche Applied Science). Concentrations were measured by the BCA protein assay kit (Pierce), and equal amounts of proteins were analyzed by Western blotting using 1:200 dilution-c-Myc (9E10) monoclonal antibody (Santa Cruz Biotechnology) and the ECL kit (Amersham Biosciences). Transfected cells were fixed and permeabilized with methanol prior to incubation with the c-Myc antibody (1:100), then washed, and incubated with a fluorescein isothiocyanate-conjugated goat anti-mouse antibody (Santa Cruz Biotechnology). Immunostaining was visualized with an Olympus BH-2 microscope.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Pax9 Is Needed for the Expression of Msx1 in Mesenchyme during Tooth Morphogenesis—To determine whether Pax9 is involved in the regulation of Msx1, the expression of Msx1 was analyzed in tooth primordia of Pax9-deficient mice. At E12.5,³ no change in expression of Msx1 was observed in the Pax9 mutant embryo (Fig. 1, A and B). At E13.5, Msx1 expression appeared drastically reduced in the mesenchyme of Pax9 mutant molar organs (Fig. 1, C and D). Although Msx1 transcripts were present at E14.5 in wild-type tooth organs, no expression was detectable in mutant tooth organs (Fig. 1, E and F).

Pax9 Can Transactivate Msx1 Promoter—Our in situ hybridization analysis of Msx1 expression in Pax9-deficient dental mesenchyme showed that both genes act within the same signaling pathway and that Pax9 shares an upstream epistasis with Msx1. To test whether Pax9 directly regulates Msx1 expression, we performed reporter assays using different Msx1 promoter constructs. Three Msx1 promoter constructs (23, 24) with the luciferase gene were each cotransfected with Pax9 into COS7 cells. These cells do not express either Pax9 or Msx1. The p3.5Msx1-Luc promoter contains 3500 bp of sequence upstream of the translation initiation site and comprises upstream and downstream promoter elements. It contains five putative paired domain-binding sites, which are located in the highly conserved region within 3.5 kb of the human and murine Msx1 promoter (Fig. 2A). When Pax9 expression plasmids were cotransfected, a dose-dependent increase in reporter gene activity was observed with increasing lengths of the Msx1 promoter (Fig. 2B).

View larger version (143K): [in this window] [in a new window]   FIGURE 1. Msx1 expression in dental mesenchyme requires Pax9. In situ hybridization analysis of Msx1 transcripts in wild-type mice (A, C, and E) and Pax9-deficient mice (B, D, and F) at the stage from E12.5 to E14.5. A and B, at E12.5, no change of Msx1 expression was noted in the mutant mesenchyme. C–F, at E13.5 and E14.5, Msx1 expression shows significant reduction in the mutant mesenchyme relative to wild type. oe, oral epithelium; de, dental epithelium; dm, dental mesenchyme; ek, enamel knot; eo, enamel organ.

Combinatorial Effects of Pax9 and Msx1 on the Bmp4 Promoter—To test the direct effect of Pax9 and Msx1 on Bmp4 regulation, we performed reporter assays using a Bmp4 promoter construct (p2.4Bmp4-Luc) containing 2372 bp of sequence upstream of the translation initiation site. We further tested whether the expression of Bmp4 is regulated via Pax9-Msx1 protein interactions. Transfection of the Pax9 expression plasmid alone results in significant activation of the p2.4Bmp4-Luc reporter plasmid, whereas transfection of Msx1 expression plasmid alone failed to regulate this promoter. Cotransfections with Pax9 and Msx1 expression plasmids showed that doubling the concentration of Msx1 while keeping the concentration of Pax9 the same resulted in a decrease in activation from almost 14-fold to nearly 5-fold (Fig. 3C). Western blotting demonstrates that although doubling the amount of Msx1 reduced Pax9-mediated transcriptional activity, no changes were observed in Pax9 expression with increasing levels of Msx1 (Fig. 3D). This suggests that increasing the concentration of Msx1 does not affect the level of Pax9 protein.

View larger version (18K): [in this window] [in a new window]   FIGURE 2. Pax9 can transactivate Msx1 promoter. A, schematic of the Msx1 promoter constructs used in transient transfection assays showing the location of putative paired domain-binding elements that are located in the conserved region between human and mouse. B, COS7 cells were transfected with 250 ng of the Msx1 promoter luciferase reporter constructs. The cells were cotransfected with increasing amounts (500 and 1000 ng) of Pax9 expression vector. The empty Pax9 expression plasmid, pCMV, was added to each reaction mixture to maintain a constant total amount of expression plasmid. Luciferase activity regulated by different fragments of the Msx1 promoter in the presence of Pax9 is enhanced with increasing lengths of the Msx1 promoter region in a dose-dependent manner. The activities are shown as the mean fold activation compared with the Msx1 promoter plasmid without Pax9 expression and normalized to -galactosidase. The error bars represent the means ± S.E. of three assays performed in duplicate.

View larger version (32K): [in this window] [in a new window]   FIGURE 3. Functional consequences of the interaction of Pax9 with Msx1 on the transcriptional regulation of the Msx1 and Bmp4 promoters. A, coimmunoprecipitation with FLAG-tagged Msx1 revealed an association of each with Myc-tagged wild-type Pax9 or L21PPax9 on Western blot (WB) with anti-c-Myc antibody. Western blot with anti-FLAG antibody indicated that equal amounts of protein were subjected to immunoprecipitation (IP). B, effect of Msx1 on Pax9-mediated transcriptional activation on Msx1 promoter. Overexpression of 250 ng of Msx1 expression vector activated Pax9-mediated activation of Msx1 promoter, whereas cotransfection of 500 ng of Msx1 expression vector blocks this activation. C, effect of Msx1 on Pax9-mediated transcriptional activation on Bmp4 promoter. Overexpression of 250 ng of Msx1 expression vector activated Pax9-mediated activation of Bmp4 promoter, whereas cotransfection of 500 ng of Msx1 expression vector blocks this activation. Differences in transfection efficiency were corrected relative to expression levels of -galactosidase. The error bars represent the means ± S.E. of three assays performed in duplicate. D, Western blot shows relative expression levels of transfected Myc-tagged Pax9 and FLAG-tagged Msx1 expression plasmids.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Despite the wealth of information available on the molecular signals required for tooth morphogenesis, there is little known about how the independent and coordinated activities of key dental mesenchymal transcription factors like Msx1 and Pax9 affect the progress of the tooth organ from the bud to cap stage of development. The down-regulation of Msx1 expression in Pax9-deficient mice and decreased levels of Bmp4 expression in Pax9 and Msx1 homozygous null mice indicate that the three genes act within the same signaling pathway. In these studies, we provide the first experimental evidence in support of a direct molecular relationship between Pax9 and Msx1 on the transcriptional level and their interactions as proteins. We report that Pax9 forms a heterodimeric complex with Msx1 and that the interaction enhances the ability of Pax9 to transactivate Msx1 and Bmp4 expression during tooth development. Our functional studies of the protein product of a naturally occurring paired domain mutation (Pax9 L21P) demonstrate that although it physically associates with Msx1, the mutant protein is unable to transcriptionally activate both the Msx1 and Bmp4 promoters. Furthermore, we found that coexpression of the Pax9 paired domain mutant and wild-type Msx1 results in a loss of synergistic transcriptional activation of the Bmp4 promoter. These data suggest that the regulation of Bmp4 expression is mediated by the paired domain of Pax9 rather than through its interactions with Msx1. Together, these findings demonstrate that the regulation of Bmp4 expression by the interaction of Pax9 with Msx1 determines the fate of the transition from bud stage to cap stage during tooth development (Fig. 7).

View larger version (41K): [in this window] [in a new window]   FIGURE 4. L21PPax9 shows interactions with Msx1. A, expression of Myc-tagged wild-type (WT) Pax9 and L21PPax9 mutant proteins were verified by Western blotting (WB) of cell extracts from transfected COS7 cells with anti-c-Myc antibody. Each lane contained the same amounts of protein. B, nuclear localization of Myc-tagged wild-type Pax9 or L21PPax9, represented in green, was similar when expressed in COS7 cells. C, Myc-tagged L21PPax9 coimmunoprecipitated with FLAG-tagged Msx1 showed similar affinity to wild-type Pax9. Equal amounts of protein were subjected to immunoprecipitation (IP) with the indicated antibodies.

View larger version (69K): [in this window] [in a new window]   FIGURE 5. L21PPax9 is unable to bind known paired domain recognition sequences. A and B, electromobility assay of two 32P-labeled high affinity paired domain-binding sites with wild-type Pax9 or L21PPax9 reveals abolished DNA binding activity of the mutant. 219InsG, a previously described Pax9 insertion mutation, is used as a negative control. Specificity of complex formation was confirmed by supershift using Pax9 and Myc antibodies. Lanes a, protein, oligonucleotide probe; lanes b, protein, oligonucleotide probe, a-Pax9; lanes c, protein, oligonucleotide probe, a-Myc).

View larger version (17K): [in this window] [in a new window]   FIGURE 6. L21PPax9 shows impaired activation of the Msx1 promoter and the Bmp4 promoter. A, in transient transfection assays, transfection with 1000 ng of wild-type Pax9 expression vector led to a 3.9-fold activation of the p3.5Msx1-Luc compared with empty plasmid, where as expression of the same amount of L21PPax9 expression vector failed to activate the promoter. B, transfection with 1000 ng of wild-type Pax9 expression vector led to a 45-fold activation of the p2.4Bmp4-Luc compared with empty plasmid, but reporter activation at Bmp4 was reduced to 4.3-fold by L21PPax9. C, although cotransfection of wild-type Pax9 and Msx1 activated p2.4Bmp4-Luc 32-fold, activation diminished to 3.5-fold with coexpression of L21PPax9 and Msx1. Protein levels were indicated by Western blot of total cell lysate. Differences in transfection efficiency were corrected relative to expression levels of -galactosidase The error bars represent the means ± S.E. of three assays performed in duplicate.

Although recent studies of human PAX9 mutations have enabled structure-function correlations, the precise molecular mechanisms that contribute to tooth agenesis are poorly understood. Our functional studies of a previously described mutation (L21P) in the amino-terminal subdomain of the paired domain (1) demonstrate impaired transcriptional activation of the Msx1 and Bmp4 promoters. It is likely that the proline cyclic side chain blocks the main chain nitrogen atom and chemically prevents it from forming a hydrogen bond. Hence, we speculate that the mutation of Leu to Pro eliminates this hydrogen bonding interaction and therefore precludes the binding and subsequent transcription of a promoter-reporter construct. Additionally, evidence has shown that the paired domain of Pax3 and the homeodomain of Msx1 are essential for the interaction between the two proteins. The results of our coimmunoprecipitation analysis indicate that the L21PPax9 mutation has no effect on its ability to interact with Msx1, suggesting that the amino-terminal subdomain of the paired domain is not involved in protein-protein interactions. Thus, it is likely that either the carboxyl-terminal subdomain of the paired domain of Pax9 is critical for this interaction or the mutation does not alter the structure of the paired domain to an extent that would disrupt heterodimerization with Msx1. Although not as likely, another explanation is that protein-protein interactions may also occur through the octapeptide motif of Pax9, which is unaffected by the mutation studied (32). We also demonstrated that synergistic transcriptional activation is reduced between L21PPax9 and Msx1 at the Bmp4 promoter. Taken together with the observation that mutant Pax9 interacts with Msx1, our results suggest that defects in DNA binding, rather than protein-protein interactions, are responsible for the pathogenesis of tooth agenesis for this mutation.

View larger version (21K): [in this window] [in a new window]   FIGURE 7. A current model of early tooth morphogenesis. A, Pax9 is not a transcriptional regulator of Msx1 at the time of tooth initiation, but the presence of Msx1 is critical for advancing of tooth morphogenesis. At E12.5, Pax9 cannot induce Msx1 in dental mesenchyme (Mes.). At 13.5, Pax9 begins to induce Msx1 expression, and the heterodimer of wild-type Pax9 and wild-type Msx1 proteins can induce and enhance Bmp4 expression in dental mesenchyme. Epi., epithelium. B, although the wild-type and L21P mutant of Pax9 bind to Msx1 protein equally well, the mutant Pax9 and Msx1, either alone or together, fail to transactivate the Bmp4 promoter. Furthermore, synergistic transcriptional activation of Bmp4 promoter was also lost if the mutant Pax9 and wild-type Msx1 were coexpressed.

	FOOTNOTES

 
^* This work was supported by National Institutes of Health Grants R01 DE13668 (to R. N. D.), K08 DE14237 (to H. K.), and DE 16346 (to T. O.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ Senior Research Career Scientist of the Department of Veterans Affairs.

² To whom correspondence should be addressed: Dept. of Biomedical Sciences, Baylor College of Dentistry, 3302 Gaston Ave, Dallas, TX 75246. Tel.: 214-828-8260; Fax: 214-828-8951; E-mail: rdsouza{at}bcd.tamhsc.edu.

³ The abbreviation used is: En, embryonic day n.

⁴ H. Peters, unpublished data.

	ACKNOWLEDGMENTS

 
The advice and insights provided by Drs. Brad Amendt and Peter Bialek are appreciated, as is the technical assistance of Adriana Cavender.

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