PITX2, β-catenin and lymphoid enhancer factor (LEF-1) are required for the inductive formation of several epithelial-derived organs, including teeth. Lef-1 is expressed in the dental epithelium after Pitx2, and both factors have overlapping expression patterns in the tooth bud and cap stages. Our analysis of Pitx2–/– mutant mice showed reduced Lef-1 expression in facial tissues by RT-PCR and quantitative RT-PCR. Consistent with these results we show that the human 2.5 kb LEF-1 promoter is activated by PITX2. Furthermore, the LEF-1 promoter is differentially activated by PITX2 isoforms, which are co-expressed in dental epithelium. The 2.5 kb LEF-1 promoter contains two regions that act to inhibit its transcription in concert with PITX2. The proximal region contains a Wnt-responsive element (WRE) that attenuates PITX2 activation. LEF-1 cannot autoregulate LEF-1 expression; however co-transfection of PITX2 and LEF-1 result in a synergistic activation of the 2.5 kb LEF-1 promoter. LEF-1 specifically interacts with the PITX2 C-terminal tail. Deletion of a distal 800 bp segment of the LEF-1 promoter resulted in enhanced PITX2 activation, and increased synergistic activation in the presence of LEF-1. Furthermore, β-catenin in combination with PITX2 synergistically activates the LEF-1 promoter and this activation is independent of the Wnt-responsive element. β-catenin directly interacts with PITX2 to synergistically regulate LEF-1 expression. We show a new mechanism where LEF-1 expression is regulated through PITX2, LEF-1 and β-catenin direct physical interactions. LEF-1 and β-catenin interactions with PITX2 provide new mechanisms for the regulation of PITX2 transcriptional activity.
Lef-1 and PITX2 function in the Wnt signaling pathway by recruiting and interacting with -catenin to activate target genes. Chromatin immunoprecipitation (ChIP) assays identified the Lef-1 promoter as a PITX2 downstream target. Transgenic mice expressing LacZ driven by the 2.5-kb LEF-1 promoter demonstrated expression in the tooth epithelium correlated with endogenous Lef-1 FL epithelial expression. PITX2 isoforms regulate the LEF-1 promoter, and -catenin synergistically enhanced activation of the LEF-1 promoter in combination with PITX2 and Lef-1 isoforms. PITX2 enhances endogenous expression of the full-length -catenin-dependent Lef-1 isoform (Lef-1 FL) while decreasing expression of the N-terminally truncated -catenin-independent isoform. Our research revealed a novel interaction between PITX2, Lef-1, and -catenin in which the Lef-1 -catenin binding domain is dispensable for its interaction with PITX2. PITX2 interacts with two sites within the Lef-1 protein. Furthermore, -catenin interacts with the PITX2 homeodomain and Lef-1 interacts with the PITX2 C-terminal tail. Lef-1 and -catenin interact simultaneously and independently with PITX2 through two different sites to regulate PITX2 transcriptional activity. These data support a role for PITX2 in cell proliferation, migration, and cell division through differential Lef-1 isoform expression and interactions with Lef-1 and -catenin.Pitx2 and Lef-1 encode two transcription factors whose expression can be regulated by early signaling events involved in numerous developmental programs. Pitx2 and Lef-1 are differentially expressed in many tissues, and they demonstrate overlapping expression during tooth development. Lef-1 can be activated by BMP, Wnt, Smads, and transforming growth factor  signaling (18,32,33). Furthermore, Lef-1 transcriptional activity is regulated by its interaction with -catenin. Secreted
PKC phosphorylation regulates PITX2 DNA binding and transcriptional activity. Mutation of individual PKC sites demonstrates the functional regulation of PITX2 through phosphorylation. Immunoprecipitation of PITX2 and a PITX2 PKC mutant protein reveal specific in vivo phosphorylation by PKC in transfected cells. The transcriptional activity of PITX2 is negatively regulated by N-terminal phosphorylation and positively regulated by C-terminal phosphorylation. We demonstrate a mechanism of increased PITX2 transcriptional activation through protein interactions facilitated by phosphorylation of the PITX2 C-terminal tail. Phosphorylation of the PITX2 C terminus enhances the interaction with cellular factors. In corroboration with the PITX2 PKC functional studies, a newly identified C-terminal PITX2 mutation associated with Axenfeld-Rieger syndrome (ARS) demonstrates reduced phosphorylation. This mutation (PITX2 DeltaT1261) creates a frameshift mutation in codon 227 resulting in 11 novel amino acids downstream followed by premature truncation of the protein. Three PKC sites in the C-terminal tail and OAR domain are deleted, which results in decreased transcriptional activation. PITX2 DeltaT1261 is unable to interact with a cellular factor to synergistically activate transcription and demonstrates the first link of ARS with defective PITX2 protein interactions. Gene expression profiling of homozygous Pitx2 mutant mouse tissue reveals decreased Dlx2 expression as a potential molecular basis for developmental defects associated with ARS patients. Overall, phosphorylation imparts another level of regulation to the activity of the PITX2 homeodomain protein during development.
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