Pax3 is expressed early during embryonic development in spatially restricted domains including limb muscle, neural crest, and neural tube. Pax3 functions at the nodal point in melanocyte stem cell differentiation, cardiogenesis and neurogenesis. Additionally Pax3 has been implicated in migration and differentiation of precursor cell populations. Currently there are questions about how Pax3 regulates these diverse functions. In this study we found that in the absence of functional Pax3, as in Splotch embryos, the neural crest cells undergo premature neurogenesis, as evidenced by increased Brn3a positive staining in neural tube explants, in comparison with wild-type. Premature neurogenesis in the absence of functional Pax3 may be due to a change in the regulation of basic helix-loop-helix transcription factors implicated in proliferation and differentiation. Using promoter-luciferase activity measurements in transient co-transfection experiments and electro-mobility shift assays, we show that Pax3 regulates Hairy and enhancer of split homolog-1 (Hes1) and Neurogenin2 (Ngn2) by directly binding to their promoters. Chromatin immunoprecipitation assays confirmed that Pax3 bound to cis-regulatory elements within Hes1 and Ngn2 promoters. These observations suggest that Pax3 regulates Hes1 and Ngn2 and imply that it may couple migration with neural stem cell maintenance and neurogenesis.
Pax3 encodes a paired homeobox containing transcription factor that is expressed in neuroepithelium, neural crest, and presomitic mesoderm (1). Homozygous mouse embryos carrying a loss-of-function Pax3 allele (Pax3 Ϫ/Ϫ ) develop open neural tube defects, such as exencephaly or spina bifida (2), and die around embryonic day 14 (E14) 4 as a consequence of heart defects (3). More recently, Pax3 has been shown to function at the nodal point in melanocyte stem cell differentiation (4). Heterozygous embryos (Pax3 ϩ/Ϫ ) are viable but exhibit white patches on their bellies caused by defective development of neural crest-derived melanocytes. This suggests that disruption of the Pax3-dependent developmental program may cause defects in the development of neural crest-derived structures.Two main Pax3-binding sites have been identified and are found in most Pax3 target elements as follows: (i) a binding site derived from the Drosophila Paired (ATTA N5 GTTCC), and (ii) a Pax3 paired domain binding site (CGTCAC(G/A)(C/ G)TT) identified by Epstein et al. (5) by CASTing (DNA-binding site selection assays) in the c-Met promoter region. In addition several paired domains, such as GTTCC, CAGTGT, GTTAT, GTGTGA, and CAAGG (6), as well as the homeodomain ATTA, have been suggested to be "putative Pax3-binding motifs" (7,8). More recently, Corey and Underhill (9) demonstrated that Pax3 can regulate target genes through alternative modes of DNA recognition. They observed that although the microphthalmia-associated transcription factor element is characterized by suboptimal recognition motifs for the paired domain and homeodomain, it sustains a higher level of Pax3 binding than TRP-1, which contains a canonical paired domain site. The basis for this difference involved a context-dependent cooperative binding event requiring both the paired and homeodomain, whereas the paired domain alone was sufficient for TRP-1 recognition.Since Pax3 is important in diverse cellular functions during development, we wanted to identify additional genes regulated by Pax3. To accomplish this we utilized oligonucleotide arrays and RNA isolated from Pax3-transfected cell lines and promoter-based data mining (6). Based on the putative Pax3-binding
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