Pax3-FKHR knock-in mice show developmental aberrations but do not develop tumors

Alveolar rhabdomyosarcoma is a pediatric disease specified by the recurrent chromosome translocations t(2;13) and t(1;13). These translocations result in the formation of the PAX3-FKHR and PAX7-FKHR fusion genes, which are thought to play a causal role in the genesis of this disease. Although PAX3-FKHR exhibits transforming activity in immortalized fibroblast cell lines, a direct role of this fusion protein in tumorigenesis in vivo has not been shown. We determined whether expression of Pax3-FKHR in the mouse germ line would render these animals prone to the development of rhabdomyosarcomas. By targeting FKHR cDNA sequences into the Pax3 locus of embryonic stem cells, we used these cells to generate mice carrying a Pax3-FKHR knock-in allele. Despite low expression of the knock-in allele, heterozygous offspring of Pax3-FKHR chimeric mice showed developmental abnormalities. These included intraventricular septum defects, tricuspid valve insufficiency, and diaphragm defects, which caused congestive heart failure leading to perinatal death. In addition, Pax3-FKHR heterozygous offspring displayed malformations of some but not all hypaxial muscles. However, neither newborn heterozygous pups nor their chimeric parents showed any signs of malignancy. We conclude that the Pax3-FKHR allele causes lethal developmental defects in knock-in mice but might be insufficient to cause muscle tumors.     

Pax3 functions in cell survival and in pax7 regulation

In developing vertebrate embryos, Pax3 is expressed in the neural tube and in the paraxial mesoderm that gives rise to skeletal muscles. Pax3 mutants develop muscular and neural tube defects; furthermore, Pax3 is essential for the proper activation of the myogenic determination factor gene, MyoD, during early muscle development and PAX3 chromosomal translocations result in muscle tumors, providing evidence that Pax3 has diverse functions in myogenesis. To investigate the specific functions of Pax3 in development, we have examined cell survival and gene expression in presomitic mesoderm, somites and neural tube of developing wild-type and Pax3 mutant (Splotch) mouse embryos. Disruption of Pax3 expression by antisense oligonucleotides significantly impairs MyoD activation by signals from neural tube/notochord and surface ectoderm in cultured presomitic mesoderm (PSM), and is accompanied by a marked increase in programmed cell death. In Pax3 mutant (Splotch) embryos, MyoD is activated normally in the hypaxial somite, but MyoD-expressing cells are disorganized and apoptosis is prevalent in newly formed somites, but not in the neural tube or mature somites. In neural tube and somite regions where cell survival is maintained, the closely related Pax7 gene is upregulated, and its expression becomes expanded into the dorsal neural tube and somites, where Pax3 would normally be expressed. These results establish that Pax3 has complementary functions in MyoD activation and inhibition of apoptosis in the somitic mesoderm and in repression of Pax7 during neural tube and somite development.     

Effects of PAX3-FKHR on malignant phenotypes in alveolar rhabdomyosarcoma

The malignancy of alveolar rhabdomyosarcoma (ARMS) has been linked to expression of the PAX3-FKHR chimeric gene. To understand the effect of this gene, we used RNAi to knock down its expression (without affecting the expressions of either PAX3 or FKHR) in human ARMS cell lines. Down-regulating PAX3-FKHR caused (a) tumor cells to accumulate in the G1 phase, inhibiting the rate of cellular proliferation, (b) a reduction in the levels of the MET, reducing cell motility stimulated by HGF, and (c) induction of the myogenic differentiation gene, myogenin, and muscle differentiation (morphologic change and the expression of muscle specific proteins, desmin, and myosin heavy chain). These results suggest that PAX3-FKHR in ARMS cells promotes malignant phenotypes such as proliferation, motility, and to suppress differentiation.     

Menin is required in cranial neural crest for palatogenesis and perinatal viability

Menin is a nuclear protein encoded by a tumor suppressor gene that is mutated in humans with multiple endocrine neoplasia type 1 (MEN1). Menin functions as a component of a histone methyltransferase complex that regulates expression of target genes including the cell cycle inhibitor p27^kip1. Here, we show that menin plays a previously unappreciated and critical role in cranial neural crest. Tissue-specific inactivation of menin in Pax3- or Wnt1-expressing neural crest cells leads to perinatal death, cleft palate and other cranial bone defects, which are associated with a decrease in p27^kip1 expression. Deletion of menin in Pax3-expressing somite precursors also produces patterning defects of rib formation. Thus, menin functions in vivo during osteogenesis and is required for palatogenesis, skeletal rib formation and perinatal viability.