Molecular markers of cardiac endocardial cushion development.

Endocardial cushions are precursors of mature heart valves. They form within the looped heart tube as discrete swellings and develop into thin, pliable leaflets that prevent regurgitation of blood. The embryonic origins of cardiac valves include endothelial, myocardial, and neural crest cells. Recently, an increasing number of animal models derived from mutational screens, gene inactivation, and transgenic studies have identified specific molecules required for normal development of the cardiac valves, and critical molecular pathways are beginning to emerge. To further this process, we have sought to assemble a diverse set of molecular markers encompassing all stages of cardiac valve development. Here, we provide a detailed comparative gene expression analysis of thirteen endocardial cushion markers. We identify endocardial cushion expression of the transcription factor Fog1, and we demonstrate active Wnt/beta-catenin signaling in developing endocardial cushions suggesting pathways that have not been previously appreciated to participate in cardiac valve formation.

Distinct enhancers regulate neural expression of Pax7.

The murine Pax7 gene has emerged as an important regulator of neural and somite development. It is expressed in discrete domains of the central nervous system, including cranial neural crest, dorsal neural tube, and mesencephalic tectum, pretectum, and base, and at the midbrain-hindbrain boundary. It is also expressed by nasal epithelia and neural crest-derived facial structures. Here, we define the 5' end of the cDNA for murine Pax7 and identify the transcriptional start site. We clarify gene structure and the murine coding sequence, and we define regions of noncoding sequence that are conserved between mice and humans. Using transgenic approaches, we identify upstream and intronic regulatory elements that confer distinct domains of neural expression in the cranial neural crest, facial mesenchyme, mesencephalon, and pontine reticular nucleus. These enhancer regions will be useful for gene expression studies and for the identification of upstream regulators of Pax7 expression.

Wnt7b regulates mesenchymal proliferation and vascular development in the lung.

Although the Wnt signaling pathway regulates inductive interactions between epithelial and mesenchymal cells, little is known of the role that this pathway plays during lung development. Wnt7b is expressed in the airway epithelium, suggesting a possible role for Wnt-mediated signaling in the regulation of lung development. To test this hypothesis, we have mutated Wnt7b in the germline of mice by replacement of the first exon with the lacZ-coding region. Wnt7b(lacZ-/-) mice exhibit perinatal death due to respiratory failure. Defects in early mesenchymal proliferation leading to lung hypoplasia are observed in Wnt7b(lacZ-/-) embryos. In addition, Wnt7b(lacZ-/-) embryos and newborn mice exhibit severe defects in the smooth muscle component of the major pulmonary vessels. These defects lead to rupture of the major vessels and hemorrhage in the lungs after birth. These results demonstrate that Wnt7b signaling is required for proper lung mesenchymal growth and vascular development.