Cardiac neural crest is necessary for normal addition of the myocardium to the arterial pole from the secondary heart field.

In cardiac neural-crest-ablated embryos, the secondary heart field fails to add myocardial cells to the outflow tract and elongation of the tube is deficient. Since that study, we have shown that the secondary heart field provides both myocardium and smooth muscle to the arterial pole. The present study was undertaken to determine whether addition of both cell types is disrupted after neural crest ablation. Marking experiments confirm that the myocardial component fails to be added to the outflow tract after neural crest ablation. The cells destined to go into the outflow myocardium fail to migrate and are left at the junction of the outflow myocardium with the nascent smooth muscle at the base of the arterial pole. In contrast, the vascular smooth muscle component is added to the arterial pole normally after neural crest ablation. When the myocardium is not added to the outflow tract, the point where the outflow joins the pharynx does not move caudally as it normally should, the aortic sac is smaller and fails to elongate resulting in abnormal connections of the outflow tract with the caudal aortic arch arteries.

Secondary heart field contributes myocardium and smooth muscle to the arterial pole of the developing heart.

The arterial pole of the heart is the region where the ventricular myocardium continues as the vascular smooth muscle tunics of the aorta and pulmonary trunk. It has been shown that the arterial pole myocardium derives from the secondary heart field and the smooth muscle tunic of the aorta and pulmonary trunk derives from neural crest. However, this neural crest-derived smooth muscle does not extend to the arterial pole myocardium leaving a region at the base of the aorta and pulmonary trunk that is invested by vascular smooth muscle of unknown origin. Using tissue marking and vascular smooth muscle markers, we show that the secondary heart field, in addition to providing myocardium to the cardiac outflow tract, also generates prospective smooth muscle that forms the proximal walls of the aorta and pulmonary trunk. As a result, there are two seams in the arterial pole: first, the myocardial junction with secondary heart field-derived smooth muscle; second, the secondary heart field-derived smooth muscle with the neural crest-derived smooth muscle. Both of these seams are points where aortic dissection frequently occurs in Marfan's and other syndromes.

Myocardial volume and organization are changed by failure of addition of secondary heart field myocardium to the cardiac outflow tract.

Cardiac neural crest ablation results in primary myocardial dysfunction and failure of the secondary heart field to add the definitive myocardium to the cardiac outflow tract. The current study was undertaken to understand the changes in myocardial characteristics in the heart tube, including volume, proliferation, and cell size when the myocardium from the secondary heart field fails to be added to the primary heart tube. We used magnetic resonance and confocal microscopy to determine that the volume of myocardium in the looped heart was dramatically reduced and the compact layer of myocardium was thinner after neural crest ablation, especially in the outflow tract and ventricular regions. Proliferation measured by 5-bromo-2'-deoxyuridine incorporation was elevated at only one stage during looping, cell death was normal and myocardial cell size was increased. Taken together, these results indicate that there are fewer myocytes in the heart. By incubation day 8 when the heart would have normally completed septation, the anterior (ventral) wall of the right ventricle and right ventricular outflow tract was significantly thinner in the neural crest-ablated embryos than normal, but the thickness of the compact myocardium was normal in all other regions of the heart. The decreased volume and number of myocardial cells in the heart tube after neural crest ablation most likely reflects the amount of myocardium added by the secondary heart field.

Hensen's node gives rise to the ventral midline of the foregut: implications for organizing head and heart development.

Patterning of the ventral head has been attributed to various cell populations, including endoderm, mesoderm, and neural crest. Here, we provide evidence that head and heart development may be influenced by a ventral midline endodermal cell population. We show that the ventral midline endoderm of the foregut is generated directly from the extreme rostral portion of Hensen's node, the avian equivalent of the Spemann organizer. The endodermal cells extend caudally in the ventral midline from the prechordal plate during development of the foregut pocket. Thus, the prechordal plate appears as a mesendodermal pivot between the notochord and the ventral foregut midline. The elongating ventral midline endoderm delimits the right and left sides of the ventral foregut endoderm. Cells derived from the midline endoderm are incorporated into the endocardium and myocardium during closure of the foregut pocket and fusion of the bilateral heart primordia. Bilateral ablation of the endoderm flanking the midline at the level of the anterior intestinal portal leads to randomization of heart looping, suggesting that this endoderm is partitioned into right and left domains by the midline endoderm, thus performing a function similar to that of the notochord in maintaining left-right asymmetry. Because of its derivation from the dorsal organizer, its extent from the forebrain through the midline of the developing face and pharynx, and its participation in formation of a single midline heart tube, we propose that the ventral midline endoderm is ideally situated to function as a ventral organizer of the head and heart.

Shortened outflow tract leads to altered cardiac looping after neural crest ablation.

BACKGROUND: Congenital conotruncal malformations frequently involve dextroposed aorta. The pathogenesis of dextroposed aorta is not known but is thought to be due to abnormal looping and/or wedging of the outflow tract during early heart development. We examined the stage of cardiac looping in an experimental model of dextroposed aorta to determine the embryogenesis of this conotruncal malformation. METHODS AND RESULTS: Hearts were examined from neural crest-ablated embryos by using videocinephotography, scanning electron microscopy, and histological sections. The inflow and outflow limbs of the looped cardiac tube were malpositioned with respect to each other, the inner curvature was diminished, and the outflow limb was straighter and displaced cranially in a manner consistent with diminished length. The altered length could be explained by a significant reduction in the number of cells added to the myocardium of the distal outflow tract from the secondary heart field. CONCLUSIONS: The data are consistent with research showing that normal looping and wedging are essential for normal alignment of the aorta with the left ventricle. These processes are abnormal in neural crest-ablated embryos because of a failure of the outflow tract to lengthen by the addition of myocardial cells from the secondary heart field.