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.
In the mouse embryo, the splanchnic mesodermal cells of the anterior heart field (AHF) migrate from the pharynx to contribute to the early myocardium of the outflow tract (OT) and right ventricle (RV). Recent studies have attempted to distinguish the AHF from other precardiac populations, and to determine the genetic and molecular mechanisms that regulate its development. Here, we have used an Fgf8 lacZ allele to demonstrate that Fgf8 is expressed within the developing AHF. In addition, we use both a hypomorphic Fgf8 allele (Fgf8 neo ) and Cre-mediated gene ablation to show that Fgf8 is essential for the survival and proliferation of the AHF. Nkx2.5Cre is expressed in the AHF, primary heart tube and pharyngeal endoderm, while TnT-Cre is expressed only within the specified heart tube myocardium. Deletion of Fgf8 by Nkx2.5Cre results in a significant loss of the Nkx2.5 Cre lineage and severe OT and RV truncations by E9.5, while the remaining heart chambers (left ventricle and atria) are grossly normal. These defects result from significant decreases in cell proliferation and aberrant cell death in both the pharyngeal endoderm and splanchnic mesoderm. By contrast, ablation of Fgf8 in the TnT-Cre domain does not result in OT or RV defects, providing strong evidence that Fgf8 expression is crucial in the pharyngeal endoderm and/or overlying splanchnic mesoderm of the AHF at a stage prior to heart tube elongation. Analysis of downstream signaling components, such as phosphorylated-Erk and Pea3, identifies the AHF splanchnic mesoderm itself as a target for Fgf8 signaling.
In this review we discuss the major morphogenetic and regulative events that control myocardial progenitor cells from the time that they delaminate from the epiblast in the primitive streak to their differentiation into cardiomyocytes in the heart tube. During chick and mouse embryogenesis, myocardial progenitor cells go through four specific processes that are sequential but overlapping: specification of the cardiogenic mesoderm, determination of the bilaterally symmetric heart fields, patterning of the heart field, and finally cardiomyocyte differentiation and formation of the heart tube. We describe the morphological and molecular events that play a pivotal role in each of these four processes.
Abstract-Recent studies have shown that the primary heart tube continues to grow by addition of cells from the coelomic wall. This growth occurs concomitantly with embryonic folding and formation of the coelomic cavity, making early heart formation morphologically complex. A scarcity of data on localized growth parameters further hampers the understanding of cardiac growth. Therefore, we investigated local proliferation during early heart formation. Firstly, we determined the cell cycle length of primary myocardium of the early heart tube to be 5.5 days, showing that this myocardium is nonproliferating and implying that initial heart formation occurs solely by addition of cells. In line with this, we show that the heart tube rapidly lengthens at its inflow by differentiation of recently divided precursor cells. To track the origin of these cells, we made quantitative 3D reconstructions of proliferation in the forming heart tube and the mesoderm of its flanking coelomic walls. These reconstructions show a single, albeit bilateral, center of rapid proliferation in the caudomedial pericardial back wall. This center expresses Islet1. Cell tracing showed that cells from this caudal growth center, besides feeding into the venous pole of the heart, also move cranially via the dorsal pericardial mesoderm and differentiate into myocardium at the arterial pole. Inhibition of caudal proliferation impairs the formation of both the atria and the right ventricle. These data show how a proliferating growth center in the caudal coelomic wall elongates the heart tube at both its venous and arterial pole, providing a morphological mechanism for early heart formation. Key Words: cardiovascular development Ⅲ proliferation Ⅲ heart fields Ⅲ Islet1 Ⅲ bromodeoxy uridine Ⅲ quantitative 3D reconstruction T he heart is sculpted by precisely orchestrated developmental programs 1,2 that are prone to errors, leading to high incidences of congenital malformations. 3 Proliferation, although not the only mechanism, is an important parameter for the formation of the heart. 4 -8 Research on heart formation was recently revolutionized by the understanding that the initially formed myocardial heart tube continues to grow by recruitment of cells that originate from flanking mesoderm, dubbed the second heart field. 9 -11 This second heart field was originally reserved for cells feeding into the outflow of the primary heart tube to form the right ventricle. 9 Shortly after these findings, cells were also shown to be added to the inflow, 11 and a debate developed regarding the existence of multiple fields of cardiac precursor cells. [12][13][14][15] Limiting factors in this debate are the virtual lack of a 3D context of cardiac growth and the scarcity of data of locally involved parameters, such as proliferation. Early heart formation is of perplexing 3D complexity, because it occurs concomitantly with folding of the embryonic disc and formation of the coelomic cavity. Most likely, this complexity has contributed to the diversity of opinions, because o...
Rationale: The epicardium contributes to the majority of nonmyocardial cells in the adult heart. Recent studies have reported that the epicardium is derived from Nkx2.5-positive progenitors and can differentiate into cardiomyocytes. Not much is known about the relation between the myocardial and epicardial lineage during development, whereas insights into these embryonic mechanisms could facilitate the design of future regenerative strategies. Objective: Acquiring insight into the signaling pathways involved in the lineage separation leading to the differentiation of myocardial and (pro)epicardial cells at the inflow of the developing heart. Methods and Results: We made 3D reconstructions of Tbx18 gene expression patterns to give insight into the developing epicardium in relation to the developing myocardium. Next, using DiI tracing, we show that the (pro)epicardium separates from the same precursor pool as the inflow myocardium. In vitro, we show that this lineage separation is regulated by a crosstalk between bone morphogenetic protein (BMP) signaling and fibroblast growth factor (FGF) signaling. BMP signaling via Smad drives differentiation toward the myocardial lineage, which is inhibited by FGF signaling via mitogen-activated protein kinase kinase (Mek)1/2. Embryos exposed to recombinant FGF2 in vivo show enhanced epicardium formation, whereas a misbalance between FGF and BMP by Mek1/2 inhibition and BMP stimulation causes a developmental arrest of the epicardium and enhances myocardium formation at the inflow of the heart. Conclusion: Our data show that FGF signaling via Mek1/2 is dominant over BMP signaling via Smad and is required to separate the epicardial lineage from precardiac mesoderm. Consequently, myocardial differentiation requires BMP signaling via Smad and inhibition of FGF signaling at the level of Mek1/2. These findings are of clinical interest for the development of regeneration-based therapies for heart disease. (Circ Res. 2009;105:431-441.)Key Words: cardiovascular development Ⅲ proepicardium Ⅲ epicardium Ⅲ BMP Ⅲ FGF Ⅲ regeneration I n contrast to the adult heart, the embryonic heart tube is devoid of nonmyocardial cells and an epicardium, consisting of an outer myocardial and an inner endocardial layer separated by cardiac jelly. The heart tube expands by recruitment of progenitor cells from the splanchnic mesoderm at both poles of the heart. 1,2 The formation of the majority of nonmyocardial cells starts with the development of the proepicardium from splanchnic mesodermal cells at the inflow of the heart. Its villous outgrowths extend into the pericardial cavity, attach to the atrioventricular canal and gradually envelop the entire "naked" heart tube, deriving the epicardium. A subset of epicardial cells undergoes epithelial-to-mesenchymal transformation. The formed subepicardial mesenchymal cells contribute to the nonmyocardial component of the heart ie, the coronary vessels and the cardiac fibroblasts. In the adult heart, the nonmyocardial component occupies approximately 25% of the my...
The Hedgehog signaling pathway is critical for a significant number of developmental patterning events. In this study, we focus on the defects in pharyngeal arch and cardiovascular patterning present in Sonic hedgehog (Shh) null mouse embryos. Our data indicate that, in the absence of Shh, there is general failure of the pharyngeal arch development leading to cardiac and craniofacial defects. The cardiac phenotype results from arch artery and outflow tract patterning defects, as well as abnormal development of migratory neural crest cells (NCCs). The constellation of cardiovascular defects resembles a severe form of the human birth defect syndrome tetralogy of Fallot with complete pulmonary artery atresia. Previous studies have demonstrated a role for Shh in NCC survival and proliferation at later stages of development. Our data suggest that SHH signaling does not act directly on NCCs as a survival factor, but rather acts to restrict the domains that NCCs can populate during early stages (e8.5-10.5) of cardiovascular and craniofacial development.
The proepicardium (PE) is an embryonic progenitor cell population that delivers the epicardium, the majority of the cardiac interstitium, and the coronary vasculature. In the present study, we compared PE development in mouse and chick embryos. In the mouse, a left and a right PE anlage appear simultaneously, which subsequently merge at the embryonic midline to form a single PE. In chick embryos, the right PE anlage appears earlier than the left and only the right anlage acquires the full PE-phenotype. The left anlage remains in a rudimentary state. The expression patterns of PE marker genes (Tbx18, Wt1) correspond to the morphological data, being bilateral in the mouse and unilateral in the chick. Bmp4, which is unilaterally expressed in the right PE of chick embryos, is symmetrically expressed in the sinus venosus wall cranial to the PE in mouse embryos. Asymmetric development of the chicken PE might reflect side-specific differences in topographical relationships to tissues with PE-inducing or repressing activity or might result from the PE-repressing activity of the right PE, which grows earlier. To test these hypotheses, we analyzed PE development in chick embryos, firstly, subsequent to experimentally induced inversion of PE topographical relationships to neighbouring tissues; secondly, in organ cultures; and, thirdly, subsequent to induction of cardia bifida. In all three experiments, only the right PE develops the full PE phenotype. Our results suggest that PE development might be controlled by the L-R pathway in the chick but not in the mouse embryo.
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