Abstract
Loss of Tbx4 results in absence of chorio-allantoic fusion and failure of formation of the primary vascular plexus of the allantois leading to embryonic death at E10.5. We reviewed the literature for genes implicated in chorio-allantoic fusion, cavitation and vascular plexus formation, processes affected in Tbx4 mutant allantoises. Using this candidate gene approach, we identified a number of genes downstream of Tbx4 in the allantois including extracellular matrix molecules Vcan, Has2, and Itgα5, transcription factors Snai1 and Twist, and signaling molecules Bmp2, Bmp7, Notch2, Jag1 and Wnt2. In addition, we show that the canonical Wnt signaling pathway contributes to the vessel-forming potential of the allantois. Ex vivo, the Tbx4 mutant phenotype can be rescued using agonists of the Wnt signaling pathway and, in wildtype allantoises, an inhibitor of the canonical Wnt signaling pathway disrupts vascular plexus formation. In vivo, Tbx4 and Wnt2 double heterozygous placentas show decreased vasculature suggesting interactions between Tbx4 and the canonical Wnt signaling pathway in the process of allantois-derived blood vessel formation.
Highlights
The chorio-allantoic placenta of eutherian mammals is critical for fetal development and growth during gestation
We show evidence that Tbx4 plays a role in these processes by regulating expression of a variety of Extracellular matrix (ECM) genes, signaling molecules and transcription factor genes either directly or indirectly
We show that expression of ECM molecules Vcan, Hyaluronic acid synthase2 (Has2), and Itga5, transcription factors Snai1 and Twist, and signaling molecules Bmp2, Bmp7, Notch2, Jag1 and Wnt2 is undetectable in Tbx4 mutant allantoises
Summary
The chorio-allantoic placenta of eutherian mammals is critical for fetal development and growth during gestation. The allantois first appears at embryonic day (E) 7.5 as a bud of mesoderm that emerges from the posterior end of the primitive streak [1,2], and grows into the exocoelomic cavity, cavitates between E7.5 and E8.25 and undergoes chorio-allantoic fusion [3]. Specification of angioblasts and their morphogenesis into endothelial tubes (ETs) proceeds proximally to the base of the allantois, where nascent allantoic blood vessels fuse with those of the embryo to create a continuous vasculature throughout the embryo and yolk sac [1,5]. The vascular plexus of the allantois presumably promotes the growth of mural cells to provide structural support for the vascular walls, similar to the yolk sac vascular plexus [6]. Extracellular matrix (ECM) is present, and there have been some reports of the presence of specific matrix components in the allantois [7,8,9,10], the presence of mural cells and the composition of the ECM is largely unknown
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