Role of the gut endoderm in relaying left-right patterning in mice

Establishment of left-right (LR) asymmetry occurs after gastrulation commences and utilizes a conserved cascade of events. In the mouse, LR symmetry is broken at a midline structure, the node, and involves signal relay to the lateral plate, where it results in asymmetric organ morphogenesis. How information transmits from the node to the distantly situated lateral plate remains unclear. Noting that embryos lacking Sox17 exhibit defects in both gut endoderm formation and LR patterning, we investigated a potential connection between these two processes. We observed an endoderm-specific absence of the critical gap junction component, Connexin43 (Cx43), in Sox17 mutants. Iontophoretic dye injection experiments revealed planar gap junction coupling across the gut endoderm in wild-type but not Sox17 mutant embryos. They also revealed uncoupling of left and right sides of the gut endoderm in an isolated domain of gap junction intercellular communication at the midline, which in principle could function as a barrier to communication between the left and right sides of the embryo. The role for gap junction communication in LR patterning was confirmed by pharmacological inhibition, which molecularly recapitulated the mutant phenotype. Collectively, our data demonstrate that Cx43-mediated communication across gap junctions within the gut endoderm serves as a mechanism for information relay between node and lateral plate in a process that is critical for the establishment of LR asymmetry in mice.     

Two populations of node monocilia initiate left-right asymmetry in the mouse

The vertebrate body plan has conserved handed left-right (LR) asymmetry that is manifested in the heart, lungs, and gut. Leftward flow of extracellular fluid at the node (nodal flow) is critical for normal LR axis determination in the mouse. Nodal flow is generated by motile node cell monocilia and requires the axonemal dynein, left-right dynein (lrd). In the absence of lrd, LR determination becomes random. The cation channel polycystin-2 is also required to establish LR asymmetry. We show that lrd localizes to a centrally located subset of node monocilia, while polycystin-2 is found in all node monocilia. Asymmetric calcium signaling appears at the left margin of the node coincident with nodal flow. These observations suggest that LR asymmetry is established by an entirely ciliary mechanism: motile, lrd-containing monocilia generate nodal flow, and nonmotile polycystin-2 containing cilia sense nodal flow initiating an asymmetric calcium signal at the left border of the node.     

BMP signaling through ACVRI is required for left-right patterning in the early mouse embryo

Vertebrate organisms are characterized by dorsal-ventral and left-right asymmetry. The process that establishes left-right asymmetry during vertebrate development involves bone morphogenetic protein (BMP)-dependent signaling, but the molecular details of this signaling pathway remain poorly defined. This study tests the role of the BMP type I receptor ACVRI in establishing left-right asymmetry in chimeric mouse embryos. Mouse embryonic stem (ES) cells with a homozygous deletion at Acvr1 were used to generate chimeric embryos. Chimeric embryos were rescued from the gastrulation defect of Acvr1 null embryos but exhibited abnormal heart looping and embryonic turning. High mutant contribution chimeras expressed left-side markers such as nodal bilaterally in the lateral plate mesoderm (LPM), indicating that loss of ACVRI signaling leads to left isomerism. Expression of lefty1 was absent in the midline of chimeric embryos, but shh, a midline marker, was expressed normally, suggesting that, despite formation of midline, its barrier function was abolished. High-contribution chimeras also lacked asymmetric expression of nodal in the node. These data suggest that ACVRI signaling negatively regulates left-side determinants such as nodal and positively regulates lefty1. These functions maintain the midline, restrict expression of left-side markers, and are required for left-right pattern formation during embryogenesis in the mouse.     

The lefty-related factor Xatv acts as a feedback inhibitor of nodal signaling in mesoderm induction and L-R axis development in xenopus

In mouse, lefty genes play critical roles in the left-right (L-R) axis determination pathway. Here, we characterize the Xenopus lefty-related factor antivin (Xatv). Xatv expression is first observed in the marginal zone early during gastrulation, later becoming restricted to axial tissues. During tailbud stages, axial expression resolves to the neural tube floorplate, hypochord, and (transiently) the notochord anlage, and is joined by dynamic expression in the left lateral plate mesoderm (LPM) and left dorsal endoderm. An emerging paradigm in embryonic patterning is that secreted antagonists regulate the activity of intercellular signaling factors, thereby modulating cell fate specification. Xatv expression is rapidly induced by dorsoanterior-type mesoderm inducers such as activin or Xnr2. Xatv is not an inducer itself, but antagonizes both Xnr2 and activin. Together with its expression pattern, this suggests that Xatv functions during gastrulation in a negative feedback loop with Xnrs to affect the amount and/or character of mesoderm induced. Our data also provide insights into the way that lefty/nodal signals interact in the initiation of differential L-R morphogenesis. Right-sided misexpression of Xnr1 (endogenously expressed in the left LPM) induces bilateral Xatv expression. Left-sided Xatv overexpression suppresses Xnr1/XPitx2 expression in the left LPM, and leads to severely disturbed visceral asymmetry, suggesting that active 'left' signals are critical for L-R axis determination in frog embryos. We propose that the induction of lefty/Xatv in the left LPM by nodal/Xnr1 provides an efficient self-regulating mechanism to downregulate nodal/Xnr1 expression and ensure a transient 'left' signal within the embryo.     

The ion channel polycystin-2 is required for left-right axis determination in mice

Generation of laterality depends on a pathway which involves the asymmetrically expressed genes nodal, Ebaf, Leftb, and Pitx2. In mouse, node monocilia are required upstream of the nodal cascade. In chick and frog, gap junctions are essential prior to node/organizer formation. It was hypothesized that differential activity of ion channels gives rise to unidirectional transfer through gap junctions, resulting in asymmetric gene expression. PKD2, which if mutated causes autosomal dominant polycystic kidney disease (ADPKD) in humans, encodes the calcium release channel polycystin-2. We have generated a knockout allele of Pkd2 in mouse. In addition to malformations described previously, homozygous mutant embryos showed right pulmonary isomerism, randomization of embryonic turning, heart looping, and abdominal situs. Leftb and nodal were not expressed in the left lateral plate mesoderm (LPM), and Ebaf was absent from floorplate. Pitx2 was bilaterally expressed in posterior LPM but absent anteriorly. Pkd2 was ubiquitously expressed at headfold and early somite stages, with higher levels in floorplate and notochord. The embryonic midline, however, was present, and normal levels of Foxa2 and shh were expressed, suggesting that polycystin-2 acts downstream or in parallel to shh and upstream of the nodal cascade.     

Distinct requirements for extra-embryonic and embryonic bone morphogenetic protein 4 in the formation of the node and primitive streak and coordination of left-right asymmetry in the mouse

In the mouse and chick embryo, the node plays a central role in generating left-right (LR) positional information. Using several different strategies, we provide evidence in the mouse that bone morphogenetic protein 4 (Bmp4) is required independently in two different sites for node morphogenesis and for LR patterning. Bmp4 expression in the trophoblast-derived extra-embryonic ectoderm is essential for the normal formation of the node and primitive streak. However, tetraploid chimera analysis demonstrates that Bmp4 made in epiblast-derived tissues is required for robust LR patterning, even when normal node morphology is restored. In the absence of embryonic Bmp4, the expression of left-side determinants such as Nodal and Lefty2 is absent in the left lateral plate mesoderm (LPM). Noggin-mediated inhibition of Bmp activity in cultured wild-type embryos results in suppression of Nodal expression in the LPM. Thus, unlike previous models proposed in the chick embryo in which Bmp4 suppresses left-sided gene expression, our results suggest that Bmp acts as a positive facilitator of the left-sided molecular cascade and is required for Nodal induction and maintenance in the left LPM.     

The Dynamic Right-to-Left Translocation of Cerl2 Is Involved in the Regulation and Termination of Nodal Activity in the Mouse Node

The determination of left-right body asymmetry in mouse embryos depends on the interplay of molecules in a highly sensitive structure, the node. Here, we show that the localization of Cerl2 protein does not correlate to its mRNA expression pattern, from 3-somite stage onwards. Instead, Cerl2 protein displays a nodal flow-dependent dynamic behavior that controls the activity of Nodal in the node, and the transmission of the laterality information to the left lateral plate mesoderm (LPM). Our results indicate that Cerl2 initially localizes and prevents the activation of Nodal genetic circuitry on the right side of the embryo, and later its right-to-left translocation shutdowns Nodal activity in the node. The consequent prolonged Nodal activity in the node by the absence of Cerl2 affects local Nodal expression and prolongs its expression in the LPM. Simultaneous genetic removal of both Nodal node inhibitors, Cerl2 and Lefty1, sustains even longer and bilateral this LPM expression.     

Left-right patterning of the mouse lateral plate requires nodal produced in the node

Initial determination of left-right (L-R) polarity in mammalian embryos takes place in the node. However, it is not known how asymmetric signals are generated in the node and transferred to the lateral plate mesoderm (LPM). Mice homozygous for a hypomorphic Nodal allele (Nodal(neo)) were generated and found to exhibit L-R defects, including right isomerism. Although the mutant embryos express Nodal at gastrulation stages, the subsequent expression of this gene in the node and left LPM is lost. A transgene that conferred Nodal expression specifically in the node rescued the L-R defects of the Nodal(neo/neo) embryos. Conversely, ectopic expression of the Nodal inhibitor Lefty2 in the node of Nodal(neo/+) embryos resulted in a phenotype similar to that of the Nodal(neo/neo) mutant. These results indicate that Nodal produced in the node is required for expression of Nodal and other left side-specific genes in the LPM.     

Expression and function of mouse Sox17 gene in the specification of gallbladder/bile-duct progenitors during early foregut morphogenesis

In early-organogenesis-stage mouse embryos, the posteroventral foregut endoderm adjacent to the heart tube gives rise to liver, ventral pancreas and gallbladder. Hepatic and pancreatic primordia become specified in the posterior segment of the ventral foregut endoderm at early somite stages. The mechanisms for demarcating gallbladder and bile duct primordium, however, are poorly understood. Here, we demonstrate that the gallbladder and bile duct progenitors are specified in the paired lateral endoderm domains outside the heart field at almost the same timing as hepatic and pancreatic induction. In the anterior definitive endoderm, Sox17 reactivation occurs in a certain population within the most lateral domains posterolateral to the anterior intestinal portal (AIP) lip on both the left and right sides. During foregut formation, the paired Sox17-positive domains expand ventromedially to merge in the midline of the AIP lip and become localized between the liver and pancreatic primordia. In Sox17-null embryos, these lateral domains are missing, resulting in a complete loss of the gallbladder/bile-duct structure. Chimera analyses revealed that Sox17-null endoderm cells in the posteroventral foregut do not display any gallbladder/bile-duct molecular characters. Our findings show that Sox17 functions cell-autonomously to specify gallbladder/bile-duct in the mouse embryo.     

The left-right axis in the mouse: from origin to morphology

The past decade or so has seen rapid progress in our understanding of how left-right (LR) asymmetry is generated in vertebrate embryos. However, many important questions about this process remain unanswered. Although a leftward flow of extra-embryonic fluid in the node cavity (nodal flow) is likely to be the symmetry-breaking event, at least in the mouse embryo, it is not yet known how this flow functions or how the asymmetric signal generated in the node is transferred to the lateral plate. The final step in left-right patterning - translation of the asymmetric signal into morphology - is also little understood.