Determination of the vertebrate left-right body axis during embryogenesis results in asymmetric development and placement of most inner organs. Although the asymmetric Nodal cascade is conserved in all vertebrates, the mechanism of symmetry breakage has remained controversial. In mammalian and fish embryos, a cilia-driven leftward flow of extracellular fluid is required for initiation of the Nodal cascade. This flow is localized at the posterior notochord ("node") and Kupffer's vesicle, respectively. In frog and chick embryos, however, molecular asymmetries are required earlier, from cleavage stages through gastrulation. The validity of a cilia-based mechanism for all vertebrates therefore has been questioned. Here we show that a cilia-driven leftward flow precedes asymmetric nodal expression in the frog Xenopus. Motile monocilia emerged on the gastrocoel roof plate during neurulation and lengthened and polarized from an initially central position to the posterior pole of cells. Concomitantly, a robust leftward fluid flow developed from stage 15 onward, significantly before asymmetric nodal transcription started in the left-lateral-plate mesoderm at stage 19. Injection of 1.5% methylcellulose into the archenteron prevented leftward flow and resulted in laterality defects, demonstrating that the flow itself was required for asymmetric gene expression and organ placement.
Vertebrate laterality, which is manifested by asymmetrically placed organs [1], depends on asymmetric activation of the Nodal signaling cascade in the left lateral plate mesoderm [2]. In fish, amphibians, and mammals, a cilia-driven leftward flow of extracellular fluid acts upstream of the Nodal cascade [3-6]. The direct target of flow has remained elusive. In Xenopus, flow occurs at the gastrocoel roof plate (GRP) in the dorsal midline of the embryo [4, 7]. The GRP is bordered by a second, bilaterally symmetrical Nodal expression domain [8]. Here we identify the Nodal inhibitor Coco as a critical target of flow. Coco and Xenopus Nodal-related 1 (Xnr1) are coexpressed in the lateralmost ciliated GRP cells. Coco becomes downregulated on the left side of the GRP as a direct readout of flow. Ablation of flow prevented Coco repression, whereas Xnr1 expression was independent of flow. Loss of flow-induced laterality defects were rescued by knockdown of Coco on the left side. Parallel knockdown of Coco and Xnr1 in GRP cells restored laterality defects in flow-impaired embryos, demonstrating that Coco acted through GRP-expressed Xnr1. Coco thus acts as a critical target of flow, suggesting that symmetry is broken by flow-mediated left-asymmetric release of Nodal repression at the midline.
Polycystic diseases and left-right (LR) axis malformations are frequently linked to cilia defects. Renal cysts also arise in mice and frogs lacking Bicaudal C (BicC), a conserved RNA-binding protein containing K-homology (KH) domains and a sterile alpha motif (SAM). However, a role for BicC in cilia function has not been demonstrated. Here, we report that targeted inactivation of BicC randomizes left-right (LR) asymmetry by disrupting the planar alignment of motile cilia required for cilia-driven fluid flow. Furthermore, depending on its SAM domain, BicC can uncouple Dvl2 signaling from the canonical Wnt pathway, which has been implicated in antagonizing planar cell polarity (PCP). The SAM domain concentrates BicC in cytoplasmic structures harboring RNA-processing bodies (P-bodies) and Dvl2. These results suggest a model whereby BicC links the orientation of cilia with PCP, possibly by regulating RNA silencing in P-bodies.
SUMMARY The mammalian PCP pathway regulates diverse developmental processes requiring coordinated cellular movement, including neural tube closure and cochlear stereociliary orientation. Here, we show that epidermal wound repair is regulated by PCP signaling. Mice carrying mutant alleles of PCP genes Vangl2, Celsr1, PTK7, and Scrb1, and the transcription factor Grhl3, interact genetically, exhibiting failed wound healing, neural tube defects and disordered cochlear polarity. Using phylogenetic analysis, ChIP, and gene expression in Grhl3−/− mice, we identified RhoGEF19, a homologue of a RhoA activator involved in PCP signaling in Xenopus, as a direct target of GRHL3. Knockdown of Grhl3 or RhoGEF19 in keratinocytes induced defects in actin polymerisation, cellular polarity and wound healing, and re-expression of RhoGEF19 rescued these defects in Grhl3-kd cells. These results define a role for Grhl3 in PCP signaling, and broadly implicate this pathway in epidermal repair.
CorrectionsBIOCHEMISTRY. For the article ''Differential effects of a centrally acting fatty acid synthase inhibitor in lean and obese mice,'' by Monica V. Kumar, Teruhiko Shimokawa, Tim R. Nagy, and M. Daniel Lane, which appeared in number 4, February 19, 2002, of Proc. Natl. Acad. Sci. USA (99, 1921-1925, the authors note the following. ''Under a licensing agreement between FASgen, Inc., and The Johns Hopkins University, Dr. Lane is entitled to a share of royalty received by the University on sales of products that embody the technology described in this article. (98, 10687-10691; First Published August 28, 2001; 10.1073͞pnas.181354398), the authors note the following. In the Introduction and Discussion of our paper, we failed to reference a recent article by Rousseau et al.(1), which demonstrated that single point mutations can significantly perturb the equilibrium between monomeric and domain-swapped dimeric p13suc1. Rational methods were used to redesign p13suc1 from a fully monomeric protein (dissociation constant of Ϸ900 mM) to a fully dimeric protein (dissociation constant of Ϸ100 nM). Fig. 3 appeared incorrectly. The correct version of the figure and its legend appear below.
Leftward flow of extracellular fluid breaks the bilateral symmetry of most vertebrate embryos, manifested by the ensuing asymmetric induction of Nodal signaling in the left lateral plate mesoderm (LPM). Flow is generated by rotational beating of polarized monocilia at the posterior notochord (PNC; mammals), Kupffer's vesicle (KV; teleost fish) and the gastrocoel roof plate (GRP; amphibians). To manipulate flow in a defined way we cloned dynein heavy chain genes dnah5, 9 and 11 in Xenopus. dnah9 expression was closely related to motile cilia from neurulation onwards. Morphant tadpoles showed impaired epidermal ciliary beating. Leftward flow at the GRP was absent, resulting in embryos with loss of asymmetric marker gene expression. Remarkably, unilateral knockdown on the right side of the GRP did not affect laterality, while left-sided ablation of flow abolished marker gene expression. Thus, flow was required exclusively on the left side of the GRP to break symmetry in the frog. Our data suggest that the substrate of flow is generated within the GRP and not at its margin, disqualifying Nodal as a candidate morphogen.
Unlike lower vertebrates, mammals are unable to replace damaged mechanosensory hair cells (HCs) in the cochlea. Recently, ablation of the retinoblastoma protein (Rb) in undifferentiated mouse HC precursors was shown to cause cochlear HC proliferation and the generation of new HCs, raising the hope that inactivation of Rb in postmitotic HCs could trigger cell division and regenerate functional HCs postnatally. Here, we acutely inactivated Rb in nearly all cochlear HCs of newborn mice, using a newly developed HCspecific inducible Cre mouse line. Beginning 48 h after Rb deletion, Ϸ40% of HCs were in the S and M phases of the cell cycle, demonstrating an overriding role for Rb in maintaining the quiescent state of postnatal HCs. Unlike Rb-null HC precursors, such HCs failed to undergo cell division and died rapidly. HC clusters were restricted to the less differentiated cochlear regions, consistent with differentiation-dependent roles of Rb. Moreover, outer HCs expressed the maturation marker prestin, suggesting an embryonic time window for Rb-dependent HC specification. We conclude that Rb plays essential and age-dependent roles during HC proliferation and differentiation, and, in contrast to previous hypotheses, cell death after forced cell-cycle reentry presents a major challenge for mammalian HC regeneration from residual postnatal HCs. Genetic and environmental factors, such as noise and ototoxic drugs, can damage HCs, leading to their death and to permanent hearing loss. Mammalian HCs are not regenerated, whereas nonmammalian vertebrates are able to replenish lost sensory HCs by proliferation and differentiation of nearby SCs within the sensory epithelium (5-7). The critical difference in the regenerative ability of mammalian cochleae and nonmammalian hearing organs appears to be their proliferative responsiveness after trauma.A key inhibitor of proliferation is the retinoblastoma protein (Rb), a member of the family of pocket domain proteins. These proteins bind to E2F transcription factors and can repress genes required during the S phase, thereby maintaining cells in a quiescent state (reviewed in ref. 8). Rb is expressed in embryonic and postnatal HCs; its absence in HC precursors of mice led to the production of supernumerary HCs that appeared functional, demonstrating that mammalian HC precursors can indeed be manipulated to proliferate (9, 10). However, HC injury typically occurs after birth; our aim was therefore to determine whether the inactivation of Rb could trigger cell-cycle reentry in postnatal HCs. The consequences of Rb loss in vivo have been studied in many tissues, using mouse models (11); in this study, we inactivated Rb in postnatal HCs, using a newly developed tamoxifen-inducible Cre mouse line. We observed that HCs rapidly reentered the cell cycle after the loss of Rb but died without generating supernumerary HCs. Thus, forced cell-cycle reentry by Rb inactivation had an entirely different outcome in postnatal HCs than in embryonic precursor cells for HCs and SCs, having limited use for ...
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