Planar Cell Polarity Pathway (planar + cell_polarity_pathway)

Distribution by Scientific Domains


Selected Abstracts


Nucleoredoxin regulates the Wnt/planar cell polarity pathway in Xenopus

GENES TO CELLS, Issue 9 2008
Yosuke Funato
The Wnt signaling pathway is conserved across species, and is essential for early development. We previously identified nucleoredoxin (NRX) as a protein that interacts with dishevelled (Dvl) in vivo to negatively regulate the Wnt/,-catenin pathway. However, whether NRX affects another branch of the Wnt pathway, the Wnt/planar cell polarity (PCP) pathway, remains unclear. Here we show that NRX regulates the Wnt/PCP pathway. In Xenopus laevis, over-expression or depletion of NRX by injection of NRX mRNA or antisense morpholino oligonucleotide, respectively, yields the bent-axis phenotype that is typically observed in embryos with abnormal PCP pathway activity. In co-injection experiments of Dvl and NRX mRNA, NRX suppresses the Dvl-induced bent-axis phenotype. Over-expression or depletion of NRX also suppresses the convergent extension movements that are believed to underlie normal gastrulation. We also found that NRX can inhibit Dvl-induced up-regulation of c-Jun phosphorylation. These results indicate that NRX plays crucial roles in the Wnt/PCP pathway through Dvl and regulates Xenopus gastrulation movements. [source]


Sfrp1, Sfrp2, and Sfrp5 regulate the Wnt/,-catenin and the planar cell polarity pathways during early trunk formation in mouse

GENESIS: THE JOURNAL OF GENETICS AND DEVELOPMENT, Issue 2 2008
Wataru Satoh
The secreted frizzled-related protein gene family encodes proteins that regulate Wnt signaling. Msx1 in situ hybridization of 9.5 days post coitus mouse embryos showing normal neural tube development in an Sfrp1; Sfrp2 double mutant (left) but severe neural tube defects in a Looptail (Lp/+); Sfrp1; Sfrp2 triple mutant (right). These findings suggest that Sfrps regulate the Wnt planar cell polarity pathway. See Satoh et al. in this issue. [source]


Neurulation in the cranial region , normal and abnormal

JOURNAL OF ANATOMY, Issue 5 2005
Andrew J. Copp
Abstract Cranial neurulation is the embryonic process responsible for formation of the brain primordium. In the mouse embryo, cranial neurulation is a piecemeal process with several initiation sites and two neuropores. Variation in the pattern of cranial neurulation occurs in different mouse strains, and a simpler version of this morphogenetic scheme has been described in human embryos. Exencephaly is more common in females than in males, an unexplained phenomenon seen in both mice and humans. As the cranial neural tube closes, a critical morphogenetic event is the formation of dorsolateral bending points near the neural fold tips, which enables subsequent midline fusion of the neural folds. Many mutant and gene-targeted mouse strains develop cranial neural tube defects, and analysis of the underlying molecular defects identifies several requirements for normal dorsolateral bending. These include a functional actin cytoskeleton, emigration of the cranial neural crest, spatio-temporally regulated apoptosis, and a balance between cell proliferation and the onset of neuronal differentiation. A small number of mouse mutants exhibit craniorachischisis, a combined brain and spine neurulation defect. Recent studies show that disturbance of a single molecular signalling cascade, the planar cell polarity pathway, is implicated in mutants with this defect. [source]


Increasingly complex: New players enter the Wnt signaling network

BIOESSAYS, Issue 10 2002
Petra Pandur
Wnt proteins can activate different intracellular signaling cascades in various organisms by interacting with receptors of the Frizzled family. The first identified Wnt signaling pathway, the Wnt/,-catenin pathway, has been studied in much detail and is highly conserved among species. As to non-canonical Wnt pathways, the current situation is more nebulous partly because the intracellular mediators of this pathway are not yet fully understood and, in some cases, even identified. However, there are increasing data that prove the existence of non-canonical Wnt signaling and demonstrate its involvement in different developmental processes. In vertebrates, Wnt-11 and Wnt-5A can activate the Wnt/JNK pathway, which resembles the planar cell polarity pathway in Drosophila. The Wnt/Ca2+ -pathway has only been described in Xenopus and zebrafish so far and it is unclear whether it also exists in other organisms. Two recent papers provide us with new insight into non-canonical Wnt signaling by (1) presenting a new intracellular mediator of non-canonical signaling in Xenopus1 and (2) implicating the existence of an additional non-canonical Wnt signaling pathway in flies.2 BioEssays 24:881,884, 2002. © 2002 Wiley Periodicals, Inc. [source]


Toward understanding the genetic basis of neural tube defects

CLINICAL GENETICS, Issue 4 2007
Z Kibar
Neural tube defects (NTDs) represent a common group of severe congenital malformations that result from failure of neural tube closure during early development. Their etiology is quite complex involving environmental and genetic factors and their underlying molecular and cellular pathogenic mechanisms remain poorly understood. Animal studies have recently demonstrated an essential role for the planar cell polarity pathway (PCP) in mediating a morphogenetic process called convergent extension during neural tube formation. Alterations in members of this pathway lead to NTDs in vertebrate models, representing novel and exciting candidates for human NTDs. Genetic studies in NTDs have focused mainly on folate-related genes based on the finding that perinatal folic acid supplementation reduces the risk of NTDs by 60,70%. A few variants in these genes have been found to be significantly associated with an increased risk for NTDs. The candidate gene approach investigating genes involved in neurulation has failed to identify major causative genes in the etiology of NTDs. Despite this history of generally negative findings, we are achieving a rapid and impressive progress in understanding the genetic basis of NTDs, based mainly on the powerful tool of animal models. [source]


Sfrp1, Sfrp2, and Sfrp5 regulate the Wnt/,-catenin and the planar cell polarity pathways during early trunk formation in mouse

GENESIS: THE JOURNAL OF GENETICS AND DEVELOPMENT, Issue 2 2008
Wataru Satoh
The secreted frizzled-related protein gene family encodes proteins that regulate Wnt signaling. Msx1 in situ hybridization of 9.5 days post coitus mouse embryos showing normal neural tube development in an Sfrp1; Sfrp2 double mutant (left) but severe neural tube defects in a Looptail (Lp/+); Sfrp1; Sfrp2 triple mutant (right). These findings suggest that Sfrps regulate the Wnt planar cell polarity pathway. See Satoh et al. in this issue. [source]