Wnt/β-catenin signaling plays a central role in development and is also involved in a diverse array of diseases. Binding of Wnts to the coreceptors Frizzled and LRP6/5 leads to phosphorylation of PPPSPxS motifs in the LRP6/5 intracellular region and the inhibition of GSK3β bound to the scaffold protein Axin. However, it remains unknown how GSK3β is specifically inhibited upon Wnt stimulation. Here, we show that overexpression of the intracellular region of LRP6 containing a Ser/Thr rich cluster and a PPPSPxS motif impairs the activity of GSK3β in cells. Synthetic peptides containing the PPPSPxS motif strongly inhibit GSK3β in vitro only when they are phosphorylated. Microinjection of these peptides into Xenopus embryos confirms that the phosphorylated PPPSPxS motif potentiates Wnt-induced second body axis formation. In addition, we show that the Ser/Thr rich cluster of LRP6 plays an important role in LRP6 binding to GSK3β. These observations demonstrate that phosphorylated LRP6/5 both recruits and directly inhibits GSK3β using two distinct portions of its cytoplasmic sequence, and suggest a novel mechanism of activation in this signaling pathway.
Wnt proteins control diverse biological processes through β-catenin-dependent canonical signaling and β-catenin-independent non-canonical signaling. The mechanisms by which these signaling pathways are differentially triggered and controlled are not fully understood. Dishevelled (Dvl) is a scaffold protein that serves as the branch point of these pathways. Here, we show that cholesterol selectively activates canonical Wnt signaling over non-canonical signaling under physiological conditions by specifically facilitating the membrane recruitment of the PDZ domain of Dvl and its interaction with other proteins. Single molecule imaging analysis shows that cholesterol is enriched around the Wnt-activated Frizzled and low-density lipoprotein receptor-related protein 5/6 receptors and plays an essential role for Dvl-mediated formation and maintenance of the canonical Wnt signaling complex. Collectively, our results suggest a new regulatory role of cholesterol in Wnt signaling and a potential link between cellular cholesterol levels and the balance between canonical and non-canonical Wnt signaling activities.
Cellular proteins are degraded in either proteasomes or lysosomes depending on the types of ubiquitin chains that covalently modify them. It is not known whether the choice between these two pathways is physiologically regulated. The Lys48-polyubiquitin chain is the major signal directing proteins for degradation in proteasomes. Here, we report the unexpected finding that canonical Wnt signaling translocates some K48-linked polyubiquitinated proteins to the endolysosomal pathway. Proteasomal target proteins, such as b-catenin, Smad1, and Smad4, were targeted into endolysosomes in a process dependent on GSK3 activity. Relocalization was also dependent on Axin1 and the multivesicular body (MVB) proteins HRS/Vps27 and Vps4. The Wnt-induced accumulation of K48-linked polyubiquitinated proteins in endolysosomal organelles was accompanied by a transient decrease in cellular levels of free mono-ubiquitin, which may contribute to Wnt-regulated stabilization of proteins (Wnt/ STOP). We conclude that Wnt redirects Lys48-polyubiquitinated proteins that are normally degraded in proteasomes to endolysosomes.
Wnt signaling is implicated in a variety of developmental and pathological processes. The molecular mechanisms governing the secretion of Wnt ligands remain to be elucidated. Wntless, an evolutionarily conserved multipass transmembrane protein, is a dedicated secretion factor of Wnt proteins that participates in Drosophila melanogaster embryogenesis. In this study, we show that Xenopus laevis Wntless (XWntless) regulates the secretion of a specific Wnt ligand, XWnt4, and that this regulation is specifically required for eye development in Xenopus. Moreover, the Retromer complex is required for XWntless recycling to regulate the XWnt4-mediated eye development. Inhibition of Retromer function by Vps35 morpholino (MO) resulted in various Wnt deficiency phenotypes, affecting mesoderm induction, gastrulation cell movements, neural induction, neural tube closure, and eye development. Overexpression of XWntless led to the rescue of Vps35 MO-mediated eye defects but not other deficiencies. These results collectively suggest that XWntless and the Retromer complex are required for the efficient secretion of XWnt4, facilitating its role in Xenopus eye development.The Wnt family of glycoproteins comprises one of the largest families of paracrine factors essential for embryonic development and adult tissue homeostasis (reviewed at the Wnt Homepage, http://www.stanford.edu/ϳrnusse/wntwindow .html). It regulates several aspects of biological processes, including cell fate specification, proliferation, migration, and polarity formation (29, 48). The Wnt signaling pathway is initiated by Wnt ligands secreted from Wnt-producing cells. The ligands bind to frizzled receptors and coreceptors expressed on the receiving cells. Wnt ligand perception (5,24,46,49), signaling cascades into receiving cells (8,27), and the consequences of gene expression (17) or cytoskeletal changes (36) are well documented in various contexts. However, relatively limited information is available about the processes in Wnt-producing cells and extracellular spaces. The establishment of the concentration gradient of the Wnt ligand in the extracellular space is mediated by lipoprotein particle formation (33). The Retromer complex is additionally required in Wnt-producing cells and for long-range secretion of Wnt (12). Porcupine is essential for posttranslational modifications, which may be essential for the proper folding and secretion of Wnt ligands (28).Recent achievements in Drosophila melanogaster genetics and genomic RNA interference screening have revealed the existence of a new component of the Wnt secretory pathway, specifically, a dedicated secretion factor of Wg designated Wntless (2), Evi (3), or Sprinter (16). Wntless is an evolutionarily conserved multipass transmembrane protein required solely for Wg secretion. Wntless is not essential for the palmitoylation of Wg, indicating that it does not act on functional Wg production, like Porcupine, another evolutionarily conserved multipass transmembrane protein. Wntless is a regulator of intracellular W...
Rab3d is a member of the Ras-related small GTPase family of secretory Rab, Rab3. In this study, we showed that Xenopus Rab3d is expressed specifically in the anterior border of the neural plate when the neural plate converges and folds to initiate neural tube formation. Morpholino-mediated knockdown of Rab3d resulted in neurulation defects both in neural plate convergence and folding. Interestingly, perturbation of BMP signaling rescued neurulation defects of Rab3d morphants, suggesting that Rab3d inhibits BMP signaling during neurulation. By secretion assay in the Xenopus animal cap, we found that Rab3d specifically regulates secretion of a BMP antagonist, Noggin, but not Chordin and Wnts. We also found that Rab3d is co-localized with Noggin and that this interaction is dependent on the GTP/GDP cycle of Rab3d. Collectively, these findings suggest that Rab3d-mediated secretion regulation of a BMP antagonist, Noggin, is one of the mechanisms of BMP antagonism during Xenopus anterior neurulation. Developmental
N6-methyladenosine (m6A) is the most prevalent internal RNA modification, and has a widespread impact on mRNA stability and translation. Methyltransferase-like 3 (Mettl3) is a responsible methyltransferase for RNA m6A modification, and it is essential for early embryogenesis before or during gastrulation in mice and zebrafish. However, due to the early embryonic lethality, loss of function phenotypes of Mettl3 beyond gastrulation, especially during neurulation stages when spatial neural patterning takes place, remains elusive. Here, we address multiple roles of Mettl3 during Xenopus neurulation on the anteroposterior neural patterning, neural crest specification and neuronal cell differentiation. Knockdown of Mettl3 causes anteriorization of neurula and tailbud embryos along with the loss of neural crest and neuronal cells. Knockdown of the m6A reader Ythdf1 and mRNA degradation factors, such as 3’ to 5’ exonuclease complex component Lsm1 or mRNA uridylation enzyme Tut7, also show a similar neural patterning defects, suggesting that m6A-dependent mRNA destabilization regulates spatial neural patterning in Xenopus . We also address that canonical WNT signaling is inhibited in Mettl3 morphants, which may underlie the neural patterning defects of the morphants. Altogether, this study reveals functions of Mettl3 during spatial neural patterning in Xenopus .
FTO and ALKBH5 are the two enzymes responsible for mRNA demethylation. Hence, the functional study of FTO has been focused on its mechanistic role in dynamic mRNA modification, and how this post-transcriptional regulation modulates signaling pathways. Here, we report that the functional landscape of FTO is largely associated with WNT signaling pathways but in a manner that is independent of its enzymatic activity. Re-analyses of public datasets identified the bifurcation of canonical and noncanonical WNT pathways as the major role of FTO. In FTO-depleted cells, we find that the canonical WNT/β-Catenin signaling is attenuated in a non-cell autonomous manner via the up-regulation of DKK1. Simultaneously, this up-regulation of DKK1 promotes cell migration via activating the noncanonical WNT/PCP pathway. Unexpectedly, this regulation of DKK1 is independent of its RNA methylation status but operates at the transcriptional level, revealing a noncanonical function of FTO in gene regulation. In conclusion, this study places the functional context of FTO at the branch point of multiple WNT signaling pathways and extends its mechanistic role in gene regulation.
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