Anja I. H. Hagemann

Filopodia-based Wnt transport during vertebrate tissue patterning

Paracrine Wnt/β-catenin signalling is important during developmental processes, tissue regeneration and stem cell regulation. Wnt proteins are morphogens, which form concentration gradients across responsive tissues. Little is known about the transport mechanism for these lipid-modified signalling proteins in vertebrates. Here we show that Wnt8a is transported on actin-based filopodia to contact responding cells and activate signalling during neural plate formation in zebrafish. Cdc42/N-Wasp regulates the formation of these Wnt-positive filopodia. Enhanced formation of filopodia increases the effective signalling range of Wnt by facilitating spreading. Consistently, reduction in filopodia leads to a restricted distribution of the ligand and a limited signalling range. Using a simulation, we provide evidence that such a short-range transport system for Wnt has a long-range signalling function. Indeed, we show that a filopodia-based transport system for Wnt8a controls anteroposterior patterning of the neural plate during vertebrate gastrulation.

Nuclear accumulation of Smad complexes occurs only after the midblastula transition in Xenopus

Activin and the Nodal-related proteins induce mesendodermal tissues during Xenopus development. These signals act through specific receptors to cause the phosphorylation, at their carboxyl termini, of Smad2 and Smad3. The phosphorylated Smad proteins form heteromeric complexes with Smad4 and translocate into the nucleus to activate the transcription, after the midblastula transition, of target genes such as Xbra and goosecoid (gsc). In this paper we use bimolecular fluorescence complementation (BiFC) to study complex formation between Smad proteins both in vivo and in response to exogenous proteins. The technique has allowed us to detect Smad2-Smad4 heteromeric interactions during normal Xenopus development and Smad2 and Smad4 homo- and heteromers in isolated Xenopus blastomeres. Smad2-Smad2 and Smad2-Smad4 complexes accumulate rapidly in the nuclei of responding cells following Activin treatment, whereas Smad4 homomeric complexes remain cytoplasmic. When cells divide, Smad2-Smad4 complexes associate with chromatin, even in the absence of ligand. Our observation that Smad2-Smad4 complexes accumulate in the nucleus only after the midblastula transition, irrespective of the stage at which cells were treated with Activin, may shed light on the mechanisms of developmental timing.

The Tale of the Three Brothers - Shh, Wnt, and Fgf during Development of the Thalamus.

The thalamic complex is an essential part of the brain that requires a combination of specialized activities to attain its final complexity. In the following review we will describe the induction process of the mid-diencephalic organizer (MDO) where three different signaling pathways merge: Wnt, Shh, and Fgf. Here, we dissect the function of each signaling pathway in the thalamus in chronological order of their appearance. First we describe the Wnt mediated induction of the MDO and compartition of the caudal forebrain, then the Shh mediated determination of proneural gene expression before discussing recent progress in characterizing Fgf function during thalamus development. Then, we focus on transcription factors, which are regulated by these pathways and which play a pivotal role in neurogenesis in the thalamus. The three signaling pathways act together in a strictly regulated chronology to orchestrate the development of the entire thalamus.

Rab5-mediated endocytosis of activin is not required for gene activation or long-range signalling in Xenopus.

Morphogen gradients provide positional cues for cell fate specification and tissue patterning during embryonic development. One important aspect of morphogen function, the mechanism by which long-range signalling occurs, is still poorly understood. In Xenopus, members of the TGF-β family such as the nodal-related proteins and activin act as morphogens to induce mesoderm and endoderm. In an effort to understand the mechanisms and dynamics of morphogen gradient formation, we have used fluorescently labelled activin to study ligand distribution and Smad2/Smad4 bimolecular fluorescence complementation (BiFC) to analyse, in a quantitative manner, the cellular response to induction. Our results indicate that labelled activin travels exclusively through the extracellular space and that its range is influenced by numbers of type II activin receptors on responding cells. Inhibition of endocytosis, by means of a dominant-negative form of Rab5, blocks internalisation of labelled activin, but does not affect the ability of cells to respond to activin and does not significantly influence signalling range. Together, our data indicate that long-range signalling in the early Xenopus embryo, in contrast to some other developmental systems, occurs through extracellular movement of ligand. Signalling range is not regulated by endocytosis, but is influenced by numbers of cognate receptors on the surfaces of responding cells.

Visualizing protein interactions by bimolecular fluorescence complementation in Xenopus.

Bimolecular fluorescence complementation (BiFC) provides a simple and direct way to visualise protein-protein interactions in vivo and in real-time. In this article, we describe methods by which one can implement this approach in embryos of the South African claw-toed frog Xenopus laevis. We have made use of Venus, an improved version of yellow fluorescent protein (YFP), so as to achieve rapid detection of protein interactions. To suppress spontaneous interactions between the N- and C-terminal fragments of Venus, a point mutation (T153M) was introduced into the N-terminal fragment. We have used this reagent to monitor signalling by members of the transforming growth factor type beta family in cells of the Xenopus embryo.

Understanding how morphogens work

In this article, we describe the mechanisms by which morphogens in the Xenopus embryo exert their long-range effects. Our results are consistent with the idea that signalling molecules such as activin and the nodal-related proteins traverse responding tissue not by transcytosis or by cytonemes but by movement through the extracellular space. We suggest, however, that additional experiments, involving real-time imaging of morphogens, are required for a real understanding of what influences signalling range and the shape of a morphogen gradient.

Tyrosine phosphorylation of LRP6 by Src and Fer inhibits Wnt/β‐catenin signalling

Low‐density lipoprotein receptor‐related proteins 5 and 6 (LRP5/6) function as transmembrane receptors to transduce Wnt signals. A key mechanism for signalling is Wnt‐induced serine/threonine phosphorylation at conserved PPPSPxS motifs in the LRP6 cytoplasmic domain, which promotes pathway activation. Conserved tyrosine residues are positioned close to all PPPSPxS motifs, which suggests they have a functional significance. Using a cell culture‐based cDNA expression screen, we identified the non‐receptor tyrosine kinases Src and Fer as novel LRP6 modifiers. Both Src and Fer associate with LRP6 and phosphorylate LRP6 directly. In contrast to the known PPPSPxS Ser/Thr kinases, tyrosine phosphorylation by Src and Fer negatively regulates LRP6‐Wnt signalling. Epistatically, they function upstream of β‐catenin to inhibit signalling and in agreement with a negative role in regulating LRP6, MEF cells lacking these kinases show enhanced Wnt signalling. Wnt3a treatment of cells enhances tyrosine phosphorylation of endogenous LRP6 and, mechanistically, Src reduces cell surface LRP6 levels and disrupts LRP6 signalosome formation. Interestingly, CK1γ inhibits Fer‐induced LRP6 phosphorylation, suggesting a mechanism whereby CK1γ acts to de‐represses inhibitory LRP6 tyrosine phosphorylation. We propose that LRP6 tyrosine phosphorylation by Src and Fer serves a negative regulatory function to prevent over‐activation of Wnt signalling at the level of the Wnt receptor, LRP6.

Secreted frizzled-related protein 2 (sFRP2) redirects non-canonical Wnt signaling from Fz7 to Ror2 during vertebrate gastrulation

Convergent extension movements during vertebrate gastrulation require a balanced activity of non-canonical Wnt signaling pathways, but the factors regulating this interplay on the molecular level are poorly characterized. Here we show that sFRP2, a member of the secreted frizzled-related protein (sFRP) family, is required for morphogenesis and papc expression during Xenopus gastrulation. We further provide evidence that sFRP2 redirects non-canonical Wnt signaling from Frizzled 7 (Fz7) to the receptor tyrosine kinase-like orphan receptor 2 (Ror2). During this process, sFRP2 promotes Ror2 signal transduction by stabilizing Wnt5a-Ror2 complexes at the membrane, whereas it inhibits Fz7 signaling, probably by blocking Fz7 receptor endocytosis. The cysteine-rich domain of sFRP2 is sufficient for Ror2 activation, and related sFRPs can substitute for this function. Notably, direct interaction of the two receptors via their cysteine-rich domains also promotes Ror2-mediated papc expression but inhibits Fz7 signaling. We propose that sFRPs can act as a molecular switch, channeling the signal input for different non-canonical Wnt pathways during vertebrate gastrulation.

The clathrin adaptor-protein subunit ap2m1 regulates canonical Wnt signalling in early neural development of the zebrafish

inal Nucleus (MTN). Analyzes of OC mutant fetuses at e9.5 indicated that the MTN was lost in the absence of OC factors. Therefore, we hypothesize a non cell-autonomous role of the OC factors in LC development: proper development of the MTN would be essential for the maintenance of the LC, potentially via BDNF secretion. A hindbrain slice culture model has been developed to test this hypothesis. These results indicate that the OC factors are essential regulators of the development of catecholaminergic populations and suggest the existence of a molecular crosstalk between the MTN and the LC during development.

WITHDRAWN: Long-range signalling of TGF-β type morphogens in the Xenopus embryo

Many experiments have demonstrated that patterning information in the sea urchin embryo is distributed throughout the ectoderm. These spatial cues are passed onto the mesoderm to correctly pattern the bilaterally symmetric larval skeleton. Previous data have shown that exposure to metals (such as nickel and zinc) can disrupt patterning information within the ectoderm, presumably due to their ability to interfere with calcium transport, resulting in mispatterned embryos with radialized skeletons. To test the hypothesis that the proper distribution of skeletal patterning information within the sea urchin ectoderm is dependent on calcium signaling, we treated embryos with an inhibitor of IP3-mediated calcium release, Xestospongin C. Our data show that Xestospongin C exposure disrupts ectodermal patterning, producing embryos with radially symmetric skeletons. Normal skeletal patterning in radialized embryos can be rescued by treatment with the calcium ionophore ionomycin. More intriguingly, radialized embryos can also be rescued by surgical bisection along the animal–vegetal axis at the mesenchyme blastula stage, followed by recovery in the presence of calcium. However, simply removing calcium from the environment during recovery was sufficient to block the rescue of skeletal patterning in bisected radialized embryos. These results suggest that it is not the wound healing process itself, but rather the presence of calcium, which is responsible for the rescue of patterning. Together, these data reveal a critical role for calcium signaling, not directly for skeletogenesis but rather for the distribution of skeletal patterning information throughout the sea urchin ectoderm.