The cytoskeletal protein Zyxin inhibits Shh signaling during the CNS patterning in Xenopus laevis through interaction with the transcription factor Gli1.

Zyxin is a cytoskeletal protein that controls cell movements by regulating actin filaments assembly, but it can also modulate gene expression owing to its interactions with the proteins involved in signaling cascades. Therefore, identification of proteins that interact with Zyxin in embryonic cells is a promising way to unravel mechanisms responsible for coupling of two major components of embryogenesis: morphogenetic movements and cell differentiation. Now we show that in Xenopus laevis embryos Zyxin can bind to and suppress activity of the primary effector of Sonic hedgehog (Shh) signaling cascade, the transcription factor Gli1. By using loss- and gain-of-function approaches, we demonstrate that Zyxin is essential for reduction of Shh signaling within the dorsal part of the neural tube of X. laevis embryo. Thus, our finding discloses a novel function of Zyxin in fine tuning of the central neural system patterning which is based on the ventral-to-dorsal gradient of Shh signaling.

Cytoskeletal Protein Zyxin Inhibits the Activity of Genes Responsible for Embryonic Stem Cell Status.

Zyxin is a cytoskeletal LIM-domain protein that regulates actin cytoskeleton assembly and gene expression. In the present work, we find that zyxin downregulation in Xenopus laevis embryos reduces the expression of numerous genes that regulate cell differentiation, but it enhances that of several genes responsible for embryonic stem cell status, specifically klf4, pou5f3.1, pou5f3.2, pou5f3.3, and vent2.1/2. For pou5f3 family genes (mammalian POU5F1/OCT4 homologs), we show that this effect is the result of mRNA stabilization due to complex formation with the Y-box protein Ybx1. When bound to Ybx1, zyxin interferes with the formation of these complexes, thereby stimulating pou5f3 mRNA degradation. In addition, in zebrafish embryos and human HEK293 cells, zyxin downregulation increases mRNA levels of the pluripotency genes KLF4, NANOG, and POU5F1/OCT4. Our findings indicate that zyxin may play a role as a switch among morphogenetic cell movement, differentiation, and embryonic stem cell status.

Noggin4 is a long-range inhibitor of Wnt8 signalling that regulates head development in Xenopus laevis.

Noggin4 is a Noggin family secreted protein whose molecular and physiological functions remain unknown. In this study, we demonstrate that in contrast to other Noggins, Xenopus laevis Noggin4 cannot antagonise BMP signalling; instead, it specifically binds to Wnt8 and inhibits the Wnt/ß -catenin pathway. Live imaging demonstrated that Noggin4 diffusivity in embryonic tissues significantly exceeded that of other Noggins. Using the Fluorescence Recovery After Photobleaching (FRAP) assay and mathematical modelling, we directly estimated the affinity of Noggin4 for Wnt8 in living embryos and determined that Noggin4 fine-tune the Wnt8 posterior-to-anterior gradient. Our results suggest a role for Noggin4 as a unique, freely diffusing, long-range inhibitor of canonical Wnt signalling, thus explaining its ability to promote head development.

The LIM-domain protein Zyxin binds the homeodomain factor Xanf1/Hesx1 and modulates its activity in the anterior neural plate of Xenopus laevis embryo.

The question of how subdivision of embryo into cell territories acquiring different fates is coordinated with morphogenetic movements shaping the embryonic body still remains poorly resolved. In the present report, we demonstrate that a key regulator of anterior neural plate patterning, the homeodomain transcriptional repressor Xanf1/Hesx1, can bind to the LIM-domain protein Zyxin, which is known to regulate cell morphogenetic movements via influence on actin cytoskeleton dynamics. Using a set of deletion mutants, we found that the Engrailed-type repressor domain of Xanf1 and LIM2-domain of Zyxin are primarily responsible for interaction of these proteins. We also demonstrate that Zyxin overexpression in Xenopus embryos elicits effects similar to those observed in embryos with downregulated Xanf1. In contrast, when the repressor-fused variant of Zyxin is expressed, the forebrain enlargements typical for embryos overexpressing Xanf1 develop. These results are consistent with a possible role of Zyxin as a negative modulator of Xanf1 transcriptional repressing activity.

Regulation of mitochondria distribution by RhoA and formins.

The distribution of mitochondria is strictly controlled by the cell because of their vital role in energy supply, regulation of cytosolic Ca2+ concentration and apoptosis. We employed cultured mammalian CV-1 cells and Drosophila BG2-C2 neuronal cells with enhanced green fluorescent protein (EGFP)-tagged mitochondria to investigate the regulation of their movement and anchorage. We show here that lysophosphatidic acid (LPA) inhibits fast mitochondrial movements in CV-1 cells acting through the small GTPase RhoA. The action of RhoA is mediated by its downstream effectors: formin-homology family members mDia1 in mammalian cells and diaphanous in Drosophila. Overexpression of constitutively active mutant forms of formins leads to dramatic loss of mitochondrial motility and to their anchorage to actin microfilaments. Conversely, depletion of endogenous diaphanous protein in BG2-C2 cells by RNA interference (RNAi) stimulates the mitochondrial movement. These effects are not simply explained by increased cytoplasm viscosity resulting from an increased F-actin concentration since stimulators of Arp2/3-dependent actin polymerization and jasplakinolide do not cause inhibition. The observed effects are highly specific to mitochondria since perturbations of diaphanous or mDia1 have no effect on movement of other membrane organelles. Thus, mitochondrial movement is controlled by the small GTPase RhoA and this control is mediated by formins.

The tetrameric molecule of conventional kinesin contains identical light chains.

Conventional kinesin is a multifunctional motor protein that transports numerous organelles along microtubules. The specificity of kinesin-cargo binding is thought to depend on the type(s) of light chains that a kinesin molecule contains. We have shown previously that different isoforms of kinesin light chains are associated with different types of cargo, mitochondria and membranes of the Golgi complex. Here, we provide evidence that the two light chains present within each kinesin molecule are always of the same type. Further, we demonstrate that kinesin heavy chains interact with nascent light-chain polypeptides on ribosomes. These data suggest that incorporation of the two identical light chains into a single kinesin molecule most likely occurs cotranslationally.