Brain enlargement with rostral bias in larvae from a spontaneously occurring female variant line of Xenopus; role of aberrant embryonic Wnt/ß-catenin signaling.

Increased brain size and its rostral bias are hallmarks of vertebrate evolution, but the underlying developmental and genetic basis remains poorly understood. To provide clues to understanding vertebrate brain evolution, we investigated the developmental mechanisms of brain enlargement observed in the offspring of a previously unrecognized, spontaneously occurring female variant line of Xenopus that appears to reflect a genetic variation. Brain enlargement in larvae from this line showed a pronounced rostral bias that could be traced back to the neural plate, the primordium of the brain. At the gastrula stage, the Spemann organizer, which is known to induce the neural plate from the adjacent dorsal ectoderm and give it the initial rostrocaudal patterning, was expanded from dorsal to ventral in a large proportion of the offspring of variant females. Consistently, siamois expression, which is required for Spemann organizer formation, was expanded laterally from dorsal to ventral at the blastula stage in variant offspring. This implies that the active region of the Wnt/ß-catenin signaling pathway was similarly expanded in advance on the dorsal side, as siamois is a target gene of this pathway. Notably, the earliest detectable change in variant offspring was in fertilized eggs, in which maternal wnt11b mRNA, a candidate dorsalizing factor responsible for activating Wnt/ß-catenin signaling in the dorsal embryonic region, had a wider distribution in the vegetal cortical cytoplasm. Since lateral spreading of wnt11b mRNA, and possibly that of other potential maternal dorsalizing factors in these eggs, is expected to facilitate lateral expansion of the active region of the Wnt/ß-catenin pathway during subsequent embryonic stages, we concluded that aberrant Wnt/ß-catenin signaling could cause rostral-biased brain enlargement via expansion of siamois expression and consequent expansion of the Spemann organizer in Xenopus. Our studies of spontaneously occurring variations in brain development in Xenopus would provide hints for uncovering genetic mutations that drive analogous morphogenetic variations during vertebrate brain evolution.

FGF/MAPK/Ets signaling in Xenopus ectoderm contributes to neural induction and patterning in an autonomous and paracrine manner, respectively.

FGF and anti-BMP signals from the Spemann organizer of mesodermal origin are essential for Xenopus neural development from gastrula ectoderm. However, the detailed cellular and molecular mechanisms of signaling, especially those underlying the neural induction process, are still controversial. We show here that the expression of early neural marker genes such as sox2 and otx2 is suppressed both in vivo and in vitro, when ectoderm cells are loaded with a dominant-negative construct of Ets transcription factors or a translation-blocking antisense FGF2 MO or FGF8 MO, respectively. This indicates that the expression of these FGF signaling molecules in ectoderm cells contributes significantly to neural induction, in contrast to the "neural default model" that has been emphasized, in which anti-BMP signaling from the organizer plays a major role in the neural induction in Xenopus. Our results indicate that cell-autonomous FGF signaling between ectoderm cells, rather than paracrine signaling from organizer cells, directly induces the expression of sox2 and otx2 via the FGF2, FGF8/MAPK/Ets pathway at very low signaling levels. This is independent of inhibiting BMP signaling via the FGF/MAPK/Smad pathway, which has been proposed as the primary pathway for FGF signaling in Xenopus neural induction. Using cultured ectoderm cells, we also obtained results suggesting that the mode of contribution of FGF signaling to neural development is altered during the subsequent neural patterning stage. As we increase the amounts of FGF in the culture medium, anterior neural genes activated at low FGF signaling levels are suppressed, and instead position-specific, more posterior neural genes are activated in a dose-dependent manner via the FGF/MAPK/Ets pathway. These results support the claim that morphogenic FGFs from the organizer diffuse in a paracrine manner through the plane of the induced neuroectoderm, causing anteroposterior patterning of neural tissue.

Polypyrimidine tract-binding protein is required for the repression of gene expression by all-trans retinoic acid.

All-trans retinoic acid is a key regulator of early development. High concentrations of retinoic acid interfere with differentiation and migration of neural crest cells. Here we report that a dinucleotide repeat in the cis-element of Snail2 (previously known as Slug) gene plays a role in repression by all-trans retinoic acid. We analyzed the cis-acting regulatory regions of the Xenopus Snail2 gene, whose expression is repressed by all-trans retinoic acid. The analysis identified a TG/CA repeat as a necessary element for the repression. By performing a yeast one-hybrid screen, we found that a polypyrimidine tract-binding protein (PTB), which is known to be a regulator of the alternative splicing of pre-messenger RNA, binds to the TG/CA repeat. Overexpression and knockdown experiments for PTB in HEK293 cells and Xenopus embryos indicated that PTB is required for repression by retinoic acid. The green fluorescent protein-PTB fusion protein was localized in the nucleus of 293T cells. In situ hybridization for PTB in Xenopus embryos showed that PTB is expressed at the regions including neural crest at the early stages. Our results indicate that PTB plays a role in the repression of gene expression by retinoic acid through binding to the TG/CA repeats.

Competition for ligands between FGFR1 and FGFR4 regulates Xenopus neural development.

Cell-surface-localized receptors and their extracellular ligands usually comprise distinct families and promote diversity of signal transduction regulation. The number of available ligand molecules is often the limiting factor for receptor activation during interpretation of the signal by the responding cell. Limited ligand availability in a particular area of tissue should lead to local competition between different members of a receptor family for binding and subsequent activation. Fibroblast growth factor receptor (FGFR) 4 (FGFR4) is a less potent activator of downstream pathways than FGFR1, the major subtype of FGFR. Regional expression of Xenopus FGFR1 and FGFR4 (XFGFR1 and XFGFR4, respectively) overlap in the anterior part of prospective and developing neural tissue. In this paper we show that XFGFR1 and XFGFR4 have opposing effects on the positioning of expression domains of mid- and hindbrain markers when the expression levels of the receptors are altered. We present a line of evidence to support our hypothesis that competition between XFGFR1 and XFGFR4 for ligands is required for correct positioning of marker expression. Local competition between receptors with different potencies should provide an efficient means for a cell to interpret the ligand signal correctly, and may constitute a more general mechanism for regulating signal transduction.

Expression cloning of Xenopus zygote arrest 2 (Xzar2) as a novel epidermalization-promoting factor in early embryos of Xenopus laevis.

In vertebrates, BMPs are known to induce epidermal fate at the expense of neural fate. To further explore the molecular mechanisms of epidermal differentiation, we have developed an expression cloning system for isolating cDNAs that encode intrinsic proteins with epidermal-inducing activity. Under our conditions, 92.5% of the dissociated animal cap cells treated with the conditioned medium from H(2)O-injected control oocytes differentiated into neural tissue, which developed neural fibers and expressed a neural marker (NCAM). In contrast, when dissociated animal cap cells were treated with the supernatant collected from the culture of BMP-4 mRNA-injected oocytes, the microcultures differentiated into epidermal tissue, which developed cilium. The cells expressed an epidermal marker (keratin), but not NCAM. Using the dissociated animal cap cells in a functional screening system, we cloned a cDNA encoding a novel polypeptide, Xenopus zygote arrest 2 (Xzar2). Over-expression of Xzar2 caused anterior defects and suppressed expressions of the neural markers. The epidermalization-promoting activity of Xzar2 was substantially not affected by over-expression of the BMP signaling antagonists Smad6 and 7, and a dominant negative receptor for BMP (tBR). Our results suggest that Xzar2 is involved in epidermal fate determination mainly through signaling pathways distinct from that of BMP-Smad during early embryogenesis.

Caenorhabditis elegans Rab escort protein (REP-1) differently regulates each Rab protein function and localization in a tissue-dependent manner.

Rab proteins play a critical role in intracellular vesicle trafficking and require post-translational modification by adding lipids at the C-terminus for proper functions. This modification is preceded by the formation of a trimeric protein complex with the Rab escort protein (REP) and the Rab geranylgeranyltransferase (RabGGTase). However, the genetic hierarchy among these proteins and the tissue-specificity of each protein function are not yet clearly understood. Here we identified the Caenorhabditis elegans rep-1 gene and found that a rep-1 mutant showed a mild defect in synaptic transmission and defecation behaviors. Genetic analyses using the exocytic Rab mutants rab-3 or rab-27 suggested that rep-1 functions only in the RAB-27 pathway, and not in the RAB-3 pathway, for synaptic transmission at neuromuscular junctions. However, the disruption of REP-1 did not cause defecation defects compared to severe defects in either RAB-27 or RabGGTase disruption, suggesting that REP-1 is not essential for RAB-27 signaling in defection. Some Rab proteins did not physically interact with REP-1, and localization of these Rab proteins was not severely affected by REP-1 disruption. These findings suggest that REP-1 functions are required in specific Rab pathways and in specific tissues, and that some Rab proteins are functionally prenylated without REP-1.

Affixin activates Rac1 via betaPIX in C2C12 myoblast.

Affixin/beta-parvin is an integrin-linked kinase (ILK)-binding focal adhesion protein highly expressed in skeletal muscle and heart. To elucidate the possible role of affixin in skeletal muscle, we established stable C2C12 cell line expressing T7-tagged human affixin (C2C12-affixin cells). Exogenous expression of affixin promotes lamellipodium formation where affixin, ILK alphap21-activated kinase (PAK)-interactive exchange factor (PIX) and betaPIX accumulate. The association of affixin and betaPIX was confirmed by immunoprecipitation and pull down assay. In C2C12-affixin cells, an increased level of activated Rac1 but not Cdc42 was observed, and mutant betaPIX lacking guanine nucleotide exchange factor activity inhibited lamellipodium formation. These results suggest that affixin is involved in reorganization of subsarcolemmal cytoskeletal actin by activation of Rac1 through alpha and betaPIXs in skeletal muscle.

Melatonin signaling regulates locomotion behavior and homeostatic states through distinct receptor pathways in Caenorhabditis elegans.

Melatonin is a hormone that controls circadian rhythms and seasonal behavioral changes in vertebrates. Recent studies indicate that melatonin participates in diverse physiological functions including the modulation of neural activities. Melatonin is also detected in many other organisms that do not exhibit obvious circadian rhythms, but their precise functions are not known. To understand the role of melatonin and its genetic pathway in vivo, we examined the effects of melatonin and its receptor antagonists on various behaviors in Caenorhabditis elegans. Exogenously applied melatonin specifically decreased locomotion rates in 15-min treatments, suggesting that melatonin directly regulates neural activities for locomotion. This melatonin signaling functions through MT1-like melatonin receptors, because the MT1/2 receptor antagonist luzindole effectively blocked the effect of melatonin on locomotion, while MT2-specific antagonist 4-phenyl-2-propionamidotetralin (4-P-PDOT) and MT3-selective antagonist prazosin had no effect. Alternatively, long-term treatment with prazosin specifically altered homeostatic states of the worm, suggesting another melatonin-signaling pathway through MT3-like receptors. We also found that two G-protein alpha subunit mutants and newly isolated five mutants exhibited defects in response to melatonin. Our findings imply that melatonin acts as a neuromodulator by regulating locomotion behavior and as a ligand for homeostatic control through distinct receptor pathways in C. elegans.

Involvement of a Xenopus nuclear GTP-binding protein in optic primordia formation.

Using a subtracted Xenopus cDNA library based on the differential sensitivity of anterior and posterior genes to retinoic acid, we isolated a novel Xenopus nuclear GTP-binding protein (XGB). XGB is expressed prominently in the optic primordia at the tailbud stage. The N-terminal region of XGB contains a set of GTP-binding protein motifs, and the C-terminal region contains two putative nuclear localization signals and two coiled regions. A GFP-XGB fusion protein was expressed in the nucleus of NIH3T3 cells where it bound to subnuclear structures. Truncated C-terminal constructs of XGB containing both nuclear localization signal(s) and coiled region(s) suppressed eye formation, whereas neither the N-terminal construct nor constructs with a mutated GTP-binding protein motif affected eye formation. Expression of Pax6 and Rx1 genes, which are crucial for eye development, was reduced in embryos overexpressing the C-terminal constructs of XGB. Suppression of Pax6 and Rx1 at earlier developmental stages as well as perturbation of eye formation at later stages was counteracted by co-expression of wild-type XGB. We conclude that XGB plays a role in the formation of optic primordia through activation of at least two eye field transcription factors.

Regulation of Slug transcription in embryonic ectoderm by beta-catenin-Lef/Tcf and BMP-Smad signaling.

Neural crest is formed at the boundary of epidermal and neural ectoderm. To understand the molecular mechanism of neural crest formation, we focused on the transcriptional regulation of the Slug gene. In the upstream sequence of the chicken Slug gene, we have identified potential binding sites for transcription factors, such as Lef/Tcf and Smad1. Transgenic mouse embryos carrying the chicken Slug promoter-reporter gene showed a crest-specific activation of the reporter, suggesting the isolated sequence included the cis-regulatory elements to receive Slug-inducing signals in the mouse neural crest. While these potential cis-regulatory elements could be recognized and activated by corresponding transcription factors, such as Lef1 and Smad1, Wnt-Lef-beta-catenin signal failed to induce endogenous Slug expression in quail neural plate tissue prepared from forebrain and midbrain levels. In contrast, Slug expression and subsequent epithelial-mesenchymal transition were effectively induced by BMP4. Consistently, while we could detect phosphorylation of Smad1 in the ectoderm including the neural plate and the neural fold region, the activation of a reporter gene for a detection of canonical Wnt signal activation was below the level of detection at the forebrain and midbrain levels. These observations indicated that in the anterior ectoderm BMP signal has a predominant role for Slug expression.

Dysferlin interacts with affixin (beta-parvin) at the sarcolemma.

The dysferlin gene is defective in Miyoshi myopathy (MM) and limb girdle muscular dystrophy type 2B (LGMD2B). Dysferlin is a sarcolemmal protein that is implicated in calcium-dependent membrane repair. Affixin (beta-parvin) is a novel, integrin-linked kinase-binding protein that is involved in the linkage between integrin and the cytoskeleton. Here we show that affixin is a dysferlin binding protein that colocalizes with dysferlin at the sarcolemma of normal human skeletal muscle. The immunoreactivity of affixin was reduced in sarcolemma of MM and LGMD2B muscles, although the total amount of the affixin protein was normal. Altered immunoreactivity of affixin was also observed in other muscle diseases including LGMD1C, where both affixin and dysferlin showed quite similar changes with a reduction of sarcolemmal staining with or without cytoplasmic accumulations. Colocalization of dysferlin and affixin was confirmed by immunofluorescence analysis using dysferlin-expressing C2 myoblasts. Wild-type and mutant dysferlin colocalized with endogenous affixin. The interaction of dysferlin and affixin was confirmed by immunoprecipitation study using normal human and mouse skeletal muscles. Using immunoprecipitation with deletion mutants of dysferlin, we have identified that C-terminal region of dysferlin is an apparent binding site for affixin. We also found N-terminal calponin homology domain of affixin as a binding site for dysferlin. Our results suggest that affixin may participate in membrane repair with dysferlin.

Functional role of a novel ternary complex comprising SRF and CREB in expression of Krox-20 in early embryos of Xenopus laevis.

Krox-20, originally identified as a member of "immediate-early" genes, plays a crucial role in the formation of two specific segments in the hindbrain during early development of the vertebrate nervous system. Here we cloned a genomic sequence of Xenopus Krox-20 (XKrox-20) and studied functions of a promoter element in the flanking sequence and associated transcription factors, which function in early Xenopus embryos. Using the luciferase reporter assay system, we showed that the 5' flanking sequence was sufficient to induce luciferase activities when the reporter construct was injected into embryos at the eight-cell stage. Deletion and mutagenesis analyses of the 5' flanking sequence revealed a minimal promoter element that included two known subelements, a CArG-box and cAMP response element (CRE) within a stretch of 22 bp nucleotide sequence (-72 to -51 from the transcription initiation site), both of which were essential for the promoter activity. The gel mobility shift assay indicated that these two subelements bound to some components in whole cell extracts prepared from stage 20 Xenopus embryos. Antibody supershift and competition experiments revealed that these components in cell extracts were serum response factor (SRF) and a member of CRE binding protein (CREB) family proteins that bound the CArG-box and CRE, respectively. They appeared to assemble on the minimal promoter element to produce a novel ternary complex. When we injected mRNA of a dominant-negative version of Xenopus SRF (XSRFDeltaC) into animal pole blastomeres at the eight-cell stage, expression of XKrox-20 in the nervous system as well as the minimal promoter activity was strongly suppressed. Suppression by XSRFDeltaC was counteracted by coexpressed wild-type XSRF. These results indicate that XSRF functions as an endogenous activator of XKrox-20 by forming a ternary complex with CREB on the minimal promoter element.

Integration of multiple signal transducing pathways on Fgf response elements of the Xenopus caudal homologue Xcad3.

Early neural patterning along the anteroposterior (AP) axis appears to involve a number of signal transducing pathways, but the precise role of each of these pathways for AP patterning and how they are integrated with signals that govern neural induction step is not well understood. We investigate the nature of Fgf response element (FRE) in a posterior neural gene, Xcad3 (Xenopus caudal homologue) that plays a crucial role of posterior neural development. We provide evidence that FREs of Xcad3 are widely dispersed in its intronic sequence and that these multiple FREs comprise Ets-binding and Tcf/Lef-binding motifs that lie in juxtaposition. Functional and physical analyses indicate that signaling pathways of Fgf, Bmp and Wnt are integrated on these FREs to regulate the expression of Xcad3 in the posterior neural tube through positively acting Ets and Sox family transcription factors and negatively acting Tcf family transcription factor(s).