Expression of the hormonal FGF co-receptor Klotho beta in the Xenopus laevis model.

Klotho beta (Klb), a single-pass transmembrane protein, has been described as a co-receptor for endocrine FGFs, such as FGF15/19 and FGF21, to regulate critical metabolic processes in multiple organs and tissues in adult mice. However, its function during early embryonic development remains largely unknown. In this paper, we evaluated for the first time the expression of klb mRNA during early development of Xenopus laevis by RT-PCR and whole mount in situ hybridization. RT-PCR experiments showed that the expression of klb was initially detected at late gastrula stage followed by a quick increasing and continued expression throughout embryonic development. Whole mount in situ hybridization detected specific expression of klb in many primordial organs at tailbud stage such as liver primordium and pancreatic buds, implying that the hormonal FGF signaling may play a role in the foregut development. The dynamic and specific expression patterns of klb also suggest that Xenopus laevis can serve a convenient model for the function of the hormonal FGF signaling in organogenesis and metabolism regulation during embryonic development.

Identification and Bioinformatics Analyses of the Basic Helix-loop-helix Transcription Factors in Xenopus laevis.

Xenopus laevis is a long established model organism for developmental, behavioral and neurological studies. Herein, an updated genome-wide survey was conducted using the ongoing genome project of Xenopus laevis and 106 non-redundant Basic Helix-Loop-Helix (bHLH) genes were identified in the Xenopus laevis genome databases. Gene Ontology (GO) enrichment statistics showed 51 significant GO annotations of biological processes and molecular functions and 5 significant KEGG pathways and a number of Xenopus laevis bHLH genes play significant role in specific development or special physiology processes like the development processes of muscle and eye and other organs. Furthermore, each sub-group of the bHLH family has its special gene functions except for the common GO term categories. Molecular phylogenetic analyses revealed that among these identified bHLH proteins, 105 sequences could classified into 39 families with 46, 25, 10, 5, 16 and 3 members in the corresponding high-order groups A, B, C, D, E and F, respectively with an addition bHLH member categorized as an orphan. The present study provides much useful information for further researches on Xenopus laevis.

Unusual evolutionary conservation and further species-specific adaptations of a large family of nonclassical MHC class Ib genes across different degrees of genome ploidy in the amphibian subfamily Xenopodinae.

Nonclassical MHC class Ib (class Ib) genes are a family of highly diverse and rapidly evolving genes wherein gene numbers, organization, and expression markedly differ even among closely related species rendering class Ib phylogeny difficult to establish. Whereas among mammals there are few unambiguous class Ib gene orthologs, different amphibian species belonging to the anuran subfamily Xenopodinae exhibit an unusually high degree of conservation among multiple class Ib gene lineages. Comparative genomic analysis of class Ib gene loci of two divergent (~65 million years) Xenopodinae subfamily members Xenopus laevis (allotetraploid) and Xenopus tropicalis (diploid) shows that both species possess a large cluster of class Ib genes denoted as Xenopus/Silurana nonclassical (XNC/SNC). Our study reveals two distinct phylogenetic patterns among these genes: some gene lineages display a high degree of flexibility, as demonstrated by species-specific expansion and contractions, whereas other class Ib gene lineages have been maintained as monogenic subfamilies with very few changes in their nucleotide sequence across divergent species. In this second category, we further investigated the XNC/SNC10 gene lineage that in X. laevis is required for the development of a distinct semi-invariant T cell population. We report compelling evidence of the remarkable high degree of conservation of this gene lineage that is present in all 12 species of the Xenopodinae examined, including species with different degrees of ploidy ranging from 2, 4, 8 to 12 N. This suggests that the critical role of XNC10 during early T cell development is conserved in amphibians.

Subfunctionalization and neofunctionalization of vertebrate Lef/Tcf transcription factors.

Invertebrates express a multitude of Wnt ligands and all Wnt/ß-catenin signaling pathways converge to only one nuclear Lef/Tcf. In vertebrates, however, four distinct Lef/Tcfs, i.e. Tcf-1, Lef, Tcf-3, and Tcf-4 fulfill this function. At present, it is largely unknown to what extent the various Lef/Tcfs are functionally similar or diversified in vertebrates. In particular, it is not known which domains are responsible for the Tcf subtype specific functions. We investigated the conserved and non-conserved functions of the various Tcfs by using Xenopus laevis as a model organism and testing Tcfs from Hydra magnipapillata, Caenorhabditis elegans and Drosophila melanogaster. In order to identify domains relevant for the individual properties we created series of chimeric constructs consisting of parts of XTcf-3, XTcf-1 and HyTcf. Rescue experiments in Xenopus morphants revealed that the three invertebrate Tcfs tested compensated the loss of distinct Xenopus Tcfs: Drosophila Tcf (Pangolin) can substitute for the loss of XTcf-1, XTcf-3 and XTcf-4. By comparison, Caenorhabditis Tcf (Pop-1) and Hydra Tcf (HyTcf) can substitute for the loss of only XTcf-3 and XTcf-4, respectively. The domain, which is responsible for subtype specific functions is the regulatory CRD domain. A phylogenetic analysis separates Tcf-1/Lef-1 from the sister group Tcf-3/4 in the vertebrate lineage. We propose that the vertebrate specific diversification of Tcfs in vertebrates resulted in subfunctionalization of a Tcf that already united most of the Lef/Tcf functions.

RFX2 is broadly required for ciliogenesis during vertebrate development.

In Caenorhabditis elegans, the RFX (Daf19) transcription factor is a major regulator of ciliogenesis, controlling the expression of the many essential genes required for making cilia. In vertebrates, however, seven RFX genes have been identified. Bioinformatic analysis suggests that Rfx2 is among the closest homologues of Daf19. We therefore hypothesize that Rfx2 broadly controls ciliogenesis during vertebrate development. Indeed, here we show that Rfx2 in Xenopus is expressed preferentially in ciliated tissues, including neural tube, gastrocoel roof plate, epidermal multi-ciliated cells, otic vesicles, and kidneys. Knockdown of Rfx2 results in cilia-defective embryonic phenotypes and fewer or truncated cilia are observed in Rfx2 morphants. These results indicate that Rfx2 is broadly required for ciliogenesis in vertebrates. Furthermore, we show that Rfx2 is essential for expression of several ciliogenic genes, including TTC25, which we show here is required for ciliogenesis, HH signaling, and left-right patterning.

Manipulating the fragile X mental retardation proteins in the frog.

The frog is a model of choice to study gene function during early development, since a large number of eggs are easily obtained and rapidly develop external to the mother. This makes it a highly flexible model system in which direct tests of gene function can be investigated by microinjecting RNA antisense reagents. Two members of the Fragile X Related (FXR) gene family, namely xFmr1 and xFxr1 have been identified in Xenopus. While the tissue distribution of their products was found to be identical to that in mammals, the pattern of isoform expression is less complex. Translational silencing of the xFmr1 and xFxr1 mRNAs by microinjection of antisense morpholino oligonucleotides (MO) induced dramatic morphological alterations, revealing tissue-specific requirements for each protein during development and in maintaining the steady state levels of a range of transcripts in these tissues. The power and versatility of the frog model is that the MO-induced phenotypes can be rescued by microinjection of the corresponding MO-insensitive mRNAs. Most importantly, this animal model allows one rapidly to determine whether any member of the FXR family can compensate for the absence of another, an approach that cannot be performed in other animal models.

International Union of Basic and Clinical Pharmacology. LXXXV: calcium-activated chloride channels.

Calcium-activated chloride channels (CaCCs) are widely expressed in various tissues and implicated in physiological processes such as sensory transduction, epithelial secretion, and smooth muscle contraction. Transmembrane proteins with unknown function 16 (TMEM16A) has recently been identified as a major component of CaCCs. Detailed molecular analysis of TMEM16A will be needed to understand its structure-function relationships. The role this channel plays in physiological systems remains to be established and is currently a subject of intense investigation.

Xenopus Dbx2 is involved in primary neurogenesis and early neural plate patterning.

The evolutionarily conserved Dbx homeodomain-containing proteins play important roles in the development of vertebrate central nervous system. In mouse, Dbx and Nkx6 have been suggested to be cross-repressive partners involved in the patterning of ventral neural tube. Here, we have isolated Xenopus Dbx2 and studied its developmental expression and function during neural development. Like XDbx1, from mid-neurula stage on, XDbx2 is expressed in stripes between the primary motoneurons and interneurons. At the tailbud stages, it is detected in the middle region of the neural tube. XDbx2 acts as a transcriptional repressor in vitro and over-expression of XDbx2 inhibits primary neurogenesis in Xenopus embryos. Over-expression of XDbx genes represses the expression of XNkx6.2 and vise versa. Knockdown of either XDbx1, XDbx2 or both by specific morpholinos induces lateral expansion of XNkx6.2 expression domains. These data reveal conserved roles for Dbx in primary neurogenesis and dorsoventral neural patterning in Xenopus.

Characterization of three synuclein genes in Xenopus laevis.

The synuclein family consists of three small intracellular proteins mainly expressed in neural tissues, and has been associated with human neurodegenerative diseases. We have examined the spatial and temporal expression patterns of three synuclein genes during embryogenesis of Xenopus laevis. The Xenopus synucleins were firstly expressed in the developing nervous system at the tail bud stages. At tadpole stages, Xenopus snca was expressed in the brain, branchial arch and somite, and sncbb signals were detected in entire brain and spinal cord. However, sncg was only expressed in the peripheral nervous system including trigeminal nerve and dorsal root ganglion. RT-PCR indicated that expression of synucleins was up-regulated at the end of neurulation, and then maintained at later examined stages. Our study provides the spatiotemporal expression patterns of the synuclein family genes in Xenopus embryos, and forms a basis for further functional analysis of synucleins.

Endothelial nitric oxide synthase in the amphibian, Xenopus tropicalis.

Nitric oxide (NO) is generated by NO synthase (NOS) of which there are three isoforms: neuronal NOS (nNOS, nos1), inducible NOS (iNOS, nos2), and endothelial NOS (eNOS, nos3). This study utilised the genome of Xenopus tropicalis to sequence a nos3 cDNA and determine if eNOS protein is expressed in blood vessels. A nos3 cDNA was sequenced that encoded a 1177 amino acid protein called XteNOS, which showed closest sequence identity to mammalian eNOS protein. The X. tropicalis nos3 gene and eNOS protein were determined to be an orthologue of mammalian nos3 and eNOS using gene synteny and phylogenetic analyses, respectively. In X. tropicalis, nos3 mRNA expression was highest in lung and skeletal muscle and lower in the liver, gut, kidney, heart and brain. Western analysis of kidney protein using an affinity-purified anti-XteNOS produced a single band at 140kDa. Immunohistochemistry showed XteNOS immunoreactivity in the proximal tubule of the kidney and endocardium of the heart, but not in the endothelium of blood vessels. Thus, X. tropicalis has a nos3 gene that appears not to be expressed in the vascular endothelium.

The transcriptional coactivators Yap and TAZ are expressed during early Xenopus development.

The Yap and TAZ genes encode highly conserved domains which bind various transcription factors. Yap and TAZ act as transcriptional coactivators to modulate transcriptional activity. The activities of Yap and TAZ are negatively regulated by Hippo signaling via direct phosphorylation. In this study, we describe the expression patterns of Yap and TAZ during the development of Xenopus tropicalis. The Xenopus tropicalis Yap (xtYap) and Xenopus tropicalis TAZ (xtTAZ) genes are expressed maternally. xtYap is widely expressed throughout embryogenesis, particularly in the facial connective tissues, branchial arch, midbrain-hindbrain boundary, otic vesicle, pronephros, notochord, hindgut and tailbud. xtTAZ expression occurs predominantly in the presomitic mesoderm, facial connective tissues, brain, branchial arch, trunk neural crest cells and migrating hypaxial myoblasts. In the muscle lineage, xtTAZ expression is transient and restricted to proliferating cells, the presomitic mesoderm and the edges of the hypaxial myoblasts, with no expression detected in mature muscle cells. These results provide insights into the functions of Yap and TAZ and their regulation by Hippo signaling during early development in Xenopus.

p24 Proteins from the same subfamily are functionally nonredundant.

The p24 proteins function in early secretory pathway transport processes, but their exact role is unclear. In physiologically activated Xenopus melanotrope cells, a representative of each p24 subfamily (p24α(3), -ß(1), -γ(3), -δ(2)) is upregulated coordinately with the major melanotrope cargo, proopiomelanocortin (POMC), whereas two other p24s (p24γ(2) and -δ(1)) are also expressed, but not coordinately with POMC. Using melanotrope-specific transgene expression, we here find that the roles of both p24γ(2) and p24δ(1) in the transport, glycosylation, sulphation and cleavage of POMC are different from those of their upregulated subfamily relatives (p24γ(3) and p24δ(2), respectively). Thus, even p24 proteins from the same subfamily have distinct functions in secretory cargo biosynthesis.

The G-protein-coupled receptor, GPR84, is important for eye development in Xenopus laevis.

G-protein-coupled receptors (GPCRs) represent diverse, multifamily groups of cell signaling receptors involved in many cellular processes. We identified Xenopus laevis GPR84 as a member of the A18 subfamily of GPCRs. During development, GPR84 is detected in the embryonic lens placode, differentiating lens fiber cells, retina, and cornea. Anti-sense morpholino oligonucleotide-mediated knockdown and RNA rescue experiments demonstrate GPR84's importance in lens, cornea, and retinal development. Examination of cell proliferation using an antibody against histone H3 S10P reveals significant increases in the lens and retina following GPR84 knockdown. Additionally, there was also an increase in apoptosis in the retina and lens, as revealed by TUNEL assay. Reciprocal transplantation of the presumptive lens ectoderm between uninjected controls and morpholino-injected embryos demonstrates that GPR84 is necessary in the retina for proper development of the retina, as well as other eye tissues including the lens and cornea.

Developmental expression of sideroflexin family genes in Xenopus embryos.

Emerging evidence indicates that mitochondrial carriers are not only crucial for metabolism, but also important for embryonic development. Sideroflexin is a novel family of mitochondrial tricarboxylate carrier proteins, of which the in vivo function is largely unknown. Here, we report on the expression patterns of five sideroflexin genes in Xenopus embryos. Whole-mount in situ hybridization analysis reveals that while sideroflexin2 is expressed in the pancreas, sideroflexin1 and 3 display a complex expression in the central nervous system, somites, pronephros, liver, and pancreas. In contrast, only a weak expression of sideroflexin4 and 5 was detected in embryonic brain. Taken together, the five sideroflexin genes show both overlapping and nonoverlapping expression during Xenopus embryogenesis. As the primary structures of the five sideroflexin proteins are also quite similar, their functional redundancy should be taken into consideration for gene targeting studies.

Vestigial like gene family expression in Xenopus: common and divergent features with other vertebrates.

The Drosophila Vestigial and Scalloped proteins form heterodimers that control wing development and are involved in muscle differentiation. Four vestigial like genes have been described in mammals. Similar to the Drosophila vestigial gene, they encode a short conserved domain (TONDU) required for interaction with the mammalian paralogues of Drosophila Scalloped (i.e., TEAD proteins). We previously identified two TEAD genes in Xenopus laevis and we report here the expression of four distinct vestigial like genes in Xenopus (vgll1-4) that represent amphibian orthologs of the mammalian vestigial like genes. Vgll1 has a unique expression pattern which is restricted to epidermal cells, both in the embryo and in the adult. Vgll2 is expressed in the skeletal muscle lineage downstream of myogenic factors and in the embryonic brain similar to the avian and mammalian orthologues. Vgll3 expression is transient, identifies embryonic hindbrain rhombomere 2, and is negatively regulated by en2, but not by egr2. Vgll4 is mainly expressed in anterior neural structures. In summary, the four Xenopus vgll genes have unique/complex expression profiles and they are differently expressed during embryogenesis. Moreover, these amphibian vestigial like genes display distinct responses to the major signaling pathways (i.e., activin, FGF or BMP) that orchestrate pattern-formation during early development.

Developmental expression of Xenopus short-chain dehydrogenase/reductase 3.

During early embryonic development, the retinoic acid signaling pathway coordinates with other signaling pathways to regulate body axis patterning and organogenesis. The production of retinoic acid requires two enzymatic reactions, the first of which is the oxidization of vitamin A (all-trans-retinol) to all-trans -retinal, mediated in part by the short-chain dehydrogenase/reductase. Through DNA microarrays, we have identified a gene in Xenopus laevis which shares a high sequence similarity to human short-chain dehydrogenase/reductase member 3. We therefore annotated the gene Xenopus short-chain dehydrogenase/reductase 3 (dhrs3). Expression of dhrs3 was detected by whole mount in situ hybridization in the dorsal blastopore lip and axial mesoderm region in gastrula embryos. During neurulation, dhrs3 transcripts were found in the notochord and neural ectoderm. Strong expression of dhrs3 was mainly detected in the brain, spinal cord and pronephros region in tailbud and tadpole stages. Temporal expression tested by RT-PCR indicated that dhrs3 was activated at the onset of gastrulation, and remained highly expressed at later stages of embryonic development. The distinct and highly regulated spatial and temporal expression of dhrs3 highlights the complexity of retinoic acid regulation.

Identification of protein domains required for makorin-2-mediated neurogenesis inhibition in Xenopus embryos.

Makorin-2, consisting of four highly conserved C(3)H zinc fingers, a Cys-His motif and a C(3)HC(4) RING zinc finger domain, is a putative ribonucleoprotein. We have previously reported that Xenopus makorin-2 (mkrn2) is a neurogenesis inhibitor acting upstream of glycogen synthase kinase-3beta (GSK-3beta) in the phosphatidylinositol 3-kinase/Akt pathway. In an effort to identify the functional domains required for its anti-neurogenic activity, we designed and constructed a series of N- and C-terminal truncation mutants of mkrn2. Concurred with the full-length mkrn2, we showed that overexpression of one of the truncation mutants mkrn2(s)-7, which consists of only the third C(3)H zinc finger, Cys-His motif and C(3)HC(4) RING zinc finger, is essential and sufficient to produce the phenotypical dorso-posterior deficiencies and small-head/short-tail phenotype in tadpoles. In animal cap explant assay, we further demonstrated that mkrn2(s)-7 not only inhibits activin and retinoic acid-induced animal cap neuralization and the expression of a pan-neural marker neural cell adhesion molecule, but also induces GSK-3beta expression. These results collectively suggest that the third C(3)H zinc finger, Cys-His motif and C(3)HC(4) RING zinc finger are indispensable for the anti-neurogenic activity of mkrn2.

Xenopus meiotic microtubule-associated interactome.

In metazoan oocytes the assembly of a microtubule-based spindle depends on the activity of a large number of accessory non-tubulin proteins, many of which remain unknown. In this work we isolated the microtubule-bound proteins from Xenopus eggs. Using mass spectrometry we identified 318 proteins, only 43 of which are known to bind microtubules. To integrate our results, we compiled for the first time a network of the meiotic microtubule-related interactome. The map reveals numerous interactions between spindle microtubules and the newly identified non-tubulin spindle components and highlights proteins absent from the mitotic spindle proteome. To validate newly identified spindle components, we expressed as GFP-fusions nine proteins identified by us and for first time demonstrated that Mgc68500, Loc398535, Nif3l1bp1/THOC7, LSM14A/RAP55A, TSGA14/CEP41, Mgc80361 and Mgc81475 are associated with spindles in egg extracts or in somatic cells. Furthermore, we showed that transfection of HeLa cells with siRNAs, corresponding to the human orthologue of Mgc81475 dramatically perturbs spindle formation in HeLa cells. These results show that our approach to the identification of the Xenopus microtubule-associated proteome yielded bona fide factors with a role in spindle assembly.

Cryptochrome genes are highly expressed in the ovary of the African clawed frog, Xenopus tropicalis.

Cryptochromes (CRYs) are flavoproteins sharing high homology with photolyases. Some of them have function(s) including transcription regulation in the circadian clock oscillation, blue-light photoreception for resetting the clock phase, and light-dependent magnetoreception. Vertebrates retain multiple sets of CRY or CRY-related genes, but their functions are yet unclear especially in the lower vertebrates. Although CRYs and the other circadian clock components have been extensively studied in the higher vertebrates such as mice, only a few model species have been studied in the lower vertebrates. In this study, we identified two CRYs, XtCRY1 and XtCRY2 in Xenopus tropicalis, an excellent experimental model species. Examination of tissue specificity of their mRNA expression by real-time PCR analysis revealed that both the XtCRYs showed extremely high mRNA expression levels in the ovary. The mRNA levels in the ovary were about 28-fold (XtCry1) and 48-fold (XtCry2) higher than levels in the next abundant tissues, the retina and kidney, respectively. For the functional analysis of the XtCRYs, we cloned circadian positive regulator XtCLOCK and XtBMAL1, and found circadian enhancer E-box in the upstream of XtPer1 gene. XtCLOCK and XtBMAL1 exhibited strong transactivation from the XtPer1 E-box element, and both the XtCRYs inhibited the XtCLOCK:XtBMAL1-mediated transactivation, thereby suggesting this element to drive the circadian transcription. These results revealed a conserved main feedback loop in the X. tropicalis circadian clockwork and imply a possible physiological importance of CRYs in the ovarian functions such as synthesis of steroid hormones and/or control of estrus cycles via the transcription regulation.

The Xenopus Bowline/Ripply family proteins negatively regulate the transcriptional activity of T-box transcription factors.

Bowline, which is a member of the Xenopus Bowline/Ripply family of proteins, represses the transcription of somitogenesis-related genes before somite segmentation, which makes Bowline indispensable for somitogenesis. Although there are three bowline/Ripply family genes in each vertebrate species, it is not known whether the Bowline/Ripply family proteins share a common role in development. To elucidate their developmental roles, we examined the expression patterns and functions of the Xenopus Bowline/Ripply family proteins Bowline, Ledgerline, and a novel member of this protein family, xRipply3. We found that the expression patterns of bowline and ledgerline overlapped in the presomitic mesoderm (PSM), whereas ledgerline was additionally expressed in the newly formed somites. In addition, we isolated xRipply3, which is expressed in the pharyngeal region. Co-immunoprecipitation assays revealed that Ledgerline and xRipply3 interacted with T-box proteins and the transcriptional co-repressor Groucho/TLE. In luciferase assays, xRipply3 weakly suppressed the transcriptional activity of Tbx1, while Ledgerline strongly suppressed that of Tbx6. In line with the repressive role of Ledgerline, knockdown of Ledgerline resulted in enlargement of expression regions of the somitogenesis-related-genes mespb and Tbx6. Inhibition of histone deacetylase activity increased the expression of mespb, as seen in the Bowline and Ledgerline knockdown experiments. These results suggest that the Groucho-HDAC complex is required for the repressive activity of Bowline/Ripply family proteins during Xenopus somitogenesis. We conclude that although the Xenopus Bowline/Ripply family proteins Bowline, Ledgerline and xRipply3 are expressed differentially, they all act as negative regulators of T-box proteins.