Cynoglossus semilaevis Rspo3 Regulates Embryo Development by Inhibiting the Wnt/ß-Catenin Signaling Pathway.

Cynoglossus semilaevis is an important economic fish species and has long been cultivated in China. Since the completion of its genome and transcriptome sequencing, genes relating to C. semilaevis development have been extensively studied. R-spondin 3 (Rspo3) is a member of the R-spondin family. It plays an important role in biological processes such as vascular development and oncogenesis. In this study, we cloned and characterized the expression patterns and functions of C. semilaevisRspo3. Initial structural and phylogenetic analyses revealed a unique FU3 domain that exists only in ray-finned fish RSPO3. Subsequent embryonic expression profile analysis showed elevating expression of Rspo3 from gastrulation to the formation of the eye lens, while, in tail bud embryos, Rspo3 expression was significantly high in the diencephalon and mesencephalon. The overexpression of C. semilaevis Rspo3 in Danio rerio embryos resulted in a shortened rostral⁻caudal axis, edema of the pericardial cavity, stubby yolk extension, and ecchymosis. Vascular anomalies were also observed, which is consistent with Rspo3 role in vascular development. Drug treatment and a dual-luciferase reporter assay confirmed the inhibitory role of C. semilaevis Rspo3 in D. rerio Wnt/ß-catenin signaling pathway. We further concluded that the FU2, FU3, and TSP1 domains regulate the maternal Wnt/ß-catenin signaling pathway, while the FU1 domain regulates the zygotic Wnt/β-catenin signaling pathway. This study enriches Rspo3 research in non-model animals and serves as the basis for further research into the interactions between Rspo and the Wnt/ß-catenin signaling pathway.

The evolution of thrombospondins and their ligand-binding activities.

The extracellular matrix (ECM) is a complex, multiprotein network that has essential roles in tissue integrity and intercellular signaling in the metazoa. Thrombospondins (TSPs) are extracellular, calcium-binding glycoproteins that have biologically important roles in mammals in angiogenesis, vascular biology, connective tissues, immune response, and synaptogenesis. The evolution of these complex functional properties is poorly understood. We report here on the evolution of TSPs and their ligand-binding capacities, from comparative genomics of species representing the major phyla of metazoa and experimental analyses of the oligomerization properties of noncanonical TSPs of basal deuterostomes. Monomeric, dimeric, trimeric, and pentameric TSPs have arisen through separate evolutionary events involving gain, loss, or modification of a coiled-coil domain or distinct domains at the amino-terminus. The relative transience of monomeric forms under evolution implicates a biological importance for multivalency of the C-terminal region of TSPs. Most protostomes have a single TSP gene encoding a pentameric TSP. The pentameric form is also present in deuterostomes, and gene duplications at the origin of deuterostomes and gene loss and further gene duplication events in the vertebrate lineage gave rise to distinct forms and novel domain architectures. Parallel analysis of the major ligands of mammalian TSPs revealed that many binding activities are neofunctions representing either coevolutionary innovations in the deuterostome lineage or neofunctions of ancient molecules such as CD36. Contrasting widely conserved capacities include binding to heparan glycosaminoglycans, fibrillar collagen, or RGD-dependent integrins. These findings identify TSPs as fundamental components of the extracellular interaction systems of metazoa and thus impact understanding of the evolution of ECM networks. The widely conserved activities of TSPs in binding to ECM components or PS2 clade integrins will be relevant to use of TSPs in synthetic extracellular matrices or tissue engineering. In contrast, the neofunctions of vertebrate TSPs likely include interactions suitable for therapeutic targeting without general disruption of ECM.

Thrombospondin-based antiangiogenic therapy.

Thrombospondins (TSPs) are a family of extracellular matrix proteins that regulate tissue genesis and remodeling. TSP-1 plays a pivotal role in the regulation of both physiological and pathological angiogenesis. The inhibitory effects of TSP-1 on angiogenesis have been established in numerous experimental models. Among other TSP members, TSP-2 has equivalent domain structure as TSP-1 and shares most functions of TSP-1. The mechanisms by which TSP-1 and -2 inhibit angiogenesis can be broadly characterized as direct effects on vascular endothelial cells and indirect effects on the various angiogenic regulators. The fact that TSP-1 and -2 are potent endogenous angiogenic inhibitors has prompted studies to explore their therapeutic applications, and detailed understanding of the mechanisms of action of TSP-1 and -2 has facilitated the design of therapeutic strategies to optimize these activities. The therapeutic effects can be achieved by up-regulation of endogenous TSPs, or by the delivery of recombinant proteins or synthetic peptides that contain sequences from the angiogenic domain of TSP-1. In this article, we review the progress in thrombospondin-based antiangiogenic therapy and discuss the perspectives on the significant challenges that remain.

R-Spondin proteins: a novel link to beta-catenin activation.

The R-spondin (Rspo) protein family is a recently described group of four distinct human secreted proteins. Reported activities for Rspo proteins include essential roles in vertebrate development and their ligand-type activities overlap substantially with those of the canonical Wnt ligands in that both Rspo and canonical Wnt signaling result in the activation of beta-catenin. In a general functional screen for human secreted proteins using transgenic mouse models, we identified human R-spondin1 (hRspo1) protein as a potent and specific mitogen for the gastrointestinal epithelium and demonstrated a potential therapeutic application for the protein in mouse models of cancer therapy-induced mucositis. In contrast to previous studies, our data indicated only partial overlap between Wnt and Rspo ligand activities, suggesting that there may be independent receptor/signaling pathways for Rspo proteins that intersect those of Wnt at the level of beta-catenin. Here we summarize the current reported data on the Rspo family and discuss these results in terms of alternate mechanisms of action. We have extended our observations on the potential therapeutic application of Rspo proteins by showing that all four human Rspo family members are capable of inducing epithelial proliferation and report the first non-vertebrate Rspo family member.

The thrombospondins.

Thrombospondin-1 (TSP-1) was studied in the 1980s as a major component of platelet alpha-granules released upon platelet activation and also as a cell adhesion molecule. In 1993, we published a short review that discussed the exciting identification by molecular cloning of four additional vertebrate gene products related to TSP-1 [Current Biology 3 (1993) 188]. We put forward a structurally based classification for the newly identified proteins and discussed the functional and evolutionary implications of the new gene family. Since that time, the depth and breadth of knowledge on vertebrate TSPs and their functions in cells and tissues in health and disease has expanded into important new areas. Of particular interest is the new knowledge on the complex, domain and cell-type specific effects of TSPs on cell-signaling and cell-adhesion behaviour, the roles of TSP-1 and TSP-2 as anti-angiogenic agents, the roles of TSP-1 and TSP-2 in wound-healing, and associations of point mutations and polymorphisms in TSP-1, TSP-4 and TSP-5/COMP with human genetic diseases. The TSP family also now includes invertebrate members. In this article, we give the 2004 view on TSPs and our perspectives on the significant challenges that remain. Other articles in this issue discuss the functions of vertebrate TSPs in depth.