Abstract
The TGF-β signaling pathway is a metazoan-specific intercellular signaling pathway known to be important in many developmental and cellular processes in a wide variety of animals. We investigated the complexity and possible functions of this pathway in a member of one of the earliest branching metazoan phyla, the ctenophore Mnemiopsis leidyi. A search of the recently sequenced Mnemiopsis genome revealed an inventory of genes encoding ligands and the rest of the components of the TGF-β superfamily signaling pathway. The Mnemiopsis genome contains nine TGF-β ligands, two TGF-β-like family members, two BMP-like family members, and five gene products that were unable to be classified with certainty. We also identified four TGF-β receptors: three Type I and a single Type II receptor. There are five genes encoding Smad proteins (Smad2, Smad4, Smad6, and two Smad1s). While we have identified many of the other components of this pathway, including Tolloid, SMURF, and Nomo, notably absent are SARA and all of the known antagonists belonging to the Chordin, Follistatin, Noggin, and CAN families. This pathway likely evolved early in metazoan evolution as nearly all components of this pathway have yet to be identified in any non-metazoan. The complement of TGF-β signaling pathway components of ctenophores is more similar to that of the sponge, Amphimedon, than to cnidarians, Trichoplax, or bilaterians. The mRNA expression patterns of key genes revealed by in situ hybridization suggests that TGF-β signaling is not involved in ctenophore early axis specification. Four ligands are expressed during gastrulation in ectodermal micromeres along all three body axes, suggesting a role in transducing earlier maternal signals. Later expression patterns and experiments with the TGF-β inhibitor SB432542 suggest roles in pharyngeal morphogenesis and comb row organization.
Highlights
The transforming growth factor-b (TGF-b) signaling pathway was first discovered about 30 years ago, a pathway in which certain secreted proteins had the capability of transforming cells and tissues
Ligand diversity Similar to the situation previously seen for the Wnt/b-catenin pathway, searches of the Mnemiopsis genome have revealed a near complete TGF-b signaling pathway (Table 1)
When further analyses were run on the TGF-b-like clade using both the propeptide domain and the peptide domain, MlTGFbA and MlTGFbB end up as sister to the Activin+Myostatin grouping; we do not think these genes are TGF-b sensu stricto or Lefty orthologs per se, but rather divergent members of the TGF-b-like clade
Summary
The transforming growth factor-b (TGF-b) signaling pathway was first discovered about 30 years ago, a pathway in which certain secreted proteins had the capability of transforming cells and tissues. Similar proteins were discovered in animals as diverse as flies, nematodes, and vertebrates, all of which had similar functions in tissue morphogenesis (reviewed in [2,3,4,5]). Through the use of cloning and sequencing technologies, it was soon discovered that the genes encoding for these proteins were all related and diversified from a common ancestral gene. The TGF-b-like class includes TGFb sensu stricto, Lefty, Activin/Inhibin, and Myostatin/Gdf. The BMP class includes Bmp2/4/Dpp, Bmp, Bmp, Gdf, Gdf, Vg1/Univin, ADMP, and Nodal. Besides being known for its roles in morphogenesis, TGF-b signaling, especially via Bmp2/4/Dpp, is known for its role in dorsal-ventral patterning in both protostomes and deuterostomes (reviewed in [6,7])
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