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Activity of the Transforming growth factor-β (TGFβ) pathway is essential to the establishment of body axes and tissue differentiation in bilaterians. Orthologs for core pathway members have been found in all metazoans, but uncertain homology of the body axes and tissues patterned by these signals raises questions about the activities of these molecules across the metazoan tree. We focus on the principal canonical transduction proteins (R-Smads) of the TGFβ pathway, which instruct both axial patterning and tissue differentiation in the developing embryo. We compare the activity of R-Smads from a cnidarian (Nematostella vectensis), an arthropod (Drosophila melanogaster), and a vertebrate (Xenopus laevis) in Xenopus embryonic assays.Overexpressing NvSmad1/5 ventralized Xenopus embryos when expressed in dorsal blastomeres, similar to the effects of Xenopus Smad1. However, NvSmad1/5 was less potent than XSmad1 in its ability to activate downstream target genes in Xenopus animal cap assays. NvSmad2/3 strongly induced general mesendodermal marker genes, but weakly induced ones involved in specifying the Spemann organizer. NvSmad2/3 was unable to induce a secondary trunk axis in Xenopus embryos, whereas the orthologs from Xenopus (XSmad2 and XSmad3) and Drosophila (dSmad2) were capable of doing so. Replacement of the NvSmad2/3 MH2 domain with the Xenopus XSmad2 MH2 slightly increased its inductive capability, but did not confer an ability to generate a secondary body axis.Vertebrate and cnidarian Smad1/5 have similar axial patterning and induction activities, although NvSmad1/5 is less efficient than the vertebrate gene. We conclude that the activities of Smad1/5 orthologs have been largely conserved across Metazoa. NvSmad2/3 efficiently activates general mesendoderm markers, but is unable to induce vertebrate organizer-specific genes or to produce a secondary body axis in Xenopus. Orthologs dSmad2 and XSmad3 generate a secondary body axis, but activate only low expression of organizer-specific genes that are strongly induced by XSmad2. We suggest that in the vertebrate lineage, Smad2 has evolved a specialized role in the induction of the embryonic organizer. Given the high level of sequence identity between Smad orthologs, this work underscores the functional importance of the emergence and fixation of a few divergent amino acids among orthologs during evolution.
Figure 1. R-Smads are defined by two conserved protein domains. (A) Diagram of a typical R-Smad showing the two conserved domains (MH1 and MH2) with important regions noted. (B) A table of pairwise percent identity of the MAD homology domains and the non-conserved linker regions of Xenopus and Nematostella R-Smads [see Additional file
1 for a detailed amino acid alignment and Additional file
2 for a table of GenBank accession numbers]. (C) Alignment of relevant sections of the Smad1/5/8 linker regions from multiple taxa. The Smurf1 site PPXY motif is highlighted in cyan, MAPK recognition sites are highlighted in yellow, and GSK3 consensus sites are highlighted in green. (D) Alignment of relevant sections of the Smad2/3 linker regions from multiple taxa. The Smurf2 site PPXY motif is highlighted in cyan, MAPK recognition sites are highlighted in yellow, and proline-directed kinase sites are highlighted in magenta. Underlined sequences in (C) and (D) indicate consensus sites identified for the particular protein and species in the literature; all other highlights reflect our inferences based on the alignments.
Figure 2. Phenotypes caused by ectopic NvSmad1/5 mRNA mimic phenotypes caused by XSmad1 mRNA. Microinjection of NvSmad1/5 mRNA into the two dorsal blastomeres of a four-cell Xenopus embryo causes similar ventralization phenotypes as injection of XSmad1 mRNA. All tadpoles are shown at stage 34. (A) Shows normal development in Xenopus tadpoles. In contrast, tadpoles in (B) were injected with 4 ng of XSmad1 mRNA and show severe ventralization. (C) Tadpoles injected with 4 ng NvSmad1/5 show a similar but less severe ventralization phenotype. Severity of phenotype was scored according the Dorso-Anterior Index (DAI)
[30]. (D) Shows the DAI scores graphically.
Figure 3. NvSmad1/5 induces expression of downstream BMP pathway genes in the frog embryo. After animal pole injection of XSmad1 or NvSmad1/5 at the 2-cell stage, stage 11 animal caps show elevated expression of genes downstream of the BMP pathway. (A) Depiction of the animal cap assay procedure; animal caps were processed for western blot or RT-PCR when control embryos reached mid-gastrulation (Niewkoop and Faber stage 11). The western blot shows protein translation levels in injected and uninjected whole embryos (Lâ=âBenchmark protein ladder, showing the 58-kDa band). XSmad1 and NvSmad1/5 show equal levels of translation, whereas the uninjected embryos show no background signal. (B) Real-time quantitative RT-PCR (qPCR) shows fold induction levels of BMP pathway response genes Vent1, Vent2, Msx1, and Xhox3 compared to the uninjected whole embryos. Uninjected Xenopus animal caps (UN), animal caps injected with XSmad1, and animal caps injected with NvSmad1/5 are shown. The Y-axis of all RT-PCR graphs shows the fold induction compared to endogenous whole embryo (1.0). Error bars indicate the standard error.
Figure 4. NvSmad2 induces expression of downstream Activin/Nodal pathway genes in Xenopus . Animal caps injected with XSmad2, XSmad3, dSmad2, or NvSmad2 mRNA at the two-cell stage show elevated expression of genes downstream of the Activin/Nodal pathway. (A) Western blot showing tagged protein translation levels in injected and uninjected whole embryos (Lâ=âBenchmark protein ladder, showing the 58-kDa band). XSmad2, XSmad3, NvSmad2/3, and dSmad2 show equal levels of translation, whereas uninjected embryos show no background signal. Real-time quantitative PCR (RT-PCR) shows fold induction levels of Activin/Nodal pathway members on the Y-axis. (B) Class I markers goosecoid and anti-dorsalizing morphogenetic protein (ADMP). (C) Class II markers chordin, noggin, follistatin, and eomesodermin. (D) Class III markers mixer, mix.2, and sox17α. (E) Class IV marker Xbra. (F) Xbra induction response to 2 ng, 5 ng, and 10 ng XSmad2 or NvSmad2/3. See text for discussion of marker classes.
Figure 5. Swapping in the MH2 domain from XSmad2 increases the inductive activity of NvSmad2/3 . (A) Design of chimeras swapping XSmad2 domains into NvSmad2/3. (B) Western blot showing tagged protein translation levels in injected and uninjected whole embryos (Lâ=âBenchmark protein ladder, showing the 58-kDa band). XSmad2, XSmad3, NvSmad2/3, MH1 chimera, and MH2 chimera show equal levels of translation, whereas the uninjected embryos show none. The linker chimera (âLinkâ) shows slightly lower levels of translation. Note, XSmad3 was injected and included in translation blot to check continuity with previous experiments, but was not used in subsequent animal cap analyses. Animal caps injected with XSmad2, NvSmad2, MH1 chimera, linker chimera, or MH2 chimera mRNA at the two-cell stage show elevated expression of genes downstream in the Activin/Nodal pathway. Real time quantitative PCR shows fold induction levels of Activin/Nodal pathway members on the Y-axis. (C) Class I markers goosecoid and ADMP. (D) Class II markers chordin, noggin, follistatin, and eomesodermin. (E) Class III markers mixer, mix.2, and sox17α. (F) Class IV marker Xbra.
Figure 6. Ectopic overexpression of NvSmad2/3 does not induce a secondary axis in Xenopus embryos. Injection of 0.5 ng XSmad2 mRNA into the marginal zone of one ventralvegetal blastomere at the 8-cell stage can produce a secondary body axis in Xenopus embryos. (A) Uninjected, wild type tadpoles. (B) Tadpoles that were injected with XSmad2 show a classic secondary body axis phenotype (marked with white arrowheads in this photo only). (C) Injection of XSmad3 shows a clear secondary axis. (D) dSmad2 is able to induce the formation of a second body axis. (E) NvSmad2/3 is not able to generate a second body axis, but can perturb the original axis. (F) The MH1 chimera acutely perturbs the original axis, but generates a complete second axis in only a few cases. Embryos were scored for axial phenotypes at neurula stage. Examples: (G) wild type, (H) double axis that would result in a second body axis at tadpole stage (result of XSmad2 mRNA, in this case), (I) another double axis (caused by dSmad2 mRNA, in this case), (J) ‘incipient’ axis that will eventually get subsumed into the primary axis and result in the ‘perturbed axis’ phenotype (result of XSmad3 mRNA, in this case, though it could be caused by any of the treatments), (K) phenotype that would be scored as ‘wild type’ (result of NvSmad2/3 mRNA, in this case). (L) Bar graph illustrating the range of phenotypes from each treatment. See Additional file
6 for more photos illustrating the ‘perturbed axis’ phenotype.
Figure 7. XSmad2ÎExon3 induces expression of downstream Activin/Nodal pathway genes in a pattern resembling XSmad3 rather than full-length XSmad2. Animal caps from gastrulae that had been injected with XSmad2, XSmad2ÎExon3, XSmad3, dSmad2, or NvSmad2 mRNA at the two-cell stage showed elevated expression of genes downstream of the Activin/Nodal pathway. With all markers, the expression patterns induced by XSmad2ÎExon3 (orange column) were more similar to that of XSmad3 (green column) and NvSmad2/3 (teal column) than to full length XSmad2 (red column). (A) Class I marker goosecoid. (B) Class II markers chordin, noggin, and eomesodermin. (C) Class III markers mixer and mix.2.
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