Zhang C and Klymkowsky MW (2007), The Sox axis, Nodal signaling, and germ layer s...

XB-ART-36186

Differentiation 2007 Jul 01;756:536-45. doi: 10.1111/j.1432-0436.2007.00190.x.

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The Sox axis, Nodal signaling, and germ layer specification.

Zhang C , Klymkowsky MW .

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Asymmetries in the egg, established during oogenesis, set the stage for a cascade of intercellular signaling events leading to differential gene expression and subsequent tissue and organ formation. Maternally supplied Sox-type transcription factors have recently emerged as key components in the patterning of the early embryo and the regulation of embryonic stem cell differentiation. In deuterostomes, B1-type Soxs are asymmetrically localized to the future animal/ectodermal region where they act to suppress mesendodermal, and favor neuroectodermal differentiation, while vegetally localized F-type Soxs are involved in mesendodermal differentiation. Here, we review past observations and present new data from studies on the clawed frog Xenopus laevis. Animally localized Sox3 acts to inhibit Nodal (Xnr5 and Xnr6) expression, and induces the expression of genes (Ectodermin, Xema, and Coco) whose products repress Nodal signaling. Vegetally localized Sox7 positively regulates Nodal (Xnr4, Xnr5, and Xnr6) expression, as well as the expression of genes involved in mesodermal (Xmenf, Slug, and Snail) and endodermal (Endodermin and Sox17beta) differentiation. Given the evolutionary strategy of using common regulatory networks, it seems likely that a homologous Sox-Axis is active during embryonic development in many metazoans.

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Species referenced: Xenopus laevis
Genes referenced: a2m ctnnb1 dand5 foxi1 menf.1 nodal nodal1 nodal2 nodal5.4 nodal6 pou5f3.2 pou5f3.3 snai1 snai2 sox1 sox17a sox18 sox2 sox3 sox7 tbxt trim33 twist1

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	Fig. 1 (A) This schematic shows the relative location of the sequence-specific DNA-binding high mobility group (HMG) domain within the Sox3 and Sox7 polypeptides. (B) An alignment of the HMG boxes of Xenopus laevis Sox1, Sox2, Sox3, Sox7, Sox17b, and Sox18b polypeptides shows the similarity between B1-type Soxs (ââB1-typeââ)(all residues identical ââââ or conserved ââ:ââ); F-type Soxs (ââF-typeââ); and B1- and F-type Soxs (ââcommonââ) HMG domains. The alignment was generated using the http://align. genome.jp/web site. Between the F-type Soxs, there are two sites that are different (arrows) in all three proteins. (C) The structure of the HMG domain of Sox2 (yellow) bound to the minor groove of DNA as determined crystallographically by Williams et al. (2004).
	Fig. 2 Sox3â€™s regulatory targets: (A) Fertilized eggs were injected with RNA (600 pg/embryo) encoding GR-Sox3-GFP; animal caps were prepared at stage 8/9; the protein was activated shortly thereafter and analyzed by quantitative reverse-transcriptase polymerase chain reaction when control embryos reached stage 11. Levels of Xnr1, Xnr2, Xnr4, Xnr5, and Xnr6 RNAs decreased between 70% and 80% compared with control animal caps (no dexamethasoneâ€” black bar). Emetine blocked the effects of Sox3 on Xnr1, Xnr2, and Xnr4 RNAs, but had little effect on Xnr5 and Xnr6 RNA levels. (B) Activation of GR-Sox3-GFP led to a small but reproducible, emetine- insensitive increase in the levels of Oct25 and Oct60 RNAs.
	Fig. 3 Sox3 acts downstream of Xnr5: Fertilized eggs were injected with Xnr5 RNA (200 pg/embryo) alone or together with Sox3 RNA (600 pg/embryo) and an RNA encoding the lineage marker b-galactosidase (100 pg/embryo); at stage 11, embryos were stained for Xbra RNA. In Xnr5 RNA-injected embryos (A), Xbra expression, normally restricted to a region around the blastopore, was found throughout the animal hemisphere. Co-injection of Sox3 RNA (B) blocked the Xnr5-induced Xbra expression. The area where the b-galactosidase lineage marker was found is marked by a dashed circle. In embryos injected with GR-Sox3-GFP RNA, dexamethasone treatment (at stage 8/9) led to an emetine-insensitive increase in Ectodermin (C), Coco, and Xema (D) mRNAs, and an emetine-sensitive decrease in the levels of Xmenf RNA (D) (embryos analyzed at stage 11). (E) Fertilized eggs were injected with an antiSox3c antibody (10 or 20 ng/embryo) and analyzed by quantitative reverse-transcriptase polymerase chain reaction at stage 11; compared with uninjected embryos, antiSox3c-injected embryos displayed decreased levels of Ectodermin, Coco, and Xema RNAs and increased levels of Xmenf RNA. (F) Injection of antiSox3c led to an increase in Endodermin RNAs, while injection of antiTcf3c produced no effect. The antiSox3c-induced increase in Endodermin RNA was blocked by co-injection of the Nodal inhibitor CerS; similar results were reported previously for the endodermal marker Sox17b (Zhang et al., 2004).
	Fig. 4 Sox7-regulated target genes: (A) In embryos injected with GR-Sox7-GFP RNA (600 pg/embryo), Ectodermin RNA levels were decreased in an emetine-sensitive manner upon dexamethasone- treatment activation. (B) Reverse-transcriptase polymerase chain reaction studies indicate an emetine-insensitive Sox7-dependent up-regulation of Xmenf and Endodermin RNAs in animal caps, whereas Sox7â€™s effect on Twist RNA levels was emetine-sensitive, and so likely to be indirect. (C) In whole embryo studies (analyzed at stage 11), both Slug and Snail appear to be direct and positively regulated targets of Sox7.
	Fig. 5 (A) Schematic showing how animally localized Sox3 acts to repress the expression of Nodals and activate the expression of repressors of Nodal activity (Oct, Ectodermin, Coco, and Xema), while vegetally localized Sox7 acts to increase the levels of Nodal RNAs. (B) A more detailed, although still quite incomplete and tentative network links Sox3-dependent suppression of Nodal expression and signaling with Sox7âs ability to induce Nodal expression, as well as markers of the mesendodermal germ layer.