Kam RK , Shi W , Chan SO , Chen Y , Xu G , Lau CB , Fung KP , Chan WY , Zhao H .

	FIGURE 1. dhrs3 expression is induced by atRA. A, expression of dhrs3 in whole embryos and animal caps was induced in response to a 4-h treatment of 1 μM atRA or xnr1 overexpression. WE, whole embryos; AC, animal cap. B, expression patterns of dhrs3 and cyp26a1 in stage 12 embryos in response to a 4-h treatment of 1 μM atRA. Dorsal view. C, expression patterns of dhrs3, cyp26a1, and aldh1a2, in stage 13 (dorsal view) and stage 35 embryos (lateral view).
	FIGURE 2. Overexpression of dhrs3 counteracts the action of Aldh1a2. A, morphology of stage 35 embryos injected with 2 ng of aldh1a2 alone or in combination with 2 ng of dhrs3 at the two-cell stage, followed by treatment with either DMSO or 0.5 μM atRAL during gastrulation. Arrows indicate the measurement of the head diameter. B, quantification of the relative embryo head diameter of uninjected and injected embryos treated with atRAL. C, expression of atRA-responsive genes hoxd1, gbx2, cdx4, and lhx1 in animal caps overexpressing aldh1a2 alone or in combination with dhrs3, DMSO, or atRAL treatment. D, proposed role of dhrs3 in the atRA metabolism. Dashed arrow indicates the induced expression of dhrs3 by atRA. WE, whole embryos; AC, animal caps.
	FIGURE 3. Overexpression of dhrs3 attenuates RA signaling. A, overexpression of dhrs3 counteracts the action of rdh10. Expression of atRA-responsive genes hoxd1, gbx2, and cdx4 in animal caps overexpressing rdh10 alone or in combination with dhrs3 in the presence of atROL. The expression of atRA-responsive genes was induced by ectopic rdh10, but this induction was suppressed by co-expression with dhrs3. WE, whole embryos; AC, animal caps. B and C, dhrs3 overexpression phenotypes were reversed by atRAL. Lateral view of stage 35 embryos showed phenotypes induced by dhrs3 overexpression, which were reversed by a nonteratogenic dose of 0.5 μM atRAL during gastrulation (B). Quantification of relative embryo length of embryos exposed to atRAL with or without dhrs3 overexpression (C). ***, analysis of variance, p < 0.0005. D and E, dhrs3 overexpression enhanced the phenotypes induced by ectopic cyp26a1. Lateral view of stage 35 embryos exhibited shortened trunk of AP axis when overexpressing dhrs3, cyp26a1, or both (D). Two-cell stage embryos were injected with 4 ng of dhrs3, 2 ng of cyp26a1 mRNA, or both. Quantification of relative embryo length is shown in E. F, overexpression of dhrs3 caused a posterior shift of the expression domain of en2, krox20, and hoxb3. At the four-cell stage, one dorsal blastomere of the embryo was injected with 4 ng of dhrs3 mRNA together with 100 pg of lacZ mRNA as lineage tracer. Injected side is on the right (asterisk). Overexpression of dhrs3 caused a posterior shift of the expression domain of the examined neural markers. Images of en2, krox20, and hoxb3 are the frontal view of the embryos. Percentages of embryos showing the phenotype is marked in the figure.
	FIGURE 4. dhrs3 negatively regulates the synthesis of endogenous atRA. A, log-log plot showing the relationship between different concentrations of atRA standard applied to HEK293T cells and the respective luciferase activity. B, relative concentration of embryonic atRA under different treatment conditions compared with control as measured by cell-based luciferase assay. Overexpression of cyp26a1 and dhrs3 reduced the endogenous atRA level, whereas overexpression of aldh1a2, rdh10, or knockdown of dhrs3 strongly increased atRA concentration in the embryos. The measured concentration of atRA in cell culture is indicated in the plot as mean � S.D. in nM. Readings were taken in triplicate. C, relative concentration of embryonic atRA in aldh1a2-overexpressing embryos and Dhrs3 knockdown embryos, as measured by LC-MS. Relative level of atRA is represented as fold change compared with control reading. Injection dose of each condition per embryo is as follows: 4 ng for cyp26a1; 4 ng for dhrs3 ORF; 30 ng for Dhrs3 MO; 4 ng for aldh1a2; 4 ng for rdh10.
	FIGURE 5. dhrs3 morphants exhibit shortened axis and reduced head structure. A, 25-base-long morpholino was designed to target the 5′-UTR region of dhrs3. The start codon ATG is underlined. B, Western blot shows that Dhrs3 MO inhibited in vitro translation of C-terminal FLAG-tagged full-length dhrs3 (Dhrs3-FLAG). Dhrs3-FLAG contained the targeting sequence of Dhrs3 MO. C, Dhrs3 MO decreased translation of Dhrs3-FLAG in embryos. Embryos were first injected with dhrs3 mRNA with or without Dhrs3 MO, followed by protein extraction at stage 10. Anti-FLAG antibody was used to detect Dhrs3-FLAG, and endogenous actin was employed as the loading control. D, stage 35 embryos injected with 30 ng of Dhrs3 MO at the two-cell stage or treated with 1 μM atRA during gastrulation showed a shortened AP axis and reduced head structure compared with uninjected embryos. Co-injection of 1 ng of dhrs3 mRNA lacking 5′-UTR rescued the morphant phenotypes. E, quantification of the relative head diameter of uninjected and Dhrs3 MO-injected embryos. F, expression of en2, krox20, and hoxb3 in Dhrs3 morphants. At the four-cell stage, one dorsal blastomere was injected with 12.5 ng of Dhrs3 MO together with 100 pg of lacZ mRNA as the lineage tracer. Injected side is on the right (asterisk). Whole mount in situ hybridization was performed at stage 19. Expression of en2, krox20, and hoxb3 was localized in the anterior neuroectoderm. Knockdown of dhrs3 suppressed the expression of these three genes on the injected side (asterisk). Percentages of embryos showing the phenotype are marked in the figure. G, real time PCR indicated that expression level of en2, krox20, and hoxb3 at stage 19 was down-regulated by dhrs3 knockdown. ***, analysis of variance, p < 0.0005.
	FIGURE 6. Expression patterns of mesoderm and organizer marker genes in Dhrs3 morphants and embryos treated with 1 μM atRA during gastrulation. Embryos were injected at the two-cell stage with either 30 ng of Dhrs3 MO or 30 ng of Dhrs3 MO plus 1 ng of dhrs3 mRNA or treated with 1 μM of atRA at gastrulation stages. Whole mount in situ hybridization was used to visualize mesoderm marker gene brachyury (bra) (A1�A4), organizer marker genes lhx1 (B1�B4), and goosecoid (gsc) (C1�C4). Expression of bra was disrupted in Dhrs3 morphants (A2, arrow) and in embryos treated with atRA (A4, arrow). Injection of 1 ng of dhrs3 mRNA rescued the disruption (A3). The expression intensity of lhx1 was elevated by Dhrs3 knockdown (B2) and atRA treatment (B4). Compared with the control embryos (C1), the expression domain of gsc was closer to the blastopore in Dhrs3 morphants (C2) and was abolished by atRA treatment (C4). Dotted line outlined the blastopore.
	FIGURE 7. Defective convergent extension movement induced by knockdown of Dhrs3. Expression of mesoderm and notochord marker genes brachyury (bra), not, and goosecoid (gsc), and CE marker gene papc in control embryos (A-D), in response to dhrs3 knockdown (E-H), dhrs3 overexpression (I-L), or exogenous atRA (M-P). The expression domain of bra and not was shortened by Dhrs3 knockdown (E and F) and embryos treated with atRA (M and N). A similar but less severe shortening of bra expression domain was observed in embryos overexpressing dhrs3 (I). The not expression domain remained in normal shape, but the signal was less intensified in embryos overexpressing dhrs3 (J). The expression of gsc was suppressed by Dhrs3 knockdown (G) and atRA treatment (O) but was unaffected by dhrs3 overexpression (K). papc expression domain was more diffused in Dhrs3 morphants (H) and atRA treated embryos (P) when compared with control embryos (D). Percentages of embryos showing the phenotypes were marked in the figure. All embryos are dorsal view.
	FIGURE 8. Knockdown of Dhrs3 interferes with somitogenesis. Dhrs3 MO (30 ng) was injected at the two-cell stage, and the morphants were collected at stage 28 for immunostaining and whole mount in situ hybridization analysis. A-B′, immunostaining with 12/101 antibody indicated that in Dhrs3 morphants the somites showed a diffused pattern and a reduction in immunoreactivity. C-H′, expression of somite marker genes myoD, pax3, and fgf8 on the dorsal side of the embryos showed the segmented expression pattern of somite units in the control embryos (C′-E′, arrow) was not observed in Dhrs3 morphants (F′-H′). I, real time PCR indicated that expression level of myoD, pax3, and fgf8 at stage 21 was down-regulated in Dhrs3 morphants.
	Figure S1: dhrs3 has the similar effect of cyp26a1 on neuroectoderm patterning. At 4-cell stage, one dorsal blastomere of the embryo was injected with different combinations of 2 ng cyp26a1 or 4 ng dhrs3, together with 100 pg LacZ as lineage tracer. Whole mount in situ hybridization was done at stage 19. Injected side is on the right (asterisk). (A, B) expression of en2, krox20, and foxd3 in control embryos. (C-F) overexpression of cyp26a1 or dhrs3 causes posterior shift of en2 and krox20 expression. Similar trend was observed for neural crest marker foxd3 (white dashed line).
	Figure S2: dhrs3 suppresses the formation of pronephros. (A) The pronephros marker gene lhx1 indicated the position of the pronephros in stage 35 embryos. lhx1 was also expressed in the neural tube. (B) The expression of lhx1 in the pronephros region was enhanced by dhrs3 knockdown, suggesting that dhrs3 exerted an inhibitory role on pronephros development. (C) Overexpression of dhrs3 inhibited the development of pronephros, as showed by lhx1 staining in that region.

Abu-Abed, The retinoic acid-metabolizing enzyme, CYP26A1, is essential for normal hindbrain patterning, vertebral identity, and development of posterior structures. 2001, Pubmed

Abu-Abed, The retinoic acid-metabolizing enzyme, CYP26A1, is essential for normal hindbrain patterning, vertebral identity, and development of posterior structures. 2001, Pubmed
Aulehla, Signaling gradients during paraxial mesoderm development. 2010, Pubmed
Bollig, A highly conserved retinoic acid responsive element controls wt1a expression in the zebrafish pronephros. 2009, Pubmed
Brent, FGF acts directly on the somitic tendon progenitors through the Ets transcription factors Pea3 and Erm to regulate scleraxis expression. 2004, Pubmed
Caneparo, Dickkopf-1 regulates gastrulation movements by coordinated modulation of Wnt/beta catenin and Wnt/PCP activities, through interaction with the Dally-like homolog Knypek. 2007, Pubmed , Xenbase
Cartry, Retinoic acid signalling is required for specification of pronephric cell fate. 2006, Pubmed , Xenbase
Cerignoli, retSDR1, a short-chain retinol dehydrogenase/reductase, is retinoic acid-inducible and frequently deleted in human neuroblastoma cell lines. 2002, Pubmed
Chen, Cell-autonomous and signal-dependent expression of liver and intestine marker genes in pluripotent precursor cells from Xenopus embryos. 2003, Pubmed , Xenbase
Chen, A concentration gradient of retinoids in the early Xenopus laevis embryo. 1994, Pubmed , Xenbase
Chen, Retinoic acid signaling is essential for pancreas development and promotes endocrine at the expense of exocrine cell differentiation in Xenopus. 2004, Pubmed , Xenbase
Chen, Inhibition of Tgf beta signaling by endogenous retinoic acid is essential for primary lung bud induction. 2007, Pubmed
Dequéant, Segmental patterning of the vertebrate embryonic axis. 2008, Pubmed
Duester, Cytosolic retinoid dehydrogenases govern ubiquitous metabolism of retinol to retinaldehyde followed by tissue-specific metabolism to retinoic acid. 2003, Pubmed
Duester, Retinoic acid regulation of the somitogenesis clock. 2007, Pubmed
Esteban-Pretel, Vitamin A deficiency alters rat lung alveolar basement membrane: reversibility by retinoic acid. 2010, Pubmed
Feng, Dhrs3a regulates retinoic acid biosynthesis through a feedback inhibition mechanism. 2010, Pubmed
Gronemeyer, Principles for modulation of the nuclear receptor superfamily. 2004, Pubmed
Harada, Retinoic acid-inducible G protein-coupled receptors bind to frizzled receptors and may activate non-canonical Wnt signaling. 2007, Pubmed , Xenbase
Harland, In situ hybridization: an improved whole-mount method for Xenopus embryos. 1991, Pubmed , Xenbase
Harvey, MyoD protein expression in Xenopus embryos closely follows a mesoderm induction-dependent amplification of MyoD transcription and is synchronous across the future somite axis. 1992, Pubmed , Xenbase
Hollemann, Regionalized metabolic activity establishes boundaries of retinoic acid signalling. 1998, Pubmed , Xenbase
Hukriede, Conserved requirement of Lim1 function for cell movements during gastrulation. 2003, Pubmed , Xenbase
Isaacs, eFGF regulates Xbra expression during Xenopus gastrulation. 1994, Pubmed , Xenbase
Ishibashi, Expression of Siamois and Twin in the blastula Chordin/Noggin signaling center is required for brain formation in Xenopus laevis embryos. 2008, Pubmed , Xenbase
Janssens, Direct control of Hoxd1 and Irx3 expression by Wnt/beta-catenin signaling during anteroposterior patterning of the neural axis in Xenopus. 2010, Pubmed , Xenbase
Jones, Nodal-related signals induce axial mesoderm and dorsalize mesoderm during gastrulation. 1995, Pubmed , Xenbase
Kam, Retinoic acid synthesis and functions in early embryonic development. 2012, Pubmed
Kam, Developmental expression of Xenopus short-chain dehydrogenase/reductase 3. 2010, Pubmed , Xenbase
Kim, The role of paraxial protocadherin in selective adhesion and cell movements of the mesoderm during Xenopus gastrulation. 1998, Pubmed , Xenbase
Kolm, Xenopus hindbrain patterning requires retinoid signaling. 1997, Pubmed , Xenbase
Kolm, Regulation of the Xenopus labial homeodomain genes, HoxA1 and HoxD1: activation by retinoids and peptide growth factors. 1995, Pubmed , Xenbase
Kuroda, Axial protocadherin is a mediator of prenotochord cell sorting in Xenopus. 2002, Pubmed , Xenbase
Latinkić, The Xenopus Brachyury promoter is activated by FGF and low concentrations of activin and suppressed by high concentrations of activin and by paired-type homeodomain proteins. 1997, Pubmed , Xenbase
Lee, XPteg (Xenopus proximal tubules-expressed gene) is essential for pronephric mesoderm specification and tubulogenesis. 2010, Pubmed , Xenbase
Lee, Retinoic acid leads to cytoskeletal rearrangement through AMPK-Rac1 and stimulates glucose uptake through AMPK-p38 MAPK in skeletal muscle cells. 2008, Pubmed
Luxardi, Distinct Xenopus Nodal ligands sequentially induce mesendoderm and control gastrulation movements in parallel to the Wnt/PCP pathway. 2010, Pubmed , Xenbase
Mansukhani, Sox2 induction by FGF and FGFR2 activating mutations inhibits Wnt signaling and osteoblast differentiation. 2005, Pubmed
Mendelsohn, Function of the retinoic acid receptors (RARs) during development (II). Multiple abnormalities at various stages of organogenesis in RAR double mutants. 1994, Pubmed
Mic, Novel retinoic acid generating activities in the neural tube and heart identified by conditional rescue of Raldh2 null mutant mice. 2002, Pubmed
Mizuseki, Xenopus Zic-related-1 and Sox-2, two factors induced by chordin, have distinct activities in the initiation of neural induction. 1998, Pubmed , Xenbase
Niederreither, Embryonic retinoic acid synthesis is essential for heart morphogenesis in the mouse. 2001, Pubmed
Ryckebusch, Retinoic acid deficiency alters second heart field formation. 2008, Pubmed
Sandell, RDH10 is essential for synthesis of embryonic retinoic acid and is required for limb, craniofacial, and organ development. 2007, Pubmed
Shen, Nodal signaling: developmental roles and regulation. 2007, Pubmed
Strate, Retinol dehydrogenase 10 is a feedback regulator of retinoic acid signalling during axis formation and patterning of the central nervous system. 2009, Pubmed , Xenbase
Tada, Convergent extension: using collective cell migration and cell intercalation to shape embryos. 2012, Pubmed , Xenbase
Taira, The LIM domain-containing homeo box gene Xlim-1 is expressed specifically in the organizer region of Xenopus gastrula embryos. 1992, Pubmed , Xenbase
Taira, Expression of the LIM class homeobox gene Xlim-1 in pronephros and CNS cell lineages of Xenopus embryos is affected by retinoic acid and exogastrulation. 1994, Pubmed , Xenbase
Tanibe, Retinoic acid metabolizing factor xCyp26c is specifically expressed in neuroectoderm and regulates anterior neural patterning in Xenopus laevis. 2008, Pubmed , Xenbase
Uehara, Removal of maternal retinoic acid by embryonic CYP26 is required for correct Nodal expression during early embryonic patterning. 2009, Pubmed
Wessely, Neural plate patterning by secreted signals. 2002, Pubmed
White, How degrading: Cyp26s in hindbrain development. 2008, Pubmed
Williams, Pax-3 expression in segmental mesoderm marks early stages in myogenic cell specification. 1994, Pubmed
Wingert, The cdx genes and retinoic acid control the positioning and segmentation of the zebrafish pronephros. 2007, Pubmed , Xenbase
Zhao, Isolation and characterization of a Xenopus gene (XMLP) encoding a MARCKS-like protein. 2001, Pubmed , Xenbase