Maternal Tgif1 regulates nodal gene expression in Xenopus

Developmental Dynamics

Volumn 237, Issue 10, 2008, Pages 2862-2873

  Kerr, Tyler C ^a   Cuykendall, Tawny N ^a   Luettjohann, Laura C ^a   Houston, Douglas W ^a  

^a UNIVERSITY OF IOWA   (United States)

Author keywords

Holoprosencephaly (HPE); Maternal mRNA; Nodal, VegT; TG interacting factor; Tgif1

Indexed keywords

HOMEODOMAIN PROTEIN; PROTEIN DERIVATIVE; PROTEIN NODAL; PROTEIN NR5; PROTEIN NR6; RETINOID; TG INTERACTING FACTOR 1 PROTEIN; TRANSCRIPTION FACTOR; TRANSCRIPTION FACTOR SIN3; TRANSCRIPTION FACTOR VEGT; TRANSFORMING GROWTH FACTOR BETA; UNCLASSIFIED DRUG;

ARTICLE; CARBOXY TERMINAL SEQUENCE; CONTROLLED STUDY; EMBRYO; GENE EXPRESSION; GENE REPRESSION; NONHUMAN; NUCLEOTIDE SEQUENCE; PRIORITY JOURNAL; PROTEIN DEPLETION; PROTEIN DOMAIN; PROTEIN EXPRESSION; PROTEIN FUNCTION; SIGNAL TRANSDUCTION; UPREGULATION; XENOPUS;

AMINO ACID SEQUENCE; ANIMALS; ANIMALS, GENETICALLY MODIFIED; EMBRYO, NONMAMMALIAN; FEMALE; GENE DELETION; GENE EXPRESSION REGULATION, DEVELOPMENTAL; HOMEODOMAIN PROTEINS; HUMANS; MOLECULAR SEQUENCE DATA; MOTHERS; NODAL PROTEIN; RETINOIDS; RNA, MESSENGER; SEQUENCE ALIGNMENT; SEQUENCE HOMOLOGY, AMINO ACID; SIGNAL TRANSDUCTION; SMAD2 PROTEIN; XENOPUS LAEVIS; XENOPUS PROTEINS;

EID: 54549094847     PISSN: 10588388     EISSN: 10970177     Source Type: Journal    
DOI: 10.1002/dvdy.21707     Document Type: Article

References (45)

1. Agius E, Oelgeschläger M, Wessely O, Kemp C, De Robertis EM. 2000. Endodermal Nodal-related signals and mesoderm induction in Xenopus. Development 127:1173-1183.
2. Bartholin L, Powers SE, Melhuish TA, Lasse S, Weinstein M, Wotton D. 2006. TGIF inhibits retinoid signaling. Mol Cell Biol 26:990-1001.
3. Bartholin L, Melhuish TA, Powers SE, Goddard-Léon S, Treilleux I, Sutherland AE, Wotton D. 2008. Maternal Tgif is required for vascularization of the embryonic placenta. Dev Biol 319:285-297.
4. Bertolino E, Reimund B, Wildt-Perinic D, Clerc RG. 1995. A novel homeobox protein which recognizes a TGT core and functionally interferes with a retinoid-responsive motif. J Biol Chem 270:31178-31188.
5. Blanco-Arias P, Sargent CA, Affara NA. 2002. The human-specific Yp11.2/Xq21.3 homology block encodes a potentially functional testis-specific TGIF-like retroposon. Mamm Genome 13:463-468.
6. Braissant O, Wahil W. 1998. A simplified in situ hybridization protocol using non-radioactively labeled probes to detect abundant and rare mRNAs on tissue sections. Biochemica 1:10-16.
7. Brown SA, Warburton D, Brown LY, Yu CY, Roeder ER, Stengel-Rutkowski S, Hennekam RC, Muenke M. 1998. Holoprosencephaly due to mutations in ZIC2, a homologue of Drosophila odd-paired. Nat Genet 20:180-183.
8. Chea HK, Wright CV, Swalla BJ. 2005. Nodal signaling and the evolution of deuterostome gastrulation. Dev Dyn 234:269-278.
9. Cohen MJ. 2004. SHH and holoprosencephaly. In: Epstein C, Erickson R, Wynshaw-Boris A, editors. Inborn errors of development: the molecular basis of clinical disorders of morphogenesis. New York: Oxford University Press. p 240-248.
10. Dash P, Lotan I, Knapp M, Kandel ER, Goelet P. 1987. Selective elimination of mRNAs in vivo: complementary oligodeoxynucleotides promote RNA degradation by an RNase H-like activity. Proc Natl Acad Sci U S A 84:7896-7900.
11. El-Jaick KB, Powers SE, Bartholin L, Myers KR, Hahn J, Orioli IM, Ouspenskaia M, Lacbawan F, Roessler E, Wotton D, Muenke M. 2007. Functional analysis of mutations in TGIF associated with holoprosencephaly. Mol Genet Metab 90:97-111.
12. Gripp KW, Wotton D, Edwards MC, Roessler E, Ades L, Meinecke P, Richieri-Costa A, Zackai EH, Massague J, Muenke M, Elledge SJ. 2000. Mutations in TGIF cause holoprosencephaly and link NODAL signalling to human neural axis determination. Nat Genet 25:205-208.
13. Heasman J, Holwill S, Wylie CC. 1991. Fertilization of cultured Xenopus oocytes and use in studies of maternally inherited molecules. Methods Cell Biol 36:213-230.
14. Heasman J, Wessely O, Langland R, Craig EJ, Kessler DS. 2001. Vegetal localization of maternal mRNAs is disrupted by VegT depletion. Dev Biol 240:377-386.
15. Hilton E, Rex M, Old R. 2003. VegT activation of the early zygotic gene Xnr5 requires lifting of Tcf-mediated repression in the Xenopus blastula. Mech Dev 120:1127-1138.
16. Houston DW, Wylie C. 2005. Maternal Xenopus Zic2 negatively regulates Nodal-related gene expression during anteroposterior patterning. Development 132:4845-4855.
17. Houston DW, Kofron M, Resnik E, Langland R, Destree O, Wylie C, Heasman J. 2002. Repression of organizer genes in dorsal and ventral Xenopus cells mediated by maternal XTcf3. Development 129:4015-4025.
18. Hyman CA, Bartholin L, Newfeld SJ, Wotton D. 2003. Drosophila TGIF proteins are transcriptional activators. Mol Cell Biol 23:9262-9274.
19. Jin L, Zhou Y, Kuang C, Lin L, Chen Y. 2005. Expression pattern of TG-interacting factor 2 during mouse development. Gene Expr Patterns 5:457-462.
20. Jin JZ, Gu S, McKinney P, Ding J. 2006. Expression and functional analysis of Tgif during mouse midline development. Dev Dyn 235:547-553.
21. Klein SL, Strausberg RL, Wagner L, Pontius J, Clifton SW, Richardson P. 2002. Genetic and genomic tools for Xenopus research: the NIH Xenopus initiative. Dev Dyn 225:384-391.
22. Kofron M, Puck H, Standley H, Wylie C, Old R, Whitman M, Heasman J. 2004. New roles for FoxH1 in patterning the early embryo. Development 131:5065-5078.
23. Lagutin OV, Zhu CC, Kobayashi D, Topczewski J, Shimamura K, Puelles L, Russell HR, McKinnon PJ, Solnica-Krezel L, Oliver G. 2003. Six3 repression of Wnt signaling in the anterior neuroectoderm is essential for vertebrate forebrain development. Genes Dev 17:368-379.
24. Lo RS, Wotton D, Massague J. 2001. Epidermal growth factor signaling via Ras controls the Smad transcriptional co-repressor TGIF. EMBO J 20:128-136.
25. Mar L, Hoodless PA. 2006. Embryonic fibroblasts from mice lacking Tgif were defective in cell cycling. Mol Cell Biol 26:4302-4310.
26. Melhuish TA, Wotton, D. 2000. The interaction of the carboxyl terminus-binding protein with the Smad corepressor TGIF is disrupted by a holoprosencephaly mutation in TGIF. J Biol Chem 275:39762-39766.
27. Melhuish TA, Gallo CM, Wotton D. 2001. TGIF2 interacts with histone deacetylase 1 and represses transcription. J Biol Chem 276:32109-32114.
28. Mukherjee K, Bürglin TR. 2007. Comprehensive analysis of animal TALE homeobox genes: new conserved motifs and cases of accelerated evolution. J Mol Evol 65:137-153.
29. Nishita M, Hashimoto MK, Ogata S, Laurent MN, Ueno N, Shibuya H, Cho KW. 2000. Interaction between Wnt and TGF-beta signalling pathways during formation of Spemann's organizer. Nature 403:781-785.
30. Pasquier L, Dubourg C, Blayau M, Lazaro L, Le Marec B, David V, Odent S. 2000. A new mutation in the six-domain of SIX3 gene causes holoprosencephaly. Eur J Hum Genet 8:797-800.
31. Piccolo S, Agius E, Leyns L, Bhattacharyya S, Grunz H, Bouwmeester T, De Robertis EM. 1999. The head inducer Cerberus is a multifunctional antagonist of Nodal, BMP and Wnt signals. Nature 397:707-710.
32. Shen J, Walsh CA. 2005. Targeted disruption of Tgif, the mouse ortholog of a human holoprosencephaly gene, does not result in holoprosencephaly in mice. Mol Cell Biol 25:3639-3647.
33. Shen MM. 2007. Nodal signaling: developmental roles and regulation. Development 134:1023-1034.
34. Sive H, Grainger RM, Harland RM. 2000. Early development of Xenopus laevis: a laboratory manual. Cold Spring Harbor, NY: Cold Spring Harbor Laboratory Press. p 249-297.
35. Spagnoli FM, Brivanlou AH. 2008. The Gata5 target, TGIF2, defines the pancreatic region by modulating BMP signals within the endoderm. Development 135:451-461.
36. Suri C, Haremaki T, Weinstein DC. 2005. Xema, a foxi-class gene expressed in the gastrula stage Xenopus ectoderm, is required for the suppression of mesendoderm. Development 132:2733-2742.
37. Tabin CJ. 2006. The key to left-right asymmetry. Cell 127:27-32.
38. Takahashi S, Yokota C, Takano K, Tanegashima K, Onuma Y, Goto J, Asashima M. 2000. Two novel nodal-related genes initiate early inductive events in Xenopus Nieuwkoop center. Development 127:5319-5329.
39. Takahashi S, Onuma Y, Yokota C, Westmoreland JJ, Asashima M, Wright CV. 2006. Nodal-related gene Xnr5 is amplified in the Xenopus genome. Genesis 44:309-321.
40. Wotton D, Lo RS, Lee S, Massague J. 1999a. A Smad transcriptional corepressor. Cell 97:29-39.
41. Wotton D, Lo RS, Swaby LA, Massague J. 1999b. Multiple modes of repression by the Smad transcriptional corepressor TGIF. J Biol Chem 274:37105-37110.
42. Wotton D, Knoepfler PS, Laherty CD, Eisenman RN, Massague J. 2001. The Smad transcriptional corepressor TGIF recruits mSin3. Cell Growth Differ 12:457-463.
43. Xanthos JB, Kofron M, Tao Q, Schaible K, Wylie C, Heasman J. 2002. The roles of three signaling pathways in the formation and function of the Spemann Organizer. Development 129:4027-4043.
44. Yokota C, Kofron M, Zuck M, Houston DW, Isaacs H, Asashima M, Wylie CC, Heasman J. 2003. A novel role for a nodal-related protein; Xnr3 regulates convergent extension movements via the FGF receptor. Development 130:2199-2212.
45. Zhang C, Basta T, Jensen ED, Klymkowsky MW. 2003. The beta-catenin/VegT-regulated early zygotic gene Xnr5 is a direct target of SOX3 regulation. Development 130:5609-5624.