Kinoshita N et al. (1995), The identification of two novel ligands of the ...

XB-ART-19013

Cell 1995 Nov 17;834:621-30. doi: 10.1016/0092-8674(95)90102-7.

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The identification of two novel ligands of the FGF receptor by a yeast screening method and their activity in Xenopus development.

Kinoshita N , Minshull J , Kirschner MW .

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We have developed a functional screen in yeast to identify ligands for receptor tyrosine kinases. Using this method, we cloned two Xenopus genes that activate the fibroblast growth factor (FGF) receptor. These encode novel secreted proteins, designated FRL1 and FRL2, distantly related to the epidermal growth factor and angiogenin/ribonuclease families, respectively. Both genes activate the FGF receptor in Xenopus oocytes as well as in yeast. Overexpression induces mesoderm and neural-specific genes in Xenopus explants; induction is blocked by a dominant negative inhibitor of the FGF receptor. FRL1 is broadly expressed during gastrulation and neurulation, while FRL2 is expressed principally in the axial mesoderm and brain at later stages. Our results indicate that despite their lack of similarity with FGF, FRL1 and FRL2 are ligands for the FGF receptor that play distinct roles in development.

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Species referenced: Xenopus
Genes referenced: cripto.3 fgf2 gsc tbx2 XB5802829

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	Figure 1. Activation of the FGF Receptor in Yeast by Coexpression of the FGF2 Gene (A) Phosphotyrosinecontent of endogenousyeast proteins in response to expression of FGF and its receptor. Yeast strains transformed with the vectors (lanes 1 and 5), pG-FGFR (lanes 2 and 6) pG-FGFR plus pFGF (lanes 3 and 7), and pG-FGFR plus pssFGF (lanes 4 and 6) were cultured in glucose-containing media (lanes l-4) and in galactose- containing media (lanes 5-8). Whole-cell extracts were prepared by cell disruption with glass beads and were analyzed by immunoblotting with anti-phosphotyrosine antibody. (6) The detection of the FGF receptor activation in yeast cells by colony immunoblotting. FGF and the FGF receptorwere coexpressed in yeast and analyzed by colony immunoblotting with anti-phosphotyrosine antibody. The FGF receptor was under the control of the GAL7 promoter (G-FGFR) or the ACT7 promoter (A-FGFR). FGF with or without signal sequence (ssFGF or FGF) was under the control of the GAL I promoter. Yeast strains transformed by the indicated genes were grown on a plate. Colonies were transferred to two membranes and cultured on a glucose-containing or a galactose-containing plate.
	Figure 2. The Activation of the FGF Receptor by FRL7 and FRLP in Yeast A yeast strain expressing the FGF receptor was cotransformed with ssFGF, FRLl, and FRLPgenesunderthecontroloftheGALl promoter. The transformants were streaked, and the colonies were transferred to two membranes and cultured on a glucose-containing or a galactose- containing plate. The membraneswere analyzed by colony immunoblotting method with anti-phosphotyrosine antibody.
	Figure 3. Ammo Acid Sequences of FRLl and FRLZ (A) Sequence alignment of FRLI with mouse cripto. Stars indicate identical amino acid residues. The putative signal sequence and the C-terminal hydrophobic region of FRLl are underlined. (B) Sequence alignment of FRL2 with bovine angiogenin and pancreatic ribonuclease A. Asterisks indicate amino acid residues identical among the three. The putative signal sequence and the C-terminal hydrophobic region of FRLZ are underlined. (C) Hydrophobicity plots of FRLI and FRL2 (Kyte and Doolittle, 1982). (D) Phylogenetic analysis of FRL2 and some of the angiogeninlribonuclease family members: human angiogenin (Kurachi et al., 1985), mouse angiogenin (Bond and Vallee, 1990) rabbit angiogenin (Bond et al., 1993) bovine angiogenin (Maes et al., 1988) mouse ribonuclease A (Schuller et al., 1990) bovine ribonuclease A (Carsana et al., 1988), and bullfrog ribonuclease (Titani et al., 1987).
	Figure 4. The Activation of the FGF Receptor in Xenopus Oocytes by FRLI and FRL2 Indicated RNAs were transcribed in vitro and injected into oocytes. After 48 hr of incubation, oocytes were labeled with Wa2+ for 3 hr, and released Ca2+ from oocytes was measured over 10 min.
	Figure 5. FRLP Binding to the FGF Receptor The fusion protein XFR-AP, composed of the extracellular domain of the FGF receptor and alkaline phosphatase, was produced in COS ceils. %-labeled FRL2 protein synthesized in the reticulocyte lysate was mixed with the XFR-AP in the presence or absence of unlabeled FGF. The proteins precipitated with anti-alkaline phosphatase antibody were analyzed by autoradiography. The vector-transfected COS cells was used as a control (vector). The receptor brings down the 18 kDa ligand at a level of 3.9x over background. Excess cold FGF reduces this to 1.9x over background.
	Figure 6. Effects of the Overexpression of FRLl and FRLZ on Animal Caps and Embryos (A) Morphological changes in animal caps. FRL7 RNA (5 ng) and FRLZ RNA (1 ng) were injected into both blastomeres at the 2-cell stage. Animal caps were isolated at stage 8, cultured for 20 hr at 16OC, and photographed. (B) The effect of FRLI and FRL2 on muscle actin and N-CAM expression. Uninjected animal caps and animal caps injected with 1 ng and 5 ng of FRLI, 5 ng of FRLl plus 1 ng of HAV@, 5 ng of FRLl plus 1 ng of XFD, 1 ng of FRLZ RNA, 1 ng of FRLP plus 1 ng of HAVQ, or 1 ng of FRLP plus 1 ng of XFD RNA were cultured at 16OC for 20 hr. RNA was isolated, and induction of muscle actin (m. actin) and N-CAM genes was assayed by RT-PCR. EFl o was used as an internal control. (C)Common phenotypes of the tailbud stage embryos overexpressing FRLl and FRLP. FRLi or FRL2 RNA (1 ng) was injected into both blastomeres at the 2-cell stage. The left side is anterior.
	Figure 7. The Paracrine Signaling Assay (A) The procedure. mRNA encoding FRLI or FRL2 (10 ng) was injected into Xenopus oocytes. After 1 day of incubation, animal cap explants isolated from Xenopus embryos at stage 8 were grafted onto the injected or uninjected oocytes. (B) The effect of FRLl and FRL2 on muscle actin and N-CAM expression. RNA was isolated from the grafted explants when the sibling embryos reached stage 25. Induction of muscle actin (m. actin) and N-CAM genes was assayed by RT-PCR. EFI a was used as an internal control.
	Figure 8. The Temporal and Spatial Expression of FRL7 and FRLP Genes during Embryogenesis (A) Temporal expression. RNA was isolated from unfertilized eggs and the indicated stages of embryos. The expression of the FRLl and FRLP genes was assayed by RT-PCR. Ornithine decarboxylase (ODC) is present as an internal control. (B) Spatial expression. Stage 10 embryos were dissected into the dorsal half (Dr) and the ventral half (Vn), or into the vegetal half including the marginal zone (Vg) and the animal half (An), and RNA was isolated from these tissues or from stage 10 embryos (Em). The expression of the FRLl gene was assayed by RT-PCR. goosecoid (gsc) is known to be expressed in the dorsal marginal zone (Cho et al., 1991). EFlu is a ubquitously expressed control (Krieg et al., 1989). (C) Whole-mount in situ hybridization in the tailbud stage embryo of FRL2 RNA. Purple staining indicates the localization of the antisense FRL2 probe.
	unnamed (FRL2 protein) gene expression in Xenopus laevis embryo, assayed via in situ hybridization, NF stage 30, lateral view, anterior left, dorsal up.