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FIG. 1. The ability of FGF to induce posterior neural tissue and to
posteriorize existing neural tissue is mediated through Ras, but
Ras-mediated FGF signaling is not required for anterior neural induction.
(A) RT-PCR of animal caps treated with soluble noggin, bFGF, or
both in the presence or absence of N17Ras. Stage 25 whole-embryo
positive control (lane 1) and RT2 negative control (lane 2) were both
derived from total RNA isolated from a normal embryo. Animal caps
without N17Ras (lanes 3â6) and animal caps injected with 1 ng of
N17Ras mRNA (lanes 7â10) were subjected to RT-PCR for various
region-specific A-P neural markers. (B) RT-PCR of animal caps injected
with 100 pg of mRNA encoding Xenopus noggin (lane 4) or 100
pg noggin in combination with 1 ng of inactive FGF receptor mRNA
(HAVf, lane 5), 1 ng dominant negative FGF receptor (XFD, lane 6), 1
ng wild-type c-Ras (lane 7), or 1 ng dominant negative Ras (N17Ras,
lane 8). (C) RT-PCR of animal caps injected with 100 pg of mRNA
encoding Xenopus neurogenin (ngn) in combination with 1 ng XFD or
1 ng N17Ras mRNA. Uninjected animal caps (lane 3), neurogenin
alone (lane 4), neurogenin and XFD (lane 5), and neurogenin and
N17Ras (lane 6).
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FIG. 2. Noggin does not require Ras-mediated FGF signaling to induce anterior neural tissue. Whole-mount in situ hybridizations of
animal caps explanted from uninjected embryos (A, E, I) and embryos injected with 100 pg Xenopus noggin mRNA alone (B, F, J, M), 100
pg noggin in combination with 1 ng XFD mRNA (C, G, K, N), or 100 pg noggin in combination with 1 ng N17Ras mRNA (D, H, L, O).
Markers examined include (AâD) MyoD, (EâH) Nrp1, and (IâL) Otx2. A, E, and I are photographed at half the magnification relative to the
others.
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FIG. 3. N17Ras blocks the activation of the embryonic wounding response in animal caps. A commercially available antibody directed
against the bisphosphorylated forms of MAPK (ERK1 and ERK2, see Materials and Methods) reveals the activation of the embryonic
wounding response in explanted animal caps. The phosphorylation of MAPK is visualized in animal caps derived from uninjected control
embryos at (A) 1, (B) 5, (C) 10, and (D) 20 min after explantation. MAPK phosphorylation is maximal at 10 min and is visible in the cells
at the edges of the tissue. The phosphorylation of MAPK is largely reversed by 20 min after explantation. The activation of the wounding
response is not prevented by 1 ng of c-Ras mRNA (E), but is blocked by 1 ng of N17Ras mRNA (F). Animal caps derived from embryos
injected with 100 pg of Xenopus noggin mRNA alone (G), in combination with 1 ng of XFD mRNA (H), or in combination with 1 ng of
N17Ras mRNA (I). The phosphorylation of MAPK in response to the removal of the animal caps is visible in the presence of noggin alone
or noggin in combination with XFD but not when noggin is co-injected with N17Ras. The animal caps pictured in EâI were fixed 10 min
after explantation.
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FIG. 4. Induction of posterior neural tissue by XBF2 and XMeis3 requires Ras-mediated FGF signaling. Markers used include Otx2,
NCAM, Engrailed 2 (En2), hoxB9, HoxD, Krox20, muscle actin (MA), and EF1a as a control for loading. (A) RT-PCR of animal caps injected
with XBF2 in combination with either XFD or N17Ras. RT-PCR was done on RNA isolated from 10 animal caps per condition. Stage 25
whole-embryo positive control (lane 1), RT2 negative control (lane 2), 100 pg XBF2 mRNA (lane 3), 100 pg XBF2 mRNA in combination
with 1 ng XFD mRNA (lane 4), or 100 pg XBF2 mRNA in combination with 1 ng N17Ras mRNA (lane 5). (B) RT-PCR of animal caps injected
with mRNA encoding XMeis3 in combination with N17Ras. RNA was isolated from 18 animal caps per condition. Stage 20 whole-embryo
positive control (lane 1), uninjected animal caps (lane 2), 1 ng XMeis3 alone (lane 3), 1 ng N17Ras alone (lane 4), 1 ng XMeis3 in combination
with 1 ng N17Ras (lane 5), and RT2 negative control (lane 6). (C) RT-PCR of animal caps injected with mRNA encoding XMeis3 in
combination with MAP kinase phosphatase (MKP). RNA was isolated from 18 animal caps per condition. Stage 20 whole-embryo positive
control (lane 1), uninjected animal caps (lane 2), 1 ng XMeis3 (lane 3), 4 ng MKP (lane 4), 1 ng XMeis3 in combination with 4 ng MKP (lane
5), and RT2 negative control (lane 6).
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FIG. 5. Disruption of Ras-mediated FGF signaling affects the expression of Sox2 in the posterior neural plate. b-Galactosidase activity
stain (red) in the neural plates of embryos stained for Sox2 expression (blue) by in situ hybridization. (A) Uninjected control embryo in
which the normal expression domain of Sox2 is visible. Embryos injected with lacZ mRNA in addition to XFD (B, C), c-Ras (D), or N17Ras
(E, F). If XFD (B) or N17Ras (E) injected mRNAs are expressed in the anterior portion of the neural plate then the expression of the general
neural marker Sox2 is unaffected compared to the control of c-Ras (D). However, if XFD (C) or N17Ras (F) mRNAs are expressed in the
posterior portion of the neural plate, disruptions of Sox2 staining result. All embryos are oriented with the anterior neural plate facing
upward. Arrows indicate loss of Sox2 expression in the posterior neural plate.
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FIG. 6. Grafted neural plates expressing XFD or N17Ras exhibit disruption of posterior neural patterning. (A) A schematic diagram
illustrating the neural plate graft technique. (B) A photo of a graft-recipient embryo shortly after the grafted tissue has healed in place. The
darkly pigmented ectodermal graft is visible on one side of the host embryo, near the dorsal blastopore lip which is oriented up. (CâE) 1 ng
of RNA encoding nuclear b-galactosidase was injected into the animal pole of one-cell embryos. b-Galactosidase activity (red) was used to
indicate the distribution of injected RNA in whole donor embryos (C), embryos after grafts have been removed (D), and isolated grafts (E).
b-Galactosidase activity is visible throughout the animal pole of the donor embryos and is clearly visible throughout the entire graft. (F,
H, J) The location of grafted tissue is revealed by the fluorescence of the Texas red dextran. (G, I, K) Sox2 expression in the same embryos.
(F, G) c-Ras-expressing graft in which the expression of Sox2 is normal. (H, I) XFD-expressing graft and (J, K) N17Ras-expressing graft in
which the expression of Sox2 is disrupted in the posterior but not anterior neural plate. (L) Cell expressing XFD in the spinal cord.
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