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Widespread expression of the DNA-binding protein Brachyury in Xenopus animal caps causes ectopic mesoderm formation. In this paper, we first show that two types of mesoderm are induced by different concentrations of Brachyury. Animal pole explants from embryos injected with low doses of Xbra RNA differentiate into vesicles containing mesothelial smooth muscle and mesenchyme. At higher concentrations somitic muscle is formed. The transition from smooth muscle formation to that of somitic muscle occurs over a two-fold increase in Brachyury concentration. Brachyury is required for differentiation of notochord in mouse and fish embryos, but even the highest concentrations of Brachyury do not induce this tissue in Xenopus animal caps. Co-expression of Brachyury with the secreted glycoprotein noggin does cause notochord formation, but it is difficult to understand the molecular basis of this phenomenon without knowing more about the noggin signal transduction pathway. To overcome this difficulty, we have now tested mesoderm-specific transcription factors for the ability to synergize with Brachyury. We find that co-expression of Pintallavis, but not goosecoid, with Brachyury causes formation of dorsal mesoderm, including notochord. Furthermore, the effect of Pintallavis, like that of Brachyury, is dose-dependent: a two-fold increase in Pintallavis RNA causes a transition from ventral mesoderm formation to that of muscle, and a further two-fold increase induces notochord and neural tissue. These results suggest that Pintallavis cooperates with Brachyury to pattern the mesoderm in Xenopus.
Fig. 1. Injection of increasing
amounts of Xbra RNA does not
saturate the translation
machinery. The indicated
quantities of Xbra RNA,
together with 1 mCi/ml
[35S]methionine, were injected
into Xenopus embryos at the 1-
cell stage. Animal caps were
dissected at the mid-blastula
stage and cultured in 75% NAM
to control stage 12, when
cellular proteins were subjected
to immunoprecipitation using an
anti-Xbra antiserum.
Immunoprecipitates were
analyzed by polyacrylamide gel
electrophoresis followed by
fluorography.
Fig. 2. Activation of muscle-specific cardiac actin genes requires a
threshold quantity of injected Xbra RNA. Embryos at the 1-cell stage
were injected with the indicated quantities of Xbra RNA. Animal
caps were dissected from these embryos at the mid-blastula stage and
cultured to stage 17/18. RNA was analyzed for expression of cardiac
(muscle-specific) actin by RNAase protection.
Fig. 3. Histological analysis of animal caps derived from embryos injected with increasing quantities of Xbra RNA. Embryos at the 1-cell stage
were injected with increasing amounts of Xbra RNA. Animal caps were dissected from these embryos at the mid-blastula stage and cultured to
stage 42 when they were fixed, sectioned at 7 mm and stained by the Feulgen technique and with Light Green and Orange G. (A) An uninjected
animal cap forms atypical epidermis. (B) Animal caps from embryos injected with 0.5 ng Xbra RNA. This ventral tissue is typical of caps
derived from embryos injected with 0.12 ng to 1 ng Xbra RNA. (C) Animal caps from embryos injected with 4 ng Xbra RNA. This muscle-like
tissue is typical of caps from embryos injected with 1 ng to 4 ng Xbra RNA. Scale bar in C is 100 mm, and also applies to A and B.
Fig. 4. Immunohistochemical analysis of animal caps injected with increasing quantities of Xbra RNA. a-smooth muscle actin and somitic
muscle were defined with monoclonal antibodies a-SM actin (Saint-Jeannet et al., 1992) and 12/101 (Kintner and Brockes, 1984), respectively.
Embryos at the 1-cell stage were injected with increasing amounts of Xbra RNA. Animal caps were dissected from these embryos at the midblastula
stage and cultured to stage 47, when they were fixed and embedded in acrylamide prior to sectioning at 10 mm (see Cunliffe and Smith,
1994). Sections were immunostained with a-SM actin (A-C) and 12/101 (D-F), and a FITC-conjugated goat anti-mouse secondary antibody.
(A,D) Uninjected animal caps. (B,E) Animal caps from embryos injected with 0.5 ng Xbra RNA. (C,F) Animal caps from embryos injected
with 4 ng Xbra RNA. Results are summarised in Table 2. Scale bar in F is 50 mm, and also applies to A to E.
Fig. 5. Co-expression of zebrafish goosecoid and ntl RNAs does not
induce cardiac (muscle-specific) actin expression in Xenopus animal
caps. Embryos at the 1-cell stage were injected with RNA encoding
zebrafish goosecoid (1 ng) and/or ntl (0.4 ng) and/or Xenopus noggin
(100 pg) as indicated. Animal caps were dissected at the mid-blastula
stage and cultured to stage 28, when they were analyzed for
expression of actin genes by RNAase protection. 0.4 ng ntl did not
induce expression of muscle-specific actin genes, but did cause
formation of ventral mesoderm as judged by morphological and
histological criteria (not shown). Co-expression of noggin and ntl,
but not goosecoid and ntl, induces expression of muscle-specific
actin RNA.
Fig. 6. Xbra and noggin act synergistically to induce expression of
Pintallavis. Embryos at the 1-cell stage were injected with RNA
encoding Xbra (1.0 ng) and/or noggin (200 pg) as indicated. Animal
caps were dissected at the mid-blastula stage and cultured to stage
12, when they were analyzed for expression of Pintallavis by
RNAase protection. noggin did not induce expression of Pintallavis
and Xbra caused weak induction, but co-expression of the two genes
elicited significant expression. This experiment was performed three
times with similar results.
Fig. 7. Co-expression of Pintallavis and Xbra RNAs induces
expression of muscle-specific actin RNA in Xenopus animal caps.
Embryos were injected at the 1- to 2-cell stage with the indicated
combinations of Pintallavis and Xbra RNAs. Animal caps were
excised at the mid-blastula stage and cultured to stage 31 when they
were analyzed by RNAase protection. Maximal expression of
muscle-specific actin RNA is seen in explants co-injected with 1.3 ng
Xbra RNA and 0.8 ng Pintallavis RNA. This experiment was
performed four times with similar results.
Fig. 8. Histological analysis of animal caps derived from embryos
co-injected with ntl RNA and increasing quantities of Pintallavis
RNA. (A) Ventral mesoderm resulting from injection of 0.4 ng ntl
RNA and 0.2 ng Pintallavis RNA. (B) Muscle masses resulting from
injection of 0.4 ng ntl RNA and 0.4 ng Pintallavis RNA.
(C) Notochord, muscle and neural tissue resulting from injection of
0.4 ng ntl RNA and 0.8 ng Pintallavis RNA. Notochord is marked
with arrows. Scale bar in C is 100 mm and also applies to A and B.
Fig. 9. Distribution of Pintallavis RNA in Xenopus embryos
visualised by whole-mount in situ hybridisation. (A) Vegetal view of
early gastrula stage showing expression of Pintallavis in prospective
dorsal mesoderm. (B) Dorsal view of early neurula showing
Pintallavis expression in midline structures including the notochord.
(C) Horizontal section through the marginal zone of an early gastrula
as in A, showing graded distribution of Pintallavis RNA in dorsal
mesoderm. (D) Computer densitometric analysis of the section
shown in C. The image was converted to greyscale and after
background subtraction different degrees of grey were assigned false
colours, with 1-7 units of grey as yellow, 8-15 units as green, and 16-
30 units as red. Scale bar in A is 0.5 mm and also applies to B-D.
