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We have isolated and characterized a novel Xenopus wnt gene, Xwnt-11, whose expression pattern and overexpression phenotype suggest that it may be important for dorsal-ventral axis formation. Xwnt-11 mRNA is present during oogenesis and embryonic development through swimming tadpole stages. Xwnt-11 mRNA is ubiquitous in early oocytes and is localized during mid-oogenesis. By late oocyte stages, Xwnt-11 mRNA is localized to the vegetal cortex, with some mRNA in the vegetal cytoplasm. After egg maturation, Xwnt-11 mRNA is released from the vegetal cortex and is found in the vegetal cytoplasm. This early pattern of Xwnt-11 mRNA localization is similar to another vegetally localized maternal mRNA, Vg1 (D. A. Melton (1987) Nature 328, 80-82). In the late blastula, Xwnt-11 mRNA is found at high levels in the dorsal marginal zone. As gastrulation proceeds, Xwnt-11 mRNA appears in the lateral and ventral marginal zone and, during tadpole stages, it is found in the somites and first branchial arch. Injection of Xwnt-11 mRNA into UV-ventralized embryos can substantially rescue the UV defect by inducing the formation of dorsal tissues. The rescued embryos develop somitic muscle and neural tube; however, they lack notochord and anteriorhead structures.
Fig. 1. Sequence of Xwnt-11 and
comparison with other Xwnt genes. (A) The
nucleotide sequence of Xwnt-11 is shown,
with the amino acid sequence underneath.
Numbers in bold refer to the amino acid
sequence. (B) Amino acid sequence
comparisons are shown for Xwnt-1, Xwnt-4,
Xwnt-8 and Xwnt-11, for which complete
coding region sequence is known. Cysteines
that are conserved between all other known
mouse wnt genes are printed in bold.
Potential N-linked glycosylation sites are
underlined in the Xwnt-11 sequence. The
regions to which degenerate PCR primers
were made are indicated by double
underlining. The asterisks mark the end of
the coding region. (C) Amino acid sequence
similarities are compared between Xwnt-1,
Xwnt-4, Xwnt-8 and Xwnt-11. The numbers
above the diagonal are absolute amino acid
similiarities, and the numbers below the
diagonal include conserved amino acid
substitutions (serine-threonine, isoleucineleucine-
methionine-valine, glutamic acidaspartic
acid, glutamine-asparagine and
lysine-arginine).
Fig. 2. Maternal expression and vegetal localization of Xwnt-11
RNA. Northern blot probed with Xwnt-11 and with fibronectin as
a control for RNA loading. The numbers refer to developmental
stages (Nieuwkoop and Faber, 1967), V is the vegetal hemisphere,
A is the animal hemisphere and T is total embryo. The vegetal and
animal dissections were done at the 8-cell stage.
Fig. 3. In situ hybridization to sectioned tissue from oocytes and embryos. Middle and late stage oocytes were oriented during embedding
such that sections cut through the animal-vegetal axis. Early stage oocytes were randomly oriented during embedding. (A) Early stage I-II
oocytes (small arrows) have Xwnt-11 mRNA distributed uniformly in the cytoplasm. Middle stage III-IV oocytes (large arrows) are
beginning to localize Xwnt-11 mRNA at one pole of the oocyte. The germinal vesicle is visible as a dark circle in the middle of each
oocyte. The sections shown in B, C and D are all oriented with the animal pole facing up and the vegetal pole facing down. (B) Late stage
V-VI oocyte shows that Xwnt-11 mRNA is localized to the vegetal cortex and to patches in the vegetal cytoplasm. The germinal vesicle is
in the animal hemisphere. (C) Unfertilized egg shows that Xwnt-11 mRNA is diffusely localized to the vegetal hemisphere. (D) 8-cellstage
embryo shows that Xwnt-11 mRNA remains diffusely localized to the vegetal hemisphere. The horizontal cleavage plane of the
third cell division (arrowheads) confines the mRNA to vegetal blastomeres.
Fig. 4. Whole-mount in situ hybridization with a Xwnt-11 probe on embryos of different stages. (A) Late blastula (stage 9), vegetal view,
dorsal is up. Staining is present in a broad arc in the marginal zone of the embryo on the dorsal side. This arc is much broader than the
organizer. (B) Early gastrula (stage 10.5), vegetal view, dorsal is up. The marginal zone staining has extended laterally and ventrally.
Highest levels of expression are on the dorsal side in an area roughly corresponding to the organizer (60°around the dorsal mid-line). The
lateral and ventral marginal zone staining does not extend down to the blastopore lip. (C) Late gastrula (stage 12.5), vegetal view, dorsal
is up. A ring of staining around the closing blastopore is present. The few dorsal-most staining cells extending out along the dorsal
midline probably include presumptive posterior neural plate and archenteron roof cells. (D) Late neurula (neural folds have closed), view
from posterior-ventral side, dorsal is up. The blastopore is almost completely closed and is visible only as a small slit. Xwnt-11 expressing
cells are present both dorsal and ventral to the blastopore. (E) Early tailbud (stage 22-23), anterior to the right, dorsal is up. The
predominant staining is around somite nuclei, which are aligned vertically in each somite, and in the first branchial arch. (F) Tadpole
(stage 28), anterior to the right, dorsal is up. Xwnt-11 staining is present around the somite nuclei, which are aligned vertically in each
somite, and in the first branchial arch. Scale bars all represent 500 μm.
Fig. 5. Sections of whole-mount embryos
hybridized with Xwnt-11 antisense probe. All
sections were oriented during embedding such
that the sections cut through the dorsal and
ventral midline. (A). This section is late stage 9
or early stage 10, and Xwnt-11 mRNA (between
arrowheads) is beginning to appear in a region
that will later be above the dorsal blastopore lip.
No involution has occurred yet at this stage, and
the mRNA is present in surface and deep layer
cells. The embryo is oriented with the animal
pole up and the vegetal pole (vg) down. The
blastocoel floor is marked (bf). Fissures are an
artifact of sectioning. (B) Mid gastrula (stage 12)
shows Xwnt-11 mRNA (between arrowheads) in
the dorsal blastopore lip (area below dotted line).
Cell boundaries are difficult to discern, but the
positively staining cells probably include both
surface epithelial cells and deeper cells but not
cells that have already involuted. The
archenteron is marked (a).
Fig. 6. Histological sections of UVventralized
eggs injected with Xwnt-11
mRNA. UV-ventralized embryos, UV
embryos injected with Xwnt-11 mRNA
and normal embryos were fixed at stage
26-28, sectioned and stained to determine
what structures had formed. (A) UVventralized
embryo, cross section. (B) UV
embryos injected with Xwnt-11 mRNA.
Mid-trunk cross section, dorsal is up.
(C) Higher magnification of a UV embryo
injected with Xwnt-11 mRNA. The neural
tube (nt) consists of a dark- and a palestained
region. There is no lumen in this
section, but other sections sometimes do
show a lumen. The pale-stained region is
the âmarginal zone (mz)â, where axon
tracts are located. There is one large
marginal zone in the ventral midline
(compare with Fig. 6E). There is also one
large mass of muscle (m) that extends
across the midline. (D) Normal embryo.
Mid-trunk cross-section, dorsal is up.
(E) Higher magnification view of a normal
embryo. Neural tube (nt) and notochord
(n) are visible. One of the two files of
somitic muscle on each side of the
notochord is marked (m). Note the two
lateral pale-stained âmarginal zonesâ (mz)
separated by ventral floor plate cells. The
scale bars in A, B and D) represent 100
μm and in D and E represent 50 μm.
Fig. 7. Whole-mount immunohistochemistry of Xwnt-11-injected embryos. UV-ventralized embryos (A,D), UV embryos injected with
Xwnt-11 mRNA (B,E) and normal embryos (C,F) were fixed at stage 26-28, and whole-mount immunohistochemistry was done with
tissue-specific antibodies. UV-ventralized embryos have neither notochord nor muscle. UV embryos injected with Xwnt-11 mRNA have
somitic muscle but no notochord. Normal control embryos have both muscle and notochord. (A-C) Incubated with the notochord-specific
monoclonal antibody (mAb) Tor 70 (Kushner, 1984; Bolce et al., 1992). (D-F) Incubated with the muscle-specific monoclonal (mAb)
antibody 12101 (Kintner and Brockes, 1984). (A) UV-ventralized embryo plus Tor 70 mAb. There are no Tor 70-positive cells. (B) UV
embryo injected with Xwnt-11 mRNA plus Tor 70 mAb. There are a few scattered Tor 70-positive cells but no organized notochord is
present. (C) Normal embryo plus Tor 70 mAb. An extensive notochord is present along the dorsal axis. (D) UV-ventralized embryo plus
12101 mAb. There are no 12101-positive cells. (E) UV embryo injected with Xwnt-11 mRNA plus 12101 mAb. Extensive somitic muscle
is present along the dorsal axis. (F) Normal embryo plus 12101 mAb. Somitic muscle is present. Scale bars all represent 100 μm.
