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FIG. 2. Xlefty expression during Xenopus development. (A) Whole-mount in situ localization of Xlefty transcripts at gastrula through
tailbud stages. (A) Vegetal pole view, dorsal at top. (B, C, E, J, L, and N) Dorsal view, anterior at left. (D, F, G, K, M, O, P) Left lateral view,
anterior at left. (C, D), (E, F), (I, J), and (M, N) show a dorsal and a left lateral view of the same embryo. Stage of embryo(s) depicted is shown
at the bottom right. (A) During early gastrulation, Xlefty expression predominantly localized to the dorsal blastopore margin. Note the
punctate expression in other regions around the blastopore (arrowheads). (B) As gastrulation proceeded, Xlefty expression became localized
to the prospective floor plate and prechordal plate, but was still present around the closing blastopore (arrowheads). (C, D) During early
neurulation, expression continued to be localized to the prospective floor plate and prechordal plate (arrows), in addition to expression
around the ventrolateral yolk plug (arrowhead). (E, F) As neurulation proceeded, the dorsal midline expression of Xlefty was downregulated
centrally (arrows), resulting in an anterior and posterior domain of expression (arrowheads). (G) Following neurulation, Xlefty expression
appeared in the posterior midline in the floor plate (arrowhead), notochord (asterisk), and hypochord (arrow). (H) The expression in the
floor plate and hypochord remained through tailbud stages (H), while the notochord expression was transient and variable in intensity
(G). The floor plate and hypochord expression progressed in a posterior-to-anterior direction (G) and receded in the opposite direction
(P; data not shown). At st. 23, unilateral Xlefty expression became apparent in the left lateral plate mesoderm (arrowhead in H), then
migrated anteriorly (I), and eventually became localized to the left cardiac field (arrowhead in O). Between st. 24 and st. 25, another
unilateral domain of Xlefty expression emerged in the left anterior dorsal endoderm (arrowheads in K, L) and remained into early tailbud
stages (K). Variable levels of bilateral posterior endoderm expression (arrow in K) were also present from approximately st. 245 through
tailbud stages (K; data not shown).
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FIG. 1. The amino acid sequence predicted from Xlefty is conserved in vertebrate evolution. The amino acid sequences of Xenopus (X)
Lefty-a and Lefty-b are compared to zebrafish (z) Lefty1 and 2, chick (c) Lefty, mouse (m) Lefty1 and 2, and human (h) LEFTY A and B. Light
gray shading represents conservative amino acid substitutions, and medium gray indicates amino acid identity. Putative cleavage sites,
with RXXR consensus sequence, and conserved cysteines, predicted to form the characteristic cysteine knot of the TGFb superfamily, are
shown in black. The position of the missing cysteine in the Lefty subfamily is indicated with an arrow.
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FIG. 2. Xlefty expression during Xenopus development. (A–P) Whole-mount in situ localization of Xlefty transcripts at gastrula through
tailbud stages. (A) Vegetal pole view, dorsal at top. (B, C, E, J, L, and N) Dorsal view, anterior at left. (D, F, G–I, K, M, O, P) Left lateral view,
anterior at left. (C, D), (E, F), (I, J), and (M, N) show a dorsal and a left lateral view of the same embryo. Stage of embryo(s) depicted is shown
at the bottom right. (A) During early gastrulation, Xlefty expression predominantly localized to the dorsal blastopore margin. Note the
punctate expression in other regions around the blastopore (arrowheads). (B) As gastrulation proceeded, Xlefty expression became localized
to the prospective floor plate and prechordal plate, but was still present around the closing blastopore (arrowheads). (C, D) During early
neurulation, expression continued to be localized to the prospective floor plate and prechordal plate (arrows), in addition to expression
around the ventrolateral yolk plug (arrowhead). (E, F) As neurulation proceeded, the dorsal midline expression of Xlefty was downregulated
centrally (arrows), resulting in an anterior and posterior domain of expression (arrowheads). (G) Following neurulation, Xlefty expression
appeared in the posterior midline in the floor plate (arrowhead), notochord (asterisk), and hypochord (arrow). (H–P) The expression in the
floor plate and hypochord remained through tailbud stages (H–P), while the notochord expression was transient and variable in intensity
(G–I). The floor plate and hypochord expression progressed in a posterior-to-anterior direction (G–I) and receded in the opposite direction
(P; data not shown). At st. 23, unilateral Xlefty expression became apparent in the left lateral plate mesoderm (arrowhead in H), then
migrated anteriorly (I–N), and eventually became localized to the left cardiac field (arrowhead in O). Between st. 24 and st. 25, another
unilateral domain of Xlefty expression emerged in the left anterior dorsal endoderm (arrowheads in K, L) and remained into early tailbud
stages (K–O). Variable levels of bilateral posterior endoderm expression (arrow in K) were also present from approximately st. 24–25 through
tailbud stages (K–P; data not shown).
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FIG. 3. Normal and leftâright reversed cardiac orientation in st. 46 Xenopus embryos. (A, B) Ventral views of immunofluorescent hearts,
with anterior at the top, stained with a monoclonal antibody against bovine cardiac troponin T. (A) Normal leftâright orientation of the
Xenopus heart, with the outflow tract (conotruncus; ct) arising from the right anterior aspect of the ventricle (v) and looping to the left. (B)
A leftâright reversed Xenopus heart, with the outflow tract arising from the left anterior aspect of the ventricle and looping to the right.
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FIG. 4. Normal and leftâright reversed gut classes and subclasses in st. 46 Xenopus embryos. (AâL) Ventral views of Xenopus guts, with
anterior at the top, as viewed by light microscopy. (A, B, and I), (C, D, and J), (E, F, and K), and (G, H, and L) depict different views of the
same gut. The pancreas is marked by an asterisk in A, C, E, and G. (A, C) Normal, right gut coil origins (RO class). (E, G) Reversed, left gut
coil origins (LO class). (B, F) Normal, counterclockwise gut coil direction (CCW class). (D, H) Reversed, clockwise gut coil direction. (I)
Normal leftâright orientation of the Xenopus gut (RO/CCW subclass). (J) Abnormal Xenopus gut with a normal, right coil origin and a
reversed, clockwise coil direction (RO/CW subclass). (K) Abnormal Xenopus gut with a reversed, left coil origin and a normal,
counterclockwise coil direction (LO/CCW subclass). (L) âMirror-image,â leftâright reversed Xenopus gut (LO/CW subclass).
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FIG. 5. Loss of XPitx2 lateral plate mesoderm expression in Xlefty-injected embryos. (AâD) Whole-mount in situ localization of XPitx2
transcripts at st. 26 in embryos unilaterally injected on the left or right with 25 pg of Xlefty DNA. (A, C, D) Left lateral view, anterior to
left. (B) Dorsal view, anterior to left. (A, B) Normal XPitx2 expression in the left lateral plate mesoderm (arrows), as well as in the head and
dorsal midline (arrowheads). (C, D) Loss of XPitx2 expression in the left lateral plate mesoderm of embryos injected on the left (C) or right
(D) with Xlefty DNA. Note the presence of the other endogenous domains of XPitx2 expression in these embryos (arrowheads).
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FIG. 6. Summary of results from Xlefty DNA injections (25 pg) and Xlefty/BVg1 and Xlefty/XBMP4 DNA co-injections. The percentage
of leftâright reversals observed for each experimental group is given in parentheses. The arrows indicate an increase or decrease in reversal
percentage from the percentage given in the preceding line.
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