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Fig. 1. Histological sections of Xenopus oocytes and embryos embedded by the ester-wax procedure. Xenopus oocytes
and embryos were fixed and embedded as described in Materials and methods and 7-5 pm sections were stained with
toluidine blue. (A) Stage-I and -IV oocytes. Stage-I oocytes are previtellogenic, the nucleus is clearly visible, has a
regular shape and nucleoli can be seen at its periphery (thin arrow). Stage-IV oocytes have accumulated yolk platelets
(y), the outline of the nucleus is irregular and the number of peripheral nucleoli decreases (thick arrow); a rim of
toluidinic cytoplasm separates the nucleus from the surrounding yolk platelets (asterisk), xlOO. e, oocyte envelopes
(ovarian and follicular epithelia). (B) Late morula stage-5 embryo (Nieuwkoop & Faber, 1967). Large blastomeres
containing larger yolk platelets are located at the vegetal hemisphere (thick arrow) and smaller blastomeres at the
animal hemisphere (thin arrow); b, blastocelic cavity, x50. (C) is a detail of B; a blastomere is dividing (asterisk),
xlOO. (D) Stage-10 early gastrula embryo. Gastrulation is indicated by the appearance of a slightly bent furrow (arrow);
the fold on the left of this furrow is the dorsal lip of the blastopore (star); at this level, the future chordomesoderm
invaginates (cm), ec, ectoderm; en, endoderm, x70. (E) Detail of D, X140. (F and G) Stage-22 neurula embryo:
parasagittal sections. (F) General view, x50; (G) detail of the dorsal region, xllO. c, notochord; de, dorsal endoderm;
ep, epidermis; g, gut; n, neural tube; s, mesodermal cords beginning to divide into metamerized somites; y, yolk
endoderm.
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Fig. 2. Localization of c-myc RNA during oogenesis. In situ hybridization of myc 35S-DNA probes (A,B) and myc
antisense 35S-RNA probes (C-F) to Xenopus oocytes sections. A high level of labelling was detected throughout the
cytoplasm of young oocytes both with DNA (A,B) or RNA probes (C,D). In later stage-Ill and -IV oocytes (E,F), the
density of silver grains is lower and still uniformly distributed in the cytoplasm. The white ring around the oocyte
(arrow) is due to pigment granules in the cortex of wild-type oocyte. (G) Hybridization with a pUC18 DNA probe and
(H) with a sense myc RNA probe: no signal above background can be observed. Labels as Fig. 1. (A,C,E-H) Darkfield
illumination; (B,D) brightfield illumination. (E) X120; (A,F,G) X130; (B,C,D,H) X180.
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Fig. 3. Quantification of in situ hybridization signals
during oogenesis. Quantification of silver grain density
was done as described in Materials and methods.
(A) Values were corrected for the grain density
background as a function of oocyte diameter. Values are
the average of several measurements in different sections.
The average background values were 9xlO~3 grains per
im\2 for RNA probes and 7xlO~3 grains per fim2 for
DNA probes. (B) The number of grains per oocyte was
calculated from the oocyte diameter and the thickness of
the section (7-5 /an) with correction for the background
level. It was compared with the number of myc RNA
transcripts as determined by both slot blot and Northern
blot hybridizations (Taylor et al. 1986). Histograms are
displayed as a function of oocyte growth.
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Fig. 4. Localized expression of c-myc in neurula embryos. Stage-22 (neurula) Xenopus embryo sections were hybridized
with a 35S-labelled antisense c-myc RNA probe. (A,C,D,F) Dark-field illumination; (B,E,G) bright-field illumination.
(A,B) Sagittal sections. The neural tube (n), notochord (c) and dorsal endoderm (en), exhibit a signal above the
background of the whole embryo, g, gut; ep, epidermis. (C-G) Frontal sections. In (C) the neurula is oriented so that
the anterior region is on the right side. The section becomes partially sagittal on the right side due to the twisting of the
embryo by the cytological protocol. The cut plane crosses both the foregut or pharyngeal cavity (ph) and hindgut near
the blastopore (bl) which remains as a posterior opening of the gut (future anus). (D) and (E) are an enlarged detail of
C (rectangle on the right side). This detail shows the region located anterodorsally toward the pharyngeal cavity and
including the pharyngeal endoderm (en), neural tube (n) and head epidermis (ep). The hybridization signal is generally
high in these tissues, with some areas more intensely labelled (thick arrows). Thin arrow, neural lumen. (F) and (G) are
another detail of C (rectangle on the left side). Signals are detected over yolk-laden endoderm (y). The grain density is
higher both over the posterior epidermis (ep), the mesoderm, and immediately underlying endoderm (star), all of which
are composed of moderately yolk-laden blastomeres. (C) x80; (D,E) X170; (A,B) X190; (F,G) x200.
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Fig. 5. Localized expression of c-myc in the tailbud embryo. Embryo frontal sections were hybridized with a 35Slabelled
antisense c-myc RNA probe. (A,B,E) Dark-field illumination; (C,D,F) bright-field illumination. A is a general
view which shows that the probe hybridized intensely to epidermis (ep), optic cups (op) and lateral pharyngeal walls
(arrows). Abbreviations: cep, caudal epidermis; en, yolk-laden endoderm; ph, pharyngeal cavity. B and C are a detail of
A in the cephalic region. (D) Caudal region. (E) Frontal section of the anterior part of the embryo showing an intense
signal in the right optic cup (op), the left lens placode (le) and the cephalic epidermis (thick arrow). Periphery of the
right optic cup is preferentially labelled (thin arrow) and might include the wall of the cup; the less preferentially
labelled inner region might include part of the cup cavity. The left optic cup (asterisk) is more weakly labelled because
the cut plane barely crosses the cup. g, gut. (A,D) x50; (B,E,F) x90; (C) x!40.
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