|
Display additional annotations [+]
| Gene |
Clone |
Species |
Stages |
Anatomy |
|
mtss1.2
|
|
laevis
|
unfertilized egg stage
|
animal hemisphere
|
|
mtss1.2
|
|
laevis
|
NF stage 4 (8-cell)
|
animal blastomere
,
animal
|
|
mtss1.2
|
|
laevis
|
NF stage 8
|
animal hemisphere
|
|
mtss1.2
|
|
laevis
|
NF stage 10
to
NF stage 12
|
ectoderm
,
neuroectoderm
,
dorsal
|
|
mtss1.2
|
|
laevis
|
NF stage 17
|
neural plate
,
anterior neural fold
|
|
mtss1.2
|
|
laevis
|
NF stage 19
|
pre-chordal neural plate
,
chordal neural plate
,
neural plate
,
cranial neural crest
|
|
mtss1.2
|
|
laevis
|
NF stage 23
|
presomitic mesoderm
,
somite
,
paraxial mesoderm
,
anterior neural fold
,
neural tube
|
|
| |
Fig. 4. Temporal and spatial expression pattern of MIM and regulation of anterior neural fold closure by MIM. (A) Xenopus MIM (XMIM) is expressed throughout development as monitored by RT-PCR analysis. ODC is used as a loading control; −RT, without reverse transcriptase. (B) The spatial expression pattern of XMIM is dynamic, with highest expression observed in the neural folds of the neurula stage embryo. Stages and views of the embryos are indicated. No signal is detected using a XMIM sense probe. Arrow indicates the plane of the transverse section (TS). (C) Injection of MIM or IMD RNA produces no morphological defects in the Xenopus embryo, whereas injection of MIM MO (50 ng) dorsally inhibits anterior neural fold closure. The MIM MO phenotype can be effectively rescued by co-injection of 400 pg δN MIM RNA. (D) Location of the MIM MO target sequences; these are absent from the MIM rescue construct (δN MIM), which only includes sequence downstream of the MO1 target. (E) Injection of MIM MO1 or MO2 inhibits translation of Myc-MIM but not of endogenous β-catenin. (F) Injection of MIM MO1 inhibits translation of endogenous MIM but not of endogenous actin in the Xenopus embryo. (G) Quantification of the results of C. The number of injected embryos analyzed is shown above each bar. |
