Feledy JA et al. (1999), Inhibitory patterning of the anterior neural pl...

XB-ART-12576

Dev Biol 1999 Aug 15;2122:455-64. doi: 10.1006/dbio.1999.9374.

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Inhibitory patterning of the anterior neural plate in Xenopus by homeodomain factors Dlx3 and Msx1.

Feledy JA , Beanan MJ , Sandoval JJ , Goodrich JS , Lim JH , Matsuo-Takasaki M , Sato SM , Sargent TD .

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Patterning of the embryonic ectoderm is dependent upon the action of negative (antineural) and positive (neurogenic) transcriptional regulators. Msx1 and Dlx3 are two antineural genes for which the anterior epidermal-neural boundaries of expression differ, probably due to differential sensitivity to BMP signaling in the ectoderm. In the extreme anterior neural plate, Dlx3 is strongly expressed while Msx1 is silent. While both of these factors prevent the activation of genes specific to the nascent central nervous system, Msx1 inhibits anterior markers, including Otx2 and cement gland-specific genes. Dlx3 has little, if any, effect on these anterior neural plate genes, instead providing a permissive environment for their expression while repressing more panneural markers, including prepattern genes belonging to the Zic family and BF-1. These properties define a molecular mechanism for translating the organizer-dependent morphogenic gradient of BMP activity into spatially restricted gene expression in the prospective anterior neural plate.

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Species referenced: Xenopus laevis
Genes referenced: ag1 dlx1 dlx3 foxg1 krt12.4 mrc1 msx1 nrp1 otx2 tbxt zic3

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	FIG. 1. Expression of Dlx3 and Msx1 at late gastrula. Whole, fixed albino embryos were hybridized in situ with probes for Dlx3 (A, C, E, G, I) or Msx1 (B, D, F, H, J). At stage 12 (A–F) the posterior boundary of Dlx3 expression was significantly closer to the blastopore than for Msx1. (A, B) Dorsal view (anterior toward top), (C, D) anterior view (dorsal toward top), (E, F) lateral view (dorsal to right). Double hybridizations in situ were performed with Xag1 (brackets, G, H) and BF-1 (arrowheads, I, J). In the extreme anterior neural plate region, both Xag1 and BF-1 transcripts were contained within the Dlx3 expression domain (G, I). In contrast, Xag1 and BF-1 expression was posterior to that of Msx1 (H, J). The dashed line in I corresponds to the plane of section shown in Fig. 2.
	FIG. 2. Dlx3 and BF-1 are expressed in different strata of the anterior neurectoderm. An embryo which had undergone double in situ hybridization with Dlx3 (purple) and BF-1 (turquoise) was cryosectioned sagittally, as indicated by the dotted line in Fig. 1I. Arrows delineate the deep boundary of the anterior neural fold (asterisk). Dlx3 is expressed in the superficial cells, while BF-1 is expressed in the deep ectoderm. B is a magnification of the box shown in A.
	FIG. 3. Differential sensitivity of Dlx3 and Msx1 expression to inhibition of BMP signaling. Animal caps were isolated from embryos injected with 500, 1000, 2000, or 4000 pg of RNA encoding tBR, cultured until siblings reached stage 11, and analyzed for Dlx3 and Msx1 expression by Northern blotting. Dlx3 expression persists at significantly higher levels of tBR than does that of Msx1. (A) Graph summarizing densitometric analysis of multiple exposures of X-ray film, normalized to linear film response range. (B) Sample exposure.
	FIG. 4. Differential sensitivity of Dlx3 and Msx1 expression to inhibition of protein synthesis. Animal caps were isolated at stage 7 and cultured until stage 11 (midgastrula) in 0.33 MMR (Control) or 0.33 MMR 1 5 mg/ml cycloheximide (CHX) and then analyzed by RNA blotting for Dlx3 and Msx1 expression. Dlx3 RNA accumulation was substantially blocked by this procedure, while Msx1 expression was superinduced. w11, whole stage 11.
	FIG. 5. Gene expression in animal caps injected with RNAs encoding tBR, Msx1, and Dlx3. Animal caps were removed from embryos injected with 2 ng tBR, 2 ng tBR1120 pg Dlx3, 2 ng tBR1120 pg Msx1 RNA, or 2 ng tBR1120 pg Dlx31120 pg Msx1 or from uninjected embryos, cultured until sibling embryos reached late neurula (stage 18; W18), and processed for RNA extraction. Northern blot analysis revealed that Dlx3 was permissive for expression of the anterior neural marker Otx2 and the cement gland markers CG7 and Xag1, while Msx1 inhibited expression of these markers. Dlx3 suppressed expression of the panneural marker gene Nrp1, the “prepattern” gene Zic3, and the anterior neural fold gene BF1. Msx1 also inhibited Zic3 and BF1, but appeared to have less effect on Nrp1. The epidermal keratin gene XK81 was robustly expressed in uninjected caps and suppressed by tBR injection. Neither Dlx3 nor Msx1, nor a combination of both factors (last lane), increased XK81 expression significantly. Absence of signal with Xbra verified that the animal caps were not contaminated with mesoderm, and the accumulation of the ribosomal protein RNA L1 was used as a control for explant viability. At the bottom is a photograph of the ethidium bromide staining of the 18S region from a typical gel.
	FIG. 6. Dlx3 functions upstream of Zic3. Animal caps were isolated from embryos injected with 2 ng tBR, 2 ng tBR1120 pg Dlx3, or 2 ng tBR1120 pg Dlx31100 pg Zic3 RNA and from uninjected embryos, cultured until sibling embryos reached late neurula (W18; stage 18), and analyzed by Northern blot (A). Expression of the panneural marker Nrp1 was induced by tBR, inhibited by Dlx3, and restored by Zic3, indicating that Zic3 functions downstream of the negative regulatory step imposed by Dlx3. Ethidium bromide staining of the 18S rRNA region is shown as a gel loading control. Absence of hybridization to the Xbra probe indicated that the animal caps were not contaminated with mesoderm. (B) Histogram representing densitometry of Nrp1 hybridization signals.
	FIG. 7. Disruption of anterior neural gene expression in vivo by Dlx3. Embryos were injected in a single dorsal animal blastomere at the 8- to 16-cell stage with a mixture of RNA encoding Dlx3 (40–60 pg) and b-galactosidase (300 pg). At stage 17 embryos were fixed and stained briefly with salmon-gal to identify correctly targeted embryos, which were then hybridized in situ with probe for BF-1 (A), Zic3 (B), or Xag1 (C). The salmon-gal staining is pinkish-red, and the hybridization staining is purple. The co-injected side is to the left, and the uninjected right side serves as a control. Dlx3 injection repressed expression of BF-1 and Zic3, but had no discernable effect on Xag1.
	FIG. 8. Model of ectodermal patterning by BMP-regulated expression of Dlx3 and Msx1. A sagittal section of a midgastrula embryo is depicted to illustrate the spatial relationships occurring along the dorsal–ventral neuraxis during gastrulation. Under the influence of the BMP signaling (purple), Msx1 (magenta) is expressed ventrally from a point near the blastopore lip to an anterior limit relatively distant from the leading edge of organizer tissue (yellow). Dlx3 (green) is also ventrally expressed but the domain extends from a point farther from the blastopore lip than Msx1 and extends more posteriorly, into a region with relatively greater attenuation of the BMP signal. In the extreme anterior neural plate, the ectoderm is divided into three domains: Msx11/Dlx31, which forms epidermis, Msx12/Dlx1, giving rise predominantly to the cement gland (tan), and Msx12/Dlx32, which is initially specified as anterior prospective central nervous system tissue (light blue). Thus, differential activation of Dlx3 and Msx1 by intermediate levels of BMP activity results in patterning of the anteriormost dorsal ectoderm. Dorsal is to the right and anterior is up in this diagram.