Taira M et al. (1992), The LIM domain-containing homeo box gene Xlim-1...

XB-ART-23973

Genes Dev 1992 Mar 01;63:356-66. doi: 10.1101/gad.6.3.356.

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The LIM domain-containing homeo box gene Xlim-1 is expressed specifically in the organizer region of Xenopus gastrula embryos.

Taira M , Jamrich M , Good PJ , Dawid IB .

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A novel cysteine-rich motif, named LIM, has been identified in the homeo box genes lin-11, Isl-1, and mec-3; the mec-3 and lin-11 genes determine cell lineages in Caenorhabditis elegans. We isolated LIM class homeo box genes from Xenopus laevis that are closely related to lin-11 and mec-3 in the LIM and homeo domains. This paper deals with one of these genes, Xlim-1. Xlim-1 mRNA is found at low abundance in the unfertilized egg, has a major expression phase at the gastrula stage, decreases, and rises again during the tadpole stage. In adult tissues the brain shows the highest abundance, by far, of Xlim-1 mRNA. The maternal and late expression phases of the Xlim-1 gene suggest that it has multiple functions at different stages of the Xenopus life cycle. In the gastrula embryo, Xlim-1 mRNA is localized in the dorsal lip and the dorsal mesoderm, that is, in the region of Spemann's organizer. Explant experiments showed that Xlim-1 mRNA is induced by the mesoderm-inducer activin A and by retinoic acid, which is not a mesoderm inducer but affects patterning during Xenopus embryogenesis; application of activin A and retinoic acid together results in synergistic induction. The structure, inducibility, and localized expression in the organizer of the Xlim-1 gene suggest that it has a role in establishing body pattern during gastrulation.

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Species referenced: Xenopus laevis
Genes referenced: fgf2 inhba lhx1 lim2 tbx2 tff3.7

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	Figure 1. [A] Nucleotide sequences of PCR products obtained as described in Materials and methods. The predicted amino acid sequence of Xlim-l and Xlim-2B, which is identical, is shown at the top-, that of Xlini-3 is at the bottom. Underlining indicates amino acids that are different from Xlim-l. Xlim-ZA has a single-amino-acid difference, isoleucine (ATT codon), which is also underHned. Dots indicate identical nucleotides. The GenBank/EMBL accession numbers for sequences of PCR clones 30, 152, and 171 are Zl 1587, Z11588, and Z11589, respectively. [B] Nucleotide and predicted amino acid sequence of Xlim-l. Amino acids are in the single-letter code. Asterisks denote in-frame stop codons. Below the sequence the general structure of the cDNA clone, pXH32, is illustrated. The GenBank/EMBL accession number is X63889. (C) Comparison of LIMl, LIM2, and homeo box domains of Xlim-l, lin-11 (Freyd et al. 1990), mec-3 (Way and Chalfie 1988), lsl-1 (Karlsson et al. 1990), and rhombotin (McGuire et al. 1989; Boehm et al. 1990). Identities are indicated by dots; spaces inserted for alignment, by dashes. The consensus LIM motif is shown by vertical bars. The positions of helix 1-3 and the turn are indicated in the homeo domain (Scott et al. 1989). PCR primers A and B are shown by arrows.
	Figure 2. [A] Developmental expression of Xlim-1. Total RNA samples (7.5 \|xg) from stages 0 (unfertilized egg), 8 (early blastula), 9 (late blastula), 10 (initial gastrula), 11/12 (late gastrula), 14/15 (neural plate stage), 18/19 (neural tube stage), 23/24 (tail bud stage), 33/34 (early tadpole), and 37/38 (tadpole) were separated on a gel, blotted, and hybridized with an Xlim-l probe (see Materials and methods). The positions of 18S and 28S rRNAs are indicated at right. [B] Tissue distribution of Xlim-1 mRNA in adult Xenopus. Ten micrograms of total RNA was loaded onto each lane. Staining of the gel with ethidium bromide verified that closely similar amounts of RNA were loaded onto each lane.
	Figure 3. Spatial distribution of Xlim-1 mRNA in gastrula embryos. Stage 11 Xenopus embryos were dissected into ectoderm (Ec) and endoderm plus mesoderm (En -I- M), or into ventral (Ven) and dorsal (Dor) halves. Ten micrograms of total RNA was applied on each lane. Mix.l and EF-la were analyzed for comparison (see text).
	Figure 4. Spatial distribution of Xlim-1 mRNA in the gastrula as visualized by whole-mount in situ hybridization (see Materials and methods). A and B show the same stage 11 embryo. A is photographed from a lateral viewpoint, with the focal plane at the center of the embryo; animal at the top and dorsal on the right. The blastocoel has largely collapsed during preparation. B shows a vegetal view tilted slightly dor sally; dorsal is at the top. In this early midgastrula embryo the mesoderm has involuted only a short distance from the dorsal lip. Xlim-1 is expressed at the dorsal lip and in a fan-like widening at the anterior margin of the mesoderm. C and D show a slightly older embryo at stage 11.5, with animal at the top. The mesoderm has migrated farther toward the animal pole, as seen in the lateral view in C; dorsal is at the right. The dorsal view in D shows that the highest Xhm-1 expression is now located in the anterior region of the dorsal mesoderm, which will shortly form the prechordal plate.
	Figure 5. Induction of Xlim-l expression in animal explants. [A] Stage 8-8.5 animal explants were cultured in the presence of different factors for 4 hr. (B) Stage 8-8.5 explants were cultured for 5 hr until siblings reached stage 10.5. (C) Stage 9-9.5 animal explants were cultured for 30 min in CHX, 30 min in CHX plus activin A, and 2 hr in activin A; siblings reached stage 10-10.5. Five micrograms of total RNA from each sample was analyzed for expression of different genes, as indicated. In A, hybridization with EF-la, and in B and C, staining with ethidium bromide (not shown) verified that closely similar levels of RNA had been loaded. The following factor concentrations were used: activin A, 50 pM (1.4 ng/ml); RA, 10 JJLM; TGF-p2, 200 ng/ml; TGF-p3, 50 ng/ml; bFGF, 100 ng/ml; cycloheximide (CHX), 5 \|xg/ml.
	Figure 6. [A] Kinetics of induction of Xlim-l and Mix.l in animal explants by 50 pM activin A. {B] Kinetics of induction of Xlim-1 by 10 ixM RA and activin (50 pM) plus RA; two data points with activin alone show that the peak expression of Xlim-1 in this experiment occurred at 4 hr, as shown in A. A and B are different experiments. The expression of the marker gene EF-la increases continuously with incubation time.
	Figure 7. Expression of Xlim-1 in RA-treated embryos. Embryos at stage 8.5-9 were exposed to 10 \|JLM RA for 30 min, as described (Durston et al. 1989). Total RNA was extracted at various stages and analyzed for Xlim-1 RNA. At stage 11 some of the embryos were dissected into dorsal and ventral halves and 5 \|xg of total RNA was analyzed. Blotting with EF-la probe showed that equal amounts of dorsal and ventral RNA were loaded onto the gel.