Distinct roles for Distal-less genes Dlx3 and Dlx5 in regulating ectodermal development in Xenopus.

In vertebrates, there are six or more copies of genes related to the Drosophila pattern formation homeodomain gene Distal-less. Among this family, Dlx3 and Dlx5 share extensive sequence homology and have similar, but distinctive, expression patterns, suggesting that these two factors may have substantially redundant developmental functions. Here we show that at the earliest phases of embryogenesis in Xenopus, there are significant differences between Dlx3 and Dlx5 expression and that this correlates with different functions in the restriction of neural crest and neural plate boundaries, respectively.

Differential regulation of Dlx gene expression by a BMP morphogenetic gradient.

Three members of the vertebrate Distal-less gene family, Dlx3, 5 and 6, are transcribed in early gastrula embryos of Xenopus laevis. This expression is confined to ectoderm and is excluded from the presumptive neural plate region. Expression of all three genes is dependent upon BMP signaling, with significant differences in how the three genes respond to the BMP antagonist chordin. This correlates with the different expression domain boundaries in vivo for Dlx3 compared to Dlx5 and 6, suggesting that BMP signal attenuation could be the primary factor in determining these different patterns in the gastrula ectoderm.

Regulation and function of Dlx3 in vertebrate development.

Dlx3 is a homeodomain transcription factor in vertebrates, related to Distal-less in Drosophila, that is expressed in differentiating epidermal cells, in neural crest, hair follicles, dental epithelium and mesenchyme, the otic and olfactory placodes, limb bud, placenta, and in the cement gland, which is located in the extreme anterior neural plate in Xenopus embryos. This factor behaves as a transcriptional activator, and positively regulates gene expression in the skin, and negatively regulates central nervous system markers in Xenopus epidermis and anterior neural plate. A mutation in the DLX3 gene is associated with a hereditary syndrome in humans, and loss of Dlx3 function is a developmental lethal in gene-targeted mice, where it is essential for proper modeling of the labyrinthine layer of the placenta. In this review, we discuss the evolution, expression, regulation, and function of Dlx3 in mouse, amphibians, and zebrafish. Published 2000 Wiley-Liss, Inc.

Cloning and expression of a novel zinc finger gene, Fez, transcribed in the forebrain of Xenopus and mouse embryos.

We have identified and cloned a novel zinc finger gene, Fez (forebrain embryonic zinc-finger), as a potential downstream determinant of anterior neural plate formation in Xenopus. Fez was isolated as one of several neural-specific genes that was induced by the neuralizing factor, noggin (Smith and Harland, 1992. Cell 70, 829-840), in uncommitted ectoderm. Fez has an open reading frame comprising 466 amino acids, and contains six C(2)H(2) type zinc finger domains, which are highly conserved among Drosophila, zebrafish, mouse, and human. In Xenopus, the expression of Fez begins at stage 12 in the rostral end of the neural plate, and by stage 45, it is localized to several telencephalic regions, including the olfactory bulbs, nervus terminalis, and ventricular zone. The mouse homologue of Fez is similarly expressed in the mouse forebrain by embryonic day 11.

Regulation of early expression of Dlx3, a Xenopus anti-neural factor, by beta-catenin signaling.

The ectoderm of the pre-gastrula Xenopus embryo has previously been shown to be at least partially patterned along the dorsal-ventral axis. The early expression of the anti-neural homeodomain gene Dlx3 is localized to the ventral ectoderm by a mechanism that occurs prior to gastrulation and is independent of the Spemann organizer. The repression of Dlx3 is mediated by signaling though beta-catenin, but is probably not dependent on the induction of the Xnr3 or chordin genes by beta-catenin. We propose a model in which this early regulation of Dlx3 accounts for the pro-neural bias of dorsal ectoderm.

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

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.

Transcriptional activation by the homeodomain protein distal-less 3.

PCR-based methods and mobility shift competition assays were used to determine the basic biochemical features of the homeodomain transcription factor Distal-less 3 (Dlx3), including an optimal DNA binding site, the binding constant and dissociation rates of this protein. Expression of Dlx3 protein in either HeLa cells or Xenopus embryos resulted in strong activation of a model target gene construct containing three tandem copies of the Dlx3 binding site upstream from the TATA element. In addition, deletion analysis revealed that transcriptional activation by Dlx3 depends on two subdomains located on either side of the homeobox: removal of either subdomain resulted in complete loss of Dlx3 function. These observations provide new insight regarding the function of Dlx3 in vertebrate development and tissue differentiation and also suggest a mechanism for the dominant inheritance pattern of a hereditary disease resulting from mutation of the DLX3 gene in human.

Placental failure in mice lacking the homeobox gene Dlx3.

Dlx3 is a homeodomain transcription factor and a member of the vertebrate Distal-less family. Targeted deletion of the mouse Dlx3 gene results in embryonic death between day 9.5 and day 10 because of placental defects that alter the development of the labyrinthine layer. In situ hybridization reveals that the Dlx3 gene is initially expressed in ectoplacental cone cells and chorionic plate, and later in the labyrinthine trophoblast of the chorioallantoic placenta, where major defects are observed in the Dlx3 -/- embryos. The expression of structural genes, such as 4311 and PL-1, which were used as markers to follow the fate of different derivatives of the placenta, was not affected in the Dlx3-null embryos. However, by day 10.5 of development, expression of the paired-like homeodomain gene Esx1 was strongly down-regulated in affected placenta tissue, suggesting that Dlx3 is required for the maintenance of Esx1 expression, normal placental morphogenesis, and embryonic survival.

Molecular cloning of Xenopus hatching enzyme and its specific expression in hatching gland cells.

UVS.2 has been known as a cloned cDNA expressed selectively in the hatching gland cells of Xenopus laevis. To determine the molecular identity and function of UVS.2-encoded proteins, antibodies were raised against a bacterially-expressed fusion protein comprising glutathione-S-transferase (GST) and UVS.2. Anti-GST-UVS.2 antibodies inhibited the vitelline envelope digesting activity of the medium (hatching medium) in which dejellied prehatching embryos were cultured. On Western blotting, hatching medium contained 60 kDa and 40 kDa molecules reactive with these antibodies. Whole-mount immunostaining showed a specific localization of UVS.2 protein in the hatching gland cells which appeared first at stage 20, increased in number and intensity to stage 31 then decreased gradually thereafter. Immunoelectron microscopy revealed that UVS.2 protein is localized exclusively in the secretory granules in the hatching gland cells. A cDNA library from the dorsoanterior portion of stage 25 embryos was screened with UVS.2, and a 1.8 kb insert thus cloned contained additional 619bp and 204bp at the 5' and 3' ends of UVS.2, respectively. This clone, designated XHE, contained an open reading frame encoding 514 amino acids including both signal and propeptide sequences. The predicted mature enzyme comprising 425 amino acids consists of about 200 amino acid-long metalloprotease sequence of astacin family at the N-terminus, followed by two repeats of CUB domain each 110 amino acid-length. We conclude that UVS.2 represents an approximately 3/4 C-terminal portion of the hatching enzyme.

Regulation of epidermal differentiation by a Distal-less homeodomain gene.

The Distal-less-related homeodomain gene Dlx3 is expressed in terminally differentiated murine epidermal cells. Ectopic expression of this gene in the basal cell layer of transgenic skin results in a severely abnormal epidermal phenotype and leads to perinatal lethality. The basal cells of affected mice ceased to proliferate, and expressed the profilaggrin and loricrin genes which are normally transcribed only in the latest stages of epidermal differentiation. All suprabasal cell types were diminished and the stratum corneum was reduced to a single layer. These data indicate that Dlx3 misexpression results in transformation of basal cells into more differentiated keratinocytes, suggesting that this homeoprotein is an important regulator of epidermal differentiation.

Disruption of cell adhesion in Xenopus embryos by Pagliaccio, an Eph-class receptor tyrosine kinase.

Pagliaccio (Pag) is a receptor tyrosine kinase of the Eph family that is expressed in Xenopus embryos in a diverse set of localized tissues. Pag is the Xenopus homolog of Hek-8 (human), Sek-1 (mouse), cek8 (chicken), and RTK-1 (zebrafish). We have investigated the function of this protein by injecting RNA encoding an epidermal growth factor receptor-Pag chimera into early Xenopus embryos. Activation of the chimeric receptor results in a kinase-dependent loss of cell-cell adhesion. This dissociation can be reversed by co-injection of RNA encoding C-cadherin, suggesting that one or more cadherins could be the functional targets for Pag activity.

Ventral neural cadherin, a novel cadherin expressed in a subset of neural tissues in the zebrafish embryo.

Cadherins are calcium-binding transmembrane glycoproteins that are important mediators of cell-cell association. Here we describe a novel member of this gene family, zebrafish ventral neural cadherin (VN-cad). Multiple VN-cad transcripts are first detectable by Northern blots at 60% epiboly. In the developing neural tube, VN-cad RNA is first found in the neuroectoderm, directly above the notochord, and later was localized to the neural keel. At the 20-somite stage, VN-cad transcripts are confined to the ventral neural tube, otic vesicle, midbrain, and diencephelon. Transcription of VN-cad RNA continues in adult fish. The embryonic pattern of expression is not significantly disrupted in cyclops or no tail mutants, which lack the floor plate and notochord, respectively. Therefore, neither of these structures is absolutely required for VN-cad expression. The localized pattern of VN-cad expression suggests a possible role for this adhesion molecule in the initial formation and subsequent differentiation of the central nervous system.

Novel members of the eph receptor tyrosine kinase subfamily expressed during Xenopus development.

Three cDNAs encoding receptor tyrosine kinases (RTKs) of the eph-subfamily have been identified based on their homology to Pagliaccio (Winning and Sargent, 1994, Mech. Dev. 46:219-229). These have been named TCK, Xelk (Xenopus homologue of elk), and PL7a (pag-like clone 7a). Each of these genes is expressed in a distinctive, tissue specific manner during early development. TCK is expressed in pre-somitic mesoderm, caudal somites, midbrain and cement gland. Xelk is expressed in the brain and spinal cord and in the first and fourth visceral arches. PL7a cDNA is expressed throughout the head and in the tip of the tail. All of the genes are represented in maternal mRNA, and are expressed in adult tissues. The Xelk cDNA encodes a protein which is 94% identical to rat elk and therefore is likely to represent the Xenopus homologue of this gene. TCK and PL7a are less related to previously identified eph-subfamily RTKs. The inability to unambiguously assign TCK and PL7a as Xenopus homologues of any previously identified eph RTK leads us to conclude that these cDNAs represent novel members of this family.

A Xenopus distal-less gene in transgenic mice: conserved regulation in distal limb epidermis and other sites of epithelial-mesenchymal interaction.

In this paper, we show the conserved regulation of the homeodomain gene Distal-less-3 (Dlx-3) by analyzing the expression of a promoter from the Xenopus ortholog, Xdll-2, in transgenic mice. A 470-bp frog regulatory sequence confers appropriate expression on a lacZ reporter gene in the ectodermal component of structures derived from epithelial-mesenchymal interactions. Remarkably, this includes structures absent in Xenopus, such as the hair follicle and mammary gland, suggesting that conserved regulatory elements can be used to control the formation of structures peculiar to individual species. In addition, expression of Dlx-3 in developing limbs is highest at the most distal portion. This pattern is duplicated by the Xenopus promoter, indicating that this DNA may include sequences responsive to conserved proximodistal patterning signals in the vertebrate limb.

Pagliaccio, a member of the Eph family of receptor tyrosine kinase genes, has localized expression in a subset of neural crest and neural tissues in Xenopus laevis embryos.

Cranial neural crest cells arise from neural folds in the embryonic head and differentiate to produce most of the cartilages and bones of the skull and the somatosensory ganglia of several cranial nerves, among other tissues. Since the molecular basis of the determination of these cells is poorly understood, we have begun a search for molecules involved in signal transduction in cranial neural crest. From a Xenopus laevis cranial neural crest cDNA bank, we have cloned a cDNA encoding a putative receptor tyrosine kinase, which we call Pagliaccio (Pag). Pag RNA is present transiently in visceral arch 3, probably representing neural crest cells in this tissue. Pag is also expressed in the forebrain, rhombomeres r3 and r5 of the hindbrain and in the pronephros. Based on this localized expression, we propose that Pag may play a role in the differentiation of cranial neural crest and other tissues.

Differential expression of a Distal-less homeobox gene Xdll-2 in ectodermal cell lineages.

Neural induction in Xenopus requires the activation of new sets of genes that are necessary for cellular and regional specification of the neural tube. It has been reported earlier that members of the Distal-less homeobox gene family are specifically activated in distinct regions of the central nervous system (CNS) of Xenopus embryos (Dirksen et al., 1993; Papalopulu and Kintner, 1993). In this paper we describe in detail a Xenopus homeobox containing gene Xdll-2, which belongs to the Distal-less gene family. In contrast to other previously described Xenopus family members, Xdll-2 is expressed in the embryonic ectoderm and is specifically repressed in the CNS. This repression can be mimicked in isolated animal caps by treatment with activin. Expression of Xdll-2 persists in the epidermis and some neural crest cells. Because of its spatial and temporal expression pattern this gene is a good candidate to have a regulatory function in the initial formation of the epidermis. Its high level of expression in adult skin indicates that its function is continuously required in this tissue.

The homeodomain gene Xenopus Distal-less-like-2 (Xdll-2) is regulated by a conserved mechanism in amphibian and mammalian epidermis.

Xenopus Distal-less-like-2 (Xdll-2) is a gene encoding a homeodomain protein expressed predominantly in the epidermis of frog embryos. We report here that this epidermal expression is specified by a regulatory 5' flanking DNA region located within 933 bp of the start of transcription. This regulatory DNA also confers upon a globin reporter gene calcium-inducible expression in cultured murine keratinocytes and induction-dependent repression in frog ectodermal cells treated in vitro with activin A. These results reveal a new example of phylogenetically conserved, tissue-specific transcriptional regulation of a homeodomain gene.

Transcription factor AP-2 is tissue-specific in Xenopus and is closely related or identical to keratin transcription factor 1 (KTF-1).

This paper identifies a new, developmental role for transcription factor AP-2 in the activation of amphibian embryonic epidermal keratin gene expression. Keratin transcription factor KTF-1 is shown by several criteria to be identical or closely related to AP-2. KTF-1/AP-2 is shown to be tissue-specific from its first transcription in Xenopus embryos, and restricted to a small number of adult tissues, including skin. Epidermis-specific keratin transcription closely follows specification of the embryonic ectoderm in Xenopus, and is subject to regulation by growth factors and embryonic induction. We further show that in mouse basal keratinocytes, a KTF-1/AP-2-like factor is present and binds to a DNA sequence previously shown to be important in the regulation of the keratin K14 gene, which is actively expressed in these cells. Thus, the study of AP-2 and its role in the regulation of keratin gene transcription should enhance our understanding of both amphibian embryonic development and mammalian skin differentiation.

Developmental regulation of transcription factor AP-2 during Xenopus laevis embryogenesis.

We have isolated a cDNA clone encoding the Xenopus homologue of the transcription factor AP-2 (XAP-2). The predicted amino acid sequence derived from the Xenopus cDNA shows very strong conservation with the amino acid sequence of human AP-2, suggesting that this protein is evolutionarily conserved, at least among vertebrates. This is further substantiated by the demonstration that an in vitro translation product of XAP-2 cDNA bound specifically to an AP-2 binding site from the human MT-IIA gene. Northern blot analysis of Xenopus embryo RNA revealed the existence of three major XAP-2 mRNA species that were only detectable after the midblastula transition (when embryonic transcription is activated), with peak accumulation of the transcripts occurring during gastrulation. Therefore, in contrast to other Xenopus transcription factors, XAP-2 is not maternally derived but arises exclusively from zygotic transcription. Unlike the situation in cultured human teratocarcinoma (NT2) cells, retinoic acid treatment did not induce XAP-2 mRNA in Xenopus embryos, even though the treatment had a pronounced morphogenetic effect on the embryos. Our results suggest that XAP-2 may play a distinctive role during Xenopus embryogenesis.