Drosophila goosecoid participates in neural development but not in body axis formation.

In vertebrate embryos, the homeobox gene goosecoid (gsc) is expressed in the gastrula organizer region and in later arising embryonic tissues including the foregut anlage. Ectopic expression and loss-of-function studies have demonstrated that Xenopus gsc elicits a dorsalizing activity that contributes to body axis formation. Here we report that the gsc gene is conserved in invertebrates. In Drosophila, D-gsc is expressed most strongly in the foregut anlage, which gives rise to the foregut proper and the stomatogastric nervous system (SNS). D-gsc expression overlaps with one of the three SNS precursor groups invaginating from the foregut anlage. Embryos mutant for D-gsc gastrulate normally but show disrupted invagination in the SNS primordium and lack one specific SNS ganglion. In addition, D-gsc mutant embryos show a less well defined defect in foregut arrangement. Our results indicate that this invertebrate homolog of gsc is not required for gastrulation but plays a role in neurogenesis in post-gastrula Drosophila embryos.     

The role of gsc and BMP-4 in dorsal-ventral patterning of the marginal zone in Xenopus: a loss-of-function study using antisense RNA.

The dorsal-specific homeobox gene goosecoid (gsc) and the bone morphogenetic protein 4 gene (BMP-4) are expressed in complementary regions of the Xenopus gastrula. Injection of gsc mRNA dorsalizes ventral mesodermal tissue and can induce axis formation in normal and UV-ventralized embryos. On the other hand, BMP-4 mRNA injection, which has a strong ventralizing effect on whole embryos, has been implicated in ventralization by UV, and can rescue tail structures in embryos dorsalized by LiCl. The above-mentioned putative roles for BMP-4 and gsc are based on gain-of-function experiments. In order to determine the in vivo role of these two genes in the patterning of the Xenopus mesoderm during gastrulation, partial loss-of-function experiments were performed using antisense RNA injections. Using marker genes that are expressed early in gastrulation, we show that antisense gsc RNA has a ventralizing effect on embryos, whereas antisense BMP-4 RNA dorsalizes mesodermal tissue. These loss-of-function studies also show a requirement for gsc and BMP-4 in the dorsalization induced by LiCl and in the ventralization generated by UV irradiation, respectively. Thus, both gain- and loss-of-function results for gsc and BMP-4 support the view that these two genes are necessary components of the dorsal and ventral patterning pathways in Xenopus embryos.     

Retinoic acid induces changes in the localization of homeobox proteins in the antero-posterior axis of Xenopus laevis embryos.

We have studied the localization of the proteins of Xeb1 and Xeb2, two homeobox (hbx)-containing genes that are expressed during the early development of Xenopus laevis. Both proteins are expressed in juxtaposed and partially overlapping domains along the antero-posterior axis of Xenopus laevis embryos, with clearly defined anterior boundaries. Xeb2 is predominantly expressed in the caudal region of the hindbrain, whereas the Xeb1 protein is located in the most rostral region of the spinal cord. Furthermore, both proteins are expressed in single cells dispersed in the lateral flanks of the embryo in positions that correlate with the expression domains in the neural tube. We suggest that these cells are migratory neural crest cells that have acquired positional information in the neural tube prior to migration. The Xeb2 protein was also detected in the most posterior branchial arches and the pronephros. In stage 45 embryos, nuclei of the IX-X cranial ganglia, the lung buds and cells spreading into the forelimb rudiment express the Xeb2 antigen. The Xeb1 protein was also detected in the lung buds and the forelimb rudiment. To examine the effect of retinoic acid on expression, gastrula embryos were treated with all-trans retinoic acid (RA). Increasing concentrations of RA caused progressive truncation of anterior structures. The most severely affected embryos lacked eyes, nasal pits, forebrain, midbrain and otic vesicles, and the anterior boundary of the hindbrain seemed to be displaced rostrally. This alteration correlates with a progressive displacement of the anterior boundary of the expression domain of Xeb2. On the other hand, 10(-6) M RA induces an ectopic site of Xeb1 expression at the anterior end of the central nervous system, located just anterior to the extended domain of Xeb2 whereas expression in the spinal cord remains unaffected.     

Regional gene expression in the epithelia of the Xenopus tadpole gut

In recent years much progress has been made in the understanding of the genes and mechanisms involved in specification of the cells of the endoderm, which give rise to the epithelium of the gut and respiratory system. However, little is known about the way in which the gut becomes patterned along its anterior-posterior axis, that is, how boundaries are established between the different epithelia of the gut tube. Here we show that the expression patterns of five genes divide the Xenopus tadpole gut epithelium into at least four regions along this axis in the undifferentiated, 3-day-old gut (stage 41), and that these divisions are maintained until at least 7 days, when cell differentiation is well under way. In addition, the restricted expression patterns of these genes clearly mark the anterior and posterior boundaries of the intestine. Xsox2 is expressed in the anterior gut, spanning the oesophagus and stomach but terminating at the stomach/intestine boundary. Xcad1 and Xcad2, two caudal-type homeobox genes, are expressed in a region with an anterior limit at this boundary and a posterior limit between the colon and proctodeum, therefore covering the whole of the small and large intestines. Intestinal fatty acid binding protein (IFABP) is expressed only in the anterior small intestine, and the even-skipped homeobox gene Xhox3 is expressed in the most posterior part of the gut, the proctodeum.     

Homoiogenetic regulation through the ectoderm on localized expression of the hatching gland phenotype in the head area of Xenopus embryos

Ectoderm pieces explanted from embryos of Xenopus laevis were cultured and examined for differentiation of hatching gland cells, using immunoreactivity against anti-XHE (Xenopus hatching enzyme) as a marker. The anterio-dorsal ectoderm excised from stage 12-13 (mid-late gastrula) embryos developed hatching gland cells. Meanwhile, the posterio-, but not the anterio-dorsal ectoderm from stage 11 (early gastrula) embryos developed these cells, although it is not fated to do so during normogenesis. This hatching gland cell differentiation from stage 11 posterior ectoderm was not affected by conjugated sandwich culture with the mesoderm but was suppressed when explants contained an anterior portion of the ectoderm. Conjugated cultures of anterior and posterior portions of the ectoderm in various combinations indicated that differentiation of hatching gland cells from stage 11 posterior and stage 12 anterior portions was suppressed specifically by stage 11 anterior ectoderm. Northern blot analyses of cultured explants showed that XHE was expressed in association with XA-1, suggesting its dependence on the anteriorized state. These results indicate that the planar signal(s) emanating from stage 11 anterior ectoderm participates in suppression of the expression of the anteriorized phenotype so that an ordered differentiation along the anteroposterior axis of the surface ectoderm is accomplished.     

Anteroposterior patterning of the epidermis by inductive influences from the vegetal hemisphere cells in the ascidian embryo.

Patterning along the anteroposterior axis is a critical step during animal embryogenesis. Although mechanisms of anteroposterior patterning in the neural tube have been studied in various chordates, little is known about those of the epidermis. To approach this issue, we investigated patterning mechanisms of the epidermis in the ascidian embryo. First we examined expression of homeobox genes (Hrdll-1, Hroth, HrHox-1 and Hrcad) in the epidermis. Hrdll-1 is expressed in the anterior tip of the epidermis that later forms the adhesive papillae, while Hroth is expressed in the anterior part of the trunk epidermis. HrHox-1 and Hrcad are expressed in middle and posterior parts of the epidermis, respectively. These data suggested that the epidermis of the ascidian embryo is patterned anteroposteriorly. In ascidian embryogenesis, the epidermis is exclusively derived from animal hemisphere cells. To investigate regulation of expression of the four homeobox genes in the epidermis by vegetal hemisphere cells, we next performed hemisphere isolation and cell ablation experiments. We showed that removal of the vegetal cells before the late 16-cell stage results in loss of expression of these homeobox genes in the animal hemisphere cells. Expression of Hrdll-1 and Hroth depends on contact with the anterior-vegetal (the A-line) cells, while expression of HrHox-1 and Hrcad requires contact with the posterior-vegetal (the B-line) cells. We also demonstrated that contact with the vegetal cells until the late 32-cell stage is sufficient for animal cells to express Hrdll-1, Hroth and Hrcad, while longer contact is necessary for HrHox-1 expression. Contact with the A-line cells until the late 32-cell stage is also sufficient for formation of the adhesive papillae. Our data indicate that the epidermis of the ascidian embryo is patterned along the anteroposterior axis by multiple inductive influences from the vegetal hemisphere cells and provide the first insight into mechanisms of epidermis patterning in the chordate embryos.     

Isolation and embryonic expression of an abdominal-A-like gene from the lepidopteran, Manduca sexta.

Using sequence homology to the Drosophila Antennapedia gene, we isolated a homeobox-containing gene from the lepidopteran, Manduca sexta. Sequence analysis and in situ hybridizations to tissue sections suggest that the Manduca gene encodes a lepidopteran homologue of the Drosophila Bithorax complex gene abdominal-A. The predicted amino acid sequence of a 76 amino acid region that includes the homeobox and the regions immediately flanking it are identical between the Manduca and Drosophila genes. Northern blots reveal that the manduca abd-A gene is expressed first in the early embryo and continues to be expressed throughout later embryonic and larval stages. In situ hybridizations show that the posterior half of the first abdominal segment marks the anterior border of the Manduca abd-A expression. This expression pattern demonstrates the conservation of parasegments as domains of gene activity in the lepidopteran embryo. The Manduca abd-A expression extends from the posterior half of the first abdominal segment through the tenth abdominal segment, a domain that is greater than that of the Drosophila abd-A expression, and reflects the difference in visible segment number between the two insects.     

<Emphasis Type="Italic">AmphiFoxQ2</Emphasis>, a novel winged helix/forkhead gene,exclusively marks the anterior end of the amphioxus embryo

A full-length FoxQ-related gene (AmphiFoxQ2) was isolated from amphioxus. Expression is first detectable in the animal/anterior hemisphere at the mid blastula stage. The midpoint of this expression domain coincides with the anterior pole of the embryo and is offset dorsally by about 20 degrees from the animal pole. During the gastrula stage, expression is limited to the anterior ectoderm. By the early neurula stage, expression remains in the anterior ectoderm and also appears in the adjacent anterior mesendoderm. By the early larval stages, expression is detectable in the anteriormost ectoderm and in the rostral tip of the notochord. AmphiFoxQ2 is never expressed anywhere except at the anterior tip of amphioxus embryos and larvae. This is the first gene known that exclusively marks the anterior pole of chordate embryos. It may, therefore, play an important role in establishing and/or maintaining the anterior/posterior axis.     

Tissue-specific localization of mRNA for carrot homeobox genes, CHBs, in carrot somatic embryos

We examined spatial and temporal expression patterns of four carrot HD-Zip I homeobox genes in somatic embryos. The mRNAs for CHB3, CHB4 and CHB5 were accumulated preferentially in the innermost cortical cell layers of the embryo axis in the torpedo-shaped embryo. In contrast, the accumulation of CHB6 mRNA was restricted to procambial cells of the heart- and torpedo-shaped embryos. In the embryonic cotyledons and the hypocotyl of the seedlings, all of the mRNAs for the four genes were located in the vascular tissues. These findings indicate that different HD-Zip I homeobox genes may be involved in the differentiation of specific tissues during somatic embryogenesis.