Interaction between X-Delta-2 and Hox genes regulates segmentation and patterning of the anteroposterior axis

In vertebrates, the paraxial mesoderm already exhibits a complex Hox gene pattern by the time that segmentation occurs and somites are formed. The anterior boundaries of the Hox genes are always maintained at the same somite number, suggesting coordination between somite formation and Hox expression. To study this interaction, we used morpholinos to knockdown either the somitogenesis gene X-Delta-2 or the complete Hox paralogous group 1 (PG1) in Xenopus laevis. When X-Delta-2 is knocked down, Hox genes from different paralogous groups are downregulated from the beginning of their expression at gastrula stages. This effect is not via the canonical Notch pathway, as it is independent of the Notch effector Su(H). We also reveal for the first time a clear role for Hox genes in somitogenesis, as loss of PG1 gene function results in the perturbation of somite formation and downregulation of the X-Delta-2 expression in the PSM. This effect on X-Delta-2 expression is also observed during neurula stages, before the somites are formed. These results show that somitogenesis and patterning of the anteroposterior axis are closely linked via a feedback loop involving Hox genes and X-Delta-2, suggesting the existence of a coordination mechanism between somite formation and anteroposterior patterning. Such a mechanism is likely to be functional during gastrulation, before the formation of the first pair of somites, as suggested by the early X-Delta-2 regulation of the Hox genes.     

The fates of zebrafish Hox gene duplicates

In his 1970 book, Susumu Ohno stressed the importance of gene duplication in the evolution of the vertebrate genome and body plan. He elaborated the idea that duplication events provide novel genetic material on which evolution may act. Data are accumulating to show that extensive duplication events, perhaps incorporating the duplication of entire genomes, occurred in the lineage leading to teleost fishes. These duplications may have been pivotal in the explosive radiation of this highly successful vertebrate group. Thus, the teleosts provide us with an ideal opportunity to investigate the fates and functions of duplicated genes. A convenient system for these studies is the zebrafish, Danio rerio, which has become a popular genetic and embryological model.     

Retinoic acid in the anteroposterior patterning of the zebrafish trunk

Retinoic acid has been linked to pattern formation in the vertebrate anteroposterior axis. This report describes the spatial and temporal distributions of both endogenous retinoic acid and retinoic acid synthase activity along the anteroposterior axis of neurulating zebrafish embryos, as detected by a transient transgenic assay and by a zymography bioassay. Both retinoic acid levels and synthase activity were found to be highest in anterior regions of the trunk at all of the stages which were analysed. The drug disulfiram inhibited retinoic acid synthase activity in the zebrafish trunk both in vitro and in vivo, and reduced retinoic acid levels in vivo. Disulfiram treatment of neurulating embryos resulted in larvae with hypertrophic wavy notochords, shortened spinal cords and deformed pectoral fins. The results support the hypothesis that retinoic acid plays a role in the coordination of axial patterning at the developing node/zone of involution, as well as in the subsequent development of anterior trunk structures such as the fins.     

Of mites and zen: expression studies in a chelicerate arthropod confirm zen is a divergent Hox gene

 We have cloned, from an oribatid mite, a gene homologous to the zerknült (zen) genes of insects and the Hox 3 genes of vertebrates. Hox genes specify cell fates in specific regions of the body in all metazoans studied and are expressed in antero-posteriorly restricted regions of the embryo. This is true of the vertebrate Hox 3 but not of the zen genes, the insect homologs, and it has been proposed that the zen genes have lost their Hox-like function in the ancestor of the insects. We studied expression of a mite Hox 3/zen homolog and found that it is expressed in a discrete antero-posterior region of the body with an anterior boundary coinciding with that of the chelicerate homolog of the Drosophila Hox gene, proboscipedia, and propose that its loss of Hox function in insects is due to functional redundancy due to this overlap with another Hox gene. Received: 23 April 1998 / Accepted: 25 August 1998     

Hox C6 expression during development and regeneration of forelimbs in larval Notophthalmus viridescens

 A central theme concerning the epimorphic regenerative potential of urodele amphibian appendages is that limb regeneration in the adult parallels larval limb development. Results of previous research have led to the suggestion that homeobox containing genes are ”re-expressed” during the epimorphic regeneration of forelimbs of adult Notophthalmus viridescens in patterns which retrace larval limb development. However, to date no literature exists concerning expression patterns of any homeobox containing genes during larval development of this species. The lack of such information has been a hindrance in exploring the similarities as well as differences which exist between limb regeneration in adults and limb development in larvae. Here we report the first such results of the localization of Hox C6 (formerly, NvHBox-1) in developing and regenerating forelimbs of N. viridescens larvae as demonstrated by whole-mount in situ hybridization. Inasmuch as the pattern of Hox C6 expression is similar in developing forelimb buds of larvae and epimorphically regenerating forelimb blastemata of both adults and larvae, our results support the paradigm that epimorphic regeneration in adult newts parallels larval forelimb development. However, in contrast with observations which document the presence of Hox C6 in both intact, as well as regenerating hindlimbs and tails of adult newts, our results reveal no such Hox C6 expression during larval development of hindlimbs or the tail. As such, our findings indicate that critical differences in larval hindlimb and tail development versus adult expression patterns of this gene in these two appendages may be due primarily to differences in gene regulation as opposed to gene function. Thus, the apparent ability of urodeles to regulate genes in such a highly co-ordinated fashion so as to replace lost, differentiated, appendicular structures in adult animals may assist, at least in part, in better elucidating the phenomenon of epimorphic regeneration. Received: 6 November 1998 / Accepted: 12 December 1998     

The leech hunchback protein is expressed in the epithelium and CNS but not in the segmental precursor lineages

We are interested in identifying the regulatory genes involved in segmental pattern formation in annelids. The Drosophila segmentation gene hunchback (hb) is critical for the proper anteroposterior development of the fly embryo, but its function outside the diptera is currently unknown. Here, the protein expression pattern of Leech Zinc Finger II (LZF2), a leech orthologue of hb is characterized. In early embryogenesis, LZF2 protein is expressed in a subset of micromeres and is later expressed in the micromere-derived epithelium of the provisional epithelium and prostomium. LZF2 protein is detected in the ventral nerve cord during organogenesis, first in interganglionic muscle cells and later in subsets of neurons in each neuromere of the CNS. The location of immunoreactive cells during development and the similarity of the expression pattern of LZF2 to the expression of the Caenhorhabditis elegans hb homologue hbl-1 suggests that LZF2 plays a role in the morphogenetic movements of leech gastrulation and later in CNS specification but not in anteroposterior pattern formation. Received: 28 May 1999 / Accepted: 21 December 1999     

The evolution of paired appendages in vertebrates: T-box genes in the zebrafish

The presence of two sets of paired appendages is one of the defining features of jawed vertebrates. We are interested in identifying genetic systems that could have been responsible for the origin of the first set of such appendages, for their subsequent duplication at a different axial level, and/or for the generation of their distinct identities. It has been hypothesized that four genes of the T-box gene family (Tbx2–Tbx5) played important roles in the course of vertebrate limb evolution. To test this idea, we characterized the orthologs of tetrapod limb-expressed T-box genes from a teleost, Danio rerio. Here we report isolation of three of these genes, tbx2, tbx4, and tbx5. We found that their expression patterns are remarkably similar to those of their tetrapod counterparts. In particular, expression of tbx5 and tbx4 is restricted to pectoral and pelvic fin buds, respectively, while tbx2 can be detected at the anterior and posterior margins of the outgrowing fin buds. This, in combination with conserved expression patterns in other tissues, suggests that the last common ancestor of teleosts and tetrapods possessed all four of these limb-expressed T-box genes (Tbx2–Tbx5), and that these genes had already acquired, and have subsequently maintained, their gene-specific functions. Furthermore, this evidence provides molecular support for the notion that teleost pectoral and pelvic fins and tetrapod fore- and hindlimbs, respectively, are homologous structures, as suggested by comparative morphological analyses. Received: 14 July 1999 / Accepted: 4 September 1999     

Analysis of axon tract formation in the zebrafish brain: the role of territories of gene expression and their boundaries

Mutant analysis in the zebrafish is revealing the genes that are expressed in the early neuroepithelium and that regulate factors responsible for the guidance of commissural axons. We review work on the developing zebrafish brain illustrating the way in which territories of regulatory gene expression influence the formation and positioning of axon pathways. Received: 20 May 1997 / Accepted: 9 June 1997     

Characterisation of five novel zebrafish Eph-related receptor tyrosine kinases suggests roles in patterning the neural plate

 Eph-related receptor tyrosine kinases (RTKs) are the largest known subfamily of RTKs, comprising at least a dozen members. Expression studies suggest roles for these genes in patterning and differentiation of the nervous system, the neural crest, developing limbs and somites. Some of the recently isolated family of ligands for Eph-related RTKs have been shown to function as positional identifiers in the retinotectal system. We have previously characterised three Eph-related RTKs in the zebrafish (rtk1-3). Here we report the identification of five new zebrafish Eph-related RTKs (rtk4, rtk5, rtk6, rtk7 and rtk8) and describe their dynamic expression patterns. Based on these expression patterns, we propose that rtk4-8 play various roles in establishing territories within the developing central nervous system (CNS) and in the subsequent differentiation of defined neuronal populations. Received: 22 November 1996 / Accepted: 3 January 1997     

A recombinogenic targeting method to modify large-inserts for cis-regulatory analysis in transgenic mice: construction and expression of a 100-kb, zebrafish Hoxa-11b-lacZ reporter gene

The identification of cis-sequences responsible for spatiotemporal patterns of gene expression often requires the functional analysis of large genomic regions. In this study a 100-kb zebrafish Hoxa-11b-lacZ reporter gene was constructed and expressed in transgenic mice. PAC clone 10-O19, containing a portion of the zebrafish HoxA-b cluster, was captured into the yeast-bacterial shuttle vector, pPAC-ResQ, by recombinogenic targeting. A lacZ reporter gene was then inserted in-frame into exon 1 of the zfHoxa-11b locus by a second round of recombinogenic targeting. Expression of the zfHoxa-11b-lacZ reporter gene in 10.5 d.p.f. transgenic mouse embryos was observed only in the posterior portion of the A-P axis, in the paraxial mesoderm, neural tube, and somites. These findings demonstrate the utility of recombinogenic targeting for the modification and expression of large inserts captured from P1/PAC clones. Received: 22 June 1999 / Accepted: 1 September 1999     

Characterization of the zebrafish tbx16 gene and evolution of the vertebrate T-box family

 We report on a new zebrafish T-box-containing gene, tbx16. It encodes a message that is first detected throughout the blastoderm soon after the initiation of zygotic gene expression. Following gastrulation, expression becomes restricted to paraxial mesoderm and later primarily to the developing tail bud. To gain an evolutionary prospective on the potential function of this gene, we have analyzed its phylogenetic relationships to known T-box genes from other species. Zebrafish tbx16 is likely orthologous to the chicken Tbx6L and Xenopus Xombi/Antipodean/Brat/VegT genes. Our analysis also shows that zebrafish tbx6 and mouse Tbx6 genes are paralogous to zebrafish tbx16. We present evidence which argues, that despite the same name and similar expression, zebrafish tbx6 and mouse Tbx6 genes are not orthologous to each other but instead represent relatively distant paralogs. The expression patterns of all genes are discussed in the light of their evolutionary relationships. Received: 27 November 1997 / Accepted: 27 January 1998     

Bone morphogenetic protein-4 expression characterizes inductive boundaries in organs of developing zebrafish

 We have cloned and examined the expression pattern of zebrafish bone morphogenetic protein-4 (BMP4) as a start to evaluating signals which might participate in the fashioning of organ systems in this genetically tractable species. The predicted sequence of the mature zebrafish protein is more than 75% identical to that of other vertebrates and 66% identical to Drosophila decapentaplegic (Dpp). As in other species, BMP4 is expressed ventrally during gastrulation, but the zebrafish is unusual in having an additional dorsal domain of expression. Subsequent BMP4 expression is especially prominent in sensory organs, fin buds, and in the gut, kidney, and heart. In all these sites, it becomes particularly enriched in regions of inductive demarcations. For example, expression initially extends through the entire heart tube but then becomes limited to the boundaries between cardiac chambers (sinus venosus-atrial junction, atrio-ventricular junction, and aortic root) prior to cushion formation. In early pectoral fin development, BMP4 is at first expressed uniformly but then becomes restricted to the mesenchyme subjacent to the apical ectodermal ridge. This suggests that among its roles in development, BMP4 serves as a signal in primordial outgrowth and also as a signal demarcating the borders within organs or structures where subspecializations occur. Received: 13 January 1997 / Accepted: 3 April 1997     

Shaping the zebrafish heart: From left-right axis specification to epithelial tissue morphogenesis

Although vertebrates appear bilaterally symmetric on the outside, various internal organs, including the heart, are asymmetric with respect to their position and/or their orientation based on the left/right (L/R) axis. The L/R axis is determined during embryo development. Determination of the L/R axis is fundamentally different from the determination of the anterior-posterior or the dorsal-ventral axis. In all vertebrates a ciliated organ has been described that induces a left-sided gene expression program, which includes Nodal expression in the left lateral plate mesoderm. To have a better understanding of organ laterality it is important to understand how L/R patterning induces cellular responses during organogenesis. In this review, we discuss the current understanding of the mechanisms of L/R patterning during zebrafish development and focus on how this affects cardiac morphogenesis. Several recent studies have provided unprecedented insights into the intimate link between L/R signaling and the cellular responses that drive morphogenesis of this organ.