A rational nomenclature for vertebrate homeobox (HOX) genes.

Developmental fates along the anterior-posterior axes of animals are controlled by clustered homeotic genes which in vertebrates are called Hox genes. The gene clusters are similar and probably functionally homologous in animals as different as nematodes, flies, and mammals. A new set of names for Hox genes was recently agreed upon by many workers in the field. Remarkably, the order of the Hox genes along the chromosome reflects where they are expressed along the body axis. This simple principle is reflected in the new nomenclature system.     

Regulation of vertebrate eye development by Rx genes

The paired-like homeobox-containing gene Rx has a critical role in the eye development of several vertebrate species including Xenopus, mouse, chicken, medaka, zebrafish and human. Rx is initially expressed in the anterior neural region of developing embryos, and later in the retina and ventral hypothalamus. Abnormal regulation or function of Rx results in severe abnormalities of eye formation. Overexpression of Rx in Xenopus and zebrafish embryos leads to overproliferation of retinal cells. A targeted elimination of Rx in mice results in a lack of eye formation. Mutations in Rx genes are the cause of the mouse mutation eyeless (ey1), the medaka temperature sensitive mutation eyeless (el) and the zebrafish mutation chokh. In humans, mutations in Rx lead to anophthalmia. All of these studies indicate that Rx genes are key factors in vertebrate eye formation. Because these results cannot be easily reconciled with the most popular dogmas of the field, we offer our interpretation of eye development and evolution.     

Unmethylated domains in vertebrate DNA.

We have detected a fraction that is rich in unmethylated HpaII and HhaI sites by end-labelling HpaII fragments of chicken DNA. The fraction is not obvious when DNA fragments are stained with ethidium bromide as it amounts to less than 2% of the genome. The average frequency of sites for HpaII is over thirteen times greater in the unmethylated fraction than in total DNA. Partial digests indicate that the unmethylated sites are clustered in the genome. Similar unmethylated fractions were detected in six other vertebrates in both somatic and germ line DNA.     

Two vertebrate homeobox genes related to the Drosophila empty spiracles gene are expressed in the embryonic cerebral cortex.

We cloned two homeobox genes, Emx1 and Emx2, related to empty spiracles, a gene expressed in very anterior body regions during early Drosophila embryogenesis, and studied their expression in mouse embryos. Emx1 expression is detectable from day 9.5 of gestation whereas Emx2 appears to be already expressed in 8.5 day embryos. Both genes are expressed in the presumptive cerebral cortex and olfactory bulbs. Emx1 is expressed exclusively there, whereas Emx2 is also expressed in some neuroectodermal areas in embryonic head including olfactory placodes in earlier stages and olfactory epithelia later in development.     

Retinal homeobox genes and the role of cell proliferation in cavefish eye degeneration

The teleost Astyanax mexicanus exhibits eyed surface dwelling (surface fish) and blind cave dwelling (cavefish) forms. Despite lacking functional eyes as adults, cavefish embryos form eye primordia, which later arrest in development, degenerate and sink into the orbit. We are comparing the expression patterns of various eye regulatory genes during surfacefish and cavefish development to determine the cause of eye degeneration. Here we examine Rx and Chx/Vsx family homeobox genes, which have a major role in cell proliferation in the vertebrate retina. We isolated and sequenced a full-length RxcDNA clone (As-Rx1) and part of a Chx/Vsx(As-Vsx2) gene, which appear to be most closely related to the zebrafish Rx1 and Alx/Vsx2 genes respectively. In situ hybridization shows that these genes have similar but non-identical expression patterns during Astyanax eye development. Expression is first detected in the optic vesicle, then throughout the presumptive retina of the optic cup, and finally in the ciliary marginal zone (CMZ), the region of the growing retina where most new retinoblasts are formed. In addition, As-Rx1 is expressed in the outer nuclear layer (ONL) of the retina, which contains the photoreceptor cells, and As-Vsx2 is expressed in the inner nuclear layer, probably in the bipolar cells. With the exception of reduced As-Rx-1 expression in the ONL, the As-Rx1 and As-Vsx2 expression patterns were unchanged in the developing retina of two different cavefish populations, suggesting that cell proliferation is not inhibited. These results were confirmed by using PCNA and BrdU markers for retinal cell division. We conclude that the CMZ is active in cell proliferation long after eye growth is diminished and is therefore not the major cause of eye degeneration.     

Amphioxus and ascidian Dmbx homeobox genes give clues to the vertebrate origins of midbrain development

The ancestral chordate neural tube had a tripartite structure, comprising anterior, midbrain-hindbrain boundary (MHB) and posterior regions. The most anterior region encompasses both forebrain and midbrain in vertebrates. It is not clear when or how the distinction between these two functionally and developmentally distinct regions arose in evolution. Recently, we reported a mouse PRD-class homeobox gene, Dmbx1, expressed in the presumptive midbrain at early developmental stages, and the hindbrain at later stages, with exclusion from the MHB. This gene provides a route to investigate the evolution of midbrain development. We report the cloning, genomic structure, phylogeny and embryonic expression of Dmbx genes from amphioxus and from Ciona, representing the two most closely related lineages to the vertebrates. Our analyses show that Dmbx genes form a distinct, ancient, homeobox gene family, with highly conserved sequence and genomic organisation, albeit more divergent in Ciona. In amphioxus, no Dmbx expression is observed in the neural tube, supporting previous arguments that the MHB equivalent region has been secondarily modified in evolution. In Ciona, the CiDmbx gene is detected in neural cells caudal to Pax2/5/8-positive cells (MHB homologue), in the Hox-positive region, but, interestingly, not in any cells rostral to them. These results suggest that a midbrain homologue is missing in Ciona, and argue that midbrain development is a novelty that evolved specifically on the vertebrate lineage. We discuss the evolution of midbrain development in relation to the ancestry of the tripartite neural ground plan and the origin of the MHB organiser.     

Loss and gain of domains during evolution of cut superclass homeobox genes

The cut superclass of homeobox genes has been divided into three classes: CUX, ONECUT and SATB. Given the various completed genomes, we have now made a comprehensive survey. We find that there are only two cut domain containing genes in Drosophila, one CUX and one ONECUT type. Caenorhabditis elegans has undergone an expansion of the ONECUT subclass genes and has a gene cluster with three ONECUT class genes, one of which has lost the cut domain. Two of these genes contain a conserved sequence motif, termed OCAM, which also occurs in another gene in C. elegans this motif seems to be nematode specific. A recently uncovered C. elegans CUX gene has sequence conservation in its amino-terminus with vertebrate CUX proteins. Further, the 5' end of this gene containing the conserved region can undergo alternative splicing to give rise to a protein with a different carboxy-terminus lacking the cut- and homeodomain. This protein is conserved in its entirety with vertebrate genes termed CASP--which are also alternative splice products of the CUX genes--and with plant and fungal genes. The highly divergent SATB genes share a conserved amino terminal domain, COMPASS, with the Drosophila defective proventriculus gene and a C. elegans ORF. These two "COMPASS" family genes encode two highly divergent homeodomains, may be homologues of the SATB genes and thus probably belong to the cut superclass, too.     

Homeobox genes in vertebrate evolution.

A wide range of anatomical features are shared by all vertebrates, but absent in our closest invertebrate relatives. The origin of vertebrate embryogenesis must have involved the evolution of new regulatory pathways to control the development of new features, but how did this occur? Mutations affecting regulatory genes, including those containing homeobox sequences, may have been important: for example, perhaps gene duplications allowed recruitment of genes to new roles. Here I ask whether comparative data on the genomic organization and expression patterns of homeobox genes support this hypothesis. I propose a model in which duplications of particular homeobox genes, followed by the acquisition of gene-specific secondary expression domains, allowed the evolution of the neural crest, extensive organogenesis and craniofacial morphogenesis. Specific details of the model are amenable to testing by extension of this comparative approach to molecular embryology.     

Gradient fields and homeobox genes.

We review here old experiments that defined the existence of morphogenetic gradient fields in vertebrate embryos. The rather abstract idea of cell fields of organ-forming potential has become less popular among modern developmental and molecular biologists. Results obtained with antibodies directed against homeodomain proteins suggest that gradient fields may indeed be visualized at the level of individual regulatory molecules in vertebrate embryos.     

The role of Wnt genes in vertebrate development.

Over the past decade, many potential candidates for molecules involved in pattern formation in the vertebrate embryo have been identified. Manipulation of the expression of some of these factors has generated fascinating results that have allowed investigators to address their roles in embryogenesis. One such family consists of a group of putative cell signaling molecules related to the proto-oncogene Wnt-1. An accumulating body of evidence suggests that the Wnt-family plays a major role in several aspects of vertebrate development.