Dominant mutation of the murine Hox-2.2 gene results in developmental abnormalities.

Genes carrying the homeobox were originally identified in Drosophila, in which they are now known to play key roles in establishing segmentation patterns and in determining segment identities. A number of genes with striking homology to the Drosophila homeobox genes have now been found in the mouse genome, and mutational analysis is beginning to shed light on their function in mammalian development. To understand better the developmental significance of the murine Hox-2.2 gene, we have generated gain of function mutants by using the chicken beta-actin promoter to drive ubiquitous expression in transgenic mice. The resulting Hox-2.2 misexpression produces early postnatal lethality as well as craniofacial and axial skeletal perturbations that include open eyes at birth, cleft palate, micrognathia, microtia, skull bone deficiencies, and structural and positional alterations in the vertebral column. We repeatedly observe complete or partial absence of the supraoccipital bone and malformations of the exoccipital and the basioccipital bones. These results suggests a role for the Hox-2.2 gene in specifying positional identity along the anterior-posterior axis.     

Hox-3.6: isolation and characterization of a new murine homeobox gene located in the 5' region of the Hox-3 cluster.

Most members of the murine Hox gene system can be grouped into two subclasses based on their structural similarity to either one of the Drosophila homeotic genes Antennapedia (Antp) or Abdominal B (AbdB). All the AbdB-like genes reported thus far are located in the 5' region of their respective cluster. We describe here the isolation, structural characterization and spatio-temporal expression pattern of a new AbdB-like homeobox gene designated Hox-3.6 that is located in the 5' region of the Hox-3 cluster. Hox-3.6 has an extreme posterior expression domain in embryos of 12.5 days of gestation, a feature that has thus far only been observed for the 5' most genes of the Hox-4 cluster. Like the other members of the AbdB subfamily, Hox-3.6 exhibits spatially restricted expression in the hindlimb bud, but the expression domain is antero-proximal in contrast to the postero-distal domain reported for its cognate gene Hox-4.5. Structural analysis of the 5' region revealed the presence of a 35 bp sequence which shares homology and relative 5' position with an upstream sequence present in its two nearest downstream neighbors, Hox-3.2 and -3.1.     

The localization and regulation of Antennapedia protein expression in Drosophila embryos

The homeotic Antennapedia (Antp) gene of Drosophila is required for the normal differentiation of the thoracic segments during embryonic development and metamorphosis. Antibodies to a recombinant Antp protein were used to localize the protein in whole mount embryos. Antp is expressed in the nuclei of cells of the thoracic embryonic epidermis and several segments of the ventral and peripheral nervous systems. Analysis of Antp expression in mutant embryos revealed three levels of Antp regulation by genes of the bithorax complex, pleiotropic homeotic loci, and Antp itself. The distributions of the Antp and the Ultrabithorax (Ubx) proteins in doubly-labeled embryos suggest that the Ubx protein may be one direct negative regulator of Antp gene expression.     

The murine and Drosophila homeobox gene complexes have common features of organization and expression

In situ hybridization analysis of mouse embryos shows the seven members of the Hox-2 complex to be differentially expressed in the central and peripheral nervous system and in mesodermal derivatives (somites and lung). Beginning at the 5' end of the cluster, each successive gene displays a more anterior boundary of expression in the central nervous system. A gene's position in the Hox-2 cluster therefore reflects its relative domain of expression along the anteroposterior axis of the embryo, a feature observed with Drosophila homeotic genes. Sequence comparisons of the Hox-2 cluster with other mouse and Drosophila homeobox genes have defined subgroups of related genes; in the mouse there are four clusters related by duplication and divergence. Alignment shows a clear relationship among genes in the mouse and Drosophila complexes, based on relative position, sequence identity, and domains of expression along the rostral-caudal axis. Our results argue that these complexes arose from a common ancestor, present before the divergence of lineages that gave rise to arthropods and vertebrates.     

Direct control of antennal identity by the spineless-aristapedia gene of Drosophila

Loss-of-function mutations in the spineless-aristapedia gene of Drosophila (ssa mutants) cause transformations of the distal antenna to distal second leg, deletions or fusions of the tarsi from all three legs, a general reduction in bristle size, and sterility. Because ssa mutants are pleiotropic, it has been suggested that ss+ has some rather general function and that the ssa antennal transformation is an indirect consequence of perturbations in the expression of other genes that more directly control antennal or second leg identity. Here we test whether the ssa transformation results from aberrant expression of Antennapedia (Antp), a homeotic gene thought to specify directly the identity of the second thoracic segment. We find that Antp-ssa mitotic recombination clones in the distal antenna behave identically to Antp+ ssa clones, and are transformed to second leg. This demonstrates that the ssa antennal transformation is independent of Antp+, and suggests that ss+ may itself directly define distal antennal identity. The results also reveal that Antp+ is not required for the development of distal second leg structures, as these develop apparently normally in Antp- ssa antennal clones. Because Antp- mutations cause deletions or transformations that are restricted to proximal structures, whereas ssa alleles cause similar defects that are distally restricted, we suggest that ss+ and Antp+ may play similar, but complementary, roles in the distal and proximal portions of appendages, respectively.     

Sequence analysis of the homeobox-containing exon of the murine Hox-4.3 homeogene.

A homeobox-containing gene * was detected by Southern analysis of a cosmid spanning a region of the murine HOX-4 complex between Hox-4.4 (Hox-5.2) and Hox-4.2 (Hox-5.1) with a probe derived from the Hox-4.2 homeobox. The sequence of a cross-hybridizing region revealed an open reading frame encoding an Antennapedia (Antp) class homeodomain highly homologous to the products of human HOX4C (Hox-5.4/HOX4E), mouse Hox-3.1 and Hox-2.4. This, together with strong conservation of sequences 3' to the homoebox, indicates that we have cloned the murine Hox-4.3 gene. No other homeobox sequences were detected in this screen suggesting that the HOX-4 complex lacks paralogous genes represented in the equivalent regions of other HOX loci.     

Murine genes related to the Drosophila AbdB homeotic genes are sequentially expressed during development of the posterior part of the body.

The cloning, characterization and developmental expression patterns of two novel murine Hox genes, Hox-4.6 and Hox-4.7, are reported. Structural data allow us to classify the four Hox-4 genes located in the most upstream (5') position in the HOX-4 complex as members of a large family of homeogenes related to the Drosophila homeotic gene Abdominal B (AbdB). It therefore appears that these vertebrate genes are derived from a selective amplification of an ancestral gene which gave rise, during evolution, to the most posterior of the insect homeotic genes so far described. In agreement with the structural colinearity, these genes have very posteriorly restricted expression profiles. In addition, their developmental expression is temporally regulated according to a cranio-caudal sequence which parallels the physical ordering of these genes along the chromosome. We discuss the phylogenetic alternative in the evolution of genetic complexity by amplifying either genes or regulatory sequences, as exemplified by this system in the mouse and Drosophila. Furthermore, the possible role of 'temporal colinearity' in the ontogeny of all coelomic (metamerized) metazoans showing a temporal anteroposterior morphogenetic progression is addressed.     

Human homeo box-containing genes located at chromosome regions 2q31----2q37 and 12q12----12q13

Four human homeo box-containing cDNAs isolated from mRNA of an SV40-transformed human fibroblast cell line have been regionally localized on the human gene map. One cDNA clone, c10, was found to be nearly identical to the previously mapped Hox-2.1 gene at 17q21. A second cDNA clone, c1, which is 87% homologous to Hox-2.2 at the nucleotide level but is distinct from Hox-2.1 and Hox-2.2, also maps to this region of human chromosome 17 and is probably another member of the Hox-2 cluster of homeo box-containing genes. The third cDNA clone, c8, in which the homeo box is approximately 84% homologous to the mouse Hox-1.1 homeo box region on mouse chromosome 6, maps to chromosome region 12q12----12q13, a region that is involved in chromosome abnormalities in human seminomas and teratomas. The fourth cDNA clone, c13, whose homeo box is approximately 73% homologous to the Hox-2.2 homeo box sequence, is located at chromosome region 2q31----q37. The human homeo box-containing cluster of genes at chromosome region 17q21 is the human cognate of the mouse homeo box-containing gene cluster on mouse chromosome 11. Other mouse homeo box-containing genes of the Antennapedia class (class I) map to mouse chromosomes 6 (Hox-1, proximal to the IgK locus) and 15 (Hox-3). A mouse gene, En-1, with an engrailed-like homeo box (class II) and flanking region maps to mouse chromosome 1 (near the dominant hemimelia gene). Neither of the class I homeo box-containing genes--c8 and c13--maps to a region of obvious homology to chromosomal positions of the presently known mouse homeo box-containing genes.     

The structural and functional organization of the murine HOX gene family resembles that of Drosophila homeotic genes.

This paper reports the cloning of the fourth major murine homeogene complex, HOX-5. The partial characterization of this gene cluster revealed the presence of two novel genes (Hox-5.2, Hox-5.3) located at the 5' extremity of this complex. In situ hybridization experiments showed that these two genes are transcribed in very posterior domains during embryonic and foetal development. We also show that Hox-1.6, the gene located at the 3' most position in the HOX-1 complex, has a very anterior expression boundary during early development. These results clearly support the recently proposed hypothesis that the expression of murine Antp-like homeobox-containing genes along the antero-posterior developing body axis follows a positional hierarchy which reflects their respective physical positions within the HOX clusters, similar to that which is found for the Drosophila homeotic genes. Such a structural and functional organization is likely conserved in most vertebrates. Moreover, on the basis of sequence comparisons, we propose that the ordering of homeobox-containing genes within clusters has been conserved between Drosophila and the house mouse. Thus, very different body plans might be achieved, both in insects and vertebrates, by evolutionarily conserved gene networks possibly displaying similar regulatory interactions.