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.     

The murine genes Hox-5.1 and Hox-4.1 belong to the same HOX complex on chromosome 2

Two different loci of Antennapedia-related homeobox-containing genes have been shown to map to mouse chromosome 2: the HOX-5 complex and the Hox-4.1 gene. These independently derived loci are likely to be parts of a single gene complex, although their close linkage has not yet been demonstrated. Since cosmid walks to extend the HOX-5 cluster and to potentially link the two loci were unsuccessful, we have used large restriction fragments separated by pulsed-field gel electrophoresis to demonstrate the linkage between probes from the HOX-5 region and sequences near Hox-4.1. To further define the distance between the two linked loci, we screened a NotI jumping library with sequences near the Hox-5.1 gene to obtain a marker within the region predicted to contain Hox-4.1. The jumping endpoint lies within genomic clones from a lambda phage walk extending from the 5' end of Hox-4.1, and thus provides clear evidence of linkage between the two Hox loci. Our results demonstrate that Hox-4.1 lies approximately 35 kb downstream of the Hox-5.1 gene and that the two loci do indeed thus constitute parts of the same HOX complex.     

Sequence and embryonic expression of the murine Hox-3.5 gene.

The murine Hox-3.5 gene has been mapped and linked genomically to a position 18 kb 3' of its most 5' locus neighbour, Hox-3.4, on chromosome 15. The sequence of the Hox-3.5 cDNA, together with the position of the gene within the locus, show it to be a paralogue of Hox-2.6, Hox-1.4 and Hox-4.2. The patterns of embryonic expression for the Hox-3.5 gene are examined in terms of three rules, proposed to relate a Hox gene's expression pattern to its position within the locus. The anterior boundaries of Hox-3.5 expression in the hindbrain and prevertebral column lie anterior to those of Hox-3.4 and all other, more 5'-located Hox-3 genes. Within the hindbrain, the Hox-3.5 boundary is seen to lie posterior to that of its paralogue, Hox-2.6, by a distance equal to about the length of one rhombomere. Patterns of Hox-3.5 expression within the oesophagus and spinal cord, but not the testis, are similar to those of other Hox-3 genes, Hox-3.3 and Hox-3.4.     

Isolation and analysis of embryonic expression of Hox-4.9, a member of the murine labial-like gene family.

Two members of the murine labial (lab) subfamily of Antennapedia-like homeobox-containing genes, Hox-1.6 and Hox-2.9, have been identified previously. Here we describe a third member genetically linked to the Hox-4 cluster on chromosome 2. This gene, designated Hox-4.9, is similar in structure to the other lab subfamily members. However, little coding sequence other than the homeobox and sequences immediately upstream of it have been conserved. By in situ hybridization analysis, Hox-4.9 mRNA is first detected at the end of the late streak stage (E7.75) in presumptive lateral and extraembryonic mesoderm. During early neurogenesis (E8.0-8.5), Hox-4.9 is detected solely in lateral mesoderm; its lack of expression in somitic mesoderm and the neural tube makes it unique among the Hox genes. By late neurogenesis and through mid-gestation (E9.0-E11.5), Hox-4.9 is no longer detected in lateral mesoderm but is found instead in a restricted region of presumed trunk neural crest and in the dermatome. These data are discussed in comparison with what is known about expression of the other members of the lab subfamily.     

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.     

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.     

Exogenous retinoic acid rapidly induces anterior ectopic expression of murine Hox-2 genes in vivo.

Exogenous retinoic acid (RA) has teratogenic effects on vertebrate embryos and alters Hox-C gene expression in vivo and in vitro. We wish to examine whether RA has a role in the normal regulation of Hox-C genes, and whether altered Hox-C gene expression in response to RA leads to abnormal morphology. The expression of 3' Hox-2 genes (Hox-2.9, Hox-2.8, Hox-2.6 and Hox-2.1) and a 5' gene (Hox-2.5) were examined by whole-mount in situ hybridization on embryos 4 hours after maternal administration of teratogenic doses of RA on embryonic day 7 to 9. The expression of the 3' Hox-2 genes was found to be ectopically induced in anterior regions in a stage-specific manner. The Hox-2.9 and Hox-2.8 genes were induced anteriorly in the neurectoderm in response to RA on day 7 but not at later stages. Expression of Hox-2.6 and Hox-2.1 was ectopically induced anteriorly in neurectoderm in response to RA on day 8. Hox-2.1 remained responsive on day 9, whereas Hox-2.6 was no longer responsive at this stage. The expression of the 5' gene Hox-2.5 was not detectably altered at any of these stages by RA treatments. We also examined the response of other genes whose expression is spatially regulated in early embryos. The expression of En-2 and Wnt-7b was not detectably altered by RA, whereas RAR beta expression was induced anteriorly by RA on day 7 and 8. Krox-20 expression was reduced in a stage- and region-specific manner by RA. The ectopic anterior expression of Hox-2.8 and Hox-2.9 induced by RA on day 7 was persistent to day 8, as was the altered expression of Krox-20. The altered pattern of expression of these genes in response to RA treatment on day 7 may be indicative of a transformation of anterior hindbrain to posterior hindbrain, specifically, a transformation of rhombomeres 1 to 3 towards rhombomere 4 identity with an anterior expansion of rhombomere 5. The ectopic expression of the 3' Hox-2 genes in response to RA is consistent with a role for these genes in mediating the teratogenic effects of RA; the rapid response of the Hox-C genes to RA is consistent with a role for endogenous RA in refining 3' Hox-C gene expression boundaries early in development.     

Expression of Hox-2.4 homeobox gene directed by proviral insertion in a myeloid leukemia.

The presence of an altered Hox-2.4 gene in the WEHI3B murine myeloid leukemia suggests that homeobox genes may contribute to neoplasia. A survey of 31 leukemia cell lines of the myeloid, lymphoid and erythroid lineages revealed that Hox-2.4 was expressed only in WEHI3B and the pre-B lymphoid line 70Z/3, in which no DNA rearrangement was observed. To clarify the WEHI3B alteration and normal Hox-2.4 structure, we have sequenced near full length cDNA clones from WEHI3B and 70Z/3, and the 5' portion of the normal Hox-2.4 gene. A WEHI3B cDNA clone demonstrates that an intracisternal A-particle (IAP) provirus has inserted within the first exon of the gene and generated a Hox-2.4 mRNA with a 5' sequence derived from the IAP long terminal repeat. A remarkable degree of similarity found between the amino acid sequences of Hox-2.4 and Hox-3.1, which reside on different chromosomes, supports the notion that an ancient homeobox gene cluster has been duplicated and dispersed early in vertebrate evolution.     

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.     

Identification of a retinoic acid response element upstream of the murine Hox-4.2 gene.

Hox genes play an important role in the process of vertebrate pattern formation, and their expression is intricately regulated both temporally and spatially. All-trans-retinoic acid (RA), a physiologically active metabolite of vitamin A, affects the expression of a large number of Hox genes in vitro and in vivo. However, the regulatory mechanisms underlying the RA response of these genes have not been extensively studied, and no response element for RA receptors (RARs) has been characterized in a Hox regulatory region. The expression of murine Hox-4.2 and its human homolog, HOX4B, is increased in embryonal carcinoma (EC) cell lines upon RA treatment (M. S. Featherstone, A. Baron, S. J. Gaunt, M.-G. Mattei, and D. Duboule, Proc. Natl. Acad. Sci. USA 85:4760-4764, 1988; A. Simeone, D. Acampora, V. Nigro, A. Faiella, M. D'Esposito, A. Stornaiuolo, F. Mavilio, and E. Boncinelli, Mech. Dev. 33:215-228, 1991). Using transient expression assays, we showed that luciferase reporter gene constructs carrying genomic sequences located upstream of Hox-4.2 responded to RA in murine P19 EC cells. A 402-bp NcoI fragment was necessary for the RA responsiveness of reporter constructs. This fragment contained a regulatory element, 5'-AGGTGA(N)5AGGTCA-3', that closely resembles the consensus sequence for an RA response element. The Hox-4.2 RA response element was critical for the RA induction and specifically bound RARs. In addition, the response to RA could be inhibited by expressing a dominant negative form of RAR alpha in transfected P19 EC cells. These results suggested that Hox-4.2 is a target for RAR-mediated regulation by RA.     

Primary structure and embryonic expression pattern of the mouse Hox-4.3 homeobox gene

We report the cloning, genomic localization, primary structure and developmental expression pattern of the novel mouse Hox-4.3 gene. This gene is located within the HOX-4(5) complex, at a position which classifies it as a member of the Hox-3.1 and -2.4 subfamily, the DNA and predicted protein sequences further confirmed this classification. Hox-4.3 has a primary structure characteristic of a Hox gene but, in addition, contains several monotonic stretches of amino acids, one of the 'paired'-like type. As expected from its presence and position within the complex. Hox-4.3 is developmentally expressed in structures of either mesodermal or neurectodermal origin located or derived from below a precise craniocaudal level. However, a very important offset between anteroposterior boundaries within neuroectoderm versus mesoderm derivatives is observed. Like other genes of the HOX-4(5) complex, Hox-4.3 is expressed in developing limbs and gonads, suggesting that 'cluster specificity' could be a feature of the HOX network.