Mouse Hox-2.2 specifies thoracic segmental identity in Drosophila embryos and larvae

The mouse genome has a number of homeobox genes that are structurally similar to the Drosophila Antenapedia (Antp) gene. We find that one of the mouse Antp-like genes, Hox-2.2, when expressed in developing Drosophila cells under control of a heat shock promoter, can induce homeotic transformations that are nearly identical to those caused by ectopic expression of Antp. In larvae, the Hox-2.2-induced transformations include thoracic denticle belts in place of head structures; in adults, the Hox-2.2 transformations include thoracic legs in place of antennae. The phenotypic effects of Hox-2.2 do not depend on the endogenous Antp gene, whose spatial limits of expression are unaffected by Hox-2.2 expression. Thus, in the Drosophila embryo, Hox-2.2 can substitute for some of the segmental identity functions of Antp, presumably by regulating the same set of downstream genes.     

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.     

DNA rearrangement of a homeobox gene in myeloid leukaemic cells.

A homeobox gene rearrangement has been detected in WEHI-3B mouse myeloid leukaemic cells. The rearranged gene was identified as Hox-2.4 which is a member of the Hox-2 gene cluster on mouse chromosome 11. Both the normal and the rearranged genes were cloned and analysed, and the rearranged genomic Hox-2.4 gene was sequenced. The results indicate that the rearrangement is due to insertion of an intracisternal A particle 5' upstream to Hox-2.4 and that this resulted in constitutive expression of the homeobox gene. It is suggested that constitutive expression of the homeobox gene may interrupt the normal development program in these leukaemic cells.     

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.     

Isolation and regional localization of the murine homeobox-containing gene Hox-3.3 to mouse chromosome region 15E

A murine homeobox-containing cDNA clone has been isolated from an adult spinal cord library. Using in situ hybridization and somatic cell genetics techniques, the newly isolated homeobox gene has been mapped to mouse chromosome region 15E. Because of its chromosomal location, we called this gene locus Hox-3.3. Nucleotide sequence analysis revealed that the Hox-3.3 gene represents the murine cognate of the human homeobox gene c8. The presumptive organization of the murine Hox-3 homeobox gene cluster is discussed.     

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.