Craniofacial abnormalities induced by ectopic expression of the homeobox gene Hox-1.1 in transgenic mice

Hox-1.1 is a murine homeobox-containing gene expressed in a time- and cell-specific manner during embryogenesis. We have generated transgenic mice that ectopically express Hox-1.1 from the chicken beta-actin promoter. In these mice Hox-1.1 expression was changed to an almost ubiquitous pattern. Ectopic expression of Hox-1.1 leads to death of the transgenic animals shortly after birth and is associated with multiple craniofacial anomalies, such as cleft palate, open eyes at birth, and nonfused pinnae. This phenotype is similar to the effects seen after systemic administration of retinoic acid during gestation. This suggests that retinoic acid embryopathy and the specific developmental defects caused by ectopic expression of a potential developmental control gene share a common pathogenic mechanism.     

Separate elements cause lineage restriction and specify boundaries of Hox-1.1 expression.

The Hox genes are a class of putative developmental control genes that are thought to be involved in the specification of positional identity along the anteroposterior axis of the vertebrate embryo. It is apparent from their expression pattern that their regulation is dependent upon positional information. In a previous analysis of the Hox-1.1 promoter in transgenic mice, we identified sequences that were sufficient to establish transgene expression in a specific region of the embryo. The construct used, however, did not contain enough regulatory sequences to reproduce all aspects of Hox-1.1 expression. In particular, neither a posterior boundary nor a restriction of expression to prevertebrae was achieved. Here we show correct regulation by Hox-1.1 sequences in transgenic mice and identify the elements responsible for different levels of control. Concomitant with the subdivision of mesodermal cells into different lineages during gastrulation and organogenesis, Hox-1.1 expression is restricted to successively smaller sets of cells. Distinct elements are required at different stages of development to execute this developmental programme. One position-responsive element (130 bp nontranslated leader) was shown to be crucial for the restriction of expression not only along the anteroposterior axis of the embryo, setting the posterior border, but also along the dorsoventral axis of the neural tube and to the lineage giving rise to the prevertebrae. Thus, Hox-1.1 expression is established in a specific region of the embryo and in a specific lineage of the mesoderm by restricting the activity of the promoter by the combined effect of several regulatory elements.     

Ectopic expression of Hox-2.3 induces craniofacial and skeletal malformations in transgenic mice.

To better understand the role of the Hox-2.3 murine homeobox gene during development, a dominant gain-of-function mutation was generated. The developmental malformations that resulted when the chicken beta-actin promoter was used to direct widespread expression of the Hox-2.3 gene in transgenic mice included early postnatal death as well as craniofacial abnormalities, including open eyes and cleft palate. Ventricular septal defects were also observed in the hearts of three transgenic mice. Skeletal malformations were seen in the bones of the craniocervical transition, with the occipital, basisphenoid, and atlas bones deficient or misshapen. Interestingly, one mutant exhibited an extra pair of ribs as well as alterations in cervical vertebrae identities. Some of the malformations observed in Hox-2.3 gain-of-function mutants overlap with those seen in Hox-1.1 and Hox-2.2 misexpression mutants which suggests functional similarities between paralogous homeobox genes. The results of these experiments are consistent with a role for Hox-2.3 in specifying positional information during development.     

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.     

An autoregulatory element of the murine Hox-4.2 gene.

Hox-4.2 promoter activity was assayed by transient expression assays in P19 embryonal carcinoma (EC) cells. Cotransfection of a luciferase reporter gene construct driven by Hox-4.2 upstream sequences with an expression vector for the Hox-4.2 gene product resulted in a 20-fold increase in luciferase activity. This activity was specific in that the Hox-1.6 gene product had no effect in the same assay. Mutational analysis defined a cis-acting element with enhancer function which conferred most of this increase. Activation was largely dependent on two TAAT/ATTA motifs within this 217 bp fragment and HOX-4.2 bound specifically to both of these motifs. The 217 bp element maps within a highly conserved region of the human Hox-4.2 gene (HOX4B) which has been shown to display spatial enhancer activity in mice and flies. These findings suggest a conserved autoregulatory mechanism for the control of Hox-4.2 expression.     

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.     

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.     

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.     

A regulatory region from the mouse Hox-2.2 promoter directs gene expression into developing limbs

To characterize cis-acting regulatory elements of the murine homeobox gene, Hox-2.2, transgenic mouse lines were generated that contained the LacZ reporter gene under the control of different fragments from the presumptive Hox-2.2 promoter. A promoter region of 3600 base pairs (bp) was identified, which reproducibly directed reporter gene expression into specific regions of developing mouse embryos. At 8.5 days postcoitum (p.c.) reporter gene activity was detected in posterior regions of the lateral mesoderm and, in subsequent developmental stages, expression of the LacZ gene was restricted to specific regions of the developing limb buds and the mesenchyme of the ventrolateral body region. This pattern of Hox-2.2-LacZ expression was found in all transgenic embryos that have been generated with the 3.6 kb promoter fragment (two founder embryos and embryos from five transgenic lines). In addition, embryos from two transgenic mouse lines expressed the reporter gene at low levels in the developing central nervous system (CNS). Our results are consistent with the idea that in addition to their presumptive role in CNS and vertebrae development, Hox-2.2 gene products are involved in controlling pattern formation in developing limbs.     

Conditional immortalization of mouse myelomonocytic, megakaryocytic and mast cell progenitors by the Hox-2.4 homeobox gene.

The murine myelomonocytic cell line WEHI-3B exhibits ectopic expression of the genes encoding the homeobox protein, Hox-2.4, and the myeloid growth factor, interleukin-3 (IL-3). We showed previously that concomitant expression of IL-3 and Hox-2.4 in bone marrow cells induced the development of transplantable growth factor-independent tumours resembling the WEHI-3B tumour. We have now investigated the effect of enforced expression of Hox-2.4 alone. Bone marrow cells were infected with Hox-2.4 retrovirus and then either cultured in agar or transplanted into irradiated mice. In vitro, colonies derived from virus-infected cells readily yielded IL-3-dependent, non-tumorigenic cell lines of the myelomonocytic, megakaryocytic and mast cell lineages. Surprisingly, both the establishment and maintenance of these lines required very high concentrations of IL-3 and reduced levels promoted differentiation. Transplanted mice analysed after 3 months appeared normal but their spleen and bone marrow contained abundant provirus-bearing progenitor cells, from which IL-3-dependent long-term cell lines could readily be established in vitro. Four of 18 animals monitored for up to 12 months eventually developed clonal leukaemia, associated in three cases with IL-3 production. Thus ectopic expression of Hox-2.4 enhances self-renewal of immature myeloid progenitors and progression to a fully malignant state is favoured by somatic mutations conferring autocrine production of IL-3.     

Homeosis in the mouse induced by a null mutation in the Hox-3.1 gene.

We have replaced the Hox-3.1 coding sequence with the E. coli lacZ gene by means of homologous recombination in embryonic stem cells and thus produced null mutant mice. Homozygous mice were born alive, but most of them died within a few days. In the trunk region of homozygotes, several skeletal segments were transformed into the likeness of more anterior ones, as observed in Drosophila with loss-of-function homeotic mutations. The most obvious transformations were the attachment of the 8th pair of ribs to the sternum and the appearance of a 14th pair of ribs on the 1st lumbar vertebra. The pattern of beta-galactosidase activity was identical in heterozygotes and homozygotes and reflected faithfully the Hox-3.1 expression pattern. Thus, the mutation modified the identity, rather than the position, of embryonic cells that would normally express Hox-3.1.     

A Mouse Homeo Box Gene, Hox-1.5, and the Morphological Locus, Hd, Map to within 1 Cm on Chromosome 6

Mo-10, a homeo box-containing sequence in the Hox-1 complex of genes referred to as Hox-1.5, was found to be polymorphic in inbred and wild mice, and a strain distribution of three allelic forms of Hox-1.5 are reported. The position of Hox-1.5 was mapped in backcross experiments to within 1 cM of the hypodactyly locus on chromosome 6. This identifies the Hd mutation as a useful model for the examination of homeo box expression during mammalian development.     

Deletion of a homeobox gene in myeloid leukemias with a deletion in chromosome 2

Mouse myeloid leukemias are characterized by a frequent deletion in one chromosome number 2. We now show that there is a deletion of one copy of the Hox-4.1 homeobox gene in the myeloid leukemias with this deletion in chromosome 2. It is suggested that deletion of this homeobox gene plays a role in determining the abnormal developmental program in myeloid leukemia.     

Molecular aspects of regeneration in developing vertebrate limbs.

We review embryological as well as molecular evidence that emphasizes the idea that both the regenerate and the developing vertebrate limb bud utilize a similar set of signals that regulate pattern formation. Evidence is presented to implicate the Hox-7.1 gene in the developmental regulation of growth, differentiation, and positional assignment during limb outgrowth and the proposal is made that the expression of this gene governs the cellular activities within the progress zone during limb outgrowth. Finally, we review the limited information known about the regenerative capabilities of limb buds in organisms that cannot regenerate as adults. We content that a solution to the problem of regenerative failure among higher vertebrates will come progressively through a stepwise analysis of impaired regeneration associated with increasing developmental age.