Hmx2 homeobox gene control of murine vestibular morphogenesis.

Development of the vertebrate inner ear is characterized by a series of genetically programmed events involving induction of surface ectoderm, preliminary morphogenesis, specification and commitment of sensory, nonsensory and neuronal cells, as well as outgrowth and restructuring of the otocyst to form a complex labyrinth. Hmx2, a member of the Hmx homeobox gene family, is coexpressed with Hmx3 in the dorsolateral otic epithelium. Targeted disruption of Hmx2 in mice demonstrates the temporal and spatial involvement of Hmx2 in the embryonic transition of the dorsal portion (pars superior) of the otocyst to a fully developed vestibular system. In Hmx2 null embryos, a perturbation in cell fate determination in the lateral aspect of the otic epithelium results in reduced cell proliferation in epithelial cells, which includes the vestibular sensory patches and semicircular duct fusion plates, as well as in the adjacent mesenchyme. Consequently, enlargement and morphogenesis of the pars superior of the otocyst to form a complex labyrinth of cavities and ducts is blocked, as indicated by the lack of any distinguishable semicircular ducts, persistence of the primordial vestibular diverticula, significant loss in the three cristae and the macula utriculus, and a fused utriculosaccular chamber. The developmental regulators Bmp4, Dlx5 and Pax2 all play a critical role in inner ear ontogeny, and the expression of each of these genes is affected in the Hmx2 null otocyst suggesting a complex regulatory role for Hmx2 in this genetic cascade. Both Hmx2 and Hmx3 transcripts are coexpressed in the developing central nervous system including the neural tube and hypothalamus. A lack of defects in the CNS, coupled with the fact that not all of the Hmx2-positive regions in developing inner ear are impaired in the Hmx2 null mice, suggest that Hmx2 and Hmx3 have both unique and overlapping functions during embryogenesis.

Hmx: an evolutionary conserved homeobox gene family expressed in the developing nervous system in mice and Drosophila.

Three homeobox genes, one from Drosophila melanogaster (Drosophila Hmx gene) and two from mouse (murine Hmx2 and Hmx3) were isolated and the full-length cDNAs and corresponding genomic structures were characterized. The striking homeodomain similarity encoded by these three genes to previously identified genes in sea urchin, chick and human, as well as the recently cloned murine Hmx1 gene, and the low homology to other homeobox genes indicate that the Hmx genes comprise a novel gene family. The widespread existence of Hmx genes in the animal kingdom suggests that this gene family is of ancient origin. Drosophila Hmx was mapped to the 90B5 region of Chromosome 3 and at early embryonic stages is primarily expressed in distinct areas of the neuroectoderm and subsets of neuroblasts in the developing fly brain. Later its expression continues in rostral areas of the brain in a segmented pattern, suggesting a putative role in the development of the Drosophila central nervous system. During evolution, mouse Hmx2 and Hmx3 may have retained a primary function in central nervous system development as suggested by their expression in the postmitotic cells of the neural tube, as well as in the hypothalamus, the mesencephalon, metencephalon and discrete regions in the myelencephalon during embryogenesis. Hmx1 has diverged from other Hmx members by its expression in the dorsal root, sympathetic and vagal nerve (X) ganglia. Aside from their expression in the developing nervous system, all three Hmx genes display expression in sensory organ development, and in the adult uterus. Hmx2 and Hmx3 show identical expression in the otic vesicle, whereas Hmx1 is strongly expressed in the developing eye. Transgenic mouse lines were generated to examine the DNA regulatory elements controlling Hmx2 and Hmx3. Transgenic constructs spanning more than 31 kb of genomic DNA gave reproducible expression patterns in the developing central and peripheral nervous systems, eye, ear and other tissues, yet failed to fully recapitulate the endogenous expression pattern of either Hmx2 or Hmx3, suggesting both the presence and absence of certain critical enhancers in the transgenes, or the requirement of proximal enhancers to work synergistically.

The murine Otp homeobox gene plays an essential role in the specification of neuronal cell lineages in the developing hypothalamus.

Hypothalamic nuclei, including the anterior periventricular (aPV), paraventricular (PVN), and supraoptic (SON) nuclei strongly express the homeobox gene Orthopedia (Otp) during embryogenesis. Targeted inactivation of Otp in the mouse results in the loss of these nuclei in the homozygous null neonates. The Otp null hypothalamus fails to secrete neuropeptides somatostatin, arginine vasopressin, oxytocin, corticotropin-releasing hormone, and thyrotropin-releasing hormone in an appropriate spatial and temporal fashion, and leads to the death of Otp null pups shortly after birth. Failure to produce these neuropeptide hormones is evident prior to E15.5, indicating a failure in terminal differentiation of the aPV/PVN/SON neurons. Absence of elevated apoptotic activity, but reduced cell proliferation together with the ectopic activation of Six3 expression in the presumptive PVN, indicates a critical role for Otp in terminal differentiation and maturation of these neuroendocrine cell lineages. Otp employs distinct regulatory mechanisms to modulate the expression of specific molecular markers in the developing hypothalamus. At early embryonic stages, expression of Sim2 is immediately downregulated as a result of the absence of Otp, indicating a potential role for Otp as an upstream regulator of Sim2. In contrast, the regulation of Brn4 which is also expressed in the SON and PVN is independent of Otp function. Hence no strong evidence links Otp and Brn4 in the same regulatory pathway. The involvement of Otp and Sim1 in specifying specific hypothalamic neurosecretory cell lineages is shown to operate via distinct signaling pathways that partially overlap with Brn2.

Mapping and developmental expression analysis of the WD-repeat gene Preb.

We have isolated from mouse a novel WD-motif-containing gene designated Preb. This gene encodes a predicted protein of 416 amino acids and has significant homology with other members of the WD-motif gene superfamily that play a role in cell fate determination. Preb maps to the proximal end of chromosome 5 in mouse, near the Hmx1 homeobox gene. Preb is detectable in early stage embryos in the peripheral nervous system, developing liver, and surface ectoderm. Later, Preb is expressed in the anterior portion of Rathke's pouch, which gives rise to the anterior pituitary, the organ responsible for the production of prolactin and other hormones. In midgestation embryos, the most extensive expression of Preb is observed in the perichondrium of the craniofacial, axial, and appendicular skeleton. The expression pattern of Preb in murine embryos suggests a potential role in the specification of multiple cell types, in particular, the fetal skeleton.

The murine Bapx1 homeobox gene plays a critical role in embryonic development of the axial skeleton and spleen.

Our previous studies in both mouse and human identified the Bapx1 homeobox gene, a member of the NK gene family, as one of the earliest markers for prechondrogenic cells that will subsequently undergo mesenchymal condensation, cartilage production and, finally, endochondral bone formation. In addition, Bapx1 is an early developmental marker for splanchnic mesoderm, consistent with a role in visceral mesoderm specification, a function performed by its homologue bagpipe, in Drosophila. The human homologue of Bapx1 has been identified and mapped to 4p16.1, a region containing loci for several skeletal diseases. Bapx1 null mice are affected by a perinatal lethal skeletal dysplasia and asplenia, with severe malformation or absence of specific bones of the vertebral column and cranial bones of mesodermal origin, with the most severely affected skeletal elements corresponding to ventral structures associated with the notochord. We provide evidence that the failure of the formation of skeletal elements in Bapx1 null embryos is a consequence of a failure of cartilage development, as demonstrated by downregulation of several molecular markers required for normal chondroblast differentiation (&agr; 1(II) collagen, Fgfr3, Osf2, Indian hedgehog, Sox9), as well as a chondrocyte-specific alpha1 (II) collagen-lacZ transgene. The cartilage defects are correlated with failed differentiation of the sclerotome at the time when these cells are normally initiating chondrogenesis. Loss of Bapx1 is accompanied by an increase in apoptotic cell death in affected tissues, although cell cycling rates are unaltered.

Mammalian Dlx homeobox gene control of craniofacial and inner ear morphogenesis.

The Dlx homeobox gene family is of ancient origin, with apparent ancestral developmental functions in both nervous system regionalization and appendage (limb) outgrowth. Additional roles in inner ear and craniofacial development were likely acquired by the Dlx gene family during the course of animal evolution. Loss-of-function genetic mutations generated in the mouse have revealed a striking role for Dlx genes in patterning of the mammalian central nervous system, craniofacial structures and inner ear. Interestingly, none of the individual murine Dlx gene mutations to date have resulted in limb defects, suggesting a potentially significant developmental overlap of Dlx activity in this embryonic structure. J. Cell. Biochem. Suppls. 32/33:133-140, 1999.

Inner ear and maternal reproductive defects in mice lacking the Hmx3 homeobox gene.

The Hmx homeobox gene family is of ancient origin, being present in species as diverse as Drosophila, sea urchin and mammals. The three members of the murine Hmx family, designated Hmx1, Hmx2 and Hmx3, are expressed in tissues that suggest a common functional role in sensory organ development and pregnancy. Hmx3 is one of the earliest markers for vestibular inner ear development during embryogenesis, and is also upregulated in the myometrium of the uterus during pregnancy. Targeted disruption of the Hmx3 gene results in mice with abnormal circling behavior and severe vestibular defects owing to a depletion of sensory cells in the saccule and utricle, and a complete loss of the horizontal semicircular canal crista, as well as a fusion of the utricle and saccule endolymphatic spaces into a common utriculosaccular cavity. Both the sensory and secretory epithelium of the cochlear duct appear normal in the Hmx3 null animals. The majority of Hmx3 null females have a reproductive defect. Hmx3 null females can be fertilized and their embryos undergo normal preimplantation development, but the embryos fail to implant successfully in the Hmx3 null uterus and subsequently die. Transfer of preimplantation embryos from mutant Hmx3 uterine horns to wild-type pseudopregnant females results in successful pregnancy, indicating a failure of the Hmx3 null uterus to support normal post-implantation pregnancy. Molecular analysis revealed the perturbation of Hmx, Wnt and LIF gene expression in the Hmx3 null uterus. Interestingly, expression of both Hmx1 and Hmx2 is downregulated in the Hmx3 null uterus, suggesting a hierarchical relationship among the three Hmx genes during pregnancy.

Bapx1: an evolutionary conserved homologue of the Drosophila bagpipe homeobox gene is expressed in splanchnic mesoderm and the embryonic skeleton.

In Drosophila, the visceral mesoderm giving rise to gut musculature is specified by the bagpipe homeobox gene. We have isolated, from both mouse and human, homologues of the bagpipe gene designated Bapx1 and BAPX1, respectively. Bapx1 encodes a predicted protein of 333 amino acids, and has significant regions of homology outside the homeodomain with members of the NK homeobox gene superfamily. Bapx1 maps to the proximal end of chromosome 5 in mouse, near the Msx1 gene. The syntenic region in human corresponds to a chromosomal region containing loci for several skeletal disorders. Bapx1 is first detectable in embryos just prior to axis rotation in lateral plate mesoderm (splanchnic mesoderm) adjacent to the endodermal lining of the prospective gut, and in the most newly formed somites in the region corresponding to the presclerotome, the precursor of the vertebrae. Thus, Bapx1 is one of the earliest developmental markers for the sclerotome portion of the somite and the gut mesentery. Bapx1 continues to be expressed well into organogenesis in lateral plate mesoderm surrounding the mid- and hindgut, and in essentially all cartilaginous condensations which will subsequently undergo endochondral bone formation. The expression pattern of Bapx1 in murine embryos suggests that there are evolutionary conserved mechanisms of visceral mesoderm development across the animal kingdom, and that the mammalian Bapx1 gene may have recently acquired an additional developmental role in skeletal patterning.

Transcriptional regulation of vertebrate Hox genes during embryogenesis.

The identification in transgenic mice of Hox gene DNA regulatory elements that can recapitulate certain aspects of the endogenous gene's expression pattern has proceeded with great success. However, perfect reproduction of the correct expression pattern is uncommon, even when large genomic fragments spanning neighboring genes are analyzed, suggesting that important regulatory regions may be located at large distances from the genes they control or that their specific context may be important. Currently, four groups of transcriptional regulators have been identified that have been shown to directly regulate Hox gene expression in the vertebrate embryo: retinoic acid receptors, Krox20, members of the Pbx/exd family, and the Hox genes themselves.

Molecular cloning, chromosomal mapping and developmental expression of BAPX1, a novel human homeobox-containing gene homologous to Drosophila bagpipe.

We describe here the cloning of the human BAPX1 gene, a homologue of the Drosophila bagpipe gene which has 87% aa identity within the homeodomain relative to the fly gene. We recently have identified the murine bagpipe homolog. The predicted aa sequence of the human gene has 85% overall identity to the murine gene, with 100% identity in the homeodomain. In mouse, this gene maps to the proximal portion of chromosome 5. We show that the human gene maps to 4p16.1, the human region syntenic with mouse chromosome 5. Expression of BAPX1 was evaluated during human embryonic development by RT-PCR analysis and by RNA in situ hybridization. RT-PCR analysis showed that BAPX1 is expressed in embryo tissues, particularly the limb, and at a lower level in an embryonic lung cell line. RNA in situ hybridization revealed that BAPX1 is predominantly expressed in mesenchymal condensations of the fetal limb and axial skeleton, and in lateral plate mesoderm giving rise to visceral muscle. The expression pattern of BAPX1 combined with the chromosomal localization to 4p16.1, where several human genetic diseases involving dysmorphology of the skeleton have been assigned, raises the potential of it being a candidate gene for one of these disorders. O

Dicistronic LacZ and alkaline phosphatase reporter constructs permit simultaneous histological analysis of expression from multiple transgenes.

We report here the development of convenient dicistronic transgenic markers for the rapid and efficient simultaneous analysis of transgene activity in transgenic mice. Two sensitive histological markers, the beta-galactosidase (beta-gal)-encoding lacZ gene and the human placental alkaline phosphatase (hpAP) gene, have been fused to the internal ribosome entry sequence (IRES) from the encephalomyocarditis virus, which directs efficient mRNA cap-independent entry of the translation apparatus in mammalian cells. The IRES permits efficient translation of either lacZ or hpAP when placed anywhere within transgene exonic sequences, including both 5' and 3' untranslated regions. In addition, the production of constructs for transgenic analysis of DNA regulatory elements is greatly facilitated with IRES-lacZ or IRES-hpAP, since the IRES relieves the need for complicated in frame transgene protein fusions to produce a functional beta-gal or hpAP protein.

Nkx2.6 expression is transiently and specifically restricted to the branchial region of pharyngeal-stage mouse embryos.

The Nkx2.6 gene belongs to the NK superfamily of homeobox genes (Harvey, 1996). We report here the expression pattern of the murine Nkx2.6 gene during early mouse development, which is unique among the NK family of homeobox genes in that its expression is restricted to the very narrow development period between stages E8.5 and E10.5 of embryogenesis. The distribution of Nkx2.6 transcripts is also quite restricted spatially, with expression detected uniquely within the caudal branchial arches. Nkx2.6 is expressed in all three layers comprising the caudal branchial arches (ectoderm, mesectoderm and endoderm) with the strongest expression being detected in the surface ectoderm.

Transcriptional control of Hox genes in the vertebrate nervous system.

The identification, in transgenic mice, of Hox gene DNA regulatory elements that can recapitulate certain aspects of the endogenous gene expression pattern has proceeded with great success. Perfect reproduction of the correct expression pattern, however, is uncommon, even when large genomic fragments spanning neighboring genes are analyzed, suggesting that important regulatory regions may be located at large distances from the genes they control or that their specific context may be important. Four classes of transcriptional regulators have been identified recently that have been shown to directly regulate Hox gene expression in the murine nervous system: retinoic acid receptors, Krox20, the Pbx/exd family, and the Hox genes themselves.

Msx3: a novel murine homologue of the Drosophila msh homeobox gene restricted to the dorsal embryonic central nervous system.

We have isolated Msx3, the third member of the murine Msx homeobox gene family which is homologous to the msh gene of Drosophila. The Msx3 cDNA encodes a protein of 204 amino acids which has striking regions of homology in addition to the homeodomain when compared to the other Msx family members. Msx3 maps to the distal end of mouse chromosome 7, thus it is unlinked to either Msx1 or Msx2. RNA in situ analysis of Msx3 gene expression during early development revealed that it is restricted to the dorsal portion of the neural tube with a rostral boundary in the rostral rhombencephalon. This sole expression domain for Msx3 overlaps with both Msx1 and Msx2 at early stages, but in older embryos, Msx3 expression becomes restricted to the ventricular zone of the dorsal neural tube, whereas Msx1 and Msx2 become localized to the non-neuronal roof plate region. The absence of detectable levels of Msx3 expression outside this restricted dorsal region of the developing central nervous system (CNS) is in marked contrast to Msx1 and Msx2, which have extensive expression domains in other embryonic tissues, particularly craniofacial structures and the limbs. By analogy with the expression of msh/Msx genes in other organisms, it is likely that one of the ancestral functions of the msh/Msx gene family is in patterning of the CNS.