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

The mouse Hox-1.3 gene is functionally equivalent to the Drosophila Sex combs reduced gene

To test whether the mouse Hox-1.3 gene is a cognate of the Drosophila Sex combs reduced (Scr) gene, we inserted a hsp 70-Hox-1.3 fusion gene into the Drosophila genome. Transgenic flies displayed Scr-like homeotic transformations after ectopic expression of Hox-1.3 induced by heat shock. In larvae, the thoracic segments T2 and T3 are transformed toward T1. In adults, head structures are dramatically disrupted, including transformation of antenna towards leg. Transformations are not the result of ectopic activation of the endogenous Scr gene. Rather, Hox-1.3 appears to directly regulate Scr target genes, as demonstrated by the ectopic activation of fork head by Hox-1.3. The results suggest that mouse Hox-1.3 cannot only substitute functionally for Drosophila Scr in the determination of external structures but also can participate in the regulatory hierarchy of insect organogenesis.

The mouse Dlx-2 (Tes-1) gene is expressed in spatially restricted domains of the forebrain, face and limbs in midgestation mouse embryos

The pattern of RNA expression of the murine Dlx-2 (Tes-1) homeobox gene is described in embryos ranging in age from E8.5 through E11.5. Dlx-2 is a vertebrate homologue of the Drosophila Distal-less (Dll) gene. Dll expression in the Drosophila embryo is principally limited to the primordia of the brain, head and limbs. Dlx-2 is also expressed principally in the primordia of the forebrain, head and limbs. Within these regions it is expressed in spatially restricted domains. These include two discontinuous regions of the forebrain (basal telencephalon and ventral diencephalon), the branchial arches, facial ectoderm, cranial ganglia and limb ectoderm. Several mouse and human disorders have phenotypes which potentially are the result of mutations in the Dlx genes.

A new Drosophila homeobox gene, bsh, is expressed in a subset of brain cells during embryogenesis

Homeobox genes have been shown to control the determination of positional, tissue and cellular identity during the development of the fruitfly Drosophila melanogaster. Because genes involved in the determination of internal structures derived from neural, mesodermal and endodermal tissues may have been overlooked in conventional genetic screens, we undertook the identification of new homeobox genes expressed in these internal tissues. Here we describe the characterization of one of these new Drosophila homeobox genes, called brain-specific-homeobox (bsh). In embryos, bsh is expressed exclusively in the brain. bsh protein accumulates in approximately 30 cells in each brain hemisphere. One of these bsh expressing cells is closely associated with the terminus of the larval visual nerve (Bolwig's nerve). While deletions of chromosomal interval containing the bsh gene show no dramatic changes in embryonic brain morphology, the expression pattern of the bsh gene suggests that it may play a highly specialized role in the determination and function of cell type in the Drosophila brain.

Altering the boundaries of Hox3.1 expression: evidence for antipodal gene regulation

To investigate the function of region-specific patterns of mouse homeobox gene expression during embryogenesis, we programmed a minimal change in the distribution of Hox3.1 transcripts along the anteroposterior body axis in transgenic mice. Regulatory sequences from Hox1.4, a gene normally expressed more anteriorly than Hox3.1, were chosen to direct expression of a Hox3.1 transgene. Offspring of independent transgenic lines expressed the transgene more anteriorly than the Hox3.1 gene. Rather than predicted posterior transformations, we observed anterior transformations of vertebrae in newborn mice. Transgenic mice also developed profound gastrointestinal tissue malformations, which may provide a molecular explanation for human developmental disorders often involving these same two regions. Paradoxically, vertebral transformations in the transgenic mice were strikingly similar to those reported in mice homozygous for a null mutation of the Hox3.1 gene. This observation suggests that Hox genes may be regulated antipodally, with over- or underexpression resulting in similar phenotypes.

Colinearity in the Xenopus laevis Hox-2 complex

Here we describe experiments detailing the developmental expression, and the inducibility by all-trans retinoic acid (RA) of six members of the Xenopus Hox-2 complex of homeobox-containing genes. We first report the cloning and characterisation of two novel Xenopus Hox-2 genes (Xhox2.7 and Xhox2.9), and provide evidence that the six genes studied are indeed closely linked in the same chromosomal complex. We next show that all six genes are expressed in a spatial sequence which is colinear with their putative 3' to 5' chromosomal sequence and that five of them are also expressed in a 3' to 5' colinear temporal sequence. The sixth gene (Xhox2.9) has an exceptional spatial and temporal expression pattern. The six genes all respond to RA by showing altered spatiotemporal expression patterns, and are also hyperinduced by RA, with a sequence of magnitudes which is colinear with their 3' to 5' chromosomal sequence and with their spatial and temporal expression sequences. Our data also suggest a pre-existing anteroposterior polarity in the embryo's competence to respond to RA. These results complement and extend previous findings made using murine and avian embryos and mammalian cell lines. They suggest a mechanism whereby an endogenous retinoid could help to provide positional information in the early embryo.

Recognition of the surface of a homeo domain protein

Homeo domain proteins exhibit distinct biological functions with specificities that cannot be predicted by their sequence specificities for binding DNA. Recognition of the surface of the Oct-1 POU homeo domain provides a general model for the contribution of selective protein-protein interactions to the functional specificity of the homeo domain family of factors. The assembly of Oct-1 into a multiprotein complex on the herpes simplex virus alpha/IE enhancer is specified by the interactions of its homeo domain with ancillary factors. This complex (C1 complex) is composed of the viral alpha TIF protein (VP16), Oct-1, and one additional cellular component, the C1 factor. Variants of the Oct-1 POU homeo domain were generated by site-directed mutagenesis, which altered the residues predicted to form the exposed surface of the domain-DNA complex. Proteins with single amino acid substitutions on the surface of either helix 1 or 2 of the Oct-1 POU homeo domain had decreased abilities to form the C1 complex. The behavior of these mutants in a cooperative DNA-binding assay with alpha TIF suggested that the Oct-1 POU homeo domain is principally recognized by alpha TIF in the C1 complex. The preferential recognition of Oct-1 over the closely related Oct-2 protein is critically influenced by a single residue on the surface of helix 1 because the introduction of this residue into the Oct-2 POU homeo domain significantly enhanced its ability to form a C1 complex.

The zfh-2 gene product is a potential regulator of neuron-specific dopa decarboxylase gene expression in Drosophila

We have studied a 40-bp upstream regulatory region of the DOPA decarboxylase gene (Ddc) which is important for cell-specific expression in the Drosophila central nervous system (CNS). This region contains two redundant elements which when simultaneously mutated result in lowered DDC expression in serotonin neurons. We uncovered a protein binding site within one of these elements and have cloned a factor which binds to the site. This factor is the product of the zfh-2 gene, a complex homeodomain/zinc finger protein previously identified by binding to an opsin regulatory element. The in vivo profile of ZFH-2 in the larval CNS shows intriguing overlap with DDC in specific serotonin and dopamine neurons. We show that ZFH-2 is related to a human transcription factor ATBF1. The multiple homeodomain and zinc finger motifs in these two proteins show a similar linear arrangement which implies coordinate action among the motifs. In addition, the homology defines a new homeodomain subtype.

deadpan, an essential pan-neural gene in Drosophila, encodes a helix-loop-helix protein similar to the hairy gene product

Neural precursor cells in Drosophila acquire their identity early during their formation. In an attempt to determine whether all neural precursors share a set of genetic machinery, perhaps to control properties of differentiation common to all neurons, we used the enhancer-trap method to identify several genes (pan-neural genes) that are expressed in all neurons and/or their precursors. One of the pan-neural genes is deadpan, which encodes a helix-loop-helix protein closely related to the product of the segmentation gene hairy. The function of deadpan is essential for viability and is likely to be involved in the functional rather than the morphological differentiation of neurons.

The homeobox in perspective

The discovery of the homeobox marks the beginning of a new era in developmental biology in which a class of master control genes, which determine the body plan, have been identified. Their mechanism of action can now be studied at the molecular level and their occurrence seems to be much more universal than originally anticipated.

Cell type dependent transcription regulation by chick homeodomain proteins

Five chick homeodomain proteins (CHOXs), CHOX-1.7, -1.1, -1.4, -4.2 and -2.6, had different transcription-regulating activities in a chick cultured cell line, LMH. In particular, CHOX-1.7 highly activated transcription when NP6 was used as the target site whereas CHOX-1.4 did not. This was mainly due to differences in the activation domains since both proteins bound to NP with almost the same affinities in vitro. In LMH cells, they competitively acted on target gene transcription. Moreover, the strength of the CHOX-1.4 activation domain depended on the cell type. These findings suggest that the effect on a target gene is determined by a combination of CHOXs and cell types.

Low level of Hox1.3 gene expression does not preclude the use of promoterless vectors to generate a targeted gene disruption. off

A variety of experimental approaches have been devised recently to mutate mammalian genes by homologous recombination. In this report, we describe the disruption of the Hox1.3 locus by using two of these approaches, namely, positive-negative selection and activation of a promoterless gene. Interestingly, we observe similarly high frequencies of targeted disruption with both procedures. The high frequency of targeted disruption with a promoterless vector was unexpected given the extremely low level of Hox1.3 expression in the embryonic stem cell line used for these studies. These data indicate that minimal expression of the target gene is required to enrich for homologous recombination events with promoterless vectors and thus enhance the promoterless gene approach as a general strategy to mutate mammalian genes by homologous recombination.

Low level of Hox1.3 gene expression does not preclude the use of promoterless vectors to generate a targeted gene disruption. off

A variety of experimental approaches have been devised recently to mutate mammalian genes by homologous recombination. In this report, we describe the disruption of the Hox1.3 locus by using two of these approaches, namely, positive-negative selection and activation of a promoterless gene. Interestingly, we observe similarly high frequencies of targeted disruption with both procedures. The high frequency of targeted disruption with a promoterless vector was unexpected given the extremely low level of Hox1.3 expression in the embryonic stem cell line used for these studies. These data indicate that minimal expression of the target gene is required to enrich for homologous recombination events with promoterless vectors and thus enhance the promoterless gene approach as a general strategy to mutate mammalian genes by homologous recombination.

Functional dissection of the paired segmentation gene in Drosophila embryos

An ectopic expression assay in Drosophila embryos was used to investigate the roles of pair-rule segmentation genes in the spatial regulation of the segment-polarity gene, engrailed (en). It is hypothesized that the regions of overlap in expression of two genes, paired (prd) and even-skipped (eve), define the odd-numbered en expression stripes. Consistent with this combinatorial model, ectopic expression of prd caused these en stripes to be expanded posteriorly. Surprisingly, however, ectopic expression of a prd gene with a deletion of the conserved paired box resulted in loss of these odd-numbered en stripes. This dominant negative effect is a phenocopy of en expression in prd embryos and suggests that the paired box is necessary for normal prd- function. A similar deletion of odd-numbered en stripes was also observed after ectopic expression of a chimeric fushi tarazu (ftz) gene containing a substituted prd gene homeo box; in addition, in these embryos, the even-numbered en stripes were expanded anteriorly, as observed when the unaltered ftz gene is ectopically expressed. These effects suggest that the chimeric protein may have DNA or protein targets of both the normal Ftz and Prd proteins.

Gastrulation

At gastrulation, a single layer of cells is converted into an outer ectodermal covering, an inner ectodermal tube, and in triploblastic phyla, a middle mesodermal layer. This morphogenesis is driven by motility and directed by cell interactions, some of which involve adhesion and others that involve information transfer.

Isolation and characterization of a novel cDNA clone encoding a homeodomain that is developmentally regulated in the ventral forebrain

A complementary DNA, Tes-1, of a novel homeodomain protein has been cloned, and its pattern of expression has been characterized. It is a structural homolog of Distal-less, a homeodomain-encoding gene in D. melanogaster. Its expression is developmentally regulated and is limited to structures in the head. Within the central nervous system of the midgestation mouse embryo, it is expressed exclusively in the ventral forebrain. It is likely that Tes-1 plays a regulatory role in the development of this complex neural structure.

Regulating the expression and function of homeotic genes

Research published in the past year has led to plausible molecular models explaining the maintenance of stable patterns of homeotic gene expression through many cell generations. In addition, genes have been identified that modify the functional specificity of homeotic genes without affecting their expression patterns.

Transformation of sensory organ identity by ectopic expression of Cut in Drosophila

The loss of cut activity results in a change in neural identity in the peripheral nervous system so that the neurons and support cells of external sensory (es) organs are transformed into those of internal chordotonal (ch) organs, cut encodes a large nuclear homeo domain protein (Cut) that is expressed in the differentiated cells of es organs and their precursors but not in the cells of ch organs. We now analyze the effects of ectopic Cut expression in transformant lines of flies containing the Cut-coding sequences under inducible regulatory control. We demonstrate that ubiquitous Cut expression in embryos results specifically in the morphologic and antigenic transformation of ch organs into es organs. This effect appears to involve positive autoregulation of Cut expression. We conclude that Cut is not only necessary but sufficient for the specification of es organ identify in sensory organ precursor cells and their progeny. The specificity of Cut function to sensory organ cells involves the proneural loci daughterless and the achaete-scute complex.