Cux/CDP homeodomain protein binds to an enhancer in the rat c-mos locus and represses its activity.

The c-mos gene is transcribed in male and female germ cells, in differentiating myoblasts and in 3T3 cells from cell-specific promoters. We characterized the rat testis promoter, which contains a TATA-box and one binding site for a testis-specific transcription factor TTF-D, as well as a region which can act as enhancer, which is located approx. 2 kb upstream of the c-mos AUG start codon. It binds three factors at sites I, II and III as determined in DNAse I footprint assays. We demonstrated that a member of the NF-1/CTF family of transcription factors binds site II. Here we report the cloning of the protein that binds to enhancer site III. This protein is the rat homolog of human hCut/CDP, mouse Cux/CDP and canine Clox. hCut/Cux/CDP/Clox (hereafter called Cux/CDP), a 160 kDa protein containing multiple repeats and a homeodomain, negatively regulates the mammalian c-myc, gp91-phox and N-Cam genes. Using bacterially produced murine GST-Cux fusion proteins and GST-Cux deletion mutants, we find that Cux repeat CR3 and the homeodomain are both required for efficient binding to enhancer site III. Mouse lung and testis nuclear Cux/CDP bind to site III as determined in electrophoretic gel mobility supershift assays using two different anti-hCut specific monoclonal antibodies. Transfections of CAT constructs containing the enhancer fragment linked to a minimal promoter demonstrated that Cux/CDP represses c-mos enhancer activity.

A 3' remote control region is a candidate to modulate Hoxb-8 expression boundaries.

Hox genes have been shown to play a key role in the acquisition of positional identity by precursors of embryonic axial, paraxial and limb structures. This function is thought to depend on the sequential, concerted expression of these genes in time and space. However the underlying molecular mechanisms of this collinear expression are still largely unknown. So far we had identified proximal regulatory elements driving expression of Hoxb-8/LacZ transgenes in Hox-like expression patterns with rostral boundaries more posterior than those of the endogenous gene. In this work we have analyzed 30 kb of 3' genomic sequences for Hoxb-8 regulatory activity in transgenic mice. We have identified a control region in the Hoxb-5/b-4 intergenic region that rostrally extends the Hoxb-8/LacZ expression domain into the posterior hindbrain. In combination with the Hoxb-8 minimal promoter, the 3' control region drives transgene expression with boundaries more anterior than those of Hoxb-8 in the neural tube. When combined with a 4.5 kb Hoxb-8 upstream sequence, where essential proximal regulatory sequences are located, the 3' control region drives transgene expression in a domain which seems to correspond to that of the endogenous Hoxb-8. By deletion analysis we have narrowed down to 550bp the regulatory activity interacting with the Hoxb-8 minimal promoter. We discuss the possibility that this remote 3' enhancer, which is the closest regulatory region found in the cluster to rostrally extend Hoxb-8/LacZ expression, could be involved in the regulation of Hoxb-8 and interact with the proximal control elements.

The mouse homeodomain protein Phox2 regulates Ncam promoter activity in concert with Cux/CDP and is a putative determinant of neurotransmitter phenotype.

Transcriptional regulation of the gene encoding the cell adhesion receptor NCAM (neural cell adhesion molecule), a putative effector molecule of a variety of morphogenetic events, is likely to involve important regulators of morphogenesis. Here we identify two mouse homeodomain proteins that bind to an upstream regulatory element in the Ncam promoter: Cux, related to Drosophila cut and human CDP, and Phox2, a novel protein with a homeodomain related to that of the Drosophila paired gene. In transient transfection experiments, Cux was found to be a strong inhibitor of Ncam promoter activity, and this inhibition could be relieved by simultaneously overexpressing Phox2. These results suggest that the Ncam gene might be a direct target of homeodomain proteins and provide a striking example of regulatory cross-talk between homeodomain proteins of different classes. Whereas the expression pattern of Cux/CDP includes many NCAM-negative sites, Phox2 expression was restricted to cells also expressing Ncam or their progenitors. The localisation data thus strongly reinforce the notion that Phox2 plays a role in transcriptional activation of Ncam in Phox2-positive cell types. In the peripheral nervous system, Phox2 was strongly expressed in all ganglia of the autonomic nervous system and more weakly in some cranial sensory ganglia, but not in the sensory ganglia of the trunk. Phox2 transcripts were detected in the primordia of sympathetic ganglia as soon as they form. Phox2 expression in the brain was confined to spatially restricted domains in the hindbrain, which correspond to the noradrenergic and adrenergic nuclei once they are identifiable. All Phox2-expressing components of the peripheral nervous system are at least transiently adrenergic or noradrenergic. In the developing brain, Phox2 was expressed at all known locations of (nor)adrenergic neurones and of their precursors. These results suggest that Phox2, in addition to regulating the NCAM gene, may be part of the regulatory cascade that controls the differentiation of neurons towards this neurotransmitter phenotype.

A possible link between cell adhesion receptors, homeodomain proteins and neuronal identity.

The orderly arrangement of neuronal cell bodies and axonal projections generated during nervous system development requires precise spatio-temporal control of the expression and activity of cell adhesion receptors. Recent evidence suggests that homeobox genes, an important class of developmental control genes, many of which are preferentially expressed in developing nervous tissue, play prominent roles in the regulation of expression of these molecules. We have characterised two mouse homeobox genes, named Cux and Phox2, the products of which bind to and regulate the promoter of the Ncam gene in vitro. Its highly specific expression pattern suggests that Phox2, besides regulating Ncam, may be determinant of the noradrenergic phenotype.

An upstream regulatory element of the NCAM promoter contains a binding site for homeodomains.

In the present study, we have analyzed an upstream regulatory element of the neural cell adhesion molecule (NCAM) promoter which is required for full promoter activity. It contains an ATTATTA motif that resembles the core recognition sequence of homeodomain (HD) proteins of the Antennapedia (Antp) and related types. Electrophoretic mobility shift (EMSA) and DNase I footprinting analyses revealed that the Drosophila HDs coded by the Antp and the zerknüllt (zen) genes bind this site in vitro. In contrast, the engrailed (en) protein did not produce a detectable footprint. The functional relevance of the ATTATTA motif was demonstrated by showing that a two-nucleotide exchange curtailed stimulation of an heterologous promoter. An oligonucleotide known to be recognized with high affinity by Antp-like HDs efficiently competed for endogenous factor binding. These results suggest that the NCAM gene may be a target for HD proteins.