A specific promoter of the sensory cells of the inner ear defined by transgenesis.

To date, no promoter sequence specific to the inner ear sensory cells (hair cells) has been reported. In an effort to understand the molecular mechanisms that determine hair cell fate in the inner ear, and with the goal of developing a valuable tool for gene therapy and for the generation of conditional knockouts, we initiated a search for cis-acting DNA sequences that regulate the expression of the murine Myo7a and human MYO7A genes. These genes encode the unconventional myosin VIIA which is expressed in hair cells and in some other epithelial cells. We generated lines of transgenic mice expressing the green fluorescent protein (GFP ) reporter gene under the control of several 5'-truncated versions of the Myo7a/MYO7A promoter region and intron 1. We obtained transgenic mice with a GFP expression restricted to the hair cells of the inner ear, cochlea and vestibule. Successive deletions of the promoter allowed us to define a minimal sequence of 118 bp that is sufficient, in the presence of intron 1, to target the transgene expression to hair cells. In addition, the deletion of intron 1 from the transgenes abolished hair cell expression, thus indicating the presence of a strong enhancer in the intron. This is the first report of regulatory sequences sufficient to target the expression of a gene exclusively in sensory cells of the inner ear. It also opens up the possibility for the analysis of the hair cell transcriptome.

A P element has induced intron formation in Drosophila.

We report evidence supporting the hypothesis that some introns could be originated from transposable elements. In the Drosophila montium species subgroup, we recently described a novel example of domestication by the host genome of a P transposable element. The element is a unique truncated P sequence transcribed into a polyadenylated RNA encoding a putative 66-kDa transposition repressor-like protein. Here, we analyze the genomic modifications associated with this transition of a transposable element into a stationary gene that is useful for the host. Study of the transcription modalities of this neogene reveals that the new transcriptional unit harbors a de novo synthesis of a new exon and a new intron upstream of the original P sequence initiation site. The new exon was constructed from the genomic flanking sequence of the P sequence, whereas the first half of the new intron is composed of genomic flanking sequence and the second half is composed of P sequence. This domestication event has involved the capture of a new promoter. An investigation of a large number of species belonging to the melanogaster species group revealed that this P element domestication is restricted to the species of the montium subgroup and that the new exon-intron structure is present in at least three other species. From sequence data, we hypothesize that cryptic acceptor and donor splicing sites present on the P element and flanking sequences have been under selective constraints which have led to the emergence of a new intron.