Absence of mutations in the interspecies conserved regions of the CFTR promoter region in cystic fibrosis (CF) and CF related patients.

This study was aimed at testing if a 5.2 kb untranslated region on both sides of the first CFTR exon, shown to contain regulatory elements, could carry mutations responsible for cystic fibrosis (CF) or CF related phenotypes. Selection of the DNA segments studied within this region was based upon the identification of conserved sequences throughout evolution (phylogenetic footprints, PFs). Comparison of the CFTR sequences in eight species representing four orders of mammals (man, gibbon, rhesus monkey, squirrel, monkey, rabbit, cow, rat, and mouse) identified four clusters of PFs within the 3.9 kb of DNA sequence upstream from the initiation codon, as well as two nearby PFs at +1 kb within intron 1. Six DNA segments containing PFs were scanned for mutations by denaturing gradient gel electrophoresis (DGGE) in patients with CF (n = 29), congenital bilateral absence of the vas deferens (n = 143), or disseminated bronchiectasis (n = 33), for whom only one or no mutations had been identified despite extensive DGGE analysis of the 27 CFTR exons and exon/intron boundaries. Only one polymorphism (-966 T-->G) was identified with a frequency of 2.2% and no other sequence variations were found. This study reinforces the idea that the promoter region in the CFTR is not frequently mutated.

Phylogenetic analysis of cystic fibrosis transmembrane conductance regulator gene in mammalian species argues for the development of a rabbit model for cystic fibrosis.

The species-specific pattern of cystic fibrosis transmembrane conductance regulator (CFTR) expression was investigated in order to identify species closely related to man which can be used as potential cystic fibrosis (CF) animal models. To this purpose, the nucleotide sequences of the CFTR promoter region of eight mammalian species representing four different orders (Primates, Artiodactyla, Lagomorpha and Rodentia) were analyzed. Distance matrices and unrooted trees of the CFTR promoter region sequences yielded two deeply separated groups, one including man (Homo sapiens), nonhuman primates (Hylobates lar, Macaca fascicularis, Saimiri sciureus), cow (Bos taurus), and rabbit (Oryctolagus cuniculus) and the other including the rodents (Rattus norvegicus, Mus musculus). Divergences between rodent and nonrodent groups have been observed in putative cis transcriptional regulatory elements and can be involved in the differences of pattern of expression between these two groups. Comparison of the available CFTR cDNA sequences enabled us to root the tree with a noneutherian outgroup and to perform a phylogenetic analysis. This analysis did not detect any base composition bias and supported polyphyletic Glires. Although a long-branch attraction artifact cannot be completely excluded, these findings converge toward the recent statement (Graur, Duret, and Gouy 1996) that Lagomorpha is more closely related to Primates than to Rodentia. In addition, the phenylalanine residue in exon 10 involved in the most common CF mutation in man is conserved in rabbit. These phylogenetic analyses as well as anatomical and developmental data suggest that, once rabbit embryonic stem cells become available, the rabbit will provide a suitable tool for both gene transfer and pharmacological investigations and could lead to a better CF model than the current murine models.

Cross-species characterization of the promoter region of the cystic fibrosis transmembrane conductance regulator gene reveals multiple levels of regulation.

The cystic fibrosis transmembrane conductance regulator (CFTR) gene is highly conserved within vertebrate species. Its pattern of expression in vivo seems to be tightly regulated both developmentally and in a tissue-specific manner, but shows differences with species. To identify transcriptional regulatory elements in the CFTR promoter region, we have used a combined approach based both on the analysis of the chromatin structure in vivo in rat tissues and on evolutionary clues (i.e. phylogenetic footprinting). In CFTR-expressing tissues, 15 DNase I-hypersensitive sites were identified within a 36 kb region encompassing exon 1. Eleven of them are clustered in a 3.5 kb region that exhibits eleven phylogenetic footprints observed when comparing sequences from eight mammalian species representing four orders (Primates, Artiodactylia, Lagomorpha and Rodentia). Comparison of the two sets of data allows the identification of two types of regulatory elements. Some are conserved between species, such as a non-consensus cAMP response element (CRE) and a PMA-responsive element (TRE) located respectively at positions -0.1 and -1.3 kb relative to ATG. Some are species-specific elements such as a 300 bp purine.pyrimidine (Pu.Py) stretch that is present only in rodents. Analysis of protein/DNA interactions in vitro with rat tissue protein extracts on the conserved elements revealed that the TRE site binds a specific heterodimeric complex composed of Fra-2, Jun D and a protein immunologically related to Jun/CRE-binding protein in the duodenum, whereas the CRE-like site binds ATF-1 ubiquitously. Functional analysis in Caco-2 cells showed that the CRE-like site supports a high basal transcriptional activity but is not able by itself to induce a response to cAMP, whereas the TRE site acts as a weak transactivator stimulated by PMA. Lastly, we found that the rodent-specific Pu.Py stretch confers nuclease S1 hypersensitivity under conditions of acidic pH and supercoiling. This indicates a non-B DNA conformation and thus reinforces the biological significance of non-random Pu.Py strand asymmetry in the regulation of transcription. Thus the tight transcriptional regulation of CFTR expression involves the combination of multiple regulatory elements that act in the chromatin environment in vivo. Some of them are conserved throughout evolution, such as the CRE-like element, which is clearly involved in the basal level of transcription; others are species-specific.