Reexpression of oncoprotein MafB in proliferative ß-cells and Men1 insulinomas in mouse.

MafB, a member of the large Maf transcription factor family, is essential for the embryonic and terminal differentiation of pancreatic α- and ß-cells. However, the role of MafB in the control of adult islet-cell proliferation remains unknown. Considering its oncogenic potential in several other tissues, we investigated the possible alteration of its expression in adult mouse ß-cells under different conditions of proliferation. We found that MafB, in general silenced in these cells, was reexpressed in ∼30% of adaptive ß-cells both in gestational female mice and in mice fed with a high-fat diet. Importantly, reactivated MafB expression was also observed in the early ß-cell lesions and insulinomas that developed in ß-cell specific Men1 mutant mice, appearing in >80% of ß-cells in hyperplasic or dysplastic islets from the mutant mice >4 months of age. Moreover, MafB expression could be induced by glucose stimulation in INS-1 rat insulinoma cells. The induction was further reinforced following Men1 knockdown by siRNA. Furthermore, MafB overexpression in cultured ßTC3 cells enhanced cell foci formation both in culture medium and on soft agar, accompanied with the increased expression of Cyclin B1 and D2. Conversely, MafB downregulation by siRNA transfection reduced BrdU incorporation in INS-1E cells. Taken together, our data reveal that Men1 inactivation leads to MafB reexpression in mouse ß-cells in vivo, and provides evidence that deregulated ectopic MafB expression may have a hitherto unknown role in adult ß-cell proliferation and Men1-related tumorigenesis.

RISA-HPLC analysis of lung bacterial colonizers of cystic fibrosis children.

Microbiological analysis of sputum samples, from children affected by cystic fibrosis (CF) and showing signs of acute or chronic infections, is routinely performed by culture-dependent approaches involving selective media and biochemical tests. These identification schemes are time-consuming, and may lead to false negative results. The aim of this work was to evaluate the efficacy of a Ribosomal Intergenic Spacer Analysis (RISA) coupled to high performance liquid chromatography (HPLC) for the detection and monitoring of CF lung microbial colonizers including Staphylococcus aureus, Haemophilus influenzae, Pseudomonas aeruginosa, the Burkholderia cepacia complex, Stenotrophomonas maltophilia, and Achromobacter xylosoxidans. These RISA-HPLC analyses were performed over a 10-months period on infants (below 18 months) and children that were or were not yet known to be colonised by P. aeruginosa. The RISA-HPLC profiles were found specific of the patients' microbial communities. A specific P. aeruginosa RISA-HPLC peak corresponding to 550 bp PCR products was recorded, and used to investigate P. aeruginosa persistence through time and after various therapeutic treatments. The RISA-HPLC profiles showed the CF children to be colonized by few bacterial species, and sometimes revealed peaks corresponding to bacterial species that were not detected by the selective plating approaches. Significant RISA-HPLC infra-specific variations were observed for most bacterial colonizers of CF lungs except P. aeruginosa. These species could yield as much as 5 distinct RISA-HPLC peaks, with some of these profiles being strain-specific. RISA-HPLC shows a great potential for revealing colonization by novel emerging pathogens, and for evaluating the efficacy of therapeutic treatments on the global bacterial community of CF lungs.