Menin controls the concentration of retinoblastoma protein.

Menin, the protein encoded by the Multiple Endocrine Neoplasia type 1 gene, is involved in the cell cycle control through its participation in functional dynamics of chromatin and regulation of transcription. RB, the protein of the retinoblastoma gene RB1, controls the progression of the cell cycle and is regulated in its activity by means of a feedback by phosphorylation. Studies in double heterozygous knockout mice for Men1 and the Retinoblastoma gene Rb1 have recently indicated that both genes may be implicated in the same pathways. In the course of our studies on Menin, we found that after suppression or in absence of Menin, RB1 expression was strongly reduced in a posttranscriptional manner. Under conditions of growth arrest, the hyperphosphorylated form of RB was most strongly affected, whereas its hypophosphorylated form was less or not at all reduced. Our findings confirm the hypothesis that the pathways of two tumor suppressor genes are connected.

The bacterial Tn9 chloramphenicol resistance gene: an attractive DNA segment for Mos1 mariner insertions.

The eukaryotic mariner transposons are currently thought to have no sequence specificity for integration other than to insert within a TA contained in a degenerated [TA](1-4) tract, either in vitro or in vivo. We have investigated the properties of a suspected hotspot for the integration of the mariner Mos1 element, namely the Tn9 cat gene that encodes a chloramphenicol acetyl transferase. Using in vitro and bacterial transposition assays, we confirmed that the cat gene is a preferential target for MOS1 integration, whatever its sequence environment, copy number or chromosomal locus. We also observed that its presence increases transposition rates both in vitro and in bacterial assays. The structural and sequence features that constitute the attractiveness of cat were also investigated. We first demonstrated that supercoiling is essential for the cat gene to be a hot spot. In contrast to the situation for Tc1-like elements, DNA curvature and bendability were not found to affect integration target preferences. We found that Mos1 integrations do not occur randomly along the cat gene. All TA dinucleotides that are preferred for integration were found within either TATA or TA x TA motifs. However, these motifs are not sufficient to constitute an attractive dinucleotide, since four TATA and TA x TA sites are cold spots.