Project description:The integrated regulation of different intracellular signaling pathways is fundamental to ensure appropriate timing of cell division and, more in general, proper development of any living organism. Adopted mechanisms include the instauration of feedback regulations and/or to rely on a single molecule for the control of multiple processes. We now present evidences that in mammalian cells the CDK inhibitor p27kip1, by a CDK-independent and stathmin-dependent mechanism, is implicated in the control of the MAPK pathway, eventually influencing cell proliferation in vitro and mice growth in vivo. This p27kip1 activity regulates H-Ras driven transformation in mice and controls tumor progression in humans. Altogether, our work unveils a new mechanism that in mammalian cells contributes to proper regulation of cell proliferation and whose alteration may contribute to tumor onset and/or progression.
Project description:The CDK inhibitor p27Kip1 is a critical regulator of cell cycle progression, but the mechanisms by which p27Kip1 controls cell proliferation in vivo are still not fully elucidated. We recently demonstrated that the microtubule destabilizing protein stathmin is a relevant p27Kip1binding partner involved in the regulation of cell motility. To get more insights into the in vivo significance of this interaction, we generated p27Kip1 and stathmin double knock out (DKO) mice. Interestingly, thorough characterization of DKO mice demonstrated that most of the phenotypes of p27Kip1 null mice linked to the hyperproliferative behavior, such as the increased body and organ weights, the outgrowth of the retina basal layer and the development of pituitary adenomas, were reverted by co-ablation of stathmin. In vivo analyses showed a reduced proliferation rate in DKO compared to p27kip1 null mice, linked, at molecular level, to decreased kinase activity of CDK4/6, rather than of CDK1 and CDK2. Gene expression profile analyses of mouse thymuses confirmed the phenotypes observed in vivo, demonstrating that DKO clustered with WT and not with p27KO thymuses. Taken together, the results demonstrate that stathmin cooperates with p27Kip1 to control the early phase of G1 to S phase transition and strongly suggest that this function has particular relevance in the contest of tumor progression.
Project description:The control of cell cycle progression mostly relays on the concerted activity of cyclins, CDKs and CDKs inhibitor. Recent data demonstrated that microRNAs, by regulating the expression of these proteins, contribute to the control of cell cycle progression. Here we provide evidences that the CDK inhibitor p27Kip1 directly regulates microRNAs stability thereby influencing cell cycle exit following contact inhibition. By the use of wild type and p27 knock-out cells we uncovered several microRNAs whose expression is linked to the cell cycle exit in a p27-dependent manner. By studying one of this microRNA, miR-223, we provide evidence that p27 is an RNA binding protein able to bind miR-223 to stabilize its expression. High miR-223 levels participate in the control of cell proliferation. Overall, we identify a previously completely unknown and conserved function of p27Kip1 that contributes to the proper regulation of cell cycle progression impinging on microRNA expression.
Project description:The CDK inhibitor p27Kip1 is a critical regulator of cell cycle progression, but the mechanisms by which p27Kip1 controls cell proliferation in vivo are still not fully elucidated. We recently demonstrated that the microtubule destabilizing protein stathmin is a relevant p27Kip1binding partner involved in the regulation of cell motility. To get more insights into the in vivo significance of this interaction, we generated p27Kip1 and stathmin double knock out (DKO) mice. Interestingly, thorough characterization of DKO mice demonstrated that most of the phenotypes of p27Kip1 null mice linked to the hyperproliferative behavior, such as the increased body and organ weights, the outgrowth of the retina basal layer and the development of pituitary adenomas, were reverted by co-ablation of stathmin. In vivo analyses showed a reduced proliferation rate in DKO compared to p27kip1 null mice, linked, at molecular level, to decreased kinase activity of CDK4/6, rather than of CDK1 and CDK2. Gene expression profile analyses of mouse thymuses confirmed the phenotypes observed in vivo, demonstrating that DKO clustered with WT and not with p27KO thymuses. Taken together, the results demonstrate that stathmin cooperates with p27Kip1 to control the early phase of G1 to S phase transition and strongly suggest that this function has particular relevance in the contest of tumor progression. Four-conditions experiment (four different mouse genotypes), 6 biological replicates of wild type mouse thymus, 6 biological replicates of p27 knock-out mouse thymus, 6 biological replicates of stathmin knock-out mouse thymus, 6 biological replicates of double knock-out (p27 and stathmin) mouse thymus. Reference design: pool of RNAs derived from mouse fibroblasts of all the genotypes.Reference design;
Project description:Introgressed variants from other species can be an important source of genetic variation because they may arise rapidly, can include multiple mutations on a single haplotype, and have often been pretested by selection in the species of origin. Although introgressed alleles are generally deleterious, several studies have reported introgression as the source of adaptive alleles-including the rodenticide-resistant variant of Vkorc1 that introgressed from Mus spretus into European populations of Mus musculus domesticus. Here, we conducted bidirectional genome scans to characterize introgressed regions into one wild population of M. spretus from Spain and three wild populations of M. m. domesticus from France, Germany, and Iran. Despite the fact that these species show considerable intrinsic postzygotic reproductive isolation, introgression was observed in all individuals, including in the M. musculus reference genome (GRCm38). Mus spretus individuals had a greater proportion of introgression compared with M. m. domesticus, and within M. m. domesticus, the proportion of introgression decreased with geographic distance from the area of sympatry. Introgression was observed on all autosomes for both species, but not on the X-chromosome in M. m. domesticus, consistent with known X-linked hybrid sterility and inviability genes that have been mapped to the M. spretus X-chromosome. Tract lengths were generally short with a few outliers of up to 2.7 Mb. Interestingly, the longest introgressed tracts were in olfactory receptor regions, and introgressed tracts were significantly enriched for olfactory receptor genes in both species, suggesting that introgression may be a source of functional novelty even between species with high barriers to gene flow.
Project description:The control of cell cycle progression mostly relays on the concerted activity of cyclins, CDKs and CDKs inhibitor. Recent data demonstrated that microRNAs, by regulating the expression of these proteins, contribute to the control of cell cycle progression. Here we provide evidences that the CDK inhibitor p27Kip1 directly regulates microRNAs stability thereby influencing cell cycle exit following contact inhibition. By the use of wild type and p27 knock-out cells we uncovered several microRNAs whose expression is linked to the cell cycle exit in a p27-dependent manner. By studying one of this microRNA, miR-223, we provide evidence that p27 is an RNA binding protein able to bind miR-223 to stabilize its expression. High miR-223 levels participate in the control of cell proliferation.
Project description:Translational research is commonly performed in the C57B6/J mouse strain, chosen for its genetic homogeneity and phenotypic uniformity. Here, we evaluate the suitability of the white-footed deer mouse (Peromyscus leucopus) as a model organism for aging research, offering a comparative analysis against C57B6/J and diversity outbred (DO) Mus musculus strains. Our study includes comparisons of body composition, skeletal muscle function, and cardiovascular parameters, shedding light on potential applications and limitations of P. leucopus in aging studies. Notably, P. leucopus exhibits distinct body composition characteristics, emphasizing reduced muscle force exertion and a unique metabolism, particularly in fat mass. Cardiovascular assessments showed changes in arterial stiffness, challenging conventional assumptions and highlighting the need for a nuanced interpretation of aging-related phenotypes. Our study also highlights inherent challenges associated with maintaining and phenotyping P. leucopus cohorts. Behavioral considerations, including anxiety-induced responses during handling and phenotyping assessment, pose obstacles in acquiring meaningful data. Moreover, the unique anatomy of P. leucopus necessitates careful adaptation of protocols designed for Mus musculus. While showcasing potential benefits, further extensive analyses across broader age ranges and larger cohorts are necessary to establish the reliability of P. leucopus as a robust and translatable model for aging studies.
Project description:BACKGROUND: Long terminal repeat (LTR) retrotransposons make up a large fraction of the typical mammalian genome. They comprise about 8% of the human genome and approximately 10% of the mouse genome. On account of their abundance, LTR retrotransposons are believed to hold major significance for genome structure and function. Recent advances in genome sequencing of a variety of model organisms has provided an unprecedented opportunity to evaluate better the diversity of LTR retrotransposons resident in eukaryotic genomes. RESULTS: Using a new data-mining program, LTR_STRUC, in conjunction with conventional techniques, we have mined the GenBank mouse (Mus musculus) database and the more complete Ensembl mouse dataset for LTR retrotransposons. We report here that the M. musculus genome contains at least 21 separate families of LTR retrotransposons; 13 of these families are described here for the first time. CONCLUSIONS: All families of mouse LTR retrotransposons are members of the gypsy-like superfamily of retroviral-like elements. Several different families of unrelated non-autonomous elements were identified, suggesting that the evolution of non-autonomy may be a common event. High sequence similarity between several LTR retrotransposons identified in this study and those found in distantly-related species suggests that horizontal transfer has been a significant factor in the evolution of mouse LTR retrotransposons.