Abstract EN:

Progression through the cell cycle is regulated by the sequential activation of cyclin/CDK complexes. One level of regulation of these complexes is provided by their association with their inhibitors, the CKIs, which include p27Kip1 (p27). p27 is therefore an inhibitor of the cell division cycle, in this way, p27 acts as a tumor suppressor. However, in certain contexts, and especially when p27 is located in the cytoplasm, p27 has oncogenic functions. It appears that in addition to its role in the regulation of cyclin/CDK complexes, p27 has multiple CDK-independent roles and is involved in the control of various cellular processes such as migration, transcription, autophagy and cytokinesis. Determination of the interactome of p27 revealed that several proteins playing an essential role in cytokinesis could interact with p27, including PRC1 (Protein Regulating Cytokinesis 1) and Citron-Kinase (CitK). The objectives of my thesis are to understand how p27 participates in the control of cytokinesis via its interaction with these two proteins. Regulation of PRC1 activity by p27Kip1 PRC1 is necessary for the formation of the central spindle at the beginning of anaphase via its interaction with microtubules and other partners. For this project, my objectives were to confirm the p27/PRC1 interaction, to map the interaction domains on each partner, to test whether p27 could regulate PRC1 activity and determine by which mechanism, as well as the cellular consequences of this regulation. I validated the interactions in different cells models and identified the respective interaction domains. I found by a microtubule sedimentation technique in vitro that p27 prevents the interaction of PRC1 with microtubules. I was able to uncover two phenotypes. First, PRC1 overexpression induces excessive and massive microtubule bundling, which is abolished by co-expression of p27. Second, PRC1 overexpression causes binucleation and p27 co-expression prevents PRC1-induced binucleation. This phenotype is indicative of cytokinesis failure and suggests a CDK-independent role of p27 during cytokinesis. Citron-Kinase regulation by CDK1 and p27Kip1 Another p27 interactor previously reported by my team is CitK. CitK plays an essential role in cytokinesis and its depletion induces cytokinesis failure. CitK is involved in the final stages of cytokinesis (abscission), notably as a scaffold protein that bridges the plasma membrane and the contractile ring. The regulatory mechanisms of CitK remain poorly understood and it appears important to understand how this protein playing an essential role in cytokinesis is regulated. In our 2012 study, a p27CK- mutant, that cannot bind and inhibit cyclin-CDK complexes and is not degraded correctly by the proteasome, induced a phenotype of multinucleation by interfering with CitK activity, notably via the regulation of the CitK/RhoA interaction. We initially thought that the accumulation of p27CK- in G2/M drove this phenotype. However, our current data suggest that although the total amount of p27CK- is elevated, the amount of p27CK- at the midbody are similar to that of p27WT, suggesting that p27CK- lacks a feature that p27WT has. Since the only difference between p27WT and p27CK- is the ability to bind and inhibit cyclin/CDK complexes, we hypothesized that CitK can be regulated by CDK1 and that p27 participates in this regulation. My work has shown that CitK interacts with CDK1/Cyclin B1 in different cells lines.