Functional study of the NIMA protein kinases Nek9, Nek6 and Nek7 at the onset of mitosis. Control of the kinesin Eg5 and prophase centrosome separation

[eng] Mitosis is a tightly regulated process that aims to ensure the correct distribution of the chromosomes between the two newly generated cells. Many protein kinases have been defined as essential for this process: cyclin- dependent kinases, Aurora family and Polo family kinases are some of the m...

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Bibliographic Details
Author: Eibes González, Susana
Format: doctoral thesis
Status:Published version
Publication Date:2016
Country:España
Institution:Universidad de Barcelona
Repository:Dipòsit Digital de la UB
OAI Identifier:oai:diposit.ub.edu:2445/106177
Online Access:https://hdl.handle.net/2445/106177
http://hdl.handle.net/10803/399449
Access Level:Open access
Keyword:Mitosi
Proteïnes quinases
Mitosis
Protein kinases
Description
Summary:[eng] Mitosis is a tightly regulated process that aims to ensure the correct distribution of the chromosomes between the two newly generated cells. Many protein kinases have been defined as essential for this process: cyclin- dependent kinases, Aurora family and Polo family kinases are some of the most relevant players. The objective of this thesis is to characterize one of the less studied kinase pathways involved in this process, which is constituted by the NIMA-related kinases Nek9, Nek6 and Nek7. Nek9 is activated at the onset of mitosis by a double step mechanism mediated by CDK1 and Plk1. Once Nek9 is activated it can bind to Nek6 and Nek7 and phosphorylate them, promoting their activation. Finally, Nek6 and Nek7 are responsible for the phosphorylation of the kinesin Eg5, promoting Eg5 accumulation at centrosome, and consequently, centrosome separation. The kinesin eg5 motor protein is considered as one of the major players for centrosome separation and formation of the bipolar spindle. The tetramer configuration allows Eg5 to bind antiparallel microtubules and slide them apart, exerting a force that promotes centrosome separation and the maintenance of the bipolar spindle. Centrosome separation, however, is a highly intricate process that involves several pathways, including Eg5 activity. Dynein presents a directed activity towards the minus ends of microtubules, which has a redundant role to Eg5 in centrosome separation. Dynein accumulation at the cell cortex and the nuclear membrane, through its adaptor BicD2, is also involved in centrosome tethering at the nuclear envelope, a necessary step prior to separation. Furthermore, dynein can control the position of Eg5 at the spindle via TPX2, an event that could also happen before nuclear envelope breakdown (NEB). Here we describe the conditions required for Eg5 accumulation at the centrosmes after Ser1033 phosphorylation. During the development of this project we have explored the essential circumstances for correct Eg5 localization in cells. By using protein-protein interaction techniques and shRNA depletion of protein candidates we have determined that another motor protein, dynein, together with the adaptor BicD2 and the protein TPX2 are responsible for Eg5 accumulation around centrosomes. Additionally, we proposed TPX2 as a novel Nek9 substrate and we have investigated the role of this phosphorylation, which affects TPX2 localization during prophase, before NEB. We present with this thesis a model for Eg5 accumulation at microtubule minus ends and centrosome separation during prophase summarized in the following points: 1) Dynein complex transports Eg5 towards the centrosome. Dynein interacts with Eg5 independently of the Ser1033 phosphorylation. The adaptor BicD2, which interacts directly with Eg5 tail domain, mediates the interaction. Dynein motility towards microtubule minus ends and the presence of BicD2 on the complex are required for Eg5 localization at centrosomes. Thus, the dynein complex is required for Eg5 transport to the centrosomes during G2-M transition. 2) TPX2 inhibits Eg5 motility in response to Ser1033 phosphorylation. TPX2 is necessary for the correct localization of Eg5 at centrosomes during prophase. TPX2 mislocalization at centrosomes without altering its overall levels leads to failed Eg5 localization, therefore the presence of TPX2 at centrosomes during prophase is required for Eg5 localization. TPX2 interacts with Eg5 during mitosis and the interaction is abolished when the Ser1033 can’t be phosphorylated. Thus, TPX2 is able to respond to Eg5 Ser1033 phosphorylation, which we propose is promoting the interaction between these two proteins, and consequently inhibiting Eg5 motility at centrosomal levels. 3) TPX2 phosphorylation by Nek9 promotes its centrosomal localization. Nek9 phosphorylation of TPX2 is responsible for TPX2 localization at the spindle poles during prophase. Nek9 phosphorylates TPX2 at residues that are proximal to a NLS, making TPX2 localization more cytoplasmic and promoting its accumulation to the area where Nek9 is more active, the centrosome.