Towards the understanding of pericentriolar satellite biology

Quarantotti, Valentina

January 2018

Pericentriolar satellites (PS) are electron dense granules surrounding the centrosome, the major microtubule-organizing centre in eukaryotic cells. In cycling cells the centrosome promotes spindle assembly and the faithful execution of mitosis. In non-cycling cells it is involved in forming the cilium, a plasma membrane-resident organelle, which mediates crucial signalling pathways in development and tissue homeostasis. PS are thought to contribute to centrosome formation, through the microtubule-dependent transport of centrosome components, and they are involved in ciliogenesis and stress response. Moreover, several proteins that localize to PS are mutated in human ciliopathies and neurodevelopmental disorders. The precise roles of PS in the various molecular pathways and diseases are however poorly understood, in part due to the limited knowledge of their composition. In the first part of my study I performed a comprehensive analysis of the pericentriolar satellite proteome. This was achieved by sucrose sedimentation of PS, combined with affinity purification of a key PS component, PCM1. To eliminate contamination by centrosomes, the PS proteome was determined from wild-type cells as well as from two cell lines genetically engineered to lack centrosomes. Mass spectrometry identified 170 PS components including most of the previously described PS proteins, confirming the validity of the approach. Having determined the proteomic composition of PS from DT40 cells, I then performed validation studies both in chicken and human cell lines. In the second part of my study, I aimed to use the list of PS proteins to uncover new biological roles for pericentriolar satellites. I devised two distinct approaches to gain functional insights. First, I generated a cell line lacking PCM1 as a tool to study the role(s) of PS and PS components. Second, I performed loss-of-function studies on a set of new PS proteins to determine their function(s) in maintaining the canonical PS distribution and in forming primary cilia.

Caractérisation d'une nouvelle protéine impliquée dans la ciliogenèse, FOR20

Sedjai, Fatima

13 May 2011

Les cils/flagelles sont des organites conservés au cours de l’évolution qui peuvent permettre le mouvement de fluide, la locomotion ainsi que la chimiosensation, mécanosensation et la signalisation intracellulaire. Le cil est constitué d’un corps basal (à la base du cil) et d’un axonème émergeant à la surface cellulaire et entouré de membrane. L’axonème est constitué de neuf doublets de microtubules et une paire centrale dans le cas d'un cil motile. Leur dysfonctionnement peut conduire à des syndromes génétiques (ciliopathies) pouvant être fatale. Mon travail de thèse porte sur la caractérisation d’une nouvelle protéine centrosomale baptisé FOR20 (FOP Related protein of 20 kDa). Cette protéine très conservée possède un domaine LisH, permettant l’homodimérisation. FOR20 est retrouvée au centrosome et dans des satellites péricentriolaires. Les satellites sont des structures non membranaires enrichies en PCM1 se déplaçant le long des microtubules grâce à des moteurs, apportant certaines protéines au centrosome. L'utilisation de protéines mutées montre que la partie amino terminale de FOR20, incluant un domaine LisH fonctionnel, est responsable de cette localisation. L’inhibition d’expression de FOR20 dans des cellules ciliées, RPE1, diminue le pourcentage de cellules ciliées ainsi que la taille du cil. La distribution des satellites est perturbée et la protéine PCM1 est déplacée de la fraction insoluble à la fraction soluble en Triton-X100. Nos résultats suggèrent que FOR20 est une protéine impliquée dans la régulation de l’interaction des satellites avec les microtubules et les moteurs ainsi que dans le contrôle du transport d’éléments ciliaires au corps basal. / Cilia and flagella are evolutionary conserved organelles that generate fluid movement and locomotion, and play roles in chemosensation, mechanosensation and intracellular signalling. In complex organisms, cilia are highly diversified, which allows them to perform various functions. However, they retain a 9+0 or 9+2 microtubules structure connected to a basal body. Here, we describe FOR20 (FOP-related protein of 20 kDa), a previously uncharacterized and highly conserved protein that is required for normal formation of a primary cilium. FOR20 is found in PCM1-enriched pericentriolar satellites and centrosomes. FOR20 contains a Lis1-homology domain that promotes self-interaction and is required for its satellite localization. Inhibition of FOR20 expression in RPE1 cells decreases the percentage of ciliated cells and the length of the cilium on ciliated cells. It also modifies satellite distribution, as judged by PCM1 staining, and displaces PCM1 from a detergent-insoluble to a detergent-soluble fraction. The subcellular distribution of satellites is dependent on both microtubule integrity and molecular motor activities. Our results suggest that FOR20 could be involved in regulating the interaction of PCM1 satellites with microtubules and motors. The role of FOR20 in primary cilium formation could therefore be linked to its function in regulating pericentriolar satellites. A role for FOR20 at the basal body itself is also possible.

For20

Pcm1

Primary cilium

Satellites péricentriolaires

Centrosome

Microtubules

For20

Pcm1

Primary cilium

Pericentriolar satellites

Centrosome

Microtubules

Characterisation of a novel spindle domain in mammalian meiosis

Seres, Karmen Bianka

January 2019

The organisation of microtubule networks into a bipolar spindle is essential for reliable chromosome segregation during cell division. A pair of centrioles surrounded by pericentriolar material (PCM), define the canonical centrosome that acts as the main microtubule organising centre (MTOC) during mitosis. In mammalian meiosis, centrioles are eliminated early on during oogenesis. Despite the absence of centrosomes, a large number of centrosomal proteins are highly expressed in mouse oocytes. Here, I characterise the localisation and function of centrosomal proteins at a previously undescribed meiotic spindle pole domain (MSPD). An initial protein screen identified a group of pericentriolar satellite proteins that localised to a previously undescribed spindle pole domain throughout meiotic maturation in mouse oocytes, including Pericentriolar material 1 protein (PCM1). This domain was distinct from spindle microtubules and the acentrosomal microtubule organising centres (aMTOCs). Initial characterisation focused on PCM1, the main centriolar satellite scaffold protein in somatic cells. Depletion of PCM1 revealed interdependence with the essential aMTOC component, Pericentrin. In the absence of PCM1, aMTOCs could no longer assemble or maintain their structural integrity. PCM1 degradation and disassembly of aMTOCs disrupted spindle assembly and reduced the total amount of nucleated microtubules throughout meiosis. In the absence of the main microtubule nucleating aMTOCs, oocytes relied on the Ran GTPase activity to form a small bipolar spindle. A similar mechanism was previously reported in human oocytes that lack prominent MTOCs. The extended centrosomal protein screen identified additional components of the MSPD. TACC3, under the regulation of Aurora-A at aMTOCs, drive assembly of the MSPD. This domain was absent in MTOC free human oocytes but a second population of TACC3 (identified in mouse oocytes) localised to the meiotic spindle and K-fibres was essential for maintaining spindle pole integrity. Establishing the Lightsheet Z.1 system for live cell imaging of human oocytes enabled us to observe the dynamic distribution of TACC3 in these oocytes. In the absence of prominent MTOCs and the MSPD, human oocytes likely rely on other spindle assembly factors and motor proteins to organise their spindle. Future work to address if the absence of the MSPD could account (in part) for the observed spindle instability in human oocytes is an exciting outlook.