La protéine kinase LegK2 de Legionella pneumophila et le complexe ARP2/3 de la cellule hôte : un nouveau paradigme dans le détournement du cytosquelette d'actine par un pathogène / The protein kinase LegK2 of Legionella pneumophila and the ARP2/3 complex of the host cell : a new paradigm in the actin cytoskeleton hijacking by a pathogen

Michard, Céline

14 October 2015

Legionella pneumophila est une bactérie opportuniste qui émerge de l'environnement après multiplication dans des amibes et peut infecter accidentellement les macrophages alvéolaires humains, provoquant une pneumonie sévère, la légionellose. La capacité de L. pneumophila à survivre dans ses cellules hôtes est strictement dépendante du système de sécrétion de type 4 Dot/Icm, qui sécrète un large répertoire d'effecteurs dans le cytosol de l'hôte. Identifier la contribution individuelle de chaque protéine bactérienne sécrétée par le système Dot/Icm, dans le cycle infectieux de L. pneumophila reste un enjeu majeur pour comprendre les bases moléculaires de la virulence des légionelles. Mes travaux de thèse participent à cet objectif en caractérisant la voie cellulaire ciblée par la protéine kinase LegK2. Des tests d'interaction et de phosphorylation ont identifié le complexe nucléateur d'actine ARP2/3 comme cible de LegK2. Suite à l'adressage de LegK2 à la surface de la vacuole après sa translocation dans le cytosol de l'hôte, l'interaction LegK2-ARP2/3 inhibe la polymérisation d'actine sur le phagosome. Cette inhibition permet à Legionella de diminuer le trafic des endosomes tardifs et/ou des lysosomes vers le phagosome et favorise ainsi l'évasion du phagosome à la voie de dégradation endocytique. L'interaction LegK2-ARP2/3 met en évidence un mécanisme original de virulence dans lequel le remodelage local du cytosquelette d'actine de la cellule hôte permet à la bactérie de manipuler le trafic vésiculaire pour échapper aux défenses de l'hôte / Legionella pneumophila is an opportunistic bacterium that emerges from the environment after multiplication in protozoans and can accidentally infect human alveolar macrophages leading to a severe pneumonia, the legionellosis. The L. pneumophila ability to survive within host-cells is strictly dependent on the Dot/Icm Type 4 Secretion System that translocates a large repertoire of effectors into the host cell cytosol. Deciphering the individual contribution of each bacterial protein translocated by the Dot/Icm system in the L. pneumophila infectious cycle remains a major challenge to understand the molecular basis of Legionella virulence. My works contribute to this objective by characterizing the cellular pathway targeted by the protein kinase LegK2. Interaction and phosphorylation assays identified the actin nucleator ARP2/3 complex as the target of LegK2. Following the LegK2 addressing to the vacuole surface after its translocation into host cytosol, LegK2- ARP2/3 interplay inhibits the actin polymerization on the phagosome. This inhibition allows Legionella to decrease the late endosome/lysosome trafficking towards the phagosome and promotes the phagosome evasion from endocytic degradation pathway. LegK2-ARP2/3 interplay highlights an original mechanism of virulence wherein the local actin cytoskeleton remodeling of host cell allows bacteria to hijack the vesicles trafficking in order to escape host-cell defenses

Interaction hôte-pathogène

Legionella pneumophila

Actine

Complexe ARP2/3

Protéine kinase de Legionella

Trafic endocytique

Host-pathogen interaction

Legionella pneumophila

Actin

ARP2/3 complex

Protein kinase of Legionella

Endocytic traffic

579

The role of a trimeric coiled coil protein in WASH complex assembly / Rôle d’une protéine trimérique à superhélice dans l’assemblage du complexe WASH

Visweshwaran, Sai Prasanna

22 September 2017

Le complexe Arp2/3 génère des réseaux d’actine branchés, qui produisent une forcée de poussée permettant à la cellule de remodeler ses membranes. Le complexe WASH active le complexe Arp2/3 à la surface des endosomes et facilite ainsi la scission membranaire des intermédiaires de transports contenants des récepteurs internalisés tels que les intégrines α5β1. De ce fait, le complexe WASH en favorisant le recyclage des intégrines, joue un rôle crucial dans l’invasion des cellules tumorales durant la progression tumorale. Cependant, le mécanisme d’assemblage du complexe WASH est inconnu. Dans cette étude, nous rapportons l’identification du premier facteur d’assemblage du complexe WASH. Nous avons identifié la protéine HSBP1 grâce à un crible des protéines qui se lient aux formes précurseurs des sous-unités mais plus au complexe une fois assemblé. La reconstitution biochimique et la modélisation moléculaire nous a permis de montrer que HSBP1 est associé avec le précurseur trimérique CCDC53, le dissocie et forme un hétérotrimère qui va éventuellement libérer une forme monomérique de CCDC53 pour l’assemblage du complexe WASH. Le rôle de HSBP1 dans l’assemblage du complexe WASH est conservé. En effet, WASH est déstabilisé dans des cellules mammaires par le knock-down de HSBP1 et dans l’amibe Dictyostelium par le knock-out de HSBP1. La déstabilisation du complexe WASH par le knock-out de HSBP1 phénocopie la déplétion de WASH dans l’amibe Dictyostelium. Dans des cellules humaines de carcinomes mammaires l’inhibition de l’expression de HSBP1 altère le recyclage des intégrines à la membrane plasmidique. Il en résulte des adhésions focales défectueuses et des capacités invasives réduites. De plus, HSBP1 est localisé aux centrosomes et est requis pour la polarité des cellules lors de la migration. Enfin, nous avons trouvé que la surexpression de HSBP1 dans des tumeurs mammaires est associée à une augmentation des niveaux du complexe WASH et à un mauvais pronostic pour les patientes atteintes de cancer du sein. En conclusion, HSBP1 est un facteur d’assemblage conservé qui contrôle les niveaux du complexe WASH. / The Arp2/3 complex generates branched actin networks, which produces a pushing force that helps the cell to remodel its membranes. The WASH complex activates the Arp2/3 complex at the surface of endosomes and thereby, facilitates the membrane scission of the transport intermediates containing internalized receptors such as α5β1 integrins. Hence, by promoting integrin recycling, the WASH complex plays a crucial role in tumor cell invasion during cancer progression. However, how cells assemble the WASH complex at first is unknown. Here we report the identification of the first assembly factor of the WASH complex. We identified HSBP1 in a proteomics screen for proteins binding to precursor forms of subunits, but not to the fully assembled WASH complex. Through biochemical reconstitution and molecular modeling, we found that HSBP1 associates with the precursor CCDC53 trimer, dissociates it and forms a heterotrimer that will eventually contribute a single CCDC53 molecule to the assembling WASH complex. The role of HSBP1 in WASH complex assembly is well conserved since WASH is similarly destabilized upon HSBP1 knock-down in mammalian cells or upon HSBP1 knock-out in Dictyostelium amoeba. In line with the defective assembly of the WASH complex, the HSBP1 knock-out closely phenocopies WASH knock-out in amoeba. In human mammary carcinoma cells, HSBP1 depletion results in impaired integrin recycling to the plasma membrane leading to the defective development of focal adhesions and reduced invasion abilities. Moreover, HSBP1 was found to localize at the centrosome and was required for the polarization associated with the migration. On the other end, in mammary breast tumors, we found that HSBP1 was often overexpressed and that its overexpression was associated with increased levels of the WASH complex and with poor prognosis for breast cancer patients. Hence, HSBP1 is a conserved assembly factor that controls the levels of the WASH complex.

Complexe WASH

Cytosquelette d'actine

Assemblage des complexes

Migration des cellules

Invasion des cellules

Centrosome

Complexe Arp2/3

WASH complex

Actin cytoskeleton

Multiprotein complex assembly

Cell migration

Cell invasion

Centrosome

Arp2/3 complex

Exploiting Drosophila as a model system for studying anaplastic lymphoma kinase in vivo

Eriksson, Therese

January 2010

Anaplastic Lymphoma Kinase (ALK) is a Receptor Tyrosine Kinase (RTK) and an oncogene associated with several human diseases, but its normal function in humans and other vertebrates is unclear. Drosophila melanogaster has an ALK homolog, demonstrating that the RTK has been conserved throughout evolution. This makes Drosophila a suitable model organism for studying not only Drosophila ALK function, but also to study mammalian forms of ALK. In Drosophila the ligand Jeb activates ALK, initiating signaling crucial for visceral mesoderm development. The activating ligand for mammalian ALK is unclear, and for this reason Drosophila was employed in a cross-species approach to investigate whether Drosophila Jeb can activate mouse ALK. Jeb is unable to activate mouse ALK, and therefore mouse ALK is unable to substitute for and rescue the Drosophila ALK mutant phenotype. This suggests that there has been significant evolution in the ALK-ligand relationship between the mouse and Drosophila. In humans ALK has recently been shown to be involved in the development of neuroblastoma, a cancer tumor in children. I have developed a Drosophila model for examining human gain of function ALK mutants found in neuroblastoma patients. The various ALK variants have acquired point mutations in the kinase domain that have been predicted to activate the RTK in a constitutive and ligand independent manner. When expressed in the fly eye, active human ALK mutants result in a rough eye phenotype, while inactive wild type ALK does not, due to the lack of an activating ligand in the fly. In this way  several of the ALK mutations identified in neuroblastoma patients could be confirmed to be activated in a ligand independent manner. Moreover, a novel ALK mutant; ALKF1174S, was discovered in a neuroblastoma patient and was in the Drosophila model shown to be a gain of function mutation, and a previously predicted gain of function mutation; ALKI1250T, was shown to be a kinase dead mutation. This fly model can also be used for testing ALK selective inhibitors, for identifying activating ligands for human ALK and for identifying conserved components of the ALK signaling pathway. Gut musculature development in Drosophila is dependent on ALK signaling, while somatic muscle development is not. Proteins of the Wasp-Scar signaling network regulate Arp2/3-complex mediated actin polymerization, and I have investigated their function in visceral and somatic muscle fusion. I found that Verprolin and other members of this protein family are essential for somatic but not visceral muscle development. Despite fusion defects in both tissues in Verprolin and other examined mutants, gut development proceeds, suggesting that fusion is not crucial for visceral mesoderm development. Hence the actin polymerization machinery functions in both somatic and visceral muscle fusion, but this process only appears to be essential in somatic muscle development. / Exploiting Drosophila as a model system for studying Anaplastic Lymphoma Kinase in vivo

Anaplastic lymphoma kinase

Receptor tyrosine kinase

Jeb

neuroblastoma

actin polymerization

Wasp

Scar

Vrp1

Arp2/3

Molecular biology

Molekylärbiologi

A Mitotic Actin Regulating Pathway Induces Chromosomal Instability In Human Cancer Cells

Glaubke, Elina

28 April 2020

No description available.

570

Cancer

Chromosomal Instability

Actin

Microtubule

EB1

TRIO

Rac1

Arp2/3

Cortex architecture

Cortex tension

Biologie (PPN619462639)

Étude mécanique des gels d'actine branchés

Pujol, Thomas

11 December 2012

Les réseaux formés par les filaments d'actine jouent un rôle fondamental en mécanique cellulaire, puisqu'ils contribuent grandement à la forme des cellules, à leur capacité à migrer et à leurs propriétés mécaniques. Durant ma thèse, nous nous sommes intéressés aux propriétés mécaniques des gels d'actine branchés présents dans le lamellipode. Dans le cadre de ma thèse, nous avons développé une nouvelle technique de mesure basée sur l'attraction dipolaire entre des colloïdes magnétiques nous permettant de mesurer le module de Young de gels d'actine reconstitués à la surface des particules à l'aide de la machinerie Arp2/3. Notre technique nous permet de réaliserun très grand nombre de mesures.Les faibles barres d'erreur ainsi obtenues nous ont permis d'étudier, pour la première fois, le lien entre les propriétés microscopiques architecturales des gels et leur réponse mécanique. Nous avons observé une forte rigidification du gel avec une augmentation de la concentration en protéine nucléatrice des branches Arp2/3 et en protéine de coiffe gelsoline durant la croissance du gel, montrant ainsi un lien entre l'architecture du réseau et son élasticité. De plus, nous avons étudié le lien entre le module élastique des gels, la flexibilité des filaments et l'augmentation des contraintes internes. Ces différentes études pointent en direction d'une réponse mécanique des gels d'actine à structure dendritique d'origine enthalpique, contrairement aux gels d'actine polymérisés en solution, dont l'élasticité est d'origine entropique.

actine

cytosquelette

réseau dendritique

force magnétique dipolaire

élasticité enthalpique

polymère semi-flexible

machinerie Arp2/3

Regulation Of Spindle Orientation By A Mitotic Actin Pathway In Chromosomally Unstable Cancer Cells

Schermuly, Nadine

07 January 2020

No description available.

570

Cancer

Chromosomal Instability

Spindle Orientation

Microtubule

Actin

Rac1

Arp2/3

TRIO

Cortex Tension

Cortex Architecture

Spindle Axis Misalignment

Biologie (PPN619462639)

THE MEMBRANE BLOCK TO POLYSPERMY IN MAMMALIAN EGGS; ANALYSES OF CALCIUM SIGNALING AND ACTIN DYNAMICS DURING FERTILIZATION

Nicole Leigh Branca (15353446)

27 April 2023

<p>    </p> <p>When mammalian eggs are fertilized, they undergo an egg-to-embryo transition during which different egg activation events take place. Egg activation events include the establishment of blocks to polyspermy, which prevent multiple sperm from fertilizing an egg. One of these blocks to polyspermy occurs at the level of the egg plasma membrane (the membrane block to polyspermy). Previous work in our lab provides evidence that the mammalian membrane block to polyspermy is mediated by sperm-induced calcium signaling and the egg’s actomyosin cytoskeleton (McAvey et al., 2002). This thesis research builds upon this foundation, testing hypotheses about two specific effector molecules, one involved in calcium signaling and one with the actin cytoskeleton, and also developing the use of an actin probe for live-cell imaging, with the goal of imaging actin dynamics in eggs undergoing fertilization. Specifically, we examined the calcium effector molecule Ca2+/Calmodulin-dependent-protein kinase IIg (<strong>CaMKII</strong>g), based on previous studies showing that CaMKII plays a role in the membrane block (Gardner et al., 2007) and that the g isoform of CaMKII is necessary and sufficient for eggs to complete meiosis (Backs et al., 2010). We tested the hypothesis that CaMKIIg would mediate the membrane block to polyspermy but found that egg activation driven by expression of a constitutively active form of CaMKIIg was not sufficient to establish the membrane block. Our studies of the actin cytoskeleton focused on the Arp2/3 complex as a candidate. We tested the hypothesis that Arp2/3, which mediates actin filament branching, was involved in membrane block establishment, building on the finding that disruption of actin with the drug cytochalasin D impairs the membrane block (McAvey et al., 2022). These studies used the Arp2/3 inhibitor CK666, predicting that we would see increased sperm incorporation in CK666-treated eggs. However, an assay of sperm incorporation over time indicated that Arp2/3 may not play a significant role in the membrane block to polyspermy, although follow-up studies will be beneficial. Lastly, the actin probe SiR- Actin was assessed for use on oocytes undergoing live-cell imaging during meiosis I and II. Oocytes were treated with differing concentrations of SiR-Actin and live cell imaged while maturing through meiosis I or completing meiosis II. Higher doses and longer exposure to SiR- Actin caused abnormalities in oocytes during meiosis I but not in eggs completing meiosis II. Together, this work sets the stage of a range of future studies into the mammalian membrane block to polyspermy. </p>

Reproduction

Membrane Block to Polyspermy

mammalian fertilization

ARP2/3 complex

CaMKII y

Calcium signaling

actin cytoskeletal dynamics

Oocyte Meiosis

SiR-Actin

actin probes

Live cell imaging analysis