Exploring promoter silencing and re-expression of SH3GL2/endophilin A1 in urothelial cancer

Zucker, Isaac Jake

03 July 2018

INTRODUCTION: Bladder cancer (BC) is highly prevalent. It presents as either non-muscle invasive or muscle-invasive disease. The prognosis of muscle invasive disease is poor, with a 5-year survival rate of less than 50%. Treatment approaches for both types of BC have not advanced much in the last few years and new therapies are needed to overcome the large burden of BC. Recently, a large effort has been undertaken to classify BC into molecular subtypes. These analyses have revealed significant alterations in epigenetic modifiers in BC. A previous study from our group revealed that SH3GL2, a negative regulator of receptor tyrosine kinase (RTK) signaling, was lost with high frequency in BC, leading to increased growth of tumor cells in-vitro and in-vivo. Conversely, forced expression of SH3GL2 in BC cell lines attenuated oncogenic behaviors including growth and migration. In addition to genomic deletion, SH3GL2 is subject to methylation-induced silencing, a key epigenetic mechanism. OBJECTIVE: Epigenetic mechanisms of gene regulation are known to be perturbed in BC. The objectives of this study were to investigate methylation of the SH3GL2 promoter and to test whether agents that promote Deoxyribonucleic acid (DNA) demethylation could be used to re-express SH3GL2 thereby restoring regulation of RTK signaling. METHODS: Methylation of a specific CpG island in the SH3GL2 promoter was analyzed using methylation-specific Polymerase Chain Reaction (PCR) in a panel of BC cell lines with known SH3GL2 messenger Ribonucleic Acid (mRNA) status. Selected BC cell lines were treated with a variety of demethylating agents at different doses and for different times to evoke the re-expression of silenced SH3GL2. Demethylation inhibitors were combined with the histone deacetylase inhibitor, trichostatin A (TSA), to determine whether further re-expression could be achieved. RESULTS: The SH3GL2 promoter displayed differing extents of promoter methylation among cell lines examined. In RT4 cells, the only cell line with detectable expression of SH3GL2 mRNA and protein, the promoter was completely unmethylated. In contrast, T24 and 253J cells displayed significant promoter methylation with little to no SH3GL2 mRNA expressed, consistent with methylation-induced silencing. Treatment of T24 and 253J with 5-Aza-2’-deoxycytidine (5-Aza-dC, 20 M), a DNA methyltransferase (DNMT) inhibitor increased gene expression but this was not dose- or time-dependent. Two additional DNMT inhibitors, Zebularine and RG-108 were also tested. A much higher dosage of Zebularine was required to trigger activation (500 M) while RG-108 was unable to trigger gene reactivation at all. Combination treatment with 5-Aza-dC and TSA further increased SH3GL2 expression compared to either agent alone. These results suggest that DNA methyltransferase inhibition is an effective treatment to re-express SH3GL2 in cells with SH3GL2 promoter silencing. CONCLUSION: The present study shows silencing of SH3GL2 in a variety of BC cell lines as a consequence of DNA promoter hypermethylation. Treatment with demethylating agents was able to increase gene expression. Based on prior findings showing attenuation of tumor cell growth and migration with forced expression of SH3GL2, DNA methyltransferase inhibition represents an effective strategy to re-express SH3GL2 in BC and normalize tumor cell behavior. / 2020-07-03T00:00:00Z

Oncology

Bladder cancer

Demethylation

Endophilin

Epigenetic

SH3GL2

Understanding membrane curvature sensing

Colussi, Adeline

January 2017

Eukaryotic cells are characterised by membranes with varied and dynamic compositions and shapes. Consequently, membrane-binding proteins are tuned to recognise and modify these membrane states to perform their functions. To study the curvature sensitivity of proteins, I have developed a single-particle assay using NanoSight technology that tracks the Brownian motion of particles to measure their size. I optimised this system to track fluorescently labelled lipid-binding domains bound to liposomes of different sizes moving freely in solution. The comparison of the size distribution of the total liposomes with the fluorescently labelled population allowed me to determine their curvature preferences. To validate the method I tested proteins from the Bin/Amphiphysin/Rvs (BAR) superfamily, which are inherently curved and have known curvature preferences. My method was capable of recapitulating the behaviour of BAR domains with different curvature preferences. I then expanded the range of targets and showed that this assay is also capable of detecting curvature preferences for a variety of other lipid-binding domain families. As such, I identified AKT PH domain as a new curvature-sensing domain. Finally, using the ENTH domain of Epsin1 that causes vesicle budding, I demonstrated that this method can also be used to study membrane remodelling. Trafficking involves generation and sensing of membrane curvature combined with recognition of specific cargo. Endophilin consists of a curvature-sensitive BAR domain followed by an SH3 (Src-homology 3) domain and has recently been identified in a clathrin-independent endocytosis pathway, FEME (fast endophilin-mediated endocytosis), involved in the uptake of cell surface receptors. Endophilin recognises ligands via its SH3 domain, binding G-protein coupled receptors (GPCRs) directly in their intracellular loop 3 and receptor tyrosine kinase (RTKs) via adaptor proteins. However, a specific recognition motif has not been identified yet. Here, using a combination of biophysical approaches and NMR spectroscopy, I characterised the Endophilin binding motif of ALIX (ALG-2-interacting protein X) adaptor protein and of the GPCR $\alpha$2A adrenergic receptor. Comparison of SH3-peptide models resulted in a putative Endophilin recognition site.

Le rôle des protéines courbant les membranes dans l’endocytose indépendante de la clathrine suivie par le récepteur de l’interleukine 2 / The role of membrane-bending proteins in clathrin-independent endocytosis used by the interleukin 2 receptor

Bertot, Laëtitia

15 December 2016

L’endocytose permet l’internalisation d’éléments présents dans le milieu extracellulaire tels que les nutriments. Ce processus prend place dans la membrane plasmique. Les courbures de la membrane jouent un rôle essentiel dans l’endocytose pour générer une invagination initiale, un puits, puis une vésicule qui se sépare ensuite de la membrane plasmique pour fusionner avec les compartiments intracellulaires. Il existe plusieurs voies d’endocytose qui peuvent être classées selon des critères tels que la taille des vésicules produites, la médiation par un récepteur ou la présence d’un manteau recouvrant les vésicules. La voie d’endocytose la mieux caractérisée est celle dépendante de la clathrine. Mon laboratoire d’accueil travaille sur l’entrée du récepteur de l’interleukine 2 (IL-2R). Ce récepteur peut entrer de façon constitutive ou induite en présence de son ligand l’IL-2. Les deux voies sont indépendantes de la clathrine. Lors de mon arrivée dans le laboratoire, ces voies étaient encore peu caractérisées, notamment les facteurs induisant les courbures membranaires restaient à identifier. Ces facteurs doivent être particulièrement impliqués car les vésicules contenant l’IL-2R sont dépourvues de manteaux. Un crible par interférence à ARN, réalisé avant mon arrivée avait permis de proposer des protéines candidates pouvant courber les membranes. La première partie de ma thèse a consisté à confirmer l’importance de certaines protéines issues de ce crible puis à étudier leurs rôles dans la voie constitutive de l’IL-2R. Parmi ces protéines confirmées, deux familles de facteurs étaient particulièrement intéressantes pour leur capacité à courber les membranes, les phospholipases D et les endophilines. Ces dernières ont permis d’identifier une nouvelle voie d’entrée nommée « Fast Endophilin Mediated Endocytosis » FEME dans laquelle l’endophiline joue un rôle essentiel et qui est empruntée par de nombreux récepteurs transmettant le signal. La voie FEME partage plusieurs facteurs communs avec la voie d’endocytose induite de l’IL-2R. Pour finir, mes travaux de thèse ont porté sur l’orchestration de l’endophiline et de la dynamine dans la voie d’endocytose constitutive de l’IL-2R. Ces deux facteurs sont impliqués en fin d’endocytose, pour scinder les vésicules de la membrane plasmique. Cependant, ces deux protéines n’ont pas la même orchestration. Nos travaux montrent une action distincte de l’endophiline et de la dynamine dans les voies d’endocytose dépendante et indépendante de la clathrine. / Endocytosis allows the uptake of elements from the extracellular fluid such as nutriments. This process takes place at the plasma membrane. The membrane curvatures play an important role in endocytosis for the production of initial invagination to form a pit that will be then separate from the plasma membrane and will go to the intracellular compartments. Several routes of endocytosis exist and can be classified depending on vesicles size formed, receptor mediated endocytosis or coat on vesicles. The well-known characterized endocytosis pathway is the clathrin mediated one. My lab is working on interleukin 2 receptor (IL-2R) entry. This receptor can enter either constitutively or upon induction by the ligand IL-2. Both uptake pathways are independent of clathrin. When I arrived in the lab, those pathways were still under characterization, in particular the factors inducing the membrane curvature. Their role should be important since IL-2R containing vesicles are coated free. A small interfering RNA screen performed before my phD, allowed to identify new candidates. The first part of my thesis was to verify the involvement of some of them in the IL-2R constitutive pathway and then to study their role in this pathway. Among them, 2 families of proteins were particularly interesting as they can curve membranes, phospholipases D and endophilins. The endophilin allowed the discovery of a new route called “Fast Endophilin Mediated Endocytosis” (FEME) in which it plays an essential role and which is used by numerous receptors that transmit signal. The FEME pathway shares several factors that are common with the IL-2 induced endocytosis pathway. Then, I conducted a work on the orchestration of endophilin and dynamin during the constitutive IL-2R endocytosis. Both factors are recruited at the end of the mechanism, to separate the vesicles from the plasma membrane. However, both proteins do not have the same orchestration. Our works show a distinct action of endophilin and dynamin in clathrin dependent and independent endocytosis.

Cytokine

Endocytose

Endophiline

Dynamine

Membrane

Cytokine

Endocytosis

Endophilin

Dynamin

Membrane

Modulations of Lipid Membranes Caused by Antimicrobial Agents and Helix 0 of Endophilin

Khadka, Nawal Kishore

02 July 2019

Understanding the cellular membrane interaction with membrane active biomolecules and antimicrobial agents provides an insight in their working mechanism. Here, we studied the effect of antimicrobial agents; a recently developed peptidomimetics E107-3 and colistin as well as the N-terminal helix H0, of Endophilin A1 on the lipid bilayer. It is important to discern the interaction mechanism of antimicrobial peptides with lipid membranes in battling multidrug resistant bacterial pathogens. We study the modification of structural and mechanical properties with a recently reported peptidomimetic on lipid bilayer. The compound referred to as E107-3 is synthesized based on the acylated reduced amide scaffold and has been shown to exhibit good antimicrobial potency. This compound increases lipid bilayer permeability as indicated by our vesicle leakage essay. Micropipette aspiration experiment shows that exposure of GUV to the compound causes the protrusion length Lp to spontaneously increase and then decrease, followed by GUV rupture. Solution atomic force microscopy (AFM) is used to visualize lipid bilayer structural modulation within a nanoscopic regime. This compound induces nanoscopic heterogeneous structures rather than pore like structures as produced by melittin. Finally, we use AFM-based force spectroscopy to study the impact of the compound on lipid bilayer’s mechanical properties. With the incremental addition of this compound, we found the bilayer puncture force decreases moderately and a 39% decrease of the bilayer area compressibility modulus KA. To explain our experimental data, we propose a membrane interaction model encompassing disruption of lipid chain packing and extraction of lipid molecules. The later action mode is supported by our observation of a double-bilayer structure in the presence of fusogenic calcium ions. Polyanionic Lipopolysaccharides LPS are important in regulating the permeability of outer membrane (OM) of gram-negative bacteria. To initiate the bactericidal activity of polymyxins, it is essential to impair the LPS-enriched OM. Here, we study the mechanism of membrane permeability caused by colistin (Polymyxin E) of LPS/phospholipid bilayers. Our vesicle leakage experiment showed that colistin binding enhanced bilayer permeability; the maximum increase in the bilayer permeability was positively correlated with the LPS fraction. Addition of magnesium ions abolished the effect of LPS in enhancing bilayer permeabilization. Solution atomic force microscopy (AFM) measurements on planar lipid bilayers shows the formation of nano- and macro clusters which protruded from the bilayer by ~2nm. Moreover, increasing the fraction of LPS or colistin enhances the formation of clusters but inhibits by magnesium ions addition. To explain our experimental data, we proposed a lipid-clustering model where colistin binds to LPS to form large-scale complexes segregated from zwitterionic phospholipids. The discontinuity (and thickness mismatch) at the edge of LPS-colistin clusters will create a passage that allows solutes to permeate through. The proposed model is consistent with all data obtained from our leakage and AFM experiments. Our results of LPS-dependent membrane restructuring provided useful insights into the mechanism that could be used by polymyxins in impairing the permeability barrier of the OM of Gram-negative bacteria. Also, we studied the effect of helix H0 of a membrane modification inducing protein endophilin, on planar bilayer. We obtained transmembrane defects on the bilayer when scanned.with AFM.

AFM

Colistin

Endophilin H0

GUV

Lipid Bilayer

Peptidomimetics

Biophysics

Physics

Onset and Progression of Neurodegeneration in Mouse Models for Defective Endocytosis

Rostosky, Christine Melina

09 November 2018

No description available.

570

Neurodegeneration

Endophilin

Endocytosis

Fbxo32

Motor Behavior

endophilin-A

E3 ubiquitin ligase

autophagy

synaptojanin

dynamin

mouse model

motor coordination

gait

rotarod

aging

Biologie (PPN619462639)

New intracellular mechanisms involved in Alzheimer's disease and frontotemporal dementia

Borger, Eva

January 2012

Dementia causes an increasing social and economic burden worldwide, demanding action regarding its diagnosis, treatment and everyday management. Recent years have seen many advances in neurodegeneration research, but the search for new truly disease modifying therapies for Alzheimer's disease (AD) and frontotemporal dementia (FTD) has so far not been successful. This is mainly due to a lack of understanding of the precise intracellular events that lead up to neuronal dysfunction in early and in late stages of the disease. This thesis describes the approaches taken to extend the current knowledge about the intracellular effects of neuronal amyloid-beta and the signalling pathways causing neuronal death or disturbed synaptic function in dementia. Endophilin-1(Ep-1), amyloid-binding alcohol dehydrogenase (ABAD), peroxiredoxin-2 (Prx-2) and the EF-hand domain family, member D2 (EFHD2) have been found to be elevated in the human brain with dementia and in mouse models for frontotemporal lobar degeneration (FTLD) or AD. The expression of these proteins as well as the expression of c-Jun N-terminal kinase (JNK), c-Jun and APP were analysed by western blotting and real-time PCR in human brains affected by AD or FTLD as well as in mouse models for AD. This provided a new insight into the regulation of these proteins in relation to each other in the ageing brain and uncovered a new potential link between elevated levels of EFHD2, Prx-2 and APP in FTLD. By studying the effects of the overexpression of Ep-1 in neurons, this research has led to a better understanding of its role in JNK-activation. It furthermore verified a protective role for Prx-2 against neurotoxicity and pointed towards a new function for Prx-2 in the regulation of JNK-signalling. The analysis of the effect of increased levels of EFHD2 uncovered for the first time its involvement in the PI3K-signalling cascade in neuronal cells. The current work has therefore contributed to the knowledge about the cellular processes that are affected by Ep-1, Prx-2 and EFHD2 in different types of dementia and will greatly benefit future research into their actions in the neuronal network.

616.8

Molecular mechanisms of synaptic vesicle recycling with a focus on Endophilin A and Rabconnectin-3a

Gowrisankaran, Sindhuja

01 November 2021

No description available.

570

Synaptic vesicle recycling

Vesicle acidification

endophilin in exocytosis

rabconnectin-3a

Biologie (PPN619462639)

Importance de la phosphorylation de la ligase Itch dans la reconnaissance et l'ubiquitylation des protéines à domaine SH3

Forget, Rachel

02 1900

Itch est une ligase de l’ubiquitine impliquée dans la reconnaissance et la dégradation des protéines par le protéasome. Itch contient trois sites phosphorylés par JNK et il a été démontré que la phosphorylation de ces résidus est nécessaire pour que Itch puisse reconnaître et ubiquityler les protéines c-Jun et JunB. Ces sites de phosphorylation se retrouvent dans le domaine PRD responsable des interactions de Itch avec les protéines à domaine SH3. Si la phosphorylation de Itch par JNK est importante pour réguler son activité avec c-Jun et JunB, on connaît peu de choses sur les interactions de Itch avec les protéines à domaine SH3 ainsi que l’implication de la phosphorylation dans leur régulation. Nous avons donc créé des mutants de Itch par mutagenèse dirigée où les sites de phosphorylation étaient remplacés par des alanines (mutant non phosphorylable) et où l’un des trois sites était remplacé par un acide aspartique (mutant constitutivement phosphorylé). Ces mutants sont utilisés dans des tests d’interaction et d’ubiquitylation, dans le but de déterminer l’impact de la phosphorylation de Itch dans la reconnaissance et l’ubiquitylation des protéines SH3. Nos résultats montrent que, contrairement au modèle proposé, la phosphorylation de Itch n’est pas essentielle à l’interaction de Itch avec l’endophiline, mais la phosphorylation de Itch module l’ubiquitylation ainsi que la dégradation de l’endophiline. La régulation de l’interaction de Itch avec ses substrats est donc différente selon le substrat. / Itch is an ubiquitin ligase involved in protein recognition and degradation by the proteasome. Itch has three phosphorylation sites targeted by JNK. These sites overlap a small proline rich domain responsible for Itch binding to SH3 domain proteins. Phosphorylation of Itch is important for Itch interaction with c-Jun and JunB. However, little is known about Itch interaction with SH3 proteins and the impact of phosphorylation on Itch ability to recognize and ubiquitinate SH3 proteins. We created a phosphomimic mutant of Itch and a mutant of Itch that cannot be phosphorylated by JNK. We tested these mutants in interaction and ubiquitination assays to determine their effect on Itch ability to bind and ubiquitinate Endophilin, an SH3 domain protein. Phosphorylation is not a prerequisite for Itch binding to Endophilin but phosphorylation of Itch modulates Itch ability to ubiquitinate Endophilin. Phosphorylation of Itch also modulates Endophilin fate, as phosphomimic Itch induces degradation of Endophilin compared to non-phosphorylated Itch. These results show that phosphorylation regulates Itch activity towards differents substrates in different ways.

Itch

ubiquitylation

phosphorylation

endophiline

JNK

régulation

ubiquitination

Endophilin

interaction

SH3 proteins

Importance de la phosphorylation de la ligase Itch dans la reconnaissance et l'ubiquitylation des protéines à domaine SH3

Forget, Rachel

02 1900

Itch est une ligase de l’ubiquitine impliquée dans la reconnaissance et la dégradation des protéines par le protéasome. Itch contient trois sites phosphorylés par JNK et il a été démontré que la phosphorylation de ces résidus est nécessaire pour que Itch puisse reconnaître et ubiquityler les protéines c-Jun et JunB. Ces sites de phosphorylation se retrouvent dans le domaine PRD responsable des interactions de Itch avec les protéines à domaine SH3. Si la phosphorylation de Itch par JNK est importante pour réguler son activité avec c-Jun et JunB, on connaît peu de choses sur les interactions de Itch avec les protéines à domaine SH3 ainsi que l’implication de la phosphorylation dans leur régulation. Nous avons donc créé des mutants de Itch par mutagenèse dirigée où les sites de phosphorylation étaient remplacés par des alanines (mutant non phosphorylable) et où l’un des trois sites était remplacé par un acide aspartique (mutant constitutivement phosphorylé). Ces mutants sont utilisés dans des tests d’interaction et d’ubiquitylation, dans le but de déterminer l’impact de la phosphorylation de Itch dans la reconnaissance et l’ubiquitylation des protéines SH3. Nos résultats montrent que, contrairement au modèle proposé, la phosphorylation de Itch n’est pas essentielle à l’interaction de Itch avec l’endophiline, mais la phosphorylation de Itch module l’ubiquitylation ainsi que la dégradation de l’endophiline. La régulation de l’interaction de Itch avec ses substrats est donc différente selon le substrat. / Itch is an ubiquitin ligase involved in protein recognition and degradation by the proteasome. Itch has three phosphorylation sites targeted by JNK. These sites overlap a small proline rich domain responsible for Itch binding to SH3 domain proteins. Phosphorylation of Itch is important for Itch interaction with c-Jun and JunB. However, little is known about Itch interaction with SH3 proteins and the impact of phosphorylation on Itch ability to recognize and ubiquitinate SH3 proteins. We created a phosphomimic mutant of Itch and a mutant of Itch that cannot be phosphorylated by JNK. We tested these mutants in interaction and ubiquitination assays to determine their effect on Itch ability to bind and ubiquitinate Endophilin, an SH3 domain protein. Phosphorylation is not a prerequisite for Itch binding to Endophilin but phosphorylation of Itch modulates Itch ability to ubiquitinate Endophilin. Phosphorylation of Itch also modulates Endophilin fate, as phosphomimic Itch induces degradation of Endophilin compared to non-phosphorylated Itch. These results show that phosphorylation regulates Itch activity towards differents substrates in different ways.

Itch

ubiquitylation

phosphorylation

endophiline

JNK

régulation

ubiquitination

Endophilin

interaction

SH3 proteins

Comparaison de l’ubiquitylation de différentes protéines à domaine SH3 impliquées dans l’endocytose suite à leur interaction avec la ligase de l’ubiquitine Itch

Desrochers, Guillaume

03 1900

Itch est la seule ligase de l'ubiquitine de type C2-WW-HECT capable d'interagir avec les protéines à domaine SH3. Ce domaine est particulièrement représenté parmi les protéines régulatrices de l'endocytose. Les travaux présentés ici visaient à examiner la capacité d'Itch à interagir avec plusieurs protéines endocytiques. Nous avons utilisé la technique du BRET (Bioluminescence Resonance Energy Transfer) pour examiner quelques protéines candidates. Nous avons ensuite confirmé les résultats obtenus par BRET avec des tests d'interaction in vitro, puis déterminé la capacité d'Itch à ubiquityler les protéines liées via leurs domaines SH3. Nous avons ainsi découvert deux nouveaux partenaires d'interaction et substrats d'Itch parmi les protéines endocytiques, amphyphisine et pacsine. De plus, Itch interagit avec les domaines SH3 isolés d'intersectine, mais pas avec la protéine complète, suggérant que cette dernière n'est pas un substrat d'Itch. Itch est donc bien positionnée pour exercer un rôle régulateur de l'endocytose en ubiquitylant ses substrats. / Itch is the only C2-WW-HECT type ubiquitin ligase that can bind SH3 domain proteins. This domain is particularly frequent in accessory endocytic proteins. We have used Bioluminescent Resonance Energy Transfer to examine a few candidate endocytic proteins, in addition to the already known substrate of Itch, endophilin. We then used standard in vitro techniques to confirm these interactions, and tested Itch capacity to ubiquitylate these putative substrate proteins. We thus discovered two new substrates of Itch, amphiphysin and pacsin. We also determined that although Itch interacts with the isolated SH3 domains of intersectin, it does not recognize the full length protein, thus rulling out Intersectin as a substrate of Itch. Itch is thus a putatively important regulator of endocytosis, through its capacity to recognize and ubiquitylate several SH3-domain proteins.

Itch

Endophiline

Pacsine

Intersectine

Amphiphysine

BRET

Ubiquitine

Endocytose

Endophilin

Pacsin

Intersectin

Amphiphysin

Ubiquitin

Endocytosis