Etude de la cycline A2 : interactions, dégradation et mise en évidence du rôle de l'autophagie / Study of cyclin A2 : interactions, degradation and a new the role of autophagy

Loukil, Abdelhalim

03 December 2012

Le cycle cellulaire est finement régulé dans le temps et l'espace. Nous avons abordé les aspects dynamiques des interactions que la cycline A2 entretient avec ses partenaires Cdk1, Cdk2 et l'ubiquitine au cours du cycle cellulaire, dans des lignées cellulaires humaines. A cette fin, nous avons eu recours aux approches de FRET (Förster/fluorescence resonance energy transfer) et de FLIM (fluorescence lifetime imaging microscopy). Ceci nous a permis de montrer que les formes ubiquitinylées de la cycline A2 apparaissent principalement sous forme de foyers en prométaphase et se propagent ensuite à l'ensemble de la cellule. En outre, nous avons découvert que l'autophagie participe à la dégradation de cette cycline en mitose. Nous discutons les implications de ces observations quant à un rôle éventuel de la cycline A2 au moment de la formation de l'anneau de constriction, ainsi que de la participation de l'autophagie via cette cycline, dans la réponse aux dommages à l'ADN en mitose. / The cell cycle is finely regulated in time and space. We have studied the dynamical aspect of the interactions between cyclin A2 and its partners Cdk1, Cdk2 and ubiquitin during the cell cycle, in human cell lines. To this aim, we have used FRET (Förster/fluorescence resonance energy transfer) and FLIM (fluorescence lifetime imaging microscopy) techniques. We have thus shown that ubiquitylated forms of cyclin A2 are detected predominantly in foci in prometaphase, before spreading throughout the cell. Moreover, we have shown that autophagy contributes to cyclin A2 degradation in mitosis. We discuss the implications of these observations regarding a possible role of cyclin A2 when the cleavage furrow forms, and the participation of autophagy in DNA damage response in mitosis.

Cycline A2

Mitose

Ubiquitine

Protéasome

Autophagie

Fret/flim

Cyclin A2

Mitosis

Ubiquitin

Proteasome

Autophagy

Fret/flim

Development and analysis of recombinant fluorescent probes for use in live cell imaging of filamentous fungi

Altenbach, Kirsten

January 2010

The molecular cloning and subsequent engineering of the green fluorescent protein (GFP) of the jellyfish Aequoria victoria allowed a novel approach to the investigation of cell signalling. GFP and its mutants can now not only be used to target specific organelles in living cells but also function as a basis for a variety of sensors for biologically important ions and molecular interactions. GFP-based Ca2+- sensors have been successfully used for studies in mammalian and plant cells. In filamentous fungi, however, they have not yet been reported to work. Since only little is known about calcium signalling in filamentous fungi, this project aimed to improve existing GFP-based Ca2+- sensors by exchanging the original fluorophores for improved versions and expressing those in the filamentous fungus Aspergillus niger. During this project, the donor and acceptor fluorophores of 3 existing Ca2+-FRETprobes based on cameleons and troponin C-sensors, have been changed, 2 novel positive FRET controls have been designed and these , as well as donor and acceptor fluorophores alone, have been expressed in the filamentous fungus Aspergillus niger. The probes were assessed using different imaging techniques, such as conventional confocal laser scanning microscopy (CLSM), fluorescence lifetime imaging microscopy (FLIM) and spectral imaging using a Leica TSC SP5 confocal and IRIS, a novel spectral imaging device designed at Heriot Watt University. Problems were encountered that prevented FRET analysis using CLSM and IRIS. These were due mainly to the difference in expression level of the constructs and the distribution of the emission bandpasses of the IRIS system. Analysis of the spectral data obtained on the Leica confocal system and analysis of the FLIM results, however, revealed significant differences between the donor only and the positive FRET controls. Spectra of the positive FRET controls and the Ca2+-sensitive probes showed emission peaks of both the donor and the acceptor fluorophores upon excitation of the donor fluorophore alone while analysis of the FLIM results revealed an additional decay component in the positive FRET controls. Both results are very strong indicators that we can detect FRET in living hyphae of Aspergillus niger transformed with the probes designed during this project.

571.4

FRET analysis of splicing factors involved in exon and intron definition in living cells

Ellis, Jonathan

January 2008

I have analyzed the interactions between SR proteins and splicing components that are bound at the 5’ or 3’ splice site using fluorescence resonance energy transfer (FRET) microscopy. The SR proteins interact with the U1 snRNP-associated 70 kDa protein (U170K) at the 5’splice site and with the small subunit of the U2 snRNP auxiliary factor (U2AF35) at the 3’ splice site. These interactions have been extensively characterized biochemically in the past, and are proposed to play roles in both intron and exon definition. We employed FRET acceptor photobleaching and fluorescence lifetime imaging microscopy (FLIM) to identify and spatially localise sites of direct interactions of SF2/ASF, and other SR proteins, with U2AF35 and U1-70K in live cell nuclei. These interactions were shown to occur more strongly in interchromatin granule clusters (IGCs). They also occur in the presence of the RNA polymerase II inhibitor, DRB, demonstrating that they are not exclusively co-transcriptional. FLIM data have also revealed a novel interaction between HCC1, a factor highly related to the large subunit of the U2AF splicing factor, with both subunits of U2AF that occur in discrete domains within the nucleoplasm but not within IGCs. These data demonstrate that the interactions defining intron and exon definition do occur in living cells in a transcription-independent manner.

571.4

Spatiotemporal Dynamics of Calcium/calmodulin-dependent Kinase II in Single Dendritic Spines During Synaptic Plasticity

Lee, Seok-Jin

January 2011

<p>Synaptic plasticity is the leading candidate for the cellular/molecular basis of learning and memory. One of the key molecules involved in synaptic plasticity is Calcium/calmodulin-dependent Kinase II (CaMKII). Synaptic plasticity can be expressed at a single dendritic spine independent of its neighboring dendritic spines. Here, we investigated how long the activity of CaMKII lasts during synaptic plasticity of single dendritic spines. We found that CaMKII activity lasted ~2 minutes during synaptic plasticity and was restricted to the dendritic spines undergoing synaptic plasticity while nearby dendritic spines did not show any change in the level of CaMKII activity. Our experimental data argue against the persistent activation of CaMKII in dendritic spines undergoing synaptic plasticity and suggest that the activity of CaMKII is a spine-specific biochemical signal necessary for synapse-specificity of synaptic plasticity. We provide a biophysical explanation of how spine-specific CaMKII activation can be achieved during synaptic plasticity. We also found that CaMKII is activated by highly localized calcium influx in the proximity of Voltage-dependent Calcium Channels (VDCCs) and a different set of VDCCs and their respective Ca2+ nanodomains are responsible for the differential activation of CaMKII between dendritic spines and dendritic shafts.</p> / Dissertation

Neurosciences

Calcium Nanodomain

CaMKII

Dendritic Spine

FRET/FLIM

Synaptic Plasticity

Two-photon microscopy

Orientation and organization of the presynaptic active zone protein Bassoon: from the Golgi to the synapse

Ghelani, Tina

12 May 2016

No description available.

570

Bassoon

AZ assembly

STED imaging

FRET-FLIM imaging

Super-resolution imaging

Cytomatrix of the active zone

Orientation of Active Zone (AZ) proteins

Biologie (PPN619462639)