Over the last ten years, the joint effort of the platform PLATIM and the laboratory of Plant Development and Reproduction (RDP) has developed a strong and recognized expertise in the imaging and quantification of cell mechanical properties in living plant issues. Specific pipelines have been developed to map and quantify:
1. Wall mechanical properties through direct measurements of key parameters such as wall stiffness, adhesion, and resistance to piercing, using AFMs and nano-indenters
2. Cell hydrostatic pressure through stiffness measurements made using AFMs or nano-indenters and the subsequent application of physical models but also through the development of a nano-pressure probe (in progress).
In addition of the originality of these technological approaches in mecanotransduction, the interest of our R&D teams is to develop and support their evolution directly into the environment of an IBiSA core facility. Thus, the R&D Team PLATIM/RDP is one of the rare facilities in France to provide different and integrated mechanical evaluations for both plant and animal multicellular organisms.
Publications:
- Bauer, A., Ali, O., Bied, C., Boeuf, S., Bovio, S., Delattre, A., Ingram, G., Golz, J.F. & Landrein, B. Spatiotemporally distinct responses to mechanical forces shape the developing seed of Arabidopsis. (2024) EMBO J. https://doi.org/10.1038/s44318-024-00138-w
- Creff, A., Ali, O., Bied, C., Bayle, V., Ingram, G. & Landrein, B. Evidence that endosperm turgor pressure both promotes and restricts seed growth and size. (2023) Nature Comm. https://www.nature.com/articles/s41467-022-35542-5
Since 2010, we have developped and implemented numerous methods in optogenetics, and even chemogenetics, in order to have access to dynamics and reversible perturbations of key biological functions such as cell adhesion, cell signaling, transcription factors, inflammation, functions of immune cells and even metabolism. Our lab proposes to share this expertise to the FBI users through access for consulting and even direct collaboration. In the Rhonalpin node, our lab is focused on the coupling between optogenetics, biosensors and metabolism imaging through FLIM imaging. Indeed, we have developed a TIRF microscope presenting a module of FastFLIM imaging. Through the use of dark acceptors, this technology allows the users to extend the possibilities in terms of combining optogenetics, biosensors, metabolic imaging through ratiometric probes and classical multicolors TIRF imaging. Moreover, TIRF imaging allows long term live imaging with low levels of photoxicity. This is essential for metabolic imaging and preserving photon budget for FLIM imaging. In the future, this system will be coupled with a module of evanescent field patterning (EFP) in order to have a specific TIRF-mode illumination of only a region of interest (microm scale).
Publications
1- An optogenetic approach to control and monitor inflammasome activation. Julien Nadjar, Sylvain Monnier, Estelle Bastien, Anne-Laure Huber, Christiane Oddou, Léa Bardoulet, Gabriel Ichim, Christophe Vanbelle, Bénédicte Py, Olivier Destaing*, Virginie Petrilli*. Recently accepted in Science Signaling. bioRxiv 2023.07.25.550490; doi: https://doi.org/10.1101/2023.07.25.550490
2-Optogenetic control of YAP cellular localisation and function. Toh PJY, Lai JKH, Hermann A, Destaing O, Sheetz MP, Sudol M, Saunders TE. EMBO Rep. 2022 Sep 5;23(9):e54401.
3-Control of SRC molecular dynamics encodes distinct cytoskeletal responses by specifying its signaling pathway usage. Kerjouan A, Boyault C, Oddou C, Hiriart-Bryant E, Pezet M, Balland M, Faurobert E, Bonnet I, Coute Y, Fourcade B, Albiges-Rizo C, Destaing O. J Cell Sci. 2021 Jan 25;134(2):jcs254599.
4-β1A integrin is a master regulator of invadosome organization and function. Destaing O, Planus E, Bouvard D, Oddou C, Badowski C, Bossy V, Raducanu A, Fourcade B, Albiges-Rizo C, Block MR. Mol Biol Cell. 2010 Dec;21(23):4108-19.
The Liphy R&D team has a long experience in collaboration, joint-development and consulting in optic projects between physics and biology labs. Recently, our team developed a robust method to obtain absolute values of FRET from any epifluorescence microscope. The QuanTI-FRET method calibrates the experimental system and the fluorophore pair, allowing for absolute FRET efficiency and stoichiometry measurements in living cells. Current work focuses on skipping the calibration step with specific samples, hence offering a direct calibration on the sample of interest. This project has been partly funded by the SATT Linksium, an intellectual property has been registered on the software part and discussions are ongoing with private partners.
Another part of the team’s expertise is reflection interference contrast microscopy which allows the measurement of distances with nanometric precision in the vicinity of a reference surface, and to assess the surface functionalization in situ without staining (quantification, quality control). The combination with force application techniques such as flow chambers permits probing biomechanics through the simultaneous control of the force (applied) and the distance (measured). This is essential to study adhesions forces of different organisms: from bacteria to immune cells. The dedicated microscope is fully automated with temperature control, and the PI is currently working on the development of a user-friendly interface for biology-oriented projects.
Both developments are unique in France.
Lyon Multiscale Imaging Center is a microscopy facility opened to academic research and industry. It federates 3 imaging centers in the Lyon area and provides multi-scale imaging tools including light and electron microscopy:
- the PLATIM, located at the Ecole Normale Supérieure de Lyon and at Lyon-Sud Medical University, offers a wide range of light microscopy techniques ranging from fully automated video-microscopy, confocal and two-photon microscopy. The PLATIM accounts also for a platform of atomic force microscopy and microindentation for acquiring high resolution 3D topographies and for measuring micro/nano-mechanical properties.
- the Centre Technologique des Microstructures CTµ, located on the La Doua campus, is mainly an electron microscopy facility that handles multi-disciplinary projects at the interface between biology, chemistry and physics. the CTµ provides access to a wide range of scanning and transmission electron microscopy techniques, and masters cryomethods for sample preparation and observation.
- the East Lyon imaging center (CIQLE) is located in the Rockefeller Medical University. It provides access to wide-field and confocal light microscopy and transmission electron microscopy for the bio-medical research community.
Machines can be operated independently by the users after appropriate training. Users can also benefit partial or full assistance for their projects. LyMIC provides training sessions for groups or individuals.
The team is watching technology progress and implement new techniques to provide state-of-the-art tools.
Located in Rouen, PRIMACEN, the cell imaging facility of Normandy (1000 m2) is integrated since 2022 in HeRacLeS (Univ. Rouen Normandy, Inserm US51, CNRS UAR2026). To achieve its service offering and R&D objectives, PRIMACEN proposes a continuum with 3 pillars thanks to complementary skills in cell biology-histology, instrumentation-quality control and data processing. In tight connection with animal (rodent/marine models) and plant facilities, the first transversal pillar involves living and fixed sample preparation including labeling, for advanced light and electron microscopies. Then, appropriate resolutions are proposed to users and collaborators through multi-scale and multi-modal imaging including LSM and 2P, WF/confocal micro/macroscopy, TIRFM, FLIM-STED imaging, cryo-FLIM/confocal and TEM/cryoTEM microscopies. To finally help users in their scientific projects, image processing and analysis (3D modeling, ImageJ macros, AI…) are available on highly performing working stations.
The QuESt imaging facility combines the microscopy resources of the Institut de Génétique et Biologie Moléculaire (IGBMC) and the Laboratoire de Bioimagerie et Pathologies (PIQ). The two laboratories are located on the Illkirch bio-campus, just 10 minutes’ walk from each other. QuESt has held the IBiSA label since 2014. QuEst offers a range of instruments for multi-scale imaging, from the molecule to the whole animal. The ICI (Imaging Center IGBMC) component located at the IGBMC specialises in imaging the dynamic processes of living organisms at the molecular, cellular and whole organism levels. Researchers can analyse, in an integrated manner, their study models at different resolutions, ranging from the finest cellular structures to the complex functioning of organs in vivo. The PIQ (Plateforme d’Imagerie Quantitative – Quantitative Imaging Platform), located in the Faculty of Pharmacy, has a specific focus on quantitative molecular microscopy methods. In addition to commercial instruments, the PIQ-QuESt develops its own state-of-the-art instruments.
Microscopy systems available @QuESt
The microscopy facility was the first technology platform established in the IBMP in 1998. Its scientific programme aims at understanding the expression of plant or animal genes over space and time at various levels. Microorganisms or biomaterials studied by partner research units are other topics of interest. Our facility follows official guidelines for « Plates-Formes Technologiques du Vivant » and has received RIO 2001, 2004 and 2006 labels. It’s part of the larger PIC.sc Strasbourg Centre Cell Imaging Facility that allows sharing devices and knowledge from several research units from CNRS, INSERM, UNISTRA. Our missions include assisting research from IBMP and partner research units, developing and implement new imaging technologies, training our user base and beyond, getting involved in microscopy education and science popularization.