Nano-Immunology
Lead Research Organisation:
University of Oxford
Department Name: UNLISTED
Abstract
Research by my group aims to unravel nanoscopic changes at the molecular level in living cells to characterise important molecular processes on the cell membrane as well as inside the cell during immunological reactions. Because many cellular responses lead to changes so subtle at the molecular level, studying them requires us to not only observe them with a superior spatial resolution but also to reach a sensitivity that is able to monitor single molecules over time and space. We are using the newest and most powerful super-resolution far-field microscopes (such as STED, RESOLFT or PALM/STORM) to image and analyse cellular structures and protein-protein and protein-lipid interactions at a level of fine detail that until now has not been possible due to the limited spatial resolution of conventional optical far-field microscopes. By combining these super-resolution microscopy techniques with single-molecule sensitive detection methods (such as fluorescence correlation spectroscopy) and fast spatio-temporal tracking tools we are able to see complex dynamic processes otherwise invisible because of the lower power of conventional far-field microscopy. These molecular interactions play an important role in the immune response to infection and cancer and so we intend to use and further develop these advanced microscopy techniques and apply them to gather new insights in immunological research.
Technical Summary
Single-molecule super-resolution microscopy of membrane dynamics: Many cellular responses lead to subtle changes on the molecular level, demanding not only for a superior spatial resolution of the analyzing method but also for the sensitivity to monitor single molecules over time and space. The combination of super-resolution optical fluorescence STED microscopy with single-molecule sensitive fluorescence-detection tools such as Fluorescence Correlation Spectroscopy (FCS) as well as the fast spatio-temporal tracking of single labeled molecules (single-particle tracking, SPT) allows for the disclosure of complex dynamic processes otherwise impeded by the limited spatial resolution of conventional far-field microscopy. For example, STED-FCS or SPT offer us the possibility to gain novel insights into important cellular processes, such as lipid-lipid, lipid-protein, and protein-protein interactions and the formation of so-called “lipid-rafts” in the cellular plasma membrane. These molecular interactions play an important role in the cellular immune response. We will therefore apply and further develop the STED-FCS and SPT microscopy techniques to highlight important molecular processes on the plasma membrane as well as inside the cell during immunological reactions. For example, these techniques will be used to shed new light on different molecular pathways triggered at the cell surface and intracellularly during antigen presentation by dendritic cells and T cell activation.
Organisations
People |
ORCID iD |
Christian Eggeling (Principal Investigator) |
Publications
Pinkwart K
(2019)
Nanoscale dynamics of cholesterol in the cell membrane.
in The Journal of biological chemistry
Plochberger B
(2017)
HDL particles incorporate into lipid bilayers - a combined AFM and single molecule fluorescence microscopy study.
in Scientific reports
Polley A
(2017)
Glycosylation and Lipids Working in Concert Direct CD2 Ectodomain Orientation and Presentation.
in The journal of physical chemistry letters
Portwich F
(2022)
Ein stark fluoreszierender zweikerniger Aluminiumkomplex mit nahezu 100 %iger Quantenausbeute**
in Angewandte Chemie
Portwich FL
(2022)
A Highly Fluorescent Dinuclear Aluminium Complex with Near-Unity Quantum Yield.
in Angewandte Chemie (International ed. in English)
Reglinski K
(2020)
Fluidity and Lipid Composition of Membranes of Peroxisomes, Mitochondria and the ER From Oleic Acid-Induced Saccharomyces cerevisiae.
in Frontiers in cell and developmental biology
Reina F
(2018)
Complementary studies of lipid membrane dynamics using iSCAT and super-resolved fluorescence correlation spectroscopy.
in Journal of physics D: Applied physics
Reina F
(2021)
TRAIT2D: a Software for Quantitative Analysis of Single Particle Diffusion Data.
in F1000Research
Related Projects
Project Reference | Relationship | Related To | Start | End | Award Value |
---|---|---|---|---|---|
MC_UU_00008/1 | 01/04/2017 | 31/03/2023 | £2,738,000 | ||
MC_UU_00008/2 | Transfer | MC_UU_00008/1 | 01/04/2017 | 31/03/2023 | £1,821,000 |
MC_UU_00008/3 | Transfer | MC_UU_00008/2 | 01/04/2017 | 31/03/2023 | £2,257,000 |
MC_UU_00008/4 | Transfer | MC_UU_00008/3 | 01/04/2017 | 31/03/2023 | £1,459,000 |
MC_UU_00008/5 | Transfer | MC_UU_00008/4 | 01/04/2017 | 31/03/2023 | £1,346,000 |
MC_UU_00008/6 | Transfer | MC_UU_00008/5 | 01/04/2017 | 31/03/2023 | £1,660,000 |
MC_UU_00008/7 | Transfer | MC_UU_00008/6 | 01/04/2017 | 31/03/2023 | £401,000 |
MC_UU_00008/8 | Transfer | MC_UU_00008/7 | 01/04/2017 | 31/03/2024 | £2,876,000 |
MC_UU_00008/9 | Transfer | MC_UU_00008/8 | 01/04/2017 | 31/03/2023 | £2,568,000 |
MC_UU_00008/10 | Transfer | MC_UU_00008/9 | 01/04/2017 | 31/03/2023 | £2,060,000 |
MC_UU_00008/11 | Transfer | MC_UU_00008/10 | 01/04/2017 | 31/03/2023 | £1,477,000 |