Structural mechanisms of fibroblast growth factor receptor signalling at the membrane interface
Lead Research Organisation:
University of Leeds
Department Name: Sch of Molecular & Cellular Biology
Abstract
Fibroblast growth factor receptors (FGFRs) are receptor tyrosine kinases that play key roles in embryo development, tissue remodelling, wound healing, and cancer. An enduring enigma of FGFR signalling is the question of how the output (activation of a specific signalling module, e.g. Raf-Mek-Erk) is selected based on the nature and level of the input signal (binding of a particular FGF variant). In this project, you will combine structural biology and biophysical (native MS & structural proteomics) approaches together with mutagenesis, cell biology and imaging to elucidate key mechanistic features of the interaction between the kinase domain, juxtamembrane region and membrane lipids, and determine how these interactions influence downstream signalling through the constitutively-bound FGFR adaptor protein, FRS2.
Specifically, you will:
1. Characterise the interaction between membrane lipids and the JM-KD of FGFR3 using NMR in a membrane-mimetic system (e.g. nanodiscs)
2. Use native mass spectrometry (MS) & structural proteomics methods pioneered in Leeds, including ion-mobility (IM-MS), hydrogen-deuterium exchange (HDX-MS) and fast photochemical oxidation of proteins (FPOP), to provide orthogonal structural mapping of lipid-protein interactions as well as characterisation of the lipid composition around natively-expressed FGFRs.
3. Elucidate how FGFR3 JM-KD and the membrane-anchored adapter protein FRS2 interact using NMR, MS and cell-based imaging approaches.
The student will benefit from the Astbury Centre's world-leading structural biology infrastructure, with >£20M of recent investment, with specialist equipment including 950 MHz NMR, top-end Orbitrap protein mass spectrometry and Titan Krios cryo-EM.
Leeds and AstraZeneca have synergistic expertise in FGFR cell biology and structural biology and together can provide cutting-edge infrastructure to the project and provide a unique competitive advantage to the student, with a highly distinctive research experience that can be effectively levered for future career opportunities, whether academic or industrial.
Specifically, you will:
1. Characterise the interaction between membrane lipids and the JM-KD of FGFR3 using NMR in a membrane-mimetic system (e.g. nanodiscs)
2. Use native mass spectrometry (MS) & structural proteomics methods pioneered in Leeds, including ion-mobility (IM-MS), hydrogen-deuterium exchange (HDX-MS) and fast photochemical oxidation of proteins (FPOP), to provide orthogonal structural mapping of lipid-protein interactions as well as characterisation of the lipid composition around natively-expressed FGFRs.
3. Elucidate how FGFR3 JM-KD and the membrane-anchored adapter protein FRS2 interact using NMR, MS and cell-based imaging approaches.
The student will benefit from the Astbury Centre's world-leading structural biology infrastructure, with >£20M of recent investment, with specialist equipment including 950 MHz NMR, top-end Orbitrap protein mass spectrometry and Titan Krios cryo-EM.
Leeds and AstraZeneca have synergistic expertise in FGFR cell biology and structural biology and together can provide cutting-edge infrastructure to the project and provide a unique competitive advantage to the student, with a highly distinctive research experience that can be effectively levered for future career opportunities, whether academic or industrial.
People |
ORCID iD |
| Alexander Breeze (Primary Supervisor) | |
| Dannie Reynolds (Student) |