Description
Data sets for the experimental chapters contained within the PhD thesis titled: "Advances in Electron Paramagnetic Resonance Through Synthetic Chemistry" during study at the UoSA.
Electron paramagnetic resonance spectroscopy (EPR) is one of the most powerful and versatile tools for investigating the local structure and dynamics of paramagnetic substances. In this work, dipolar spectroscopy (PDS) and hyperfine spectroscopy (HFS) are used to investigate the binding and coordination of metal ions such as gadolinium (Gd(III)) and copper (Cu(II)) to de novo coiled-coil (Cc) peptides to characterise their local environment, and probe the nature of the binding site. This work highlights the versatility of designer miniature protein frameworks, which give access to unique and functional binding sites. This flexibility is seen through investigations of the miniature protein Cc MB1-2, presenting the characterisation of a novel oxophilic Cu(II) binding site, within a protein scaffold and a series of Cc’s based on modification of this binding site. Mutation and translation of this site
shows how the EPR parameters of the Cu(II) ion can be tuned depending on the nature of the available amino acids. High-spin EPR spin labels such as Gd(III) are of interest owing to their stability within cellular environments. However, PDS measurements using Gd(III) are known to be inaccurate at short distances (<4 nm) when excitation of the central transition (CT) often leads to unwanted
excitation of flip-flop transitions causing spectral distortions. New PDS techniques are detailed that can provide high-sensitivity, artefact free data in high-spin systems by avoiding the CT at W-band. Amplitude and phase modulated chirp pulses are also compared against standard
rectangular pulses in a variety of PDS experiments. Finally, translation of a double Gd(III) binding Cc with known distances, shows promise as a ruler system for PDS measurements, moving away from purely synthetic model rulers whose flexibility do not mirror those of native biological systems
Electron paramagnetic resonance spectroscopy (EPR) is one of the most powerful and versatile tools for investigating the local structure and dynamics of paramagnetic substances. In this work, dipolar spectroscopy (PDS) and hyperfine spectroscopy (HFS) are used to investigate the binding and coordination of metal ions such as gadolinium (Gd(III)) and copper (Cu(II)) to de novo coiled-coil (Cc) peptides to characterise their local environment, and probe the nature of the binding site. This work highlights the versatility of designer miniature protein frameworks, which give access to unique and functional binding sites. This flexibility is seen through investigations of the miniature protein Cc MB1-2, presenting the characterisation of a novel oxophilic Cu(II) binding site, within a protein scaffold and a series of Cc’s based on modification of this binding site. Mutation and translation of this site
shows how the EPR parameters of the Cu(II) ion can be tuned depending on the nature of the available amino acids. High-spin EPR spin labels such as Gd(III) are of interest owing to their stability within cellular environments. However, PDS measurements using Gd(III) are known to be inaccurate at short distances (<4 nm) when excitation of the central transition (CT) often leads to unwanted
excitation of flip-flop transitions causing spectral distortions. New PDS techniques are detailed that can provide high-sensitivity, artefact free data in high-spin systems by avoiding the CT at W-band. Amplitude and phase modulated chirp pulses are also compared against standard
rectangular pulses in a variety of PDS experiments. Finally, translation of a double Gd(III) binding Cc with known distances, shows promise as a ruler system for PDS measurements, moving away from purely synthetic model rulers whose flexibility do not mirror those of native biological systems
| Date made available | 17 May 2026 |
|---|---|
| Publisher | University of St Andrews |
| Temporal coverage | 1 Sept 2018 - 1 Aug 2022 |
Keywords
- EPR
- DEER
- RIDME
- Coiled-Coil
- AWG
- Gadolinium
- Copper
- TOAC
- Pulsed Dipolar Spectroscopy
- Hyperfine Spectroscopy
- PDS
- HFS
Research output
- 4 Article
-
Design of the elusive proteinaceous oxygen donor copper site suggests a promising future for copper for MRI contrast agents
Shah, A., Taylor, M. J., Molinaro, G., Anbu, S., Verdu, M., Jennings, L., Mikulska, I., Diaz-Moreno, S., El Mkami, H., Smith, G. M., Britton, M. M., Lovett, J. E. & Peacock, A. F. A., 4 Jul 2023, In: Proceedings of the National Academy of Sciences of the United States of America. 120, 27, e2219036120.Research output: Contribution to journal › Article › peer-review
Open AccessFile -
Neural networks in pulsed dipolar spectroscopy: a practical guide
Keeley, J., Choudhury, T., Galazzo, L., Bordignon, E., Feintuch, A., Goldfarb, D., Russell, H., Taylor, M. J., Lovett, J. E., Eggeling, A., Fabregas Ibanez, L., Keller, K., Yulikov, M., Jeschke, G. & Kuprov, I., May 2022, In: Journal of Magnetic Resonance. 338, 14 p., 107186.Research output: Contribution to journal › Article › peer-review
Open AccessFile -
Versatile para-substituted pyridine lanthanide coordination complexes allow late stage tailoring of complex function
Starck, M., Fradgley, J., De Rosa, D. F., Batsanov, A., Papa, M., Taylor, M., Lovett, J., Lutter, J., Allen, M. & Parker, D., 16 Nov 2021, (E-pub ahead of print) In: Chemistry - A European Journal. Early View, 7 p.Research output: Contribution to journal › Article › peer-review
Open AccessFile
Student theses
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Advances in electron paramagnetic resonance through synthetic chemistry
Taylor, M. J. (Author), Lovett, J. E. (Supervisor) & Smith, G. M. (Supervisor), 10 Jun 2024Student thesis: Doctoral Thesis (PhD)