Stability of the nitroxide biradical AMUPol in intact and lysed mammalian cells

[Display omitted] •AMUPol is reduced at a modest rate by intact mammalian cells and lysates.•In cells, half the AMUPol is in the DNP-silent monoradical form at earliest timepoint.•Electroporation delivers consistent quantities of AMUPol to intact cells.•Reduction is prevented by 2.5 mM N-ethlymaleim...

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Published in:Journal of magnetic resonance (1997) 2022-03, Vol.336, p.107150-107150, Article 107150
Main Authors: Ghosh, Rupam, Dumarieh, Rania, Xiao, Yiling, Frederick, Kendra K
Format: Article
Language:English
Subjects:
AMUPol
DNP NMR
Free Radicals - chemistry
HEK293 Cells
Humans
In-cell EPR
In-cell NMR
Magnetic Resonance Spectroscopy - methods
Nitrogen Oxides - chemistry
Polarizing agent
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Summary:[Display omitted] •AMUPol is reduced at a modest rate by intact mammalian cells and lysates.•In cells, half the AMUPol is in the DNP-silent monoradical form at earliest timepoint.•Electroporation delivers consistent quantities of AMUPol to intact cells.•Reduction is prevented by 2.5 mM N-ethlymaleimide but viability is compromised.•No improvement in DNP enhancements post reduction inhibition with NEM. Dynamic Nuclear Polarization (DNP) enhanced solid state NMR increases experimental sensitivity, potentially enabling detection of biomolecules at their physiological concentrations. The sensitivity of DNP experiments is due to the transfer of polarization from electron spins of free radicals to the nuclear spins of interest. Here, we investigate the reduction of AMUPol in both lysed and intact HEK293 cells. We find that nitroxide radicals are reduced with first order reduction kinetics by cell lysates at a rate of ∼ 12% of the added nitroxide radical concentration per hour. We also found that electroporation delivered a consistent amount of AMUPol to intact cells and that nitroxide radicals are reduced just slightly more rapidly (∼15% per hour) by intact cells than by cell lysates. The two nitroxide radicals of AMUPol are reduced independently and this leads to considerable accumulation of the DNP-silent monoradical form of AMUPol, particularly in preparations of intact cells where nearly half of the AMUPol is already reduced to the DNP silent monoradical form at the earliest experimental time points. This confirms that the loss of the DNP-active biradical form of AMUPol is faster than the nitroxide reduction rate. Finally, we investigate the effect of adding N-ethyl maleimide, a well-known inhibitor of thiol (-SH) group-based reduction of nitroxide biradicals in cells, on AMUPol reduction, cellular viability, and DNP performance. Although pre-treatment of cells with NEM effectively inhibited the reduction of AMUPol, exposure to NEM compromised cellular viability and, surprisingly, did not improve DNP performance. Collectively, these results indicate that, currently, the most effective strategy to obtain high DNP enhancements for DNP-assisted in-cell NMR is to minimize room temperature contact times with cellular constituents and suggest that the development of bio-resistant polarization agents for DNP could considerably increase the sensitivity of DNP-assisted in-cell NMR experiments.
ISSN:1090-7807
1096-0856
DOI:10.1016/j.jmr.2022.107150