Abstract
ABSTRACTPulse dipolar electron paramagnetic resonance (PD-EPR) has become a powerful tool for structural biology determining distances on the nanometre scale. Recent advances in hardware, methodology, and data analysis have widened the scope to complex biological systems. PD-EPR can be applied to systems containing lowly populated conformers or displaying large intrinsic flexibility, making them all but intractable for cryo-electron microscopy and crystallography. Membrane protein applications are of particular interest due to the intrinsic difficulties for obtaining high-resolution structures of all relevant conformations. Many drug targets involved in critical cell functions are multimeric channels or transporters. Here, common approaches for introducing spin labels for PD-EPR cause the presence of more than two electron spins per multimeric complex. This requires careful experimental design to overcome detrimental multi-spin effects and to secure sufficient distance resolution in presence of multiple distances. In addition to obtaining mere distances, PD-EPR can also provide information on multimerisation degrees allowing to study binding equilibria and to determine dissociation constants.
Highlights
Pulse dipolar electron paramagnetic resonance (PD-EPR) is becoming increasingly important in structural biology [1,2]
We recently demonstrated that behaves as expected in the pentameric mechanosensitive channel of large conductance from E. coli (MscL) [62]
PD-EPR distance measurements have become an important tool in the armoury of structural biology methods
Summary
Biomedical Sciences Research Complex, Centre of Magnetic Resonance and EaStCHEM School of Chemistry, University of St Andrews, North Haugh, St Andrews KY16 9ST, Scotland, UK. Pulse dipolar electron paramagnetic resonance (PD-EPR) has become a powerful tool for structural biology determining distances on the nanometre scale. PD-EPR can be applied to systems containing lowly populated conformers or displaying large intrinsic flexibility, making them all but intractable for cryo-electron microscopy and crystallography. Membrane protein applications are of particular interest due to the intrinsic difficulties for obtaining high resolution structures of all relevant conformations. Common approaches for introducing spin labels for PD-EPR cause the presence of more than two electron spins per multimeric complex. This requires careful experimental design to overcome detrimental multi-spin effects and to secure sufficient distance resolution in presence of multiple distances. In addition to obtaining mere distances, PD-EPR can provide information on multimerisation degrees allowing to study binding equilibria and to determine dissociation constants
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