1. Functional and shunt states of bacteriorhodopsin resolved by 250 GHz dynamic nuclear polarization—enhanced solid-state NMR.
- Author
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Bajaj, Vikram S., Mak-Jurkauskas, Melody L., Belenky, Marina, Herzfeld, Judith, and Griffin, Robert G.
- Subjects
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BACTERIORHODOPSIN , *GYROTRONS , *NUCLEAR magnetic resonance , *POLARIZATION (Nuclear physics) , *PROTEINS , *HETEROGENEITY - Abstract
Observation and structural studies of reaction intermediates of proteins are challenging because of the mixtures of states usually present at low concentrations. Here, we use a 250 GHz gyrotron (cyclotron resonance maser) and cryogenic temperatures to perform high-frequency dynamic nuclear polarization (DNP) NMR experiments that enhance sensitivity in magic-angle spinning NMR spectra of cryo-trapped photocycle intermediates of bacteriorhodopsin (bR) by a factor of ≈90. Multidimensional spectroscopy of U-13C,15N-labeled samples resolved coexisting states and allowed chemical shift assignments in the retinylidene chromophore for several intermediates not observed previously. The correlation spectra reveal unexpected heterogeneity in dark-adapted bR, distortion in the K state, and, most importantly, 4 discrete L substates. Thermal relaxation of the mixture of L's showed that 3 of these substates revert to bR568 and that only the 1 substate with both the strongest counterion and a fully relaxed 13-cis bond is functional. These definitive observations of functional and shunt states in the bR photocycle provide a preview of the mechanistic insights that will be accessible in membrane proteins via sensitivity-enhanced DNP NMR. These observations would have not been possible absent the signal enhancement available from DNP. [ABSTRACT FROM AUTHOR]
- Published
- 2009
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