Received August 4, 1997

Abstract:

We present a new solid-state NMR approach, based on ¹H spin diffusion with X-nucleus (¹⁵N, ¹³C, ³¹P) detection, for investigating the structure of membrane proteins. For any segment with a resolvable signal in the X-nucleus spectrum, the depth of insertion into the lipid bilayer can be determined. The technique represents the adaptation of the Goldman-Shen ¹H spin-diffusion experiment with X-nucleus detection to proteins in hydrated lipid bilayers (>25% water by weight) in the gel state at 240 K. The experiments are demonstrated on the 21-kDa channel-forming domain of the toxin-like colicin E1 molecule incorporated into lipid vesicles. More than 32% of the protons in our sample are in mobile H₂O molecules, which can be selected efficiently by the ¹H T₂ filter in the Goldman-Shen sequence. The transfer of ¹H magnetization from mobile H₂O to the colicin E1 channel domain is 80% complete within only 5 ms. This transfer to the protein, probed by the amide ¹⁵N signals, is faster than the transfer to the rigid protons on average, proving that most of the protein is preferentially located between the water and the lipid bilayer. From the spin-diffusion and dipolar-dephasing data, 60% of the 24 lysine side groups are shown to be highly mobile. Quantitative depth profiling is demonstrated using the ³¹P in the lipid phosphate head groups and the ¹³C nuclei in the lipid acyl chains as distance markers for the spin diffusion.

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