Solid state NMR reveals a pH-dependent antiparallel beta-sheet registry in fibrils formed by a beta-amyloid peptide.

We report solid state nuclear magnetic resonance (NMR) measurements that probe the supramolecular organization of beta-sheets in the cross-beta motif of amyloid fibrils formed by residues 11-25 of the beta-amyloid peptide associated with Alzheimer's disease (Abeta(11-25)). Fibrils were prepared at pH 7.4 and pH 2.4. The solid state NMR data indicate that the central hydrophobic segment of Abeta(11-25) (sequence LVFFA) adopts a beta-strand conformation and participates in antiparallel beta-sheets at both pH values, but that the registry of intermolecular hydrogen bonds is pH-dependent. Moreover, both registries determined for Abeta(11-25) fibrils are different from the hydrogen bond registry in the antiparallel beta-sheets of Abeta(16-22) fibrils at pH 7.4 determined in earlier solid state NMR studies. In all three cases, the hydrogen bond registry is highly ordered, with no detectable "registry-shift" defects. These results suggest that the supramolecular organization of beta-sheets in amyloid fibrils is determined by a sensitive balance of multiple side-chain-side-chain interactions. Recent structural models for Abeta(11-25) fibrils based on X-ray fiber diffraction data are inconsistent with the solid state NMR data at both pH values.

Arginine activity in the proton-motive photocycle of bacteriorhodopsin: solid-state NMR studies of the wild-type and D85N proteins.

15N solid-state NMR (SSNMR) spectra of guanidyl-15N-labeled bacteriorhodopsin (bR) show perturbation of an arginine residue upon deprotonation of the retinal Schiff base during the photocycle. At the epsilon position, an upfield shift of 4 ppm is observed while the eta nitrogens develop a pair of 'wing' peaks separated by 24 ppm. Proton-driven spin diffusion between the two 'wing' peaks indicates that they arise from a single Arg residue. An unusually asymmetric environment for this residue is indicated by comparison with guanidyl-15N chemical shifts in a series of arginine model compounds. The 'wing' peaks are tentatively assigned to Arg-82 on the basis of the SSNMR investigations of the alkaline and neutral dark-adapted forms of the D85N bacteriorhodopsin mutant. Another, less asymmetric pair of eta signals, that is not affected by Schiff base deprotonation or D85 mutation, is tentatively assigned to Arg-134. The results are discussed in relation to existing models of bR structure and function.

The predischarge chromophore in bacteriorhodopsin: a 15N solid-state NMR study of the L photointermediate.

The L550 intermediate in the bacteriorhodopsin (bR) photocycle has drawn much attention with respect to the mechanism of light-driven proton transport because it selectively releases the Schiff base (SB) proton to the extracellular proton channel in the L-->M transition. Here we extend our solid-state NMR studies of bR photocycle intermediates to the L state. Under conditions that stabilize L550, a new SB signal is detected in the 15N NMR spectrum which disappears upon thermal relaxation. This signal is in the range for a protonated SB, but downfield from the SB signals of bR568 and N520. Since steric interactions would have the opposite effect on shielding, the data argue against a 13,14-dicis chromophore in L550. Comparison with the 15N chemical shifts of halide salts of protonated Schiff bases (pSB's) of retinal suggests that the interaction of the SB with its counterion is significantly stronger in L550 than in N520 (which in turn is stronger than in bR568). This is consistent with models of the early photocycle in which the electrostatic interaction between the SB and its counterion constitutes an important constraint. Although the L counterion interaction is comparable to that of a 6-s-trans,13-cis chloride salt, the visible spectrum is strongly red-shifted from the lambdamax = 491 nm of the chloride. This suggests some double bond strain in L550, particularly about the C=N bond. This strain is apparently gone in the N intermediate, which has a normal relationship between the 15N chemical shift and lambdamax. Such a relaxed chromophore is consistent with orientation of the SB proton toward the cytoplasmic surface in the N intermediate.