Intermolecular Structure Determination of Amyloid Fibrils with 2 Magic-Angle Spinning and Dynamic Nuclear Polarization NMR

We describe magic-angle spinning NMR experiments designed to elucidate the interstrand architecture of amyloid fibrils. Three methods are introduced for this purpose, two being based on the analysis of long-range [superscript 13]C–[superscript 13]C correlation spectra and the third based on the identification of intermolecular interactions in [superscript 13]C–[superscript 15]N spectra. We show, in studies of fibrils formed by the 86-residue SH3 domain of PI3 kinase (PI3-SH3 or PI3K-SH3), that efficient [superscript 13]C–[superscript 13]C correlation spectra display a resonance degeneracy that establishes a parallel, in-register alignment of the proteins in the amyloid fibrils. In addition, this degeneracy can be circumvented to yield direct intermolecular constraints. The [superscript 13]C–[superscript 13]C experiments are corroborated by [superscript 15]N–[superscript 13]C correlation spectra obtained from a mixed [[superscript 15]N,[superscript 12]C]/[[superscript 14]N,[superscript 13]C] sample which directly quantify interstrand distances. Furthermore, when the spectra are recorded with signal enhancement provided by dynamic nuclear polarization (DNP) at 100 K, we demonstrate a dramatic increase (from 23 to 52) in the number of intermolecular [superscript 15]N–[superscript 13]C constraints detectable in the spectra. The increase in the information content is due to the enhanced signal intensities and to the fact that dynamic processes, leading to spectral intensity losses, are quenched at low temperatures. Thus, acquisition of low temperature spectra addresses a problem that is frequently encountered in MAS spectra of proteins. In total, the experiments provide 111 intermolecular [superscript 13]C–[superscript 13]C and [superscript 15]N–[superscript 13]C constraints that establish that the PI3-SH3 protein strands are aligned in a parallel, in-register arrangement within the amyloid fibril.National Institutes of Health (U.S.) (Grant EB-003151)National Institutes of Health (U.S.) (Grant EB-002804)National Institutes of Health (U.S.) (Grant EB-002026

Long-Range Correlations between Aliphatic 13C Nuclei in Protein MAS NMR Spectroscopy†

Highly efficient polarization transfer can be achieved in the magic-angle spinning NMR analysis of proteins by the combination of [superscript 13]C labeling at alternating positions and band-selective radio-frequency-driven recoupling (BASE RFDR), a pulse scheme aimed at exploiting the bandwidth selectivity and favorable effects of weak [superscript 13]C radio-frequency irradiation to reintroduce the homonuclear dipolar interactions between distant nuclei.National Institutes of Health (U.S.) (Grant EB-003151)National Institutes of Health (U.S.) (Grant EB-002026

High-resolution MAS NMR analysis of PI3-SH3 amyloid fibrils: Backbone conformation and implications for protofilament assembly and structure

The SH3 domain of the PI3 kinase (PI3-SH3 or PI3K-SH3) readily aggregates into fibrils in vitro and has served as an important model system in the investigation of the molecular properties and mechanism of formation of amyloid fibrils. We describe the molecular conformation of PI3-SH3 in amyloid fibril form as revealed by magic-angle spinning (MAS) solid-state nuclear magnetic resonance (NMR) spectroscopy. The MAS NMR spectra of these fibrils display excellent resolution, with narrow [superscript 13]C and [superscript 15]N line widths, representing a high degree of structural order and the absence of extensive molecular motion for the majority of the polypeptide chain. We have identified the spin systems of 82 of the 86 residues in the protein and obtained sequential resonance assignments for 75 of them. Chemical shift analysis indicates that the protein subunits making up the fibril adopt a compact conformation consisting of four well-defined β-sheet regions and four random-coil elements with varying degrees of local dynamics or disorder. The backbone conformation of PI3-SH3 in fibril form differs significantly from that of the native state of the protein, both in secondary structure and in the location of dynamic or disordered segments. The site-specific MAS NMR analysis of PI3-SH3 fibrils we report here is compared with previously published mechanistic and structural data, resulting in a detailed interpretation of the factors that mediate fibril formation by PI3-SH3 and allowing us to propose a possible model of the core structure of the fibrils. Our results confirm the structural similarities between PI3-SH3 fibrilsNational Institutes of Health (U.S.) (grant no. EB-003151)National Institutes of Health (U.S.) (grant no. EB-002026