Characterization of insulin-degrading enzyme-mediated cleavage of Aβ in distinct aggregation states

To enhance our understanding of the potential therapeutic utility of insulin-degrading enzyme (IDE) in Alzheimer's disease (AD), we studied in vitro IDE-mediated degradation of different amyloid-beta (Aβ) peptide aggregation states. Our findings show that IDE activity is driven by the dynamic equilibrium between Aβ monomers and higher ordered aggregates. We identify Met35-Val36 as a novel IDE cleavage site in the Aβ sequence and show that Aβ fragments resulting from IDE cleavage form non-toxic amorphous aggregates. These findings need to be taken into account in therapeutic strategies designed to increase Aβ clearance in AD patients by modulating IDE activity

High-resolution Structure of the Phosphorylated Form of the Histidine-containing Phosphocarrier Protein HPr from Escherichia coli Determined by Restrained Molecular Dynamics from NMR-NOE Data

The solution structure of the phosphorylated form of the histidine-containing phosphocarrier protein, HPr, from Escherichia coli has been determined by NMR in combination with restrained molecular dynamics simulations. The structure of phospho-HPr (P-HPr) results from a molecular dynamics simulation in water, using time-dependent distance restraints to attain agreement with the measured NOEs. Experimental restraints were identified from both three-dimensional 1H-1H-15N HSQC-NOESY and two-dimensional 1H-1H NOESY spectra, and compared with those of the unphosphorylated form. Structural changes upon phosphorylation of HPr are limited to the active site, as evidenced by changes in chemical shifts, in 3JNHHα-coupling constants and NOE patterns. Chemical shift changes were obtained mainly for protons that were positioned close to the phosphoryl group attached to the His15 imidazole ring. Differences could be detected in the intensity of the NOEs involving the side-chain protons of His15 and Pro18, resulting from a change in the relative position of the two rings. In addition, a small change could be detected in the three-bond J-coupling between the amide proton and the Hα proton of Thr16 and Arg17 upon phosphorylation, in agreement with the changes of the φ torsion angle of these two residues obtained from time-averaged restrained molecular dynamics simulations in water. The proposed role of the torsion-angle strain at residue 16 in the mechanism of Streptococcus faecalis HPr is not supported by these results. In contrast, phosphorylation seems to introduce torsion angle strain at residue His15. This strain could facilitate the transfer of the phosphoryl group to the A-domain at enzyme II. The phospho-histidine is not stabilised by hydrogen bonds to the side-chain group of Arg17; instead stable hydrogen bonds are formed between the phosphate group and the backbone amide protons of Thr16 and Arg17, which show the largest changes in chemical shift upon phosphorylation, and a hydrogen bond involving the side-chain Oγ proton of Thr16. HPr accepts the phosphoryl group from enzyme I and donates it subsequently to the A domain of various enzyme II species. The binding site for EI on HPr resembles that of the A domain of the mannitol-specific enzyme II, as can be concluded from the changes on the amide proton and nitrogen chemical shifts observed via heteromolecular single-quantum coherence spectroscopy.

Determination of the three-dimensional solution structure of the histidine-containing phosphocarrier protein HPr from Escherichia coli using multidimensional NMR spectroscopy

We recorded several types of heteronuclear three-dimensional (3D) NMR spectra on 15N-enriched and 13C/15N-enriched histidine-containing phosphocarrier protein, HPr, to extend the backbone assignments to the side-chain 1H, 15N and 13C resonances. From both 3D heteronuclear 1H-NOE 1H-13C and 1H-NOE 1H-15N multiple-quantum coherence (3D-NOESY-HMQC) and two-dimensional (2D) homonuclear NOE spectra, more than 1200 NOE were identified and used in a step-wise structure refinement process using distance geometry and restrained molecular dynamics involving a number of new features. A cluster of nine structures, each satisfying the set of NOE restraints, resulted from this procedure. The average root-mean-square positional difference for the Cα atoms is less than 0.12 nm. The secondary structure topology of the molecule is that of an open-face β sandwich formed by four antiparallel β strands packed against three a helices, resembling the recently published structure of Bacillus subtilis HPr, determined by X-ray crystallography.

Three-dimensional 15N-1H-1H and 15N-13C-1H nuclear-magnetic resonance studies of HPr a central component of the phosphoenolpyruvate-dependent phosphotransferase system from Escherichia coli. Assignment of backbone resonances

We have performed three-dimensional NMR studies on a central component of the phosphoenolpyruvate-dependent phosphotransferase system of Escherichia coli, denoted as HPr. The protein was uniformly enriched with 15N and 13C to overcome spectral overlap. Complete assignments were obtained for the backbone 1H, 15N and 13C resonances, using three-dimensional heteronuclear 1H NOE 1H-15N multiple-quantum coherence spectroscopy (3D-NOESY-HMQC) and three-dimensional heteronuclear total correlation 1H-15N multiple-quantum coherence spectroscopy (3D-TOCSY-HMQC) experiments on 15N-enriched HPr and an additional three-dimensional triple-resonance 1HN-15N-13Cα correlation spectroscopy (HNCA) experiment on 13C,15N-enriched HPr. Many of the sequential backbone 1H assignments, as derived from two-dimensional NMR studies, were corrected. Almost all discrepancies are in the helical regions, leaving the published antiparallel β-sheet topology almost completely intact.

The NMR determination of the IIAmtl binding site on HPr of the Escherichia coli phosphoenol pyruvate-dependent phosphotransferase system

The region of the surface of the histidine-containing protein (HPr) which interacts with the A domain of the mannitol-specific Enzyme II (IIAmtl) has been mapped by titrating the A-domain into a solution of 15N-labeled HPr and monitoring the effects on the amide proton and nitrogen chemical shifts via heteronuclear single quantum correlation spectroscopy (HSQC). Fourteen of the eighty-five HPr amino acid residues show large changes in either the 15N or 1H chemical shifts or both as a result of the presence of IIAmtl while a further seventeen residues experience lesser shifts. Most of the residues involved are surface residues accounting for approximately 25% of the surface of HPr. Phosphorylation of HPr with catalytic amounts of Enzyme I (EI), in the absence of IIAmtl resulted in chemical shift changes in a sub-set of the above residues; these were located more in the vicinity of the active site phospho-histidine. Phosphorylation of the HPr/IIAmtl complex resulted in a HSQC spectrum which was indistinguishable from the P-HPr spectrum in the absence of IIAmtl indicating that, as expected, the complex P-HPr/P-IIAmtl does not exist even at the high concentrations necessary for NMR.

Slow Cooperative Folding of a Small Globular Protein HPr

The folding of an 85-residue protein, the histidine-containing phosphocarrier protein HPr, has been studied using a variety of techniques including DSC, CD, ANS fluorescence, and NMR spectroscopy. In both kinetic and equilibrium experiments the unfolding of HPr can be adequately described as a two-state process which does not involve the accumulation of intermediates. Thermodynamic characterization of the native and the transition states has been achieved from both equilibrium and kinetic experiments. The heat capacity change from the denatured state to the transition state (3.2 kJ mol-1 K-1) is half of the heat capacity difference between the native and denatured states (6.3 kJ mol-1 K-1), while the solvent accessibility of the transition state (0.36) indicates that its compactness is closer to that of the native than that of the denatured state. The high value for the change in heat capacity upon unfolding results in the observation of cold denaturation at moderate denaturant concentrations. Refolding from high denaturant concentrations is, however, slow. The rate constant of folding in water, kfH2O (14.9 s-1), is small compared to that reported for other proteins of similar size under similar conditions. This indicates that very fast refolding is not a universal character of small globular proteins which fold in the absence of detectable intermediates.

The High-resolution Structure of the Histidine-containing Phosphocarrier Protein HPr from Escherichia coli Determined by Restrained Molecular Dynamics from Nuclear Magnetic Resonance Nuclear Overhauser Effect Data

The solution structure of the histidine-containing phosphocarrier protein HPr from Escherichia coli has been determined by NMR in combination with distance geometry and restrained molecular dynamics. The structure is based on 1520 experimental restraints identified from both three-dimensional 1H-1H-13C and 1H-1H-15N nuclear Overhauser effect multiple quantum coherence spectroscopy and two dimensional 1H-1H nuclear Overhauser effect spectra. Thirty-two four-dimensional coordinate frames were produced by metric matrix distance geometry, subjected to distance bounds driven dynamics, projected into three-dimensional space and again subjected to distance-bounds driven dynamics. These 32 distance geometry structures were refined further by restrained molecular dynamics (40 ps) in the GROMOS in vacuo force field. All 32 structures reached acceptable energy minima while satisfying the imposed restraints. Two of these structures were subjected to a further 200 ps of molecular dynamics simulation in water, using time-dependent distance restraining, followed by a 200 ps free simulation without any distance restraining. The resulting structure is very similar to the X-ray structure of Bacillus subtilis HPr, but differs mainly in the position of the two loops containing the active site histidine residue 15 and residues 53 to 57 relative to the rest of the structure. The unfavorable φ torsion angle that was found for residue 16 in the active center of unphosphorylated Streptococcus faecalis HPr was proposed to play a role in the activity of the protein. Although present at the early stages of the structure calculations, this torsion-angle strain disappeared in the final model obtained from molecular dynamics simulations in water using time-averaged distance restraining and upon releasing the distance restraints. This suggests that the strain may be an artifact of crystallization conditions instead of an essential element in the phosphorylation/dephosphorylation process.

Rapid Formation of Non-native Contacts During the Folding of HPr Revealed by Real-time Photo-CIDNP NMR and Stopped-flow Fluorescence Experiments

We report the combined use of real-time photo-CIDNP NMR and stopped-flow fluorescence techniques to study the kinetic refolding of a set of mutants of a small globular protein, HPr, in which each of the four phenylalanine residues has in turn been replaced by a tryptophan residue. The results indicate that after refolding is initiated, the protein collapses around at least three, and possibly all four, of the side-chains of these residues, as (i) the observation of transient histidine photo-CIDNP signals during refolding of three of the mutants (F2W, F29W, and F48W) indicates a strong decrease in tryptophan accessibility to the flavin dye; (ii) iodide quenching experiments show that the quenching of the fluorescence of F48W is less efficient for the species formed during the dead-time of the stopped-flow experiment than for the fully native state; and (iii) kinetic fluorescence anisotropy measurements show that the tryptophan side-chain of F48W has lower mobility in the dead-time intermediate state than in both the fully denatured and fully native states. The hydrophobic collapse observed for HPr during the early stages of its folding appears to act primarily to bury hydrophobic residues. This process may be important in preventing the protein from aggregating prior to the acquisition of native-like structure in which hydrophobic residues are exposed in order to play their role in the function of the protein. The phenylalanine residue at position 48 is likely to be of particular interest in this regard as it is involved in the binding to enzymes I and II that mediates the transfer of a phosphoryl group between the two enzymes.

Structure and localization of an essential transmembrane segment of the proton translocation channel of yeast H+-V-ATPase

AbstractVacuolar (H+)-ATPase (V-ATPase) is a proton pump present in several compartments of eukaryotic cells to regulate physiological processes. From biochemical studies it is known that the interaction between arginine 735 present in the seventh transmembrane (TM7) segment from subunit a and specific glutamic acid residues in the subunit c assembly plays an essential role in proton translocation. To provide more detailed structural information about this protein domain, a peptide resembling TM7 (denoted peptide MTM7) from Saccharomyces cerevisiae (yeast) V-ATPase was synthesized and dissolved in two membrane-mimicking solvents: DMSO and SDS. For the first time the secondary structure of the putative TM7 segment from subunit a is obtained by the combined use of CD and NMR spectroscopy. SDS micelles reveal an α-helical conformation for peptide MTM7 and in DMSO three α-helical regions are identified by 2D 1H-NMR. Based on these conformational findings a new structural model is proposed for the putative TM7 in its natural environment. It is composed of 32 amino acid residues that span the membrane in an α-helical conformation. It starts at the cytoplasmic side at residue T719 and ends at the luminal side at residue W751. Both the luminal and cytoplasmatic regions of TM7 are stabilized by the neighboring hydrophobic transmembrane segments of subunit a and the subunit c assembly from V-ATPase

Comparative NMR study on the impact of point mutations on protein stability of Pseudomonas mendocina lipase

In this work we compare the dynamics and conformational stability of Pseudomonas mendocina lipase enzyme and its F180P/S205G mutant that shows higher activity and stability for use in washing powders. Our NMR analyses indicate virtually identical structures but reveal remarkable differences in local dynamics, with striking correspondence between experimental data (i.e., 15N relaxation and H/D exchange rates) and data from Molecular Dynamics simulations. While overall the cores of both proteins are very rigid on the pico- to nanosecond timescale and are largely protected from H/D exchange, the two point mutations stabilize helices α1, α4, and α5 and locally destabilize the H-bond network of the β-sheet (β7–β9). In particular, it emerges that helix α5, undergoing some fast destabilizing motions (on the pico- to nanosecond timescale) in wild-type lipase, is substantially rigidified by the mutation of Phe180 for a proline at its N terminus. This observation could be explained by the release of some penalizing strain, as proline does not require any “N-capping” hydrogen bond acceptor in the i+3 position. The combined experimental and simulated data thus indicate that reduced molecular flexibility of the F180P/S205G mutant lipase underlies its increased stability, and thus reveals a correlation between microscopic dynamics and macroscopic thermodynamic properties. This could contribute to the observed altered enzyme activity, as may be inferred from recent studies linking enzyme kinetics to their local molecular dynamics