Phosphorylation of an alpha-synuclein peptide fragment enhances metal binding

By using Tb3+ as a luminescent probe, we demonstrate that the phosphorylation state of a 14-residue peptide fragment of alpha-synuclein, a protein implicated in Parkinson's Disease, dramatically affects the metal ion affinity of the peptide. Whereas the unphosphorylated peptide and its phosphoserine analogue show weak Tb3+ binding, its phosphotyrosine analogue shows tight 1:1 binding as well as 2:1 and 3:1 Tb:peptide adducts. Our data suggest that the phosphorylated amino acid must be appropriately positioned among additional ligating residues to establish this phosphorylation-dependent metal binding.     

Effect of freezing on amyloid peptide aggregation and self-diffusion in an aqueous solution

Pulsed-field gradient ¹H NMR is employed to investigate the self-diffusion of amyloid Aβ-peptide in an aqueous buffer solution (pH 7.44) with a protein concentration of 50 μmol at 20°C. The self-diffusion coefficient of the peptide in a freshly prepared solution corresponds to its monomeric form. The storage of the solution at 24°C causes part of the peptide molecules to form amyloid aggregates as soon as over 48 h. However, the ¹H NMR echo signal typical of aggregated molecules is not observed because of their dense packing in the aggregates and a large mass of the latter. A freezing-fusion of the solution after the aggregation does not cause changes in the self-diffusion coefficients of the peptide. After a peptide solution free of amyloid aggregates is subjected to a freezing-fusion cycle, part of the peptide molecules also remains in the monomeric form in the solution, while another part forms amyloid aggregates, with a portion of the aggregated peptide molecules retaining a high rotational mobility with virtually absolute absence of a translational mobility. The results obtained are interpreted in terms of the formation of “porous aggregates” of amyloid fibrils, with “pores” having sizes comparable with those of peptide molecules, though, being larger than water molecules. Peptide molecules, which do not form fibrils, are captured in the pores. Temperature regime is shown to be of importance for the aggregation of amyloid peptides. In particular, freezing, which is traditionally considered to be a method for the prevention from or temporary interruption of aggregation, may itself lead to the formation of amorphous amyloid aggregates, which remain preserved in solutions after their unfreezing.     

Beta-hairpin folding by a model amyloid peptide in solution and at an interface

The development of specific agents against amyloidoses requires an understanding of the conformational distribution of fibrillogenic peptides at a microscopic level. Here, I present molecular dynamics simulations of the model amyloid peptide LSFD with sequence LSFDNSGAITIG-NH2 in explicit water and at a water/vapor interface for a total time scale of approximately 1.8 micros. An extended structure was used as initial peptide configuration. At approximately 290 K, solvated LSFD was kinetically trapped in diverse misfolded beta-sheet/coil conformations. At 350 K, in contrast, the same type II' beta-hairpin in equilibrium with less ordered but also U-shaped conformations was observed for the core residues DNSGAITI in solution and at the interface in multiple independent simulations. The most stable structural unit of the beta-hairpin was the two residue turn (GA). The core residues exhibited a well-defined folded state in which the beta-hairpin was stabilized by a hydrogen bond between the side chain of Asn-385 and the main chain carbonyl group of Gly-387. My results suggest that beta-sheet conformations indicated from previous Fourier-transform infrared spectroscopy measurements immediately after preparation of the peptide solution may not arise from protofilaments as speculated by others but are a property of LSFD monomers. In addition, combined with previous results from X-ray scattering, my findings suggest that interfacial aggregation of LSFD implies a transition from U-shaped to extended peptide conformations. This work including the first simulations of reversible beta-hairpin folding at an interface is an essential step toward a microscopic understanding of interfacial peptide folding and self-assembly. Knowledge of the main conformation of the peptide core may facilitate the design of possible inhibitors of LSFD aggregation as a test ground for future computational therapeutic strategies against amyloid diseases.     

Replica exchange molecular dynamics simulations of amyloid peptide aggregation

The replica exchange molecular dynamics (REMD) approach is applied to four oligomeric peptide systems. At physiologically relevant temperature values REMD samples conformation space and aggregation transitions more efficiently than constant temperature molecular dynamics (CTMD). During the aggregation process the energetic and structural properties are essentially the same in REMD and CTMD. A condensation stage toward disordered aggregates precedes the beta-sheet formation. Two order parameters, borrowed from anisotropic fluid analysis, are used to monitor the aggregation process. The order parameters do not depend on the peptide sequence and length and therefore allow to compare the amyloidogenic propensity of different peptides     

DNA fragment analysis by an affordable multiple-channel capillary electrophoresis system

We are demonstrating a cost-effective multichannel capillary electrophoresis system for a high-efficiency double-stranded DNA (dsDNA) fragments analysis. This bench-type high-performance DNA analysis (HDA) system uses fluorescence-type detection with inexpensive solid-state light sources and nonmoving integrated emission collection micro-optics. DNA samples are analyzed simultaneously by using a multiple usage and disposable multicapillary cartridge, which contains integrated capillary channels, optical fibers and an integrated sieving gel reservoir. Using commercially available dsDNA size markers as indicators, the HDA system provides high resolving power in 7 min separations. The system can hold a total of 192 samples in two 96-well polymerase chain reaction (PCR) plates, which can be automatically analyzed within 2.5 h. This affordable system can be used in laboratories to replace slab gel electrophoresis for routine and high-throughput dsDNA analysis.     

Assembly of Alzheimer's Aβ peptide into nanostructured amyloid fibrils

The self-assembly of β-amyloid (Aβ) peptide into highly ordered amyloid fibril structures represents one of the pathological hallmarks of Alzheimer's disease. This process leads to the transient stabilization of ordered or disordered intermediates, which are thought to act as the main pathogenic culprits in neurodegenerative amyloid disease. This review describes recent results from different biophysical techniques, ranging from structure determination to single-particle methods by which the outgrowth of individual fibrils can be followed, and it explains their contributions towards understanding the mechanism of assembly. Finally, we will outline emerging methods and molecules to specifically interfere with the assembly and pathogenic impact of Aβ peptide.     

Effect of PEG crystallization on the self-assembly of PEG/peptide copolymers containing amyloid peptide fragments

The effect of poly(ethylene glycol) PEG crystallization on beta-sheet fibril formation is studied for a series of three peptide/PEG conjugates containing fragments modified from the amyloid beta peptide, specifically KLVFF, FFKLVFF, and AAKLVFF. These are conjugated to PEG with M n = 3300 g mol (-1). It is found, via small-angle X-ray scattering, X-ray diffraction, atomic force microscopy, and polarized optical microscopy, that PEG crystallinity in dried samples can disturb fibrillization, in particular cross-beta amyloid structure formation, for the conjugate containing the weak fibrillizer KLVFF, whereas this is retained for the conjugates containing the stronger fibrillizers AAKLVFF and FFKLVFF. For these two samples, the alignment of peptide fibrils also drives the orientation of the attached PEG chains. Our results highlight the importance of the antagonistic effects of PEG crystallization and peptide fibril formation in PEG/peptide conjugates.     

Morphology and persistence length of amyloid fibrils are correlated to peptide molecular structure

The formation of amyloid fibrils is a self-assembly process of peptides or proteins. The superior mechanical properties of these fibrils make them interesting for materials science but constitute a problem in amyloid-related diseases. Amyloid structures tend to be polymorphic, and their structure depends on growth conditions. To understand and control the assembly process, insights into the relation between the mechanical properties and molecular structure are essential. We prepared long, straight as well as short, worm-like β-lactoglobulin amyloid fibrils and determined their morphology and persistence length by atomic force microscopy (AFM) and the molecular conformation using vibrational sum-frequency generation (VSFG) spectroscopy. We show that long fibrils with near-100% β-sheet content have a 40-times higher persistence length than short, worm-like fibrils with β-sheet contents below 80%.     

Probing amyloid fibril formation of the NFGAIL peptide by computer simulations

Amyloid fibril formation, as observed in Alzheimer's disease and type II diabetes, is currently described by a nucleation-condensation mechanism, but the details of the process preceding the formation of the nucleus are still lacking. In this study, using an activation-relaxation technique coupled to a generic energy model, we explore the aggregation pathways of 12 chains of the hexapeptide NFGAIL. The simulations show, starting from a preformed parallel dimer and ten disordered chains, that the peptides form essentially amorphous oligomers or more rarely ordered beta-sheet structures where the peptides adopt a parallel orientation within the sheets. Comparison between the simulations indicates that a dimer is not a sufficient seed for avoiding amorphous aggregates and that there is a critical threshold in the number of connections between the chains above which exploration of amorphous aggregates is preferred.     

Detection of cis-trans isomers of a synthetic peptide fragment of erythropoietin

The synthesis of the protected fragment t-butoxycarbonyl-alanine-isoleucine-serine(benzyl)-proline (Pro)-Pro-OH derived from the hormone erythropoietin is described. The analysis of the peptide by high-pressure liquid chromatography (HPLC) and thin-layer chromatography (TLC) yields apparently inconsistent results. Although HPLC consistently indicates the presence of only one component, TLC reveals a number of distinct species. Because satisfactory amino acid analysis and fast atom bombardment-mass spectrometry results are obtained, we think it possible that the distinct components arise from the cis-trans isomerization of the peptide bonds to the prolyl residues. An analysis using capillary electrophoresis under basic conditions identifies four components in the final product. Also, under similar conditions proton nuclear magnetic resonance spectroscopy is able to confirm the presence of cis and trans isomers. The results from this study demonstrate the usefulness of each of the four techniques in identifying the isomerism of the standard amino acid-Pro bond with respect to the peptide's ionic state.     

Characterizing the first steps of amyloid formation for the ccbeta peptide

We employ constant-temperature and replica exchange molecular dynamics to survey the free energy landscape of the ccbeta peptide using a united-atom potential and an implicit solvent representation. Starting from the experimental coiled-coil structure we observe alpha to beta conversion on increasing the temperature, in agreement with experiment. Various beta-sheet trimers are identified as free energy minima, including one that closely resembles the amyloid beta-sheet model previously proposed from experimental data. We characterize two alternative pathways leading to beta-sheets. The first proceeds via direct alpha to beta conversion without dissociation of the trimer, and the second can be classified as a dissociation/reassociation pathway.     

Neutral fragment mass spectra via ambient thermal dissociation of peptide and protein ions

A novel method for the fragmentation of peptide and protein ions at atmospheric pressure outside the mass spectrometer is described. Peptide/protein ions generated by electrosonic spray ionization (ESSI) are carried through a heated coiled metal tube where they fragment. Fragment ions of types a, b, and y are observed for peptides such as angiotensin II and bradykinin. In the case of phosphopeptides, informative b and y ions which preserve the labile phosphate groups are observed in the negative ion mode, which is potentially useful in the location of phosphorylation sites in proteins through chemical analysis of phosphopeptides. The thermal dissociation method extends to proteins such as ubiquitin and myoglobin, giving rise to y-type and other fragment ions. The most important feature of this method is that it also allows characterization of the neutral fragments arising from thermal dissociation by use of on-line corona discharge ionization. This neutral re-ionization experiment is much easier to perform outside the mass spectrometer than as conventionally done, in vacuum. It yields increased structural information from the resulting mass spectra in both the positive and the negative ion modes.     

Shifting unoccupied spectral space in mass spectrum of peptide fragment ions

Ions near the high-end border of a mass defect distribution plot for native peptide fragment ions have potential as signature markers that are based on mass-to-charge ratio determination. The specificity of these marker ions, including phosphoryl ions, can be improved by removing interfering isobaric ions from the border region on the distribution plot. These interfering ions are rich in Asp and Glu content. The masses of amino acid residues and peptides are rescaled from the IUPAC scale (¹²C=12 u as the mass reference) to the averagine scale (averagine mass=111 u* as the mass reference with zero mass defect; u*: the mass unit on the averagine scale), using a scaling factor of 0.999493894. It is theoretically predicted that esterification of Asp and Glu side-chain carboxylates with n-butanol can achieve a sufficient retreat of the high-end border on a mass defect distribution plot based on the use of mass spectrometers with better-than-medium resolution. Theoretical calculations and laboratory experiments are performed to examine effects of various esterifications on the averagine-scale mass defect distribution of peptide fragment ions and on the specificity of two positive phosphoryl ions: the phosphotyrosine immonium ion and a cyclophosphoramidate ion.     

Hydrogen exchange mass spectrometry as an analytical tool for the analysis of amyloid fibrillogenesis

In this study, we have used glucagon as a model system for analyzing amyloid fibrillogenesis by hydrogen exchange MALDI mass spectrometry (HXMS). The hydrogen exchange mass spectrometry data correlated well with the traditional method based on Thioflavin T fluorescence and provided quantitative information by measuring the fibrillating molecules directly. The hydrogen exchange mass spectrometry data collected during fibrillogenesis revealed that glucagon fibrillation was a two component system showing an on/off type of interaction where only monomeric and fibrils were present without any substantial amount of intermediate species. This was evident by the extensive deuteration of the monomer and protection of the entire 29 residue glucagon peptide upon fibrillation.. The method complements the traditional procedures and has the potential to provide new information with respect to the nature of transient species, the structure of the growing fibrils and the mechanism of formation.