Influence of denaturants on amyloid ß42 aggregation kinetics.

Amyloid formation is linked to devastating neurodegenerative diseases, motivating detailed studies of the mechanisms of amyloid formation. For Aß, the peptide associated with Alzheimer's disease, the mechanism and rate of aggregation have been established for a range of variants and conditions in vitro and in bodily fluids. A key outstanding question is how the relative stabilities of monomers, fibrils and intermediates affect each step in the fibril formation process. By monitoring the kinetics of aggregation of Aß42, in the presence of urea or guanidinium hydrochloride (GuHCl), we here determine the rates of the underlying microscopic steps and establish the importance of changes in relative stability induced by the presence of denaturant for each individual step. Denaturants shift the equilibrium towards the unfolded state of each species. We find that a non-ionic denaturant, urea, reduces the overall aggregation rate, and that the effect on nucleation is stronger than the effect on elongation. Urea reduces the rate of secondary nucleation by decreasing the coverage of fibril surfaces and the rate of nucleus formation. It also reduces the rate of primary nucleation, increasing its reaction order. The ionic denaturant, GuHCl, accelerates the aggregation at low denaturant concentrations and decelerates the aggregation at high denaturant concentrations. Below approximately 0.25 M GuHCl, the screening of repulsive electrostatic interactions between peptides by the charged denaturant dominates, leading to an increased aggregation rate. At higher GuHCl concentrations, the electrostatic repulsion is completely screened, and the denaturing effect dominates. The results illustrate how the differential effects of denaturants on stability of monomer, oligomer and fibril translate to differential effects on microscopic steps, with the rate of nucleation being most strongly reduced.

Ultrastructural evidence for self-replication of Alzheimer-associated Aß42 amyloid along the sides of fibrils.

The nucleation of Alzheimer-associated Aß peptide monomers can be catalyzed by preexisting Aß fibrils. This leads to autocatalytic amplification of aggregate mass and underlies self-replication and generation of toxic oligomers associated with several neurodegenerative diseases. However, the nature of the interactions between the monomeric species and the fibrils during this key process, and indeed the ultrastructural localization of the interaction sites have remained elusive. Here we used NMR and optical spectroscopy to identify conditions that enable the capture of transient species during the aggregation and secondary nucleation of the Aß42 peptide. Cryo-electron microscopy (cryo-EM) images show that new aggregates protrude from the entire length of the progenitor fibril. These protrusions are morphologically distinct from the well-ordered fibrils dominating at the end of the aggregation process. The data provide direct evidence that self-replication through secondary nucleation occurs along the sides of fibrils, which become heavily decorated under the current solution conditions (14 µM Aß42, 20 mM sodium phosphate, 200 µM EDTA, pH 6.8).

Conserved S/T Residues of the Human Chaperone DNAJB6 Are Required for Effective Inhibition of Aß42 Amyloid Fibril Formation.

The human molecular chaperone DNAJB6, an oligomeric protein with a conserved S/T-rich region, is an efficient suppressor of amyloid fibril formation by highly aggregation-prone peptides such as the Aß and polyQ peptides associated with Alzheimer's and Huntington's disease, respectively. We previously showed that DNAJB6 can inhibit the processes through which amyloid fibrils are formed via strong interactions with aggregated forms of Aß42 that become sequestered. Here we report that the concentration-dependent capability of DNAJB6 to suppress fibril formation in thioflavin T fluorescence assays decreases progressively with an increasing number of S/T substitutions, with an almost complete loss of suppression when 18 S/T residues are substituted. The kinetics of primary nucleation in particular are affected. No detectable changes in the structure are caused by the substitutions. Also, the level of binding of DNAJB6 to Aß42 decreases with the S/T substitutions, as determined by surface plasmon resonance and microscale thermophoresis. The aggregation process monitored using nuclear magnetic resonance spectroscopy showed that DNAJB6, in contrast to a mutational variant with 18 S/T residues substituted, can keep monomeric Aß42 soluble for an extended time. The inhibition of the primary nucleation is likely to depend on hydroxyl groups in side chains of the S/T residues, and hydrogen bonding with Aß42 is one plausible molecular mechanism, although other possibilities cannot be excluded. The loss of the ability to suppress fibril formation upon S/T to A substitution was previously observed also for polyQ peptides, suggesting that the S/T residues in the DNAJB6-like chaperones have a general ability to inhibit amyloid fibril formation by different aggregation-prone peptides.

Distinct thermodynamic signatures of oligomer generation in the aggregation of the amyloid-ß peptide.

Mapping free-energy landscapes has proved to be a powerful tool for studying reaction mechanisms. Many complex biomolecular assembly processes, however, have remained challenging to access using this approach, including the aggregation of peptides and proteins into amyloid fibrils implicated in a range of disorders. Here, we generalize the strategy used to probe free-energy landscapes in protein folding to determine the activation energies and entropies that characterize each of the molecular steps in the aggregation of the amyloid-ß peptide (Aß42), which is associated with Alzheimer's disease. Our results reveal that interactions between monomeric Aß42 and amyloid fibrils during fibril-dependent secondary nucleation fundamentally reverse the thermodynamic signature of this process relative to primary nucleation, even though both processes generate aggregates from soluble peptides. By mapping the energetic and entropic contributions along the reaction trajectories, we show that the catalytic efficiency of Aß42 fibril surfaces results from the enthalpic stabilization of adsorbing peptides in conformations amenable to nucleation, resulting in a dramatic lowering of the activation energy for nucleation.

The Aß40 and Aß42 peptides self-assemble into separate homomolecular fibrils in binary mixtures but cross-react during primary nucleation.

The assembly of proteins into amyloid fibrils, a phenomenon central to several currently incurable human diseases, is a process of high specificity that commonly tolerates only a low level of sequence mismatch in the component polypeptides. However, in many cases aggregation-prone polypeptides exist as mixtures with variations in sequence length or post-translational modifications; in particular amyloid ß (Aß) peptides of variable length coexist in the central nervous system and possess a propensity to aggregate in Alzheimer's disease and related dementias. Here we have probed the co-aggregation and cross-seeding behavior of the two principal forms of Aß, Aß40 and Aß42 that differ by two hydrophobic residues at the C-terminus. We find, using isotope-labeling, mass spectrometry and electron microscopy that they separate preferentially into homomolecular pure Aß42 and Aß40 structures during fibril formation from mixed solutions of both peptides. Although mixed fibrils are not formed, the kinetics of amyloid formation of one peptide is affected by the presence of the other form. In particular monomeric Aß42 accelerates strongly the aggregation of Aß40 in a concentration-dependent manner. Whereas the aggregation of each peptide is catalyzed by low concentrations of preformed fibrils of the same peptide, we observe a comparably insignificant effect when Aß42 fibrils are added to Aß40 monomer or vice versa. Therefore we conclude that fibril-catalysed nucleus formation and elongation are highly sequence specific events but Aß40 and Aß42 interact during primary nucleation. These results provide a molecular level description of homomolecular and heteromolecular aggregation steps in mixtures of polypeptide sequence variants.

Quantification of the concentration of Aß42 propagons during the lag phase by an amyloid chain reaction assay.

The aggregation of the amyloid beta peptide, Aß42, implicated in Alzheimer's disease, is characterized by a lag phase followed by a rapid growth phase. Conventional methods to study this reaction are not sensitive to events taking place early in the lag phase promoting the assumption that only monomeric or oligomeric species are present at early stages and that the lag time is defined by the primary nucleation rate only. Here we exploit the high sensitivity of chemical chain reactions to the reagent composition to develop an assay which improves by 2 orders of magnitude the detection limit of conventional bulk techniques and allows the concentration of fibrillar Aß42 propagons to be detected and quantified even during the lag time. The method relies on the chain reaction multiplication of a small number of initial fibrils by secondary nucleation on the fibril surface in the presence of monomeric peptides, allowing the quantification of the number of initial propagons by comparing the multiplication reaction kinetics with controlled seeding data. The quantitative results of the chain reaction assay are confirmed by qualitative transmission electron microscopy analysis. The results demonstrate the nonlinearity of the aggregation process which involves both primary and secondary nucleation events even at the early stages of the reaction during the lag-phase.

Role of aromatic side chains in amyloid ß-protein aggregation.

Aggregation of the amyloid ß-protein (Aß) is believed to be involved in Alzheimer's disease pathogenesis. Here we have investigated the importance of the aromatic rings at positions 19 and 20 for the aggregation rate and mechanism by substituting phenylalanine with leucine. Aggregation kinetics were monitored as a function of time and peptide concentration by thioflavin T (ThT) fluorescence, the aggregation equilibrium by sedimentation assay, structural changes using circular dichroism spectroscopy and the presence of fibrillar material was detected with cryo-transmission electron microscopy. All peptides convert from monomer to amyloid fibrils in a concentration-dependent manner. Substituting F19 with leucine results in a peptide that aggregates significantly slower than the wild type, while substitution of F20 produces a peptide that aggregates faster. The effects of the two substitutions are additive, since simultaneous substitution of F19 and F20 produces a peptide with aggregation kinetics intermediate between F19L and F20L. Our results suggest that the aromatic side-chain of F19 favors nucleation of the aggregation process and may be an important target for therapeutic intervention.

Specific binding of a ß-cyclodextrin dimer to the amyloid ß peptide modulates the peptide aggregation process.

Alzheimer's disease involves progressive neuronal loss. Linked to the disease is the amyloid ß (Aß) peptide, a 38-43-amino acid peptide found in extracellular amyloid plaques in the brain. Cyclodextrins are nontoxic, cone-shaped oligosaccharides with a hydrophilic exterior and a hydrophobic cavity making them suitable hosts for aromatic guest molecules in water. ß-Cyclodextrin consists of seven α-d-glucopyranoside units and has been shown to reduce the level of fibrillation and neurotoxicity of Aß. We have studied the interaction between Aß and a ß-cyclodextrin dimer, consisting of two ß-cyclodextrin monomers connected by a flexible linker. The ß-cyclodextrin monomer has been found to interact with Aß(1-40) at sites Y10, F19, and/or F20 with a dissociation constant (K(D)) of 3.9 ± 2.0 mM. Here (1)H-(15)N and (1)H-(13)C heteronuclear single-quantum correlation nuclear magnetic resonance (NMR) spectra show that in addition, the ß-cyclodextrin monomer and dimer bind to the histidines. NMR translational diffusion experiments reveal the increased affinity of the ß-cyclodextrin dimer (apparent K(D) of 1.1 ± 0.5 mM) for Aß(1-40) compared to that of the ß-cyclodextrin monomer. Kinetic aggregation experiments based on thioflavin T fluorescence indicate that the dimer at 0.05-5 mM decreases the lag time of Aß aggregation, while a concentration of 10 mM increases the lag time. The ß-cyclodextrin monomer at a high concentration decreases the lag time of the aggregation. We conclude that cyclodextrin monomers and dimers have specific, modulating effects on the Aß(1-40) aggregation process. Transmission electron microscopy shows that the regular fibrillar aggregates formed by Aß(1-40) alone are replaced by a major fraction of amorphous aggregates in the presence of the ß-cyclodextrin dimer.

Biocompatibility of mannan nanogel--safe interaction with plasma proteins.

BACKGROUND: Self-assembled mannan nanogels are designed to provide a therapeutic or vaccine delivery platform based on the bioactive properties of mannan to target mannose receptor expressed on the surface of antigen-presenting cells, combined with the performance of nanogels as carriers of biologically active agents. METHODS: Proteins in the corona around mannan nanogel formed in human plasma were identified by mass spectrometry after size exclusion chromatography or centrifugation followed by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Structural changes and time dependent binding of human apolipoprotein A-I (apoA-I) and human serum albumin (HSA) to mannan nanogel were studied using intrinsic tryptophan fluorescence and circular dichroism spectroscopy. The mannan nanogel effect on blood coagulation and fibrillation of Alzheimer's disease-associated amyloid ß peptide and hemodialysis-associated amyloidosis ß2 microglobulin was evaluated using thrombin generation assay or thioflavin T fluorescence assay, respectively. RESULTS: The protein corona around mannan nanogel is formed through a slow process, is quite specific comprising apolipoproteins B-100, A-I and E and HSA, evolves over time, and the equilibrium is reached after hours to days. Structural changes and time dependent binding of apoA-I and HSA to mannan nanogel are minor. The mannan nanogel does not affect blood coagulation and retards the fibril formation. CONCLUSIONS: Mannan nanogel has a high biosafety and biocompatibility, which is mandatory for nanomaterials to be used in biomedical applications. GENERAL SIGNIFICANCE: Our research provides a molecular approach to evaluate the safety aspects of nanomaterials, which is of general concern in society and science.

Structural changes in apolipoproteins bound to nanoparticles.

Nanoparticles are widely used in the pharmaceutical and food industries, but the consequences of exposure to the human body have not been thoroughly investigated. Apolipoprotein A-I (apoAI), the major protein in high-density lipoprotein (HDL), and other lipoproteins are found in the corona around many nanoparticles, but data on protein structural and functional effects are lacking. Here we investigate the structural consequences of the adsorption of apoAI, apolipoprotein B100 (apoB100), and HDL on polystyrene nanoparticles with different surface charges. The results of circular dichroism, fluorescence spectroscopy, and limited proteolysis experiments indicate effects on both secondary and tertiary structures. Plain and negatively charged nanoparticles induce helical structure in apoAI (negative net charge) whereas positively charged nanoparticles reduce the amount of helical structure. Plain and negatively charged particles induce a small blue shift in the tryptophan fluorescence spectrum, which is not noticed with the positively charged particles. Similar results are observed with reconstituted HDL. In apoB100, both secondary and tertiary structures are perturbed by all particles. To investigate the generality of the role of surface charge, parallel experiments were performed using human serum albumin (HSA, negative net charge) and lysozyme (positive net charge). Again, the secondary structure is most affected by nanoparticles carrying an opposite surface charge relative to the protein. Nanoparticles carrying the same net charge as the protein induce only minor structural changes in lysozyme whereas a moderate change is observed for HSA. Thus, surface charge is a critical parameter for predicting structural changes in adsorbed proteins, yet the effect is specific for each protein.

Reductive openings of benzylidene acetals. Kinetic studies of borane and alane activation by Lewis acids.

The reaction kinetics for a number of reductive openings of methyl 2,3-di-O-benzyl-4,6-O-benzylidene-alpha-D-glucopyranoside have been investigated. Openings to give free HO-6 (using BH(3) x THF-AlCl(3)-THF or LiAlH(4)-AlCl(3)-Et(2)O) follow first order kinetics, while reactions yielding free HO-4 (using BH(3) x NMe(3)-AlCl(3)-THF or BH(3) x NMe(3)-BF(3) x OEt(2)-THF) follow higher order kinetics. The addition of water to the BH(3) x NMe(3)-AlCl(3)-THF results in faster reactions. The BH(3) x SMe(2)-AlCl(3)-THF system constitutes a borderline case, yielding both free HO-6 (by a first order reaction) and free HO-4 (by a higher order reaction). These results correlate well with the concept of regioselectivity by activation of borane complexes.