β‐sheet breaker peptide inhibitor of Alzheimer's amyloidogenesis with increased blood–brain barrier permeability and resistance to proteolytic degradation in plasma

Short synthetic peptides homologous to the central region of Aβ but bearing proline residues as β‐sheet blockers have been shown in vitro to bind to Aβ with high affinity, partially inhibit Aβ fibrillogenesis, and redissolve preformed fibrils. While short peptides have been used extensively as therapeutic drugs in medicine, two important problems associated with their use in central nervous system diseases have to be addressed: (a) rapid proteolytic degradation in plasma, and (b) poor blood–brain barrier (BBB) permeability. Recently, we have demonstrated that the covalent modification of proteins with the naturally occurring polyamines significantly increases their permeability at the BBB. We have extended this technology to iAβ11, an 11‐residue β‐sheet breaker peptide that inhibits Aβ fibrillogenesis, by covalently modifying this peptide with the polyamine, putrescine (PUT), and evaluating its plasma pharmacokinetics and BBB permeability. After a single intravenous bolus injection in rats, both ¹²⁵I‐YiAβ11 and ¹²⁵I‐PUT‐YiAβ11 showed rapid degradation in plasma as determined by trichloroacetic acid (TCA) precipitation and paper chromatography. By switching to the all d ‐enantiomers of YiAβ11 and PUT‐YiAβ11, significant protection from degradation by proteases in rat plasma was obtained with only 1.9% and 5.7% degradation at 15 min after intravenous bolus injection, respectively. The permeability coefficient × surface area product at the BBB was five‐ sevenfold higher in the cortex and hippocampus for the ¹²⁵I‐PUT‐d ‐YiAβ11 compared to the ¹²⁵I‐d ‐YiAβ11, with no significant difference in the residual plasma volume. In vitro assays showed that PUT‐d ‐YiAβ11 retains its ability to partially inhibit Aβ fibrillogenesis and dissolve preformed amyloid fibrils. Because of its five‐ to sevenfold increase in permeability at the BBB and its resistance to proteolysis in the plasma, this polyamine‐modified β‐sheet breaker peptide may prove to be an effective inhibitor of amyloidogenesis in vivo and, hence, an important therapy for Alzheimer's disease. © 1999 John Wiley & Sons, Inc. J Neurobiol 39: 371–382, 1999     

Inhibition of beta-amyloid(40) fibrillogenesis and disassembly of beta-amyloid(40) fibrils by short beta-amyloid congeners containing N-methyl amino acids at alternate residues.

A potential goal in the prevention or therapy of Alzheimer's disease is to decrease or eliminate neuritic plaques composed of fibrillar beta-amyloid (Abeta). In this paper we describe N-methyl amino acid containing congeners of the hydrophobic "core domain" of Abeta that inhibit the fibrillogenesis of full-length Abeta. These peptides also disassemble preformed fibrils of full-length Abeta. A key feature of the inhibitor peptides is that they contain N-methyl amino acids in alternating positions of the sequence. The most potent of these inhibitors, termed Abeta16-22m, has the sequence NH(2)-K(Me-L)V(Me-F)F(Me-A)E-CONH(2). In contrast, a peptide, NH(2)-KL(Me-V)(Me-F)(Me-F)(Me-A)-E-CONH(2), with N-methyl amino acids in consecutive order, is not a fibrillogenesis inhibitor. Another peptide containing alternating N-methyl amino acids but based on the sequence of a different fibril-forming protein, the human prion protein, is also not an inhibitor of Abeta40 fibrillogenesis. The nonmethylated version of the inhibitor peptide, NH(2)-KLVFFAE-CONH(2) (Abeta16-22), is a weak fibrillogenesis inhibitor. Perhaps contrary to expectations, the Abeta16-22m peptide is highly soluble in aqueous media, and concentrations in excess of 40 mg/mL can be obtained in buffers of physiological pH and ionic strength, compared to only 2 mg/mL for Abeta16-22. Analytical ultracentrifugation demonstrates that Abeta16-22m is monomeric in buffer solution. Whereas Abeta16-22 is susceptible to cleavage by chymotrypsin, the methylated inhibitor peptide Abeta16-22m is completely resistant to this protease. Circular dichroic spectroscopy of Abeta16-22m indicates that this peptide is a beta-strand, albeit with an unusual minimum at 226 nm. In summary, the inhibitor motif is that of alternating N-methyl and nonmethylated amino acids in a sequence critical for Abeta40 fibrillogenesis. These inhibitors appear to act by binding to growth sites of Abeta nuclei and/or fibrils and preventing the propagation of the network of hydrogen bonds that is essential for the formation of an extended beta-sheet fibril.     

Influence of fluorinated and hydrogenated nanoparticles on the structure and fibrillogenesis of amyloid beta-peptide

Peptide aggregation in amyloid fibrils is implicated in the pathogenesis of several diseases such as Alzheimer's disease. There is a strong correlation between amyloid fibril formation and a decrease in conformational stability of the native state. Amyloid-beta peptide (Abeta), the aggregating peptide in Alzheimer's disease, is natively unfolded. The deposits found in Alzheimer's disease are composed of Abeta fibrillar aggregates rich in beta-sheet structure. The influence of fluorinated complexes on the secondary structure and fibrillogenesis of Abeta peptide was studied by circular dichroism (CD) spectroscopy and transmission electron microscopy (TEM). CD spectra show that complexes of polyampholyte and fluorinated dodecanoic acid induce alpha-helix structure in Abeta, but their hydrogenated analogous lead to beta-sheet formation and aggregation. The fluorinated nanoparticles with highly negative zeta potential and hydrophobic fluorinated core have the fundamental characteristics to prevent Abeta fibrillogenesis.     

Probing the role of backbone hydrogen bonding in beta-amyloid fibrils with inhibitor peptides containing ester bonds at alternate positions

Protein-protein interactions are frequently mediated by stable, intermolecular beta-sheets. A number of cytokines and the HIV Protease, for example, dimerize through beta-sheet motifs. Evidence also suggests that the macromolecular assemblies of peptides and proteins in amyloid fibrils are stabilized by intermolecular beta-sheets. In this paper, we report that interfering with the backbone hydrogen bonding of an amyloidgenic peptide (Abeta16-20) by replacing amide bonds with ester bonds prevents the aggregation of the peptide. The ester bonds were incorporated in an alternating fashion so that the peptide presents two unique hydrogen bonding faces when arrayed in an extended, beta-strand conformation; one face of the peptide has normal hydrogen bonding capabilities, but the other face is missing amide protons and its ability to hydrogen bond is severely limited. Analytical ultracentrifugation experiments demonstrate that this ester peptide, Abeta16-20e, is predominantly monomeric under solution conditions, unlike the fibril-forming Abeta16-20 peptide. Abeta16-20e also inhibits the aggregation of the Abeta1-40 peptide and disassembles preformed Abeta1-40 fibrils. These results suggest that backbone hydrogen bonding is critical for the assembly of amyloid fibrils.     

Spatial separation of beta-sheet domains of beta-amyloid: disruption of each beta-sheet by N-methyl amino acids

In a recent model of beta-amyloid (Abeta) fibrils, based mainly on solid-state NMR data, a molecular layer consists of two beta-sheets (residues 12-23 and 31-40 of Abeta1-40), folded onto one another by a connecting "bend" structure (residues 25-29) in the side-chain dimension. In this paper, we use two N-methyl amino acids to disrupt each of the two beta-sheets individually (2NMe(NTerm), residues 17 and 19; and 2NMe(CTerm), residues 37 and 39), or both of them at the same time (4NMe, with the above four N-methylated residues). Our data indicate that incorporation of two N-methyl amino acids into one beta-sheet is sufficient to disrupt that sheet while leaving the other, unmodified beta-sheet intact and able to form fibrils. We show, however, that disruption of each of the two beta-sheets has strikingly different effects on fibrillogenesis kinetics and fibril morphology. Both 2NMe(NTerm) and 2NMe(CTerm) form fibrils at similar rates, but more slowly than that of unmodified Abeta1-40. Electron microscopy shows that 2NMe(NTerm) forms straight fibrils with fuzzy amorphous material coating the edges, while 2NMe(CTerm) forms very regular, highly twisted fibrils-in both cases, distinct from the morphology of Abeta1-40 fibrils. Both 2NMe peptides show a "CMC" approximately four times greater than that of Abeta1-40. CD spectra of these peptides also evolve differently in time: whereas the CD spectra of 2NMe(NTerm) evolve little over 10 days, those of 2NMe(CTerm) show a transition to high beta-sheet content at about day 4-5. We also show that disruption of both beta-sheet domains, as in 4NMe, prevents fibril formation altogether, and renders Abeta1-40 highly water soluble and monomeric, and with solvent-exposed side chains. In summary, our data show (1) that the two beta-sheet domains fold in a semiautonomous manner, since disrupting each one still allows the other to fold; (2) that disruption of the N-terminal beta-sheet has a more profound effect on fibrillogenesis than disruption of the C-terminal beta-sheet, suggesting that the former is the more critical for the overall structure of the fibril; and (3) that disruption of both beta-sheet domains renders the peptide monomeric and unable to form fibrils.     

Discrete conformational changes as regulators of the hydrolytic properties of beta-amyloid (1-40)

Beta-amyloid (1-40) (Abeta), the main component of senile plaques seen in the brains of Alzheimer's disease patients, was found to be toxic both as fibrils and smaller soluble globular aggregates. The hydrolytic properties of Abeta, a new biochemical activity described previously [Brzyska M, Bacia A & Elbaum D (2001) Eur J Biochem 268, 3443-3454], may contribute to its overall toxicity. In this study, the hydrolysis of fluorescein ester series was studied under predetermined conditions affecting Abeta hydrophobicity and conformation. Reaction products of the most effectively decomposed ester (dibutyrate) were characterized using HPLC and ESI-MS. Hydrophobicity of Abeta, as measured by bis-8-anilinonaphthalene fluorescence, correlated with its hydrolytic abilities. FTIR and CD data analysis showed a relationship between enhanced hydrolytic abilities and Abeta structure. Seriously limited hydrolysis caused by higher peptide concentrations is consistent with monomeric/dimeric Abeta species participation in the process, confirmed by thioflavine T binding. Inhibition of hydrolysis was caused by beta-sheet breaker peptide (LPFFD), indicating that the Abeta central hydrophobic cluster (amino acids 17-21) participates in the process. The reported Abeta properties suggest that small conformational alterations of the peptide structure may have a pronounced effect on its functions and biological activity.     

Circular dichroism and aggregation studies of amyloid beta (11-8) fragment and its variants

Aggregation of Abeta peptides is a seminal event in Alzheimer's disease. Detailed understanding of Abeta assembly would facilitate the targeting and design of fibrillogenesis inhibitors. Here comparative conformational and aggregation studies using CD spectroscopy and thioflavine T fluorescence assay are presented. As a model peptide, the 11-28 fragment of Abeta was used. This model peptide is known to contain the core region responsible for Abeta aggregation. The structural and aggregational behaviour of the peptide was compared with the properties of its variants corresponding to natural, clinically relevant mutants at positions 21-23 (A21G, E22K, E22G, E22Q and D23N). In HFIP (hexafluoro-2-propanol), a strong alpha-helix inducer, the CD spectra revealed an unexpectedly high amount of beta-sheet conformation. The aggregation process of Abeta(11-28) variants provoked by water addition to HFIP was found to be consistent with a model of an alpha-helix-containing intermediate. The aggregation propensity of all Abeta(11-28) variants was also compared and discussed.     

The ratio of monomeric to aggregated forms of Abeta40 and Abeta42 is an important determinant of amyloid-beta aggregation, fibrillogenesis, and toxicity

Aggregation and fibril formation of amyloid-beta (Abeta) peptides Abeta40 and Abeta42 are central events in the pathogenesis of Alzheimer disease. Previous studies have established the ratio of Abeta40 to Abeta42 as an important factor in determining the fibrillogenesis, toxicity, and pathological distribution of Abeta. To better understand the molecular basis underlying the pathologic consequences associated with alterations in the ratio of Abeta40 to Abeta42, we probed the concentration- and ratio-dependent interactions between well defined states of the two peptides at different stages of aggregation along the amyloid formation pathway. We report that monomeric Abeta40 alters the kinetic stability, solubility, and morphological properties of Abeta42 aggregates and prevents their conversion into mature fibrils. Abeta40, at approximately equimolar ratios (Abeta40/Abeta42 approximately 0.5-1), inhibits (> 50%) fibril formation by monomeric Abeta42, whereas inhibition of protofibrillar Abeta42 fibrillogenesis is achieved at lower, substoichiometric ratios (Abeta40/Abeta42 approximately 0.1). The inhibitory effect of Abeta40 on Abeta42 fibrillogenesis is reversed by the introduction of excess Abeta42 monomer. Additionally, monomeric Abeta42 and Abeta40 are constantly recycled and compete for binding to the ends of protofibrillar and fibrillar Abeta aggregates. Whereas the fibrillogenesis of both monomeric species can be seeded by fibrils composed of either peptide, Abeta42 protofibrils selectively seed the fibrillogenesis of monomeric Abeta42 but not monomeric Abeta40. Finally, we also show that the amyloidogenic propensities of different individual and mixed Abeta species correlates with their relative neuronal toxicities. These findings, which highlight specific points in the amyloid peptide equilibrium that are highly sensitive to the ratio of Abeta40 to Abeta42, carry important implications for the pathogenesis and current therapeutic strategies of Alzheimer disease.     

Review: modulating factors in amyloid-beta fibril formation

Amyloid formation is a key pathological feature of Alzheimer's disease and is considered to be a major contributing factor to neurodegeneration and clinical dementia. Amyloid is found as both diffuse and senile plaques in the parenchyma of the brain and is composed primarily of the 40- to 42-residue amyloid-beta (Abeta) peptides. The characteristic amyloid fiber exhibits a high beta-sheet content and may be generated in vitro by the nucleation-dependent self-association of the Abeta peptide and an associated conformational transition from random to beta-conformation. Growth of the fibrils occurs by assembly of the Abeta seeds into intermediate protofibrils, which in turn self-associate to form mature fibers. This multistep process may be influenced at various stages by factors that either promote or inhibit Abeta fiber formation and aggregation. Identification of these factors and understanding the driving forces behind these interactions as well as the structural motifs necessary for these interactions will help to elucidate potential sites that may be targeted to prevent amyloid formation and its associated toxicity. This review will discuss some of the modulating factors that have been identified to date and their role in fibrillogenesis.     

Interactions of Alzheimer amyloid-beta peptides with glycosaminoglycans effects on fibril nucleation and growth.

Proteoglycans and their constituent glycosaminoglycans are associated with all amyloid deposits and may be involved in the amyloidogenic pathway. In Alzheimer's disease, plaques are composed of the amyloid-beta peptide and are associated with at least four different proteoglycans. Using CD spectroscopy, fluorescence spectroscopy and electron microscopy, we examined glycosaminoglycan interaction with the amyloid-beta peptides 1-40 (Abeta40) and 1-42 (Abeta42) to determine the effects on peptide conformation and fibril formation. Monomeric amyloid-beta peptides in trifluoroethanol, when diluted in aqueous buffer, undergo a slow random to amyloidogenic beta sheet transition. In the presence of heparin, heparan sulfate, keratan sulfate or chondroitin sulfates, this transition was accelerated with Abeta42 rapidly adopting a beta-sheet conformation. This was accompanied by the appearance of well-defined amyloid fibrils indicating an enhanced nucleation of Abeta42. Incubation of preformed Abeta42 fibrils with glycosaminoglycans resulted in extensive lateral aggregation and precipitation of the fibrils. The glycosaminoglycans differed in their relative activities with the chondroitin sulfates producing the most pronounced effects. The less amyloidogenic Abeta40 isoform did not show an immediate structural transition that was dependent upon the shielding effect by the phosphate counter ion. Removal or substitution of phosphate resulted in similar glycosaminoglycan-induced conformational and aggregation changes. These findings clearly demonstrate that glycosaminoglycans act at the earliest stage of fibril formation, namely amyloid-beta nucleation, and are not simply involved in the lateral aggregation of preformed fibrils or nonspecific adhesion to plaques. The identification of a structure-activity relationship between amyloid-beta and the different glycosaminoglycans, as well as the condition dependence for glycosaminoglycan binding, are important for the successful development and evaluation of glycosaminoglycan-specific therapeutic interventions.     

Disassembly of amyloid beta-protein fibril by basement membrane components

Amyloid beta-protein (A3) fibril in senile plaque may be related to the pathogenesis of Alzheimer's disease (AD). Basement membrane (BM) components are associated with the plaques in AD brain. It suggests that the BM components may play an important role in the deposition of the plaque. We investigated the potential of BM components, such as type IV collagen (collagen IV) and entactin, to induce disassembly of preformed Abeta1-42 (Abeta42) fibrils in direct comparison to laminin. Thioflavin T assays revealed that these BM components disrupted preformed Abeta42 fibrils in a dose-dependent manner. The high concentration of BM components, 100 microg/mL laminin, 50 microg/mL collagen IV and 50 microg/mL entactin, had most effect on disassembly of preformed Abeta42 fibrils (Molar ratio; Abeta42:laminin = 90:1, Abeta42:collagen IV = 34:1, Abeta42:entactin = 20:1). Circular dichroism spectroscopy data indicated that the high concentration of BM components induced structural transition in Abeta42 from beta-sheet to random structures. These results suggest that collagen IV and entactin, as well as laminin, are effective inducers of disassembly of Abeta42 fibrils. The ability of these BM components to induce random structures may be linked to the disassembly of preformed Abeta42 fibrils.     

Targeting the early steps of Abeta16-22 protofibril disassembly by N-methylated inhibitors: a numerical study

Aggregation of the Abeta1-40/Abeta1-42 peptides is a key factor in Alzheimer's disease. Though the inhibitory effect of N-methylated Abeta16-22 (mAbeta16-22) peptides is well characterized in vitro, there is little information on how they disassemble full-length Abeta fibrils or block fibril formation. Here, we report coarse-grained implicit solvent molecular dynamics (MD) and replica exchange molecular dynamics (REMD) simulations on Abeta16-22 and mAbeta16-22 monomers, and then a preformed six-chain Abeta16-22 bilayer with either four copies of Abeta16-22 or four copies of mAbeta16-22. Our simulations show that the effect of N-methylation on mAbeta16-22 monomer is to reduce the density of compact forms. While 100 ns MD trajectories do not reveal any significant differences between the two ten-chain systems, the REMD simulations totaling 1 micros help understand the first steps of Abeta16-22 protofibril disassembly by N-methylated inhibitors. Notably, we find that mAbeta16-22 preferentially interacts with Abeta16-22 by blocking both beta-sheet extension and lateral association of layers, but also by intercalation of the inhibitors allowing sequestration of Abeta16-22 peptides. This third binding mode is particularly appealing for blocking Abeta fibrillogenesis.     

Lipid membrane templates the ordering and induces the fibrillogenesis of Alzheimer's disease amyloid-beta peptide

The lipid membrane has been shown to mediate the fibrillogenesis and toxicity of Alzheimer's disease (AD) amyloid-beta (Abeta) peptide. Electrostatic interactions between Abeta40 and the phospholipid headgroup have been found to control the association and insertion of monomeric Abeta into lipid monolayers, where Abeta exhibited enhanced interactions with charged lipids compared with zwitterionic lipids. To elucidate the molecular-scale structural details of Abeta-membrane association, we have used complementary X-ray and neutron scattering techniques (grazing-incidence X-ray diffraction, X-ray reflectivity, and neutron reflectivity) in this study to investigate in situ the association of Abeta with lipid monolayers composed of either the anionic lipid 1,2-dipalmitoyl-sn-glycero-3-[phospho-rac-(1-glycerol)] (DPPG), the zwitterionic lipid 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC), or the cationic lipid 1,2-dipalmitoyl 3-trimethylammonium propane (DPTAP) at the air-buffer interface. We found that the anionic lipid DPPG uniquely induced crystalline ordering of Abeta at the membrane surface that closely mimicked the beta-sheet structure in fibrils, revealing an intriguing templated ordering effect of DPPG on Abeta. Furthermore, incubating Abeta with lipid vesicles containing the anionic lipid 1-palmitoyl-2-oleoyl-sn-glycero-3-[phospho-rac-(1-glycerol)] (POPG) induced the formation of amyloid fibrils, confirming that the templated ordering of Abeta at the membrane surface seeded fibril formation. This study provides a detailed molecular-scale characterization of the early structural fluctuation and assembly events that may trigger the misfolding and aggregation of Abeta in vivo. Our results implicate that the adsorption of Abeta to anionic lipids, which could become exposed to the outer membrane leaflet by cell injury, may serve as an in vivo mechanism of templated-aggregation and drive the pathogenesis of AD.     

Identification and characterization of key kinetic intermediates in amyloid beta-protein fibrillogenesis

Amyloid beta-protein (Abeta) assembly into toxic oligomeric and fibrillar structures is a seminal event in Alzheimer's disease, therefore blocking this process could have significant therapeutic benefit. A rigorous mechanistic understanding of Abeta assembly would facilitate the targeting and design of fibrillogenesis inhibitors. Prior studies have shown that Abeta fibrillogenesis involves conformational changes leading to the formation of extended beta-sheets and that an alpha-helix-containing intermediate may be involved. However, the significance of this intermediate has been a matter of debate. We report here that the formation of an oligomeric, alpha-helix-containing assembly is a key step in Abeta fibrillogenesis. The generality of this phenomenon was supported by conformational studies of 18 different Abeta peptides, including wild-type Abeta(1-40) and Abeta(1-42), biologically relevant truncated and chemically modified Abeta peptides, and Abeta peptides causing familial forms of cerebral amyloid angiopathy. Without exception, fibrillogenesis of these peptides involved an oligomeric alpha-helix-containing intermediate and the kinetics of formation of the intermediate and of fibrils was temporally correlated. The kinetics varied depending on amino acid sequence and the extent of peptide N- and C-terminal truncation. The pH dependence of helix formation suggested that Asp and His exerted significant control over this process and over fibrillogenesis in general. Consistent with this idea, Abeta peptides containing Asp-->Asn or His-->Gln substitutions showed altered fibrillogenesis kinetics. These data emphasize the importance of the dynamic interplay between Abeta monomer conformation and oligomerization state in controlling fibrillogenesis kinetics.     

Identification of a mutant amyloid peptide that predominantly forms neurotoxic protofibrillar aggregates

The amyloid peptide (Abeta), derived from the proteolytic cleavage of the amyloid precursor protein (APP) by beta- and gamma-secretases, undergoes multistage assemblies to fibrillar depositions in the Alzheimer's brains. Abeta protofibrils were previously identified as an intermediate preceding insoluble fibrils. While characterizing a synthetic Abeta variant named EV40 that has mutations in the first two amino acids (D1E/A2V), we discerned unusual aggregation profiles of this variant. In comparison of the fibrillogenesis and cellular toxicity of EV40 to the wild-type Abeta peptide (Abeta40), we found that Abeta40 formed long fibrillar aggregates while EV40 formed only protofibrillar aggregates under the same in vitro incubation conditions. Cellular toxicity assays indicated that EV40 was slightly more toxic than Abeta40 to human neuroblastoma SHEP cells, rat primary cortical, and hippocampal neurons. Like Abeta40, the neurotoxicity of the protofibrillar EV40 could be partially attributed to apoptosis since multiple caspases such as caspase-9 were activated after SHEP cells were challenged with toxic concentrations of EV40. This suggested that apoptosis-induced neuronal loss might occur before extensive depositions of long amyloid fibrils in AD brains. This study has been the first to show that a mutated Abeta peptide formed only protofibrillar species and mutations of the amyloid peptide at the N-terminal side affect the dynamic amyloid fibrillogenesis. Thus, the identification of EV40 may lead to further understanding of the structural perturbation of Abeta to its fibrillation.     

Photoaffinity cross-linking of Alzheimer's disease amyloid fibrils reveals interstrand contact regions between assembled beta-amyloid peptide subunits

The assembly of the beta-amyloid peptide (Abeta) into amyloid fibrils is essential to the pathogenesis of Alzheimer's disease. Detailed structural information about fibrillogenesis has remained elusive due to the highly insoluble, noncrystalline nature of the assembled peptide. X-ray fiber diffraction, infrared spectroscopy, and solid-state NMR studies performed on fibrils composed of Abeta peptides have led to conflicting models of the intermolecular alignment of beta-strands. We demonstrate here the use of photoaffinity cross-linking to determine high-resolution structural constraints on Abeta monomers within amyloid fibrils. A photoreactive Abeta(1-40) ligand was synthesized by substituting L-p-benzoylphenylalanine (Bpa) for phenylalanine at position 4 (Abeta(1-40) F4Bpa). This peptide was incorporated into synthetic amyloid fibrils and irradiated with near-UV light. SDS-PAGE of dissolved fibrils revealed the light-dependent formation of a covalent Abeta dimer. Enzymatic cleavage followed by mass spectrometric analysis demonstrated the presence of a dimer-specific ion at MH(+) = 1825.9, the predicted mass of a fragment composed of the N-terminal Abeta(1-5) F4Bpa tryptic peptide covalently attached to the C-terminal Abeta(29-40) tryptic peptide. MS/MS experiments and further chemical modifications of the cross-linked dimer led to the localization of the photo-cross-link between the ketone of the Bpa4 side chain and the delta-methyl group of the Met35 side chain. The Bpa4-Met35 intermolecular cross-link is consistent with an antiparallel alignment of Abeta peptides within amyloid fibrils.     

Exaggerated polymerisation of beta-amyloid 40 stimulated by plasma lipoproteins results in fibrillar Abeta preparations that are ineffective in promoting ADP-induced platelet aggregation

The cytotoxic beta-amyloid peptide (Abeta) of Alzheimer's disease (AD) occurs in both plasma and platelets and may modulate platelet function. Its biological activity may relate to its fibril content and factors that promote Abeta fibrillogenesis, e.g., plasma lipoproteins could, therefore, have implications for Abeta action. We undertook a study in which structure-activity relationships were considered with respect to the actions of Abeta(1-40) on platelet function. Thus, the influence of soluble Abeta and various fibrillar Abeta preparations (0.1-10 microM) on platelet aggregation and endogenous 5-hydroxytryptamine (5-HT) efflux was investigated. Soluble Abeta(1-40) only enhanced platelet aggregation (+30%, P<0.05) and 5-HT release (+28%) stimulated by ADP (1 microM) at the highest concentration tested (10 microM). By contrast, fibrillar Abeta(1-40) at 1, 5 and 10 microM potentiated aggregation by 17.4%, 68.8% (P<0.05) and 99.5% (P<0.0001), respectively, and 5-HT efflux by 17.4%, 65% and 208% (P<0.001). Abeta(1-40) fibrils generated in the presence of native and oxidised very low-density lipoprotein (VLDL), low-density lipoprotein (LDL) and high-density lipoprotein (HDL) yielded platelet responses that did not differ from those seen with the lipoproteins alone. These responses were markedly lower than those obtained with homogeneous Abeta fibrils. Our data indicate that homogeneous Abeta(1-40) fibrils are more potent than soluble Abeta(1-40) in promoting platelet reactivity and that interactions with plasma lipoproteins result in the formation of Abeta fibrils that are ineffective. We suggest that lipoproteins may interfere with the recognition of Abeta by appropriate platelet receptors and/or cause Abeta to assume an "overaggregated" biologically inert state.     

Inhibitors of amyloid toxicity based on beta-sheet packing of Abeta40 and Abeta42

Amyloid fibrils associated with Alzheimer's disease and a wide range of other neurodegenerative diseases have a cross beta-sheet structure, where main chain hydrogen bonding occurs between beta-strands in the direction of the fibril axis. The surface of the beta-sheet has pronounced ridges and grooves when the individual beta-strands have a parallel orientation and the amino acids are in-register with one another. Here we show that in Abeta amyloid fibrils, Met35 packs against Gly33 in the C-terminus of Abeta40 and against Gly37 in the C-terminus of Abeta42. These packing interactions suggest that the protofilament subunits are displaced relative to one another in the Abeta40 and Abeta42 fibril structures. We take advantage of this corrugated structure to design a new class of inhibitors that prevent fibril formation by placing alternating glycine and aromatic residues on one face of a beta-strand. We show that peptide inhibitors based on a GxFxGxF framework disrupt sheet-to-sheet packing and inhibit the formation of mature Abeta fibrils as assayed by thioflavin T fluorescence, electron microscopy, and solid-state NMR spectroscopy. The alternating large and small amino acids in the GxFxGxF sequence are complementary to the corresponding amino acids in the IxGxMxG motif found in the C-terminal sequence of Abeta40 and Abeta42. Importantly, the designed peptide inhibitors significantly reduce the toxicity induced by Abeta42 on cultured rat cortical neurons.     

Switch-peptides as folding precursors in self-assembling peptides and amyloid fibrillogenesis

The study of conformational transitions of peptides has obtained considerable attention recently because of their importance as a molecular key event in a variety of degenerative diseases. However, the study of peptide self-assembly into beta-sheets and amyloid beta (Abeta) fibrils is strongly hampered by their difficult synthetic access and low solubility. We have recently developed a new concept termed switch-peptides that allows the controlled onset of polypeptide folding and misfolding at physiologic conditions. As a major feature, the folding process is initiated by chemically or enzyme triggered O,N-acyl migration in flexible and soluble folding precursors containing Ser- or Thr-derived switch (S)-elements. The elaborated methodologies are exemplified for the in situ conversion of NPY- and Cyclosporine A-derived prodrugs, as well as for the onset and reversal of alpha and beta conformational transitions in Abeta peptides. In combining orthogonally addressable switch-elements, the consecutive switching on of S-elements gives new insights into the role of individual peptide segments (hot spots) in early processes of polypeptide self-assembly and fibrillogenesis. Finally, the well-known secondary structure disrupting effect of pseudoprolines (PsiPro) is explored for its use as a building block (S-element) in switch-peptides. To this end, synthetic strategies are described, allowing for the preparation of PsiPro-containing folding precursors, exhibiting flexible random-coil conformations devoid of fibril forming propensity. The onset of beta-sheet and fibril formation by restoring the native peptide chain in a single step classify PsiPro-units as the most powerful tool for inhibiting peptide self-assembly, and complement the present methodologies of the switch-concept for the study of fibrillogenesis.     

Study of the conformational transition of A beta(1-42) using D-amino acid replacement analogues

A critical event in Alzheimer's disease is the transition of Abeta peptides from their soluble forms into disease-associated beta-sheet-rich conformers. Structural analysis of a complete D-amino acid replacement set of Abeta(1-42) enabled us to localize in the full-length 42-mer peptide the region responsible for the conformational switch into a beta-sheet structure. Although NMR spectroscopy of trifluoroethanol-stabilized monomeric Abeta(1-42) delineated two separated helical domains, only the destabilization of helix I, comprising residues 11-24, caused a transition to a beta-sheet structure. This conformational alpha-to-beta switch was directly accompanied by an aggregation process leading to the formation of amyloid fibrils.