Aggregation and Metal-Binding Properties of Mutant Forms of the Amyloid Aβ Peptide of Alzheimer's Disease

Abstract: The fibrillogenic properties of Alzheimer's Aβ peptides corresponding to residues 1–40 of the normal human sequence and to two mutant forms containing the replacement Ala²¹ to Gly or Glu²² to Gln were compared. At pH 7.4 and 37°C the Gln²² peptide was found to aggregate and precipitate from solution faster than the normal Aβ, whereas the Gly²¹ peptide aggregated much more slowly. Electron microscopy showed that the aggregates all had fibrillar structures. Circular dichroism spectra of these peptides revealed that aggregation of the normal and Gln²² sequences was associated with spectral changes consistent with a transformation from random coil to β sheet, whereas the spectrum of the Gly²¹ peptide remained almost unchanged during a period in which little or no aggregation occurred. When immobilised by spotting onto nitrocellulose membranes the peptides bound similar amounts of the radioisotope ⁶⁵Zn²⁺. Of several competing metal ions, tested at 20× the concentration of Zn²⁺, Cu²⁺ displaced >95% of the radioactivity from all three peptides and Ni²⁺ produced >50% displacement in each case. Some other metal ions tested caused lesser displacement, but Fe²⁺ and Al³⁺ were without effect. In a saturation binding assay, a value of 3.2 µM was obtained for the binding of Zn²⁺ to Aβ but our data provided no evidence for a reported higher affinity site (107 nM). The results suggest that the neuropathology associated with the Gly²¹ mutation is not due to enhanced fibrillogenic or different metal-binding properties of the peptide and that the binding of zinc to amyloid peptides is not a specific phenomenon.     

Hacking the Code of Amyloid Formation

Many research efforts in the last years have been directed towards understanding the factors determining protein misfolding and amyloid formation. Protein stability and amino acid composition have been identified as the two major factors in vitro. The research of our group has been focused on understanding the relationship between amino acid sequence and amyloid formation. Our approach has been the design of simple model systems that reproduce the biophysical properties of natural amyloids. An amyloid sequence pattern was extracted that can be used to detect amyloidogenic hexapeptide stretches in proteins. We have added evidence supporting that these amyloidogenic stretches can trigger amyloid formation by non-amyloidogenic proteins. Some experimental results in other amyloid proteins will be analyzed under the conclusions obtained in these studies. Our studies together with evidences from other groups suggest that amyloid formation is the result of the interplay between a decrease of protein stability, and the presence of highly amyloidogenic regions in proteins. As many of these results have been obtained in vitro, the challenge for the next years will be to demonstrate their validity in in vivo systems.     

Hacking the Code of Amyloid Formation: The Amyloid Stretch Hypothesis

Many research efforts in the last years have been directed towards understanding the factors determining protein misfolding and amyloid formation. Protein stability and amino acid composition have been identified as the two major factors in vitro. The research of our group has been focused on understanding the relationship between amino acid sequence and amyloid formation. Our approach has been the design of simple model systems that reproduce the biophysical properties of natural amyloids. An amyloid sequence pattern was extracted that can be used to detect amyloidogenic hexapeptide stretches in proteins. We have added evidence supporting that these amyloidogenic stretches can trigger amyloid formation by nonamyloidogenic proteins. Some experimental results in other amyloid proteins will be analyzed under the conclusions obtained in these studies. Our conclusions together with evidences from other groups suggest that amyloid formation is the result of the interplay between a decrease of protein stability, and the presence of highly amyloidogenic regions in proteins. As many of these results have been obtained in vitro, the challenge for the next years will be to demonstrate their validity in in vivo systems.     

Identification of Heparin-Binding Domains in the Amyloid Precursor Protein of Alzheimer's Disease by Deletion Mutagenesis and Peptide Mapping

Abstract: Recent studies have shown that the binding of the amyloid protein precursor (APP) of Alzheimer's disease to heparan sulfate proteoglycans (HSPGs) can modulate a neurite outgrowth-promoting function associated with APP. We used three different approaches to identify heparin-binding domains in APP. First, as heparin-binding domains are likely to be within highly folded regions of proteins, we analyzed the secondary structure of APP using several predictive algorithms. This analysis showed that two regions of APP₆₉₅ contain a high degree of secondary structure, and clusters of basic residues, considered mandatory for heparin binding, were found principally within these regions. To determine which domains of APP bind heparin, deletion mutants of APP₆₉₅ were prepared and analyzed for binding to a heparin affinity column. The results suggested that there must be at least two distinct heparin-binding regions in APP. To identify novel heparin-binding regions, peptides homologous to candidate heparin-binding domains were analyzed for their ability to bind heparin. These experiments suggested that APP contains at least four heparin-binding domains. The presence of more than one heparin-binding domain on APP suggests the possibility that APP may interact with more than one type of glycosaminoglycan.     

Oligodendrocytes are a Novel Source of Amyloid Peptide Generation

Alzheimer’s disease is characterised by regional neuronal degeneration, synaptic loss, and the progressive deposition of the 4 kDa β-amyloid peptide (Aβ) in senile plaques and accumulation of tau protein as neurofibrillary tangles. Aβ derives from the larger precursor molecule, amyloid precursor protein (APP) by proteolytic processing via β- and γ-secretases. While APP expression is well documented in neurons and astrocytes, the case for oligodendrocytes is less clear. The latter cell type is reported to express different isoforms of APP, and we have confirmed this observation by immunocytochemistry in cultures of differentiated rat cortical oligodendrocytes. Moreover, by means of a sensitive electrochemiluminescent immunoassay employing Aβ C-terminal specific antibodies, mature oligodendrocytes are shown to secrete the 40 and 42 amino acid Aβ species (Aβ40 and Aβ42). Secretion of Aβ peptides was reduced by incubating oligodendrocytes with α- and β-secretase inhibitors, or a γ-secretase inhibitor. Disturbances of APP processing and/or synthesis in oligodendrocytes may account for some myelin disorders observed in Alzheimer’s disease and other senile dementias.     

Cerebrovascular Accumulation and Increased Blood-Brain Barrier Permeability to Circulating Alzheimer's Amyloid β Peptide in Aged Squirrel Monkey with Cerebral Amyloid Angiopathy

Abstract: Senescent squirrel monkey is a valuable model to study pathogenesis of cerebrovascular amyloid angiopathy (CAA). Cerebrovascular sequestration and blood-brain barrier (BBB) permeability to ¹²⁵I-amyloid β(1-40) synthetic peptide (sAβ_1-40) were studied in adult versus aged squirrel monkey 1 h after a single intravenous injection. In aged monkey, the half-time of elimination of sAβ_1-40, t ^e_1/2, was prolonged by 0.6 h, the systemic clearance, Cl _SS, was reduced from 1.8 to 1.1 ml/min/kg, and the mean residence time of intact peptide in the circulation was increased by 1 h (45%). In adult monkey, cerebrovascular sequestration of intact sAβ_1-40 was significant, and the BBB permeability was 18.6-fold higher than for inulin. In aged monkey, the sequestration of intact sAβ_1-40 by cortical and leptomeningeal microvessels and the BBB permeability were increased by 5.9, 1.8-, and 2.1-fold, respectively, in the presence of an unchanged barrier to inulin. In brain parenchyma of aged animals, 76.1% of circulating sAβ_1-40 remained intact versus 45.7% in adult. We conclude that multiple age-related systemic effects, i.e., reduced body elimination and systemic clearance of sAβ_1-40, and reduced peripheral metabolism, may act in concert with BBB mechanisms, i.e., increased transendothelial transport and microvascular accumulation of blood-borne sAβ_1-40, and reduced brain metabolism to enhance the development of CAA.     

Neurotoxicity of a Carboxyl-Terminal Fragment of the Alzheimer's Amyloid Precursor Protein

Abstract: We have previously shown that a recombinant carboxyl-terminal 105-amino-acid fragment (CT105) of the amyloid precursor protein (APP) induced strong non-selective inward currents in Xenopus oocytes. Here we investigated the toxic effect of CT105 peptide on the cultured mammalian cells. The CT105 peptide induced a significant lactate dehydrogenase (LDH) release from cultured rat cortical neurons and PC12 cells in a concentration (from 10 µ M )- and time (from 48 h)-dependent manner. The toxic effect of CT105 was more potent than that of any fragments of amyloid β protein (Aβ). However, CT105 peptide did not affect the viability of U251 human glioblastoma cells. In contrast to CT105, Aβ increased LDH release only slightly even at 50 µ M but significantly inhibited 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide reduction at submicromolar concentrations. Among the various neuroprotective drugs tested, only cholesterol, which alters membrane fluidity, could attenuate the cytotoxicity of CT105 significantly. The CT105 peptide formed multiple self-aggregates on solubilization. Pretreatment with a sublethal concentration of CT105 did not significantly alter the susceptibility of cells to hydrogen peroxide and glutamate. Endogenous CT peptides were found not only in the cell lysates but also in the conditioned medium of PC12 cells. These results imply that CT peptide can directly attack the cell membrane probably by making pores or nonselective ion channels, whereas Aβ impairs the intracellular metabolic pathway first. Thus, it is thought that both CT and Aβ, which are formed during the processing of APP, may participate in the neuronal degeneration in Alzheimer's disease by different mechanisms.     

Genome-Wide Association Study of CSF Levels of 59 Alzheimer's Disease Candidate Proteins: Significant Associations with Proteins Involved in Amyloid Processing and Inflammation

Cerebrospinal fluid (CSF) 42 amino acid species of amyloid beta (Aβ42) and tau levels are strongly correlated with the presence of Alzheimer''s disease (AD) neuropathology including amyloid plaques and neurodegeneration and have been successfully used as endophenotypes for genetic studies of AD. Additional CSF analytes may also serve as useful endophenotypes that capture other aspects of AD pathophysiology. Here we have conducted a genome-wide association study of CSF levels of 59 AD-related analytes. All analytes were measured using the Rules Based Medicine Human DiscoveryMAP Panel, which includes analytes relevant to several disease-related processes. Data from two independently collected and measured datasets, the Knight Alzheimer''s Disease Research Center (ADRC) and Alzheimer''s Disease Neuroimaging Initiative (ADNI), were analyzed separately, and combined results were obtained using meta-analysis. We identified genetic associations with CSF levels of 5 proteins (Angiotensin-converting enzyme (ACE), Chemokine (C-C motif) ligand 2 (CCL2), Chemokine (C-C motif) ligand 4 (CCL4), Interleukin 6 receptor (IL6R) and Matrix metalloproteinase-3 (MMP3)) with study-wide significant p-values (p<1.46×10⁻¹⁰) and significant, consistent evidence for association in both the Knight ADRC and the ADNI samples. These proteins are involved in amyloid processing and pro-inflammatory signaling. SNPs associated with ACE, IL6R and MMP3 protein levels are located within the coding regions of the corresponding structural gene. The SNPs associated with CSF levels of CCL4 and CCL2 are located in known chemokine binding proteins. The genetic associations reported here are novel and suggest mechanisms for genetic control of CSF and plasma levels of these disease-related proteins. Significant SNPs in ACE and MMP3 also showed association with AD risk. Our findings suggest that these proteins/pathways may be valuable therapeutic targets for AD. Robust associations in cognitively normal individuals suggest that these SNPs also influence regulation of these proteins more generally and may therefore be relevant to other diseases.     

The Role of Prefibrillar Structures in the Assembly of a Peptide Amyloid

The self-assembly of proteins into stable, fibrillar aggregates is a general property of polypeptides most notably associated with degenerative diseases termed amyloidoses. These nano- to micrometer scale structures are formed predominantly of β-sheets that self-assemble by a nucleation-dependent mechanism. The rate-limiting step of assembly involves stabilization of high-energy intermediates in a kinetic step termed nucleation. Determination of the structural characteristics of these high-energy intermediates has been elusive, as its members are the least populated states on the assembly pathway. Using a peptide derived from diabetes-related amyloid, we use electron paramagnetic resonance (EPR) spectroscopy and disulfide crosslinking to show that fibers are composed of parallel, in-register β-sheets. Kinetic studies are then used to infer the structural elements of the pre-nucleation intermediates. Notably, stabilization of this ensemble is shown to depend on the number but not the position of amide side chains within the primary sequence. Additionally, fiber formation is accelerated by constructs that mimic the intra-sheet structure of the fiber. Our data suggest that pre-nucleation intermediates sample intra- β-sheet structure and place bounds on the possible nucleation mechanisms for fiber assembly. Understanding the nucleation of fibrillogenesis is critical so that this process can be prevented in disease and productively controlled by design.     

Prediction of Peptide and Protein Propensity for Amyloid Formation

Understanding which peptides and proteins have the potential to undergo amyloid formation and what driving forces are responsible for amyloid-like fiber formation and stabilization remains limited. This is mainly because proteins that can undergo structural changes, which lead to amyloid formation, are quite diverse and share no obvious sequence or structural homology, despite the structural similarity found in the fibrils. To address these issues, a novel approach based on recursive feature selection and feed-forward neural networks was undertaken to identify key features highly correlated with the self-assembly problem. This approach allowed the identification of seven physicochemical and biochemical properties of the amino acids highly associated with the self-assembly of peptides and proteins into amyloid-like fibrils (normalized frequency of β-sheet, normalized frequency of β-sheet from LG, weights for β-sheet at the window position of 1, isoelectric point, atom-based hydrophobic moment, helix termination parameter at position j+1 and ΔG° values for peptides extrapolated in 0 M urea). Moreover, these features enabled the development of a new predictor (available at http://cran.r-project.org/web/packages/appnn/index.html) capable of accurately and reliably predicting the amyloidogenic propensity from the polypeptide sequence alone with a prediction accuracy of 84.9 % against an external validation dataset of sequences with experimental in vitro, evidence of amyloid formation.     

Deciphering the molecular basis of memory failure in Alzheimer's disease

Acutely developing lesions of the brain have been highly instructive in elucidating the neural systems underlying memory in humans and animal models. Much less has been learned from chronic neurodegenerative disorders that insidiously impair memory. But the advent of a detailed molecular hypothesis for the development of Alzheimer's disease and the creation of compelling mouse models thereof have begun to change this situation. Experiments in rodents suggest that soluble oligomers of the amyloid beta protein (Abeta) may discretely interfere with synaptic mechanisms mediating aspects of learning and memory, including long-term potentiation. In humans, memory impairment correlates strongly with cortical levels of soluble Abeta species, which include oligomers. Local inflammatory changes, neurofibrillary degeneration, and neurotransmitter deficits all contribute to memory impairment, but available evidence suggests that these develop as a consequence of early Abeta accumulation. Accordingly, attempts to slow memory and cognitive loss by decreasing cerebral Abeta levels have entered human trials.     

Weak Glycolipid Binding of a Microdomain-Tracer Peptide Correlates with Aggregation and Slow Diffusion on Cell Membranes

Organized assembly or aggregation of sphingolipid-binding ligands, such as certain toxins and pathogens, has been suggested to increase binding affinity of the ligand to the cell membrane and cause membrane reorganization or distortion. Here we show that the diffusion behavior of the fluorescently tagged sphingolipid-interacting peptide probe SBD (Sphingolipid Binding Domain) is altered by modifications in the construction of the peptide sequence that both result in a reduction in binding to ganglioside-containing supported lipid membranes, and at the same time increase aggregation on the cell plasma membrane, but that do not change relative amounts of secondary structural features. We tested the effects of modifying the overall charge and construction of the SBD probe on its binding and diffusion behavior, by Surface Plasmon Resonance (SPR; Biacore) analysis on lipid surfaces, and by Fluorescence Correlation Spectroscopy (FCS) on live cells, respectively. SBD binds preferentially to membranes containing the highly sialylated gangliosides GT1b and GD1a. However, simple charge interactions of the peptide with the negative ganglioside do not appear to be a critical determinant of binding. Rather, an aggregation-suppressing amino acid composition and linker between the fluorophore and the peptide are required for optimum binding of the SBD to ganglioside-containing supported lipid bilayer surfaces, as well as for interaction with the membrane. Interestingly, the strength of interactions with ganglioside-containing artificial membranes is mirrored in the diffusion behavior by FCS on cell membranes, with stronger binders displaying similar characteristic diffusion profiles. Our findings indicate that for aggregation-prone peptides, aggregation occurs upon contact with the cell membrane, and rather than giving a stronger interaction with the membrane, aggregation is accompanied by weaker binding and complex diffusion profiles indicative of heterogeneous diffusion behavior in the probe population.     

Design of a Coiled-Coil-based Model Peptide System to Explore the Fundamentals of Amyloid Fibril Formation

Protein deposition as amyloid fibrils underlies more than twenty severely debilitating human disorders. Interestingly, recent studies suggest that all peptides and proteins possess an intrinsic ability to assemble into amyloid fibrils similar to those observed in disease states. The common properties and characteristics of amyloid aggregates thus offer the prospect that simple model systems can be used to systematically assess the factors that predispose a native protein to form amyloid fibrils and understand the origin and progression of fatal disorders associated with amyloid formation. Here, we report the de novo design of a 17-residue peptide model system, referred to as cc, which forms a protein-like coiled-coil structure under ambient solution conditions but can be easily converted into amyloid fibrils by raising the temperature. Oxidation of methionine residues at selected hydrophobic positions completely abolished amyloid fibril formation of the peptide while not interfering with its coiled-coil structure. This finding indicates that a small number of site-specific hydrophobic interactions can play a major role in the packing of polypeptide chain segments within amyloid fibrils. The simplicity and characteristics of the cc system make it highly suitable for probing molecular details of the assembly of amyloid structures. Abbreviations used for amino acids follow the recommendations of the IUPAC-IUB Commission of Biochemical Nomenclature [Eur. J. Biochem., 138 (1984) 9].     

Early-Onset and Robust Amyloid Pathology in a New Homozygous Mouse Model of Alzheimer's Disease

Background

Transgenic mice expressing mutated amyloid precursor protein (APP) and presenilin (PS)-1 or -2 have been successfully used to model cerebral β-amyloidosis, one of the characteristic hallmarks of Alzheimer''s disease (AD) pathology. However, the use of many transgenic lines is limited by premature death, low breeding efficiencies and late onset and high inter-animal variability of the pathology, creating a need for improved animal models. Here we describe the detailed characterization of a new homozygous double-transgenic mouse line that addresses most of these issues.

Methodology/Principal Findings

The transgenic mouse line (ARTE10) was generated by co-integration of two transgenes carrying the K670N/M671L mutated amyloid precursor protein (APP_swe) and the M146V mutated presenilin 1 (PS1) both under control of a neuron-specific promoter. Mice, hemi- as well as homozygous for both transgenes, are viable and fertile with good breeding capabilities and a low rate of premature death. They develop robust AD-like cerebral β-amyloid plaque pathology with glial inflammation, signs of neuritic dystrophy and cerebral amyloid angiopathy. Using our novel image analysis algorithm for semi-automatic quantification of plaque burden, we demonstrate an early onset and progressive plaque deposition starting at 3 months of age in homozygous mice with low inter-animal variability and 100%-penetrance of the phenotype. The plaques are readily detected in vivo by PiB, the standard human PET tracer for AD. In addition, ARTE10 mice display early loss of synaptic markers and age-related cognitive deficits. By applying a γ-secretase inhibitor we show a dose dependent reduction of soluble amyloid β levels in the brain.

Conclusions

ARTE10 mice develop a cerebral β-amyloidosis closely resembling the β-amyloid-related aspects of human AD neuropathology. Unifying several advantages of previous transgenic models, this line particularly qualifies for the use in target validation and for evaluating potential diagnostic or therapeutic agents targeting the amyloid pathology of AD.     

NMR Identification of the Formic Acid-Modified Residue in Alzheimer's Amyloid Protein

Abstract: The β/A4-amyloid protein (β/A4) and many synthetic fragments of this protein have proved to be very difficult to solubilize, leading to the use of relatively harsh chemical methods, most notably, formic acid. This treatment has previously been shown to cause a covalent modification of this peptide. In this study, one- and two-dimensional NMR techniques are used to show that the nature of this covalent modification is formation of a formate ester to a serine residue. This finding is consistent with our previously reported kinetic studies of formic acid-induced modification of β / A4 and further illustrates the potential danger of solubilizing fragments of β/A4 in formic acid. Alternative methods of solubilization are discussed.     

Stereochemical Criteria for Polypeptide and Protein Chain Conformations: II. Allowed Conformations for a Pair of Peptide Units

The conformation of a polypeptide or protein chain may be specified by stating the orientations of the two linked peptide residues at each alpha carbon atom in the chain, namely the two dihedral angles ϕ, ϕ′ about the single bonds N—αC and αC—C′ from a defined standard conformation. By using certain criteria of minimum contact distances between the various atoms, the allowed anges of (ϕ, ϕ′) have been worked out for three values of the angle N-αC-C′ (τ), namely 105, 110, and 115° for non-glycyl, and 110 and 115° for glycyl residues. The theory is compared with all the available crystallographic data (up to early 1965) on simple (di- and tri-) peptides, cyclic peptides, polypeptide and protein structures, and the observed data fully support the conclusions from theory. The effect of the gamma carbon atom, in its three possible positions, is also discussed, and is found to alter the outer limits of the allowed region of (ϕ, ϕ′) only slightly. The paper contains exhaustive references to the published data on these structures, using x-ray diffraction.     

One-Step Purification of Recombinant Proteins Using a Nanomolar-Affinity Streptavidin-Binding Peptide, the SBP-Tag

We describe the use of the SBP-tag, a new streptavidin-binding peptide, for both the one-step purification and the detection of recombinant proteins. The SBP-tag sequence is 38 amino acids long and binds to streptavidin with an equilibrium dissociation constant of 2.5 nM. We demonstrate that a single-step purification of SBP-tagged proteins from bacterial extract yields samples that are more pure than those purified using maltose-binding protein or the His-tag. The capacity of the immobilized streptavidin used to purify SBP-tagged proteins is about 0.5 mg per milliliter of matrix, which is high enough to isolate large quantities of proteins for further study. Also, the elution conditions from the streptavidin column are very mild and specific, consisting of the wash buffer plus biotin. This combination of high-affinity, high-yield, mild elution conditions, and simplicity of use makes the SBP-tag suitable for high-throughput protein expression/purification procedures, including robotically manipulated protocols with microtiter plates. Additionally, the SBP-tag can be used for detection since a wide variety of streptavidin-conjugated fluorescent and enzymatic systems are commercially available. We also present a new, rapid, method for the measurement of protein-protein, protein-peptide, or protein-small molecule equilibrium dissociation constants that require as little as 1 fmol of labeled protein. We call this method the spin-filter binding inhibition assay.     

Structural Determinants of the Alzheimer's Amyloid β-Peptide

Abstract: The hallmark event of Alzheimer's disease (AD) is the deposition of amyloid as insoluble fiber masses in extracellular neuritic plaques and around the walls of cerebral blood vessels. The main component of amyloid is a hydrophobic peptide, named amyloid β-peptide (βA4), which results from the processing of a much longer membrane amyloid precursor protein (APP). This review focuses on the structural features of βA4 and the factors that determine βA4 insolubilization. Theoretical and experimental studies of the primary structure of βA4 have shown that it is composed of a completely hydrophobic C-terminal domain, which adopts β-strand structure, and an N-terminal region, whose sequence permits different secondary structures. In fact, this region can exist as an α-helical or β-strand conformation depending on the environmental condition (pH and hydrophobicity surrounding the molecule). The effects of pH and hydrophobicity on βA4 structure may elucidate the mechanisms determining its aggregation and amyloid deposition in AD.