Isabel Morgado

Molecular basis of β-amyloid oligomer recognition with a conformational antibody fragment

Oligomers are intermediates of the β-amyloid (Aβ) peptide fibrillogenic pathway and are putative pathogenic culprits in Alzheimer’s disease (AD). Here we report the biotechnological generation and biochemical characterization of an oligomer-specific antibody fragment, KW1. KW1 not only discriminates between oligomers and other Aβ conformations, such as fibrils or disaggregated peptide; it also differentiates between different types of Aβ oligomers, such as those formed by Aβ (1–40) and Aβ (1–42) peptide. This high selectivity of binding contrasts sharply with many other conformational antibodies that interact with a large number of structurally analogous but sequentially different antigens. X-ray crystallography, NMR spectroscopy, and peptide array measurements imply that KW1 recognizes oligomers through a hydrophobic and significantly aromatic surface motif that includes Aβ residues 18–20. KW1-positive oligomers occur in human AD brain samples and induce synaptic dysfunctions in living brain tissues. Bivalent KW1 potently neutralizes this effect and interferes with Aβ assembly. By altering a specific step of the fibrillogenic cascade, it prevents the formation of mature Aβ fibrils and induces the accumulation of nonfibrillar aggregates. Our data illuminate significant mechanistic differences in oligomeric and fibril recognition and suggest the considerable potential of KW1 in future studies to detect or inhibit specific types of Aβ conformers.

Dynamics of Amyloid β Fibrils Revealed by Solid-State NMR

Background: Alzheimer disease is the most important neurodegenerative disorder; treatment approaches require atomistic knowledge of fibrillar structure and dynamics. Results: We have site-specifically studied the molecular dynamics of amyloid β (Aβ) fibrils by solid-state NMR. Conclusion: The β-sheet motifs of Aβ are essentially rigid, and the termini exhibit more flexibility. Significance: Dynamics studies of Aβ fibrils suggest a structural role of the N terminus of the peptide. We have investigated the site-specific backbone dynamics of mature amyloid β (Aβ) fibrils using solid-state NMR spectroscopy. Overall, the known β-sheet segments and the turn linking these two β-strands exhibit high order parameters between 0.8 and 0.95, suggesting low conformational flexibility. The first approximately eight N-terminal and the last C-terminal residues exhibit lower order parameters between ∼0.4 and 0.8. Interestingly, the order parameters increase again for the first two residues, Asp1 and Ala2, suggesting that the N terminus could carry some structural importance.

Solid-state NMR reveals a close structural relationship between amyloid-β protofibrils and oligomers.

Background: Little tertiary structure information is available for the toxic intermediates in the amyloid-β (Aβ) fibrillation process. Results: Aβ protofibrils show tertiary contacts between Glu-22 and Ile-31, which are not present in mature fibrils. Conclusion: Aβ protofibrils share tertiary structure features with oligomers but not with mature fibrils. Significance: Aβ protofibrils must undergo a major structural reorientation in the development of mature Aβ fibrils. We have studied tertiary contacts in protofibrils and mature fibrils of amyloid-β (Aβ) peptides using solid-state NMR spectroscopy. Although intraresidue contacts between Glu-22 and Ile-31 were found in Aβ protofibrils, these contacts were completely absent in mature Aβ fibrils. This is consistent with the current models of mature Aβ fibrils. As these intramolecular contacts have also been reported in Aβ oligomers, our measurements suggest that Aβ protofibrils are structurally more closely related to oligomers than to mature fibrils. This suggests that some structural alterations have to take place on the pathway from Aβ oligomers/protofibrils to mature fibrils, in agreement with a model that suggests a conversion of intramolecular hydrogen-bonded structures of Aβ oligomers to the intermolecular stabilized mature fibrils (Hoyer, W., Grönwall, C., Jonsson, A., Ståhl, S., and Härd, T. (2008) Proc. Natl. Acad. Sci. U.S.A. 105, 5099–5104).

Pattern Recognition with a Fibril-Specific Antibody Fragment Reveals the Surface Variability of Natural Amyloid Fibrils

Amyloid immunotherapy has led to the rise of antibodies, which target amyloid fibrils or structural precursors of fibrils, based on their specific conformational properties. Recently, we reported the biotechnological generation of the B10 antibody fragment, which provides conformation-specific binding to amyloid fibrils. B10 strongly interacts with fibrils from Alzheimers β amyloid (Aβ) peptide, while disaggregated Aβ peptide or Aβ oligomers are not explicitly recognized. B10 also enables poly-amyloid-specific binding and recognizes amyloid fibrils derived from different types of amyloidosis or different polypeptide chains. Based on our current data, however, we find that B10 does not recognize all tested amyloid fibrils and amyloid tissue deposits. It also does not specifically interact with intrinsically unfolded polypeptide chains or globular proteins even if the latter encompass high β-sheet content or β-solenoid domains. By contrast, B10 binds amyloid fibrils from d-amino acid or l-amino acid peptides and non-proteinaceous biopolymers with highly regular and anionic surface properties, such as heparin and DNA. These data establish that B10 binding does not depend on an amyloid-specific or protein-specific backbone structure. Instead, it involves the recognition of a highly regular and anionic surface pattern. This specificity mechanism is conserved in nature and occurs also within a group of natural amyloid receptors from the innate immune system, the pattern recognition receptors. Our data illuminate the structural diversity of naturally occurring amyloid scaffolds and enable the discrimination of distinct fibril populations in vitro and within diseased tissues.

Amyloid Fibril Recognition with the Conformational B10 Antibody Fragment Depends on Electrostatic Interactions.

Amyloid fibrils are naturally occurring polypeptide scaffolds with considerable importance for human health and disease. These supermolecular assemblies are β-sheet rich and characterized by a high structural order. Clinical diagnosis and emerging therapeutic strategies of amyloid-dependent diseases, such as Alzheimers, rely on the specific recognition of amyloid structures by other molecules. Recently, we generated the B10 antibody fragment, which selectively binds to Alzheimers Aβ(1-40) amyloid fibrils but does not explicitly recognize other protein conformers, such as oligomers and disaggregated Aβ peptide. B10 presents poly-amyloid specific binding and interacts with fibrillar structures consisting of different polypeptide chains. To determine the molecular basis behind its specificity, we have analyzed the molecular properties of B10 with a battery of biochemical and biophysical techniques, ranging from X-ray crystallography to chemical modification studies. We find that fibril recognition depends on positively charged residues within the B10 antigen binding site. Mutation of these basic residues into alanine potently impairs fibril binding, and reduced B10-fibril interactions are also observed when the fibril carboxyl groups are covalently masked by a chemical modification approach. These data imply that the B10 conformational specificity for amyloid fibrils depends upon specific electrostatic interactions with an acidic moiety, which is common to different amyloid fibrils.

Lipids in Amyloid-β Processing, Aggregation, and Toxicity

Aggregation of amyloid-beta (Aβ) peptide is the major event underlying neuronal damage in Alzheimers disease (AD). Specific lipids and their homeostasis play important roles in this and other neurodegenerative disorders. The complex interplay between the lipids and the generation, clearance or deposition of Aβ has been intensively investigated and is reviewed in this chapter. Membrane lipids can have an important influence on the biogenesis of Aβ from its precursor protein. In particular, increased cholesterol in the plasma membrane augments Aβ generation and shows a strong positive correlation with AD progression. Furthermore, apolipoprotein E, which transports cholesterol in the cerebrospinal fluid and is known to interact with Aβ or compete with it for the lipoprotein receptor binding, significantly influences Aβ clearance in an isoform-specific manner and is the major genetic risk factor for AD. Aβ is an amphiphilic peptide that interacts with various lipids, proteins and their assemblies, which can lead to variation in Aβ aggregation in vitro and in vivo. Upon interaction with the lipid raft components, such as cholesterol, gangliosides and phospholipids, Aβ can aggregate on the cell membrane and thereby disrupt it, perhaps by forming channel-like pores. This leads to perturbed cellular calcium homeostasis, suggesting that Aβ-lipid interactions at the cell membrane probably trigger the neurotoxic cascade in AD. Here, we overview the roles of specific lipids, lipid assemblies and apolipoprotein E in Aβ processing, clearance and aggregation, and discuss the contribution of these factors to the neurotoxicity in AD.

Structure and biomedical applications of amyloid oligomer nanoparticles.

Amyloid oligomers are nonfibrillar polypeptide aggregates linked to diseases, such as Alzheimers and Parkinsons. Here we show that these aggregates possess a compact, quasi-crystalline architecture that presents significant nanoscale regularity. The amyloid oligomers are dynamic assemblies and are able to release their individual subunits. The small oligomeric size and spheroid shape confer diffusible characteristics, electrophoretic mobility, and the ability to enter hydrated gel matrices or cells. We finally showed that the amyloid oligomers can be labeled with both fluorescence agents and iron oxide nanoparticles and can target macrophage cells. Oligomer amyloids may provide a new biological nanomaterial for improved targeting, drug release, and medical imaging.

Molecular architecture of Aβ fibrils grown in cerebrospinal fluid solution and in a cell culture model of Aβ plaque formation

Abstract Objectives: The detailed structure of brain-derived Aβ amyloid fibrils is unknown. To approach this issue, we investigate the molecular architecture of Aβ(1–40) fibrils grown in either human cerebrospinal fluid solution, in chemically simple phosphate buffer in vitro or extracted from a cell culture model of Aβ amyloid plaque formation. Methods: We have used hydrogen–deuterium exchange (HX) combined with nuclear magnetic resonance, transmission electron microscopy, seeding experiments both in vitro and in cell culture as well as several other spectroscopic measurements to compare the morphology and residue-specific conformation of these different Aβ fibrils. Results and conclusions: Our data reveal that, despite considerable variations in morphology, the spectroscopic properties and the pattern of slowly exchanging backbone amides are closely similar in the fibrils investigated. This finding implies that a fundamentally conserved molecular architecture of Aβ peptide fold is common to Aβ fibrils.

Molecular basis for a novel systemic form of human hereditary apoA-I amyloidosis with vision loss

Hereditary apolipoprotein A-I (apoA-I) amyloidosis (AApoAI) is a life-threatening incurable genetic disorder whose molecular underpinnings and the full spectrum of afflicted organs are unclear. We report a new form of AApoAI with amyloid deposition in multiple organs, including an unprecedented retinal amyloidosis. Genetic and proteomic analyses identified Glu34Lys apoA-I as the fibrillar protein causing the clinical manifestations. A life-saving combined hepatorenal transplantation was performed for one Glu34Lys carrier. To elucidate structural underpinnings for amyloidogenic properties of Glu34Lys, we generated its recombinant globular domain and compared the conformation and dynamics of its lipid-free form with those of two other naturally occurring apoA-I variants, Phe71Tyr (amyloidogenic) and Leu159Arg (non-amyloidogenic). All variants showed reduced stability and altered aromatic residue packing. Molecular dynamics simulations revealed local helical unfolding and suggested that transient opening of Trp72 induced mutation-dependent structural perturbations in a sensitive region, including the major amyloid hotspot residues 14-22. We posit that a shift from the “closed” to an “open” orientation of Trp72 modulates structural protection of amyloid hotspots, suggesting a previously unknown early step in protein misfolding.