Alzheimer proteopathic tau seeds are biochemically a forme fruste of mature paired helical filaments.

Aggregation prone molecules, such as tau, form both historically well characterized fibrillar deposits (neurofibrillary tangles) and recently identified phosphate-buffered saline (PBS) extract species called proteopathic seeds. Both can cause normal endogenous tau to undergo templated misfolding. The relationship of these seeds to the fibrils that define tau-related diseases is unknown. We characterized the aqueous extractable and sarkosyl insoluble fibrillar tau species derived from human Alzheimer brain using mass spectrometry and in vitro bioassays. Post-translational modifications (PTMs) including phosphorylation, acetylation and ubiquitination are identified in both preparations. PBS extract seed competent tau can be distinguished from sarkosyl insoluble tau by the presence of overlapping, but less abundant, PTMs and an absence of some PTMs unique to the latter. The presence of ubiquitin and other PTMs on the PBS-extracted tau species correlates with the amount of tau in the seed competent size exclusion fractions, with the bioactivity and with the aggressiveness of clinical disease. These results demonstrate that the PTMs present on bioactive, seed competent PBS extract tau species are closely related to, but distinct from, the PTMs of mature paired helical filaments, consistent with the idea that they are a forme fruste of tau species that ultimately form fibrils.

Fluorescence Resonance Energy Transfer to Detect Plasma Membrane Perturbations in Giant Plasma Membrane Vesicles.

Disruptions and perturbations of the cellular plasma membrane by peptides have garnered significant interest in the elucidation of biological phenomena. Typically, these complex processes are studied using liposomes as model membranes-either by encapsulating a fluorescent dye or by other spectroscopic approaches, such as nuclear magnetic resonance. Despite incorporating physiologically relevant lipids, no synthetic model truly recapitulates the full complexity and molecular diversity of the plasma membrane. Here, biologically representative membrane models, giant plasma membrane vesicles (GPMVs), are prepared from eukaryotic cells by inducing a budding event with a chemical stressor. The GPMVs are then isolated, and bilayers are labelled with fluorescent lipophilic tracers and incubated in a microplate with a membrane-active peptide. As the membranes become damaged and/or aggregate, the resulting fluorescence resonance energy transfer (FRET) between the two tracers increases and is measured periodically in a microplate. This approach offers a particularly useful way to detect perturbations when the membrane complexity is an important variable to consider. Additionally, it provides a way to kinetically detect damage to the plasma membrane, which can be correlated with the kinetics of peptide self-assembly or structural rearrangements. Key features • Allows testing of various peptide-membrane interaction conditions (peptide:phospholipid ratio, ionic strength, buffer, etc.) at once. • Uses intact plasma membrane vesicles that can be prepared from a variety of cell lines. • Can offer comparable throughput as with traditional synthetic lipid models (e.g., dye-encapsulated liposomes).

Specific detection of tau seeding activity in Alzheimer's disease using rationally designed biosensor cells.

BACKGROUND: The prion-like propagation of tau in neurodegenerative disorders implies that misfolded pathological tau can recruit the normal protein and template its aggregation. Here, we report the methods for the development of sensitive biosensor cell lines for the detection of tau seeding activity. RESULTS: We performed the rational design of novel tau probes based on the current structural knowledge of pathological tau aggregates in Alzheimer's disease. We generated Förster resonance energy transfer (FRET)-based biosensor stable cell lines and characterized their sensitivity, specificity, and overall ability to detect bioactive tau in human samples. As compared to the reference biosensor line, the optimized probe design resulted in an increased efficiency in the detection of tau seeding. The increased sensitivity allowed for the detection of lower amount of tau seeding competency in human brain samples, while preserving specificity for tau seeds found in Alzheimer's disease. CONCLUSIONS: This next generation of FRET-based biosensor cells is a novel tool to study tau seeding activity in Alzheimer's disease human samples, especially in samples with low levels of seeding activity, which may help studying early tau-related pathological events.

Development of a novel fluorescence assay for studying lipid bilayer perturbation induced by amyloidogenic peptides using cell plasma membrane vesicles.

Numerous pathophysiological conditions are associated with the misfolding and aggregation of proteins into insoluble amyloid fibrils. The mechanisms by which this process leads to cellular dysfunction remain elusive, though several hypotheses point toward the perturbation of the cell plasma membrane by pre-fibrillar intermediates and/or amyloid growth. However, current models to study membrane perturbations are largely limited to synthetic lipid vesicles and most of experimental approaches cannot be transposed to complex cell-derived plasma membrane systems. Herein, vesicles originating from the plasma membrane of erythrocytes and ß-pancreatic cells were used to study the perturbations induced by an amyloidogenic peptide, the islet amyloid polypeptide (IAPP). These biologically relevant lipid vesicles displayed a characteristic clustering in the presence of the amyloidogenic peptide, which was able to rupture membranes. By exploiting Förster resonance energy transfer (FRET), a rapid, simple, and potentially high-throughput assay to detect membrane perturbations of intact mammalian cell plasma membrane vesicles was implemented. The FRET kinetics of membrane perturbations closely correlated with the kinetics of thioflavin-T fluorescence associated with amyloid formation. This novel kinetics assay expands the toolbox available to study amyloid-associated membrane damage, bridging the gap between synthetic lipid vesicles and living cells.

Site-Specific Alkylation of the Islet Amyloid Polypeptide Accelerates Self-Assembly and Potentiates Perturbation of Lipid Membranes.

The accumulation of insoluble amyloids in the pancreatic islets is a pathological hallmark of type II diabetes and correlates closely with the loss of ß-cell mass. The predominant component of these amyloid deposits is the islet amyloid polypeptide (IAPP). The factors contributing to the conversion of IAPP from a monomeric bioactive peptide hormone into insoluble amyloid fibrils remain partially elusive. In this study, we investigated the effect of the oxidative non-enzymatic post-translational modification induced by the reactive metabolite 4-hydroxynonenal (HNE) on IAPP aggregation and cytotoxicity. Incubation of IAPP with exogenous HNE accelerated its self-assembly into ß-sheet fibrils and led to the formation of a Michael adduct on the His-18 side chain. To model this covalent modification, the imidazole N(π) position of histidine was alkylated using a close analogue of HNE, the octyl chain. IAPP lipidated at His-18 showed a hastened random coil-to-ß-sheet conformational conversion into fibrillar assemblies with a distinct morphology, a low level of binding to thioflavin T, and a high surface hydrophobicity. Introducing an octyl chain on His-18 enhanced the ability of the peptide to perturb synthetic lipid vesicles, to permeabilize the plasma membrane, and to induce the death of pancreatic ß-cells. Alkylated IAPP triggered the self-assembly of unmodified IAPP by prompting primary nucleation and increased its capacity to perturb the plasma membrane, indicating that only a small proportion of the modified peptide is necessary to shift the balance toward the formation of proteotoxic species. This study underlines the importance of studying IAPP post-translational modifications induced by oxidative metabolites in the context of pancreatic amyloids.

Cell surface glycosaminoglycans exacerbate plasma membrane perturbation induced by the islet amyloid polypeptide.

Glycosaminoglycans (GAGs) are long and unbranched anionic heteropolysaccharides that have been associated with virtually all amyloid deposits. Soluble sulfated GAGs are known for their propensity to promote the self-assembly of numerous amyloidogenic proteins and to modulate their cytotoxicity. Nonetheless, although GAGs are prevalent on the outer leaflet of eukaryotic cell plasma membrane as part of proteoglycans, their contributions in the perturbation of lipid bilayer induced by amyloid polypeptides remain unknown. Herein, we investigate the roles of GAGs in the cytotoxicity and plasma membrane perturbation induced by the islet amyloid polypeptide (IAPP), whose deposition in the pancreatic islets is associated with type II diabetes. Cellular assays using GAG-deficient cells reveal that GAGs exacerbate IAPP-induced cytotoxicity and permeabilization of the plasma membrane. Confocal microscopy and flow cytometry analyses show that IAPP sequestration at the cell surface is dependent of GAGs and of the aggregation propensity of the peptide. Using giant plasma membrane vesicles (GPMVs) prepared from GAG-deficient cells, we investigate the direct contributions of membrane-embedded proteoglycans in IAPP-induced membrane disassembly. In sharp contrast to soluble sulfated GAGs, kinetics of amyloid self-assembly expose that the presence of GAGs on GPMVs does not significantly modulate in vitro amyloid formation. Overall, this study indicates that cell surface GAGs increase the local concentration of IAPP in the vicinity of the plasma membrane, promoting lipid bilayer perturbation and cell death.

Guiding the Morphology of Amyloid Assemblies by Electrostatic Capping: from Polymorphic Twisted Fibrils to Uniform Nanorods.

Peptides that self-assemble into cross-ß-sheet amyloid structures constitute promising building blocks to construct highly ordered proteinaceous materials and nanoparticles. Nevertheless, the intrinsic polymorphism of amyloids and the difficulty of controlling self-assembly currently limit their usage. In this study, the effect of electrostatic interactions on the supramolecular organization of peptide assemblies is investigated to gain insights into the structural basis of the morphological diversities of amyloids. Different charged capping units are introduced at the N-terminus of a potent ß-sheet-forming sequence derived from the 20-29 segment of islet amyloid polypeptide, known to self-assemble into polymorphic fibrils. By tuning the charge and the electrostatic strength, different mesoscopic morphologies are obtained, including nanorods, rope-like fibrils, and twisted ribbons. Particularly, the addition of positive capping units leads to the formation of uniform rod-like assemblies, with lengths that can be modulated by the charge number. It is proposed that electrostatic repulsions between N-terminal positive charges hinder ß-sheet tape twisting, leading to a unique control over the size of these cytocompatible nanorods by protofilament growth frustration. This study reveals the high susceptibility of amyloid formation to subtle chemical modifications and opens to promising strategies to control the final architecture of proteinaceous assemblies from the peptide sequence.

Glycosaminoglycans Induce Amyloid Self-Assembly of a Peptide Hormone by Concerted Secondary and Quaternary Conformational Transitions.

Amyloids are polypeptide supramolecular assemblies that have been historically associated with numerous pathologies. Nonetheless, recent studies have identified many amyloid structures that accomplish vital physiological functions. Interestingly, amyloid fibrils, either pathological or functional, have been reported to be consistently associated with other biomolecules such as RNA and glycosaminoglycans (GAGs). These linear polyanions, RNA and GAGs, have also demonstrated an inherent ability to accelerate and/or promote amyloid formation. GAGs, including heparan sulfate, are highly charged polysaccharides that may have essential roles in the storage of peptide hormones in the form of amyloids. In this study, we evaluated the ability of sulfated GAGs to promote the self-assembly of the peptide (neuro)hormone PACAP27 and investigated the secondary and quaternary conformational transitions associated with the amyloidogenic process. PACAP27 readily self-assembled into insoluble, α-helix-rich globular particulates in the presence of sulfated GAGs, which gradually condensed and disappeared as nontoxic ß-sheet-rich amyloid fibrils were formed. By designing a PACAP27 derivative for which helical folding was hindered, we observed that the α-helix-to-ß-sheet conformational transition within the amorphous particulates constitutes the rate-limiting step of primary nucleation events. The proposed mechanism of GAG-induced self-assembly within insoluble particulates appears to be fundamentally different from usual amyloidogenic systems, which commonly implicates the formation of soluble prefibrillar proteospecies. Overall, this study provides new insights into the mechanistic details involved in the formation of functional amyloids catalyzed by polyanions, such as the assembly of nuclear amyloid bodies and the storage of peptide hormones.

Kinetic and Conformational Insights into Islet Amyloid Polypeptide Self-Assembly Using a Biarsenical Fluorogenic Probe.

Amyloid fibril formation and tissue deposition are associated with many diseases. Studies have shown that prefibrillar intermediates, such as oligomers, are the most toxic proteospecies of the amyloidogenic cascade. Thus, understanding the mechanisms of formation and the conformational ensemble of prefibrillar species is critical. Due to their transient and heterogeneous nature, detection and characterization of prefibrillar species remain challenging. The fluorogenic probe fluorescein arsenical hairpin (FlAsH), which recognizes a tetracysteine motif, has been recently used to detect the oligomerization of amyloidogenic peptides encompassing a Cys-Cys tag. In this study, we extended the FlAsH detection method to gain novel kinetic and conformational insights into the self-assembly of islet amyloid polypeptide (IAPP), a 37-residue peptide hormone whose deposition is associated with type II diabetes. By positional scanning of the Cys-Cys motif, the stability of the noncontiguous tetracysteine FlAsH-binding sites formed during self-assembly was evaluated and revealed rapid monomer self-recognition through the convergence of C-terminal domains. On the other hand, the N-terminal domains come close to each other only upon the formation of the cross-ß-sheet amyloid structure. We demonstrated that this method is well-suited to detect thioflavin T-negative fibrils and to screen inhibitors of amyloid formation. This study highlights that with positional scanning of the split-tetracysteine motif (Cys-Cys), the FlAsH detection method offers unique time-dependent conformational insights on the proteospecies assembled throughout the amyloidogenic pathway.

Thioflavin T fluorescence to analyse amyloid formation kinetics: Measurement frequency as a factor explaining irreproducibility.

The most frequent method to monitor amyloid formation relies on the fluorescence of thioflavin T (ThT). The present study reports a novel factor of irreproducibility in ThT kinetic assays performed in microplate. Discrepancies among kinetics of amyloid assembly, performed under quiescent conditions, were associated with the frequency of fluorescence measurement. Evaluating self-assembly of the islet amyloid polypeptide at short intervals hastened its fibrillization. This observation was confirmed by transmission electron microscopy, circular dichroism spectroscopy and 8-anilino-1-naphthalenesulfonic acid fluorescence. This effect, attributed to agitation during microplate displacements between fluorescence measurements, reinforces the importance of a better standardization in amyloid formation assays.

Identification of a conformational heparin-recognition motif on the peptide hormone secretin: key role for cell surface binding.

Secretin is a peptide hormone that exerts pleiotropic physiological functions by specifically binding to its cognate membrane-bound receptor. The membrane catalysis model of peptide-receptor interactions states that soluble peptidic ligands initially interact with the plasma membrane. This interaction increases the local concentration and structures the peptide, enhancing the rate of receptor binding. However, this model does not consider the dense network of glycosaminoglycans (GAGs) at the surface of eukaryotic cells. These sulfated polysaccharide chains are known to sequester numerous proteic signaling molecules. In the present study, we evaluated the interaction between the peptide hormone secretin and sulfated GAGs and its contribution to cell surface binding. Using GAG-deficient cells and competition experiments with soluble GAGs, we observed by confocal microscopy and flow cytometry that GAGs mediate the sequestration of secretin at the cell surface. Isothermal titration calorimetry and surface plasmon resonance revealed that secretin binds to heparin with dissociation constants ranging between 0.9 and 4 µM. By designing secretin derivatives with a restricted conformational ensemble, we observed that this interaction is mediated by the presence of a specific conformational GAG-recognition motif that decorates the surface of the peptide upon helical folding. The present study identifies secretin as a novel GAG-binding polypeptide and opens new research direction on the functional role of GAGs in the biology of secretin.

Modulation of amyloid assembly by glycosaminoglycans: from mechanism to biological significance.

Glycosaminoglycans (GAGs) are long and unbranched polysaccharides that are abundant in the extracellular matrix and basement membrane of multicellular organisms. These linear polyanionic macromolecules are involved in many physiological functions from cell adhesion to cellular signaling. Interestingly, amyloid fibrils extracted from patients afflicted with protein misfolding diseases are virtually always associated with GAGs. Amyloid fibrils are highly organized nanostructures that have been historically associated with pathological states, such as Alzheimer's disease and systemic amyloidoses. However, recent studies have identified functional amyloids that accomplish crucial physiological roles in almost all living organisms, from bacteria to insects and mammals. Over the last 2 decades, numerous reports have revealed that sulfated GAGs accelerate and (or) promote the self-assembly of a large diversity of proteins, both inherently amyloidogenic and non-aggregation prone. Despite the fact that many studies have investigated the molecular mechanism(s) by which GAGs induce amyloid assembly, the mechanistic elucidation of GAG-mediated amyloidogenesis still remains the subject of active research. In this review, we expose the contribution of GAGs in amyloid assembly, and we discuss the pathophysiological and functional significance of GAG-mediated fibrillization. Finally, we propose mechanistic models of the unique and potent ability of sulfated GAGs to hasten amyloid fibril formation.

Probing the role of λ6 immunoglobulin light chain dimerization in amyloid formation.

Light chain amyloidosis (AL) is a lethal disease associated with the deposition of misfolded immunoglobulin light chains (LC) as amyloid fibrils in the extracellular space of vital organs. The exact mechanisms of LC self-assembly and the molecular basis leading to cellular and organ failure still remain poorly understood. In this study, we investigated the relationship between the quaternary structure, the stability and the amyloidogenecity of LC variable domain (VL) from the λ6 germline. We observed that the amyloidogenic λ6 Wil and its non-amyloidogenic counterpart Jto dimerize in a concentration-dependent manner and that the dimer affinity is considerably decreased in the presence of a high ionic strength. Our results showed that the dimeric state delays the structural conversion associated with amyloid formation and that the monomer is critical to initiate amyloidogenesis. Thermal and chemical unfolding studies revealed that the dimeric state of VL λ6 has an equivalent stability to the monomer. This indicates that the protective effect of dimerization is not related to thermodynamic stability but, most likely, resides in specific structural features. The toxicity of monomeric Jto and Wil as well as fibrillar aggregates was evaluated on cardiomyoblasts and ThT-negative proteospecies reduced cellular viability when employed at high concentration. This study provides novel insights into the complex process of LC amyloidogenesis and suggests that dimer stabilization constitutes a promising strategy to prevent self-assembly and amyloid deposition.

Delineating the Role of Helical Intermediates in Natively Unfolded Polypeptide Amyloid Assembly and Cytotoxicity.

Amyloid deposition is a hallmark of many diseases, such as the Alzheimer's disease. Numerous amyloidogenic proteins, including the islet amyloid polypeptide (IAPP) associated with type II diabetes, are natively unfolded and need to undergo conformational rearrangements allowing the formation of locally ordered structure(s) to initiate self-assembly. Recent studies have indicated that the formation of α-helical intermediates accelerates fibrillization, suggesting that these species are on-pathway to amyloid assembly. By identifying an IAPP derivative with a restricted conformational ensemble that co-assembles with IAPP, we observed that helical species were off-pathway in homogenous environment and in presence of lipid bilayers or glycosaminoglycans. Moreover, preventing helical folding potentiated membrane perturbation and IAPP cytotoxicity, indicating that stabilization of helical motif(s) is a promising strategy to prevent cell degeneration associated with amyloidogenesis.

A nitric oxide regulated small RNA controls expression of genes involved in redox homeostasis in Bacillus subtilis.

RsaE is the only known trans-acting small regulatory RNA (sRNA) besides the ubiquitous 6S RNA that is conserved between the human pathogen Staphylococcus aureus and the soil-dwelling Firmicute Bacillus subtilis. Although a number of RsaE targets are known in S. aureus, neither the environmental signals that lead to its expression nor its physiological role are known. Here we show that expression of the B. subtilis homolog of RsaE is regulated by the presence of nitric oxide (NO) in the cellular milieu. Control of expression by NO is dependent on the ResDE two-component system in B. subtilis and we determined that the same is true in S. aureus. Transcriptome and proteome analyses revealed that many genes with functions related to oxidative stress and oxidation-reduction reactions were up-regulated in a B. subtilis strain lacking this sRNA. We have thus renamed it RoxS. The prediction of RoxS-dependent mRNA targets also suggested a significant enrichment for mRNAs related to respiration and electron transfer. Among the potential direct mRNA targets, we have validated the ppnKB mRNA, encoding an NAD+/NADH kinase, both in vivo and in vitro. RoxS controls both translation initiation and the stability of this transcript, in the latter case via two independent pathways implicating RNase Y and RNase III. Furthermore, RNase Y intervenes at an additional level by processing the 5' end of the RoxS sRNA removing about 20 nucleotides. Processing of RoxS allows it to interact more efficiently with a second target, the sucCD mRNA, encoding succinyl-CoA synthase, thus expanding the repertoire of targets recognized by this sRNA.