Small heat-shock proteins: important players in regulating cellular proteostasis.

Small heat-shock proteins (sHsps) are a diverse family of intra-cellular molecular chaperone proteins that play a critical role in mitigating and preventing protein aggregation under stress conditions such as elevated temperature, oxidation and infection. In doing so, they assist in the maintenance of protein homeostasis (proteostasis) thereby avoiding the deleterious effects that result from loss of protein function and/or protein aggregation. The chaperone properties of sHsps are therefore employed extensively in many tissues to prevent the development of diseases associated with protein aggregation. Significant progress has been made of late in understanding the structure and chaperone mechanism of sHsps. In this review, we discuss some of these advances, with a focus on mammalian sHsp hetero-oligomerisation, the mechanism by which sHsps act as molecular chaperones to prevent both amorphous and fibrillar protein aggregation, and the role of post-translational modifications in sHsp chaperone function, particularly in the context of disease.

Hsp90 inhibits α-synuclein aggregation by interacting with soluble oligomers.

Aggregated α-synuclein is one of the main components of the pathological Lewy bodies associated with Parkinson's disease (PD). Many other proteins, including chaperones such as Hsp90 and Hsp70, have been found co-localized with Lewy bodies and the expression levels of Hsp90 have been found to be increased in brains of PD patients. Although the role of Hsp70 in the aggregation of α-synuclein has been extensively studied, relatively little is known about the effect of Hsp90 on this process. Here, we have investigated if Hsp90 can prevent the aggregation of the A53T pathological mutant of α-synuclein in vitro. A detailed study using many biophysical methods has revealed that Hsp90 prevents α-synuclein from aggregating in an ATP-independent manner and that it forms a strong complex with the transiently populated toxic oligomeric α-synuclein species formed along the aggregation pathway. We have also shown that, upon forming a complex with Hsp90, the oligomers are rendered harmless and nontoxic to cells. Thus, we have clear evidence that Hsp90 is likely to play an important role on these processes in vivo.

A radish seed antifungal peptide with a high amyloid fibril-forming propensity.

The amyloid fibril-forming ability of two closely related antifungal and antimicrobial peptides derived from plant defensin proteins has been investigated. As assessed by sequence analysis, thioflavin T binding, transmission electron microscopy, atomic force microscopy and X-ray fiber diffraction, a 19 amino acid fragment from the C-terminal region of Raphanus sativus antifungal protein, known as RsAFP-19, is highly amyloidogenic. Further, its fibrillar morphology can be altered by externally controlled conditions. Freezing and thawing led to amyloid fibril formation which was accompanied by loss of RsAFP-19 antifungal activity. A second, closely related antifungal peptide displayed no fibril-forming capacity. It is concluded that while fibril formation is not associated with the antifungal properties of these peptides, the peptide RsAFP-19 is of potential use as a controllable, highly amyloidogenic small peptide for investigating the structure of amyloid fibrils and their mechanism of formation.

Twisting transition between crystalline and fibrillar phases of aggregated peptides.

We study two distinctly ordered condensed phases of polypeptide molecules, amyloid fibrils and amyloidlike microcrystals, and the first-order twisting phase transition between these two states. We derive a single free-energy form which connects both phases. Our model identifies relevant degrees of freedom for describing the collective behavior of supramolecular polypeptide structures, reproduces accurately the results from molecular dynamics simulations as well as from experiments, and sheds light on the uniform nature of the dimensions of different peptide fibrils.

Molecular mechanisms used by chaperones to reduce the toxicity of aberrant protein oligomers.

Chaperones are the primary regulators of the proteostasis network and are known to facilitate protein folding, inhibit protein aggregation, and promote disaggregation and clearance of misfolded aggregates inside cells. We have tested the effects of five chaperones on the toxicity of misfolded oligomers preformed from three different proteins added extracellularly to cultured cells. All the chaperones were found to decrease oligomer toxicity significantly, even at very low chaperone/protein molar ratios, provided that they were added extracellularly rather than being overexpressed in the cytosol. Infrared spectroscopy and site-directed labeling experiments using pyrene ruled out structural reorganizations within the discrete oligomers. Rather, confocal microscopy, SDS-PAGE, and intrinsic fluorescence measurements indicated tight binding between oligomers and chaperones. Moreover, atomic force microscopy imaging indicated that larger assemblies of oligomers are formed in the presence of the chaperones. This suggests that the chaperones bind to the oligomers and promote their assembly into larger species, with consequent shielding of the reactive surfaces and a decrease in their diffusional mobility. Overall, the data indicate a generic ability of chaperones to neutralize extracellular misfolded oligomers efficiently and reveal that further assembly of protein oligomers into larger species can be an effective strategy to neutralize such extracellular species.

Iron promotes the toxicity of amyloid beta peptide by impeding its ordered aggregation.

We have previously shown that overexpressing subunits of the iron-binding protein ferritin can rescue the toxicity of the amyloid ß (Aß) peptide in our Drosophila model system. These data point to an important pathogenic role for iron in Alzheimer disease. In this study, we have used an iron-selective chelating compound and RNAi-mediated knockdown of endogenous ferritin to further manipulate iron in the brain. We confirm that chelation of iron protects the fly from the harmful effects of Aß. To understand the pathogenic mechanisms, we have used biophysical techniques to see how iron affects Aß aggregation. We find that iron slows the progression of the Aß peptide from an unstructured conformation to the ordered cross-ß fibrils that are characteristic of amyloid. Finally, using mammalian cell culture systems, we have shown that iron specifically enhances Aß toxicity but only if the metal is present throughout the aggregation process. These data support the hypothesis that iron delays the formation of well ordered aggregates of Aß and so promotes its toxicity in Alzheimer disease.

Imaging amyloid fibrils within cells using a Se-labelling strategy.

The process of aggregation leading to amyloid formation by peptides and proteins is associated with diseases ranging from systemic amyloidoses to neurodegenerative disorders such as Alzheimer's disease. A key question in understanding the link between amyloid formation and its pathological consequences is the ultrastructural localisation and morphological form of amyloid species within the cellular environment. The acquisition of such information has proven to be challenging, but we report here a novel approach that enables amyloid fibrils to be visualised directly within a cell. First, fibrils are assembled from selenium analogues of the sulfur-containing cysteine peptides, and then, atomic number contrast transmission electron microscopy is used to detect the selenium doped species selectively within the carbon-rich background of the cell. We demonstrate the power of this approach by imaging human monocyte-derived macrophage cells that have been exposed to fibrils from an amyloidogenic fragment of the disease-associated protein transthyretin. The ready incorporation of seleno-cysteine and methionine instead of their natural sulfur-containing analogues, a feature that is already commonly used in X-ray diffraction studies of proteins, suggests that this method can be used as a general strategy to image specific peptides and proteins within the cellular environment using electron microscopy.

Role of intermolecular forces in defining material properties of protein nanofibrils.

Protein molecules have the ability to form a rich variety of natural and artificial structures and materials. We show that amyloid fibrils, ordered supramolecular nanostructures that are self-assembled from a wide range of polypeptide molecules, have rigidities varying over four orders of magnitude, and constitute a class of high-performance biomaterials. We elucidate the molecular origin of fibril material properties and show that the major contribution to their rigidity stems from a generic interbackbone hydrogen-bonding network that is modulated by variable side-chain interactions.

The extracellular chaperone clusterin influences amyloid formation and toxicity by interacting with prefibrillar structures.

Clusterin is an extracellular chaperone present in all disease-associated extracellular amyloid deposits, but its roles in amyloid formation and protein deposition in vivo are poorly understood. The current study initially aimed to characterize the effects of clusterin on amyloid formation in vitro by a panel of eight protein substrates. Two of the substrates (Alzheimer's beta peptide and a PI3-SH3 domain) were then used in further experiments to examine the effects of clusterin on amyloid cytotoxicity and to probe the mechanism of clusterin action. We show that clusterin exerts potent effects on amyloid formation, the nature and extent of which vary greatly with the clusterin:substrate ratio, and provide evidence that these effects are exerted via interactions with prefibrillar species that share common structural features. Proamyloidogenic effects of clusterin appear to be restricted to conditions in which the substrate protein is present at a very large molar excess; under these same conditions, clusterin coincorporates with substrate protein into insoluble aggregates. However, when clusterin is present at much higher but still substoichiometric levels (e.g., a molar ratio of clusterin:substrate=1:10), it potently inhibits amyloid formation and provides substantial cytoprotection. These findings suggest that clusterin is an important element in the control of extracellular protein misfolding.