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88 results on '"Knowles, Tuomas P. J."'

1. Aggregation of the amyloid-β peptide (Aβ40) within condensates generated through liquid–liquid phase separation.

Author

Morris, Owen M., Toprakcioglu, Zenon, Röntgen, Alexander, Cali, Mariana, Knowles, Tuomas P. J., and Vendruscolo, Michele

Abstract

The deposition of the amyloid-β (Aβ) peptide into amyloid fibrils is a hallmark of Alzheimer’s disease. Recently, it has been reported that some proteins can aggregate and form amyloids through an intermediate pathway involving a liquid-like condensed phase. These observations prompted us to investigate the phase space of Aβ. We thus explored the ability of Aβ to undergo liquid–liquid phase separation, and the subsequent liquid-to-solid transition that takes place within the resulting condensates. Through the use of microfluidic approaches, we observed that the 40-residue form of Αβ (Αβ40) can undergo liquid–liquid phase separation, and that accessing a liquid-like intermediate state enables Αβ40 to self-assemble and aggregate into amyloid fibrils through this pathway. These results prompt further studies to investigate the possible role of Αβ liquid–liquid phase separation and its subsequent aggregation in the context of Alzheimer’s disease and more generally on neurodegenerative processes. [ABSTRACT FROM AUTHOR]

Published
2024
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2. α-Synuclein oligomers form by secondary nucleation.

Author

Xu, Catherine K., Meisl, Georg, Andrzejewska, Ewa A., Krainer, Georg, Dear, Alexander J., Castellana-Cruz, Marta, Turi, Soma, Edu, Irina A., Vivacqua, Giorgio, Jacquat, Raphaël P. B., Arter, William E., Spillantini, Maria Grazia, Vendruscolo, Michele, Linse, Sara, and Knowles, Tuomas P. J.

Subjects
PARKINSON'S disease, SINGLE molecules, IONIC strength, DRUG target, MEMBRANE lipids
Abstract

Oligomeric species arising during the aggregation of α-synuclein are implicated as a major source of toxicity in Parkinson's disease, and thus a major potential drug target. However, both their mechanism of formation and role in aggregation are largely unresolved. Here we show that, at physiological pH and in the absence of lipid membranes, α-synuclein aggregates form by secondary nucleation, rather than simple primary nucleation, and that this process is enhanced by agitation. Moreover, using a combination of single molecule and bulk level techniques, we identify secondary nucleation on the surfaces of existing fibrils, rather than formation directly from monomers, as the dominant source of oligomers. Our results highlight secondary nucleation as not only the key source of oligomers, but also the main mechanism of aggregate formation, and show that these processes take place under conditions which recapitulate the neutral pH and ionic strength of the cytosol. The formation of protein aggregates is a hallmark of Parkinson's disease, with small oligomeric species implicated as a major source of toxicity. In this work, Xu et al. determine their mechanism of formation and role in aggregation. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Molecular properties and diagnostic potential of monoclonal antibodies targeting cytotoxic α-synuclein oligomers.

Author

Nielsen, Janni, Lauritsen, Johanne, Pedersen, Jannik N., Nowak, Jan S., Bendtsen, Malthe K., Kleijwegt, Giulia, Lusser, Kaija, Pitarch, Laia C., Moreno, Julián V., Schneider, Matthias M., Krainer, Georg, Goksøyr, Louise, Khalifé, Paul, Kaalund, Sanne Simone, Aznar, Susana, Kjærgaard, Magnus, Sereikaité, Vita, Strømgaard, Kristian, Knowles, Tuomas P. J., and Nielsen, Morten Agertoug

Published
2024
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4. Protein Condensate Atlas from predictive models of heteromolecular condensate composition.

Author

Saar, Kadi L., Scrutton, Rob M., Bloznelyte, Kotryna, Morgunov, Alexey S., Good, Lydia L., Lee, Alpha A., Teichmann, Sarah A., and Knowles, Tuomas P. J.

Subjects
PREDICTION models, PROTEOMICS, IMMUNOSTAINING, MACHINE learning, AMINO acid sequence, PHASE separation, PROTEINS, PROTEIN-protein interactions
Abstract

Biomolecular condensates help cells organise their content in space and time. Cells harbour a variety of condensate types with diverse composition and many are likely yet to be discovered. Here, we develop a methodology to predict the composition of biomolecular condensates. We first analyse available proteomics data of cellular condensates and find that the biophysical features that determine protein localisation into condensates differ from known drivers of homotypic phase separation processes, with charge mediated protein-RNA and hydrophobicity mediated protein-protein interactions playing a key role in the former process. We then develop a machine learning model that links protein sequence to its propensity to localise into heteromolecular condensates. We apply the model across the proteome and find many of the top-ranked targets outside the original training data to localise into condensates as confirmed by orthogonal immunohistochemical staining imaging. Finally, we segment the condensation-prone proteome into condensate types based on an overlap with biomolecular interaction profiles to generate a Protein Condensate Atlas. Several condensate clusters within the Atlas closely match the composition of experimentally characterised condensates or regions within them, suggesting that the Atlas can be valuable for identifying additional components within known condensate systems and discovering previously uncharacterised condensates. Biomolecular condensates help cells organise their content in space and time. Here the authors report a machine learning driven methodology to predict the composition of biomolecular condensates and they then validate their predictions against the composition of known biomolecular condensates. [ABSTRACT FROM AUTHOR]

Published
2024
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5. Solutes unmask differences in clustering versus phase separation of FET proteins.

Author

Kar, Mrityunjoy, Vogel, Laura T., Chauhan, Gaurav, Felekyan, Suren, Ausserwöger, Hannes, Welsh, Timothy J., Dar, Furqan, Kamath, Anjana R., Knowles, Tuomas P. J., Hyman, Anthony A., Seidel, Claus A. M., and Pappu, Rohit V.

Subjects
PHASE separation, PROTEIN fractionation, PHASE transitions, GELATION, PERCOLATION, SOLUBILITY, VISCOELASTICITY
Abstract

Phase separation and percolation contribute to phase transitions of multivalent macromolecules. Contributions of percolation are evident through the viscoelasticity of condensates and through the formation of heterogeneous distributions of nano- and mesoscale pre-percolation clusters in sub-saturated solutions. Here, we show that clusters formed in sub-saturated solutions of FET (FUS-EWSR1-TAF15) proteins are affected differently by glutamate versus chloride. These differences on the nanoscale, gleaned using a suite of methods deployed across a wide range of protein concentrations, are prevalent and can be unmasked even though the driving forces for phase separation remain unchanged in glutamate versus chloride. Strikingly, differences in anion-mediated interactions that drive clustering saturate on the micron-scale. Beyond this length scale the system separates into coexisting phases. Overall, we find that sequence-encoded interactions, mediated by solution components, make synergistic and distinct contributions to the formation of pre-percolation clusters in sub-saturated solutions, and to the driving forces for phase separation. Biomolecular condensates form via phase separation of multivalent macromolecules. Phase separation is governed by solubility whereas multivalence drives percolation, also known as gelation. The authors in this work identify the distinct energy and length scales that influence phase separation versus percolation. [ABSTRACT FROM AUTHOR]

Published
2024
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6. Maturation-dependent changes in the size, structure and seeding capacity of Aβ42 amyloid fibrils.

Author

Miller, Alyssa, Chia, Sean, Klimont, Ewa, Knowles, Tuomas P. J., Vendruscolo, Michele, and Ruggeri, Francesco Simone

Subjects
AMYLOID, AMYLOID beta-protein, DRUG discovery, ATOMIC force microscopy, ANALYTICAL chemistry, SUSTAINABLE development
Abstract

Many proteins self-assemble to form amyloid fibrils, which are highly organized structures stabilized by a characteristic cross-β network of hydrogen bonds. This process underlies a variety of human diseases and can be exploited to develop versatile functional biomaterials. Thus, protein self-assembly has been widely studied to shed light on the properties of fibrils and their intermediates. A still open question in the field concerns the microscopic processes that underlie the long-time behaviour and properties of amyloid fibrillar assemblies. Here, we use atomic force microscopy with angstrom-sensitivity to observe that amyloid fibrils undergo a maturation process, associated with an increase in both fibril length and thickness, leading to a decrease of their density, and to a change in their cross-β sheet content. These changes affect the ability of the fibrils to catalyse the formation of new aggregates. The identification of these changes helps us understand the fibril maturation processes, facilitate the targeting of amyloid fibrils in drug discovery, and offer insight into the development of biocompatible and sustainable protein-based materials. Microspray, nano-imaging and chemical analysis reveal time-dependent changes in the structural properties of amyloid fibrils in their plateau phase, conferring changes on the fibril surfaces for secondary nucleation and catalysis of aggregation. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Targeting nucleic acid phase transitions as a mechanism of action for antimicrobial peptides.

Author

Sneideris, Tomas, Erkamp, Nadia A., Ausserwöger, Hannes, Saar, Kadi L., Welsh, Timothy J., Qian, Daoyuan, Katsuya-Gaviria, Kai, Johncock, Margaret L. L. Y., Krainer, Georg, Borodavka, Alexander, and Knowles, Tuomas P. J.

Subjects
ANTIMICROBIAL peptides, PHASE transitions, BACTERIAL cell membranes, NUCLEIC acid separation, PHASE separation, NUCLEIC acids
Abstract

Antimicrobial peptides (AMPs), which combat bacterial infections by disrupting the bacterial cell membrane or interacting with intracellular targets, are naturally produced by a number of different organisms, and are increasingly also explored as therapeutics. However, the mechanisms by which AMPs act on intracellular targets are not well understood. Using machine learning-based sequence analysis, we identified a significant number of AMPs that have a strong tendency to form liquid-like condensates in the presence of nucleic acids through phase separation. We demonstrate that this phase separation propensity is linked to the effectiveness of the AMPs in inhibiting transcription and translation in vitro, as well as their ability to compact nucleic acids and form clusters with bacterial nucleic acids in bacterial cells. These results suggest that the AMP-driven compaction of nucleic acids and modulation of their phase transitions constitute a previously unrecognised mechanism by which AMPs exert their antibacterial effects. The development of antimicrobials that target nucleic acid phase transitions may become an attractive route to finding effective and long-lasting antibiotics. In this work the authors describe antimicrobial peptides (AMPs)-driven phase transitions of intracellular nucleic acids, whereby AMPs induce compaction and phase separation of nucleic acids, resulting in their sequestration and eventual cell death. [ABSTRACT FROM AUTHOR]

Published
2023
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8. Direct digital sensing of protein biomarkers in solution.

Author

Krainer, Georg, Saar, Kadi L., Arter, William E., Welsh, Timothy J., Czekalska, Magdalena A., Jacquat, Raphaël P. B., Peter, Quentin, Traberg, Walther C., Pujari, Arvind, Jayaram, Akhila K., Challa, Pavankumar, Taylor, Christopher G., van der Linden, Lize-Mari, Franzmann, Titus, Owens, Roisin M., Alberti, Simon, Klenerman, David, and Knowles, Tuomas P. J.

Subjects
MICROCHIP electrophoresis, BIOMARKERS, PROTEINS, IMMUNOCHEMISTRY
Abstract

The detection of proteins is of central importance to biomolecular analysis and diagnostics. Typical immunosensing assays rely on surface-capture of target molecules, but this constraint can limit specificity, sensitivity, and the ability to obtain information beyond simple concentration measurements. Here we present a surface-free, single-molecule microfluidic sensing platform for direct digital protein biomarker detection in solution, termed digital immunosensor assay (DigitISA). DigitISA is based on microchip electrophoretic separation combined with single-molecule detection and enables absolute number/concentration quantification of proteins in a single, solution-phase step. Applying DigitISA to a range of targets including amyloid aggregates, exosomes, and biomolecular condensates, we demonstrate that the assay provides information beyond stoichiometric interactions, and enables characterization of immunochemistry, binding affinity, and protein biomarker abundance. Taken together, our results suggest a experimental paradigm for the sensing of protein biomarkers, which enables analyses of targets that are challenging to address using conventional immunosensing approaches. There are limitations with current protein sensing methods. Here the authors report DigitISA, a digital immunosensor assay based on microchip electrophoretic separation and single-molecule detection that enables quantitation of protein biomarkers in a single, solution-phase step. [ABSTRACT FROM AUTHOR]

Published
2023
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9. Bioprinting microporous functional living materials from protein-based core-shell microgels.

Author

Ou, Yangteng, Cao, Shixiang, Zhang, Yang, Zhu, Hongjia, Guo, Chengzhi, Yan, Wei, Xin, Fengxue, Dong, Weiliang, Zhang, Yanli, Narita, Masashi, Yu, Ziyi, and Knowles, Tuomas P. J.

Subjects
BIOPRINTING, MICROGELS, BIOENGINEERING, STRUCTURAL shells, MANUFACTURING processes, MICROPOROSITY
Abstract

Living materials bring together material science and biology to allow the engineering and augmenting of living systems with novel functionalities. Bioprinting promises accurate control over the formation of such complex materials through programmable deposition of cells in soft materials, but current approaches had limited success in fine-tuning cell microenvironments while generating robust macroscopic morphologies. Here, we address this challenge through the use of core-shell microgel ink to decouple cell microenvironments from the structural shell for further processing. Cells are microfluidically immobilized in the viscous core that can promote the formation of both microbial populations and mammalian cellular spheroids, followed by interparticle annealing to give covalently stabilized functional scaffolds with controlled microporosity. The results show that the core-shell strategy mitigates cell leakage while affording a favorable environment for cell culture. Furthermore, we demonstrate that different microbial consortia can be printed into scaffolds for a range of applications. By compartmentalizing microbial consortia in separate microgels, the collective bioprocessing capability of the scaffold is significantly enhanced, shedding light on strategies to augment living materials with bioprocessing capabilities. Extrusion bioprinting can be used to produce living materials but controlling cell microenvironments is challenging. Here, the authors use a type of core-shell microgel ink that decouples cell culture from material processing to produce functional materials with a range of potential applications. [ABSTRACT FROM AUTHOR]

Published
2023
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10. Biomolecular condensate phase diagrams with a combinatorial microdroplet platform.

Author

Arter, William E., Qi, Runzhang, Erkamp, Nadia A., Krainer, Georg, Didi, Kieran, Welsh, Timothy J., Acker, Julia, Nixon-Abell, Jonathan, Qamar, Seema, Guillén-Boixet, Jordina, Franzmann, Titus M., Kuster, David, Hyman, Anthony A., Borodavka, Alexander, George-Hyslop, Peter St, Alberti, Simon, and Knowles, Tuomas P. J.

Subjects
PHASE diagrams, MICROPLATES, SMALL molecules, CELL physiology, PHASE transitions
Abstract

The assembly of biomolecules into condensates is a fundamental process underlying the organisation of the intracellular space and the regulation of many cellular functions. Mapping and characterising phase behaviour of biomolecules is essential to understand the mechanisms of condensate assembly, and to develop therapeutic strategies targeting biomolecular condensate systems. A central concept for characterising phase-separating systems is the phase diagram. Phase diagrams are typically built from numerous individual measurements sampling different parts of the parameter space. However, even when performed in microwell plate format, this process is slow, low throughput and requires significant sample consumption. To address this challenge, we present here a combinatorial droplet microfluidic platform, termed PhaseScan, for rapid and high-resolution acquisition of multidimensional biomolecular phase diagrams. Using this platform, we characterise the phase behaviour of a wide range of systems under a variety of conditions and demonstrate that this approach allows the quantitative characterisation of the effect of small molecules on biomolecular phase transitions. A central concept for characterising phase-separating systems is the phase diagram but generation of such diagrams for biomolecular systems is typically slow and low-throughput. Here the authors describe PhaseScan, a combinatorial droplet microfluidic platform for high-resolution acquisition of multidimensional biomolecular phase diagrams. [ABSTRACT FROM AUTHOR]

Published
2022
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12. Small soluble α-synuclein aggregates are the toxic species in Parkinson's disease.

Author

Emin, Derya, Zhang, Yu P., Lobanova, Evgeniia, Miller, Alyssa, Li, Xuecong, Xia, Zengjie, Dakin, Helen, Sideris, Dimitrios I., Lam, Jeff Y. L., Ranasinghe, Rohan T., Kouli, Antonina, Zhao, Yanyan, De, Suman, Knowles, Tuomas P. J., Vendruscolo, Michele, Ruggeri, Francesco S., Aigbirhio, Franklin I., Williams-Gray, Caroline H., and Klenerman, David

Subjects
PARKINSON'S disease, ALPHA-synuclein, POISONS, BRAIN diseases, SEPARATION (Technology)
Abstract

Soluble α-synuclein aggregates varying in size, structure, and morphology have been closely linked to neuronal death in Parkinson's disease. However, the heterogeneity of different co-existing aggregate species makes it hard to isolate and study their individual toxic properties. Here, we show a reliable non-perturbative method to separate a heterogeneous mixture of protein aggregates by size. We find that aggregates of wild-type α-synuclein smaller than 200 nm in length, formed during an in vitro aggregation reaction, cause inflammation and permeabilization of single-liposome membranes and that larger aggregates are less toxic. Studying soluble aggregates extracted from post-mortem human brains also reveals that these aggregates are similar in size and structure to the smaller aggregates formed in aggregation reactions in the test tube. Furthermore, we find that the soluble aggregates present in Parkinson's disease brains are smaller, largely less than 100 nm, and more inflammatory compared to the larger aggregates present in control brains. This study suggests that the small non-fibrillar α-synuclein aggregates are the critical species driving neuroinflammation and disease progression. α-synuclein aggregates cause neuronal damage, but their heterogeneity complicates studying their toxic properties. Here, the authors analyze α-synuclein aggregates in vitro and study post-mortem brain samples, providing evidence that small aggregates are the main culprit for neuronal death in Parkinson's disease. [ABSTRACT FROM AUTHOR]

Published
2022
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13. The C-terminal tail of α-synuclein protects against aggregate replication but is critical for oligomerization.

Author

Farzadfard, Azad, Pedersen, Jannik Nedergaard, Meisl, Georg, Somavarapu, Arun Kumar, Alam, Parvez, Goksøyr, Louise, Nielsen, Morten Agertoug, Sander, Adam Frederik, Knowles, Tuomas P. J., Pedersen, Jan Skov, and Otzen, Daniel Erik

Subjects
ALPHA-synuclein, PARKINSON'S disease, OLIGOMERIZATION, ELECTRIC potential, POISONS
Abstract

Aggregation of the 140-residue protein α-synuclein (αSN) is a key factor in the etiology of Parkinson's disease. Although the intensely anionic C-terminal domain (CTD) of αSN does not form part of the amyloid core region or affect membrane binding ability, truncation or reduction of charges in the CTD promotes fibrillation through as yet unknown mechanisms. Here, we study stepwise truncated CTDs and identify a threshold region around residue 121; constructs shorter than this dramatically increase their fibrillation tendency. Remarkably, these effects persist even when as little as 10% of the truncated variant is mixed with the full-length protein. Increased fibrillation can be explained by a substantial increase in self-replication, most likely via fragmentation. Paradoxically, truncation also suppresses toxic oligomer formation, and oligomers that can be formed by chemical modification show reduced membrane affinity and cytotoxicity. These remarkable changes correlate to the loss of negative electrostatic potential in the CTD and highlight a double-edged electrostatic safety guard. Farzadfard et al. present a comprehensive analysis of a range of C-terminal truncations of aSN, linking the importance of high C-terminus charge for decreased fibrillation rates. The ability to formation oligomers, to disrupt synthetic vesicles and cell toxicity was reduced with truncated aSN, aiding in understanding of the intramolecular interactions of aSN which promote/inhibit aggregation. [ABSTRACT FROM AUTHOR]

Published
2022
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15. The Hsc70 disaggregation machinery removes monomer units directly from α-synuclein fibril ends.

Author

Schneider, Matthias M., Gautam, Saurabh, Herling, Therese W., Andrzejewska, Ewa, Krainer, Georg, Miller, Alyssa M., Trinkaus, Victoria A., Peter, Quentin A. E., Ruggeri, Francesco Simone, Vendruscolo, Michele, Bracher, Andreas, Dobson, Christopher M., Hartl, F. Ulrich, and Knowles, Tuomas P. J.

Abstract

Molecular chaperones contribute to the maintenance of cellular protein homoeostasis through assisting de novo protein folding and preventing amyloid formation. Chaperones of the Hsp70 family can further disaggregate otherwise irreversible aggregate species such as α-synuclein fibrils, which accumulate in Parkinson’s disease. However, the mechanisms and kinetics of this key functionality are only partially understood. Here, we combine microfluidic measurements with chemical kinetics to study α-synuclein disaggregation. We show that Hsc70 together with its co-chaperones DnaJB1 and Apg2 can completely reverse α-synuclein aggregation back to its soluble monomeric state. This reaction proceeds through first-order kinetics where monomer units are removed directly from the fibril ends with little contribution from intermediate fibril fragmentation steps. These findings extend our mechanistic understanding of the role of chaperones in the suppression of amyloid proliferation and in aggregate clearance, and inform on possibilities and limitations of this strategy in the development of therapeutics against synucleinopathies. [ABSTRACT FROM AUTHOR]

Published
2021
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16. Sequential storage and release of microdroplets.

Author

Toprakcioglu, Zenon and Knowles, Tuomas P. J.

Abstract

Droplet microfluidic methods have opened up the possibility of studying a plethora of phenomena ranging from biological to physical or chemical processes at ultra low volumes and high throughput. A key component of such approaches is the ability to trap droplets for observation, and many device architectures for achieving this objective have been developed. A challenge with such approaches is, however, recovering the droplets following their confinement for applications involving further analysis. Here, we present a device capable of generating, confining and releasing microdroplets in a sequential manner. Through a combination of experimental and computational simulations, we shed light on the key features required for successful droplet storage and retrieval. Moreover, we explore the effect of the flow rate of the continuous phase on droplet release, determining that a critical rate is needed to ensure complete droplet deformation through constrictions holding the droplets in place prior to release. Finally, we find that once released, droplets can be retrieved and collected off chip. The ability to generate, store and sequentially release droplets renders such a device particularly promising for future applications where reactions may not only be monitored on-chip, but droplets can also be retrieved for further analysis, facilitating new exploratory avenues in the fields of analytical chemistry and biology. [ABSTRACT FROM AUTHOR]

Published
2021
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17. Controlled self-assembly of plant proteins into high-performance multifunctional nanostructured films.

Author

Kamada, Ayaka, Rodriguez-Garcia, Marc, Ruggeri, Francesco Simone, Shen, Yi, Levin, Aviad, and Knowles, Tuomas P. J.

Subjects
PLANT proteins, STRUCTURAL colors, ENGINEERING plastics, HYDROPHOBIC surfaces, PLASTICS engineering, PLANT capacity
Abstract

The abundance of plant-derived proteins, as well as their biodegradability and low environmental impact make them attractive polymeric feedstocks for next-generation functional materials to replace current petroleum-based systems. However, efforts to generate functional materials from plant-based proteins in a scalable manner have been hampered by the lack of efficient methods to induce and control their micro and nanoscale structure, key requirements for achieving advantageous material properties and tailoring their functionality. Here, we demonstrate a scalable approach for generating mechanically robust plant-based films on a metre-scale through controlled nanometre-scale self-assembly of water-insoluble plant proteins. The films produced using this method exhibit high optical transmittance, as well as robust mechanical properties comparable to engineering plastics. Furthermore, we demonstrate the ability to impart nano- and microscale patterning into such films through templating, leading to the formation of hydrophobic surfaces as well as structural colour by controlling the size of the patterned features. Green use of plant derived proteins in functional materials has been limited by inefficient methods to control micro and nanoscale structure. Here, the authors use nanoscale assembly of water-insoluble plant proteins to make meter scale films with comparable properties to conventional plastics. [ABSTRACT FROM AUTHOR]

Published
2021
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18. Shear-mediated sol-gel transition of regenerated silk allows the formation of Janus-like microgels.

Author

Toprakcioglu, Zenon and Knowles, Tuomas P. J.

Subjects
*MICROGELS, *BIOCOMPATIBILITY, *FLUORESCENCE microscopy, *MOLECULES, *FOURIER transform infrared spectroscopy
Abstract

Microcapsules and microgels consisting of macromolecular networks have received increasing attention due to their biomedical and pharmaceutical applications. Protein microgels and in particular silk-based microcapsules have desirable properties due to their biocompatibility and lack of toxicity. Typically such structures formed through emulsion templating are spherical in geometry due to interfacial tension. However, approaches to synthesis particles with more complex and non-spherical geometries are sought due to their packing properties and cargo release characteristics. Here, we describe a droplet-microfluidic strategy for generating asymmetric tubular-like microgels from reconstituted silk fibroin; a major component of native silk. It was determined using fluorescence microscopy, that the shear stress within the microchannel promotes surface protein aggregation, resulting in the asymmetric morphology of the microgels. Moreover, the structural transition that the protein undergoes was confirmed using FTIR. Crucially, the core of the microgels remains liquid, while the surface has fully aggregated into a fibrillar network. Additionally, we show that microgel morphology could be controlled by varying the dispersed to continuous phase flow rates, while it was determined that the radius of curvature of the asymmetric microgels is correlated to the wall shear stress. By comparing the surface fluorescence intensity of the microgels as a function of radius of curvature, the effect of the shear stress on the amount of aggregation could be quantified. Finally, the potential use of these asymmetric microgels as carriers of cargo molecules is showcased. As the core of the microgel remains liquid but the shell has gelled, this approach is highly suitable for the storage of bio-active cargo molecules such as antibodies, making such a delivery system attractive in the context of biomedical and pharmaceutical applications. [ABSTRACT FROM AUTHOR]

Published
2021
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19. Reentrant liquid condensate phase of proteins is stabilized by hydrophobic and non-ionic interactions.

Author

Krainer, Georg, Welsh, Timothy J., Joseph, Jerelle A., Espinosa, Jorge R., Wittmann, Sina, de Csilléry, Ella, Sridhar, Akshay, Toprakcioglu, Zenon, Gudiškytė, Giedre, Czekalska, Magdalena A., Arter, William E., Guillén-Boixet, Jordina, Franzmann, Titus M., Qamar, Seema, George-Hyslop, Peter St, Hyman, Anthony A., Collepardo-Guevara, Rosana, Alberti, Simon, and Knowles, Tuomas P. J.

Subjects
HYDROPHOBIC interactions, GAS condensate reservoirs, BOSE-Einstein condensation, PHASE separation, PHASE transitions, PROTEIN fractionation, PROTEINS
Abstract

Liquid–liquid phase separation of proteins underpins the formation of membraneless compartments in living cells. Elucidating the molecular driving forces underlying protein phase transitions is therefore a key objective for understanding biological function and malfunction. Here we show that cellular proteins, which form condensates at low salt concentrations, including FUS, TDP-43, Brd4, Sox2, and Annexin A11, can reenter a phase-separated regime at high salt concentrations. By bringing together experiments and simulations, we demonstrate that this reentrant phase transition in the high-salt regime is driven by hydrophobic and non-ionic interactions, and is mechanistically distinct from the low-salt regime, where condensates are additionally stabilized by electrostatic forces. Our work thus sheds light on the cooperation of hydrophobic and non-ionic interactions as general driving forces in the condensation process, with important implications for aberrant function, druggability, and material properties of biomolecular condensates. Elucidating the molecular driving forces underlying liquid–liquid phase separation is a key objective for understanding biological function and malfunction. Here the authors show that a wide range of cellular proteins, including FUS, TDP-43, Brd4, Sox2, and Annexin A11, which form condensates at low salt concentrations, can reenter a phase-separated regime at high salt concentrations. [ABSTRACT FROM AUTHOR]

Published
2021
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20. Infrared nanospectroscopy reveals the molecular interaction fingerprint of an aggregation inhibitor with single Aβ42 oligomers.

Author

Ruggeri, Francesco Simone, Habchi, Johnny, Chia, Sean, Horne, Robert I., Vendruscolo, Michele, and Knowles, Tuomas P. J.

Subjects
MOLECULAR interactions, DNA fingerprinting, SINGLE molecules, SMALL molecules, OLIGOMERS, PARKINSON'S disease, ATOMIC force microscopy
Abstract

Significant efforts have been devoted in the last twenty years to developing compounds that can interfere with the aggregation pathways of proteins related to misfolding disorders, including Alzheimer's and Parkinson's diseases. However, no disease-modifying drug has become available for clinical use to date for these conditions. One of the main reasons for this failure is the incomplete knowledge of the molecular mechanisms underlying the process by which small molecules interact with protein aggregates and interfere with their aggregation pathways. Here, we leverage the single molecule morphological and chemical sensitivity of infrared nanospectroscopy to provide the first direct measurement of the structure and interaction between single Aβ42 oligomeric and fibrillar species and an aggregation inhibitor, bexarotene, which is able to prevent Aβ42 aggregation in vitro and reverses its neurotoxicity in cell and animal models of Alzheimer's disease. Our results demonstrate that the carboxyl group of this compound interacts with Aβ42 aggregates through a single hydrogen bond. These results establish infrared nanospectroscopy as a powerful tool in structure-based drug discovery for protein misfolding diseases. Our understanding of the molecular mechanisms underlying pathological protein aggregation remains incomplete. Here, single molecule infrared nanospectroscopy (AFM-IR) offers insight into the structure of Aβ42 oligomeric and fibrillar species and their interaction with an aggregation inhibitor, paving the way for single molecule drug discovery studies. [ABSTRACT FROM AUTHOR]

Published
2021
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21. A dopamine metabolite stabilizes neurotoxic amyloid-β oligomers.

Author

Cataldi, Rodrigo, Chia, Sean, Pisani, Katarina, Ruggeri, Francesco S., Xu, Catherine K., Šneideris, Tomas, Perni, Michele, Sarwat, Sunehera, Joshi, Priyanka, Kumita, Janet R., Linse, Sara, Habchi, Johnny, Knowles, Tuomas P. J., Mannini, Benedetta, Dobson, Christopher M., and Vendruscolo, Michele

Subjects
NEUROTOXIC agents, OLIGOMERS, DOPAMINE, CATECHOLAMINES, ALZHEIMER'S disease, HOMEOSTASIS
Abstract

Aberrant soluble oligomers formed by the amyloid-β peptide (Aβ) are major pathogenic agents in the onset and progression of Alzheimer's disease. A variety of biomolecules can influence the formation of these oligomers in the brain, although their mechanisms of action are still largely unknown. Here, we studied the effects on Aβ aggregation of DOPAL, a reactive catecholaldehyde intermediate of dopamine metabolism. We found that DOPAL is able to stabilize Aβ oligomeric species, including dimers and trimers, that exert toxic effects on human neuroblastoma cells, in particular increasing cytosolic calcium levels and promoting the generation of reactive oxygen species. These results reveal an interplay between Aβ aggregation and key biochemical processes regulating cellular homeostasis in the brain. Cataldi et al. investigates the impact of the dopamine derivative DOPAL on the Aβ peptide oligomer formation. They report that DOPAL promotes the formation of stable Aβ oligomers that exert toxicity on neuroblastoma cells by increasing cytosolic calcium levels and generating reactive oxygen species. This study connects Aβ aggregation with processes regulating cellular homeostasis in the brain. [ABSTRACT FROM AUTHOR]

Published
2021
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22. Screening of small molecules using the inhibition of oligomer formation in α-synuclein aggregation as a selection parameter.

Author

Staats, Roxine, Michaels, Thomas C. T., Flagmeier, Patrick, Chia, Sean, Horne, Robert I., Habchi, Johnny, Linse, Sara, Knowles, Tuomas P. J., Dobson, Christopher M., and Vendruscolo, Michele

Subjects
SMALL molecules, OLIGOMERS, SYNUCLEINS, APIGENIN, PROTEINS
Abstract

The aggregation of α-synuclein is a central event in Parkinsons's disease and related synucleinopathies. Since pharmacologically targeting this process, however, has not yet resulted in approved disease-modifying treatments, there is an unmet need of developing novel methods of drug discovery. In this context, the use of chemical kinetics has recently enabled accurate quantifications of the microscopic steps leading to the proliferation of protein misfolded oligomers. As these species are highly neurotoxic, effective therapeutic strategies may be aimed at reducing their numbers. Here, we exploit this quantitative approach to develop a screening strategy that uses the reactive flux toward α-synuclein oligomers as a selection parameter. Using this approach, we evaluate the efficacy of a library of flavone derivatives, identifying apigenin as a compound that simultaneously delays and reduces the formation of α-synuclein oligomers. These results demonstrate a compound selection strategy based on the inhibition of the formation of α-synuclein oligomers, which may be key in identifying small molecules in drug discovery pipelines for diseases associated with α-synuclein aggregation. Promising treatments for neurogenerative disorders may involve targeting kinetic intermediates, including α-synuclein oligomers. Here a kinetic method for quantifying oligomer populations is used to screen small molecule inhibitors of oligomerisation and gain mechanistic insight into their modes of action. [ABSTRACT FROM AUTHOR]

Published
2020
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24. Trodusquemine displaces protein misfolded oligomers from cell membranes and abrogates their cytotoxicity through a generic mechanism.

Author

Limbocker, Ryan, Mannini, Benedetta, Ruggeri, Francesco S., Cascella, Roberta, Xu, Catherine K., Perni, Michele, Chia, Sean, Chen, Serene W., Habchi, Johnny, Bigi, Alessandra, Kreiser, Ryan P., Wright, Aidan K., Albright, J. Alex, Kartanas, Tadas, Kumita, Janet R., Cremades, Nunilo, Zasloff, Michael, Cecchi, Cristina, Knowles, Tuomas P. J., and Chiti, Fabrizio

Subjects
OLIGOMERS, STEROLS, CELL membranes, CELL-mediated cytotoxicity, DISEASE progression, ALZHEIMER'S disease
Abstract

The onset and progression of numerous protein misfolding diseases are associated with the presence of oligomers formed during the aberrant aggregation of several different proteins, including amyloid-β (Aβ) in Alzheimer's disease and α-synuclein (αS) in Parkinson's disease. These small, soluble aggregates are currently major targets for drug discovery. In this study, we show that trodusquemine, a naturally-occurring aminosterol, markedly reduces the cytotoxicity of αS, Aβ and HypF-N oligomers to human neuroblastoma cells by displacing the oligomers from cell membranes in the absence of any substantial morphological and structural changes to the oligomers. These results indicate that the reduced toxicity results from a mechanism that is common to oligomers from different proteins, shed light on the origin of the toxicity of the most deleterious species associated with protein aggregation and suggest that aminosterols have the therapeutically-relevant potential to protect cells from the oligomer-induced cytotoxicity associated with numerous protein misfolding diseases. Limbocker et al. show that trodusquemine, an aminosterol, reduces the cytotoxicity of protein misfolded oligomers by displacing them from cell membranes in the absence of any overt structural/ morphological changes in them. This mechanism appears to be general, as they test it for oligomers of αS, Aβ and the model protein HypF-N to human neuroblastoma cells. [ABSTRACT FROM AUTHOR]

Published
2020
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25. Single molecule secondary structure determination of proteins through infrared absorption nanospectroscopy.

Author

Ruggeri, Francesco Simone, Mannini, Benedetta, Schmid, Roman, Vendruscolo, Michele, and Knowles, Tuomas P. J.

Subjects
PROTEIN structure, SINGLE molecules, SINGLE molecule detection, ABSORPTION spectra, INFRARED absorption, INFRARED spectra, MOLECULAR spectra
Abstract

The chemical and structural properties of biomolecules determine their interactions, and thus their functions, in a wide variety of biochemical processes. Innovative imaging methods have been developed to characterise biomolecular structures down to the angstrom level. However, acquiring vibrational absorption spectra at the single molecule level, a benchmark for bulk sample characterization, has remained elusive. Here, we introduce off-resonance, low power and short pulse infrared nanospectroscopy (ORS-nanoIR) to allow the acquisition of infrared absorption spectra and chemical maps at the single molecule level, at high throughput on a second timescale and with a high signal-to-noise ratio (~10–20). This high sensitivity enables the accurate determination of the secondary structure of single protein molecules with over a million-fold lower mass than conventional bulk vibrational spectroscopy. These results pave the way to probe directly the chemical and structural properties of individual biomolecules, as well as their interactions, in a broad range of chemical and biological systems. While infrared nanospectroscopy methods based on thermomechanical detection (AFM-IR) enables the acquisition of absorption spectra at the nanoscale, single molecule detection has not been possible so far. Here, the authors present off-resonance, low power and short pulse infrared nanospectroscopy (ORS-nanoIR), which allows measuring infrared absorption spectra at the single molecule level in a time scale of seconds with high throughput and demonstrate that the secondary structure of single protein molecules can be determined with this method. [ABSTRACT FROM AUTHOR]

Published
2020
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27. Microfluidic approaches for the analysis of protein–protein interactions in solution.

Author

Arter, William E., Levin, Aviad, Krainer, Georg, and Knowles, Tuomas P. J.

Abstract

Exploration and characterisation of the human proteome is a key objective enabling a heightened understanding of biological function, malfunction and pharmaceutical design. Since proteins typically exhibit their behaviour by binding to other proteins, the challenge of probing protein-protein interactions has been the focus of new and improved experimental approaches. Here, we review recently developed microfluidic techniques for the study and quantification of protein–protein interactions. We focus on methodologies that utilise the inherent strength of microfluidics for the control of mass transport on the micron scale, to facilitate surface and membrane-free interrogation and quantification of interacting proteins. Thus, the microfluidic tools described here provide the capability to yield insights on protein–protein interactions under physiological conditions. We first discuss the defining principles of microfluidics, and methods for the analysis of protein–protein interactions that utilise the diffusion-controlled mixing characteristic of fluids at the microscale. We then describe techniques that employ electrophoretic forces to manipulate and fractionate interacting protein systems for their biophysical characterisation, before discussing strategies that use microdroplet compartmentalisation for the analysis of protein interactions. We conclude by highlighting future directions for the field, such as the integration of microfluidic experiments into high-throughput workflows for the investigation of protein interaction networks. [ABSTRACT FROM AUTHOR]

Published
2020
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30. Latent analysis of unmodified biomolecules and their complexes in solution with attomole detection sensitivity.

Author

Yates, Emma V., Müller, Thomas, Rajah, Luke, De Genst, Erwin J., Arosio, Paolo, Linse, Sara, Vendruscolo, Michele, Dobson, Christopher M., and Knowles, Tuomas P. J.

Subjects
BIOMOLECULES, BIOLOGICAL systems, MICROFLUIDICS, MOLECULAR weights, MOLECULAR biology
Abstract

The study of biomolecular interactions is central to an understanding of function, malfunction and therapeutic modulation of biological systems, yet often involves a compromise between sensitivity and accuracy. Many conventional analytical steps and the procedures required to facilitate sensitive detection, such as the incorporation of chemical labels, are prone to perturb the complexes under observation. Here we present a 'latent' analysis approach that uses chemical and microfluidic tools to reveal, through highly sensitive detection of a labelled system, the behaviour of the physiologically relevant unlabelled system. We implement this strategy in a native microfluidic diffusional sizing platform, allowing us to achieve detection sensitivity at the attomole level, determine the hydrodynamic radii of biomolecules that vary by over three orders of magnitude in molecular weight, and study heterogeneous mixtures. We illustrate these key advantages by characterizing a complex of an antibody domain in the solution phase and under physiologically relevant conditions. [ABSTRACT FROM AUTHOR]

Published
2015
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31. Lipid vesicles trigger α-synuclein aggregation by stimulating primary nucleation.

Author

Galvagnion, Céline, Buell, Alexander K, Meisl, Georg, Michaels, Thomas C T, Vendruscolo, Michele, Knowles, Tuomas P J, and Dobson, Christopher M

Subjects
SYNUCLEINS, CARRIER proteins, NEUROPLASTICITY, SYNAPTIC vesicles, AMYLOID beta-protein, PARKINSON'S disease
Abstract

α-Synuclein (α-syn) is a 140-residue intrinsically disordered protein that is involved in neuronal and synaptic vesicle plasticity, but its aggregation to form amyloid fibrils is the hallmark of Parkinson's disease (PD). The interaction between α-syn and lipid surfaces is believed to be a key feature for mediation of its normal function, but under other circumstances it is able to modulate amyloid fibril formation. Using a combination of experimental and theoretical approaches, we identify the mechanism through which facile aggregation of α-syn is induced under conditions where it binds a lipid bilayer, and we show that the rate of primary nucleation can be enhanced by three orders of magnitude or more under such conditions. These results reveal the key role that membrane interactions can have in triggering conversion of α-syn from its soluble state to the aggregated state that is associated with neurodegeneration and to its associated disease states. [ABSTRACT FROM AUTHOR]

Published
2015
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32. A molecular chaperone breaks the catalytic cycle that generates toxic Aβ oligomers.

Author

Cohen, Samuel I A, Arosio, Paolo, Presto, Jenny, Kurudenkandy, Firoz Roshan, Biverstål, Henrik, Dolfe, Lisa, Dunning, Christopher, Yang, Xiaoting, Frohm, Birgitta, Vendruscolo, Michele, Johansson, Jan, Dobson, Christopher M, Fisahn, André, Knowles, Tuomas P J, and Linse, Sara

Subjects
ALZHEIMER'S disease research, NEURODEGENERATION, AMYLOID, ELECTROPHYSIOLOGY, PYRAMIDAL neurons
Abstract

Alzheimer's disease is an increasingly prevalent neurodegenerative disorder whose pathogenesis has been associated with aggregation of the amyloid-β peptide (Aβ42). Recent studies have revealed that once Aβ42 fibrils are generated, their surfaces effectively catalyze the formation of neurotoxic oligomers. Here we show that a molecular chaperone, a human Brichos domain, can specifically inhibit this catalytic cycle and limit human Aβ42 toxicity. We demonstrate in vitro that Brichos achieves this inhibition by binding to the surfaces of fibrils, thereby redirecting the aggregation reaction to a pathway that involves minimal formation of toxic oligomeric intermediates. We verify that this mechanism occurs in living mouse brain tissue by cytotoxicity and electrophysiology experiments. These results reveal that molecular chaperones can help maintain protein homeostasis by selectively suppressing critical microscopic steps within the complex reaction pathways responsible for the toxic effects of protein misfolding and aggregation. [ABSTRACT FROM AUTHOR]

Published
2015
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34. The amyloid state and its association with protein misfolding diseases.

Author

Knowles, Tuomas P. J., Vendruscolo, Michele, and Dobson, Christopher M.

Subjects
*AMYLOID, *ALZHEIMER'S disease, *TYPE 2 diabetes, *PEPTIDES, *HOMEOSTASIS, *METASTASIS
Abstract

The phenomenon of protein aggregation and amyloid formation has become the subject of rapidly increasing research activities across a wide range of scientific disciplines. Such activities have been stimulated by the association of amyloid deposition with a range of debilitating medical disorders, from Alzheimer's disease to type II diabetes, many of which are major threats to human health and welfare in the modern world. It has become clear, however, that the ability to form the amyloid state is more general than previously imagined, and that its study can provide unique insights into the nature of the functional forms of peptides and proteins, as well as understanding the means by which protein homeostasis can be maintained and protein metastasis avoided. [ABSTRACT FROM AUTHOR]

Published
2014
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35. Nanomechanics of functional and pathological amyloid materials.

Author

Knowles, Tuomas P. J. and Buehler, Markus J.

Subjects
*AMYLOID, *NANOSTRUCTURED materials, *PEPTIDES, *PROTEINS, *PATHOLOGY
Abstract

Amyloid or amyloid-like fibrils represent a general class of nanomaterials that can be formed from many different peptides and proteins. Although these structures have an important role in neurodegenerative disorders, amyloid materials have also been exploited for functional purposes by organisms ranging from bacteria to mammals. Here we review the functional and pathological roles of amyloid materials and discuss how they can be linked back to their nanoscale origins in the structure and nanomechanics of these materials. We focus on insights both from experiments and simulations, and discuss how comparisons between functional protein filaments and structures that are assembled abnormally can shed light on the fundamental material selection criteria that lead to evolutionary bias in multiscale material design in nature. [ABSTRACT FROM AUTHOR]

Published
2011
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36. Nanostructured films from hierarchical self-assembly of amyloidogenic proteins.

Author

Knowles, Tuomas P. J., Oppenheim, Tomas W., Buell, Alexander K., Chirgadze, Dimitri Y., and Welland, Mark E.

Subjects
*NANOSTRUCTURES, *MOLECULAR self-assembly, *MOLECULES, *AMYLOID, *NANOTECHNOLOGY
Abstract

In nature, sophisticated functional materials are created through hierarchical self-assembly of simple nanoscale motifs. In the laboratory, much progress has been made in the controlled assembly of molecules into one-, two- and three-dimensional artificial nanostructures, but bridging from the nanoscale to the macroscale to create useful macroscopic materials remains a challenge. Here we show a scalable self-assembly approach to making free-standing films from amyloid protein fibrils. The films were well ordered and highly rigid, with a Young's modulus of up to 5–7 GPa, which is comparable to the highest values for proteinaceous materials found in nature. We show that the self-organizing protein scaffolds can align otherwise unstructured components (such as fluorophores) within the macroscopic films. Multiscale self-assembly that relies on highly specific biomolecular interactions is an attractive path for realizing new multifunctional materials built from the bottom up. [ABSTRACT FROM AUTHOR]

Published
2010
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37. Publisher Correction: A dopamine metabolite stabilizes neurotoxic amyloid-β oligomers.

Author

Cataldi, Rodrigo, Chia, Sean, Pisani, Katarina, Ruggeri, Francesco S., Xu, Catherine K., Šneideris, Tomas, Perni, Michele, Sarwat, Sunehera, Joshi, Priyanka, Kumita, Janet R., Linse, Sara, Habchi, Johnny, Knowles, Tuomas P. J., Mannini, Benedetta, Dobson, Christopher M., and Vendruscolo, Michele

Subjects
DOPAMINE, METABOLITES, OLIGOMERS
Abstract

A Correction to this paper has been published: https://doi.org/10.1038/s42003-021-01680-7. [ABSTRACT FROM AUTHOR]

Published
2021
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39. A rationally designed bicyclic peptide remodels Aβ42 aggregation in vitro and reduces its toxicity in a worm model of Alzheimer's disease.

Author

Ikenoue, Tatsuya, Aprile, Francesco A., Sormanni, Pietro, Ruggeri, Francesco S., Perni, Michele, Heller, Gabriella T., Haas, Christian P., Middel, Christoph, Limbocker, Ryan, Mannini, Benedetta, Michaels, Thomas C. T., Knowles, Tuomas P. J., Dobson, Christopher M., and Vendruscolo, Michele

Subjects
ANIMAL models of Alzheimer's disease, AMYLOID beta-protein, PHYSIOLOGICAL effects of peptides, BICYCLIC compounds, BIOMARKERS, ALZHEIMER'S disease treatment, C-terminal binding proteins, CAENORHABDITIS elegans
Abstract

Bicyclic peptides have great therapeutic potential since they can bridge the gap between small molecules and antibodies by combining a low molecular weight of about 2 kDa with an antibody-like binding specificity. Here we apply a recently developed in silico rational design strategy to produce a bicyclic peptide to target the C-terminal region (residues 31–42) of the 42-residue form of the amyloid β peptide (Aβ42), a protein fragment whose aggregation into amyloid plaques is linked with Alzheimer's disease. We show that this bicyclic peptide is able to remodel the aggregation process of Aβ42 in vitro and to reduce its associated toxicity in vivo in a C. elegans worm model expressing Aβ42. These results provide an initial example of a computational approach to design bicyclic peptides to target specific epitopes on disordered proteins. [ABSTRACT FROM AUTHOR]

Published
2020
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40. Autocatalytic amplification of Alzheimer-associated Aβ42 peptide aggregation in human cerebrospinal fluid.

Author

Frankel, Rebecca, Törnquist, Mattias, Meisl, Georg, Hansson, Oskar, Andreasson, Ulf, Zetterberg, Henrik, Blennow, Kaj, Frohm, Birgitta, Cedervall, Tommy, Knowles, Tuomas P. J., Leiding, Thom, and Linse, Sara

Subjects
CEREBROSPINAL fluid, AUTOCATALYSIS, ALZHEIMER'S disease, NUCLEATION, PEPTIDES
Abstract

Alzheimer's disease is linked to amyloid β (Aβ) peptide aggregation in the brain, and a detailed understanding of the molecular mechanism of Aβ aggregation may lead to improved diagnostics and therapeutics. While previous studies have been performed in pure buffer, we approach the mechanism in vivo using cerebrospinal fluid (CSF). We investigated the aggregation mechanism of Aβ42 in human CSF through kinetic experiments at several Aβ42 monomer concentrations (0.8–10 µM). The data were subjected to global kinetic analysis and found consistent with an aggregation mechanism involving secondary nucleation of monomers on the fibril surface. A mechanism only including primary nucleation was ruled out. We find that the aggregation process is composed of the same microscopic steps in CSF as in pure buffer, but the rate constant of secondary nucleation is decreased. Most importantly, the autocatalytic amplification of aggregate number through catalysis on the fibril surface is prevalent also in CSF. Rebecca Frankel, Mattias Törnquist et al. report the aggregation mechanism of Aβ42 in human cerebrospinal fluid in vitro. They find evidence consistent with an aggregation mechanism involving secondary nucleation of monomers on the fibril surface. [ABSTRACT FROM AUTHOR]

Published
2019
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41. Scalable integration of nano-, and microfluidics with hybrid two-photon lithography.

Author

Vanderpoorten, Oliver, Peter, Quentin, Challa, Pavan K., Keyser, Ulrich F., Baumberg, Jeremy, Kaminski, Clemens F., and Knowles, Tuomas P. J.

Abstract

Nanofluidic devices have great potential for applications in areas ranging from renewable energy to human health. A crucial requirement for the successful operation of nanofluidic devices is the ability to interface them in a scalable manner with the outside world. Here, we demonstrate a hybrid two photon nanolithography approach interfaced with conventional mask whole-wafer UV-photolithography to generate master wafers for the fabrication of integrated micro and nanofluidic devices. Using this approach we demonstrate the fabrication of molds from SU-8 photoresist with nanofluidic features down to 230 nm lateral width and channel heights from micron to sub-100 nm. Scanning electron microscopy and atomic force microscopy were used to characterize the printing capabilities of the system and show the integration of nanofluidic channels into an existing microfluidic chip design. The functionality of the devices was demonstrated through super-resolution microscopy, allowing the observation of features below the diffraction limit of light produced using our approach. Single molecule localization of diffusing dye molecules verified the successful imprint of nanochannels and the spatial confinement of molecules to 200 nm across the nanochannel molded from the master wafer. This approach integrates readily with current microfluidic fabrication methods and allows the combination of microfluidic devices with locally two-photon-written nano-sized functionalities, enabling rapid nanofluidic device fabrication and enhancement of existing microfluidic device architectures with nanofluidic features. Nanoengineering: Flexible production of micro- and nanofluidic devices A laser-based manufacturing process can produce combined nanofluidic and microfluidic devices in a rapid and scalable manner. Nanofluidic devices allow for the observation of biological processes at the single-molecule level, but current fabrication methods are slow and costly. In this article, Tuomas Knowles and his team from the UK's University of Cambridge used conventional light-blocking masks and laser technology to craft a light-sensitive material into devices with micron to nano-sized channels. The researchers used microscopy and single-molecule tracking of dyes to verify the functionality of the final imprinted device, which also demonstrates the integration of nanofluidic channels into existing microfluidics designs. The team says that further research may optimize their new platform, which they hope will offer a reliable and flexible pathway for nanofluidic device fabrication. [ABSTRACT FROM AUTHOR]

Published
2019
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42. Rapid two-dimensional characterisation of proteins in solution.

Author

Saar, Kadi L., Peter, Quentin, Müller, Thomas, Challa, Pavan K., Herling, Therese W., and Knowles, Tuomas P. J.

Abstract

Microfluidic platforms provide an excellent basis for working with heterogeneous samples and separating biomolecular components at high throughput, with high recovery rates and by using only very small sample volumes. To date, several micron scale platforms with preparative capabilities have been demonstrated. Here we describe and demonstrate a microfluidic device that brings preparative and analytical operations together onto a single chip and thereby allows the acquisition of multidimensional information. We achieve this objective by using a free-flow electrophoretic separation approach that directs fractions of sample into an on-chip analysis unit, where the fractions are characterised through a microfluidic diffusional sizing process. This combined approach therefore allows simultaneously quantifying the sizes and the charges of components in heterogenous mixtures. We illustrate the power of the platform by describing the size distribution of a mixture comprising components which are close in size and cannot be identified as individual components using state-of-the-art solution sizing techniques on their own. Furthermore, we show that the platform can be used for two-dimensional fingerprinting of heterogeneous protein mixtures within tens of seconds, opening up a possibility to obtain multiparameter data on biomolecular systems on a minute timescale. Microfluidics: 2D fingerprints of heterogenous protein mixtures Microfluidic devices provide a means for analysing heterogenous biomolecular mixtures rapidly, with high recovery rates and by using only very small sample volumes. Yet to date it has remained challenging to combine preparative and analytical processes onto a single chip and thereby fully realise the possibility of fast integrated analysis. Now, a team led by Tuomas Knowles from the University of Cambridge, demonstrates a chip that combines these two steps. Using voltage as the means to separate molecules, Kadi Saar and co-workers size a binary mixture of almost equally sized proteins which cannot be resolved by conventional sizing techniques. In parallel, the team uses the new device to acquire a 2D fingerprint of a heterogeneous protein mixture, opening up the possibility of obtaining multiparameter data on biomolecular systems on a rapid minute timescale. [ABSTRACT FROM AUTHOR]

Published
2019
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43. Different soluble aggregates of Aβ42 can give rise to cellular toxicity through different mechanisms.

Author

De, Suman, Wirthensohn, David C., Flagmeier, Patrick, Hughes, Craig, Aprile, Francesco A., Ruggeri, Francesco S., Whiten, Daniel R., Emin, Derya, Xia, Zengjie, Varela, Juan A., Sormanni, Pietro, Kundel, Franziska, Knowles, Tuomas P. J., Dobson, Christopher M., Bryant, Clare, Vendruscolo, Michele, and Klenerman, David

Abstract

Protein aggregation is a complex process resulting in the formation of heterogeneous mixtures of aggregate populations that are closely linked to neurodegenerative conditions, such as Alzheimer's disease. Here, we find that soluble aggregates formed at different stages of the aggregation process of amyloid beta (Aβ42) induce the disruption of lipid bilayers and an inflammatory response to different extents. Further, by using gradient ultracentrifugation assay, we show that the smaller aggregates are those most potent at inducing membrane permeability and most effectively inhibited by antibodies binding to the C-terminal region of Aβ42. By contrast, we find that the larger soluble aggregates are those most effective at causing an inflammatory response in microglia cells and more effectively inhibited by antibodies targeting the N-terminal region of Aβ42. These findings suggest that different toxic mechanisms driven by different soluble aggregated species of Aβ42 may contribute to the onset and progression of Alzheimer's disease. Amyloid beta (Aβ42) peptides form heterogeneous mixtures of aggregates, which are closely linked to Alzheimer's disease. This study shows how different types of Aβ42 aggregates are associated with distinct mechanisms of toxicity [ABSTRACT FROM AUTHOR]

Published
2019
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44. A method of predicting the in vitro fibril formation propensity of Aβ40 mutants based on their inclusion body levels in E. coli.

Author

Sanagavarapu, Kalyani, Nüske, Elisabeth, Nasir, Irem, Meisl, Georg, Immink, Jasper N., Sormanni, Pietro, Vendruscolo, Michele, Knowles, Tuomas P. J., Malmendal, Anders, Cabaleiro-Lago, Celia, and Linse, Sara

Abstract

Overexpression of recombinant proteins in bacteria may lead to their aggregation and deposition in inclusion bodies. Since the conformational properties of proteins in inclusion bodies exhibit many of the characteristics typical of amyloid fibrils. Based on these findings, we hypothesize that the rate at which proteins form amyloid fibrils may be predicted from their propensity to form inclusion bodies. To establish a method based on this concept, we first measured by SDS-PAGE and confocal microscopy the level of inclusion bodies in E. coli cells overexpressing the 40-residue amyloid-beta peptide, Aβ40, wild-type and 24 charge mutants. We then compared these results with a number of existing computational aggregation propensity predictors as well as the rates of aggregation measured in vitro for selected mutants. Our results show a strong correlation between the level of inclusion body formation and aggregation propensity, thus demonstrating the power of this approach and its value in identifying factors modulating aggregation kinetics. [ABSTRACT FROM AUTHOR]

Published
2019
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45. Microfluidic deposition for resolving single-molecule protein architecture and heterogeneity.

Author

Ruggeri, Francesco Simone, Charmet, Jerome, Kartanas, Tadas, Peter, Quentin, Chia, Sean, Habchi, Johnny, Dobson, Christopher M., Vendruscolo, Michele, and Knowles, Tuomas P. J.

Abstract

Scanning probe microscopy provides a unique window into the morphology, mechanics, and structure of proteins and their complexes on the nanoscale. Such measurements require, however, deposition of samples onto substrates. This process can affect conformations and assembly states of the molecular species under investigation and can bias the molecular populations observed in heterogeneous samples through differential adsorption. Here, we show that these limitations can be overcome with a single-step microfluidic spray deposition platform. This method transfers biological solutions to substrates as microdroplets with subpicoliter volume, drying in milliseconds, a timescale that is shorter than typical diffusion times of proteins on liquid-solid interfaces, thus avoiding surface mass transport and change to the assembly state. Finally, the single-step deposition ensures the attachment of the full molecular content of the sample to the substrate, allowing quantitative measurements of different molecular populations within heterogeneous systems, including protein aggregates. Manual sample deposition on a substrate can introduce artifacts in quantitative AFM measurements. Here the authors present a microfluidic spray device for reliable deposition of subpicoliter droplets which dry out in milliseconds after landing on the surface, thereby avoiding protein self-assembly. [ABSTRACT FROM AUTHOR]

Published
2018
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46. Silk micrococoons for protein stabilisation and molecular encapsulation.

Author

Shimanovich, Ulyana, Ruggeri, Francesco S., De Genst, Erwin, Adamcik, Jozef, Barros, Teresa P., Porter, David, Müller, Thomas, Mezzenga, Raffaele, Dobson, Christopher M., Vollrath, Fritz, Holland, Chris, and Knowles, Tuomas P. J.

Abstract

Naturally spun silks generate fibres with unique properties, including strength, elasticity and biocompatibility. Here we describe a microfluidics-based strategy to spin liquid native silk, obtained directly from the silk gland of Bombyx mori silkworms, into micron-scale capsules with controllable geometry and variable levels of intermolecular β-sheet content in their protein shells. We demonstrate that such micrococoons can store internally the otherwise highly unstable liquid native silk for several months and without apparent effect on its functionality. We further demonstrate that these native silk micrococoons enable the effective encapsulation, storage and release of other aggregation-prone proteins, such as functional antibodies. These results show that native silk micrococoons are capable of preserving the full activity of sensitive cargo proteins that can aggregate and lose function under conditions of bulk storage, and thus represent an attractive class of materials for the storage and release of active biomolecules. [ABSTRACT FROM AUTHOR]

Published
2017
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47. β-Synuclein suppresses both the initiation and amplification steps of α-synuclein aggregation via competitive binding to surfaces.

Author

Brown, James W. P., Buell, Alexander K., Michaels, Thomas C. T., Meisl, Georg, Carozza, Jacqueline, Flagmeier, Patrick, Vendruscolo, Michele, Knowles, Tuomas P. J., Dobson, Christopher M., and Galvagnion, Céline

Abstract

α-Synuclein is an intrinsically disordered protein that is associated with the pathogenesis of Parkinson's disease through the processes involved in the formation of amyloid fibrils. α and β-synuclein are homologous proteins found at comparable levels in presynaptic terminals but β-synuclein has a greatly reduced propensity to aggregate and indeed has been found to inhibit α-synuclein aggregation. In this paper, we describe how sequence differences between α- and β-synuclein affect individual microscopic processes in amyloid formation. In particular, we show that β-synuclein strongly suppresses both lipid-induced aggregation and secondary nucleation of α-synuclein by competing for binding sites at the surfaces of lipid vesicles and fibrils, respectively. These results suggest that β-synuclein can act as a natural inhibitor of α-synuclein aggregation by reducing both the initiation of its self-assembly and the proliferation of its aggregates. [ABSTRACT FROM AUTHOR]

Published
2016
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