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1,553 results on '"Knowles, Tuomas P. J."'

1. Learning the rules of peptide self-assembly through data mining with large language models

Author

Yang, Zhenze, Yorke, Sarah K., Knowles, Tuomas P. J., and Buehler, Markus J.

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Mesoscale and Nanoscale Physics, Computer Science - Artificial Intelligence, Computer Science - Computation and Language
Abstract

Peptides are ubiquitous and important biologically derived molecules, that have been found to self-assemble to form a wide array of structures. Extensive research has explored the impacts of both internal chemical composition and external environmental stimuli on the self-assembly behaviour of these systems. However, there is yet to be a systematic study that gathers this rich literature data and collectively examines these experimental factors to provide a global picture of the fundamental rules that govern protein self-assembly behavior. In this work, we curate a peptide assembly database through a combination of manual processing by human experts and literature mining facilitated by a large language model. As a result, we collect more than 1,000 experimental data entries with information about peptide sequence, experimental conditions and corresponding self-assembly phases. Utilizing the collected data, ML models are trained and evaluated, demonstrating excellent accuracy (>80\%) and efficiency in peptide assembly phase classification. Moreover, we fine-tune our GPT model for peptide literature mining with the developed dataset, which exhibits markedly superior performance in extracting information from academic publications relative to the pre-trained model. We find that this workflow can substantially improve efficiency when exploring potential self-assembling peptide candidates, through guiding experimental work, while also deepening our understanding of the mechanisms governing peptide self-assembly. In doing so, novel structures can be accessed for a range of applications including sensing, catalysis and biomaterials.

Published
2024

2. Competing addition processes give distinct growth regimes in the assembly of 1D filaments

Author

Akram, Sk Ashif, Brown, Tyler, Whitelam, Stephen, Meisl, Georg, Knowles, Tuomas P. J., and Schmit, Jeremy D.

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

We present a model to describe the concentration-dependent growth of protein filaments. Our model contains two states, a low entropy/high affinity ordered state and a high entropy/low affinity disordered state. Consistent with experiments, our model shows a diffusion-limited linear growth regime at low concentration, followed by a concentration independent plateau at intermediate concentrations, and rapid disordered precipitation at the highest concentrations. We show that growth in the linear and plateau regions is the result of two processes that compete amid the rapid binding and unbinding of non-specific states. The first process is the addition of ordered molecules during the periods where the end of the filament is free of incorrectly bound molecules. The second process is the capture of defects, which occurs when consecutive ordered additions occur on top of incorrectly bound molecules. We show that a key molecular property is the probability that a diffusive collision results in a correctly bound state. Small values of this probability suppress the defect capture growth mode, resulting in a plateau in the growth rate when incorrectly bound molecules become common enough to poison ordered growth. We show that conditions that non-specifically suppress or enhance intermolecular interactions, such as the addition of depletants or osmolytes, have opposite effects on the growth rate in the linear and plateau regimes. In the linear regime stronger interactions promote growth by reducing dissolution events, but in the plateau regime stronger interactions inhibit growth by stabilizing incorrectly bound molecules., Comment: 20 pages, 7 figures

Published
2024

3. Design of amyloidogenic peptide traps

Author

Sahtoe, Danny D., Andrzejewska, Ewa A., Han, Hannah L., Rennella, Enrico, Schneider, Matthias M., Meisl, Georg, Ahlrichs, Maggie, Decarreau, Justin, Nguyen, Hannah, Kang, Alex, Levine, Paul, Lamb, Mila, Li, Xinting, Bera, Asim K., Kay, Lewis E., Knowles, Tuomas P. J., and Baker, David

Published
2024
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6. Single-molecule digital sizing of proteins in solution

Author

Krainer, Georg, Jacquat, Raphael P. B., Schneider, Matthias M., Welsh, Timothy J., Fan, Jieyuan, Peter, Quentin A. E., Andrzejewska, Ewa A., Šneiderienė, Greta, Czekalska, Magdalena A., Ausserwoeger, Hannes, Chai, Lin, Arter, William E., Saar, Kadi L., Herling, Therese W., Franzmann, Titus M., Kosmoliaptsis, Vasilis, Alberti, Simon, Hartl, F. Ulrich, Lee, Steven F., and Knowles, Tuomas P. J.

Published
2024
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7. 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.

Published
2024
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8. 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., Nielsen, Morten Agertoug, Sander, Adam F., Romero-Ramos, Marina, and Otzen, Daniel E.

Published
2024
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17. 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.

Published
2023
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18. Hamiltonian Dynamics of Saturated Elongation in Amyloid Fiber Formation

Author

Hong, Liu, Liu, Xizhou, Michaels, Thomas C. T., and Knowles, Tuomas P. J.

Subjects
Quantitative Biology - Quantitative Methods, Physics - Biological Physics, Quantitative Biology - Biomolecules
Abstract

Elongation is a fundament process in amyloid fiber growth, which is normally characterized by a linear relationship between the fiber elongation rate and the monomer concentration. However, in high concentration regions, a sub-linear dependence was often observed, which could be explained by a universal saturation mechanism. In this paper, we modeled the saturated elongation process through a Michaelis-Menten like mechanism, which is constituted by two sub-steps -- unspecific association and dissociation of a monomer with the fibril end, and subsequent conformational change of the associated monomer to fit itself to the fibrillar structure. Typical saturation concentrations were found to be $7-70\mu M$ for A$\beta$40, $\alpha$-synuclein and etc. Furthermore, by using a novel Hamiltonian formulation, analytical solutions valid for both weak and strong saturated conditions were constructed and applied to the fibrillation kinetics of $\alpha$-synuclein and silk fibroin., Comment: 15 pages, 4 figures

Published
2020

19. Deformable and robust core-shell protein microcapsules templated by liquid-liquid phase separated microdroplets

Author

Xu, Yufan, Shen, Yi, Michaels, Thomas C. T., Baumann, Kevin N., Vigolo, Daniele, Peter, Quentin, Lu, Yuqian, Saar, Kadi L., Vella, Dominic, Zhu, Hongjia, Li, Bing, Yang, He, Guttenplan, Alexander P. M., Rodriguez-Garcia, Marc, Klenerman, David, and Knowles, Tuomas P. J.

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Biological Physics
Abstract

Microcapsules are a key class of microscale materials with applications in areas ranging from personal care to biomedicine, and with increasing potential to act as extracellular matrix (ECM) models of hollow organs or tissues. Such capsules are conventionally generated from non-ECM materials including synthetic polymers. Here, we fabricated robust microcapsules with controllable shell thickness from physically- and enzymatically-crosslinked gelatin and achieved a core-shell architecture by exploiting a liquid-liquid phase separated aqueous dispersed phase system in a one-step microfluidic process. Microfluidic mechanical testing revealed that the mechanical robustness of thicker-shell capsules could be controlled through modulation of the shell thickness. Furthermore, the microcapsules demonstrated environmentally-responsive deformation, including buckling by osmosis and external mechanical forces. A sequential release of cargo species was obtained through the degradation of the capsules. Stability measurements showed the capsules were stable at 37 {\deg}C for more than two weeks. Finally, all-aqueous liquid-liquid phase separated and multiphase liquid-liquid phase separated systems were generated with the gel-sol transition of microgel precursors. These smart capsules are promising models of hollow biostructures, microscale drug carriers, and building blocks or compartments for active soft materials and robots., Comment: 51 pages (main text + supplementary information), 5 figures (main text), 20 figures (sppl info), 1 table (sppl info)

Published
2020

21. Top-down proteomics on a microfluidic platform

Author

Zhang, Yuewen, Wright, Maya A., Challa, Pavan K., Saar, Kadi-Liis, Devenish, Sean, Peter, Quentin, and Knowles, Tuomas P. J.

Subjects
Physics - Biological Physics, Quantitative Biology - Biomolecules
Abstract

Protein identification and profiling is critical for the advancement of cell and molecular biology as well as medical diagnostics. Although mass spectrometry and protein microarrays are commonly used for protein identification, both methods require extensive experimental steps and long data analysis times. Here we present a microfluidic top down proteomics platform giving multidimensional read outs of the essential amino acids of proteins. We obtain hydrodynamic radius and fluorescence signals relating to the content of tryptophans, tyrosines and lysines of proteins using a combination of diffusional sizing of proteins, label-free detection and on-chip labelling of proteins with a latent fluorophore in the solution phase. We thereby achieve identification of proteins on a single microfluidic chip by separating and mapping proteins in multidimensional space based on their characteristic physical parameters. Our results have significant implications in the development of easy and rapid platforms to use for native protein identification in clinical and laboratory settings., Comment: 17 pages, 3 figures

Published
2019

23. Reaction rate theory for supramolecular kinetics: application to protein aggregation

Author

Michaels, Thomas C. T., Liu, Lucie X., Curk, Samo, Bolhuis, Peter G., Saric, Andela, and Knowles, Tuomas P. J.

Subjects
Physics - Biological Physics, Quantitative Biology - Biomolecules
Abstract

Probing the reaction mechanisms of supramolecular processes in soft- and biological matter, such as protein aggregation, is inherently challenging. These processes emerge from the simultaneous action of multiple molecular mechanisms, each of which is associated with the rearrangement of a large number of weak bonds, resulting in a complex free energy landscape with many kinetic barriers. Reaction rate measurements of supramolecular processes at different temperatures can offer unprecedented insights into the underlying molecular mechanisms and their thermodynamic properties. However, to be able to interpret such measurements in terms of the underlying microscopic mechanisms, a key challenge is to establish which properties of the complex free energy landscapes are probed by the reaction rate. Here, we present a reaction rate theory for supramolecular kinetics based on Kramers rate theory for diffusive reactions over multiple kinetic barriers, and apply the results to protein aggregation. Using this framework and Monte Carlo simulations, we show that reaction rates for protein aggregation are of the Arrhenius-Eyring type and that the associated activation energies probe only one relevant barrier along the respective free energy landscapes. We apply this advancement to interpret, both in experiments and in coarse-grained computer simulations, reaction rate measurements of amyloid aggregation kinetics in terms of the underlying molecular mechanisms and associated thermodynamic signatures. Our results establish a general platform for probing the mechanisms and energetics of supramolecular phenomena in soft- and biological matter using the framework of chemical kinetics.

Published
2018
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30. DNA-coated Functional Oil Droplets

Author

Caciagli, Alessio, Zupkauskas, Mykolas, Levin, Aviad, Knowles, Tuomas P. J., Mugemana, Clément, Bruns, Nico, O'Neill, Thomas, Frith, William J., and Eiser, Erika

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

Many industrial soft materials often include oil-in-water (O/W) emulsions at the core of their formulations. By using tuneable interface stabilizing agents, such emulsions can self-assemble into complex structures. DNA has been used for decades as a thermoresponsive highly specific binding agent between hard and, recently, soft colloids. Up until now, emulsion droplets functionalized with DNA had relatively low coating densities and were expensive to scale up. Here a general O/W DNA-coating method using functional non-ionic amphiphilic block copolymers, both diblock and triblock, is presented. The hydrophilic polyethylene glycol ends of the surfactants are functionalized with azides, allowing for efficient, dense and controlled coupling of dibenzocyclooctane functionalized DNA to the polymers through a strain-promoted alkyne-azide click reaction. The protocol is readily scalable due to the triblock's commercial availability. Different production methods (ultrasonication, microfluidics and membrane emulsification) are used with different oils (hexadecane and silicone oil) to produce functional droplets in various size ranges (sub-micron, $\sim 20\,\mathrm{\mu m}$ and $> 50\,\mathrm{\mu m}$), showcasing the generality of the protocol. Thermoreversible sub-micron emulsion gels, hierarchical "raspberry" droplets and controlled droplet release from a flat DNA-coated surface are demonstrated. The emulsion stability and polydispersity is evaluated using dynamic light scattering and optical microscopy. The generality and simplicity of the method opens up new applications in soft matter and biotechnological research and industrial advances., Comment: 7 pages, 2 figures, 1 table

Published
2017
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37. Biomolecular condensates sustain pH gradients at equilibrium driven by charge neutralisation

Author

Ausserwöger, Hannes, primary, Scrutton, Rob, additional, Sneideris, Tomas, additional, Fischer, Charlotte M., additional, Qian, Daoyuan, additional, de Csilléry, Ella, additional, Saar, Kadi L., additional, Białek, Alan Z., additional, Oeller, Marc, additional, Krainer, Georg, additional, Franzmann, Titus M., additional, Wittmann, Sina, additional, Iglesias-Artola, Juan M., additional, Invernizzi, Gaetano, additional, Hyman, Anthony A., additional, Alberti, Simon, additional, Lorenzen, Nikolai, additional, and Knowles, Tuomas P. J., additional

Published
2024
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43. Rational design of a conformation-specific antibody for the quantification of Aβ oligomers

Author

Aprile, Francesco A., Sormanni, Pietro, Podpolny, Marina, Chhangur, Shianne, Needham, Lisa-Maria, Ruggeri, Francesco S., Perni, Michele, Limbocker, Ryan, Heller, Gabriella T., Sneideris, Tomas, Scheidt, Tom, Mannini, Benedetta, Habchi, Johnny, Lee, Steven F., Salinas, Patricia C., Knowles, Tuomas P. J., Dobson, Christopher M., and Vendruscolo, Michele

Published
2020

44. Kinetic diversity of amyloid oligomers

Author

Dear, Alexander J., Michaels, Thomas C. T., Meisl, Georg, Klenerman, David, Wu, Si, Perrett, Sarah, Linse, Sara, Dobson, Christopher M., and Knowles, Tuomas P. J.

Published
2020

46. Kinetics of spontaneous filament nucleation via oligomers: insights from theory and simulation

Author

Šarić, Anđela, Michaels, Thomas C. T., Zaccone, Alessio, Knowles, Tuomas P. J., and Frenkel, Daan

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Biological Physics, Quantitative Biology - Biomolecules
Abstract

Nucleation processes are at the heart of a large number of phenomena, from cloud formation to protein crystallization. A recently emerging area where nucleation is highly relevant is the initiation of filamentous protein self-assembly, a process that has broad implications from medicine to nanotechnology. As such, spontaneous nucleation of protein fibrils has received much attention in recent years with many theoretical and experimental studies focussing on the underlying physical principles. In this paper we make a step forward in this direction and explore the early time behaviour of filamentous protein growth in the context of nucleation theory. We first provide an overview of the thermodynamics and kinetics of spontaneous nucleation of protein filaments in the presence of one relevant degree of freedom, namely the cluster size. In this case, we review how key kinetic observables, such as the reaction order of spontaneous nucleation, are directly related to the physical size of the critical nucleus. We then focus on the increasingly prominent case of filament nucleation that includes a conformational conversion of the nucleating building-block as an additional slow step in the nucleation process. Using computer simulations, we study the concentration dependence of the nucleation rate. We find that, under these circumstances, the reaction order of spontaneous nucleation with respect to the free monomer does no longer relate to the overall physical size of the nucleating aggregate but rather to the portion of the aggregate that actively participates in the conformational conversion. Our results thus provide a novel interpretation of the common kinetic descriptors of protein filament formation, including the reaction order of the nucleation step or the scaling exponent of lag times, and put into perspective current theoretical descriptions of protein aggregation.

Published
2016
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47. Intra-chain organisation of hydrophobic residues controls inter-chain aggregation rates of amphiphilic polymers

Author

Varilly, Patrick, Willard, Adam P., Kirkegaard, Julius B., Knowles, Tuomas P. J., and Chandler, David

Subjects
Physics - Biological Physics, Condensed Matter - Soft Condensed Matter, Quantitative Biology - Biomolecules
Abstract

Aggregation of amphiphiles through the action of hydrophobic interactions is a common feature in soft condensed matter systems and is of particular importance in the context of biophysics as it underlies both the generation of functional biological machinery as well as the formation of pathological misassembled states of proteins. Here we explore the aggregation behaviour of amphiphilic polymers using lattice Monte-Carlo calculations and show that the distribution of hydrophobic residues within the polymer sequence determines the facility with which dry/wet interfaces can be created and that such interfaces drive the aggregation process.

Published
2016
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48. A general reaction network unifies the aggregation behaviour of the A$\beta$42 peptide and its variants

Author

Meisl, Georg, Yang, Xiaoting, Dobson, Christopher M., Linse, Sara, and Knowles, Tuomas P. J.

Subjects
Quantitative Biology - Molecular Networks, Quantitative Biology - Biomolecules
Abstract

The amyloid $\beta$ peptide (A$\beta$42), whose aggregation is associated with Alzheimer's disease, is an amphiphatic peptide with a high propensity to self-assemble. A$\beta$42 has a net negative charge at physiological pH and modulations of intermolecular electrostatic interactions can significantly alter its aggregation behaviour. Variations in sequence and solution conditions lead to varied macroscopic behaviour, often resulting in a number of different mechanistic explanations for the aggregation of these closely related systems. Here we alter the electrostatic interactions governing the fibril aggregation kinetics by varying the ionic strength over an order of magnitude, which allows us to sample the space of different reaction mechanisms, and develop a minimal reaction network that explains the experimental kinetics under all the different conditions. We find that an increase in the ionic strength leads to an increased rate of surface catalysed nucleation over fragmentation and eventually to a saturation of this nucleation process. More generally, this reaction network connects previously separate systems, such as mutants of A$\beta$42 and the wild type, on a continuous mechanistic landscape, thereby providing a unified picture of the aggregation mechanism of A$\beta$42 and the means of directly comparing the effects of intrinsic modifications of the peptide to those of simple electrostatic shielding.

Published
2016
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