Professor Tuomas Knowles

Professor of Physical Chemistry and Biophysics

1920 Professor of Physical Chemistry

Our research

We study the physical and chemical aspects of the behaviour of biopolymers and other soft systems. Much of our work has been focused on the physical aspects underlying the self-assembly of protein molecules. Self-organisation is the driving force generating complex matter in nature, and the process by which the machinery providing functionality in living systems is assembled. The goal of our research is to understand the physical and chemical factors which control the structures and dynamics of biomolecular assemblies, and the connections between the nanoscale characteristics of the component molecules and the physical properties of large-scale assemblies and their behaviour on a mesoscopic to macroscopic scale. The techniques used in our laboratory include biosensors, optical lithography, microfluidic devices and scanning probe microscopy and spectroscopy. We work both with natural and synthetic polymers and our interests range from fundamental chemical physics to technological applications in material science and molecular medicine.

Watch Professor Knowles discuss his research

Take a tour of the Sir Rodney Sweetnam laboratory

Publications

DNA-Coated Functional Oil Droplets.

A Caciagli, M Zupkauskas, A Levin, TPJ Knowles, C Mugemana, N Bruns, T O'Neill, WJ Frith, E Eiser

Langmuir

(2018)

10073

(doi: 10.1021/acs.langmuir.8b01828)

Self-Assembly-Mediated Release of Peptide Nanoparticles through Jets Across Microdroplet Interfaces.

A Levin, TCT Michaels, TO Mason, T Müller, L Adler-Abramovich, L Mahadevan, ME Cates, E Gazit, TPJ Knowles

ACS Applied Materials & Interfaces

(2018)

27578

(doi: 10.1021/acsami.8b09511)

Combining Affinity Selection and Specific Ion Mobility for Microchip Protein Sensing.

WE Arter, J Charmet, J Kong, KL Saar, TW Herling, T Müller, UF Keyser, TPJ Knowles

Anal Chem

(2018)

10302

(doi: 10.1021/acs.analchem.8b02051)

Massively parallel C. elegans tracking provides multi-dimensional fingerprints for phenotypic discovery.

M Perni, PK Challa, JB Kirkegaard, R Limbocker, M Koopman, MC Hardenberg, P Sormanni, T Müller, KL Saar, LWY Roode, J Habchi, G Vecchi, N Fernando, S Casford, EAA Nollen, M Vendruscolo, CM Dobson, TPJ Knowles

J Neurosci Methods

(2018)

306

(doi: 10.1016/j.jneumeth.2018.02.005)

Conserved S/T Residues of the Human Chaperone DNAJB6 Are Required for Effective Inhibition of Aβ42 Amyloid Fibril Formation.

C Månsson, RTP van Cruchten, U Weininger, X Yang, R Cukalevski, P Arosio, CM Dobson, T Knowles, M Akke, S Linse, C Emanuelsson

Biochemistry

(2018)

4891

(doi: 10.1021/acs.biochem.8b00353)

O2‐02‐02: TARGETING AMYLOID FORMATION USING RATIONALLY DESIGNED ANTIBODIES

FA Aprile, P Sormanni, M Perni, P Arosio, R Limbocker, S Chhangur, B Mannini, S Linse, T Knowles, CM Dobson, M Vendruscolo

Alzheimer's & Dementia

(2018)

p611

(doi: 10.1016/j.jalz.2018.06.2646)

Multistep Inhibition of α-Synuclein Aggregation and Toxicity in Vitro and in Vivo by Trodusquemine.

M Perni, P Flagmeier, R Limbocker, R Cascella, FA Aprile, C Galvagnion, GT Heller, G Meisl, SW Chen, JR Kumita, PK Challa, JB Kirkegaard, SIA Cohen, B Mannini, D Barbut, EAA Nollen, C Cecchi, N Cremades, TPJ Knowles, F Chiti, M Zasloff, M Vendruscolo, CM Dobson

ACS Chem Biol

(2018)

2308

(doi: 10.1021/acschembio.8b00466)