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A Semi-Automated Antibody-Discovery Platform to Target Challenging Biomolecules

Lead Research Organisation: Imperial College London
Department Name: Chemistry

Abstract

A major bottleneck in biomedical research is the scarcity of tools to study disease mechanisms directly in their 'true' biological environments, such as in living being, in an accurate manner. A remarkable example of the implications of this technology gap is given by our current understanding of dementia. Dementia is an umbrella term referring to a set of incurable diseases, including Alzheimer's, Parkinson's, and frontotemporal dementia. Altogether, these pathologies currently affect more than 50 million people worldwide. Despite this prevalence of dementia, we still lack effective diagnostic and therapeutic molecules for it because of the sparse information on the pathological mechanisms. A major mechanism of dementia is the formation of protein clusters in the nervous system, which are associated with cellular death. Over the last two decades, researchers have focused on understanding protein clustering under highly controlled experimental conditions using proteins in isolation (in vitro approaches). These accurate studies have contributed to the understanding of the physical laws that regulate protein clustering; nevertheless, they have also provided an overly simplistic picture of the clustering mechanism. They did not account for the many events in the nervous system, as proven by the fact that protein clusters isolated from patients are heavily chemically modified and tightly associated with other biomolecules, including nucleic acids.

Because of their specific binding to targets, antibodies represent a fast-growing class of protein drugs and find a wide application as probes in biomedical research. Antibodies allow scientists to bridge highly precise in vitro measurements with the use of highly complex biological samples. Nevertheless, despite their potential, the use of antibodies is still hindered by challenges associated with their production. Antibody discovery can be a lengthy and costly procedure. Furthermore, several biomolecules, such as chemically modified proteins, protein clusters, and nucleic acids, are challenging to target with standard antibody-discovery approaches, despite these biomolecules being highly prevalent in diseases, e.g., dementia. The goal of this project is to deliver an innovative, generally applicable antibody-discovery technology able to target protein clusters which are chemically modified or in complex with other biomolecules, such as nucleic acids. To achieve our goal, we will work on two systems, the protein FUS and the transactive response DNA-binding protein 43 (TDP-43), involved in amyotrophic lateral sclerosis, frontotemporal dementia and Alzheimer's disease. Both proteins have been reported to undergo several types of chemical modifications and to bind to different RNA molecules. We will develop antibodies using our integrative discovery platform with the addition of a semi-automated screening component to target clusters of the proteins of interest carrying chemical modifications and/or in complex with RNAs associated with the disease. Thus, we will use the antibodies to monitor the distribution of the protein-RNA aggregates in human tissue. Our results will provide novel information on these diseases and lead to a generally applicable time- and cost-effective antibody-discovery technology to produce antibodies against biomolecules beyond proteins.
 
Description Over the first year of the extension period, we have made significant advancements in antibody discovery and protein aggregation research. Our efforts have focused on developing new methods, enhancing the screening capabilities of our antibody discovery platform, and broadening the scope of our investigations. Below are the key areas where we have made notable progress.

1. New Methods for Antibody Discovery
One of our major achievements has been the development of innovative techniques for discovering antibodies. Antibodies are essential tools in medicine and research, as they can bind to specific targets, such as proteins, to detect or neutralise them in disease. Traditionally, producing antibodies for certain protein shapes has been challenging. To overcome this, we have integrated advanced computational design strategies with functional screening approaches. This allows us to generate antibodies capable of targeting a wider range of protein structures more effectively. These advancements improve the precision and versatility of antibody discovery, with potential applications in diagnostics, therapeutics, and fundamental biological research.

2. Expanding the Range of Antibody Targets
In addition to refining our methods, we have also broadened the scope of our antibody research. While our previous efforts primarily focused on individual protein systems, many essential biological processes rely on complex molecular interactions. These include proteins that interact with lipid membranes and nucleic acids, which play crucial roles in cell function, communication, and disease progression. To deepen our understanding of these intricate systems, we have begun characterising key targets, including TDP-43, a protein linked to neurodegenerative diseases such as amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). Our initial studies have focused on characterising its interactions with lipid membranes. Understanding these interactions could provide valuable insights into disease mechanisms and potential therapeutic strategies.

3. Development of Fluorescent Probes for Protein Clustering
Protein clustering is a key pathological mechanism in various diseases, yet detecting these clusters has been challenging. To address this, we have developed new fluorescent probes that can sense protein clustering based on changes in local viscosity. Viscosity refers to how thick or fluid a substance is. In this case, our probes detect an increase in local viscosity when proteins cluster together. This innovative approach enables researchers to study protein aggregation in real time, providing crucial insights into disease progression and potential intervention strategies.
Exploitation Route These outcomes can be used across research, diagnostics, and treatment development. The new methods for antibody discovery can help researchers and biotech companies create antibodies for difficult-to-target proteins. They can also be used to find treatments for new diseases, improve efficiency, and work alongside computational methods to make antibody discovery more precise.
Expanding the range of antibody targets will support further research into diseases like ALS and FTD by studying the protein TDP-43. It can also help scientists understand how proteins interact with cell membranes and nucleic acids, leading to new treatments for various diseases.
The fluorescent probes for protein clustering can improve disease diagnosis, real-time imaging, and drug screening. Scientists can refine them to be more accurate and use them to study diseases like Alzheimer's and Parkinson's, where protein clusters play a key role.
These discoveries can be shared through research collaborations or licensing agreements to be used more widely. They can also be applied to other scientific fields, such as synthetic biology and bioengineering. By building on these findings, others can help develop new treatments, diagnostic tools, and a better understanding of diseases.
Sectors Chemicals

Healthcare

Pharmaceuticals and Medical Biotechnology
 
Description Our discoveries have the potential to make a significant impact beyond Academia. In particular, we are focused on maximising the translational applications of our research outcomes, such as methods and molecules. We have been discussing opportunities to collaborate and joint research projects with biotech companies. At the same time, we are exploring the possibility of launching a startup to further develop and commercialise our technologies. Additionally, our insights into antibody discovery for dementia have gained attention in the media (https://www.eurekalert.org/news-releases/1073534, https://www.newswise.com/articles/new-antibody-discovery-platform-can-inform-alzheimer-s-and-parkinson-s, https://www.biophysics.org/news-room?ArtMID=802&ArticleID=16512?view=true) and have supported charities in their fundraising efforts, helping to raise awareness and drive further investment in dementia research and care.
First Year Of Impact 2024
Sector Chemicals,Healthcare,Manufacturing, including Industrial Biotechology,Pharmaceuticals and Medical Biotechnology
Impact Types Societal
 
Description Research Project Grant
Amount £393,668 (GBP)
Funding ID RPG-2023-147 
Organisation The Leverhulme Trust 
Sector Charity/Non Profit
Country United Kingdom
Start 02/2024 
End 01/2027
 
Title A microscopy method to investigate protein liquid-liquid phase separation kinetics 
Description We have developed a microscopy approach to investigate protein liquid-liquid phase separation (LLPS) in real time. This method can be used to characterize protein LLPS and to screen the effects of molecules or modifications that alter the process. 
Type Of Material Technology assay or reagent 
Year Produced 2024 
Provided To Others? Yes  
Impact This method has enabled us to understand the effect of protein post-translational modifications on the LLPS of a-synuclein, a protein associated with Parkinson's disease. 
URL https://www.biorxiv.org/content/10.1101/2024.06.06.597302v3
 
Title Fluorescent molecules to investigate protein oligomers 
Description We have developed an approach using fluorescent molecules to investigate the microviscosity of the protein environment and gain insight into its oligomeric state. We have applied this method to study the self-assembly process of the protein alpha-synuclein. 
Type Of Material Technology assay or reagent 
Year Produced 2025 
Provided To Others? Yes  
Impact We have published a research paper which is available the the Doing below. 
URL https://pubs.acs.org/doi/10.1021/acsami.4c21710
 
Title Source data supporting: Allerton et al. _Molecular Rotors Detect the Formation and Conversion of a-Synuclein Oligomers 
Description This dataset includes all raw data (main text and Supplementary Information) for the study titled "Molecular Rotors Detect the Formation and Conversion of a-Synuclein Oligomers", Allerton et al. It includes individual fluorescence lifetime decay data along with corresponding phasor coordinates, raw intensity aggregation assay plots, dynamic light scattering (DLS) data, mass spectrometry (MS) data, transmission electron microscopy (TEM) images, western blot membrane images and SDS-PAGE gel images. 
Type Of Material Database/Collection of data 
Year Produced 2025 
Provided To Others? Yes  
Impact This dataset is linked to the research paper "Molecular Rotors Detect the Formation and Conversion of a-Synuclein Oligomers". In this paper, we propose a novel approach using molecular rotor lifetime to investigate protein aggregation. 
URL https://zenodo.org/doi/10.5281/zenodo.13951259
 
Description TDP43 variants - lipid membranes interaction in neuro-degenerative disorders 
Organisation Institut Laue–Langevin
Department ILL Neutrons for Society
Country France 
Sector Academic/University 
PI Contribution The project aims to understand how the protein TDP-43 interacts with lipid membranes. TDP-43 is involved in amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). This interaction has only recently been documented in the context of extracellular vesicles. As part of this collaboration, we have provided different variants of TDP-43, conducted neutron measurements of these proteins in the presence of lipid membranes, and analysed and interpreted the data.
Collaborator Contribution Our collaborators have provided reagents and support in performing neutron reflectometry experiments and data analysis.
Impact This is a multidisciplinary project which combines biochemistry, chemical biology, and physical chemistry. A dataset is available at https://doi.ill.fr/10.5291/ILL-DATA.8-02-1017
Start Year 2024
 
Description EDI Co-director of the Department of Chemistry, Imperial College London 
Form Of Engagement Activity A formal working group, expert panel or dialogue
Part Of Official Scheme? No
Geographic Reach International
Primary Audience Other audiences
Results and Impact As EDI co-director, I coordinate activities (such as training and events) and influence policy to ensure that the EDI values are embraced by our department and all staff and students feel welcome and respected.
Year(s) Of Engagement Activity 2023,2024
 
Description Press release by the Biophysical Society for their Annual Meeting 2025 
Form Of Engagement Activity A press release, press conference or response to a media enquiry/interview
Part Of Official Scheme? No
Geographic Reach International
Primary Audience Other audiences
Results and Impact I collaborated with the Communication Office of the Biophysical Society for a press release about my presentation at their annual meeting in February 2025.
Year(s) Of Engagement Activity 2024
URL https://www.biophysics.org/news-room?ArtMID=802&ArticleID=16512&preview=true
 
Description Saturday Science Club at Imperial College London 
Form Of Engagement Activity Participation in an activity, workshop or similar
Part Of Official Scheme? No
Geographic Reach Local
Primary Audience Public/other audiences
Results and Impact I participated to a hands-on workshop organised by the Public Engagement Team of Imperial College. The activity aims to engage with the local London community. During this workshop, I use hands-on experiments to make slime, explaining molecules and polymers to children and families to spark their interest in chemistry and science in general.
Year(s) Of Engagement Activity 2024