MICA - Developing novel single-cell multiplexing methods to identify drug targets for the treatment of multiple myeloma
Lead Research Organisation:
University of Oxford
Department Name: Botnar Research Centre
Abstract
Multiple Myeloma is a bone marrow cancer that affects over 5,700 new patients a year in the UK. Current response rates to treatment are varied and there is a mean survival age of only 4-5 years, with a 10-year survival rate of only ~3%. A significant proportion of treatment failure is due to the emergence of multi-drug resistance, which arise because of changes (mutations) in the nucleotides that form the building blocks of our DNA. RNA is a type of DNA and mostly acts as a messenger to carry out the instructions of DNA. Epigenetics is the addition of information on top of the DNA sequence that can modify the behaviour of a cell. This is achieved by adding a variety of chemical modifications or "marks" to the nucleotides.
Historically, scientists have investigated complex disease biology by mashing up pieces of tissue and taking biological measurements to work out the causes of disease. This is akin to blending fruit into a smoothie and then giving it to someone else to work out the ingredients by looking through the glass. Some fruit may be easy to identify, while others may be impossible to recognise. More recently, scientists have developed technologies that have allowed us to reconstruct the smoothie more easily by looking at its individual parts in finer detail. These "single-cell" technologies allow us to look at the components of the tissue one cell at a time and permit us to work out what may be causing disease. With this information we can design better drugs that target disease. In this fellowship, I will develop novel single-cell technology that are capable of capturing many more biological readouts than previously possible with currently technologies. This technology will then be applied to understand DNA, RNA and epigenetic mechanisms that contribute to the development of a bone cancer called Multiple Myeloma (MM).
In partnership with a biotechnology company, I have developed such a technology within in my lab that is capable of measuring RNA and DNA simultaneously from the same single cell. The first aim of this fellowship will be to extend the utility of this technology so that I can increase the different types of measurements that are possible. For example, I will develop a method that makes it possible to measure both RNA and the epigenetic marks on the DNA. Next, I will use this technology to investigate MM disease.
Specifically, I will ask the following questions:
1) why do patients develop MM? and
2) why do patients develop resistance to current clinical therapies?
Ultimately, the main goal of my research is to better understand MM disease biology so we can develop new medicines to treat this incurable disease.
In order to work out why drug resistance occurs we need to make sense of the patterns of data that are generated using our single-cell technologies. Given the large amount of data generated during this project, I will use my skills as a software developer to generate computer code that will automate this process. Ultimately, outputs from this code will allow me to generate a map of disease that I can then use to identify drug targets for treating MM patients.
Why does this project have a greater chance of success?
Very few methods have been developed that can look at more than one biological measurement simultaneously. The assays that I will develop during this fellowship, which are based on our unique single-cell technology, will provide and unparalleled understanding of the complex mechanisms that contribute to the development of MM and drug resistance. This timely technology will allow me to identify novel drug targets for MM, which will then be followed up in pre-clinical models within the Oxford Centre for Multiple Myeloma Research and ultimately translated towards the clinic.
Historically, scientists have investigated complex disease biology by mashing up pieces of tissue and taking biological measurements to work out the causes of disease. This is akin to blending fruit into a smoothie and then giving it to someone else to work out the ingredients by looking through the glass. Some fruit may be easy to identify, while others may be impossible to recognise. More recently, scientists have developed technologies that have allowed us to reconstruct the smoothie more easily by looking at its individual parts in finer detail. These "single-cell" technologies allow us to look at the components of the tissue one cell at a time and permit us to work out what may be causing disease. With this information we can design better drugs that target disease. In this fellowship, I will develop novel single-cell technology that are capable of capturing many more biological readouts than previously possible with currently technologies. This technology will then be applied to understand DNA, RNA and epigenetic mechanisms that contribute to the development of a bone cancer called Multiple Myeloma (MM).
In partnership with a biotechnology company, I have developed such a technology within in my lab that is capable of measuring RNA and DNA simultaneously from the same single cell. The first aim of this fellowship will be to extend the utility of this technology so that I can increase the different types of measurements that are possible. For example, I will develop a method that makes it possible to measure both RNA and the epigenetic marks on the DNA. Next, I will use this technology to investigate MM disease.
Specifically, I will ask the following questions:
1) why do patients develop MM? and
2) why do patients develop resistance to current clinical therapies?
Ultimately, the main goal of my research is to better understand MM disease biology so we can develop new medicines to treat this incurable disease.
In order to work out why drug resistance occurs we need to make sense of the patterns of data that are generated using our single-cell technologies. Given the large amount of data generated during this project, I will use my skills as a software developer to generate computer code that will automate this process. Ultimately, outputs from this code will allow me to generate a map of disease that I can then use to identify drug targets for treating MM patients.
Why does this project have a greater chance of success?
Very few methods have been developed that can look at more than one biological measurement simultaneously. The assays that I will develop during this fellowship, which are based on our unique single-cell technology, will provide and unparalleled understanding of the complex mechanisms that contribute to the development of MM and drug resistance. This timely technology will allow me to identify novel drug targets for MM, which will then be followed up in pre-clinical models within the Oxford Centre for Multiple Myeloma Research and ultimately translated towards the clinic.
Technical Summary
My goal is to develop novel multiplexed single-cell technologies to identify the mechanisms that contribute to Multiple Myeloma (MM) disease pathology. MM is a cancer of plasma cells in the bone marrow, that due to its rapid proliferative function, can quickly develop resistance to first line proteasome therapy. Currently, the mechanisms that contribute to MM development or drug resistance are poorly understood. A better understanding of the complexity and diversity of the MM bone marrow tumour microenvironment (TME) is required to identify novel treatment targets. Given the cellular heterogeneity within the TME, the TME needs to be studied at the single-cell level. However, current single-cell methods are costly, specialised and most are restricted to measuring only one analyte at a time, typically RNA.
In collaboration with colleagues at a UK biotechnology firm, we have established cost-effective multiplexed single-cell technology that is capable of capturing both RNA and DNA on the same oligonucleotide. This technology therefore enables the measurement of both the transcriptome as well as the accessibility of the chromatin, within the same cell - an important advance in the area of single-cell technology. To realise the full potential of our technology, I will expand its utility to include the multiplexing of transcriptomics with epigenomics and genomics (mutational profiling). These improvements will be used to profile bone marrow samples isolated from pre-malignant patients, patients with MM, and MM patients with drug resistance. To facilitate biological interpretation of the data, I will develop single-cell computational tools and systems biology methodologies. These will allow me to map the interactions between the different biological components of the TME and inform how MM develops and drug resistance occurs. Ultimately, I will generate a list of priority drug targets that will be followed up by the Oxford Centre for MM Research, University of Oxford.
In collaboration with colleagues at a UK biotechnology firm, we have established cost-effective multiplexed single-cell technology that is capable of capturing both RNA and DNA on the same oligonucleotide. This technology therefore enables the measurement of both the transcriptome as well as the accessibility of the chromatin, within the same cell - an important advance in the area of single-cell technology. To realise the full potential of our technology, I will expand its utility to include the multiplexing of transcriptomics with epigenomics and genomics (mutational profiling). These improvements will be used to profile bone marrow samples isolated from pre-malignant patients, patients with MM, and MM patients with drug resistance. To facilitate biological interpretation of the data, I will develop single-cell computational tools and systems biology methodologies. These will allow me to map the interactions between the different biological components of the TME and inform how MM develops and drug resistance occurs. Ultimately, I will generate a list of priority drug targets that will be followed up by the Oxford Centre for MM Research, University of Oxford.
Publications
Awoyemi T
(2023)
A cross-sectional analysis of syncytiotrophoblast membrane extracellular vesicles-derived transcriptomic biomarkers in early-onset preeclampsia.
in Frontiers in cardiovascular medicine
Baldwin M
(2023)
A roadmap for delivering a human musculoskeletal cell atlas
in Nature Reviews Rheumatology
Baldwin MJ
(2021)
Mapping the musculoskeletal system one cell at a time.
in Nature reviews. Rheumatology
Baldwin MJ
(2021)
Electrospun Scaffold Micro-Architecture Induces an Activated Transcriptional Phenotype within Tendon Fibroblasts.
in Frontiers in bioengineering and biotechnology
Boakye Serebour T
(2024)
Overcoming barriers to single-cell RNA sequencing adoption in low- and middle-income countries.
in European journal of human genetics : EJHG
Brown EJ
(2024)
PRMT5 inhibition shows in vitro efficacy against H3K27M-altered diffuse midline glioma, but does not extend survival in vivo.
in Scientific reports
Chen N
(2022)
Edible plant-derived nanotherapeutics and nanocarriers: recent progress and future directions.
in Expert opinion on drug delivery
COvid-19 Multi-Omics Blood ATlas (COMBAT) Consortium
(2022)
A blood atlas of COVID-19 defines hallmarks of disease severity and specificity
in Cell
| Description | An ancestrally inclusive atlas of healthy human musculoskeletal tissues |
| Amount | $1,999,999 (USD) |
| Organisation | Chan Zuckerberg Initiative |
| Sector | Private |
| Country | United States |
| Start | 03/2022 |
| End | 04/2025 |
| Description | BMS-Oxford Fellowship program |
| Amount | £650,000 (GBP) |
| Organisation | Bristol-Myers Squibb |
| Sector | Private |
| Country | United Kingdom |
| Start | 01/2021 |
| End | 01/2024 |
| Description | EPSRC IAA Technology Fund |
| Amount | £75,000 (GBP) |
| Funding ID | 0009858 |
| Organisation | Engineering and Physical Sciences Research Council (EPSRC) |
| Sector | Public |
| Country | United Kingdom |
| Start | 01/2021 |
| End | 12/2021 |
| Description | EPSRC IAA Technology award |
| Amount | £49,000 (GBP) |
| Organisation | Engineering and Physical Sciences Research Council (EPSRC) |
| Sector | Public |
| Country | United Kingdom |
| Start | 01/2022 |
| End | 06/2022 |
| Description | Harnessing the interplay of genetics, cells, and matrix, to deliver insights into musculoskeletal health and new therapies in musculoskeletal disease |
| Amount | £4,254,142 (GBP) |
| Funding ID | MR/Y030419/1 |
| Organisation | Medical Research Council (MRC) |
| Sector | Public |
| Country | United Kingdom |
| Start | 03/2024 |
| End | 04/2028 |
| Description | Studentship for Danson Loi |
| Amount | £150,692 (GBP) |
| Organisation | Cancer Research UK |
| Sector | Charity/Non Profit |
| Country | United Kingdom |
| Start | 09/2022 |
| End | 10/2026 |
| Description | Studentship for Roy Nathanson |
| Amount | £133,744 (GBP) |
| Organisation | Cancer Research UK |
| Sector | Charity/Non Profit |
| Country | United Kingdom |
| Start | 09/2024 |
| End | 10/2028 |
| Title | scCOLOR-seq for long-read single-cell sequencing |
| Description | scCOLOR-seq enables error correction of barcode and unique molecular identifier oligonucleotide sequences and permits standalone cDNA nanopore sequencing of single cells. |
| Type Of Material | Technology assay or reagent |
| Year Produced | 2021 |
| Provided To Others? | Yes |
| Impact | The development of this assay has led to the establishment of Caeruleus Genomics, an early stage spinout company to commercialise this technology. I have also been invited to attend several prestigious conferences and workshops in the coming year. |
| URL | https://www.nature.com/articles/s41587-021-00965-w |
| Description | Collaboration with Kwee Yong at UCL |
| Organisation | University College London |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | In collaboration with Professor Kwee Yong at University College London (UCL), our research team has significantly contributed to the RADAR trial, a pioneering study aimed at improving risk stratification in multiple myeloma (MM) through advanced genomic profiling. Our efforts have centred around the application and refinement of DNA and RNA long-read sequencing techniques, which are crucial for uncovering the complex genomic features that underpin risk in MM. |
| Collaborator Contribution | Our primary contribution has been the development and optimisation of long-read sequencing protocols specific to the MM genome. This involved rigorous benchmarking against existing sequencing methods to ensure superior accuracy and efficiency in detecting structural variations and splice variants that short-read sequencing might miss. Our expertise in bioinformatics has enabled us to design custom analytical pipelines that can process and interpret the voluminous data produced by long-read sequencing, thereby identifying genomic markers of prognosis and treatment response with unprecedented clarity. Furthermore, we have been deeply involved in the integration of these genomic insights with clinical data, aiming to construct a more nuanced risk stratification model for MM patients. By doing so, we aim to facilitate personalised treatment approaches that can significantly improve patient outcomes. |
| Impact | We have currently sequenced 20 DNA samples whole genome and 75 RNA samples using Oxford Nanopore Technologies |
| Start Year | 2023 |
| Title | BEAD-HASHING |
| Description | The invention relates to means and methods for producing libraries of analytes, such as polynucleotides, from a plurality of samples, such as single cells. The invention uses micro- particles that include both barcoded analyte capture polynucleotides and barcoded polynucleotides having a hairpin sequence. The micro-particles are divided between compartments together with sample. During library production, the hairpin sequences dimerise to produce polynucleotides comprising two barcode sequences. The dimers provide information about how many micro-particles were co-compartmentalised and with which sample analytes. This bead hashing method allows for increased loading of micro-particles into compartments with sample leading to increased throughput, greater efficiency and reduced loss of sample from analysis. |
| IP Reference | WO2024028589 |
| Protection | Patent / Patent application |
| Year Protection Granted | 2024 |
| Licensed | Yes |
| Title | CHIMERIC ARTEFACT DETECTION METHOD |
| Description | The invention relates to methods for detecting chimeric artefact polynucleotides produced during amplification of a mixed sample of polynucleotide. The methods comprise adding identifier sequences to both ends of a sample polynucleotide. Also provided are arrays of annealed oligonucleotide strand pairs for providing a mixed pool of identifier sequences; kits and methods for producing a library of polynucleotides, or libraries of polynucleotides having identifier sequences at both ends of the polynucleotides; and arrays of template switch oligonucleotides. |
| IP Reference | WO2023194714 |
| Protection | Patent / Patent application |
| Year Protection Granted | 2023 |
| Licensed | Yes |
| Title | Multiplexed Sequencing |
| Description | The invention was first conceived at the Botnar Research Centre during back of the envelope discussions between Martin Philpott and Adam Cribbs. The invention was then further refined following discussions between ATDBio, Prof Tom Brown and Prof Udo Oppermann. |
| IP Reference | |
| Protection | Patent application published |
| Year Protection Granted | 2021 |
| Licensed | No |
| Impact | The technology is the bases for a spin-out company 'Caeruleus Genomics' |
| Title | OLIGONUCLEOTIDES |
| Description | The invention relates to methods of adding identifier sequences to polynucleotides of an array. The identifier sequences comprise a plurality of nucleotide blocks. Also provided are arrays of polynucleotides having identifier sequences, microparticles comprising said arrays, a plurality of 5 said microparticles, surfaces comprising said arrays, kits and methods for generating libraries using the array, methods for determining the accuracy of sequencing or amplification an array, and methods of analysing said libraries. |
| IP Reference | WO2022118027 |
| Protection | Patent / Patent application |
| Year Protection Granted | 2022 |
| Licensed | Yes |
| Impact | The patent has been licensed to Caeruleus Genomics a spinout company that I co-founded |
| Title | POLYNUCLEOTIDE ARRAYS |
| Description | The invention relates to micro-particles in which polynucleotides are joined to a bead at the 3' end and include a linker that can be cleaved to separate the polynucleotides from the bead and provide free 3' hydroxyl groups. Also provided are arrays of polynucleotides, pluralities of micro-particles, fluidic compartments comprising micro-particles, methods of synthesising the arrays and methods of generating libraries using the array. |
| IP Reference | WO2021229230 |
| Protection | Patent application published |
| Year Protection Granted | 2021 |
| Licensed | No |
| Impact | This patent protects the basis of single-cell sequencing technology and has led to the establishment of a spinout company "Caeruleus Genomics". We will deliver sequencing platform agnostic turnkey solutions built on unique modular technologies that enable novel single cell applications Caeruleus Genomics sits at the interface between long read sequencing, single cell sequencing and genomics. |
| Title | TallyNN - correcting single-cell barcodes and UMIs |
| Description | TallyNN is a collection of single-cell workflows that allow users to perform barcode and UMI correction for oligonucleotide sequences that are synthesised using double phosphoramidites for droplet based single-cell sequencing. |
| Type Of Technology | Software |
| Year Produced | 2021 |
| Open Source License? | Yes |
| Impact | This software facilitates the analysis of single-cell long-read sequencing and has allowed other single-cell researchers to adopt our scCOLOR-seq technology. |
| URL | https://github.com/Acribbs/TallyNN |
| Title | TallyTriN |
| Description | TallyTriN is a collection of bulk and single-cell workflows that utilize Unique Molecular Identifiers (UMIs) synthesized using trimer blocks of nucleotides. |
| Type Of Technology | Software |
| Year Produced | 2024 |
| Open Source License? | Yes |
| Impact | The development of the software for analysing trimer Unique Molecular Identifiers (UMIs) in the context of single-cell and long-read sequencing technologies has had several notable impacts on the scientific community, particularly in genomics and transcriptomics. These impacts can be categorised into methodological advancements, enhanced accuracy, and broadened research applications: Methodological Advancements: The introduction of trimer UMIs has significantly improved the methodology for distinguishing between true biological sequences and those resulting from PCR duplicates or sequencing errors. This is critical in single-cell sequencing where the amplification of minute amounts of DNA is necessary, and in long-read sequencing where error rates can be higher than short-read approaches. By accurately identifying unique molecules, the software enables more precise quantification of gene expression levels and genetic variations. Enhanced Accuracy and Data Quality: The use of trimer UMIs has been instrumental in enhancing the accuracy of sequencing data. By facilitating the distinction between technical noise and genuine biological variation, the software improves the reliability of downstream analyses, such as variant calling, allele-specific expression, and detection of rare transcripts or mutations. This accuracy is vital for studies that rely on subtle genomic or transcriptomic differences to draw biological conclusions. Broadened Research Applications: The ability to accurately analyse single-cell and long-read data using trimer UMIs has broadened the scope of research applications. This includes complex studies on tumor heterogeneity, cell lineage tracing, and the mapping of full-length transcripts in single cells. It enables researchers to delve deeper into the complexities of genomic and transcriptomic landscapes at a resolution previously unattainable, facilitating discoveries in fields such as developmental biology, neurology, and cancer research. Facilitation of Large-scale Studies: The software has made it feasible to conduct large-scale studies that require the analysis of thousands to millions of cells or extensive genomic regions. This scalability is essential for population-level studies, comprehensive disease mapping, and the construction of detailed cell atlases, contributing to our understanding of human health and disease. |
| URL | https://github.com/cribbslab/TallyTriN |
| Title | cgat-developers/cgat-core: v0.6.9 |
| Description | This release removed the yaml.load() in favour of yaml.safe_load() |
| Type Of Technology | Software |
| Year Produced | 2021 |
| Open Source License? | Yes |
| Impact | This software is a major release of code that was initially published in 2019 (https://f1000research.com/articles/8-377/v2). This software is a python framework that underpins all of our computational workflows and this major release adds cloud based functionality and improved cluster functionality. |
| URL | https://zenodo.org/record/5574592 |
| Title | mclUMI - demultiplexing UMIs |
| Description | This repository deposits the Mclumi toolkit developed by Markov clustering (MCL) network-based algorithms for precisely localizing unique UMIs and thus removing PCR duplicates. Mclumi enables a construction of sub-graphs with UMI nodes to be relatively strongly connected. |
| Type Of Technology | Software |
| Year Produced | 2021 |
| Open Source License? | Yes |
| Impact | This software will form the basis of a manuscript that is currently in draft stage. I have also been asked to present this work at a long-read workshop at the Jackson laboratories in 2022 (https://www.jax.org/education-and-learning/education-calendar/2022/may/long-read-sequencing-workshop) |
| Company Name | Caeruleus Genomics |
| Description | Caeruleus Genomics develops technology for functional cell profiling and novel target discovery. |
| Year Established | 2022 |
| Impact | The company has only recently been established and we are currently in the process of raising venture capital funds to fully incorporate the company and develop single-cell sequencing products. |
| Website | http://caeruleus.bio |
| Description | Attended the Bone Cancer Research Trust 25 year party |
| Form Of Engagement Activity | Participation in an activity, workshop or similar |
| Part Of Official Scheme? | No |
| Geographic Reach | National |
| Primary Audience | Supporters |
| Results and Impact | I attended the BCRT 25 year celebrations. As part of this I presented two posters detailing the groups work and talked to several patients about the research currently undertaken within the group. |
| Year(s) Of Engagement Activity | 2021 |
| Description | Patient group online talk |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | National |
| Primary Audience | Patients, carers and/or patient groups |
| Results and Impact | Over 100 individuals from the Bone Cancer Research Trust (BCRT) patient network were invited to attend my talk on Multiple Myeloma and Chordoma research. |
| Year(s) Of Engagement Activity | 2021 |