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  • Douglas Higgs

About the Research

Our laboratory is interested in the general question of how mammalian genes are switched on and off during lineage commitment and differentiation. We use the most recent genomics technologies and computational approaches to study both the entire genome and individual genes in detail. We study all aspects of gene expression including the key cis-regulatory elements (enhancers, promoters and insulators), the transcription factors and co-factors that bind them, the epigenetic modifications of chromatin and DNA, and the role of associated phenomena such as chromosome conformation and nuclear sub-compartmentalisation using state-of-the-art imaging techniques. These studies are performed both in cell systems and in model organisms as well as in material from human patients with various inherited and acquired, genetic and epigenetic abnormalities. The translational goal of our work is to develop new ways to modify gene expression during blood formation with the aim of manipulating gene expression and ameliorating the clinical phenotypes of patients with a variety of blood disorders. 

We study gene regulation using the human and mouse globin loci as haematopoietic cells undergo lineage fate decisions and differentiation. Our aim is to understand the principles by which all mammalian genes are switched on and off during cell fate decisions. Globin gene expression is controlled by a group of conserved, long-range regulatory elements some of which lie within the introns of an adjacent widely expressed gene (Nprl3) and another lies in intergenic DNA. All of these elements have the chromatin signature of enhancers. Using Chromosome Conformation Capture, we have shown that these enhancers physically interact with each other and with the globin gene promoters, and together are essential for normal globin gene expression. From genome-wide studies, this configuration appears to be a common feature of highly expressed, lineage-specific genes and such groups of regulatory elements are referred to as “super-enhancers”. We continue to study such enhancers to understand how they interact with the globin promoters and their effect on the transcription cycle. More recently we have developed analyses to examine gene regulation in single cells including imaging approaches that allow us to visualise chromatin movements and transcription of these genes in real time. 

We have recently performed Hi-C experiments and have defined the Topologically Associated chromatin Domain (TAD) containing the globin gene cluster in erythroid and non-erythroid cells. We have also characterised the formation of this domain and of the enhancer promoter contacts during normal in vivo differentiation. We are currently investigating how activation, deletion and re-orientation of the globin regulatory elements (enhancers, promoters and boundary elements) affect expression of other genes within the same TAD and in neighbouring TADs. We also study chromatin structure and movement in real time using super-resolution imaging. Importantly, using globin as our model, we are addressing the general question of the relationship between higher order, long-range chromosomal structure and function. 

In addition to understanding how genes are activated we are also interested in how they are silenced. One of the globin genes, lying within the TAD, is only expressed in early developmental life and then remains silenced during adult life. Reactivation of this gene may represent a novel therapeutic option for patients with severe alpha-thalassemia. We are studying the transcriptional and epigenetic pathway by which this gene is silenced and kept so even though it lies adjacent to active erythroid enhancers. Again this is a general question in mammalian genetics and the globin system provides a unique opportunity to establish the biological principles by which gene silencing occurs. 

An important aim of our work is to develop new ways of treating blood disorders by genome editing of the regulatory elements we are studying. We currently have clinical projects underway in Sri Lanka and Thailand to develop such techniques to treat patients with thalassaemia, a common form of inherited anaemia. 

Students joining our laboratory will have a choice of projects which address current topics in the regulation of gene expression, and their application to human genetic disease, using state-of-the-art approaches to these questions.

Additional supervision will be provided by Dr Mira Kassouf. 

Please see the Weatherall Institute for Molecular Medicine (WIMM) for information about applications for a DPhil in Medical Sciences with groups based in the WIMM.

Training Opportunities

The Higgs laboratory offers a wide range of training opportunities in cell biology, molecular biology and computational approaches to biology. We train students in all aspects of cell biology using cell lines and primary cells from a range of organisms. We use all forms of flow cytometry to isolate and characterise common and rare cell types including stem/progenitor cells and we provide full training in this technology. When required, we also train students in mouse genetics to generate specific models for our research. Molecular techniques used in the laboratory include all forms of sequence- based analysis of DNA, RNA and chromatin both in cell populations (ATAC-seq, RNA-seq, ChIP-seq, CUT&RUN etc) and in individual single cells (scRNA-seq, scATAC-seq).  We also have access to the full range of proteomics, including single cell proteomics, and structural biology. The laboratory has also pioneered high resolution protocols for chromosomal conformation capture. We also routinely use genome editing, advanced forms of homology directed recombination, and synthetic biology to develop new models and approaches to understand the regulation of gene expression. An important new dimension to our research involves the use of advanced imaging, including super-resolution imaging, particularly in real time. Students interested in such projects will receive appropriate training in these techniques. We provide comprehensive training in all aspects of computational biology to analyse the resulting datasets.

Students will be enrolled on the MRC WIMM DPhil Course, which takes place in the autumn of their first year. Running over several days, this course helps students to develop basic research and presentation skills, as well as introducing them to a wide-range of scientific techniques and principles, ensuring that students have the opportunity to build a broad-based understanding of differing research methodologies.

Generic skills training is offered through the Medical Sciences Division's Skills Training Programme. This programme offers a comprehensive range of courses covering many important areas of researcher development: knowledge and intellectual abilities, personal effectiveness, research governance and organisation, and engagement, influence and impact. Students are actively encouraged to take advantage of the training opportunities available to them.

As well as the specific training detailed above, students will have access to a wide-range of seminars and training opportunities through the many research institutes and centres based in Oxford.

All MRC WIMM graduate students are encouraged to participate in the successful mentoring scheme of the Radcliffe Department of Medicine, which is the host department of the MRC WIMM. This mentoring scheme provides an additional possible channel for personal and professional development outside the regular supervisory framework. The RDM also holds an Athena SWAN Silver Award in recognition of our efforts to build a happy and rewarding environment where all staff and students are supported to achieve their full potential.

 

PUBLICATIONS

1

Single-Cell Proteomics Reveal that Quantitative Changes in Co-expressed Lineage-Specific Transcription Factors Determine Cell Fate. Palii CG, Cheng Q, Gillespie MA, Shannon P, Mazurczyk M, Napolitani G, Price ND, Ranish JA, Morrissey E, Higgs DR, Brand M. Cell Stem Cell. 2019 

2

A tissue-specific self-interacting chromatin domain forms independently of enhancer-   promoter interactions. Brown JM, Roberts NA, Graham B, Waithe D, Lagerholm C, Telenius JM, De Ornellas S, Oudelaar AM, Scott C, Szczerbal I, Babbs C, Kassouf MT, Hughes JR, Higgs DR, Buckle VJ.  2017 Nat Commun. 

3

Tissue-specific CTCF-cohesin-mediated chromatin architecture delimits enhancer interactions and function in vivo. Hanssen LLP, Kassouf MT, Oudelaar AM, Biggs D, Preece C, Downes DJ, Gosden M, Sharpe JA, Sloane-Stanley JA, Hughes JR ...Higgs DR and Buckle V. 2017. Nat Cell Biol 19: 952-961.

4

Testing the super-enhancer concept by in-vivo dissection. Hay D, Hughes JR, Babbs C, Davies JOJ, Graham BJ, Hanssen L, Kassouf MT, Oudelaar AM, Sharpe ja, Suciu M, Telenius J, Williams R, Rode C, Li P-S, Pennacchio LA, Sauka-Spengler T, Sloane-Stanley JA, Ayyub H, Butler S, Gibbons RJ, Smith AJH, Wood WG & Higgs DR (2016) Nature genetics, 48, 895-903.

5

Analysis of hundreds of cis-regulatory landscapes at high resolution in a single, high-throughput experiment.  Hughes, J.R., Roberts, N., McGowan, S., Haay, D., Giannoulatou, E., Lynch, M., de Gobbi, M., Taylor, S., Gibbons, R. & Higgs, D.R. (2014) Nat Genet46: 205-212.

6

Single-allele chromatin interactions identify regulatory hubs in dynamic compartmentalized domains. Oudelaar AM, Davies JOJ, Hanssen LLP, Telenius JM, Schwessinger R, Liu Y, Brown JM, Downes DJ, Chiariello AM, Bianco S, Nicodemi M, Buckle VJ, Dekker J, Higgs DR, Hughes JR. Nat Genet. 2018 

7

Dynamics of the 4D genome during in vivo lineage specification and differentiation. Oudelaar AM, Beagrie RA, Gosden M, de Ornellas S, Georgiades E, Kerry J, Hidalgo D, Carrelha J, Shivalingam A, El-Sagheer AH, Telenius JM, Brown T, Buckle VJ, Socolovsky M, Higgs DR, Hughes JR . Nat Commun. 2020

Jeziorska DM, Tunnacliffe EAJ, Brown JM, Ayyub H, Sloane-Stanley J, Sharpe JA, Lagerholm BC, Babbs C, Smith AJH, Buckle VJ, Higgs DR. On-microscope staging of live cells reveals changes in the dynamics of transcriptional bursting during differentiation. Nat Commun. 2022