Updates from the Sussex Cancer Research Centre on World Cancer Day.

Our brain constantly processes information coming from our senses. According to new scientific models, when impaired, these processes lead to feeling fatigued. While people with and beyond cancer are likely to experience fatigue, these models have yet to be tested in cancer patients. This project will investigate sensory information processing and fatigue in people with cancer and healthy participants. This project will also examine immune profiles to try and identify causes of fatigue.

This project establishes a new team consisting of an oncologist, psychiatrist and researchers from across Sussex. The team also have access to new facilities to enable research in partnership with people who live with and beyond cancer.

Cancer-related fatigue is recognized as a significant and distressing symptom and both causes and management strategies are key research priorities in the UK. This project will enable us to study its cause so patients and carers can understand the symptom better, allowing for the development of interventions to help all beat it.

Project Lead: Dr Jeanne Dekerle, Reader, School of Education, Sport and Health, University of Brighton

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Diffuse large B-cell lymphoma (DLBCL) is the most common type of blood cancer. While standard treatment works for about 60% of patients, 40% either do not respond or experience relapse, highlighting the need for better treatment options. One major reason for treatment failure is that some cancer cells can survive therapy (drug resistance). These surviving tumour cells are often supported by the “normal” cells surrounding the tumour, known as the tumour microenvironment (TME), which help the tumour survive and grow.

This project works toward bringing a new combination treatment to DLBCL patients. Through new methods that enable the investigation of interactions between cancer and TME, this project will test our promising new drug combination, paving the way for potential clinical trials.

Project Lead: Dr Fabio Simoes, Assistant Professor in Cancer Research at Brighton and Sussex Medical School

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People who undergo colorectal cancer surgery do better if they are physically active. This project is the first step in the development of an inclusive intervention, to help less active people, get active. We aim to collect information about activity to ‘co-produce’ a user-friendly activity intervention. This will be through partnering with patients, the public and health care professionals.

This project will engage people who’ve had colorectal cancer surgery to understand how we could improve outcomes with physical activity. It will focus particularly on technology (e.g. smartphones), to see if they could help. This project will also work with people who have had colorectal cancer surgery to determine what they think are important goals to achieve and what a good recovery looks like.

Colorectal cancer is the fourth most common cancer in the UK. For physical activity, the biggest benefit is moving people from being inactive to doing even light activities. Therefore, this project will focus on this group and aims to support patients to be best prepared for surgery. As a result, they would be more likely to recover well. This will benefit both individuals and the wider health service.

Project Lead: Dr Luke Hodgson, Intensive Care and Respiratory Consultant, Worthing Hospital

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The DNA in human cells is regularly damaged, even by the body's normal cellular processes. A DNA break in a chromosome can be caused by environmental exposure to radiation and chemicals but may also result from cell metabolism. Left unrepaired or incorrectly repaired, this may have the potential to cause and drive cancer. Fortunately, the body has sophisticated pathways to repair damaged DNA, but these are often altered in cancer to help tumours grow or resist chemotherapy and radiation treatment. Some cancers suppress the DNA repair system to allow cancer cells to divide with markedly damaged chromosomes. Ovarian cancers make use of a specific protein, which allows them to ignore DNA repair systems. Blocking or removing this protein from ovarian cancer cells makes them more susceptible to dying with chemotherapy and can reduce tumour growth. Despite its promise we do not understand, at an atomic level, what this protein looks like and how it works. Such information is critical for the discovery and development of intelligently designed drugs. We are aiming to find vulnerabilities in this protein that we can exploit for drug development. This could form the basis for a new class of chemotherapies to treat and cure the disease. Resistance to chemotherapy is a problem for ovarian cancers, therefore new therapies are much needed.

Project Lead: Dr Luke Yates, Assistant Professor in Genome Stability, Genome Damage and Stability Centre, University of Sussex

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Acute myeloid leukemia (AML) is an aggressive type of blood cancer that produces defective immature white blood cells which eventually lead to bone marrow failure. Adults and children can get AML, but typically this disease is diagnosed in older people. There is an urgent medical need for alternative targeted treatments with reduced side-effects.

Most AML cases present with overexpression of a cancer-promoting protein called beta-catenin yet there remains no approved drug that targets beta-catenin. Beta-catenin promotes leukemia by interacting with other proteins, so our lab investigated these partner proteins and discovered a new family of partner proteins.

This project will exploit the expertise of multiple institutes within the Sussex Cancer Research Centre to discover the overall level of these new protein partners in leukemia patient samples, their contribution to healthy blood and AML development, and how they regulate the signalling in AML cells. This initial information will allow us to design a new class of drugs that are safe and effective at reducing the levels of beta-catenin in blood cells. Future collaboration with medicinal chemists and structural biologists will work towards the creation of new class of drugs to halt AML progression, which could also be applicable to many other cancer types beyond.

Project Lead: Megan Wagstaff, Research Fellow, School of Life Sciences, University of Sussex

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This project has two parts, one located at the Falmer campus, and one found across the SCRC campus. These artworks arose from Markus’s physical and psychological experiences during and after treatment for an incurable blood cancer.

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This project offers an innovative way to put people with lived experience at the heart our research.

Through creative workshops, people with lived experience of cancer will explore their own stories, using facilitated creative writing and collage. Co-production of artistic pieces containing words and collage will create the opportunitiy for the patient voice to be heard. By using the experience of the waiting room, where people often ruminate on their disease and consultation, this project will give unique insights into the lived experience of those served by our research.

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